src/sync/map.go - go - Git at Google

 // Copyright 2016 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 sync

 import (
 	"sync/atomic"
 )

 // Map is like a Go map[any]any but is safe for concurrent use
 // by multiple goroutines without additional locking or coordination.
 // Loads, stores, and deletes run in amortized constant time.
 //
 // The Map type is specialized. Most code should use a plain Go map instead,
 // with separate locking or coordination, for better type safety and to make it
 // easier to maintain other invariants along with the map content.
 //
 // The Map type is optimized for two common use cases: (1) when the entry for a given
 // key is only ever written once but read many times, as in caches that only grow,
 // or (2) when multiple goroutines read, write, and overwrite entries for disjoint
 // sets of keys. In these two cases, use of a Map may significantly reduce lock
 // contention compared to a Go map paired with a separate [Mutex] or [RWMutex].
 //
 // The zero Map is empty and ready for use. A Map must not be copied after first use.
 //
 // In the terminology of the Go memory model, Map arranges that a write operation
 // “synchronizes before” any read operation that observes the effect of the write, where
 // read and write operations are defined as follows.
 // [Map.Load], [Map.LoadAndDelete], [Map.LoadOrStore], [Map.Swap], [Map.CompareAndSwap],
 // and [Map.CompareAndDelete] are read operations;
 // [Map.Delete], [Map.LoadAndDelete], [Map.Store], and [Map.Swap] are write operations;
 // [Map.LoadOrStore] is a write operation when it returns loaded set to false;
 // [Map.CompareAndSwap] is a write operation when it returns swapped set to true;
 // and [Map.CompareAndDelete] is a write operation when it returns deleted set to true.
 type Map struct {
 	mu Mutex

 	// read contains the portion of the map's contents that are safe for
 	// concurrent access (with or without mu held).
 	//
 	// The read field itself is always safe to load, but must only be stored with
 	// mu held.
 	//
 	// Entries stored in read may be updated concurrently without mu, but updating
 	// a previously-expunged entry requires that the entry be copied to the dirty
 	// map and unexpunged with mu held.
 	read atomic.Pointer[readOnly]

 	// dirty contains the portion of the map's contents that require mu to be
 	// held. To ensure that the dirty map can be promoted to the read map quickly,
 	// it also includes all of the non-expunged entries in the read map.
 	//
 	// Expunged entries are not stored in the dirty map. An expunged entry in the
 	// clean map must be unexpunged and added to the dirty map before a new value
 	// can be stored to it.
 	//
 	// If the dirty map is nil, the next write to the map will initialize it by
 	// making a shallow copy of the clean map, omitting stale entries.
 	dirty map[any]*entry

 	// misses counts the number of loads since the read map was last updated that
 	// needed to lock mu to determine whether the key was present.
 	//
 	// Once enough misses have occurred to cover the cost of copying the dirty
 	// map, the dirty map will be promoted to the read map (in the unamended
 	// state) and the next store to the map will make a new dirty copy.
 	misses int
 }

 // readOnly is an immutable struct stored atomically in the Map.read field.
 type readOnly struct {
 	m       map[any]*entry
 	amended bool // true if the dirty map contains some key not in m.
 }

 // expunged is an arbitrary pointer that marks entries which have been deleted
 // from the dirty map.
 var expunged = new(any)

 // An entry is a slot in the map corresponding to a particular key.
 type entry struct {
 	// p points to the interface{} value stored for the entry.
 	//
 	// If p == nil, the entry has been deleted, and either m.dirty == nil or
 	// m.dirty[key] is e.
 	//
 	// If p == expunged, the entry has been deleted, m.dirty != nil, and the entry
 	// is missing from m.dirty.
 	//
 	// Otherwise, the entry is valid and recorded in m.read.m[key] and, if m.dirty
 	// != nil, in m.dirty[key].
 	//
 	// An entry can be deleted by atomic replacement with nil: when m.dirty is
 	// next created, it will atomically replace nil with expunged and leave
 	// m.dirty[key] unset.
 	//
 	// An entry's associated value can be updated by atomic replacement, provided
 	// p != expunged. If p == expunged, an entry's associated value can be updated
 	// only after first setting m.dirty[key] = e so that lookups using the dirty
 	// map find the entry.
 	p atomic.Pointer[any]
 }

 func newEntry(i any) *entry {
 	e := &entry{}
 	e.p.Store(&i)
 	return e
 }

 func (m *Map) loadReadOnly() readOnly {
 	if p := m.read.Load(); p != nil {
 		return *p
 	}
 	return readOnly{}
 }

