1 files changed, 0 insertions, 931 deletions
diff --git a/vendor/github.com/willf/bitset/bitset.go b/vendor/github.com/willf/bitset/bitset.go
deleted file mode 100644
index 21e889da2..000000000
--- a/vendor/github.com/willf/bitset/bitset.go
+++ /dev/null
@@ -1,931 +0,0 @@
-/*
-Package bitset implements bitsets, a mapping
-between non-negative integers and boolean values. It should be more
-efficient than map[uint] bool.
-
-It provides methods for setting, clearing, flipping, and testing
-individual integers.
-
-But it also provides set intersection, union, difference,
-complement, and symmetric operations, as well as tests to
-check whether any, all, or no bits are set, and querying a
-bitset's current length and number of positive bits.
-
-BitSets are expanded to the size of the largest set bit; the
-memory allocation is approximately Max bits, where Max is
-the largest set bit. BitSets are never shrunk. On creation,
-a hint can be given for the number of bits that will be used.
-
-Many of the methods, including Set,Clear, and Flip, return
-a BitSet pointer, which allows for chaining.
-
-Example use:
-
-	import "bitset"
-	var b BitSet
-	b.Set(10).Set(11)
-	if b.Test(1000) {
-		b.Clear(1000)
-	}
-	if B.Intersection(bitset.New(100).Set(10)).Count() > 1 {
-		fmt.Println("Intersection works.")
-	}
-
-As an alternative to BitSets, one should check out the 'big' package,
-which provides a (less set-theoretical) view of bitsets.
-
-*/
-package bitset
-
-import (
-	"bufio"
-	"bytes"
-	"encoding/base64"
-	"encoding/binary"
-	"encoding/json"
-	"errors"
-	"fmt"
-	"io"
-	"strconv"
-)
-
-// the wordSize of a bit set
-const wordSize = uint(64)
-
-// log2WordSize is lg(wordSize)
-const log2WordSize = uint(6)
-
-// allBits has every bit set
-const allBits uint64 = 0xffffffffffffffff
-
-// default binary BigEndian
-var binaryOrder binary.ByteOrder = binary.BigEndian
-
-// default json encoding base64.URLEncoding
-var base64Encoding = base64.URLEncoding
-
-// Base64StdEncoding Marshal/Unmarshal BitSet with base64.StdEncoding(Default: base64.URLEncoding)
-func Base64StdEncoding() { base64Encoding = base64.StdEncoding }
-
-// LittleEndian Marshal/Unmarshal Binary as Little Endian(Default: binary.BigEndian)
-func LittleEndian() { binaryOrder = binary.LittleEndian }
-
-// A BitSet is a set of bits. The zero value of a BitSet is an empty set of length 0.
-type BitSet struct {
-	length uint
-	set    []uint64
-}
-
-// Error is used to distinguish errors (panics) generated in this package.
-type Error string
-
-// safeSet will fixup b.set to be non-nil and return the field value
-func (b *BitSet) safeSet() []uint64 {
-	if b.set == nil {
-		b.set = make([]uint64, wordsNeeded(0))
-	}
-	return b.set
-}
-
-// From is a constructor used to create a BitSet from an array of integers
-func From(buf []uint64) *BitSet {
-	return &BitSet{uint(len(buf)) * 64, buf}
-}
-
-// Bytes returns the bitset as array of integers
-func (b *BitSet) Bytes() []uint64 {
-	return b.set
-}
-
-// wordsNeeded calculates the number of words needed for i bits
-func wordsNeeded(i uint) int {
-	if i > (Cap() - wordSize + 1) {
-		return int(Cap() >> log2WordSize)
-	}
-	return int((i + (wordSize - 1)) >> log2WordSize)
-}
-
-// New creates a new BitSet with a hint that length bits will be required
-func New(length uint) (bset *BitSet) {
-	defer func() {
-		if r := recover(); r != nil {
-			bset = &BitSet{
-				0,
-				make([]uint64, 0),
-			}
-		}
-	}()
-
-	bset = &BitSet{
-		length,
-		make([]uint64, wordsNeeded(length)),
-	}
-
-	return bset
-}
-
-// Cap returns the total possible capacity, or number of bits
-func Cap() uint {
-	return ^uint(0)
-}
-
-// Len returns the number of bits in the BitSet.
-// Note the difference to method Count, see example.
