// Copyright 2011 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 race_test import ( "bytes" "errors" "fmt" "hash/crc32" "io" "os" "runtime" "sync" "testing" "time" "unsafe" ) type Point struct { x, y int } type NamedPoint struct { name string p Point } type DummyWriter struct { state int } type Writer interface { Write(p []byte) (n int) } func (d DummyWriter) Write(p []byte) (n int) { return 0 } var GlobalX, GlobalY int = 0, 0 var GlobalCh chan int = make(chan int, 2) func GlobalFunc1() { GlobalY = GlobalX GlobalCh <- 1 } func GlobalFunc2() { GlobalX = 1 GlobalCh <- 1 } func TestRaceIntRWGlobalFuncs(t *testing.T) { go GlobalFunc1() go GlobalFunc2() <-GlobalCh <-GlobalCh } func TestRaceIntRWClosures(t *testing.T) { var x, y int _ = y ch := make(chan int, 2) go func() { y = x ch <- 1 }() go func() { x = 1 ch <- 1 }() <-ch <-ch } func TestNoRaceIntRWClosures(t *testing.T) { var x, y int _ = y ch := make(chan int, 1) go func() { y = x ch <- 1 }() <-ch go func() { x = 1 ch <- 1 }() <-ch } func TestRaceInt32RWClosures(t *testing.T) { var x, y int32 _ = y ch := make(chan bool, 2) go func() { y = x ch <- true }() go func() { x = 1 ch <- true }() <-ch <-ch } func TestNoRaceCase(t *testing.T) { var y int for x := -1; x <= 1; x++ { switch { case x < 0: y = -1 case x == 0: y = 0 case x > 0: y = 1 } } y++ } func TestRaceCaseCondition(t *testing.T) { var x int = 0 ch := make(chan int, 2) go func() { x = 2 ch <- 1 }() go func() { switch x < 2 { case true: x = 1 //case false: // x = 5 } ch <- 1 }() <-ch <-ch } func TestRaceCaseCondition2(t *testing.T) { // switch body is rearranged by the compiler so the tests // passes even if we don't instrument '<' var x int = 0 ch := make(chan int, 2) go func() { x = 2 ch <- 1 }() go func() { switch x < 2 { case true: x = 1 case false: x = 5 } ch <- 1 }() <-ch <-ch } func TestRaceCaseBody(t *testing.T) { var x, y int _ = y ch := make(chan int, 2) go func() { y = x ch <- 1 }() go func() { switch { default: x = 1 case x == 100: x = -x } ch <- 1 }() <-ch <-ch } func TestNoRaceCaseFallthrough(t *testing.T) { var x, y, z int _ = y ch := make(chan int, 2) z = 1 go func() { y = x ch <- 1 }() go func() { switch { case z == 1: case z == 2: x = 2 } ch <- 1 }() <-ch <-ch } func TestRaceCaseFallthrough(t *testing.T) { var x, y, z int _ = y ch := make(chan int, 2) z = 1 go func() { y = x ch <- 1 }() go func() { switch { case z == 1: fallthrough case z == 2: x = 2 } ch <- 1 }() <-ch <-ch } func TestRaceCaseIssue6418(t *testing.T) { m := map[string]map[string]string{ "a": { "b": "c", }, } ch := make(chan int) go func() { m["a"]["x"] = "y" ch <- 1 }() switch m["a"]["b"] { } <-ch } func TestRaceCaseType(t *testing.T) { var x, y int var i any = x c := make(chan int, 1) go func() { switch i.(type) { case nil: case int: } c <- 1 }() i = y <-c } func TestRaceCaseTypeBody(t *testing.T) { var x, y int var i any = &x c := make(chan int, 1) go func() { switch i := i.(type) { case nil: case *int: *i = y } c <- 1 }() x = y <-c } func TestRaceCaseTypeIssue5890(t *testing.T) { // spurious extra instrumentation of the initial interface // value. var x, y int m := make(map[int]map[int]any) m[0] = make(map[int]any) c := make(chan int, 1) go func() { switch i := m[0][1].