// MIT License // Copyright (c) 2018 Andy Pan // Permission is hereby granted, free of charge, to any person obtaining a copy // of this software and associated documentation files (the "Software"), to deal // in the Software without restriction, including without limitation the rights // to use, copy, modify, merge, publish, distribute, sublicense, and/or sell // copies of the Software, and to permit persons to whom the Software is // furnished to do so, subject to the following conditions: // // The above copyright notice and this permission notice shall be included in all // copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, // OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE // SOFTWARE. package ants import ( "log" "os" "runtime" "sync" "sync/atomic" "testing" "time" "github.com/stretchr/testify/assert" ) const ( _ = 1 << (10 * iota) KiB // 1024 MiB // 1048576 //GiB // 1073741824 //TiB // 1099511627776 (超过了int32的范围) //PiB // 1125899906842624 //EiB // 1152921504606846976 //ZiB // 1180591620717411303424 (超过了int64的范围) //YiB // 1208925819614629174706176 ) const ( Param = 100 AntsSize = 1000 TestSize = 10000 n = 100000 ) var curMem uint64 // TestAntsPoolWaitToGetWorker is used to test waiting to get worker. func TestAntsPoolWaitToGetWorker(t *testing.T) { var wg sync.WaitGroup p, _ := NewPool(AntsSize) defer p.Release() for i := 0; i < n; i++ { wg.Add(1) _ = p.Submit(func() { demoPoolFunc(Param) wg.Done() }) } wg.Wait() t.Logf("pool, running workers number:%d", p.Running()) mem := runtime.MemStats{} runtime.ReadMemStats(&mem) curMem = mem.TotalAlloc/MiB - curMem t.Logf("memory usage:%d MB", curMem) } func TestAntsPoolWaitToGetWorkerPreMalloc(t *testing.T) { var wg sync.WaitGroup p, _ := NewPool(AntsSize, WithPreAlloc(true)) defer p.Release() for i := 0; i < n; i++ { wg.Add(1) _ = p.Submit(func() { demoPoolFunc(Param) wg.Done() }) } wg.Wait() t.Logf("pool, running workers number:%d", p.Running()) mem := runtime.MemStats{} runtime.ReadMemStats(&mem) curMem = mem.TotalAlloc/MiB - curMem t.Logf("memory usage:%d MB", curMem) } // TestAntsPoolWithFuncWaitToGetWorker is used to test waiting to get worker. func TestAntsPoolWithFuncWaitToGetWorker(t *testing.T) { var wg sync.WaitGroup p, _ := NewPoolWithFunc(AntsSize, func(i interface{}) { demoPoolFunc(i) wg.Done() }) defer p.Release() for i := 0; i < n; i++ { wg.Add(1) _ = p.Invoke(Param) } wg.Wait() t.Logf("pool with func, running workers number:%d", p.Running()) mem := runtime.MemStats{} runtime.ReadMemStats(&mem) curMem = mem.TotalAlloc/MiB - curMem t.Logf("memory usage:%d MB", curMem) } func TestAntsPoolWithFuncWaitToGetWorkerPreMalloc(t *testing.T) { var wg sync.WaitGroup p, _ := NewPoolWithFunc(AntsSize, func(i interface{}) { demoPoolFunc(i) wg.Done() }, WithPreAlloc(true)) defer p.Release() for i := 0; i < n; i++ { wg.Add(1) _ = p.Invoke(Param) } wg.Wait() t.Logf("pool with func, running workers number:%d", p.Running()) mem := runtime.MemStats{} runtime.ReadMemStats(&mem) curMem = mem.TotalAlloc/MiB - curMem t.Logf("memory usage:%d MB", curMem) } // TestAntsPoolGetWorkerFromCache is used to test getting worker from sync.Pool. func TestAntsPoolGetWorkerFromCache(t *testing.T) { p, _ := NewPool(TestSize) defer p.Release() for i := 0; i < AntsSize; i++ { _ = p.Submit(demoFunc) } time.Sleep(2 * DefaultCleanIntervalTime) _ = p.Submit(demoFunc) t.Logf("pool, running workers number:%d", p.Running()) mem := runtime.MemStats{} runtime.ReadMemStats(&mem) curMem = mem.TotalAlloc/MiB - curMem t.Logf("memory