 // Load returns the value stored in the map for a key, or nil if no
 // value is present.
 // The ok result indicates whether value was found in the map.
 func (m *Map) Load(key any) (value any, ok bool) {
 	read := m.loadReadOnly()
 	e, ok := read.m[key]
 	if !ok && read.amended {
 		m.mu.Lock()
 		// Avoid reporting a spurious miss if m.dirty got promoted while we were
 		// blocked on m.mu. (If further loads of the same key will not miss, it's
 		// not worth copying the dirty map for this key.)
 		read = m.loadReadOnly()
 		e, ok = read.m[key]
 		if !ok && read.amended {
 			e, ok = m.dirty[key]
 			// Regardless of whether the entry was present, record a miss: this key
 			// will take the slow path until the dirty map is promoted to the read
 			// map.
 			m.missLocked()
 		}
 		m.mu.Unlock()
 	}
 	if !ok {
 		return nil, false
 	}
 	return e.load()
 }

 func (e *entry) load() (value any, ok bool) {
 	p := e.p.Load()
 	if p == nil || p == expunged {
 		return nil, false
 	}
 	return *p, true
 }

 // Store sets the value for a key.
 func (m *Map) Store(key, value any) {
 	_, _ = m.Swap(key, value)
 }

 // Clear deletes all the entries, resulting in an empty Map.
 func (m *Map) Clear() {
 	read := m.loadReadOnly()
 	if len(read.m) == 0 && !read.amended {
 		// Avoid allocating a new readOnly when the map is already clear.
 		return
 	}

 	m.mu.Lock()
 	defer m.mu.Unlock()

 	read = m.loadReadOnly()
 	if len(read.m) > 0 || read.amended {
 		m.read.Store(&readOnly{})
 	}

 	clear(m.dirty)
 	// Don't immediately promote the newly-cleared dirty map on the next operation.
 	m.misses = 0
 }

 // tryCompareAndSwap compare the entry with the given old value and swaps
 // it with a new value if the entry is equal to the old value, and the entry
 // has not been expunged.
 //
 // If the entry is expunged, tryCompareAndSwap returns false and leaves
 // the entry unchanged.
 func (e *entry) tryCompareAndSwap(old, new any) bool {
 	p := e.p.Load()
 	if p == nil || p == expunged || *p != old {
 		return false
 	}

 	// Copy the interface after the first load to make this method more amenable
 	// to escape analysis: if the comparison fails from the start, we shouldn't
 	// bother heap-allocating an interface value to store.
 	nc := new
 	for {
 		if e.p.CompareAndSwap(p, &nc) {
 			return true
 		}
 		p = e.p.Load()
 		if p == nil || p == expunged || *p != old {
 			return false
 		}
 	}
 }

 // unexpungeLocked ensures that the entry is not marked as expunged.
 //
 // If the entry was previously expunged, it must be added to the dirty map
 // before m.mu is unlocked.
 func (e *entry) unexpungeLocked() (wasExpunged bool) {
 	return e.p.CompareAndSwap(expunged, nil)
 }

 // swapLocked unconditionally swaps a value into the entry.
 //
 // The entry must be known not to be expunged.
 func (e *entry) swapLocked(i *any) *any {
 	return e.p.Swap(i)
 }

 // LoadOrStore returns the existing value for the key if present.
 // Otherwise, it stores and returns the given value.
 // The loaded result is true if the value was loaded, false if stored.
 func (m *Map) LoadOrStore(key, value any) (actual any, loaded bool) {
 	// Avoid locking if it's a clean hit.
 	read := m.loadReadOnly()
 	if e, ok := read.m[key]; ok {
 		actual, loaded, ok := e.tryLoadOrStore(value)
 		if ok {
 			return actual, loaded
 		}
 	}

