VictoriaMetrics/lib/uint64set/uint64set.go
Aliaksandr Valialkin 2233d6ed8a lib/uint64set: store pointers to bucket16 instead of bucket16 objects in bucket32
This speeds up bucket32.addBucketAtPos() when bucket32.buckets contains big number of items,
since the copying of bucket16 pointers is much faster than the copying of bucket16 objects.

This is a cpu profile for copying bucket16 objects:

      10ms     13.43s (flat, cum) 32.01% of Total
      10ms      120ms    650:	b.b16his = append(b.b16his[:pos+1], b.b16his[pos:]...)
         .          .    651:	b.b16his[pos] = hi
         .     13.31s    652:	b.buckets = append(b.buckets[:pos+1], b.buckets[pos:]...)
         .          .    653:	b16 := &b.buckets[pos]
         .          .    654:	*b16 = bucket16{}
         .          .    655:	return b16
         .          .    656:}

This is a cpu profile for copying pointers to bucket16:

      10ms      1.14s (flat, cum)  2.19% of Total
         .      100ms    647:	b.b16his = append(b.b16his[:pos+1], b.b16his[pos:]...)
         .          .    648:	b.b16his[pos] = hi
      10ms      700ms    649:	b.buckets = append(b.buckets[:pos+1], b.buckets[pos:]...)
         .      330ms    650:	b16 := &bucket16{}
         .          .    651:	b.buckets[pos] = b16
         .          .    652:	return b16
         .          .    653:}
2021-05-25 14:20:52 +03:00

987 lines
19 KiB
Go

package uint64set
import (
"math/bits"
"sort"
"sync"
"sync/atomic"
"unsafe"
)
// Set is a fast set for uint64.
//
// It should work faster than map[uint64]struct{} for semi-sparse uint64 values
// such as MetricIDs generated by lib/storage.
//
// It is unsafe calling Set methods from concurrent goroutines.
type Set struct {
itemsCount int
buckets bucket32Sorter
// Most likely the buckets contains only a single item, so put it here for performance reasons
// in order to improve memory locality.
scratchBuckets [1]bucket32
}
type bucket32Sorter []bucket32
func (s *bucket32Sorter) Len() int { return len(*s) }
func (s *bucket32Sorter) Less(i, j int) bool {
a := *s
return a[i].hi < a[j].hi
}
func (s *bucket32Sorter) Swap(i, j int) {
a := *s
a[i], a[j] = a[j], a[i]
}
// Clone returns an independent copy of s.
func (s *Set) Clone() *Set {
if s == nil || s.itemsCount == 0 {
// Return an empty set, so data could be added into it later.
return &Set{}
}
var dst Set
dst.itemsCount = s.itemsCount
if len(s.buckets) == 1 {
dst.buckets = dst.scratchBuckets[:]
} else {
dst.buckets = make([]bucket32, len(s.buckets))
}
for i := range s.buckets {
s.buckets[i].copyTo(&dst.buckets[i])
}
return &dst
}
func (s *Set) fixItemsCount() {
n := 0
for i := range s.buckets {
n += s.buckets[i].getLen()
}
s.itemsCount = n
}
func (s *Set) cloneShallow() *Set {
var dst Set
dst.itemsCount = s.itemsCount
if len(s.buckets) == 1 {
dst.buckets = dst.scratchBuckets[:]
}
dst.buckets = append(dst.buckets[:0], s.buckets...)
return &dst
}
// SizeBytes returns an estimate size of s in RAM.
func (s *Set) SizeBytes() uint64 {
if s == nil {
return 0
}
n := uint64(unsafe.Sizeof(*s))
for i := range s.buckets {
n += s.buckets[i].sizeBytes()
}
return n
}
// Len returns the number of distinct uint64 values in s.
func (s *Set) Len() int {
if s == nil {
return 0
}
return s.itemsCount
}
// Add adds x to s.
func (s *Set) Add(x uint64) {
hi32 := uint32(x >> 32)
lo32 := uint32(x)
bs := s.buckets
if len(bs) > 0 && bs[0].hi == hi32 {
// Manually inline bucket32.add for performance reasons.
hi16 := uint16(lo32 >> 16)
lo16 := uint16(lo32)
b32 := &bs[0]
his := b32.b16his
if n := b32.getHint(); n < uint32(len(his)) && his[n] == hi16 {
bs := b32.buckets
if n < uint32(len(bs)) && bs[n].add(lo16) {
s.itemsCount++
}
return
}
if b32.addSlow(hi16, lo16) {
s.itemsCount++
}
return
}
for i := range bs {
b32 := &bs[i]
if b32.hi == hi32 {
if b32.add(lo32) {
s.itemsCount++
}
return
}
}
b32 := s.addBucket32()
b32.hi = hi32
_ = b32.add(lo32)
s.itemsCount++
}
// AddMulti adds all the items from a to s.
