all: fix a bunch of inconsequential goroutine leaks (#20667)

The leaks were mostly in unit tests, and could all be resolved by
adding suitably-sized channel buffers or by restructuring the test
to not send on a channel after an error has occurred.

There is an unavoidable goroutine leak in Console.Interactive: when
we receive a signal, the line reader cannot be unblocked and will get
stuck. This leak is now documented and I've tried to make it slightly 
less bad by adding a one-element buffer to the output channels of
the line-reading loop. Should the reader eventually awake from its
blocked state (i.e. when stdin is closed), at least it won't get stuck
trying to send to the interpreter loop which has quit long ago.

Co-authored-by: Felix Lange <fjl@twurst.com>
This commit is contained in:
Boqin Qin 2020-04-04 02:07:22 +08:00 committed by GitHub
parent 98eab2dbe7
commit be6078ad83
No known key found for this signature in database
GPG Key ID: 4AEE18F83AFDEB23
6 changed files with 124 additions and 107 deletions

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@ -74,17 +74,22 @@ func TestLazyQueue(t *testing.T) {
q.Push(&items[i]) q.Push(&items[i])
} }
var lock sync.Mutex var (
stopCh := make(chan chan struct{}) lock sync.Mutex
wg sync.WaitGroup
stopCh = make(chan chan struct{})
)
defer wg.Wait()
wg.Add(1)
go func() { go func() {
defer wg.Done()
for { for {
select { select {
case <-clock.After(testQueueRefresh): case <-clock.After(testQueueRefresh):
lock.Lock() lock.Lock()
q.Refresh() q.Refresh()
lock.Unlock() lock.Unlock()
case stop := <-stopCh: case <-stopCh:
close(stop)
return return
} }
} }
@ -104,6 +109,8 @@ func TestLazyQueue(t *testing.T) {
if rand.Intn(100) == 0 { if rand.Intn(100) == 0 {
p := q.PopItem().(*lazyItem) p := q.PopItem().(*lazyItem)
if p.p != maxPri { if p.p != maxPri {
lock.Unlock()
close(stopCh)
t.Fatalf("incorrect item (best known priority %d, popped %d)", maxPri, p.p) t.Fatalf("incorrect item (best known priority %d, popped %d)", maxPri, p.p)
} }
q.Push(p) q.Push(p)
@ -113,7 +120,5 @@ func TestLazyQueue(t *testing.T) {
clock.WaitForTimers(1) clock.WaitForTimers(1)
} }
stop := make(chan struct{}) close(stopCh)
stopCh <- stop
<-stop
} }