 	m.mu.Lock()
 	read = m.loadReadOnly()
 	if e, ok := read.m[key]; ok {
 		if e.unexpungeLocked() {
 			m.dirty[key] = e
 		}
 		actual, loaded, _ = e.tryLoadOrStore(value)
 	} else if e, ok := m.dirty[key]; ok {
 		actual, loaded, _ = e.tryLoadOrStore(value)
 		m.missLocked()
 	} else {
 		if !read.amended {
 			// We're adding the first new key to the dirty map.
 			// Make sure it is allocated and mark the read-only map as incomplete.
 			m.dirtyLocked()
 			m.read.Store(&readOnly{m: read.m, amended: true})
 		}
 		m.dirty[key] = newEntry(value)
 		actual, loaded = value, false
 	}
 	m.mu.Unlock()

 	return actual, loaded
 }

 // tryLoadOrStore atomically loads or stores a value if the entry is not
 // expunged.
 //
 // If the entry is expunged, tryLoadOrStore leaves the entry unchanged and
 // returns with ok==false.
 func (e *entry) tryLoadOrStore(i any) (actual any, loaded, ok bool) {
 	p := e.p.Load()
 	if p == expunged {
 		return nil, false, false
 	}
 	if p != nil {
 		return *p, true, true
 	}

 	// Copy the interface after the first load to make this method more amenable
 	// to escape analysis: if we hit the "load" path or the entry is expunged, we
 	// shouldn't bother heap-allocating.
 	ic := i
 	for {
 		if e.p.CompareAndSwap(nil, &ic) {
 			return i, false, true
 		}
 		p = e.p.Load()
 		if p == expunged {
 			return nil, false, false
 		}
 		if p != nil {
 			return *p, true, true
 		}
 	}
 }

 // LoadAndDelete deletes the value for a key, returning the previous value if any.
 // The loaded result reports whether the key was present.
 func (m *Map) LoadAndDelete(key any) (value any, loaded bool) {
 	read := m.loadReadOnly()
 	e, ok := read.m[key]
 	if !ok && read.amended {
 		m.mu.Lock()
 		read = m.loadReadOnly()
 		e, ok = read.m[key]
 		if !ok && read.amended {
 			e, ok = m.dirty[key]
 			delete(m.dirty, key)
 			// Regardless of whether the entry was present, record a miss: this key
 			// will take the slow path until the dirty map is promoted to the read
 			// map.
 			m.missLocked()
 		}
 		m.mu.Unlock()
 	}
 	if ok {
 		return e.delete()
 	}
 	return nil, false
 }

 // Delete deletes the value for a key.
 func (m *Map) Delete(key any) {
 	m.LoadAndDelete(key)
 }

 func (e *entry) delete() (value any, ok bool) {
 	for {
 		p := e.p.Load()
 		if p == nil || p == expunged {
 			return nil, false
 		}
 		if e.p.CompareAndSwap(p, nil) {
 			return *p, true
 		}
 	}
 }

 // trySwap swaps a value if the entry has not been expunged.
 //
 // If the entry is expunged, trySwap returns false and leaves the entry
 // unchanged.
 func (e *entry) trySwap(i *any) (*any, bool) {
 	for {
 		p := e.p.Load()
 		if p == expunged {
 			return nil, false
 		}
 		if e.p.CompareAndSwap(p, i) {
 			return p, true
 		}
 	}
 }

 // Swap swaps the value for a key and returns the previous value if any.
 // The loaded result reports whether the key was present.
 func (m *Map) Swap(key, value any) (previous any, loaded bool) {
 	read := m.loadReadOnly()
 	if e, ok := read.m[key]; ok {
 		if v, ok := e.trySwap(&value); ok {
 			if v == nil {
 				return nil, false
 			}
 			return *v, true
 		}
 	}

 	m.mu.Lock()
 	read = m.loadReadOnly()
 	if e, ok := read.m[key]; ok {
 		if e.unexpungeLocked() {
 			// The entry was previously expunged, which implies that there is a
 			// non-nil dirty map and this entry is not in it.
 			m.dirty[key] = e
 		}
 		if v := e.swapLocked(&value); v != nil {
 			loaded = true
 			previous = *v
 		}
 	} else if e, ok := m.dirty[key]; ok {
 		if v := e.swapLocked(&value); v != nil {
 			loaded = true
 			previous = *v
 		}
 	} else {
 		if !read.amended {
 			// We're adding the first new key to the dirty map.
 			// Make sure it is allocated and mark the read-only map as incomplete.
 			m.dirtyLocked()
 			m.read.Store(&readOnly{m: read.m, amended: true})
 		}
 		m.dirty[key] = newEntry(value)
 	}
 	m.mu.Unlock()
 	return previous, loaded
 }