(type) { case nil: case *int: *i = x } c <- 1 }() m[0][1] = y <-c } func TestNoRaceRange(t *testing.T) { ch := make(chan int, 3) a := [...]int{1, 2, 3} for _, v := range a { ch <- v } close(ch) } func TestNoRaceRangeIssue5446(t *testing.T) { ch := make(chan int, 3) a := []int{1, 2, 3} b := []int{4} // used to insert a spurious instrumentation of a[i] // and crash. i := 1 for i, a[i] = range b { ch <- i } close(ch) } func TestRaceRange(t *testing.T) { const N = 2 var a [N]int var x, y int _ = x + y done := make(chan bool, N) var i, v int // declare here (not in for stmt) so that i and v are shared w/ or w/o loop variable sharing change for i, v = range a { go func(i int) { // we don't want a write-vs-write race // so there is no array b here if i == 0 { x = v } else { y = v } done <- true }(i) // Ensure the goroutine runs before we continue the loop. runtime.Gosched() } for i := 0; i < N; i++ { <-done } } func TestRaceForInit(t *testing.T) { c := make(chan int) x := 0 go func() { c <- x }() for x = 42; false; { } <-c } func TestNoRaceForInit(t *testing.T) { done := make(chan bool) c := make(chan bool) x := 0 go func() { for { _, ok := <-c if !ok { done <- true return } x++ } }() i := 0 for x = 42; i < 10; i++ { c <- true } close(c) <-done } func TestRaceForTest(t *testing.T) { done := make(chan bool) c := make(chan bool) stop := false go func() { for { _, ok := <-c if !ok { done <- true return } stop = true } }() for !stop { c <- true } close(c) <-done } func TestRaceForIncr(t *testing.T) { done := make(chan bool) c := make(chan bool) x := 0 go func() { for { _, ok := <-c if !ok { done <- true return } x++ } }() for i := 0; i < 10; x++ { i++ c <- true } close(c) <-done } func TestNoRaceForIncr(t *testing.T) { done := make(chan bool) x := 0 go func() { x++ done <- true }() for i := 0; i < 0; x++ { } <-done } func TestRacePlus(t *testing.T) { var x, y, z int _ = y ch := make(chan int, 2) go func() { y = x + z ch <- 1 }() go func() { y = x + z + z ch <- 1 }() <-ch <-ch } func TestRacePlus2(t *testing.T) { var x, y, z int _ = y ch := make(chan int, 2) go func() { x = 1 ch <- 1 }() go func() { y = +x + z ch <- 1 }() <-ch <-ch } func TestNoRacePlus(t *testing.T) { var x, y, z, f int _ = x + y + f ch := make(chan int, 2) go func() { y = x + z ch <- 1 }() go func() { f = z + x ch <- 1 }() <-ch <-ch } func TestRaceComplement(t *testing.T) { var x, y, z int _ = x ch := make(chan int, 2) go func() { x = ^y ch <- 1 }() go func() { y = ^z ch <- 1 }() <-ch <-ch } func TestRaceDiv(t *testing.T) { var x, y, z int _ = x ch := make(chan int, 2) go func() { x = y / (z + 1) ch <- 1 }() go func() { y = z ch <- 1 }() <-ch <-ch } func TestRaceDivConst(t *testing.T) { var x, y, z uint32 _ = x ch := make(chan int, 2) go func() { x = y / 3 // involves only a HMUL node ch <- 1 }() go func() { y = z ch <- 1 }() <-ch <-ch } func TestRaceMod(t *testing.T) { var x, y, z int _ = x ch := make(chan int, 2) go func() { x = y % (z + 1) ch <- 1 }() go func() { y = z ch <- 1 }() <-ch <-ch } func TestRaceModConst(t *testing.T) { var x, y, z int _ = x ch := make(chan int, 2) go func() { x = y % 3 ch <- 1 }() go func() { y = z ch <- 1 }() <-ch <-ch } func TestRaceRotate(t *testing.T) { var x, y, z uint32 _ = x ch := make(chan int, 2) go func() { x = y<<12 | y>>20 ch <- 1 }() go func() { y = z ch <- 1 }() <-ch <-ch } // May crash if the instrumentation is reckless. func TestNoRaceEnoughRegisters(t *testing.T) { // from erf.go const ( sa1 = 1 sa2 = 2 sa3 = 3 sa4 = 4 sa5 = 5 sa6 = 6 sa7 = 7 sa8 = 8 ) var s, S