mirror of
https://github.com/superseriousbusiness/gotosocial.git
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29007b1b88
* update bun libraries to v1.2.5 * pin old v1.29.0 of otel
695 lines
20 KiB
Go
695 lines
20 KiB
Go
package xsync
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import (
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"fmt"
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"math"
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"sync"
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"sync/atomic"
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"unsafe"
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)
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const (
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// number of MapOf entries per bucket; 5 entries lead to size of 64B
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// (one cache line) on 64-bit machines
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entriesPerMapOfBucket = 5
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defaultMeta uint64 = 0x8080808080808080
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metaMask uint64 = 0xffffffffff
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defaultMetaMasked uint64 = defaultMeta & metaMask
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emptyMetaSlot uint8 = 0x80
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)
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// MapOf is like a Go map[K]V but is safe for concurrent
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// use by multiple goroutines without additional locking or
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// coordination. It follows the interface of sync.Map with
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// a number of valuable extensions like Compute or Size.
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//
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// A MapOf must not be copied after first use.
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//
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// MapOf uses a modified version of Cache-Line Hash Table (CLHT)
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// data structure: https://github.com/LPD-EPFL/CLHT
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//
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// CLHT is built around idea to organize the hash table in
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// cache-line-sized buckets, so that on all modern CPUs update
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// operations complete with at most one cache-line transfer.
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// Also, Get operations involve no write to memory, as well as no
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// mutexes or any other sort of locks. Due to this design, in all
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// considered scenarios MapOf outperforms sync.Map.
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//
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// MapOf also borrows ideas from Java's j.u.c.ConcurrentHashMap
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// (immutable K/V pair structs instead of atomic snapshots)
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// and C++'s absl::flat_hash_map (meta memory and SWAR-based
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// lookups).
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type MapOf[K comparable, V any] struct {
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totalGrowths int64
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totalShrinks int64
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resizing int64 // resize in progress flag; updated atomically
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resizeMu sync.Mutex // only used along with resizeCond
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resizeCond sync.Cond // used to wake up resize waiters (concurrent modifications)
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table unsafe.Pointer // *mapOfTable
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hasher func(K, uint64) uint64
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minTableLen int
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growOnly bool
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}
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type mapOfTable[K comparable, V any] struct {
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buckets []bucketOfPadded
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// striped counter for number of table entries;
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// used to determine if a table shrinking is needed
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// occupies min(buckets_memory/1024, 64KB) of memory
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size []counterStripe
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seed uint64
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}
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// bucketOfPadded is a CL-sized map bucket holding up to
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// entriesPerMapOfBucket entries.
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type bucketOfPadded struct {
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//lint:ignore U1000 ensure each bucket takes two cache lines on both 32 and 64-bit archs
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pad [cacheLineSize - unsafe.Sizeof(bucketOf{})]byte
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bucketOf
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}
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type bucketOf struct {
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meta uint64
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entries [entriesPerMapOfBucket]unsafe.Pointer // *entryOf
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next unsafe.Pointer // *bucketOfPadded
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mu sync.Mutex
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}
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// entryOf is an immutable map entry.
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type entryOf[K comparable, V any] struct {
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key K
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value V
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}
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// NewMapOf creates a new MapOf instance configured with the given
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// options.
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func NewMapOf[K comparable, V any](options ...func(*MapConfig)) *MapOf[K, V] {
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return NewMapOfWithHasher[K, V](defaultHasher[K](), options...)
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}
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// NewMapOfWithHasher creates a new MapOf instance configured with
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// the given hasher and options. The hash function is used instead
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// of the built-in hash function configured when a map is created
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// with the NewMapOf function.