usage:%d MB", curMem) } // TestAntsPoolWithFuncGetWorkerFromCache is used to test getting worker from sync.Pool. func TestAntsPoolWithFuncGetWorkerFromCache(t *testing.T) { dur := 10 p, _ := NewPoolWithFunc(TestSize, demoPoolFunc) defer p.Release() for i := 0; i < AntsSize; i++ { _ = p.Invoke(dur) } time.Sleep(2 * DefaultCleanIntervalTime) _ = p.Invoke(dur) t.Logf("pool with func, running workers number:%d", p.Running()) mem := runtime.MemStats{} runtime.ReadMemStats(&mem) curMem = mem.TotalAlloc/MiB - curMem t.Logf("memory usage:%d MB", curMem) } func TestAntsPoolWithFuncGetWorkerFromCachePreMalloc(t *testing.T) { dur := 10 p, _ := NewPoolWithFunc(TestSize, demoPoolFunc, WithPreAlloc(true)) defer p.Release() for i := 0; i < AntsSize; i++ { _ = p.Invoke(dur) } time.Sleep(2 * DefaultCleanIntervalTime) _ = p.Invoke(dur) t.Logf("pool with func, running workers number:%d", p.Running()) mem := runtime.MemStats{} runtime.ReadMemStats(&mem) curMem = mem.TotalAlloc/MiB - curMem t.Logf("memory usage:%d MB", curMem) } //------------------------------------------------------------------------------------------- // Contrast between goroutines without a pool and goroutines with ants pool. //------------------------------------------------------------------------------------------- func TestNoPool(t *testing.T) { var wg sync.WaitGroup for i := 0; i < n; i++ { wg.Add(1) go func() { demoFunc() wg.Done() }() } wg.Wait() mem := runtime.MemStats{} runtime.ReadMemStats(&mem) curMem = mem.TotalAlloc/MiB - curMem t.Logf("memory usage:%d MB", curMem) } func TestAntsPool(t *testing.T) { defer Release() var wg sync.WaitGroup for i := 0; i < n; i++ { wg.Add(1) _ = Submit(func() { demoFunc() wg.Done() }) } wg.Wait() t.Logf("pool, capacity:%d", Cap()) t.Logf("pool, running workers number:%d", Running()) t.Logf("pool, free workers number:%d", Free()) mem := runtime.MemStats{} runtime.ReadMemStats(&mem) curMem = mem.TotalAlloc/MiB - curMem t.Logf("memory usage:%d MB", curMem) } //------------------------------------------------------------------------------------------- //------------------------------------------------------------------------------------------- func TestPanicHandler(t *testing.T) { var panicCounter int64 var wg sync.WaitGroup p0, err := NewPool(10, WithPanicHandler(func(p interface{}) { defer wg.Done() atomic.AddInt64(&panicCounter, 1) t.Logf("catch panic with PanicHandler: %v", p) })) assert.NoErrorf(t, err, "create new pool failed: %v", err) defer p0.Release() wg.Add(1) _ = p0.Submit(func() { panic("Oops!") }) wg.Wait() c := atomic.LoadInt64(&panicCounter) assert.EqualValuesf(t, 1, c, "panic handler didn't work, panicCounter: %d", c) assert.EqualValues(t, 0, p0.Running(), "pool should be empty after panic") p1, err := NewPoolWithFunc(10, func(p interface{}) { panic(p) }, WithPanicHandler(func(p interface{}) { defer wg.Done() atomic.AddInt64(&panicCounter, 1) })) assert.NoErrorf(t, err, "create new pool with func failed: %v", err) defer p1.Release() wg.Add(1) _ = p1.Invoke("Oops!") wg.Wait() c = atomic.LoadInt64(&panicCounter) assert.EqualValuesf(t, 2, c, "panic handler didn't work, panicCounter: %d", c) assert.EqualValues(t, 0, p1.Running(), "pool should be empty after panic") } func TestPanicHandlerPreMalloc(t *testing.T) { var panicCounter int64 var wg sync.WaitGroup p0, err := NewPool(10, WithPreAlloc(true), WithPanicHandler(func(p interface{}) { defer wg.Done() atomic.AddInt64(&panicCounter, 1) t.Logf("catch panic with PanicHandler: %v", p) })) assert.NoErrorf(t, err, "create