zolfa
/
tendermint


								package bitarray


								import (

									"bytes"

									"encoding/binary"

									"errors"

									"fmt"

									"regexp"

									"strings"

								)


								// CompactBitArray is an implementation of a space efficient bit array.

								// This is used to ensure that the encoded data takes up a minimal amount of

								// space after amino encoding.

								// This is not thread safe, and is not intended for concurrent usage.

								type CompactBitArray struct {

									ExtraBitsStored byte   `json:"extra_bits"` // The number of extra bits in elems.

									Elems           []byte `json:"bits"`

								}


								// NewCompactBitArray returns a new compact bit array.

								// It returns nil if the number of bits is zero.

								func NewCompactBitArray(bits int) *CompactBitArray {

									if bits <= 0 {

										return nil

									}

									return &CompactBitArray{

										ExtraBitsStored: byte(bits % 8),

										Elems:           make([]byte, (bits+7)/8),

									}

								}


								// Size returns the number of bits in the bitarray

								func (bA *CompactBitArray) Size() int {

									if bA == nil {

										return 0

									} else if bA.ExtraBitsStored == byte(0) {

										return len(bA.Elems) * 8

									}

									// num_bits = 8*num_full_bytes + overflow_in_last_byte

									// num_full_bytes = (len(bA.Elems)-1)

									return (len(bA.Elems)-1)*8 + int(bA.ExtraBitsStored)

								}


								// GetIndex returns the bit at index i within the bit array.

								// The behavior is undefined if i >= bA.Size()

								func (bA *CompactBitArray) GetIndex(i int) bool {

									if bA == nil {

										return false

									}

									if i >= bA.Size() {

										return false

									}

									return bA.Elems[i>>3]&(uint8(1)<<uint8(7-(i%8))) > 0

								}


								// SetIndex sets the bit at index i within the bit array.

								// The behavior is undefined if i >= bA.Size()

								func (bA *CompactBitArray) SetIndex(i int, v bool) bool {

									if bA == nil {

										return false

									}

									if i >= bA.Size() {

										return false

									}

									if v {

										bA.Elems[i>>3] |= (uint8(1) << uint8(7-(i%8)))

									} else {

										bA.Elems[i>>3] &= ^(uint8(1) << uint8(7-(i%8)))

									}

									return true

								}


								// NumTrueBitsBefore returns the number of bits set to true before the

								// given index. e.g. if bA = _XX__XX, NumOfTrueBitsBefore(4) = 2, since

								// there are two bits set to true before index 4.

								func (bA *CompactBitArray) NumTrueBitsBefore(index int) int {

									numTrueValues := 0

									for i := 0; i < index; i++ {

										if bA.GetIndex(i) {

											numTrueValues++

										}

									}

									return numTrueValues

								}


								// Copy returns a copy of the provided bit array.

								func (bA *CompactBitArray) Copy() *CompactBitArray {

									if bA == nil {

										return nil

									}

									c := make([]byte, len(bA.Elems))

									copy(c, bA.Elems)

									return &CompactBitArray{

										ExtraBitsStored: bA.ExtraBitsStored,

										Elems:           c,

									}

								}


								// String returns a string representation of CompactBitArray: BA{<bit-string>},

								// where <bit-string> is a sequence of 'x' (1) and '_' (0).

								// The <bit-string> includes spaces and newlines to help people.

								// For a simple sequence of 'x' and '_' characters with no spaces or newlines,

								// see the MarshalJSON() method.

								// Example: "BA{_x_}" or "nil-BitArray" for nil.

								func (bA *CompactBitArray) String() string {

									return bA.StringIndented("")

								}


								// StringIndented returns the same thing as String(), but applies the indent

								// at every 10th bit, and twice at every 50th bit.

								func (bA *CompactBitArray) StringIndented(indent string) string {

									if bA == nil {

										return "nil-BitArray"

									}

									lines := []string{}

									bits := ""

									size := bA.Size()

									for i := 0; i < size; i++ {

										if bA.GetIndex(i) {

											bits += "x"

										} else {

											bits += "_"

										}

										if i%100 == 99 {

											lines = append(lines, bits)

											bits = ""

										}

										if i%10 == 9 {

											bits += indent

										}

										if i%50 == 49 {

											bits += indent

										}

									}

									if len(bits) > 0 {

										lines = append(lines, bits)

									}

									return fmt.Sprintf("BA{%v:%v}", size, strings.Join(lines, indent))

								}


								// MarshalJSON implements json.Marshaler interface by marshaling bit array

								// using a custom format: a string of '-' or 'x' where 'x' denotes the 1 bit.

								func (bA *CompactBitArray) MarshalJSON() ([]byte, error) {

									if bA == nil {

										return []byte("null"), nil

									}


									bits := `"`

									size := bA.Size()

									for i := 0; i < size; i++ {

										if bA.GetIndex(i) {

											bits += `x`

										} else {

											bits += `_`

										}

									}

									bits += `"`

									return []byte(bits), nil

								}


								var bitArrayJSONRegexp = regexp.MustCompile(`\A"([_x]*)"\z`)


								// UnmarshalJSON implements json.Unmarshaler interface by unmarshaling a custom

								// JSON description.

								func (bA *CompactBitArray) UnmarshalJSON(bz []byte) error {

									b := string(bz)

									if b == "null" {

										// This is required e.g. for encoding/json when decoding

										// into a pointer with pre-allocated BitArray.

										bA.ExtraBitsStored = 0

										bA.Elems = nil

										return nil

									}


									// Validate 'b'.

									match := bitArrayJSONRegexp.FindStringSubmatch(b)

									if match == nil {

										return fmt.Errorf("bitArray in JSON should be a string of format %q but got %s", bitArrayJSONRegexp.String(), b)

									}

									bits := match[1]


									// Construct new CompactBitArray and copy over.

									numBits := len(bits)

									bA2 := NewCompactBitArray(numBits)

									for i := 0; i < numBits; i++ {

										if bits[i] == 'x' {

											bA2.SetIndex(i, true)

										}

									}

									*bA = *bA2

									return nil

								}


								// CompactMarshal is a space efficient encoding for CompactBitArray.

								// It is not amino compatible.

								func (bA *CompactBitArray) CompactMarshal() []byte {

									size := bA.Size()

									if size <= 0 {

										return []byte("null")

									}

									bz := make([]byte, 0, size/8)

									// length prefix number of bits, not number of bytes. This difference

									// takes 3-4 bits in encoding, as opposed to instead encoding the number of

									// bytes (saving 3-4 bits) and including the offset as a full byte.

									bz = appendUvarint(bz, uint64(size))

									bz = append(bz, bA.Elems...)

									return bz

								}


								// CompactUnmarshal is a space efficient decoding for CompactBitArray.

								// It is not amino compatible.

								func CompactUnmarshal(bz []byte) (*CompactBitArray, error) {

									if len(bz) < 2 {

										return nil, errors.New("compact bit array: invalid compact unmarshal size")

									} else if bytes.Equal(bz, []byte("null")) {

										return NewCompactBitArray(0), nil

									}

									size, n := binary.Uvarint(bz)

									bz = bz[n:]

									if len(bz) != int(size+7)/8 {

										return nil, errors.New("compact bit array: invalid compact unmarshal size")

									}


									bA := &CompactBitArray{byte(int(size % 8)), bz}

									return bA, nil

								}


								func appendUvarint(b []byte, x uint64) []byte {

									var a [binary.MaxVarintLen64]byte

									n := binary.PutUvarint(a[:], x)

									return append(b, a[:n]...)

								}