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func NewMapOfWithHasher[K comparable, V any](
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hasher func(K, uint64) uint64,
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options ...func(*MapConfig),
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) *MapOf[K, V] {
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c := &MapConfig{
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sizeHint: defaultMinMapTableLen * entriesPerMapOfBucket,
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}
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for _, o := range options {
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o(c)
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}
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m := &MapOf[K, V]{}
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m.resizeCond = *sync.NewCond(&m.resizeMu)
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m.hasher = hasher
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var table *mapOfTable[K, V]
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if c.sizeHint <= defaultMinMapTableLen*entriesPerMapOfBucket {
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table = newMapOfTable[K, V](defaultMinMapTableLen)
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} else {
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tableLen := nextPowOf2(uint32((float64(c.sizeHint) / entriesPerMapOfBucket) / mapLoadFactor))
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table = newMapOfTable[K, V](int(tableLen))
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}
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m.minTableLen = len(table.buckets)
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m.growOnly = c.growOnly
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atomic.StorePointer(&m.table, unsafe.Pointer(table))
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return m
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}
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// NewMapOfPresized creates a new MapOf instance with capacity enough
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// to hold sizeHint entries. The capacity is treated as the minimal capacity
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// meaning that the underlying hash table will never shrink to
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// a smaller capacity. If sizeHint is zero or negative, the value
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// is ignored.
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//
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// Deprecated: use NewMapOf in combination with WithPresize.
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func NewMapOfPresized[K comparable, V any](sizeHint int) *MapOf[K, V] {
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return NewMapOf[K, V](WithPresize(sizeHint))
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}
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func newMapOfTable[K comparable, V any](minTableLen int) *mapOfTable[K, V] {
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buckets := make([]bucketOfPadded, minTableLen)
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for i := range buckets {
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buckets[i].meta = defaultMeta
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}
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counterLen := minTableLen >> 10
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if counterLen < minMapCounterLen {
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counterLen = minMapCounterLen
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} else if counterLen > maxMapCounterLen {
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counterLen = maxMapCounterLen
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}
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counter := make([]counterStripe, counterLen)
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t := &mapOfTable[K, V]{
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buckets: buckets,
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size: counter,
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seed: makeSeed(),
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}
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return t
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}
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// Load returns the value stored in the map for a key, or zero value
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// of type V if no value is present.
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// The ok result indicates whether value was found in the map.
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func (m *MapOf[K, V]) Load(key K) (value V, ok bool) {
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table := (*mapOfTable[K, V])(atomic.LoadPointer(&m.table))
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hash := m.hasher(key, table.seed)
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h1 := h1(hash)
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h2w := broadcast(h2(hash))
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bidx := uint64(len(table.buckets)-1) & h1
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b := &table.buckets[bidx]
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for {
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metaw := atomic.LoadUint64(&b.meta)
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markedw := markZeroBytes(metaw^h2w) & metaMask
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for markedw != 0 {
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idx := firstMarkedByteIndex(markedw)
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eptr := atomic.LoadPointer(&b.entries[idx])
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if eptr != nil {
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e := (*entryOf[K, V])(eptr)
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if e.key == key {
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return e.value, true
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}
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}
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markedw &= markedw - 1
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}
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bptr := atomic.LoadPointer(&b.next)
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if bptr == nil {
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return
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}
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b = (*bucketOfPadded)(bptr)
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}
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}
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// Store sets the value for a key.
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func (m *MapOf[K, V]) Store(key K, value V) {
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m.doCompute(
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key,
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func(V, bool) (V, bool) {
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return value, false
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},
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false,
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false,
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)
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}
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// LoadOrStore returns the existing value for the key if present.
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// Otherwise, it stores and returns the given value.
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// The loaded result is true if the value was loaded, false if stored.
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func (m *MapOf[K, V]) LoadOrStore(key K, value V) (actual V, loaded bool) {
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return m.doCompute(
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key,
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func(V, bool) (V, bool) {
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return value, false
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},
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true,
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false,
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)
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}
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// LoadAndStore returns the existing value for the key if present,
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// while setting the new value for the key.
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// It stores the new value and returns the existing one, if present.
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// The loaded result is true if the existing value was loaded,
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// false otherwise.
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func (m *MapOf[K, V]) LoadAndStore(key K, value V) (actual V, loaded bool) {
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return m.doCompute(
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key,
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func(V, bool) (V, bool) {
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return value, false
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},
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false,
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false,
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)
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}
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// LoadOrCompute returns the existing value for the key if present.
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// Otherwise, it computes the value using the provided function and
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// returns the computed value. The loaded result is true if the value
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// was loaded, false if stored.
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//
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// This call locks a hash table bucket while the compute function
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// is executed. It means that modifications on other entries in
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// the bucket will be blocked until the valueFn executes. Consider
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// this when the function includes long-running operations.
