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arraycontainer.go
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arraycontainer.go
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package roaring
import (
"unsafe"
)
type arrayContainer struct {
content []uint16
}
func (ac *arrayContainer) fillLeastSignificant16bits(x []uint32, i int, mask uint32) {
for k := 0; k < len(ac.content); k++ {
x[k+i] = uint32(ac.content[k]) | mask
}
}
func (ac *arrayContainer) getShortIterator() shortIterable {
return &shortIterator{ac.content, 0}
}
func (ac *arrayContainer) getSizeInBytes() int {
// unsafe.Sizeof calculates the memory used by the top level of the slice
// descriptor - not including the size of the memory referenced by the slice.
// http://golang.org/pkg/unsafe/#Sizeof
return ac.getCardinality()*2 + int(unsafe.Sizeof(ac.content))
}
func (ac *arrayContainer) serializedSizeInBytes() int {
// based on https://golang.org/src/pkg/encoding/binary/binary.go#265
// there is no serialization overhead for writing an array of fixed size vals
return ac.getCardinality() * 2
}
// add the values in the range [firstOfRange,lastofRange)
// unused code
/*func (ac *arrayContainer) addRange(firstOfRange, lastOfRange int) container {
if firstOfRange >= lastOfRange {
return ac.clone()
}
indexstart := binarySearch(ac.content, uint16(firstOfRange))
if indexstart < 0 {
indexstart = -indexstart - 1
}
indexend := binarySearch(ac.content, uint16(lastOfRange-1))
if indexend < 0 {
indexend = -indexend - 1
} else {
indexend++
}
rangelength := lastOfRange - firstOfRange
newcardinality := indexstart + (ac.getCardinality() - indexend) + rangelength
if newcardinality > arrayDefaultMaxSize {
a := ac.toBitmapContainer()
return a.iaddRange(firstOfRange, lastOfRange)
}
answer := &arrayContainer{make([]uint16, newcardinality)}
copy(answer.content[:indexstart], ac.content[:indexstart])
copy(answer.content[indexstart+rangelength:], ac.content[indexend:])
for k := 0; k < rangelength; k++ {
answer.content[k+indexstart] = uint16(firstOfRange + k)
}
return answer
}*/
// remove the values in the range [firstOfRange,lastofRange)
// unused code
/*func (ac *arrayContainer) removeRange(firstOfRange, lastOfRange int) container {
if firstOfRange >= lastOfRange {
return ac.clone()
}
indexstart := binarySearch(ac.content, uint16(firstOfRange))
if indexstart < 0 {
indexstart = -indexstart - 1
}
indexend := binarySearch(ac.content, uint16(lastOfRange-1))
if indexend < 0 {
indexend = -indexend - 1
} else {
indexend++
}
rangelength := indexend - indexstart
answer := &arrayContainer{make([]uint16, ac.getCardinality()-rangelength)}
copy(answer.content[:indexstart], ac.content[:indexstart])
copy(answer.content[indexstart:], ac.content[indexstart+rangelength:])
return answer
}*/
// add the values in the range [firstOfRange,lastofRange)
func (ac *arrayContainer) iaddRange(firstOfRange, lastOfRange int) container {
if firstOfRange >= lastOfRange {
return ac
}
indexstart := binarySearch(ac.content, uint16(firstOfRange))
if indexstart < 0 {
indexstart = -indexstart - 1
}
indexend := binarySearch(ac.content, uint16(lastOfRange-1))
if indexend < 0 {
indexend = -indexend - 1
} else {
indexend++
}
rangelength := lastOfRange - firstOfRange
newcardinality := indexstart + (ac.getCardinality() - indexend) + rangelength
if newcardinality > arrayDefaultMaxSize {
a := ac.toBitmapContainer()
return a.iaddRange(firstOfRange, lastOfRange)
}
if cap(ac.content) < newcardinality {