//
// It is usually faster than calling s.Add() for each item in a.
//
// The caller is responsible for splitting a into items with clustered values.
func (s *Set) AddMulti(a []uint64) {
if len(a) == 0 {
return
}
hiPrev := uint32(a[0] >> 32)
i := 0
for j, x := range a {
hi := uint32(x >> 32)
if hi == hiPrev {
continue
}
b32 := s.getOrCreateBucket32(hiPrev)
s.itemsCount += b32.addMulti(a[i:j])
hiPrev = hi
i = j
}
b32 := s.getOrCreateBucket32(hiPrev)
s.itemsCount += b32.addMulti(a[i:])
}
func (s *Set) getOrCreateBucket32(hi uint32) *bucket32 {
bs := s.buckets
for i := range bs {
if bs[i].hi == hi {
return &bs[i]
}
}
b32 := s.addBucket32()
b32.hi = hi
return b32
}
func (s *Set) addBucket32() *bucket32 {
if len(s.buckets) == 0 {
s.buckets = s.scratchBuckets[:]
} else {
s.buckets = append(s.buckets, bucket32{})
}
return &s.buckets[len(s.buckets)-1]
}
// Has verifies whether x exists in s.
func (s *Set) Has(x uint64) bool {
if s == nil {
return false
}
hi32 := uint32(x >> 32)
lo32 := uint32(x)
bs := s.buckets
for i := range bs {
b32 := &bs[i]
if b32.hi == hi32 {
return b32.has(lo32)
}
}
return false
}
// Del deletes x from s.
func (s *Set) Del(x uint64) {
hi := uint32(x >> 32)
lo := uint32(x)
bs := s.buckets
if len(bs) > 0 && bs[0].hi == hi {
if bs[0].del(lo) {
s.itemsCount--
}
return
}
for i := range bs {
b32 := &bs[i]
if b32.hi == hi {
if b32.del(lo) {
s.itemsCount--
}
return
}
}
}
// AppendTo appends all the items from the set to dst and returns the result.
//
// The returned items are sorted.
//
// AppendTo can mutate s.
func (s *Set) AppendTo(dst []uint64) []uint64 {
if s == nil {
return dst
}
// pre-allocate memory for dst
dstLen := len(dst)
if n := s.Len() - cap(dst) + dstLen; n > 0 {
dst = append(dst[:cap(dst)], make([]uint64, n)...)
dst = dst[:dstLen]
}
s.sort()
for i := range s.buckets {
dst = s.buckets[i].appendTo(dst)
}
return dst
}
func (s *Set) sort() {
// sort s.buckets if it isn't sorted yet
if !sort.IsSorted(&s.buckets) {
sort.Sort(&s.buckets)
}
}
// Union adds all the items from a to s.
func (s *Set) Union(a *Set) {
s.union(a, false)
}
// UnionMayOwn adds all the items from a to s.
//
// It may own a if s is empty. This means that `a` cannot be used
// after the call to UnionMayOwn.
func (s *Set) UnionMayOwn(a *Set) {
s.union(a, true)
}
func (s *Set) union(a *Set, mayOwn bool) {
if a.Len() == 0 {
// Fast path - nothing to union.
return
}
if s.Len() == 0 {
// Fast path - copy `a` to `s`.
if !mayOwn {
a = a.Clone()
}
*s = *a
return
}
// Make shallow copy of `a`, since it can be modified by a.sort().
if !mayOwn {
a = a.cloneShallow()
}
a.sort()
s.sort()
i := 0
j := 0
sBucketsLen := len(s.buckets)
for {
for i < sBucketsLen && j < len(a.buckets) && s.buckets[i].hi < a.buckets[j].hi {
i++
}
if i >= sBucketsLen {
for j < len(a.buckets) {
b32 := s.addBucket32()
a.buckets[j].copyTo(b32)
j++
}
break
}
for j < len(a.buckets) && a.buckets[j].hi < s.buckets[i].hi {
b32 := s.addBucket32()
a.buckets[j].copyTo(b32)
j++
}
if j >= len(a.buckets) {
break
}
if s.buckets[i].hi == a.buckets[j].hi {
s.buckets[i].union(&a.buckets[j], mayOwn)
i++
j++
}
}
s.fixItemsCount()
}
// Intersect removes all the items missing in a from s.
func (s *Set) Intersect(a *Set) {
if s.Len() == 0 || a.Len() == 0 {
// Fast path - the result is empty.