float64 s = 3.1415 S = 1 + s*(sa1+s*(sa2+s*(sa3+s*(sa4+s*(sa5+s*(sa6+s*(sa7+s*sa8))))))) s = S } // emptyFunc should not be inlined. // //go:noinline func emptyFunc(x int) { if false { fmt.Println(x) } } func TestRaceFuncArgument(t *testing.T) { var x int ch := make(chan bool, 1) go func() { emptyFunc(x) ch <- true }() x = 1 <-ch } func TestRaceFuncArgument2(t *testing.T) { var x int ch := make(chan bool, 2) go func() { x = 42 ch <- true }() go func(y int) { ch <- true }(x) <-ch <-ch } func TestRaceSprint(t *testing.T) { var x int ch := make(chan bool, 1) go func() { fmt.Sprint(x) ch <- true }() x = 1 <-ch } func TestRaceArrayCopy(t *testing.T) { ch := make(chan bool, 1) var a [5]int go func() { a[3] = 1 ch <- true }() a = [5]int{1, 2, 3, 4, 5} <-ch } // Blows up a naive compiler. func TestRaceNestedArrayCopy(t *testing.T) { ch := make(chan bool, 1) type ( Point32 [2][2][2][2][2]Point Point1024 [2][2][2][2][2]Point32 Point32k [2][2][2][2][2]Point1024 Point1M [2][2][2][2][2]Point32k ) var a, b Point1M go func() { a[0][1][0][1][0][1][0][1][0][1][0][1][0][1][0][1][0][1][0][1].y = 1 ch <- true }() a = b <-ch } func TestRaceStructRW(t *testing.T) { p := Point{0, 0} ch := make(chan bool, 1) go func() { p = Point{1, 1} ch <- true }() q := p <-ch p = q } func TestRaceStructFieldRW1(t *testing.T) { p := Point{0, 0} ch := make(chan bool, 1) go func() { p.x = 1 ch <- true }() _ = p.x <-ch } func TestNoRaceStructFieldRW1(t *testing.T) { // Same struct, different variables, no // pointers. The layout is known (at compile time?) -> // no read on p // writes on x and y p := Point{0, 0} ch := make(chan bool, 1) go func() { p.x = 1 ch <- true }() p.y = 1 <-ch _ = p } func TestNoRaceStructFieldRW2(t *testing.T) { // Same as NoRaceStructFieldRW1 // but p is a pointer, so there is a read on p p := Point{0, 0} ch := make(chan bool, 1) go func() { p.x = 1 ch <- true }() p.y = 1 <-ch _ = p } func TestRaceStructFieldRW2(t *testing.T) { p := &Point{0, 0} ch := make(chan bool, 1) go func() { p.x = 1 ch <- true }() _ = p.x <-ch } func TestRaceStructFieldRW3(t *testing.T) { p := NamedPoint{name: "a", p: Point{0, 0}} ch := make(chan bool, 1) go func() { p.p.x = 1 ch <- true }() _ = p.p.x <-ch } func TestRaceEfaceWW(t *testing.T) { var a, b any ch := make(chan bool, 1) go func() { a = 1 ch <- true }() a = 2 <-ch _, _ = a, b } func TestRaceIfaceWW(t *testing.T) { var a, b Writer ch := make(chan bool, 1) go func() { a = DummyWriter{1} ch <- true }() a = DummyWriter{2} <-ch b = a a = b } func TestRaceIfaceCmp(t *testing.T) { var a, b Writer a = DummyWriter{1} ch := make(chan bool, 1) go func() { a = DummyWriter{1} ch <- true }() _ = a == b <-ch } func TestRaceIfaceCmpNil(t *testing.T) { var a Writer a = DummyWriter{1} ch := make(chan bool, 1) go func() { a = DummyWriter{1} ch <- true }() _ = a == nil <-ch } func TestRaceEfaceConv(t *testing.T) { c := make(chan bool) v := 0 go func() { go func(x any) { }(v) c <- true }() v = 42 <-c } type OsFile struct{} func (*OsFile) Read() { } type IoReader interface { Read() } func TestRaceIfaceConv(t *testing.T) { c := make(chan bool) f := &OsFile{} go func() { go func(x IoReader) { }(f) c <- true }() f = &OsFile{} <-c } func TestRaceError(t *testing.T) { ch := make(chan bool, 1) var err error go func() { err = nil ch <- true }() _ = err <-ch } func TestRaceIntptrRW(t *testing.T) { var x, y int var p *int = &x