tmp := make([]uint16, newcardinality, newcardinality)
copy(tmp[:indexstart], ac.content[:indexstart])
copy(tmp[indexstart+rangelength:], ac.content[indexend:])
ac.content = tmp
} else {
ac.content = ac.content[:newcardinality]
copy(ac.content[indexstart+rangelength:], ac.content[indexend:])
}
for k := 0; k < rangelength; k++ {
ac.content[k+indexstart] = uint16(firstOfRange + k)
}
return ac
}
// remove the values in the range [firstOfRange,lastOfRange)
func (ac *arrayContainer) iremoveRange(firstOfRange, lastOfRange int) container {
if firstOfRange >= lastOfRange {
return ac
}
indexstart := binarySearch(ac.content, uint16(firstOfRange))
if indexstart < 0 {
indexstart = -indexstart - 1
}
indexend := binarySearch(ac.content, uint16(lastOfRange-1))
if indexend < 0 {
indexend = -indexend - 1
} else {
indexend++
}
rangelength := indexend - indexstart
answer := ac
copy(answer.content[indexstart:], ac.content[indexstart+rangelength:])
answer.content = answer.content[:ac.getCardinality()-rangelength]
return answer
}
// flip the values in the range [firstOfRange,lastOfRange)
func (ac *arrayContainer) not(firstOfRange, lastOfRange int) container {
if firstOfRange >= lastOfRange {
return ac.clone()
}
return ac.notClose(firstOfRange, lastOfRange-1) // remove everything in [firstOfRange,lastOfRange-1]
}
// flip the values in the range [firstOfRange,lastOfRange]
func (ac *arrayContainer) notClose(firstOfRange, lastOfRange int) container {
if firstOfRange > lastOfRange { // unlike add and remove, not uses an inclusive range [firstOfRange,lastOfRange]
return ac.clone()
}
// determine the span of array indices to be affected^M
startIndex := binarySearch(ac.content, uint16(firstOfRange))
if startIndex < 0 {
startIndex = -startIndex - 1
}
lastIndex := binarySearch(ac.content, uint16(lastOfRange))
if lastIndex < 0 {
lastIndex = -lastIndex - 2
}
currentValuesInRange := lastIndex - startIndex + 1
spanToBeFlipped := lastOfRange - firstOfRange + 1
newValuesInRange := spanToBeFlipped - currentValuesInRange
cardinalityChange := newValuesInRange - currentValuesInRange
newCardinality := len(ac.content) + cardinalityChange
if newCardinality > arrayDefaultMaxSize {
return ac.toBitmapContainer().not(firstOfRange, lastOfRange+1)
}
answer := newArrayContainer()
answer.content = make([]uint16, newCardinality, newCardinality) //a hack for sure
copy(answer.content, ac.content[:startIndex])
outPos := startIndex
inPos := startIndex
valInRange := firstOfRange
for ; valInRange <= lastOfRange && inPos <= lastIndex; valInRange++ {
if uint16(valInRange) != ac.content[inPos] {
answer.content[outPos] = uint16(valInRange)
outPos++
} else {
inPos++
}
}
for ; valInRange <= lastOfRange; valInRange++ {
answer.content[outPos] = uint16(valInRange)
outPos++
}
for i := lastIndex + 1; i < len(ac.content); i++ {
answer.content[outPos] = ac.content[i]
outPos++
}
answer.content = answer.content[:newCardinality]
return answer
}
func (ac *arrayContainer) equals(o interface{}) bool {
srb, ok := o.(*arrayContainer)
if ok {
// Check if the containers are the same object.
if ac == srb {
return true
}
if len(srb.content) != len(ac.content) {
return false
}
for i, v := range ac.content {
if v != srb.content[i] {
return false
}
}
return true
}
return false
}
func (ac *arrayContainer) toBitmapContainer() *bitmapContainer {
bc := newBitmapContainer()
bc.loadData(ac)
return bc
}
func (ac *arrayContainer) add(x uint16) container {
// Special case adding to the end of the container.