-func (b *BitSet) Len() uint {
-	return b.length
-}
-
-// extendSetMaybe adds additional words to incorporate new bits if needed
-func (b *BitSet) extendSetMaybe(i uint) {
-	if i >= b.length { // if we need more bits, make 'em
-		if i >= Cap() {
-			panic("You are exceeding the capacity")
-		}
-		nsize := wordsNeeded(i + 1)
-		if b.set == nil {
-			b.set = make([]uint64, nsize)
-		} else if cap(b.set) >= nsize {
-			b.set = b.set[:nsize] // fast resize
-		} else if len(b.set) < nsize {
-			newset := make([]uint64, nsize, 2*nsize) // increase capacity 2x
-			copy(newset, b.set)
-			b.set = newset
-		}
-		b.length = i + 1
-	}
-}
-
-// Test whether bit i is set.
-func (b *BitSet) Test(i uint) bool {
-	if i >= b.length {
-		return false
-	}
-	return b.set[i>>log2WordSize]&(1<<(i&(wordSize-1))) != 0
-}
-
-// Set bit i to 1, the capacity of the bitset is automatically
-// increased accordingly.
-// If i>= Cap(), this function will panic.
-// Warning: using a very large value for 'i'
-// may lead to a memory shortage and a panic: the caller is responsible
-// for providing sensible parameters in line with their memory capacity.
-func (b *BitSet) Set(i uint) *BitSet {
-	b.extendSetMaybe(i)
-	b.set[i>>log2WordSize] |= 1 << (i & (wordSize - 1))
-	return b
-}
-
-// Clear bit i to 0
-func (b *BitSet) Clear(i uint) *BitSet {
-	if i >= b.length {
-		return b
-	}
-	b.set[i>>log2WordSize] &^= 1 << (i & (wordSize - 1))
-	return b
-}
-
-// SetTo sets bit i to value.
-// If i>= Cap(), this function will panic.
-// Warning: using a very large value for 'i'
-// may lead to a memory shortage and a panic: the caller is responsible
-// for providing sensible parameters in line with their memory capacity.
-func (b *BitSet) SetTo(i uint, value bool) *BitSet {
-	if value {
-		return b.Set(i)
-	}
-	return b.Clear(i)
-}
-
-// Flip bit at i.
-// If i>= Cap(), this function will panic.
-// Warning: using a very large value for 'i'
-// may lead to a memory shortage and a panic: the caller is responsible
-// for providing sensible parameters in line with their memory capacity.
-func (b *BitSet) Flip(i uint) *BitSet {
-	if i >= b.length {
-		return b.Set(i)
-	}
-	b.set[i>>log2WordSize] ^= 1 << (i & (wordSize - 1))
-	return b
-}
-
-// Shrink shrinks BitSet so that the provided value is the last possible
-// set value. It clears all bits > the provided index and reduces the size
-// and length of the set.
-//
-// Note that the parameter value is not the new length in bits: it is the
-// maximal value that can be stored in the bitset after the function call.
-// The new length in bits is the parameter value + 1. Thus it is not possible
-// to use this function to set the length to 0, the minimal value of the length
-// after this function call is 1.
-//
-// A new slice is allocated to store the new bits, so you may see an increase in
-// memory usage until the GC runs. Normally this should not be a problem, but if you
-// have an extremely large BitSet its important to understand that the old BitSet will
-// remain in memory until the GC frees it.
-func (b *BitSet) Shrink(lastbitindex uint) *BitSet {
-	length := lastbitindex + 1
-	idx := wordsNeeded(length)
-	if idx > len(b.set) {
-		return b
-	}
-	shrunk := make([]uint64, idx)
-	copy(shrunk, b.set[:idx])
-	b.set = shrunk
-	b.length = length
-	b.set[idx-1] &= (allBits >> (uint64(64) - uint64(length&(wordSize-1))))
-	return b
-}
-
-// Compact shrinks BitSet to so that we preserve all set bits, while minimizing
-// memory usage. Compact calls Shrink.
-func (b *BitSet) Compact() *BitSet {
-	idx := len(b.set) - 1
-	for ; idx >= 0 && b.set[idx] == 0; idx-- {
-	}
-	newlength := uint((idx + 1) << log2WordSize)
-	if newlength >= b.length {
-		return b // nothing to do
-	}
-	if newlength > 0 {
-		return b.Shrink(newlength - 1)
-	}
-	// We preserve one word
-	return b.Shrink(63)
-}
-
-// InsertAt takes an index which indicates where a bit should be
-// inserted. Then it shifts all the bits in the set to the left by 1, starting
-// from the given index position, and sets the index position to 0.