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func (m *MapOf[K, V]) LoadOrCompute(key K, valueFn func() V) (actual V, loaded bool) {
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return m.doCompute(
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key,
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func(V, bool) (V, bool) {
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return valueFn(), false
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},
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true,
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false,
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)
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}
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// Compute either sets the computed new value for the key or deletes
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// the value for the key. When the delete result of the valueFn function
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// is set to true, the value will be deleted, if it exists. When delete
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// is set to false, the value is updated to the newValue.
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// The ok result indicates whether value was computed and stored, thus, is
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// present in the map. The actual result contains the new value in cases where
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// the value was computed and stored. See the example for a few use cases.
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//
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// This call locks a hash table bucket while the compute function
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// is executed. It means that modifications on other entries in
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// the bucket will be blocked until the valueFn executes. Consider
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// this when the function includes long-running operations.
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func (m *MapOf[K, V]) Compute(
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key K,
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valueFn func(oldValue V, loaded bool) (newValue V, delete bool),
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) (actual V, ok bool) {
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return m.doCompute(key, valueFn, false, true)
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}
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// LoadAndDelete deletes the value for a key, returning the previous
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// value if any. The loaded result reports whether the key was
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// present.
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func (m *MapOf[K, V]) LoadAndDelete(key K) (value V, loaded bool) {
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return m.doCompute(
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key,
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func(value V, loaded bool) (V, bool) {
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return value, true
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},
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false,
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false,
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)
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}
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// Delete deletes the value for a key.
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func (m *MapOf[K, V]) Delete(key K) {
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m.doCompute(
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key,
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func(value V, loaded bool) (V, bool) {
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return value, true
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},
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false,
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false,
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)
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}
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func (m *MapOf[K, V]) doCompute(
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key K,
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valueFn func(oldValue V, loaded bool) (V, bool),
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loadIfExists, computeOnly bool,
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) (V, bool) {
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// Read-only path.
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if loadIfExists {
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if v, ok := m.Load(key); ok {
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return v, !computeOnly
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}
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}
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// Write path.
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for {
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compute_attempt:
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var (
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emptyb *bucketOfPadded
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emptyidx int
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)
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table := (*mapOfTable[K, V])(atomic.LoadPointer(&m.table))
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tableLen := len(table.buckets)
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hash := m.hasher(key, table.seed)
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h1 := h1(hash)
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h2 := h2(hash)
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h2w := broadcast(h2)
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bidx := uint64(len(table.buckets)-1) & h1
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rootb := &table.buckets[bidx]
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rootb.mu.Lock()
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// The following two checks must go in reverse to what's
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// in the resize method.
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if m.resizeInProgress() {
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// Resize is in progress. Wait, then go for another attempt.
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rootb.mu.Unlock()
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m.waitForResize()
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goto compute_attempt
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}
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if m.newerTableExists(table) {
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// Someone resized the table. Go for another attempt.
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rootb.mu.Unlock()
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goto compute_attempt
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}
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b := rootb
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for {
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metaw := b.meta
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markedw := markZeroBytes(metaw^h2w) & metaMask
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for markedw != 0 {
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idx := firstMarkedByteIndex(markedw)
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eptr := b.entries[idx]
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if eptr != nil {
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e := (*entryOf[K, V])(eptr)
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if e.key == key {
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if loadIfExists {
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rootb.mu.Unlock()
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return e.value, !computeOnly
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}
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// In-place update/delete.
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// We get a copy of the value via an interface{} on each call,
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// thus the live value pointers are unique. Otherwise atomic
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// snapshot won't be correct in case of multiple Store calls
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// using the same value.
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oldv := e.value
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newv, del := valueFn(oldv, true)
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if del {
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// Deletion.
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// First we update the hash, then the entry.
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newmetaw := setByte(metaw, emptyMetaSlot, idx)
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atomic.StoreUint64(&b.meta, newmetaw)
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atomic.StorePointer(&b.entries[idx], nil)
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rootb.mu.Unlock()
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table.addSize(bidx, -1)
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// Might need to shrink the table if we left bucket empty.
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if newmetaw == defaultMeta {
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m.resize(table, mapShrinkHint)
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}
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return oldv, !computeOnly
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}
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newe := new(entryOf[K, V])
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newe.key = key
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newe.value = newv
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atomic.StorePointer(&b.entries[idx], unsafe.Pointer(newe))
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rootb.mu.Unlock()
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if computeOnly {
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// Compute expects the new value to be returned.