ch := make(chan bool, 1) go func() { *p = 5 ch <- true }() y = *p x = y <-ch } func TestRaceStringRW(t *testing.T) { ch := make(chan bool, 1) s := "" go func() { s = "abacaba" ch <- true }() _ = s <-ch } func TestRaceStringPtrRW(t *testing.T) { ch := make(chan bool, 1) var x string p := &x go func() { *p = "a" ch <- true }() _ = *p <-ch } func TestRaceFloat64WW(t *testing.T) { var x, y float64 ch := make(chan bool, 1) go func() { x = 1.0 ch <- true }() x = 2.0 <-ch y = x x = y } func TestRaceComplex128WW(t *testing.T) { var x, y complex128 ch := make(chan bool, 1) go func() { x = 2 + 2i ch <- true }() x = 4 + 4i <-ch y = x x = y } func TestRaceUnsafePtrRW(t *testing.T) { var x, y, z int x, y, z = 1, 2, 3 var p unsafe.Pointer = unsafe.Pointer(&x) ch := make(chan bool, 1) go func() { p = (unsafe.Pointer)(&z) ch <- true }() y = *(*int)(p) x = y <-ch } func TestRaceFuncVariableRW(t *testing.T) { var f func(x int) int f = func(x int) int { return x * x } ch := make(chan bool, 1) go func() { f = func(x int) int { return x } ch <- true }() y := f(1) <-ch x := y y = x } func TestRaceFuncVariableWW(t *testing.T) { var f func(x int) int _ = f ch := make(chan bool, 1) go func() { f = func(x int) int { return x } ch <- true }() f = func(x int) int { return x * x } <-ch } // This one should not belong to mop_test func TestRacePanic(t *testing.T) { var x int _ = x var zero int = 0 ch := make(chan bool, 2) go func() { defer func() { err := recover() if err == nil { panic("should be panicking") } x = 1 ch <- true }() var y int = 1 / zero zero = y }() go func() { defer func() { err := recover() if err == nil { panic("should be panicking") } x = 2 ch <- true }() var y int = 1 / zero zero = y }() <-ch <-ch if zero != 0 { panic("zero has changed") } } func TestNoRaceBlank(t *testing.T) { var a [5]int ch := make(chan bool, 1) go func() { _, _ = a[0], a[1] ch <- true }() _, _ = a[2], a[3] <-ch a[1] = a[0] } func TestRaceAppendRW(t *testing.T) { a := make([]int, 10) ch := make(chan bool) go func() { _ = append(a, 1) ch <- true }() a[0] = 1 <-ch } func TestRaceAppendLenRW(t *testing.T) { a := make([]int, 0) ch := make(chan bool) go func() { a = append(a, 1) ch <- true }() _ = len(a) <-ch } func TestRaceAppendCapRW(t *testing.T) { a := make([]int, 0) ch := make(chan string) go func() { a = append(a, 1) ch <- "" }() _ = cap(a) <-ch } func TestNoRaceFuncArgsRW(t *testing.T) { ch := make(chan byte, 1) var x byte go func(y byte) { _ = y ch <- 0 }(x) x = 1 <-ch } func TestRaceFuncArgsRW(t *testing.T) { ch := make(chan byte, 1) var x byte go func(y *byte) { _ = *y ch <- 0 }(&x) x = 1 <-ch } // from the mailing list, slightly modified // unprotected concurrent access to seen[] func TestRaceCrawl(t *testing.T) { url := "dummyurl" depth := 3 seen := make(map[string]bool) ch := make(chan int, 100) var wg sync.WaitGroup var crawl func(string, int) crawl = func(u string, d int) { nurl := 0 defer func() { ch <- nurl }() seen[u] = true if d <= 0 { wg.Done() return } urls := [...]string{"a", "b", "c"} for _, uu := range urls { if _, ok := seen[uu]; !ok { wg.Add(1) go crawl(uu, d-1) nurl++ } } wg.Done() } wg.Add(1) go crawl(url, depth) wg.Wait() } func TestRaceIndirection(t *testing.T) { ch := make(chan struct{}, 1) var y int var x *int = &y go func() { *x = 1 ch <- struct{}{} }() *x = 2 <-ch _ = *x } func TestRaceRune(t *testing.T) { c := make(chan