-//
-// Depending on the size of your BitSet, and where you are inserting the new entry,
-// this method could be extremely slow and in some cases might cause the entire BitSet
-// to be recopied.
-func (b *BitSet) InsertAt(idx uint) *BitSet {
-	insertAtElement := (idx >> log2WordSize)
-
-	// if length of set is a multiple of wordSize we need to allocate more space first
-	if b.isLenExactMultiple() {
-		b.set = append(b.set, uint64(0))
-	}
-
-	var i uint
-	for i = uint(len(b.set) - 1); i > insertAtElement; i-- {
-		// all elements above the position where we want to insert can simply by shifted
-		b.set[i] <<= 1
-
-		// we take the most significant bit of the previous element and set it as
-		// the least significant bit of the current element
-		b.set[i] |= (b.set[i-1] & 0x8000000000000000) >> 63
-	}
-
-	// generate a mask to extract the data that we need to shift left
-	// within the element where we insert a bit
-	dataMask := ^(uint64(1)<<uint64(idx&(wordSize-1)) - 1)
-
-	// extract that data that we'll shift
-	data := b.set[i] & dataMask
-
-	// set the positions of the data mask to 0 in the element where we insert
-	b.set[i] &= ^dataMask
-
-	// shift data mask to the left and insert its data to the slice element
-	b.set[i] |= data << 1
-
-	// add 1 to length of BitSet
-	b.length++
-
-	return b
-}
-
-// String creates a string representation of the Bitmap
-func (b *BitSet) String() string {
-	// follows code from https://github.com/RoaringBitmap/roaring
-	var buffer bytes.Buffer
-	start := []byte("{")
-	buffer.Write(start)
-	counter := 0
-	i, e := b.NextSet(0)
-	for e {
-		counter = counter + 1
-		// to avoid exhausting the memory
-		if counter > 0x40000 {
-			buffer.WriteString("...")
-			break
-		}
-		buffer.WriteString(strconv.FormatInt(int64(i), 10))
-		i, e = b.NextSet(i + 1)
-		if e {
-			buffer.WriteString(",")
-		}
-	}
-	buffer.WriteString("}")
-	return buffer.String()
-}
-
-// DeleteAt deletes the bit at the given index position from
-// within the bitset
-// All the bits residing on the left of the deleted bit get
-// shifted right by 1
-// The running time of this operation may potentially be
-// relatively slow, O(length)
-func (b *BitSet) DeleteAt(i uint) *BitSet {
-	// the index of the slice element where we'll delete a bit
-	deleteAtElement := i >> log2WordSize
-
-	// generate a mask for the data that needs to be shifted right
-	// within that slice element that gets modified
-	dataMask := ^((uint64(1) << (i & (wordSize - 1))) - 1)
-
-	// extract the data that we'll shift right from the slice element
-	data := b.set[deleteAtElement] & dataMask
-
-	// set the masked area to 0 while leaving the rest as it is
-	b.set[deleteAtElement] &= ^dataMask
-
-	// shift the previously extracted data to the right and then
-	// set it in the previously masked area
-	b.set[deleteAtElement] |= (data >> 1) & dataMask
-
-	// loop over all the consecutive slice elements to copy each
-	// lowest bit into the highest position of the previous element,
-	// then shift the entire content to the right by 1
-	for i := int(deleteAtElement) + 1; i < len(b.set); i++ {
-		b.set[i-1] |= (b.set[i] & 1) << 63
-		b.set[i] >>= 1
-	}
-
-	b.length = b.length - 1
-
-	return b
-}
-
-// NextSet returns the next bit set from the specified index,
-// including possibly the current index
-// along with an error code (true = valid, false = no set bit found)
-// for i,e := v.NextSet(0); e; i,e = v.NextSet(i + 1) {...}
-//
-// Users concerned with performance may want to use NextSetMany to
-// retrieve several values at once.
