// Copyright 2023 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 iter_test import ( "fmt" . "iter" "runtime" "testing" ) func count(n int) Seq[int] { return func(yield func(int) bool) { for i := range n { if !yield(i) { break } } } } func squares(n int) Seq2[int, int64] { return func(yield func(int, int64) bool) { for i := range n { if !yield(i, int64(i)*int64(i)) { break } } } } func TestPull(t *testing.T) { for end := 0; end <= 3; end++ { t.Run(fmt.Sprint(end), func(t *testing.T) { ng := stableNumGoroutine() wantNG := func(want int) { if xg := runtime.NumGoroutine() - ng; xg != want { t.Helper() t.Errorf("have %d extra goroutines, want %d", xg, want) } } wantNG(0) next, stop := Pull(count(3)) wantNG(1) for i := range end { v, ok := next() if v != i || ok != true { t.Fatalf("next() = %d, %v, want %d, %v", v, ok, i, true) } wantNG(1) } wantNG(1) if end < 3 { stop() wantNG(0) } for range 2 { v, ok := next() if v != 0 || ok != false { t.Fatalf("next() = %d, %v, want %d, %v", v, ok, 0, false) } wantNG(0) } wantNG(0) stop() stop() stop() wantNG(0) }) } } func TestPull2(t *testing.T) { for end := 0; end <= 3; end++ { t.Run(fmt.Sprint(end), func(t *testing.T) { ng := stableNumGoroutine() wantNG := func(want int) { if xg := runtime.NumGoroutine() - ng; xg != want { t.Helper() t.Errorf("have %d extra goroutines, want %d", xg, want) } } wantNG(0) next, stop := Pull2(squares(3)) wantNG(1) for i := range end { k, v, ok := next() if k != i || v != int64(i*i) || ok != true { t.Fatalf("next() = %d, %d, %v, want %d, %d, %v", k, v, ok, i, i*i, true) } wantNG(1) } wantNG(1) if end < 3 { stop() wantNG(0) } for range 2 { k, v, ok := next() if v != 0 || ok != false { t.Fatalf("next() = %d, %d, %v, want %d, %d, %v", k, v, ok, 0, 0, false) } wantNG(0) } wantNG(0) stop() stop() stop() wantNG(0) }) } } // stableNumGoroutine is like NumGoroutine but tries to ensure stability of // the value by letting any exiting goroutines finish exiting. func stableNumGoroutine() int { // The idea behind stablizing the value of NumGoroutine is to // see the same value enough times in a row in between calls to // runtime.Gosched. With GOMAXPROCS=1, we're trying to make sure // that other goroutines run, so that they reach a stable point. // It's not guaranteed, because it is still possible for a goroutine // to Gosched back into itself, so we require NumGoroutine to be // the same 100 times in a row. This should be more than enough to // ensure all goroutines get a chance to run to completion (or to // some block point) for a small group of test goroutines. defer runtime.GOMAXPROCS(runtime.GOMAXPROCS(1)) c := 0 ng := runtime.NumGoroutine() for i := 0; i < 1000; i++ { nng := runtime.NumGoroutine() if nng == ng { c++ } else { c = 0 ng = nng } if c >= 100 { // The same value 100 times in a row is good enough. return ng } runtime.Gosched() } panic("failed to stabilize NumGoroutine after 1000 iterations") } func TestPullDoubleNext(t *testing.T) { next, _ := Pull(doDoubleNext()) nextSlot = next next() if nextSlot != nil { t.Fatal("double next did not fail") } } var nextSlot func() (int, bool) func doDoubleNext() Seq[int] { return func(_ func(int) bool) { defer func() { if recover() != nil { nextSlot = nil } }() nextSlot() } } func TestPullDoubleNext2(t *testing.T) { next, _ := Pull2(doDoubleNext2()) nextSlot2 = next next() if nextSlot2 != nil { t.Fatal("double next did not fail") } } var nextSlot2 func() (int, int, bool) func doDoubleNext2() Seq2[int, int] { return func(_ func(int, int) bool) { defer func() { if recover() != nil { nextSlot2 = nil } }() nextSlot2() } } func TestPullDoubleYield(t *testing.T) { next, stop := Pull(storeYield()) next() if yieldSlot == nil { t.Fatal("yield failed") } defer func() { if recover() != nil { yieldSlot = nil } stop() }() yieldSlot(5) if yieldSlot != nil { t.Fatal("double yield did not fail") } } func storeYield() Seq[int] { return func(yield func(int) bool) { yieldSlot = yield if !yield(5) { return } } } var yieldSlot func(int) bool func TestPullDoubleYield2(t *testing.T) { next, stop := Pull2(storeYield2()) next() if yieldSlot2 == nil { t.Fatal("yield failed") } defer func() { if recover() != nil { yieldSlot2 = nil } stop() }() yieldSlot2(23, 77) if yieldSlot2 != nil { t.Fatal("double yield did not fail") } } func storeYield2() Seq2[int, int] { return func(yield func(int, int) bool) { yieldSlot2 = yield if !yield(23, 77) { return } } } var yieldSlot2 func(int, int) bool func TestPullPanic(t *testing.T) { t.Run("next", func(t *testing.T) { next, stop := Pull(panicSeq()) if !panicsWith("boom", func() { next() }) { t.Fatal("failed to propagate panic on first next") } // Make sure we don't panic again if we try to call next or stop. if _, ok := next(); ok { t.Fatal("next returned true after iterator