bool) var x rune go func() { x = 1 c <- true }() _ = x <-c } func TestRaceEmptyInterface1(t *testing.T) { c := make(chan bool) var x any go func() { x = nil c <- true }() _ = x <-c } func TestRaceEmptyInterface2(t *testing.T) { c := make(chan bool) var x any go func() { x = &Point{} c <- true }() _ = x <-c } func TestRaceTLS(t *testing.T) { comm := make(chan *int) done := make(chan bool, 2) go func() { var x int comm <- &x x = 1 x = *(<-comm) done <- true }() go func() { p := <-comm *p = 2 comm <- p done <- true }() <-done <-done } func TestNoRaceHeapReallocation(t *testing.T) { // It is possible that a future implementation // of memory allocation will ruin this test. // Increasing n might help in this case, so // this test is a bit more generic than most of the // others. const n = 2 done := make(chan bool, n) empty := func(p *int) { _ = p } for i := 0; i < n; i++ { ms := i go func() { <-time.After(time.Duration(ms) * time.Millisecond) runtime.GC() var x int empty(&x) // x goes to the heap done <- true }() } for i := 0; i < n; i++ { <-done } } func TestRaceAnd(t *testing.T) { c := make(chan bool) x, y := 0, 0 go func() { x = 1 c <- true }() if x == 1 && y == 1 { } <-c } func TestRaceAnd2(t *testing.T) { c := make(chan bool) x, y := 0, 0 go func() { x = 1 c <- true }() if y == 0 && x == 1 { } <-c } func TestNoRaceAnd(t *testing.T) { c := make(chan bool) x, y := 0, 0 go func() { x = 1 c <- true }() if y == 1 && x == 1 { } <-c } func TestRaceOr(t *testing.T) { c := make(chan bool) x, y := 0, 0 go func() { x = 1 c <- true }() if x == 1 || y == 1 { } <-c } func TestRaceOr2(t *testing.T) { c := make(chan bool) x, y := 0, 0 go func() { x = 1 c <- true }() if y == 1 || x == 1 { } <-c } func TestNoRaceOr(t *testing.T) { c := make(chan bool) x, y := 0, 0 go func() { x = 1 c <- true }() if y == 0 || x == 1 { } <-c } func TestNoRaceShortCalc(t *testing.T) { c := make(chan bool) x, y := 0, 0 go func() { y = 1 c <- true }() if x == 0 || y == 0 { } <-c } func TestNoRaceShortCalc2(t *testing.T) { c := make(chan bool) x, y := 0, 0 go func() { y = 1 c <- true }() if x == 1 && y == 0 { } <-c } func TestRaceFuncItself(t *testing.T) { c := make(chan bool) f := func() {} go func() { f() c <- true }() f = func() {} <-c } func TestNoRaceFuncUnlock(t *testing.T) { ch := make(chan bool, 1) var mu sync.Mutex x := 0 _ = x go func() { mu.Lock() x = 42 mu.Unlock() ch <- true }() x = func(mu *sync.Mutex) int { mu.Lock() return 43 }(&mu) mu.Unlock() <-ch } func TestRaceStructInit(t *testing.T) { type X struct { x, y int } c := make(chan bool, 1) y := 0 go func() { y = 42 c <- true }() x := X{x: y} _ = x <-c } func TestRaceArrayInit(t *testing.T) { c := make(chan bool, 1) y := 0 go func() { y = 42 c <- true }() x := []int{0, y, 42} _ = x <-c } func TestRaceMapInit(t *testing.T) { c := make(chan bool, 1) y := 0 go func() { y = 42 c <- true }() x := map[int]int{0: 42, y: 42} _ = x <-c } func TestRaceMapInit2(t *testing.T) { c := make(chan bool, 1) y := 0 go func() { y = 42 c <- true }() x := map[int]int{0: 42, 42: y} _ = x <-c } type Inter interface { Foo(x int) } type InterImpl struct { x, y int } //go:noinline func (p InterImpl) Foo(x int) { } type InterImpl2 InterImpl func (p *InterImpl2) Foo(x int) { if p == nil { InterImpl{}.Foo(x) } InterImpl(*p).Foo(x) } func TestRaceInterCall(t *testing.T) { c := make(chan bool, 1) p := InterImpl{} var x Inter = p go func() { p2 := InterImpl{} x = p2 c <- true }() x.Foo(0) <-c } func TestRaceInterCall2(t *testing.T) { c := make(chan bool, 1) p := InterImpl{} var x Inter = p z := 0 go func() { z = 42 c <- true }() x.Foo(z) <-c } func TestRaceFuncCall(t *testing.T) { c := make(chan bool, 1) f := func(x, y int) { _ = y } x, y := 0, 0 go func() { y = 42 c <- true }() f(x, y) <-c } func TestRaceMethodCall(t *testing.T) { c := make(chan bool, 1) i := InterImpl{} x := 0 go func() { x = 42 c <- true }() i.Foo(x) <-c } func TestRaceMethodCall2(t *testing.T) { c := make(chan bool, 1) i := &InterImpl{} go func() { i = &InterImpl{} c <- true }() i.Foo(0) <-c } // Method value with concrete value receiver. func TestRaceMethodValue(t *testing.T) { c := make(chan bool, 1) i := InterImpl{} go func() { i = InterImpl{} c <- true }() _ = i.Foo <-c } // Method value with interface receiver. func TestRaceMethodValue2(t *testing.T) { c := make(chan bool, 1) var i Inter = InterImpl{} go func() { i = InterImpl{} c <- true }() _ = i.Foo <-c } // Method value with implicit dereference. func TestRaceMethodValue3(t *testing.T) { c := make(chan bool, 1) i := &InterImpl{} go func() { *i = InterImpl{} c <- true }() _ = i.Foo // dereferences i. <-c } // Method value implicitly taking receiver address. func TestNoRaceMethodValue(t *testing.T) { c := make(chan bool, 1) i := InterImpl2{} go func() { i = InterImpl2{} c <- true }() _ = i.Foo // takes the address of i only. <-c } func TestRacePanicArg(t *testing.T) { c := make(chan bool, 1) err := errors.New("err") go func() { err = errors.New("err2") c <- true }() defer func() { recover() <-c }() panic(err) } func TestRaceDeferArg(t *testing.T) { c := make(chan bool, 1) x := 0 go func() { x = 42 c <- true }() func() { defer func(x int) { }(x) }() <-c } type DeferT int func (d DeferT) Foo() { } func TestRaceDeferArg2(t *testing.T) { c := make(chan bool, 1) var x DeferT go func() { var y DeferT x = y c <- true }() func() { defer x.Foo() }() <-c } func TestNoRaceAddrExpr(t *testing.T) { c := make(chan bool, 1) x := 0 go func() { x = 42 c <- true }() _ = &x <-c } type AddrT struct { _ [256]byte x int } type AddrT2 struct { _ [512]byte p *AddrT } func TestRaceAddrExpr(t *testing.T) { c := make(chan bool, 1) a := AddrT2{p: &AddrT{x: 42}} go func() { a.p = &AddrT{x: 43} c <- true }() _ = &a.p.x <-c } func TestRaceTypeAssert(t *testing.T) { c := make(chan bool, 1) x := 0 var i any = x go func() { y := 0 i = y c <- true }() _ = i.(int) <-c } func TestRaceBlockAs(t *testing.T) { c := make(chan bool, 1) var x, y int go func() { x = 42 c <- true }() x, y = y, x <-c } func TestRaceBlockCall1(t *testing.T) { done := make(chan bool) x, y := 0, 0 go func() { f := func() (int, int) { return 42, 43 } x, y = f() done <- true }() _ = x <-done if x != 42 || y != 43 { panic("corrupted data") } } func TestRaceBlockCall2(t *testing.T) { done := make(chan bool) x, y := 0, 0 go func() { f := func() (int, int) { return 42, 43 } x, y = f() done <- true }() _ = y <-done if x != 42 || y != 43 { panic("corrupted data") } } func TestRaceBlockCall3(t *testing.T) { done := make(chan bool) var x *int y := 0 go func() { f := func() (*int, int) { i := 42 return &i, 43 } x, y = f() done <- true }() _ = x <-done if *x != 42 || y != 43 { panic("corrupted data") } } func TestRaceBlockCall4(t *testing.T) { done := make(chan bool) x := 0 var y *int go