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return newv, true
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}
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// LoadAndStore expects the old value to be returned.
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return oldv, true
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}
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}
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markedw &= markedw - 1
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}
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if emptyb == nil {
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// Search for empty entries (up to 5 per bucket).
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emptyw := metaw & defaultMetaMasked
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if emptyw != 0 {
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idx := firstMarkedByteIndex(emptyw)
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emptyb = b
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emptyidx = idx
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}
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}
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if b.next == nil {
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if emptyb != nil {
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// Insertion into an existing bucket.
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var zeroedV V
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newValue, del := valueFn(zeroedV, false)
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if del {
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rootb.mu.Unlock()
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return zeroedV, false
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}
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newe := new(entryOf[K, V])
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newe.key = key
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newe.value = newValue
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// First we update meta, then the entry.
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atomic.StoreUint64(&emptyb.meta, setByte(emptyb.meta, h2, emptyidx))
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atomic.StorePointer(&emptyb.entries[emptyidx], unsafe.Pointer(newe))
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rootb.mu.Unlock()
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table.addSize(bidx, 1)
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return newValue, computeOnly
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}
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growThreshold := float64(tableLen) * entriesPerMapOfBucket * mapLoadFactor
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if table.sumSize() > int64(growThreshold) {
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// Need to grow the table. Then go for another attempt.
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rootb.mu.Unlock()
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m.resize(table, mapGrowHint)
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goto compute_attempt
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}
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// Insertion into a new bucket.
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var zeroedV V
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newValue, del := valueFn(zeroedV, false)
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if del {
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rootb.mu.Unlock()
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return newValue, false
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}
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// Create and append a bucket.
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newb := new(bucketOfPadded)
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newb.meta = setByte(defaultMeta, h2, 0)
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newe := new(entryOf[K, V])
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newe.key = key
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newe.value = newValue
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newb.entries[0] = unsafe.Pointer(newe)
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atomic.StorePointer(&b.next, unsafe.Pointer(newb))
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rootb.mu.Unlock()
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table.addSize(bidx, 1)
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return newValue, computeOnly
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}
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b = (*bucketOfPadded)(b.next)
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}
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}
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}
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func (m *MapOf[K, V]) newerTableExists(table *mapOfTable[K, V]) bool {
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curTablePtr := atomic.LoadPointer(&m.table)
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return uintptr(curTablePtr) != uintptr(unsafe.Pointer(table))
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}
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func (m *MapOf[K, V]) resizeInProgress() bool {
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return atomic.LoadInt64(&m.resizing) == 1
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}
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func (m *MapOf[K, V]) waitForResize() {
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m.resizeMu.Lock()
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for m.resizeInProgress() {
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m.resizeCond.Wait()
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}
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m.resizeMu.Unlock()
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}
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func (m *MapOf[K, V]) resize(knownTable *mapOfTable[K, V], hint mapResizeHint) {
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knownTableLen := len(knownTable.buckets)
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// Fast path for shrink attempts.
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if hint == mapShrinkHint {
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if m.growOnly ||
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m.minTableLen == knownTableLen ||
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knownTable.sumSize() > int64((knownTableLen*entriesPerMapOfBucket)/mapShrinkFraction) {
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return
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}
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}
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// Slow path.
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if !atomic.CompareAndSwapInt64(&m.resizing, 0, 1) {
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// Someone else started resize. Wait for it to finish.
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m.waitForResize()
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return
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}
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var newTable *mapOfTable[K, V]
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table := (*mapOfTable[K, V])(atomic.LoadPointer(&m.table))
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tableLen := len(table.buckets)
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switch hint {
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case mapGrowHint:
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// Grow the table with factor of 2.
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atomic.AddInt64(&m.totalGrowths, 1)
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newTable = newMapOfTable[K, V](tableLen << 1)
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case mapShrinkHint:
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shrinkThreshold := int64((tableLen * entriesPerMapOfBucket) / mapShrinkFraction)
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if tableLen > m.minTableLen && table.sumSize() <= shrinkThreshold {
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// Shrink the table with factor of 2.