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@ -340,62 +340,61 @@ func (c *Console) Evaluate(statement string) {
// the configured user prompter. // the configured user prompter.
func (c *Console) Interactive() { func (c *Console) Interactive() {
var ( var (
prompt = c.prompt // Current prompt line (used for multi-line inputs) prompt = c.prompt // the current prompt line (used for multi-line inputs)
indents = 0 // Current number of input indents (used for multi-line inputs) indents = 0 // the current number of input indents (used for multi-line inputs)
input = "" // Current user input input = "" // the current user input
scheduler = make(chan string) // Channel to send the next prompt on and receive the input inputLine = make(chan string, 1) // receives user input
inputErr = make(chan error, 1) // receives liner errors
requestLine = make(chan string) // requests a line of input
interrupt = make(chan os.Signal, 1)
) )
// Start a goroutine to listen for prompt requests and send back inputs
go func() {
for {
// Read the next user input
line, err := c.prompter.PromptInput(<-scheduler)
if err != nil {
// In case of an error, either clear the prompt or fail
if err == liner.ErrPromptAborted { // ctrl-C
prompt, indents, input = c.prompt, 0, ""
scheduler <- ""
continue
}
close(scheduler)
return
}
// User input retrieved, send for interpretation and loop
scheduler <- line
}
}()
// Monitor Ctrl-C too in case the input is empty and we need to bail
abort := make(chan os.Signal, 1)
signal.Notify(abort, syscall.SIGINT, syscall.SIGTERM)
// Start sending prompts to the user and reading back inputs // Monitor Ctrl-C. While liner does turn on the relevant terminal mode bits to avoid
// the signal, a signal can still be received for unsupported terminals. Unfortunately
// there is no way to cancel the line reader when this happens. The readLines
// goroutine will be leaked in this case.
signal.Notify(interrupt, syscall.SIGINT, syscall.SIGTERM)
defer signal.Stop(interrupt)
// The line reader runs in a separate goroutine.
go c.readLines(inputLine, inputErr, requestLine)
defer close(requestLine)
for { for {
// Send the next prompt, triggering an input read and process the result // Send the next prompt, triggering an input read.
scheduler <- prompt requestLine <- prompt
select { select {
case <-abort: case <-interrupt:
// User forcefully quite the console
fmt.Fprintln(c.printer, "caught interrupt, exiting") fmt.Fprintln(c.printer, "caught interrupt, exiting")
return return
case line, ok := <-scheduler: case err := <-inputErr:
// User input was returned by the prompter, handle special cases if err == liner.ErrPromptAborted && indents > 0 {
if !ok || (indents <= 0 && exit.MatchString(line)) { // When prompting for multi-line input, the first Ctrl-C resets
// the multi-line state.
prompt, indents, input = c.prompt, 0, ""
continue
}
return
case line := <-inputLine:
// User input was returned by the prompter, handle special cases.
if indents <= 0 && exit.MatchString(line) {
return return
} }
if onlyWhitespace.MatchString(line) { if onlyWhitespace.MatchString(line) {
continue continue
} }
// Append the line to the input and check for multi-line interpretation // Append the line to the input and check for multi-line interpretation.
input += line + "\n" input += line + "\n"
indents = countIndents(input) indents = countIndents(input)
if indents <= 0 { if indents <= 0 {
prompt = c.prompt prompt = c.prompt
} else { } else {
prompt = strings.Repeat(".", indents*3) + " " prompt = strings.Repeat(".", indents*3) + " "
} }
// If all the needed lines are present, save the command and run // If all the needed lines are present, save the command and run it.
if indents <= 0 { if indents <= 0 {
if len(input) > 0 && input[0] != ' ' && !passwordRegexp.MatchString(input) { if len(input) > 0 && input[0] != ' ' && !passwordRegexp.MatchString(input) {
if command := strings.TrimSpace(input); len(c.history) == 0 || command != c.history[len(c.history)-1] { if command := strings.TrimSpace(input); len(c.history) == 0 || command != c.history[len(c.history)-1] {
@ -412,6 +411,18 @@ func (c *Console) Interactive() {
} }
} }
// readLines runs in its own goroutine, prompting for input.
func (c *Console) readLines(input chan<- string, errc chan<- error, prompt <-chan string) {
for p := range prompt {
line, err := c.prompter.PromptInput(p)
if err != nil {
errc <- err
} else {
input <- line
}
}
}
// countIndents returns the number of identations for the given input. // countIndents returns the number of identations for the given input.
// In case of invalid input such as var a = } the result can be negative. // In case of invalid input such as var a = } the result can be negative.
func countIndents(input string) int { func countIndents(input string) int {

View File

@ -203,6 +203,7 @@ func BenchmarkPostConcurrent(b *testing.B) {
// for comparison // for comparison
func BenchmarkChanSend(b *testing.B) { func BenchmarkChanSend(b *testing.B) {
c := make(chan interface{}) c := make(chan interface{})
defer close(c)
closed := make(chan struct{}) closed := make(chan struct{})
go func() { go func() {
for range c { for range c {