new pool failed: %v", err) defer p0.Release() wg.Add(1) _ = p0.Submit(func() { panic("Oops!") }) wg.Wait() c := atomic.LoadInt64(&panicCounter) assert.EqualValuesf(t, 1, c, "panic handler didn't work, panicCounter: %d", c) assert.EqualValues(t, 0, p0.Running(), "pool should be empty after panic") p1, err := NewPoolWithFunc(10, func(p interface{}) { panic(p) }, WithPanicHandler(func(p interface{}) { defer wg.Done() atomic.AddInt64(&panicCounter, 1) })) assert.NoErrorf(t, err, "create new pool with func failed: %v", err) defer p1.Release() wg.Add(1) _ = p1.Invoke("Oops!") wg.Wait() c = atomic.LoadInt64(&panicCounter) assert.EqualValuesf(t, 2, c, "panic handler didn't work, panicCounter: %d", c) assert.EqualValues(t, 0, p1.Running(), "pool should be empty after panic") } func TestPoolPanicWithoutHandler(t *testing.T) { p0, err := NewPool(10) assert.NoErrorf(t, err, "create new pool failed: %v", err) defer p0.Release() _ = p0.Submit(func() { panic("Oops!") }) p1, err := NewPoolWithFunc(10, func(p interface{}) { panic(p) }) assert.NoErrorf(t, err, "create new pool with func failed: %v", err) defer p1.Release() _ = p1.Invoke("Oops!") } func TestPoolPanicWithoutHandlerPreMalloc(t *testing.T) { p0, err := NewPool(10, WithPreAlloc(true)) assert.NoErrorf(t, err, "create new pool failed: %v", err) defer p0.Release() _ = p0.Submit(func() { panic("Oops!") }) p1, err := NewPoolWithFunc(10, func(p interface{}) { panic(p) }) assert.NoErrorf(t, err, "create new pool with func failed: %v", err) defer p1.Release() _ = p1.Invoke("Oops!") } func TestPurge(t *testing.T) { p, err := NewPool(10) assert.NoErrorf(t, err, "create TimingPool failed: %v", err) defer p.Release() _ = p.Submit(demoFunc) time.Sleep(3 * DefaultCleanIntervalTime) assert.EqualValues(t, 0, p.Running(), "all p should be purged") p1, err := NewPoolWithFunc(10, demoPoolFunc) assert.NoErrorf(t, err, "create TimingPoolWithFunc failed: %v", err) defer p1.Release() _ = p1.Invoke(1) time.Sleep(3 * DefaultCleanIntervalTime) assert.EqualValues(t, 0, p.Running(), "all p should be purged") } func TestPurgePreMalloc(t *testing.T) { p, err := NewPool(10, WithPreAlloc(true)) assert.NoErrorf(t, err, "create TimingPool failed: %v", err) defer p.Release() _ = p.Submit(demoFunc) time.Sleep(3 * DefaultCleanIntervalTime) assert.EqualValues(t, 0, p.Running(), "all p should be purged") p1, err := NewPoolWithFunc(10, demoPoolFunc) assert.NoErrorf(t, err, "create TimingPoolWithFunc failed: %v", err) defer p1.Release() _ = p1.Invoke(1) time.Sleep(3 * DefaultCleanIntervalTime) assert.EqualValues(t, 0, p.Running(), "all p should be purged") } func TestNonblockingSubmit(t *testing.T) { poolSize := 10 p, err := NewPool(poolSize, WithNonblocking(true)) assert.NoErrorf(t, err, "create TimingPool failed: %v", err) defer p.Release() for i := 0; i < poolSize-1; i++ { assert.NoError(t, p.Submit(longRunningFunc), "nonblocking submit when pool is not full shouldn't return error") } ch := make(chan struct{}) ch1 := make(chan struct{}) f := func() { <-ch close(ch1) } // p is full now. assert.NoError(t, p.Submit(f), "nonblocking submit when pool is not full shouldn't return error") assert.EqualError(t, p.Submit(demoFunc), ErrPoolOverload.Error(), "nonblocking submit when pool is full should get an ErrPoolOverload") // interrupt f to get an available worker close(ch) <-ch1 assert.NoError(t, p.Submit(demoFunc), "nonblocking submit when pool is not full shouldn't return error") } func TestMaxBlockingSubmit(t *testing.T) { poolSize := 10 