 // CompareAndSwap swaps the old and new values for key
 // if the value stored in the map is equal to old.
 // The old value must be of a comparable type.
 func (m *Map) CompareAndSwap(key, old, new any) (swapped bool) {
 	read := m.loadReadOnly()
 	if e, ok := read.m[key]; ok {
 		return e.tryCompareAndSwap(old, new)
 	} else if !read.amended {
 		return false // No existing value for key.
 	}

 	m.mu.Lock()
 	defer m.mu.Unlock()
 	read = m.loadReadOnly()
 	swapped = false
 	if e, ok := read.m[key]; ok {
 		swapped = e.tryCompareAndSwap(old, new)
 	} else if e, ok := m.dirty[key]; ok {
 		swapped = e.tryCompareAndSwap(old, new)
 		// We needed to lock mu in order to load the entry for key,
 		// and the operation didn't change the set of keys in the map
 		// (so it would be made more efficient by promoting the dirty
 		// map to read-only).
 		// Count it as a miss so that we will eventually switch to the
 		// more efficient steady state.
 		m.missLocked()
 	}
 	return swapped
 }

 // CompareAndDelete deletes the entry for key if its value is equal to old.
 // The old value must be of a comparable type.
 //
 // If there is no current value for key in the map, CompareAndDelete
 // returns false (even if the old value is the nil interface value).
 func (m *Map) CompareAndDelete(key, old any) (deleted bool) {
 	read := m.loadReadOnly()
 	e, ok := read.m[key]
 	if !ok && read.amended {
 		m.mu.Lock()
 		read = m.loadReadOnly()
 		e, ok = read.m[key]
 		if !ok && read.amended {
 			e, ok = m.dirty[key]
 			// Don't delete key from m.dirty: we still need to do the “compare” part
 			// of the operation. The entry will eventually be expunged when the
 			// dirty map is promoted to the read map.
 			//
 			// Regardless of whether the entry was present, record a miss: this key
 			// will take the slow path until the dirty map is promoted to the read
 			// map.
 			m.missLocked()
 		}
 		m.mu.Unlock()
 	}
 	for ok {
 		p := e.p.Load()
 		if p == nil || p == expunged || *p != old {
 			return false
 		}
 		if e.p.CompareAndSwap(p, nil) {
 			return true
 		}
 	}
 	return false
 }

 // Range calls f sequentially for each key and value present in the map.
 // If f returns false, range stops the iteration.
 //
 // Range does not necessarily correspond to any consistent snapshot of the Map's
 // contents: no key will be visited more than once, but if the value for any key
 // is stored or deleted concurrently (including by f), Range may reflect any
 // mapping for that key from any point during the Range call. Range does not
 // block other methods on the receiver; even f itself may call any method on m.
 //
 // Range may be O(N) with the number of elements in the map even if f returns
 // false after a constant number of calls.
 func (m *Map) Range(f func(key, value any) bool) {
 	// We need to be able to iterate over all of the keys that were already
 	// present at the start of the call to Range.
 	// If read.amended is false, then read.m satisfies that property without
 	// requiring us to hold m.mu for a long time.
 	read := m.loadReadOnly()
 	if read.amended {
 		// m.dirty contains keys not in read.m. Fortunately, Range is already O(N)
 		// (assuming the caller does not break out early), so a call to Range
 		// amortizes an entire copy of the map: we can promote the dirty copy
 		// immediately!
 		m.mu.Lock()
 		read = m.loadReadOnly()
 		if read.amended {
 			read = readOnly{m: m.dirty}
 			copyRead := read
 			m.read.Store(&copyRead)
 			m.dirty = nil
 			m.misses = 0
 		}
 		m.mu.Unlock()
 	}

 	for k, e := range read.m {
 		v, ok := e.load()
 		if !ok {
 			continue
 		}
 		if !f(k, v) {
 			break
 		}
 	}
 }

 func (m *Map) missLocked() {
 	m.misses++
 	if m.misses < len(m.dirty) {
 		return
 	}
 	m.read.Store(&readOnly{m: m.dirty})
 	m.dirty = nil
 	m.misses = 0
 }

 func (m *Map) dirtyLocked() {
 	if m.dirty != nil {
 		return
 	}

 	read := m.loadReadOnly()
 	m.dirty = make(map[any]*entry, len(read.m))
 	for k, e := range read.m {
 		if !e.tryExpungeLocked() {
 			m.dirty[k] = e
 		}
 	}
 }

 func (e *entry) tryExpungeLocked() (isExpunged bool) {
 	p := e.p.Load()
 	for p == nil {
 		if e.p.CompareAndSwap(nil, expunged) {
 			return true
 		}
 		p = e.p.Load()
 	}
 	return p == expunged
 }
	// Copyright 2016 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 sync

	import (
	"sync/atomic"
	)