func() { f := func() (int, *int) { i := 43 return 42, &i } x, y = f() done <- true }() _ = y <-done if x != 42 || *y != 43 { panic("corrupted data") } } func TestRaceBlockCall5(t *testing.T) { done := make(chan bool) var x *int y := 0 go func() { f := func() (*int, int) { i := 42 return &i, 43 } x, y = f() done <- true }() _ = y <-done if *x != 42 || y != 43 { panic("corrupted data") } } func TestRaceBlockCall6(t *testing.T) { done := make(chan bool) x := 0 var y *int go func() { f := func() (int, *int) { i := 43 return 42, &i } x, y = f() done <- true }() _ = x <-done if x != 42 || *y != 43 { panic("corrupted data") } } func TestRaceSliceSlice(t *testing.T) { c := make(chan bool, 1) x := make([]int, 10) go func() { x = make([]int, 20) c <- true }() _ = x[2:3] <-c } func TestRaceSliceSlice2(t *testing.T) { c := make(chan bool, 1) x := make([]int, 10) i := 2 go func() { i = 3 c <- true }() _ = x[i:4] <-c } func TestRaceSliceString(t *testing.T) { c := make(chan bool, 1) x := "hello" go func() { x = "world" c <- true }() _ = x[2:3] <-c } func TestRaceSliceStruct(t *testing.T) { type X struct { x, y int } c := make(chan bool, 1) x := make([]X, 10) go func() { y := make([]X, 10) copy(y, x) c <- true }() x[1].y = 42 <-c } func TestRaceAppendSliceStruct(t *testing.T) { type X struct { x, y int } c := make(chan bool, 1) x := make([]X, 10) go func() { y := make([]X, 0, 10) y = append(y, x...) c <- true }() x[1].y = 42 <-c } func TestRaceStructInd(t *testing.T) { c := make(chan bool, 1) type Item struct { x, y int } i := Item{} go func(p *Item) { *p = Item{} c <- true }(&i) i.y = 42 <-c } func TestRaceAsFunc1(t *testing.T) { var s []byte c := make(chan bool, 1) go func() { var err error s, err = func() ([]byte, error) { t := []byte("hello world") return t, nil }() c <- true _ = err }() _ = string(s) <-c } func TestRaceAsFunc2(t *testing.T) { c := make(chan bool, 1) x := 0 go func() { func(x int) { _ = x }(x) c <- true }() x = 42 <-c } func TestRaceAsFunc3(t *testing.T) { c := make(chan bool, 1) var mu sync.Mutex x := 0 go func() { func(x int) { _ = x mu.Lock() }(x) // Read of x must be outside of the mutex. mu.Unlock() c <- true }() mu.Lock() x = 42 mu.Unlock() <-c } func TestNoRaceAsFunc4(t *testing.T) { c := make(chan bool, 1) var mu sync.Mutex x := 0 _ = x go func() { x = func() int { // Write of x must be under the mutex. mu.Lock() return 42 }() mu.Unlock() c <- true }() mu.Lock() x = 42 mu.Unlock() <-c } func TestRaceHeapParam(t *testing.T) { done := make(chan bool) x := func() (x int) { go func() { x = 42 done <- true }() return }() _ = x <-done } func TestNoRaceEmptyStruct(t *testing.T) { type Empty struct{} type X struct { y int64 Empty } type Y struct { x X y int64 } c := make(chan X) var y Y go func() { x := y.x c <- x }() y.y = 42 <-c } func TestRaceNestedStruct(t *testing.T) { type X struct { x, y int } type Y struct { x X } c := make(chan Y) var y Y go func() { c <- y }() y.x.y = 42 <-c } func TestRaceIssue5567(t *testing.T) { testRaceRead(t, false) } func TestRaceIssue51618(t *testing.T) { testRaceRead(t, true) } func testRaceRead(t *testing.T, pread bool) { defer runtime.GOMAXPROCS(runtime.GOMAXPROCS(4)) in := make(chan []byte) res := make(chan error) go func() { var err error defer func() { close(in) res <- err }() path := "mop_test.go" f, err := os.Open(path) if err != nil { return } defer f.Close() var