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atomic.AddInt64(&m.totalShrinks, 1)
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newTable = newMapOfTable[K, V](tableLen >> 1)
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} else {
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// No need to shrink. Wake up all waiters and give up.
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m.resizeMu.Lock()
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atomic.StoreInt64(&m.resizing, 0)
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m.resizeCond.Broadcast()
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m.resizeMu.Unlock()
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return
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}
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case mapClearHint:
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newTable = newMapOfTable[K, V](m.minTableLen)
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default:
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panic(fmt.Sprintf("unexpected resize hint: %d", hint))
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}
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// Copy the data only if we're not clearing the map.
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if hint != mapClearHint {
|
|
for i := 0; i < tableLen; i++ {
|
|
copied := copyBucketOf(&table.buckets[i], newTable, m.hasher)
|
|
newTable.addSizePlain(uint64(i), copied)
|
|
}
|
|
}
|
|
// Publish the new table and wake up all waiters.
|
|
atomic.StorePointer(&m.table, unsafe.Pointer(newTable))
|
|
m.resizeMu.Lock()
|
|
atomic.StoreInt64(&m.resizing, 0)
|
|
m.resizeCond.Broadcast()
|
|
m.resizeMu.Unlock()
|
|
}
|
|
|
|
func copyBucketOf[K comparable, V any](
|
|
b *bucketOfPadded,
|
|
destTable *mapOfTable[K, V],
|
|
hasher func(K, uint64) uint64,
|
|
) (copied int) {
|
|
rootb := b
|
|
rootb.mu.Lock()
|
|
for {
|
|
for i := 0; i < entriesPerMapOfBucket; i++ {
|
|
if b.entries[i] != nil {
|
|
e := (*entryOf[K, V])(b.entries[i])
|
|
hash := hasher(e.key, destTable.seed)
|
|
bidx := uint64(len(destTable.buckets)-1) & h1(hash)
|
|
destb := &destTable.buckets[bidx]
|
|
appendToBucketOf(h2(hash), b.entries[i], destb)
|
|
copied++
|
|
}
|
|
}
|
|
if b.next == nil {
|
|
rootb.mu.Unlock()
|
|
return
|
|
}
|
|
b = (*bucketOfPadded)(b.next)
|
|
}
|
|
}
|
|
|
|
// 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, Range
|
|
// may reflect any mapping for that key from any point during the
|
|
// Range call.
|
|
//
|
|
// It is safe to modify the map while iterating it, including entry
|
|
// creation, modification and deletion. However, the concurrent
|
|
// modification rule apply, i.e. the changes may be not reflected
|
|
// in the subsequently iterated entries.
|
|
func (m *MapOf[K, V]) Range(f func(key K, value V) bool) {
|
|
var zeroPtr unsafe.Pointer
|
|
// Pre-allocate array big enough to fit entries for most hash tables.
|
|
bentries := make([]unsafe.Pointer, 0, 16*entriesPerMapOfBucket)
|
|
tablep := atomic.LoadPointer(&m.table)
|
|
table := *(*mapOfTable[K, V])(tablep)
|
|
for i := range table.buckets {
|
|
rootb := &table.buckets[i]
|
|
b := rootb
|
|
// Prevent concurrent modifications and copy all entries into
|
|
// the intermediate slice.
|
|
rootb.mu.Lock()
|
|
for {
|
|
for i := 0; i < entriesPerMapOfBucket; i++ {
|
|
if b.entries[i] != nil {
|
|
bentries = append(bentries, b.entries[i])
|
|
}
|
|
}
|
|
if b.next == nil {
|
|
rootb.mu.Unlock()
|
|
break
|
|
}
|
|
b = (*bucketOfPadded)(b.next)
|
|
}
|
|
// Call the function for all copied entries.
|
|
for j := range bentries {
|
|
entry := (*entryOf[K, V])(bentries[j])
|
|
if !f(entry.key, entry.value) {
|
|
return
|
|
}
|
|
// Remove the reference to avoid preventing the copied
|
|
// entries from being GCed until this method finishes.
|
|
bentries[j] = zeroPtr
|
|
}
|
|
bentries = bentries[:0]
|
|
}
|
|
}
|
|
|
|
// Clear deletes all keys and values currently stored in the map.