	// Map is like a Go map[any]any but is safe for concurrent use
	// by multiple goroutines without additional locking or coordination.
	// Loads, stores, and deletes run in amortized constant time.
	//
	// The Map type is specialized. Most code should use a plain Go map instead,
	// with separate locking or coordination, for better type safety and to make it
	// easier to maintain other invariants along with the map content.
	//
	// The Map type is optimized for two common use cases: (1) when the entry for a given
	// key is only ever written once but read many times, as in caches that only grow,
	// or (2) when multiple goroutines read, write, and overwrite entries for disjoint
	// sets of keys. In these two cases, use of a Map may significantly reduce lock
	// contention compared to a Go map paired with a separate [Mutex] or [RWMutex].
	//
	// The zero Map is empty and ready for use. A Map must not be copied after first use.
	//
	// In the terminology of the Go memory model, Map arranges that a write operation
	// “synchronizes before” any read operation that observes the effect of the write, where
	// read and write operations are defined as follows.
	// [Map.Load], [Map.LoadAndDelete], [Map.LoadOrStore], [Map.Swap], [Map.CompareAndSwap],
	// and [Map.CompareAndDelete] are read operations;
	// [Map.Delete], [Map.LoadAndDelete], [Map.Store], and [Map.Swap] are write operations;
	// [Map.LoadOrStore] is a write operation when it returns loaded set to false;
	// [Map.CompareAndSwap] is a write operation when it returns swapped set to true;
	// and [Map.CompareAndDelete] is a write operation when it returns deleted set to true.
	type Map struct {
	mu Mutex

	// read contains the portion of the map's contents that are safe for
	// concurrent access (with or without mu held).
	//
	// The read field itself is always safe to load, but must only be stored with
	// mu held.
	//
	// Entries stored in read may be updated concurrently without mu, but updating
	// a previously-expunged entry requires that the entry be copied to the dirty
	// map and unexpunged with mu held.
	read atomic.Pointer[readOnly]

	// dirty contains the portion of the map's contents that require mu to be
	// held. To ensure that the dirty map can be promoted to the read map quickly,
	// it also includes all of the non-expunged entries in the read map.
	//
	// Expunged entries are not stored in the dirty map. An expunged entry in the
	// clean map must be unexpunged and added to the dirty map before a new value
	// can be stored to it.
	//
	// If the dirty map is nil, the next write to the map will initialize it by
	// making a shallow copy of the clean map, omitting stale entries.
	dirty map[any]*entry

	// misses counts the number of loads since the read map was last updated that
	// needed to lock mu to determine whether the key was present.
	//
	// Once enough misses have occurred to cover the cost of copying the dirty
	// map, the dirty map will be promoted to the read map (in the unamended
	// state) and the next store to the map will make a new dirty copy.
	misses int
	}

	// readOnly is an immutable struct stored atomically in the Map.read field.
	type readOnly struct {
	m map[any]*entry
	amended bool // true if the dirty map contains some key not in m.
	}

	// expunged is an arbitrary pointer that marks entries which have been deleted
	// from the dirty map.
	var expunged = new(any)

	// An entry is a slot in the map corresponding to a particular key.
	type entry struct {
	// p points to the interface{} value stored for the entry.
	//
	// If p == nil, the entry has been deleted, and either m.dirty == nil or
	// m.dirty[key] is e.
	//
	// If p == expunged, the entry has been deleted, m.dirty != nil, and the entry
	// is missing from m.dirty.
	//
	// Otherwise, the entry is valid and recorded in m.read.m[key] and, if m.dirty
	// != nil, in m.dirty[key].
	//
	// An entry can be deleted by atomic replacement with nil: when m.dirty is
	// next created, it will atomically replace nil with expunged and leave
	// m.dirty[key] unset.
	//
	// An entry's associated value can be updated by atomic replacement, provided
	// p != expunged. If p == expunged, an entry's associated value can be updated
	// only after first setting m.dirty[key] = e so that lookups using the dirty
	// map find the entry.
	p atomic.Pointer[any]
	}

	func newEntry(i any) *entry {
	e := &entry{}
	e.p.Store(&i)
	return e
	}

	func (m *Map) loadReadOnly() readOnly {
	if p := m.read.Load(); p != nil {
	return *p
	}
	return readOnly{}
	}

