zolfa
/
tendermint

package common
import (	"encoding/binary"	"fmt"	"math/rand"	"strings"	"sync")
type BitArray struct {	mtx   sync.Mutex	Bits  int      `json:"bits"`  // NOTE: persisted via reflect, must be exported
	Elems []uint64 `json:"elems"` // NOTE: persisted via reflect, must be exported
}
// There is no BitArray whose Size is 0.  Use nil instead.
func NewBitArray(bits int) *BitArray {	if bits == 0 {		return nil	}	return &BitArray{		Bits:  bits,		Elems: make([]uint64, (bits+63)/64),	}}
func (bA *BitArray) Size() int {	if bA == nil {		return 0	}	return bA.Bits}
// NOTE: behavior is undefined if i >= bA.Bits
func (bA *BitArray) GetIndex(i int) bool {	if bA == nil {		return false	}	bA.mtx.Lock()	defer bA.mtx.Unlock()	return bA.getIndex(i)}
func (bA *BitArray) getIndex(i int) bool {	if i >= bA.Bits {		return false	}	return bA.Elems[i/64]&(uint64(1)<<uint(i%64)) > 0}
// NOTE: behavior is undefined if i >= bA.Bits
func (bA *BitArray) SetIndex(i int, v bool) bool {	if bA == nil {		return false	}	bA.mtx.Lock()	defer bA.mtx.Unlock()	return bA.setIndex(i, v)}
func (bA *BitArray) setIndex(i int, v bool) bool {	if i >= bA.Bits {		return false	}	if v {		bA.Elems[i/64] |= (uint64(1) << uint(i%64))	} else {		bA.Elems[i/64] &= ^(uint64(1) << uint(i%64))	}	return true}
func (bA *BitArray) Copy() *BitArray {	if bA == nil {		return nil	}	bA.mtx.Lock()	defer bA.mtx.Unlock()	return bA.copy()}
func (bA *BitArray) copy() *BitArray {	c := make([]uint64, len(bA.Elems))	copy(c, bA.Elems)	return &BitArray{		Bits:  bA.Bits,		Elems: c,	}}
func (bA *BitArray) copyBits(bits int) *BitArray {	c := make([]uint64, (bits+63)/64)	copy(c, bA.Elems)	return &BitArray{		Bits:  bits,		Elems: c,	}}
// Returns a BitArray of larger bits size.
func (bA *BitArray) Or(o *BitArray) *BitArray {	if bA == nil {		o.Copy()	}	bA.mtx.Lock()	defer bA.mtx.Unlock()	c := bA.copyBits(MaxInt(bA.Bits, o.Bits))	for i := 0; i < len(c.Elems); i++ {		c.Elems[i] |= o.Elems[i]	}	return c}
// Returns a BitArray of smaller bit size.
func (bA *BitArray) And(o *BitArray) *BitArray {	if bA == nil {		return nil	}	bA.mtx.Lock()	defer bA.mtx.Unlock()	return bA.and(o)}
func (bA *BitArray) and(o *BitArray) *BitArray {	c := bA.copyBits(MinInt(bA.Bits, o.Bits))	for i := 0; i < len(c.Elems); i++ {		c.Elems[i] &= o.Elems[i]	}	return c}
func (bA *BitArray) Not() *BitArray {	if bA == nil {		return nil // Degenerate
	}	bA.mtx.Lock()	defer bA.mtx.Unlock()	c := bA.copy()	for i := 0; i < len(c.Elems); i++ {		c.Elems[i] = ^c.Elems[i]	}	return c}
func (bA *BitArray) Sub(o *BitArray) *BitArray {	if bA == nil {		return nil	}	bA.mtx.Lock()	defer bA.mtx.Unlock()	if bA.Bits > o.Bits {		c := bA.copy()		for i := 0; i < len(o.Elems)-1; i++ {			c.Elems[i] &= ^c.Elems[i]		}		i := len(o.Elems) - 1		if i >= 0 {			for idx := i * 64; idx < o.Bits; idx++ {				// NOTE: each individual GetIndex() call to o is safe.
				c.setIndex(idx, c.getIndex(idx) && !o.GetIndex(idx))			}		}		return c	} else {		return bA.and(o.Not()) // Note degenerate case where o == nil
	}}
func (bA *BitArray) IsEmpty() bool {	if bA == nil {		return true // should this be opposite?