n, total int b := make([]byte, 17) // the race is on b buffer for err == nil { if pread { n, err = f.ReadAt(b, int64(total)) } else { n, err = f.Read(b) } total += n if n > 0 { in <- b[:n] } } if err == io.EOF { err = nil } }() h := crc32.New(crc32.MakeTable(0x12345678)) for b := range in { h.Write(b) } _ = h.Sum(nil) err := <-res if err != nil { t.Fatal(err) } } func TestRaceIssue5654(t *testing.T) { text := `Friends, Romans, countrymen, lend me your ears; I come to bury Caesar, not to praise him. The evil that men do lives after them; The good is oft interred with their bones; So let it be with Caesar. The noble Brutus Hath told you Caesar was ambitious: If it were so, it was a grievous fault, And grievously hath Caesar answer'd it. Here, under leave of Brutus and the rest - For Brutus is an honourable man; So are they all, all honourable men - Come I to speak in Caesar's funeral. He was my friend, faithful and just to me: But Brutus says he was ambitious; And Brutus is an honourable man.` data := bytes.NewBufferString(text) in := make(chan []byte) go func() { buf := make([]byte, 16) var n int var err error for ; err == nil; n, err = data.Read(buf) { in <- buf[:n] } close(in) }() res := "" for s := range in { res += string(s) } _ = res } type Base int func (b *Base) Foo() int { return 42 } func (b Base) Bar() int { return int(b) } func TestNoRaceMethodThunk(t *testing.T) { type Derived struct { pad int Base } var d Derived done := make(chan bool) go func() { _ = d.Foo() done <- true }() d = Derived{} <-done } func TestRaceMethodThunk(t *testing.T) { type Derived struct { pad int *Base } var d Derived done := make(chan bool) go func() { _ = d.Foo() done <- true }() d = Derived{} <-done } func TestRaceMethodThunk2(t *testing.T) { type Derived struct { pad int Base } var d Derived done := make(chan bool) go func() { _ = d.Bar() done <- true }() d = Derived{} <-done } func TestRaceMethodThunk3(t *testing.T) { type Derived struct { pad int *Base } var d Derived d.Base = new(Base) done := make(chan bool) go func() { _ = d.Bar() done <- true }() d.Base = new(Base) <-done } func TestRaceMethodThunk4(t *testing.T) { type Derived struct { pad int *Base } var d Derived d.Base = new(Base) done := make(chan bool) go func() { _ = d.Bar() done <- true }() *(*int)(d.Base) = 42 <-done } func TestNoRaceTinyAlloc(t *testing.T) { const P = 4 const N = 1e6 var tinySink *byte _ = tinySink done := make(chan bool) for p := 0; p < P; p++ { go func() { for i := 0; i < N; i++ { var b byte if b != 0 { tinySink = &b // make it heap allocated } b = 42 } done <- true }() } for p := 0; p < P; p++ { <-done } } func TestNoRaceIssue60934(t *testing.T) { // Test that runtime.RaceDisable state doesn't accidentally get applied to // new goroutines. // Create several goroutines that end after calling runtime.RaceDisable. var wg sync.WaitGroup ready := make(chan struct{}) wg.Add(32) for i := 0; i < 32; i++ { go func() { <-ready // ensure we have multiple goroutines running at the same time runtime.RaceDisable() wg.Done() }() } close(ready) wg.Wait() // Make sure race detector still works. If the runtime.RaceDisable state // leaks, the happens-before edges here will be ignored and a race on x will // be reported. var x int ch := make(chan struct{}, 0) wg.Add(2) go func() { x = 1 ch <- struct{}{} wg.Done() }() go func() { <-ch _ = x wg.Done() }() wg.Wait() }