	// Load returns the value stored in the map for a key, or nil if no
	// value is present.
	// The ok result indicates whether value was found in the map.
	func (m *Map) Load(key any) (value any, ok bool) {
	read := m.loadReadOnly()
	e, ok := read.m[key]
	if !ok && read.amended {
	m.mu.Lock()
	// Avoid reporting a spurious miss if m.dirty got promoted while we were
	// blocked on m.mu. (If further loads of the same key will not miss, it's
	// not worth copying the dirty map for this key.)
	read = m.loadReadOnly()
	e, ok = read.m[key]
	if !ok && read.amended {
	e, ok = m.dirty[key]
	// Regardless of whether the entry was present, record a miss: this key
	// will take the slow path until the dirty map is promoted to the read
	// map.
	m.missLocked()
	}
	m.mu.Unlock()
	}
	if !ok {
	return nil, false
	}
	return e.load()
	}

	func (e *entry) load() (value any, ok bool) {
	p := e.p.Load()
	if p == nil \|\| p == expunged {
	return nil, false
	}
	return *p, true
	}

	// Store sets the value for a key.
	func (m *Map) Store(key, value any) {
	_, _ = m.Swap(key, value)
	}

	// Clear deletes all the entries, resulting in an empty Map.
	func (m *Map) Clear() {
	read := m.loadReadOnly()
	if len(read.m) == 0 && !read.amended {
	// Avoid allocating a new readOnly when the map is already clear.
	return
	}

	m.mu.Lock()
	defer m.mu.Unlock()

	read = m.loadReadOnly()
	if len(read.m) > 0 \|\| read.amended {
	m.read.Store(&readOnly{})
	}

	clear(m.dirty)
	// Don't immediately promote the newly-cleared dirty map on the next operation.
	m.misses = 0
	}

	// tryCompareAndSwap compare the entry with the given old value and swaps
	// it with a new value if the entry is equal to the old value, and the entry
	// has not been expunged.
	//
	// If the entry is expunged, tryCompareAndSwap returns false and leaves
	// the entry unchanged.
	func (e *entry) tryCompareAndSwap(old, new any) bool {
	p := e.p.Load()
	if p == nil \|\| p == expunged \|\| *p != old {
	return false
	}

	// Copy the interface after the first load to make this method more amenable
	// to escape analysis: if the comparison fails from the start, we shouldn't
	// bother heap-allocating an interface value to store.
	nc := new
	for {
	if e.p.CompareAndSwap(p, &nc) {
	return true
	}
	p = e.p.Load()
	if p == nil \|\| p == expunged \|\| *p != old {
	return false
	}
	}
	}

	// unexpungeLocked ensures that the entry is not marked as expunged.
	//
	// If the entry was previously expunged, it must be added to the dirty map
	// before m.mu is unlocked.
	func (e *entry) unexpungeLocked() (wasExpunged bool) {
	return e.p.CompareAndSwap(expunged, nil)
	}

	// swapLocked unconditionally swaps a value into the entry.
	//
	// The entry must be known not to be expunged.
	func (e entry) swapLocked(i any) *any {
	return e.p.Swap(i)
	}

	// LoadOrStore returns the existing value for the key if present.
	// Otherwise, it stores and returns the given value.
	// The loaded result is true if the value was loaded, false if stored.
	func (m *Map) LoadOrStore(key, value any) (actual any, loaded bool) {
	// Avoid locking if it's a clean hit.
	read := m.loadReadOnly()
	if e, ok := read.m[key]; ok {
	actual, loaded, ok := e.tryLoadOrStore(value)
	if ok {
	return actual, loaded
	}
	}