-func (b *BitSet) NextSet(i uint) (uint, bool) {
-	x := int(i >> log2WordSize)
-	if x >= len(b.set) {
-		return 0, false
-	}
-	w := b.set[x]
-	w = w >> (i & (wordSize - 1))
-	if w != 0 {
-		return i + trailingZeroes64(w), true
-	}
-	x = x + 1
-	for x < len(b.set) {
-		if b.set[x] != 0 {
-			return uint(x)*wordSize + trailingZeroes64(b.set[x]), true
-		}
-		x = x + 1
-
-	}
-	return 0, false
-}
-
-// NextSetMany returns many next bit sets from the specified index,
-// including possibly the current index and up to cap(buffer).
-// If the returned slice has len zero, then no more set bits were found
-//
-//    buffer := make([]uint, 256) // this should be reused
-//    j := uint(0)
-//    j, buffer = bitmap.NextSetMany(j, buffer)
-//    for ; len(buffer) > 0; j, buffer = bitmap.NextSetMany(j,buffer) {
-//     for k := range buffer {
-//      do something with buffer[k]
-//     }
-//     j += 1
-//    }
-//
-//
-// It is possible to retrieve all set bits as follow:
-//
-//    indices := make([]uint, bitmap.Count())
-//    bitmap.NextSetMany(0, indices)
-//
-// However if bitmap.Count() is large, it might be preferable to
-// use several calls to NextSetMany, for performance reasons.
-func (b *BitSet) NextSetMany(i uint, buffer []uint) (uint, []uint) {
-	myanswer := buffer
-	capacity := cap(buffer)
-	x := int(i >> log2WordSize)
-	if x >= len(b.set) || capacity == 0 {
-		return 0, myanswer[:0]
-	}
-	skip := i & (wordSize - 1)
-	word := b.set[x] >> skip
-	myanswer = myanswer[:capacity]
-	size := int(0)
-	for word != 0 {
-		r := trailingZeroes64(word)
-		t := word & ((^word) + 1)
-		myanswer[size] = r + i
-		size++
-		if size == capacity {
-			goto End
-		}
-		word = word ^ t
-	}
-	x++
-	for idx, word := range b.set[x:] {
-		for word != 0 {
-			r := trailingZeroes64(word)
-			t := word & ((^word) + 1)
-			myanswer[size] = r + (uint(x+idx) << 6)
-			size++
-			if size == capacity {
-				goto End
-			}
-			word = word ^ t
-		}
-	}
-End:
-	if size > 0 {
-		return myanswer[size-1], myanswer[:size]
-	}
-	return 0, myanswer[:0]
-}
-
-// NextClear returns the next clear bit from the specified index,
-// including possibly the current index
-// along with an error code (true = valid, false = no bit found i.e. all bits are set)
-func (b *BitSet) NextClear(i uint) (uint, bool) {
-	x := int(i >> log2WordSize)
-	if x >= len(b.set) {
-		return 0, false
-	}
-	w := b.set[x]
-	w = w >> (i & (wordSize - 1))
-	wA := allBits >> (i & (wordSize - 1))
-	index := i + trailingZeroes64(^w)
-	if w != wA && index < b.length {
-		return index, true
-	}
-	x++
-	for x < len(b.set) {
-		index = uint(x)*wordSize + trailingZeroes64(^b.set[x])
-		if b.set[x] != allBits && index < b.length {
-			return index, true
-		}
-		x++
-	}
-	return 0, false
-}
-
-// ClearAll clears the entire BitSet
-func (b *BitSet) ClearAll() *BitSet {
-	if b != nil && b.set != nil {
-		for i := range b.set {
-			b.set[i] = 0
-		}
-	}
-	return b
-}
-
-// wordCount returns the number of words used in a bit set
-func (b *BitSet) wordCount() int {
-	return len(b.set)
-}
-
-// Clone this BitSet
-func (b *BitSet) Clone() *BitSet {
-	c := New(b.length)
-	if b.set != nil { // Clone should not modify current object
-		copy(c.set, b.set)
-	}
-	return c
-}
-
-// Copy into a destination BitSet
-// Returning the size of the destination BitSet
-// like array copy
-func (b *BitSet) Copy(c *BitSet) (count uint) {
-	if c == nil {
-		return
-	}
-	if b.set != nil { // Copy should not modify current object
-		copy(c.set, b.set)
-	}
-	count = c.length
-	if b.length < c.length {
-		count = b.length
-	}
-	return
-}
-
-// Count (number of set bits).
-// Also known as "popcount" or "popularity count".