p, err := NewPool(poolSize, WithMaxBlockingTasks(1)) assert.NoErrorf(t, err, "create TimingPool failed: %v", err) defer p.Release() for i := 0; i < poolSize-1; i++ { assert.NoError(t, p.Submit(longRunningFunc), "submit when pool is not full shouldn't return error") } ch := make(chan struct{}) f := func() { <-ch } // p is full now. assert.NoError(t, p.Submit(f), "submit when pool is not full shouldn't return error") var wg sync.WaitGroup wg.Add(1) errCh := make(chan error, 1) go func() { // should be blocked. blocking num == 1 if err := p.Submit(demoFunc); err != nil { errCh <- err } wg.Done() }() time.Sleep(1 * time.Second) // already reached max blocking limit assert.EqualError(t, p.Submit(demoFunc), ErrPoolOverload.Error(), "blocking submit when pool reach max blocking submit should return ErrPoolOverload") // interrupt f to make blocking submit successful. close(ch) wg.Wait() select { case <-errCh: t.Fatalf("blocking submit when pool is full should not return error") default: } } func TestNonblockingSubmitWithFunc(t *testing.T) { poolSize := 10 ch1 := make(chan struct{}) p, err := NewPoolWithFunc(poolSize, func(i interface{}) { longRunningPoolFunc(i) close(ch1) }, WithNonblocking(true)) assert.NoError(t, err, "create TimingPool failed: %v", err) defer p.Release() for i := 0; i < poolSize-1; i++ { assert.NoError(t, p.Invoke(nil), "nonblocking submit when pool is not full shouldn't return error") } ch := make(chan struct{}) // p is full now. assert.NoError(t, p.Invoke(ch), "nonblocking submit when pool is not full shouldn't return error") assert.EqualError(t, p.Invoke(nil), ErrPoolOverload.Error(), "nonblocking submit when pool is full should get an ErrPoolOverload") // interrupt f to get an available worker close(ch) <-ch1 assert.NoError(t, p.Invoke(nil), "nonblocking submit when pool is not full shouldn't return error") } func TestMaxBlockingSubmitWithFunc(t *testing.T) { poolSize := 10 p, err := NewPoolWithFunc(poolSize, longRunningPoolFunc, WithMaxBlockingTasks(1)) assert.NoError(t, err, "create TimingPool failed: %v", err) defer p.Release() for i := 0; i < poolSize-1; i++ { assert.NoError(t, p.Invoke(Param), "submit when pool is not full shouldn't return error") } ch := make(chan struct{}) // p is full now. assert.NoError(t, p.Invoke(ch), "submit when pool is not full shouldn't return error") var wg sync.WaitGroup wg.Add(1) errCh := make(chan error, 1) go func() { // should be blocked. blocking num == 1 if err := p.Invoke(Param); err != nil { errCh <- err } wg.Done() }() time.Sleep(1 * time.Second) // already reached max blocking limit assert.EqualErrorf(t, p.Invoke(Param), ErrPoolOverload.Error(), "blocking submit when pool reach max blocking submit should return ErrPoolOverload: %v", err) // interrupt one func to make blocking submit successful. close(ch) wg.Wait() select { case <-errCh: t.Fatalf("blocking submit when pool is full should not return error") default: } } func TestRebootDefaultPool(t *testing.T) { defer Release() Reboot() var wg sync.WaitGroup wg.Add(1) _ = Submit(func() { demoFunc() wg.Done() }) wg.Wait() Release() assert.EqualError(t, Submit(nil), ErrPoolClosed.Error(), "pool should be closed") Reboot() wg.Add(1) assert.NoError(t, Submit(func() { wg.Done() }), "pool should be rebooted") wg.Wait() } func TestRebootNewPool(t *testing.T) { var wg sync.WaitGroup p, err := NewPool(10) assert.NoErrorf(t, err, "create Pool failed: %v", err) defer p.Release() wg.Add(1) _ = p.Submit(func() { demoFunc() wg.Done() }) wg.Wait() p.Release() assert.EqualError(t, p.Submit(nil), ErrPoolClosed.Error(), "pool