// Copyright (c) Tailscale Inc & AUTHORS // SPDX-License-Identifier: BSD-3-Clause // Package syncs contains additional sync types and functionality. package syncs import ( "context" "iter" "sync" "sync/atomic" "tailscale.com/util/mak" ) // ClosedChan returns a channel that's already closed. func ClosedChan() <-chan struct{} { return closedChan } var closedChan = initClosedChan() func initClosedChan() <-chan struct{} { ch := make(chan struct{}) close(ch) return ch } // AtomicValue is the generic version of [atomic.Value]. type AtomicValue[T any] struct { v atomic.Value } // wrappedValue is used to wrap a value T in a concrete type, // otherwise atomic.Value.Store may panic due to mismatching types in interfaces. // This wrapping is not necessary for non-interface kinds of T, // but there is no harm in wrapping anyways. // See https://cs.opensource.google/go/go/+/refs/tags/go1.22.2:src/sync/atomic/value.go;l=78 type wrappedValue[T any] struct{ v T } // Load returns the value set by the most recent Store. // It returns the zero value for T if the value is empty. func (v *AtomicValue[T]) Load() T { x, _ := v.LoadOk() return x } // LoadOk is like Load but returns a boolean indicating whether the value was // loaded. func (v *AtomicValue[T]) LoadOk() (_ T, ok bool) { x := v.v.Load() if x != nil { return x.(wrappedValue[T]).v, true } var zero T return zero, false } // Store sets the value of the Value to x. func (v *AtomicValue[T]) Store(x T) { v.v.Store(wrappedValue[T]{x}) } // Swap stores new into Value and returns the previous value. // It returns the zero value for T if the value is empty. func (v *AtomicValue[T]) Swap(x T) (old T) { oldV := v.v.Swap(wrappedValue[T]{x}) if oldV != nil { return oldV.(wrappedValue[T]).v } return old } // CompareAndSwap executes the compare-and-swap operation for the Value. func (v *AtomicValue[T]) CompareAndSwap(oldV, newV T) (swapped bool) { return v.v.CompareAndSwap(wrappedValue[T]{oldV}, wrappedValue[T]{newV}) } // WaitGroupChan is like a sync.WaitGroup, but has a chan that closes // on completion that you can wait on. (This, you can only use the // value once) // Also, its zero value is not usable. Use the constructor. type WaitGroupChan struct { n int64 // atomic done chan struct{} // closed on transition to zero } // NewWaitGroupChan returns a new single-use WaitGroupChan. func NewWaitGroupChan() *WaitGroupChan { return &WaitGroupChan{done: make(chan struct{})} } // DoneChan returns a channel that's closed on completion. func (wg *WaitGroupChan) DoneChan() <-chan struct{} { return wg.done } // Add adds delta, which may be negative, to the WaitGroupChan // counter. If the counter becomes zero, all goroutines blocked on // Wait or the Done chan are released. If the counter goes negative, // Add panics. // // Note that calls with a positive delta that occur when the counter // is zero must happen before a Wait. Calls with a negative delta, or // calls with a positive delta that start when the counter is greater // than zero, may happen at any time. Typically this means the calls // to Add should execute before the statement creating the goroutine // or other event to be waited for. func (wg *WaitGroupChan) Add(delta int) { n := atomic.AddInt64(&wg.n, int64(delta)) if n == 0 { close(wg.done) } } // Decr decrements the WaitGroup counter by one. // // (It is like sync.WaitGroup's Done method, but we don't use Done in // this type, because it's ambiguous between Context.Done and // WaitGroup.Done. So we use DoneChan and Decr instead.) func (wg *WaitGroupChan) Decr() { wg.Add(-1) } // Wait blocks until the WaitGroupChan counter is zero. func (wg *WaitGroupChan) Wait() { <-wg.done } // Semaphore is a counting semaphore. // // Use NewSemaphore to create one. type Semaphore struct { c chan struct{} } // NewSemaphore returns a semaphore with resource count n. func NewSemaphore(n int) Semaphore { return Semaphore{c: make(chan struct{}, n)} } // Acquire blocks until a resource is acquired. func (s Semaphore) Acquire() { s.c <- struct{}{} } // AcquireContext reports whether the resource was acquired before the ctx was done. func (s Semaphore) AcquireContext(ctx context.Context) bool { select { case s.c <- struct{}{}: return true case <-ctx.Done(): return false } } // TryAcquire reports, without blocking, whether the resource was acquired. func (s Semaphore) TryAcquire() bool { select { case s.c <- struct{}{}: return true default: return false } } // Release releases a resource. func (s Semaphore) Release() { <-s.c } // Map is a Go map protected by a [sync.RWMutex]. // It is preferred over [sync.Map] for maps with entries that change // at a relatively high frequency. // This must not be shallow copied. type Map[K comparable, V any] struct { mu sync.RWMutex m map[K]V } // Load loads the value for the provided