*s = Set{}
return
}
// Make shallow copy of `a`, since it can be modified by a.sort().
a = a.cloneShallow()
a.sort()
s.sort()
i := 0
j := 0
for {
for i < len(s.buckets) && j < len(a.buckets) && s.buckets[i].hi < a.buckets[j].hi {
s.buckets[i] = bucket32{}
i++
}
if i >= len(s.buckets) {
break
}
for j < len(a.buckets) && a.buckets[j].hi < s.buckets[i].hi {
j++
}
if j >= len(a.buckets) {
for i < len(s.buckets) {
s.buckets[i] = bucket32{}
i++
}
break
}
if s.buckets[i].hi == a.buckets[j].hi {
s.buckets[i].intersect(&a.buckets[j])
i++
j++
}
}
s.fixItemsCount()
}
// Subtract removes from s all the shared items between s and a.
func (s *Set) Subtract(a *Set) {
if s.Len() == 0 || a.Len() == 0 {
// Fast path - nothing to subtract.
return
}
a.ForEach(func(part []uint64) bool {
for _, x := range part {
s.Del(x)
}
return true
})
}
// Equal returns true if s contains the same items as a.
func (s *Set) Equal(a *Set) bool {
if s.Len() != a.Len() {
return false
}
equal := true
a.ForEach(func(part []uint64) bool {
for _, x := range part {
if !s.Has(x) {
equal = false
return false
}
}
return true
})
return equal
}
// ForEach calls f for all the items stored in s.
//
// Each call to f contains part with arbitrary part of items stored in the set.
// The iteration is stopped if f returns false.
func (s *Set) ForEach(f func(part []uint64) bool) {
if s == nil {
return
}
for i := range s.buckets {
if !s.buckets[i].forEach(f) {
return
}
}
}
type bucket32 struct {
hi uint32
// hint may contain bucket index for the last successful operation.
// This allows saving CPU time on subsequent calls to the same bucket.
hint uint32
// b16his contains high 16 bits for each bucket in buckets.
//
// It is always sorted.
b16his []uint16
// buckets are sorted by b16his
buckets []*bucket16
}
func (b *bucket32) getLen() int {
n := 0
for i := range b.buckets {
n += b.buckets[i].getLen()
}
return n
}
func (b *bucket32) union(a *bucket32, mayOwn bool) {
i := 0
j := 0
bBucketsLen := len(b.buckets)
for {
for i < bBucketsLen && j < len(a.b16his) && b.b16his[i] < a.b16his[j] {
i++
}
if i >= bBucketsLen {
for j < len(a.b16his) {
b16 := b.addBucket16(a.b16his[j])
if mayOwn {
*b16 = *a.buckets[j]
} else {
a.buckets[j].copyTo(b16)
}
j++
}
break
}
for j < len(a.b16his) && a.b16his[j] < b.b16his[i] {
b16 := b.addBucket16(a.b16his[j])
if mayOwn {
*b16 = *a.buckets[j]
} else {
a.buckets[j].copyTo(b16)
}
j++
}
if j >= len(a.b16his) {
break
}
if b.b16his[i] == a.b16his[j] {
b.buckets[i].union(a.buckets[j])
i++
j++
}
}
// Restore buckets order, which could be violated during the merge above.