View File

@ -17,7 +17,6 @@
package miner package miner
import ( import (
"fmt"
"math/big" "math/big"
"math/rand" "math/rand"
"sync/atomic" "sync/atomic"
@ -210,49 +209,37 @@ func testGenerateBlockAndImport(t *testing.T, isClique bool) {
w, b := newTestWorker(t, chainConfig, engine, db, 0) w, b := newTestWorker(t, chainConfig, engine, db, 0)
defer w.close() defer w.close()
// This test chain imports the mined blocks.
db2 := rawdb.NewMemoryDatabase() db2 := rawdb.NewMemoryDatabase()
b.genesis.MustCommit(db2) b.genesis.MustCommit(db2)
chain, _ := core.NewBlockChain(db2, nil, b.chain.Config(), engine, vm.Config{}, nil) chain, _ := core.NewBlockChain(db2, nil, b.chain.Config(), engine, vm.Config{}, nil)
defer chain.Stop() defer chain.Stop()
var ( // Ignore empty commit here for less noise.
loopErr = make(chan error)
newBlock = make(chan struct{})
subscribe = make(chan struct{})
)
listenNewBlock := func() {
sub := w.mux.Subscribe(core.NewMinedBlockEvent{})
defer sub.Unsubscribe()
subscribe <- struct{}{}
for item := range sub.Chan() {
block := item.Data.(core.NewMinedBlockEvent).Block
_, err := chain.InsertChain([]*types.Block{block})
if err != nil {
loopErr <- fmt.Errorf("failed to insert new mined block:%d, error:%v", block.NumberU64(), err)
}
newBlock <- struct{}{}
}
}
// Ignore empty commit here for less noise
w.skipSealHook = func(task *task) bool { w.skipSealHook = func(task *task) bool {
return len(task.receipts) == 0 return len(task.receipts) == 0
} }
go listenNewBlock()
<-subscribe // Ensure the subscription is created // Wait for mined blocks.
w.start() // Start mining! sub := w.mux.Subscribe(core.NewMinedBlockEvent{})
defer sub.Unsubscribe()
// Start mining!
w.start()
for i := 0; i < 5; i++ { for i := 0; i < 5; i++ {
b.txPool.AddLocal(b.newRandomTx(true)) b.txPool.AddLocal(b.newRandomTx(true))
b.txPool.AddLocal(b.newRandomTx(false)) b.txPool.AddLocal(b.newRandomTx(false))
w.postSideBlock(core.ChainSideEvent{Block: b.newRandomUncle()}) w.postSideBlock(core.ChainSideEvent{Block: b.newRandomUncle()})
w.postSideBlock(core.ChainSideEvent{Block: b.newRandomUncle()}) w.postSideBlock(core.ChainSideEvent{Block: b.newRandomUncle()})
select { select {
case e := <-loopErr: case ev := <-sub.Chan():
t.Fatal(e) block := ev.Data.(core.NewMinedBlockEvent).Block
case <-newBlock: if _, err := chain.InsertChain([]*types.Block{block}); err != nil {
case <-time.NewTimer(3 * time.Second).C: // Worker needs 1s to include new changes. t.Fatalf("failed to insert new mined block %d: %v", block.NumberU64(), err)
}
case <-time.After(3 * time.Second): // Worker needs 1s to include new changes.
t.Fatalf("timeout") t.Fatalf("timeout")
} }
} }

View File

@ -413,15 +413,14 @@ func TestClientHTTP(t *testing.T) {
// Launch concurrent requests. // Launch concurrent requests.
var ( var (
results = make([]echoResult, 100) results = make([]echoResult, 100)
errc = make(chan error) errc = make(chan error, len(results))
wantResult = echoResult{"a", 1, new(echoArgs)} wantResult = echoResult{"a", 1, new(echoArgs)}
) )
defer client.Close() defer client.Close()
for i := range results { for i := range results {
i := i i := i
go func() { go func() {
errc <- client.Call(&results[i], "test_echo", errc <- client.Call(&results[i], "test_echo", wantResult.String, wantResult.Int, wantResult.Args)
wantResult.String, wantResult.Int, wantResult.Args)
}() }()
} }