key and whether it was found. func (m *Map[K, V]) Load(key K) (value V, loaded bool) { m.mu.RLock() defer m.mu.RUnlock() value, loaded = m.m[key] return value, loaded } // LoadFunc calls f with the value for the provided key // regardless of whether the entry exists or not. // The lock is held for the duration of the call to f. func (m *Map[K, V]) LoadFunc(key K, f func(value V, loaded bool)) { m.mu.RLock() defer m.mu.RUnlock() value, loaded := m.m[key] f(value, loaded) } // Store stores the value for the provided key. func (m *Map[K, V]) Store(key K, value V) { m.mu.Lock() defer m.mu.Unlock() mak.Set(&m.m, key, value) } // LoadOrStore returns the value for the given key if it exists // otherwise it stores value. func (m *Map[K, V]) LoadOrStore(key K, value V) (actual V, loaded bool) { if actual, loaded = m.Load(key); loaded { return actual, loaded } m.mu.Lock() defer m.mu.Unlock() actual, loaded = m.m[key] if !loaded { actual = value mak.Set(&m.m, key, value) } return actual, loaded } // LoadOrInit returns the value for the given key if it exists // otherwise f is called to construct the value to be set. // The lock is held for the duration to prevent duplicate initialization. func (m *Map[K, V]) LoadOrInit(key K, f func() V) (actual V, loaded bool) { if actual, loaded := m.Load(key); loaded { return actual, loaded } m.mu.Lock() defer m.mu.Unlock() if actual, loaded = m.m[key]; loaded { return actual, loaded } loaded = false actual = f() mak.Set(&m.m, key, actual) return actual, loaded } // LoadAndDelete returns the value for the given key if it exists. // It ensures that the map is cleared of any entry for the key. func (m *Map[K, V]) LoadAndDelete(key K) (value V, loaded bool) { m.mu.Lock() defer m.mu.Unlock() value, loaded = m.m[key] if loaded { delete(m.m, key) } return value, loaded } // Delete deletes the entry identified by key. func (m *Map[K, V]) Delete(key K) { m.mu.Lock() defer m.mu.Unlock() delete(m.m, key) } // Range iterates over the map in an undefined order calling f for each entry. // Iteration stops if f returns false. Map changes are blocked during iteration. // A read lock is held for the entire duration of the iteration. // Use the [WithLock] method instead to mutate the map during iteration. // // Deprecated: Use [All], [Keys], or [Values] instead. func (m *Map[K, V]) Range(f func(key K, value V) bool) { m.mu.RLock() defer m.mu.RUnlock() for k, v := range m.m { if !f(k, v) { return } } } // Keys iterates over all keys in the map in an undefined order. // A read lock is held for the entire duration of the iteration. // Use the [WithLock] method instead to mutate the map during iteration. func (m *Map[K, V]) Keys() iter.Seq[K] { return func(yield func(K) bool) { m.mu.RLock() defer m.mu.RUnlock() for k := range m.m { if !yield(k) { return } } } } // Values iterates over all values in the map in an undefined order. // A read lock is held for the entire duration of the iteration. // Use the [WithLock] method instead to mutate the map during iteration. func (m *Map[K, V]) Values() iter.Seq[V] { return func(yield func(V) bool) { m.mu.RLock() defer m.mu.RUnlock() for _, v := range m.m { if !yield(v) { return } } } } // All iterates over all entries in the map in an undefined order. // A read lock is held for the entire duration of the iteration. // Use the [WithLock] method instead to mutate the map during iteration. func (m *Map[K, V]) All() iter.Seq2[K, V] { return func(yield func(K, V) bool) { m.mu.RLock() defer m.mu.RUnlock() for k, v := range m.m { if !yield(k, v) { return } } } } // WithLock calls f with the underlying map. // Use of m2 must not escape the duration of this call. // The write-lock is held for the entire duration of this call. func (m *Map[K, V]) WithLock(f func(m2 map[K]V)) { m.mu.Lock() defer m.mu.Unlock() f(m.m) } // Len returns the length of the map. func (m *Map[K, V]) Len() int { m.mu.RLock() defer m.mu.RUnlock() return len(m.m) } // Clear removes all entries from the map. func (m *Map[K, V]) Clear() { m.mu.Lock() defer m.mu.Unlock() clear(m.m) } // Swap stores the value for the provided key, and returns the previous value // (if any). If there was no previous value set, a zero value will be returned. func (m *Map[K, V]) Swap(key K, value V) (oldValue V) { m.mu.Lock() defer m.mu.Unlock() oldValue = m.m[key] mak.Set(&m.m, key, value) return oldValue } // WaitGroup is identical to [sync.WaitGroup], // but provides a Go method to start a goroutine. type WaitGroup struct{ sync.WaitGroup } // Go calls the given function in a new goroutine. // It automatically increments the counter before execution and // automatically decrements the counter after execution. // It must not be called concurrently with Wait. func (wg *WaitGroup) Go(f func()) { wg.Add(1) go func() { defer wg.Done() f() }() }