if !sort.IsSorted(b) {
sort.Sort(b)
}
}
// This is for sort.Interface used in bucket32.union
func (b *bucket32) Len() int { return len(b.b16his) }
func (b *bucket32) Less(i, j int) bool { return b.b16his[i] < b.b16his[j] }
func (b *bucket32) Swap(i, j int) {
his := b.b16his
buckets := b.buckets
his[i], his[j] = his[j], his[i]
buckets[i], buckets[j] = buckets[j], buckets[i]
}
func (b *bucket32) intersect(a *bucket32) {
i := 0
j := 0
for {
for i < len(b.b16his) && j < len(a.b16his) && b.b16his[i] < a.b16his[j] {
*b.buckets[i] = bucket16{}
i++
}
if i >= len(b.b16his) {
break
}
for j < len(a.b16his) && a.b16his[j] < b.b16his[i] {
j++
}
if j >= len(a.b16his) {
for i < len(b.b16his) {
*b.buckets[i] = bucket16{}
i++
}
break
}
if b.b16his[i] == a.b16his[j] {
b.buckets[i].intersect(a.buckets[j])
i++
j++
}
}
// Remove zero buckets
b16his := b.b16his[:0]
bs := b.buckets[:0]
for i, b16 := range b.buckets {
if b16.isZero() {
continue
}
b16his = append(b16his, b.b16his[i])
bs = append(bs, b16)
}
for i := len(bs); i < len(b.buckets); i++ {
b.buckets[i] = nil
}
b.hint = 0
b.b16his = b16his
b.buckets = bs
}
func (b *bucket32) forEach(f func(part []uint64) bool) bool {
xbuf := partBufPool.Get().(*[]uint64)
buf := *xbuf
for i, b16 := range b.buckets {
hi16 := b.b16his[i]
buf = b16.appendTo(buf[:0], b.hi, hi16)
if !f(buf) {
return false
}
}
*xbuf = buf
partBufPool.Put(xbuf)
return true
}
var partBufPool = &sync.Pool{
New: func() interface{} {
buf := make([]uint64, 0, bitsPerBucket)
return &buf
},
}
func (b *bucket32) sizeBytes() uint64 {
n := uint64(unsafe.Sizeof(*b))
n += 2 * uint64(len(b.b16his))
for _, b16 := range b.buckets {
n += b16.sizeBytes()
}
return n
}
func (b *bucket32) copyTo(dst *bucket32) {
dst.hi = b.hi
dst.b16his = append(dst.b16his[:0], b.b16his...)
// Do not reuse dst.buckets, since it may be used in other places.
dst.buckets = nil
if len(b.buckets) > 0 {
dst.buckets = make([]*bucket16, len(b.buckets))
for i, b16 := range b.buckets {
b16Dst := &bucket16{}
b16.copyTo(b16Dst)
dst.buckets[i] = b16Dst
}
}
}
func (b *bucket32) getHint() uint32 {
return atomic.LoadUint32(&b.hint)
}
func (b *bucket32) setHint(n int) {
atomic.StoreUint32(&b.hint, uint32(n))
}
func (b *bucket32) add(x uint32) bool {
hi := uint16(x >> 16)
lo := uint16(x)
his := b.b16his
if n := b.getHint(); n < uint32(len(his)) && his[n] == hi {
// Fast path - add to the previously used bucket.
bs := b.buckets
return n < uint32(len(bs)) && bs[n].add(lo)
}
return b.addSlow(hi, lo)
}
func (b *bucket32) addMulti(a []uint64) int {
if len(a) == 0 {
return 0
}
count := 0
hiPrev := uint16(a[0] >> 16)
i := 0
for j, x := range a {
hi := uint16(x >> 16)
if hi == hiPrev {
continue
}
b16 := b.getOrCreateBucket16(hiPrev)
count += b16.addMulti(a[i:j])
hiPrev = hi
i = j
}
b16 := b.getOrCreateBucket16(hiPrev)
count += b16.addMulti(a[i:])
return count
}
func (b *bucket32) getOrCreateBucket16(hi uint16) *bucket16 {
his := b.b16his
bs := b.buckets
n := binarySearch16(his, hi)
if n < 0 || n >= len(his) || his[n] != hi {
return b.addBucketAtPos(hi, n)
}
return bs[n]
}
func (b *bucket32) addSlow(hi, lo uint16) bool {
his := b.b16his
n := binarySearch16(his, hi)
if n < 0 || n >= len(his) || his[n] != hi {
b16 := b.addBucketAtPos(hi, n)
b16.add(lo)
return true
}
b.setHint(n)
bs := b.buckets
return n < len(bs) && bs[n].add(lo)
}
func (b *bucket32) addBucket16(hi uint16) *bucket16 {
b.b16his = append(b.b16his, hi)
b.buckets = append(b.buckets, &bucket16{})
return b.buckets[len(b.buckets)-1]
}
func (b *bucket32) addBucketAtPos(hi uint16, pos int) *bucket16 {
if pos < 0 {
// This is a hint to Go compiler to remove automatic bounds checks below.