panicked") } // Calling stop again should be a no-op. stop() }) t.Run("stop", func(t *testing.T) { next, stop := Pull(panicCleanupSeq()) x, ok := next() if !ok || x != 55 { t.Fatalf("expected (55, true) from next, got (%d, %t)", x, ok) } if !panicsWith("boom", func() { stop() }) { t.Fatal("failed to propagate panic on stop") } // Make sure we don't panic again if we try to call next or stop. if _, ok := next(); ok { t.Fatal("next returned true after iterator panicked") } // Calling stop again should be a no-op. stop() }) } func panicSeq() Seq[int] { return func(yield func(int) bool) { panic("boom") } } func panicCleanupSeq() Seq[int] { return func(yield func(int) bool) { for { if !yield(55) { panic("boom") } } } } func TestPull2Panic(t *testing.T) { t.Run("next", func(t *testing.T) { next, stop := Pull2(panicSeq2()) if !panicsWith("boom", func() { next() }) { t.Fatal("failed to propagate panic on first next") } // Make sure we don't panic again if we try to call next or stop. if _, _, ok := next(); ok { t.Fatal("next returned true after iterator panicked") } // Calling stop again should be a no-op. stop() }) t.Run("stop", func(t *testing.T) { next, stop := Pull2(panicCleanupSeq2()) x, y, ok := next() if !ok || x != 55 || y != 100 { t.Fatalf("expected (55, 100, true) from next, got (%d, %d, %t)", x, y, ok) } if !panicsWith("boom", func() { stop() }) { t.Fatal("failed to propagate panic on stop") } // Make sure we don't panic again if we try to call next or stop. if _, _, ok := next(); ok { t.Fatal("next returned true after iterator panicked") } // Calling stop again should be a no-op. stop() }) } func panicSeq2() Seq2[int, int] { return func(yield func(int, int) bool) { panic("boom") } } func panicCleanupSeq2() Seq2[int, int] { return func(yield func(int, int) bool) { for { if !yield(55, 100) { panic("boom") } } } } func panicsWith(v any, f func()) (panicked bool) { defer func() { if r := recover(); r != nil { if r != v { panic(r) } panicked = true } }() f() return } func TestPullGoexit(t *testing.T) { t.Run("next", func(t *testing.T) { var next func() (int, bool) var stop func() if !goexits(t, func() { next, stop = Pull(goexitSeq()) next() }) { t.Fatal("failed to Goexit from next") } if x, ok := next(); x != 0 || ok { t.Fatal("iterator returned valid value after iterator Goexited") } stop() }) t.Run("stop", func(t *testing.T) { next, stop := Pull(goexitCleanupSeq()) x, ok := next() if !ok || x != 55 { t.Fatalf("expected (55, true) from next, got (%d, %t)", x, ok) } if !goexits(t, func() { stop() }) { t.Fatal("failed to Goexit from stop") } // Make sure we don't panic again if we try to call next or stop. if x, ok := next(); x != 0 || ok { t.Fatal("next returned true or non-zero value after iterator Goexited") } // Calling stop again should be a no-op. stop() }) } func goexitSeq() Seq[int] { return func(yield func(int) bool) { runtime.Goexit() } } func goexitCleanupSeq() Seq[int] { return func(yield func(int) bool) { for { if !yield(55) { runtime.Goexit() } } } } func TestPull2Goexit(t *testing.T) { t.Run("next", func(t *testing.T) { var next func() (int, int, bool) var stop func() if !goexits(t, func() { next, stop = Pull2(goexitSeq2()) next() }) { t.Fatal("failed to Goexit from next") } if x, y, ok := next(); x != 0 || y != 0 || ok { t.Fatal("iterator returned valid value after iterator Goexited") } stop() }) t.Run("stop", func(t *testing.T) { next, stop := Pull2(goexitCleanupSeq2()) x, y, ok := next() if !ok || x != 55 || y != 100 { t.Fatalf("expected (55, 100, true) from next, got (%d, %d, %t)", x, y, ok) } if !goexits(t, func() { stop() }) { t.Fatal("failed to Goexit from stop") } // Make sure we don't panic again if we try to call next or stop. if x, y, ok := next(); x != 0 || y != 0 || ok { t.Fatal("next returned true or non-zero after iterator Goexited") } // Calling stop again should be a no-op. stop() }) } func goexitSeq2() Seq2[int, int] { return func(yield func(int, int) bool) { runtime.Goexit() } } func goexitCleanupSeq2() Seq2[int, int] { return func(yield func(int, int) bool) { for { if !yield(55, 100) { runtime.Goexit() } } } } func goexits(t *testing.T, f func()) bool { t.Helper() exit := make(chan bool) go func() { cleanExit := false defer func() { exit <- recover() == nil && !cleanExit }() f() cleanExit = true }() return <-exit } func TestPullImmediateStop(t *testing.T) { next, stop := Pull(panicSeq()) stop() // Make sure we don't panic if we try to call next or stop. if _, ok := next(); ok { t.Fatal("next returned true after iterator was stopped") } } func TestPull2ImmediateStop(t *testing.T) { next, stop := Pull2(panicSeq2()) stop() // Make sure we don't panic if we try to call next or stop. if _, _, ok := next(); ok { t.Fatal("next returned true after iterator was stopped") } }