l := len(ac.content)
if l > 0 && l < arrayDefaultMaxSize && ac.content[l-1] < x {
ac.content = append(ac.content, x)
return ac
}
loc := binarySearch(ac.content, x)
if loc < 0 {
if len(ac.content) >= arrayDefaultMaxSize {
a := ac.toBitmapContainer()
a.add(x)
return a
}
s := ac.content
i := -loc - 1
s = append(s, 0)
copy(s[i+1:], s[i:])
s[i] = x
ac.content = s
}
return ac
}
func (ac *arrayContainer) remove(x uint16) container {
loc := binarySearch(ac.content, x)
if loc >= 0 {
s := ac.content
s = append(s[:loc], s[loc+1:]...)
ac.content = s
}
return ac
}
func (ac *arrayContainer) or(a container) container {
switch a.(type) {
case *arrayContainer:
return ac.orArray(a.(*arrayContainer))
case *bitmapContainer:
return a.or(ac)
}
panic("unsupported container type")
}
func (ac *arrayContainer) ior(a container) container {
switch a.(type) {
case *arrayContainer:
return ac.orArray(a.(*arrayContainer))
case *bitmapContainer:
return a.ior(ac)
}
panic("unsupported container type")
}
func (ac *arrayContainer) lazyIOR(a container) container {
switch a.(type) {
case *arrayContainer:
return ac.lazyorArray(a.(*arrayContainer))
case *bitmapContainer:
return a.lazyOR(ac)
}
panic("unsupported container type")
}
func (ac *arrayContainer) lazyOR(a container) container {
switch a.(type) {
case *arrayContainer:
return ac.lazyorArray(a.(*arrayContainer))
case *bitmapContainer:
return a.lazyOR(ac)
}
panic("unsupported container type")
}
func (ac *arrayContainer) orArray(value2 *arrayContainer) container {
value1 := ac
maxPossibleCardinality := value1.getCardinality() + value2.getCardinality()
if maxPossibleCardinality > arrayDefaultMaxSize { // it could be a bitmap!^M
bc := newBitmapContainer()
for k := 0; k < len(value2.content); k++ {
v := value2.content[k]
i := uint(v) >> 6
mask := uint64(1) << (v % 64)
bc.bitmap[i] |= mask
}
for k := 0; k < len(ac.content); k++ {
v := ac.content[k]
i := uint(v) >> 6
mask := uint64(1) << (v % 64)
bc.bitmap[i] |= mask
}
bc.cardinality = int(popcntSlice(bc.bitmap))
if bc.cardinality <= arrayDefaultMaxSize {
return bc.toArrayContainer()
}
return bc
}
answer := newArrayContainerCapacity(maxPossibleCardinality)
nl := union2by2(value1.content, value2.content, answer.content)
answer.content = answer.content[:nl] // reslice to match actual used capacity
return answer
}
func (ac *arrayContainer) lazyorArray(value2 *arrayContainer) container {
value1 := ac
maxPossibleCardinality := value1.getCardinality() + value2.getCardinality()
if maxPossibleCardinality > arrayLazyLowerBound { // it could be a bitmap!^M
bc := newBitmapContainer()
for k := 0; k < len(value2.content); k++ {
v := value2.content[k]
i := uint(v) >> 6
mask := uint64(1) << (v % 64)
bc.bitmap[i] |= mask
}
for k := 0; k < len(ac.content); k++ {
v := ac.content[k]
i := uint(v) >> 6
mask := uint64(1) << (v % 64)
bc.bitmap[i] |= mask
}
bc.cardinality = invalidCardinality
return bc
}
answer := newArrayContainerCapacity(maxPossibleCardinality)
nl := union2by2(value1.content, value2.content, answer.content)
answer.content = answer.content[:nl] // reslice to match actual used capacity
return answer
}
func (ac *arrayContainer) and(a container) container {
switch a.(type) {
case *arrayContainer:
return ac.andArray(a.(*arrayContainer))
case *bitmapContainer:
return a.and(ac)
}