return nil
}
if pos >= len(b.b16his) {
return b.addBucket16(hi)
}
b.b16his = append(b.b16his[:pos+1], b.b16his[pos:]...)
b.b16his[pos] = hi
b.buckets = append(b.buckets[:pos+1], b.buckets[pos:]...)
b16 := &bucket16{}
b.buckets[pos] = b16
return b16
}
func (b *bucket32) has(x uint32) bool {
hi := uint16(x >> 16)
lo := uint16(x)
his := b.b16his
n := binarySearch16(his, hi)
if n < 0 || n >= len(his) || his[n] != hi {
return false
}
// Do not call b.setHint(n) here, since this may trash performance
// when many concurrent goroutines call b.has() method from many CPU cores.
bs := b.buckets
return n < len(bs) && bs[n].has(lo)
}
func (b *bucket32) del(x uint32) bool {
hi := uint16(x >> 16)
lo := uint16(x)
his := b.b16his
if n := b.getHint(); n < uint32(len(his)) && his[n] == hi {
// Fast path - use the bucket from the previous operation.
bs := b.buckets
return n < uint32(len(bs)) && bs[n].del(lo)
}
return b.delSlow(hi, lo)
}
func (b *bucket32) delSlow(hi, lo uint16) bool {
his := b.b16his
n := binarySearch16(his, hi)
if n < 0 || n >= len(his) || his[n] != hi {
return false
}
b.setHint(n)
bs := b.buckets
return n < len(bs) && bs[n].del(lo)
}
func (b *bucket32) appendTo(dst []uint64) []uint64 {
for i := range b.buckets {
hi16 := b.b16his[i]
dst = b.buckets[i].appendTo(dst, b.hi, hi16)
}
return dst
}
const (
bitsPerBucket = 1 << 16
wordsPerBucket = bitsPerBucket / 64
)
type bucket16 struct {
bits *[wordsPerBucket]uint64
smallPool [smallPoolSize]uint16
smallPoolLen int
}
const smallPoolSize = 56
func (b *bucket16) isZero() bool {
return b.bits == nil && b.smallPoolLen == 0
}
func (b *bucket16) getLen() int {
if b.bits == nil {
return b.smallPoolLen
}
n := 0
for _, x := range b.bits {
if x > 0 {
n += bits.OnesCount64(x)
}
}
return n
}
func (b *bucket16) union(a *bucket16) {
if a.bits != nil && b.bits != nil {
// Fast path - use bitwise ops.
ab := a.bits
bb := b.bits
_ = bb[len(ab)-1]
for i, ax := range ab {
bx := bb[i]
bx |= ax
bb[i] = bx
}
return
}
// Slow path
xbuf := partBufPool.Get().(*[]uint64)
buf := *xbuf
buf = a.appendTo(buf[:0], 0, 0)
for _, x := range buf {
x16 := uint16(x)
b.add(x16)
}
*xbuf = buf
partBufPool.Put(xbuf)
}
func (b *bucket16) intersect(a *bucket16) {
if a.bits != nil && b.bits != nil {
// Fast path - use bitwise ops
ab := a.bits
bb := b.bits
_ = bb[len(ab)-1]
for i, ax := range ab {
bx := bb[i]
bx &= ax
bb[i] = bx
}
return
}
// Slow path
xbuf := partBufPool.Get().(*[]uint64)
buf := *xbuf
buf = b.appendTo(buf[:0], 0, 0)
for _, x := range buf {
x16 := uint16(x)
if !a.has(x16) {
b.del(x16)
}
}
*xbuf = buf
partBufPool.Put(xbuf)
}
func (b *bucket16) sizeBytes() uint64 {
n := unsafe.Sizeof(*b)
if b.bits != nil {
n += unsafe.Sizeof(*b.bits)
}
return uint64(n)
}
func (b *bucket16) copyTo(dst *bucket16) {
// Do not reuse dst.bits, since it may be used in other places.