-func (b *BitSet) Count() uint {
-	if b != nil && b.set != nil {
-		return uint(popcntSlice(b.set))
-	}
-	return 0
-}
-
-// Equal tests the equivalence of two BitSets.
-// False if they are of different sizes, otherwise true
-// only if all the same bits are set
-func (b *BitSet) Equal(c *BitSet) bool {
-	if c == nil || b == nil {
-		return c == b
-	}
-	if b.length != c.length {
-		return false
-	}
-	if b.length == 0 { // if they have both length == 0, then could have nil set
-		return true
-	}
-	// testing for equality shoud not transform the bitset (no call to safeSet)
-
-	for p, v := range b.set {
-		if c.set[p] != v {
-			return false
-		}
-	}
-	return true
-}
-
-func panicIfNull(b *BitSet) {
-	if b == nil {
-		panic(Error("BitSet must not be null"))
-	}
-}
-
-// Difference of base set and other set
-// This is the BitSet equivalent of &^ (and not)
-func (b *BitSet) Difference(compare *BitSet) (result *BitSet) {
-	panicIfNull(b)
-	panicIfNull(compare)
-	result = b.Clone() // clone b (in case b is bigger than compare)
-	l := int(compare.wordCount())
-	if l > int(b.wordCount()) {
-		l = int(b.wordCount())
-	}
-	for i := 0; i < l; i++ {
-		result.set[i] = b.set[i] &^ compare.set[i]
-	}
-	return
-}
-
-// DifferenceCardinality computes the cardinality of the differnce
-func (b *BitSet) DifferenceCardinality(compare *BitSet) uint {
-	panicIfNull(b)
-	panicIfNull(compare)
-	l := int(compare.wordCount())
-	if l > int(b.wordCount()) {
-		l = int(b.wordCount())
-	}
-	cnt := uint64(0)
-	cnt += popcntMaskSlice(b.set[:l], compare.set[:l])
-	cnt += popcntSlice(b.set[l:])
-	return uint(cnt)
-}
-
-// InPlaceDifference computes the difference of base set and other set
-// This is the BitSet equivalent of &^ (and not)
-func (b *BitSet) InPlaceDifference(compare *BitSet) {
-	panicIfNull(b)
-	panicIfNull(compare)
-	l := int(compare.wordCount())
-	if l > int(b.wordCount()) {
-		l = int(b.wordCount())
-	}
-	for i := 0; i < l; i++ {
-		b.set[i] &^= compare.set[i]
-	}
-}
-
-// Convenience function: return two bitsets ordered by
-// increasing length. Note: neither can be nil
-func sortByLength(a *BitSet, b *BitSet) (ap *BitSet, bp *BitSet) {
-	if a.length <= b.length {
-		ap, bp = a, b
-	} else {
-		ap, bp = b, a
-	}
-	return
-}
-
-// Intersection of base set and other set
-// This is the BitSet equivalent of & (and)
-func (b *BitSet) Intersection(compare *BitSet) (result *BitSet) {
-	panicIfNull(b)
-	panicIfNull(compare)
-	b, compare = sortByLength(b, compare)
-	result = New(b.length)
-	for i, word := range b.set {
-		result.set[i] = word & compare.set[i]
-	}
-	return
-}
-
-// IntersectionCardinality computes the cardinality of the union
-func (b *BitSet) IntersectionCardinality(compare *BitSet) uint {
-	panicIfNull(b)
-	panicIfNull(compare)
-	b, compare = sortByLength(b, compare)
-	cnt := popcntAndSlice(b.set, compare.set)
-	return uint(cnt)
-}
-
-// InPlaceIntersection destructively computes the intersection of
-// base set and the compare set.
-// This is the BitSet equivalent of & (and)
-func (b *BitSet) InPlaceIntersection(compare *BitSet) {
-	panicIfNull(b)
-	panicIfNull(compare)
-	l := int(compare.wordCount())
-	if l > int(b.wordCount()) {
-		l = int(b.wordCount())
-	}
-	for i := 0; i < l; i++ {
-		b.set[i] &= compare.set[i]
-	}
-	for i := l; i < len(b.set); i++ {
-		b.set[i] = 0
-	}
-	if compare.length > 0 {
-		b.extendSetMaybe(compare.length - 1)
-	}
-}
-
-// Union of base set and other set
-// This is the BitSet equivalent of | (or)
-func (b *BitSet) Union(compare *BitSet) (result *BitSet) {
-	panicIfNull(b)
-	panicIfNull(compare)
-	b, compare = sortByLength(b, compare)
-	result = compare.Clone()
-	for i, word := range b.set {
-		result.set[i] = word | compare.set[i]
-	}
-	return
-}
-
-// UnionCardinality computes the cardinality of the uniton of the base set
-// and the compare set.
