Consul is a distributed, highly available, and data center aware solution to connect and configure applications across dynamic, distributed infrastructure.
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// Copyright (c) HashiCorp, Inc.
// SPDX-License-Identifier: MPL-2.0
package routine
import (
"context"
"os"
"sync"
"github.com/hashicorp/go-hclog"
)
type Routine func(ctx context.Context) error
// cancelCh is the ctx.Done()
// When cancel() is called, if the routine is running a blocking call (e.g. some ACL replication RPCs),
// stoppedCh won't be closed till the blocking call returns, while cancelCh will be closed immediately.
// cancelCh is used to properly detect routine running status between cancel() and close(stoppedCh)
type routineTracker struct {
cancel context.CancelFunc
cancelCh <-chan struct{} // closed when ctx is done
stoppedCh chan struct{} // closed when no longer running
}
func (r *routineTracker) running() bool {
select {
case <-r.stoppedCh:
return false
case <-r.cancelCh:
return false
default:
return true
}
}
func (r *routineTracker) wait() {
<-r.stoppedCh
}
type Manager struct {
lock sync.RWMutex
logger hclog.Logger
routines map[string]*routineTracker
}
func NewManager(logger hclog.Logger) *Manager {
if logger == nil {
logger = hclog.New(&hclog.LoggerOptions{
Output: os.Stderr,
})
}
return &Manager{
logger: logger,
routines: make(map[string]*routineTracker),
}
}
func (m *Manager) IsRunning(name string) bool {
m.lock.Lock()
defer m.lock.Unlock()
if routine, ok := m.routines[name]; ok {
return routine.running()
}
return false
}
func (m *Manager) Start(ctx context.Context, name string, routine Routine) error {
m.lock.Lock()
defer m.lock.Unlock()
if instance, ok := m.routines[name]; ok && instance.running() {
return nil
}
if ctx == nil {
ctx = context.Background()
}
rtCtx, cancel := context.WithCancel(ctx)
instance := &routineTracker{
cancel: cancel,
cancelCh: ctx.Done(),
stoppedCh: make(chan struct{}),
}
go m.execute(rtCtx, name, routine, instance.stoppedCh)
m.routines[name] = instance
m.logger.Info("started routine", "routine", name)
return nil
}
// execute will run the given routine in the foreground and close the given channel when its done executing
func (m *Manager) execute(ctx context.Context, name string, routine Routine, done chan struct{}) {
defer func() {
close(done)
}()
err := routine(ctx)
if err != nil && err != context.DeadlineExceeded && err != context.Canceled {
m.logger.Error("routine exited with error",
"routine", name,
"error", err,
)
} else {
m.logger.Info("stopped routine", "routine", name)
}
}
// Caveat: The returned stoppedCh indicates that the routine is completed
// It's possible that ctx is canceled, but stoppedCh not yet closed
// Use mgr.IsRunning(name) than this stoppedCh to tell whether the
// instance is still running (not cancelled or completed).
func (m *Manager) Stop(name string) <-chan struct{} {
instance := m.stopInstance(name)
if instance == nil {
// Fabricate a closed channel so it won't block forever.
ch := make(chan struct{})
close(ch)
return ch
}
return instance.stoppedCh
}
func (m *Manager) stopInstance(name string) *routineTracker {
m.lock.Lock()
defer m.lock.Unlock()
instance, ok := m.routines[name]
if !ok {
// no running instance
return nil
}
if !instance.running() {
return instance
}
m.logger.Info("stopping routine", "routine", name)
instance.cancel()
delete(m.routines, name)
return instance
}
// StopAll goroutines. Once StopAll is called, it is no longer safe to add no
// goroutines to the Manager.
func (m *Manager) StopAll() {
m.lock.Lock()
defer m.lock.Unlock()
for name, routine := range m.routines {
if !routine.running() {
continue
}
m.logger.Info("stopping routine", "routine", name)
routine.cancel()
}
}
// Wait for all goroutines to stop after StopAll is called.
func (m *Manager) Wait() {
m.lock.Lock()
defer m.lock.Unlock()
for _, routine := range m.routines {
routine.wait()
}
}