|
|
func (m *MapOf[K, V]) Clear() {
|
|
table := (*mapOfTable[K, V])(atomic.LoadPointer(&m.table))
|
|
m.resize(table, mapClearHint)
|
|
}
|
|
|
|
// Size returns current size of the map.
|
|
func (m *MapOf[K, V]) Size() int {
|
|
table := (*mapOfTable[K, V])(atomic.LoadPointer(&m.table))
|
|
return int(table.sumSize())
|
|
}
|
|
|
|
func appendToBucketOf(h2 uint8, entryPtr unsafe.Pointer, b *bucketOfPadded) {
|
|
for {
|
|
for i := 0; i < entriesPerMapOfBucket; i++ {
|
|
if b.entries[i] == nil {
|
|
b.meta = setByte(b.meta, h2, i)
|
|
b.entries[i] = entryPtr
|
|
return
|
|
}
|
|
}
|
|
if b.next == nil {
|
|
newb := new(bucketOfPadded)
|
|
newb.meta = setByte(defaultMeta, h2, 0)
|
|
newb.entries[0] = entryPtr
|
|
b.next = unsafe.Pointer(newb)
|
|
return
|
|
}
|
|
b = (*bucketOfPadded)(b.next)
|
|
}
|
|
}
|
|
|
|
func (table *mapOfTable[K, V]) addSize(bucketIdx uint64, delta int) {
|
|
cidx := uint64(len(table.size)-1) & bucketIdx
|
|
atomic.AddInt64(&table.size[cidx].c, int64(delta))
|
|
}
|
|
|
|
func (table *mapOfTable[K, V]) addSizePlain(bucketIdx uint64, delta int) {
|
|
cidx := uint64(len(table.size)-1) & bucketIdx
|
|
table.size[cidx].c += int64(delta)
|
|
}
|
|
|
|
func (table *mapOfTable[K, V]) sumSize() int64 {
|
|
sum := int64(0)
|
|
for i := range table.size {
|
|
sum += atomic.LoadInt64(&table.size[i].c)
|
|
}
|
|
return sum
|
|
}
|
|
|
|
func h1(h uint64) uint64 {
|
|
return h >> 7
|
|
}
|
|
|
|
func h2(h uint64) uint8 {
|
|
return uint8(h & 0x7f)
|
|
}
|
|
|
|
// Stats returns statistics for the MapOf. Just like other map
|
|
// methods, this one is thread-safe. Yet it's an O(N) operation,
|
|
// so it should be used only for diagnostics or debugging purposes.
|
|
func (m *MapOf[K, V]) Stats() MapStats {
|
|
stats := MapStats{
|
|
TotalGrowths: atomic.LoadInt64(&m.totalGrowths),
|
|
TotalShrinks: atomic.LoadInt64(&m.totalShrinks),
|
|
MinEntries: math.MaxInt32,
|
|
}
|
|
table := (*mapOfTable[K, V])(atomic.LoadPointer(&m.table))
|
|
stats.RootBuckets = len(table.buckets)
|
|
stats.Counter = int(table.sumSize())
|
|
stats.CounterLen = len(table.size)
|
|
for i := range table.buckets {
|
|
nentries := 0
|
|
b := &table.buckets[i]
|
|
stats.TotalBuckets++
|
|
for {
|
|
nentriesLocal := 0
|
|
stats.Capacity += entriesPerMapOfBucket
|
|
for i := 0; i < entriesPerMapOfBucket; i++ {
|
|
if atomic.LoadPointer(&b.entries[i]) != nil {
|
|
stats.Size++
|
|
nentriesLocal++
|
|
}
|
|
}
|
|
nentries += nentriesLocal
|
|
if nentriesLocal == 0 {
|
|
stats.EmptyBuckets++
|
|
}
|
|
if b.next == nil {
|
|
break
|
|
}
|
|
b = (*bucketOfPadded)(atomic.LoadPointer(&b.next))
|
|
stats.TotalBuckets++
|
|
}
|
|
if nentries < stats.MinEntries {
|
|
stats.MinEntries = nentries
|
|
}
|
|
if nentries > stats.MaxEntries {
|
|
stats.MaxEntries = nentries
|
|
}
|
|
}
|
|
return stats
|
|
}
|