dst.bits = nil
if b.bits != nil {
bits := *b.bits
dst.bits = &bits
}
dst.smallPool = b.smallPool
dst.smallPoolLen = b.smallPoolLen
}
func (b *bucket16) add(x uint16) bool {
bits := b.bits
if bits == nil {
return b.addToSmallPool(x)
}
wordNum, bitMask := getWordNumBitMask(x)
ok := bits[wordNum]&bitMask == 0
if ok {
bits[wordNum] |= bitMask
}
return ok
}
func (b *bucket16) addMulti(a []uint64) int {
count := 0
if b.bits == nil {
// Slow path
for i, x := range a {
if b.add(uint16(x)) {
count++
}
if b.bits != nil {
a = a[i+1:]
goto fastPath
}
}
return count
}
fastPath:
bits := b.bits
for _, x := range a {
wordNum, bitMask := getWordNumBitMask(uint16(x))
if bits[wordNum]&bitMask == 0 {
bits[wordNum] |= bitMask
count++
}
}
return count
}
func (b *bucket16) addToSmallPool(x uint16) bool {
if b.hasInSmallPool(x) {
return false
}
sp := b.smallPool[:]
if b.smallPoolLen < len(sp) {
sp[b.smallPoolLen] = x
b.smallPoolLen++
return true
}
b.smallPoolLen = 0
var bits [wordsPerBucket]uint64
b.bits = &bits
for _, v := range sp[:] {
b.add(v)
}
b.add(x)
return true
}
func (b *bucket16) has(x uint16) bool {
if b.bits == nil {
return b.hasInSmallPool(x)
}
wordNum, bitMask := getWordNumBitMask(x)
return b.bits[wordNum]&bitMask != 0
}
func (b *bucket16) hasInSmallPool(x uint16) bool {
for _, v := range b.smallPool[:b.smallPoolLen] {
if v == x {
return true
}
}
return false
}
func (b *bucket16) del(x uint16) bool {
if b.bits == nil {
return b.delFromSmallPool(x)
}
wordNum, bitMask := getWordNumBitMask(x)
word := &b.bits[wordNum]
ok := *word&bitMask != 0
*word &^= bitMask
return ok
}
func (b *bucket16) delFromSmallPool(x uint16) bool {
sp := b.smallPool[:]
for i, v := range sp[:b.smallPoolLen] {
if v == x {
copy(sp[i:], sp[i+1:])
b.smallPoolLen--
return true
}
}
return false
}
func (b *bucket16) appendTo(dst []uint64, hi uint32, hi16 uint16) []uint64 {
hi64 := uint64(hi)<<32 | uint64(hi16)<<16
if b.bits == nil {
// Use smallPoolSorter instead of sort.Slice here in order to reduce memory allocations.
sps := smallPoolSorterPool.Get().(*smallPoolSorter)
// Sort a copy of b.smallPool, since b must be readonly in order to prevent from data races
// when b.appendTo is called from concurrent goroutines.
sps.smallPool = b.smallPool
sps.a = sps.smallPool[:b.smallPoolLen]
if len(sps.a) > 1 && !sort.IsSorted(sps) {
sort.Sort(sps)
}
for _, v := range sps.a {
x := hi64 | uint64(v)
dst = append(dst, x)
}
smallPoolSorterPool.Put(sps)
return dst
}
var wordNum uint64
for _, word := range b.bits {
if word == 0 {
wordNum++
continue
}
x64 := hi64 | (wordNum * 64)
for {
tzn := uint64(bits.TrailingZeros64(word))
if tzn >= 64 {
break
}
word &^= uint64(1) << tzn
x := x64 | tzn
dst = append(dst, x)
}
wordNum++
}
return dst
}
var smallPoolSorterPool = &sync.Pool{
New: func() interface{} {
return &smallPoolSorter{}
},
}
type smallPoolSorter struct {
smallPool [smallPoolSize]uint16
a []uint16
}
func (sps *smallPoolSorter) Len() int { return len(sps.a) }
func (sps *smallPoolSorter) Less(i, j int) bool {
a := sps.a
return a[i] < a[j]
}
func (sps *smallPoolSorter) Swap(i, j int) {
a := sps.a
a[i], a[j] = a[j], a[i]
}
func getWordNumBitMask(x uint16) (uint16, uint64) {
wordNum := x / 64
bitMask := uint64(1) << (x & 63)
return wordNum, bitMask
}
func binarySearch16(u16 []uint16, x uint16) int {
// The code has been adapted from sort.Search.
n := len(u16)
if n > 0 && u16[n-1] < x {
// Fast path for values scanned in ascending order.
return n
}
i, j := 0, n
for i < j {
h := int(uint(i+j) >> 1)
if h >= 0 && h < len(u16) && u16[h] < x {
i = h + 1
} else {
j = h
}
}
return i
}