	m.mu.Lock()
	read = m.loadReadOnly()
	if e, ok := read.m[key]; ok {
	if e.unexpungeLocked() {
	m.dirty[key] = e
	}
	actual, loaded, _ = e.tryLoadOrStore(value)
	} else if e, ok := m.dirty[key]; ok {
	actual, loaded, _ = e.tryLoadOrStore(value)
	m.missLocked()
	} else {
	if !read.amended {
	// We're adding the first new key to the dirty map.
	// Make sure it is allocated and mark the read-only map as incomplete.
	m.dirtyLocked()
	m.read.Store(&readOnly{m: read.m, amended: true})
	}
	m.dirty[key] = newEntry(value)
	actual, loaded = value, false
	}
	m.mu.Unlock()

	return actual, loaded
	}

	// tryLoadOrStore atomically loads or stores a value if the entry is not
	// expunged.
	//
	// If the entry is expunged, tryLoadOrStore leaves the entry unchanged and
	// returns with ok==false.
	func (e *entry) tryLoadOrStore(i any) (actual any, loaded, ok bool) {
	p := e.p.Load()
	if p == expunged {
	return nil, false, false
	}
	if p != nil {
	return *p, true, true
	}

	// Copy the interface after the first load to make this method more amenable
	// to escape analysis: if we hit the "load" path or the entry is expunged, we
	// shouldn't bother heap-allocating.
	ic := i
	for {
	if e.p.CompareAndSwap(nil, &ic) {
	return i, false, true
	}
	p = e.p.Load()
	if p == expunged {
	return nil, false, false
	}
	if p != nil {
	return *p, true, true
	}
	}
	}

	// LoadAndDelete deletes the value for a key, returning the previous value if any.
	// The loaded result reports whether the key was present.
	func (m *Map) LoadAndDelete(key any) (value any, loaded bool) {
	read := m.loadReadOnly()
	e, ok := read.m[key]
	if !ok && read.amended {
	m.mu.Lock()
	read = m.loadReadOnly()
	e, ok = read.m[key]
	if !ok && read.amended {
	e, ok = m.dirty[key]
	delete(m.dirty, key)
	// Regardless of whether the entry was present, record a miss: this key
	// will take the slow path until the dirty map is promoted to the read
	// map.
	m.missLocked()
	}
	m.mu.Unlock()
	}
	if ok {
	return e.delete()
	}
	return nil, false
	}

	// Delete deletes the value for a key.
	func (m *Map) Delete(key any) {
	m.LoadAndDelete(key)
	}

	func (e *entry) delete() (value any, ok bool) {
	for {
	p := e.p.Load()
	if p == nil \|\| p == expunged {
	return nil, false
	}
	if e.p.CompareAndSwap(p, nil) {
	return *p, true
	}
	}
	}

	// trySwap swaps a value if the entry has not been expunged.
	//
	// If the entry is expunged, trySwap returns false and leaves the entry
	// unchanged.
	func (e entry) trySwap(i any) (*any, bool) {
	for {
	p := e.p.Load()
	if p == expunged {
	return nil, false
	}
	if e.p.CompareAndSwap(p, i) {
	return p, true
	}
	}
	}

	// Swap swaps the value for a key and returns the previous value if any.
	// The loaded result reports whether the key was present.
	func (m *Map) Swap(key, value any) (previous any, loaded bool) {
	read := m.loadReadOnly()
	if e, ok := read.m[key]; ok {
	if v, ok := e.trySwap(&value); ok {
	if v == nil {
	return nil, false
	}
	return *v, true
	}
	}

	m.mu.Lock()
	read = m.loadReadOnly()
	if e, ok := read.m[key]; ok {
	if e.unexpungeLocked() {
	// The entry was previously expunged, which implies that there is a
	// non-nil dirty map and this entry is not in it.
	m.dirty[key] = e
	}
	if v := e.swapLocked(&value); v != nil {
	loaded = true
	previous = *v
	}
	} else if e, ok := m.dirty[key]; ok {
	if v := e.swapLocked(&value); v != nil {
	loaded = true
	previous = *v
	}
	} else {
	if !read.amended {
	// We're adding the first new key to the dirty map.
	// Make sure it is allocated and mark the read-only map as incomplete.
	m.dirtyLocked()
	m.read.Store(&readOnly{m: read.m, amended: true})
	}
	m.dirty[key] = newEntry(value)
	}
	m.mu.Unlock()
	return previous, loaded
	}