-func (b *BitSet) UnionCardinality(compare *BitSet) uint {
-	panicIfNull(b)
-	panicIfNull(compare)
-	b, compare = sortByLength(b, compare)
-	cnt := popcntOrSlice(b.set, compare.set)
-	if len(compare.set) > len(b.set) {
-		cnt += popcntSlice(compare.set[len(b.set):])
-	}
-	return uint(cnt)
-}
-
-// InPlaceUnion creates the destructive union of base set and compare set.
-// This is the BitSet equivalent of | (or).
-func (b *BitSet) InPlaceUnion(compare *BitSet) {
-	panicIfNull(b)
-	panicIfNull(compare)
-	l := int(compare.wordCount())
-	if l > int(b.wordCount()) {
-		l = int(b.wordCount())
-	}
-	if compare.length > 0 {
-		b.extendSetMaybe(compare.length - 1)
-	}
-	for i := 0; i < l; i++ {
-		b.set[i] |= compare.set[i]
-	}
-	if len(compare.set) > l {
-		for i := l; i < len(compare.set); i++ {
-			b.set[i] = compare.set[i]
-		}
-	}
-}
-
-// SymmetricDifference of base set and other set
-// This is the BitSet equivalent of ^ (xor)
-func (b *BitSet) SymmetricDifference(compare *BitSet) (result *BitSet) {
-	panicIfNull(b)
-	panicIfNull(compare)
-	b, compare = sortByLength(b, compare)
-	// compare is bigger, so clone it
-	result = compare.Clone()
-	for i, word := range b.set {
-		result.set[i] = word ^ compare.set[i]
-	}
-	return
-}
-
-// SymmetricDifferenceCardinality computes the cardinality of the symmetric difference
-func (b *BitSet) SymmetricDifferenceCardinality(compare *BitSet) uint {
-	panicIfNull(b)
-	panicIfNull(compare)
-	b, compare = sortByLength(b, compare)
-	cnt := popcntXorSlice(b.set, compare.set)
-	if len(compare.set) > len(b.set) {
-		cnt += popcntSlice(compare.set[len(b.set):])
-	}
-	return uint(cnt)
-}
-
-// InPlaceSymmetricDifference creates the destructive SymmetricDifference of base set and other set
-// This is the BitSet equivalent of ^ (xor)
-func (b *BitSet) InPlaceSymmetricDifference(compare *BitSet) {
-	panicIfNull(b)
-	panicIfNull(compare)
-	l := int(compare.wordCount())
-	if l > int(b.wordCount()) {
-		l = int(b.wordCount())
-	}
-	if compare.length > 0 {
-		b.extendSetMaybe(compare.length - 1)
-	}
-	for i := 0; i < l; i++ {
-		b.set[i] ^= compare.set[i]
-	}
-	if len(compare.set) > l {
-		for i := l; i < len(compare.set); i++ {
-			b.set[i] = compare.set[i]
-		}
-	}
-}
-
-// Is the length an exact multiple of word sizes?
-func (b *BitSet) isLenExactMultiple() bool {
-	return b.length%wordSize == 0
-}
-
-// Clean last word by setting unused bits to 0
-func (b *BitSet) cleanLastWord() {
-	if !b.isLenExactMultiple() {
-		b.set[len(b.set)-1] &= allBits >> (wordSize - b.length%wordSize)
-	}
-}
-
-// Complement computes the (local) complement of a biset (up to length bits)
-func (b *BitSet) Complement() (result *BitSet) {
-	panicIfNull(b)
-	result = New(b.length)
-	for i, word := range b.set {
-		result.set[i] = ^word
-	}
-	result.cleanLastWord()
-	return
-}
-
-// All returns true if all bits are set, false otherwise. Returns true for
-// empty sets.
-func (b *BitSet) All() bool {
-	panicIfNull(b)
-	return b.Count() == b.length
-}
-
-// None returns true if no bit is set, false otherwise. Returns true for
-// empty sets.