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@ -125,22 +125,25 @@ func TestSubscriptions(t *testing.T) {
// This test checks that unsubscribing works. // This test checks that unsubscribing works.
func TestServerUnsubscribe(t *testing.T) { func TestServerUnsubscribe(t *testing.T) {
p1, p2 := net.Pipe()
defer p2.Close()
// Start the server. // Start the server.
server := newTestServer() server := newTestServer()
service := &notificationTestService{unsubscribed: make(chan string)} service := &notificationTestService{unsubscribed: make(chan string, 1)}
server.RegisterName("nftest2", service) server.RegisterName("nftest2", service)
p1, p2 := net.Pipe()
go server.ServeCodec(NewCodec(p1), 0) go server.ServeCodec(NewCodec(p1), 0)
p2.SetDeadline(time.Now().Add(10 * time.Second))
// Subscribe. // Subscribe.
p2.SetDeadline(time.Now().Add(10 * time.Second))
p2.Write([]byte(`{"jsonrpc":"2.0","id":1,"method":"nftest2_subscribe","params":["someSubscription",0,10]}`)) p2.Write([]byte(`{"jsonrpc":"2.0","id":1,"method":"nftest2_subscribe","params":["someSubscription",0,10]}`))
// Handle received messages. // Handle received messages.
resps := make(chan subConfirmation) var (
notifications := make(chan subscriptionResult) resps = make(chan subConfirmation)
errors := make(chan error) notifications = make(chan subscriptionResult)
errors = make(chan error, 1)
)
go waitForMessages(json.NewDecoder(p2), resps, notifications, errors) go waitForMessages(json.NewDecoder(p2), resps, notifications, errors)
// Receive the subscription ID. // Receive the subscription ID.
@ -173,34 +176,45 @@ type subConfirmation struct {
subid ID subid ID
} }
// waitForMessages reads RPC messages from 'in' and dispatches them into the given channels.
// It stops if there is an error.
func waitForMessages(in *json.Decoder, successes chan subConfirmation, notifications chan subscriptionResult, errors chan error) { func waitForMessages(in *json.Decoder, successes chan subConfirmation, notifications chan subscriptionResult, errors chan error) {
for { for {
resp, notification, err := readAndValidateMessage(in)
if err != nil {
errors <- err
return
} else if resp != nil {
successes <- *resp
} else {
notifications <- *notification
}
}
}
func readAndValidateMessage(in *json.Decoder) (*subConfirmation, *subscriptionResult, error) {
var msg jsonrpcMessage var msg jsonrpcMessage
if err := in.Decode(&msg); err != nil { if err := in.Decode(&msg); err != nil {
errors <- fmt.Errorf("decode error: %v", err) return nil, nil, fmt.Errorf("decode error: %v", err)
return
} }
switch { switch {
case msg.isNotification(): case msg.isNotification():
var res subscriptionResult var res subscriptionResult
if err := json.Unmarshal(msg.Params, &res); err != nil { if err := json.Unmarshal(msg.Params, &res); err != nil {
errors <- fmt.Errorf("invalid subscription result: %v", err) return nil, nil, fmt.Errorf("invalid subscription result: %v", err)
} else {
notifications <- res
} }
return nil, &res, nil
case msg.isResponse(): case msg.isResponse():
var c subConfirmation var c subConfirmation
if msg.Error != nil { if msg.Error != nil {
errors <- msg.Error return nil, nil, msg.Error
} else if err := json.Unmarshal(msg.Result, &c.subid); err != nil { } else if err := json.Unmarshal(msg.Result, &c.subid); err != nil {
errors <- fmt.Errorf("invalid response: %v", err) return nil, nil, fmt.Errorf("invalid response: %v", err)
} else { } else {
json.Unmarshal(msg.ID, &c.reqid) json.Unmarshal(msg.ID, &c.reqid)
successes <- c return &c, nil, nil
} }
default: default:
errors <- fmt.Errorf("unrecognized message: %v", msg) return nil, nil, fmt.Errorf("unrecognized message: %v", msg)
return
}
} }
} }