	}	bA.mtx.Lock()	defer bA.mtx.Unlock()	for _, e := range bA.Elems {		if e > 0 {			return false		}	}	return true}
func (bA *BitArray) IsFull() bool {	if bA == nil {		return true	}	bA.mtx.Lock()	defer bA.mtx.Unlock()
	// Check all elements except the last
	for _, elem := range bA.Elems[:len(bA.Elems)-1] {		if (^elem) != 0 {			return false		}	}
	// Check that the last element has (lastElemBits) 1's
	lastElemBits := (bA.Bits+63)%64 + 1	lastElem := bA.Elems[len(bA.Elems)-1]	return (lastElem+1)&((uint64(1)<<uint(lastElemBits))-1) == 0}
func (bA *BitArray) PickRandom() (int, bool) {	if bA == nil {		return 0, false	}	bA.mtx.Lock()	defer bA.mtx.Unlock()
	length := len(bA.Elems)	if length == 0 {		return 0, false	}	randElemStart := rand.Intn(length)	for i := 0; i < length; i++ {		elemIdx := ((i + randElemStart) % length)		if elemIdx < length-1 {			if bA.Elems[elemIdx] > 0 {				randBitStart := rand.Intn(64)				for j := 0; j < 64; j++ {					bitIdx := ((j + randBitStart) % 64)					if (bA.Elems[elemIdx] & (uint64(1) << uint(bitIdx))) > 0 {						return 64*elemIdx + bitIdx, true					}				}				PanicSanity("should not happen")			}		} else {			// Special case for last elem, to ignore straggler bits
			elemBits := bA.Bits % 64			if elemBits == 0 {				elemBits = 64			}			randBitStart := rand.Intn(elemBits)			for j := 0; j < elemBits; j++ {				bitIdx := ((j + randBitStart) % elemBits)				if (bA.Elems[elemIdx] & (uint64(1) << uint(bitIdx))) > 0 {					return 64*elemIdx + bitIdx, true				}			}		}	}	return 0, false}
func (bA *BitArray) String() string {	if bA == nil {		return "nil-BitArray"	}	bA.mtx.Lock()	defer bA.mtx.Unlock()	return bA.stringIndented("")}
func (bA *BitArray) StringIndented(indent string) string {	if bA == nil {		return "nil-BitArray"	}	bA.mtx.Lock()	defer bA.mtx.Unlock()	return bA.stringIndented(indent)}
func (bA *BitArray) stringIndented(indent string) string {
	lines := []string{}	bits := ""	for i := 0; i < bA.Bits; i++ {		if bA.getIndex(i) {			bits += "X"		} else {			bits += "_"		}		if i%100 == 99 {			lines = append(lines, bits)			bits = ""		}		if i%10 == 9 {			bits += " "		}		if i%50 == 49 {			bits += " "		}	}	if len(bits) > 0 {		lines = append(lines, bits)	}	return fmt.Sprintf("BA{%v:%v}", bA.Bits, strings.Join(lines, indent))}
func (bA *BitArray) Bytes() []byte {	bA.mtx.Lock()	defer bA.mtx.Unlock()
	numBytes := (bA.Bits + 7) / 8	bytes := make([]byte, numBytes)	for i := 0; i < len(bA.Elems); i++ {		elemBytes := [8]byte{}		binary.LittleEndian.PutUint64(elemBytes[:], bA.Elems[i])		copy(bytes[i*8:], elemBytes[:])	}	return bytes}
// NOTE: other bitarray o is not locked when reading,
// so if necessary, caller must copy or lock o prior to calling Update.
// If bA is nil, does nothing.
func (bA *BitArray) Update(o *BitArray) {	if bA == nil {		return	}	bA.mtx.Lock()	defer bA.mtx.Unlock()
	copy(bA.Elems, o.Elems)}