	// CompareAndSwap swaps the old and new values for key
	// if the value stored in the map is equal to old.
	// The old value must be of a comparable type.
	func (m *Map) CompareAndSwap(key, old, new any) (swapped bool) {
	read := m.loadReadOnly()
	if e, ok := read.m[key]; ok {
	return e.tryCompareAndSwap(old, new)
	} else if !read.amended {
	return false // No existing value for key.
	}

	m.mu.Lock()
	defer m.mu.Unlock()
	read = m.loadReadOnly()
	swapped = false
	if e, ok := read.m[key]; ok {
	swapped = e.tryCompareAndSwap(old, new)
	} else if e, ok := m.dirty[key]; ok {
	swapped = e.tryCompareAndSwap(old, new)
	// We needed to lock mu in order to load the entry for key,
	// and the operation didn't change the set of keys in the map
	// (so it would be made more efficient by promoting the dirty
	// map to read-only).
	// Count it as a miss so that we will eventually switch to the
	// more efficient steady state.
	m.missLocked()
	}
	return swapped
	}

	// CompareAndDelete deletes the entry for key if its value is equal to old.
	// The old value must be of a comparable type.
	//
	// If there is no current value for key in the map, CompareAndDelete
	// returns false (even if the old value is the nil interface value).
	func (m *Map) CompareAndDelete(key, old any) (deleted bool) {
	read := m.loadReadOnly()
	e, ok := read.m[key]
	if !ok && read.amended {
	m.mu.Lock()
	read = m.loadReadOnly()
	e, ok = read.m[key]
	if !ok && read.amended {
	e, ok = m.dirty[key]
	// Don't delete key from m.dirty: we still need to do the “compare” part
	// of the operation. The entry will eventually be expunged when the
	// dirty map is promoted to the read map.
	//
	// Regardless of whether the entry was present, record a miss: this key
	// will take the slow path until the dirty map is promoted to the read
	// map.
	m.missLocked()
	}
	m.mu.Unlock()
	}
	for ok {
	p := e.p.Load()
	if p == nil \|\| p == expunged \|\| *p != old {
	return false
	}
	if e.p.CompareAndSwap(p, nil) {
	return true
	}
	}
	return false
	}

	// Range calls f sequentially for each key and value present in the map.
	// If f returns false, range stops the iteration.
	//
	// Range does not necessarily correspond to any consistent snapshot of the Map's
	// contents: no key will be visited more than once, but if the value for any key
	// is stored or deleted concurrently (including by f), Range may reflect any
	// mapping for that key from any point during the Range call. Range does not
	// block other methods on the receiver; even f itself may call any method on m.
	//
	// Range may be O(N) with the number of elements in the map even if f returns
	// false after a constant number of calls.
	func (m *Map) Range(f func(key, value any) bool) {
	// We need to be able to iterate over all of the keys that were already
	// present at the start of the call to Range.
	// If read.amended is false, then read.m satisfies that property without
	// requiring us to hold m.mu for a long time.
	read := m.loadReadOnly()
	if read.amended {
	// m.dirty contains keys not in read.m. Fortunately, Range is already O(N)
	// (assuming the caller does not break out early), so a call to Range
	// amortizes an entire copy of the map: we can promote the dirty copy
	// immediately!
	m.mu.Lock()
	read = m.loadReadOnly()
	if read.amended {
	read = readOnly{m: m.dirty}
	copyRead := read
	m.read.Store(&copyRead)
	m.dirty = nil
	m.misses = 0
	}
	m.mu.Unlock()
	}

	for k, e := range read.m {
	v, ok := e.load()
	if !ok {
	continue
	}
	if !f(k, v) {
	break
	}
	}
	}

	func (m *Map) missLocked() {
	m.misses++
	if m.misses < len(m.dirty) {
	return
	}
	m.read.Store(&readOnly{m: m.dirty})
	m.dirty = nil
	m.misses = 0
	}

	func (m *Map) dirtyLocked() {
	if m.dirty != nil {
	return
	}

	read := m.loadReadOnly()
	m.dirty = make(map[any]*entry, len(read.m))
	for k, e := range read.m {
	if !e.tryExpungeLocked() {
	m.dirty[k] = e
	}
	}
	}

	func (e *entry) tryExpungeLocked() (isExpunged bool) {
	p := e.p.Load()
	for p == nil {
	if e.p.CompareAndSwap(nil, expunged) {
	return true
	}
	p = e.p.Load()
	}
	return p == expunged
	}