should be closed") p.Reboot() wg.Add(1) assert.NoError(t, p.Submit(func() { wg.Done() }), "pool should be rebooted") wg.Wait() p1, err := NewPoolWithFunc(10, func(i interface{}) { demoPoolFunc(i) wg.Done() }) assert.NoErrorf(t, err, "create TimingPoolWithFunc failed: %v", err) defer p1.Release() wg.Add(1) _ = p1.Invoke(1) wg.Wait() p1.Release() assert.EqualError(t, p1.Invoke(nil), ErrPoolClosed.Error(), "pool should be closed") p1.Reboot() wg.Add(1) assert.NoError(t, p1.Invoke(1), "pool should be rebooted") wg.Wait() } func TestInfinitePool(t *testing.T) { c := make(chan struct{}) p, _ := NewPool(-1) _ = p.Submit(func() { _ = p.Submit(func() { <-c }) }) c <- struct{}{} if n := p.Running(); n != 2 { t.Errorf("expect 2 workers running, but got %d", n) } } func TestRestCodeCoverage(t *testing.T) { _, err := NewPool(-1, WithExpiryDuration(-1)) t.Log(err) _, err = NewPool(1, WithExpiryDuration(-1)) t.Log(err) _, err = NewPoolWithFunc(-1, demoPoolFunc, WithExpiryDuration(-1)) t.Log(err) _, err = NewPoolWithFunc(1, demoPoolFunc, WithExpiryDuration(-1)) t.Log(err) options := Options{} options.ExpiryDuration = time.Duration(10) * time.Second options.Nonblocking = true options.PreAlloc = true poolOpts, _ := NewPool(1, WithOptions(options)) t.Logf("Pool with options, capacity: %d", poolOpts.Cap()) p0, _ := NewPool(TestSize, WithLogger(log.New(os.Stderr, "", log.LstdFlags))) defer func() { _ = p0.Submit(demoFunc) }() defer p0.Release() for i := 0; i < n; i++ { _ = p0.Submit(demoFunc) } t.Logf("pool, capacity:%d", p0.Cap()) t.Logf("pool, running workers number:%d", p0.Running()) t.Logf("pool, free workers number:%d", p0.Free()) p0.Tune(TestSize) p0.Tune(TestSize / 10) t.Logf("pool, after tuning capacity, capacity:%d, running:%d", p0.Cap(), p0.Running()) pprem, _ := NewPool(TestSize, WithPreAlloc(true)) defer func() { _ = pprem.Submit(demoFunc) }() defer pprem.Release() for i := 0; i < n; i++ { _ = pprem.Submit(demoFunc) } t.Logf("pre-malloc pool, capacity:%d", pprem.Cap()) t.Logf("pre-malloc pool, running workers number:%d", pprem.Running()) t.Logf("pre-malloc pool, free workers number:%d", pprem.Free()) pprem.Tune(TestSize) pprem.Tune(TestSize / 10) t.Logf("pre-malloc pool, after tuning capacity, capacity:%d, running:%d", pprem.Cap(), pprem.Running()) p, _ := NewPoolWithFunc(TestSize, demoPoolFunc) defer func() { _ = p.Invoke(Param) }() defer p.Release() for i := 0; i < n; i++ { _ = p.Invoke(Param) } time.Sleep(DefaultCleanIntervalTime) t.Logf("pool with func, capacity:%d", p.Cap()) t.Logf("pool with func, running workers number:%d", p.Running()) t.Logf("pool with func, free workers number:%d", p.Free()) p.Tune(TestSize) p.Tune(TestSize / 10) t.Logf("pool with func, after tuning capacity, capacity:%d, running:%d", p.Cap(), p.Running()) ppremWithFunc, _ := NewPoolWithFunc(TestSize, demoPoolFunc, WithPreAlloc(true)) defer func() { _ = ppremWithFunc.Invoke(Param) }() defer ppremWithFunc.Release() for i := 0; i < n; i++ { _ = ppremWithFunc.Invoke(Param) } time.Sleep(DefaultCleanIntervalTime) t.Logf("pre-malloc pool with func, capacity:%d", ppremWithFunc.Cap()) t.Logf("pre-malloc pool with func, running workers number:%d", ppremWithFunc.Running()) t.Logf("pre-malloc pool with func, free workers number:%d", ppremWithFunc.Free()) ppremWithFunc.Tune(TestSize) ppremWithFunc.Tune(TestSize / 10) t.Logf("pre-malloc pool with func, after tuning capacity, capacity:%d, running:%d", ppremWithFunc.Cap(), ppremWithFunc.Running()) }