-func (b *BitSet) None() bool {
-	panicIfNull(b)
-	if b != nil && b.set != nil {
-		for _, word := range b.set {
-			if word > 0 {
-				return false
-			}
-		}
-		return true
-	}
-	return true
-}
-
-// Any returns true if any bit is set, false otherwise
-func (b *BitSet) Any() bool {
-	panicIfNull(b)
-	return !b.None()
-}
-
-// IsSuperSet returns true if this is a superset of the other set
-func (b *BitSet) IsSuperSet(other *BitSet) bool {
-	for i, e := other.NextSet(0); e; i, e = other.NextSet(i + 1) {
-		if !b.Test(i) {
-			return false
-		}
-	}
-	return true
-}
-
-// IsStrictSuperSet returns true if this is a strict superset of the other set
-func (b *BitSet) IsStrictSuperSet(other *BitSet) bool {
-	return b.Count() > other.Count() && b.IsSuperSet(other)
-}
-
-// DumpAsBits dumps a bit set as a string of bits
-func (b *BitSet) DumpAsBits() string {
-	if b.set == nil {
-		return "."
-	}
-	buffer := bytes.NewBufferString("")
-	i := len(b.set) - 1
-	for ; i >= 0; i-- {
-		fmt.Fprintf(buffer, "%064b.", b.set[i])
-	}
-	return buffer.String()
-}
-
-// BinaryStorageSize returns the binary storage requirements
-func (b *BitSet) BinaryStorageSize() int {
-	return binary.Size(uint64(0)) + binary.Size(b.set)
-}
-
-// WriteTo writes a BitSet to a stream
-func (b *BitSet) WriteTo(stream io.Writer) (int64, error) {
-	length := uint64(b.length)
-
-	// Write length
-	err := binary.Write(stream, binaryOrder, length)
-	if err != nil {
-		return 0, err
-	}
-
-	// Write set
-	err = binary.Write(stream, binaryOrder, b.set)
-	return int64(b.BinaryStorageSize()), err
-}
-
-// ReadFrom reads a BitSet from a stream written using WriteTo
-func (b *BitSet) ReadFrom(stream io.Reader) (int64, error) {
-	var length uint64
-
-	// Read length first
-	err := binary.Read(stream, binaryOrder, &length)
-	if err != nil {
-		return 0, err
-	}
-	newset := New(uint(length))
-
-	if uint64(newset.length) != length {
-		return 0, errors.New("unmarshalling error: type mismatch")
-	}
-
-	// Read remaining bytes as set
-	err = binary.Read(stream, binaryOrder, newset.set)
-	if err != nil {
-		return 0, err
-	}
-
-	*b = *newset
-	return int64(b.BinaryStorageSize()), nil
-}
-
-// MarshalBinary encodes a BitSet into a binary form and returns the result.
-func (b *BitSet) MarshalBinary() ([]byte, error) {
-	var buf bytes.Buffer
-	writer := bufio.NewWriter(&buf)
-
-	_, err := b.WriteTo(writer)
-	if err != nil {
-		return []byte{}, err
-	}
-
-	err = writer.Flush()
-
-	return buf.Bytes(), err
-}
-
-// UnmarshalBinary decodes the binary form generated by MarshalBinary.
-func (b *BitSet) UnmarshalBinary(data []byte) error {
-	buf := bytes.NewReader(data)
-	reader := bufio.NewReader(buf)
-
-	_, err := b.ReadFrom(reader)
-
-	return err
-}
-
-// MarshalJSON marshals a BitSet as a JSON structure
-func (b *BitSet) MarshalJSON() ([]byte, error) {
-	buffer := bytes.NewBuffer(make([]byte, 0, b.BinaryStorageSize()))
-	_, err := b.WriteTo(buffer)
-	if err != nil {
-		return nil, err
-	}
-
-	// URLEncode all bytes
-	return json.Marshal(base64Encoding.EncodeToString(buffer.Bytes()))
-}
-
-// UnmarshalJSON unmarshals a BitSet from JSON created using MarshalJSON
-func (b *BitSet) UnmarshalJSON(data []byte) error {
-	// Unmarshal as string
-	var s string
-	err := json.Unmarshal(data, &s)
-	if err != nil {
-		return err
-	}
-
-	// URLDecode string
-	buf, err := base64Encoding.DecodeString(s)
-	if err != nil {
-		return err
-	}
-
-	_, err = b.ReadFrom(bytes.NewReader(buf))
-	return err
-}