panic("unsupported container type")
}
func (ac *arrayContainer) intersects(a container) bool {
switch a.(type) {
case *arrayContainer:
return ac.intersectsArray(a.(*arrayContainer))
case *bitmapContainer:
return a.intersects(ac)
}
panic("unsupported container type")
}
func (ac *arrayContainer) iand(a container) container {
switch a.(type) {
case *arrayContainer:
return ac.iandArray(a.(*arrayContainer))
case *bitmapContainer:
return ac.iandBitmap(a.(*bitmapContainer))
}
panic("unsupported container type")
}
func (ac *arrayContainer) iandBitmap(bc *bitmapContainer) *arrayContainer {
pos := 0
c := ac.getCardinality()
for k := 0; k < c; k++ {
if bc.contains(ac.content[k]) {
ac.content[pos] = ac.content[k]
pos++
}
}
ac.content = ac.content[:pos]
return ac
}
func (ac *arrayContainer) xor(a container) container {
switch a.(type) {
case *arrayContainer:
return ac.xorArray(a.(*arrayContainer))
case *bitmapContainer:
return a.xor(ac)
}
panic("unsupported container type")
}
func (ac *arrayContainer) xorArray(value2 *arrayContainer) container {
value1 := ac
totalCardinality := value1.getCardinality() + value2.getCardinality()
if totalCardinality > arrayDefaultMaxSize { // it could be a bitmap!
bc := newBitmapContainer()
for k := 0; k < len(value2.content); k++ {
v := value2.content[k]
i := uint(v) >> 6
bc.bitmap[i] ^= (uint64(1) << (v % 64))
}
for k := 0; k < len(ac.content); k++ {
v := ac.content[k]
i := uint(v) >> 6
bc.bitmap[i] ^= (uint64(1) << (v % 64))
}
bc.computeCardinality()
if bc.cardinality <= arrayDefaultMaxSize {
return bc.toArrayContainer()
}
return bc
}
desiredCapacity := totalCardinality
answer := newArrayContainerCapacity(desiredCapacity)
length := exclusiveUnion2by2(value1.content, value2.content, answer.content)
answer.content = answer.content[:length]
return answer
}
func (ac *arrayContainer) andNot(a container) container {
switch a.(type) {
case *arrayContainer:
return ac.andNotArray(a.(*arrayContainer))
case *bitmapContainer:
return ac.andNotBitmap(a.(*bitmapContainer))
}
panic("unsupported container type")
}
func (ac *arrayContainer) iandNot(a container) container {
switch a.(type) {
case *arrayContainer:
return ac.iandNotArray(a.(*arrayContainer))
case *bitmapContainer:
return ac.iandNotBitmap(a.(*bitmapContainer))
}
panic("unsupported container type")
}
func (ac *arrayContainer) andNotArray(value2 *arrayContainer) container {
value1 := ac
desiredcapacity := value1.getCardinality()
answer := newArrayContainerCapacity(desiredcapacity)
length := difference(value1.content, value2.content, answer.content)
answer.content = answer.content[:length]
return answer
}
func (ac *arrayContainer) iandNotArray(value2 *arrayContainer) container {
length := difference(ac.content, value2.content, ac.content)
ac.content = ac.content[:length]
return ac
}
func (ac *arrayContainer) andNotBitmap(value2 *bitmapContainer) container {
desiredcapacity := ac.getCardinality()
answer := newArrayContainerCapacity(desiredcapacity)
answer.content = answer.content[:desiredcapacity]
pos := 0
for _, v := range ac.content {
if !value2.contains(v) {
answer.content[pos] = v
pos++
}
}
answer.content = answer.content[:pos]
return answer
}
func (ac *arrayContainer) andBitmap(value2 *bitmapContainer) container {
desiredcapacity := ac.getCardinality()
answer := newArrayContainerCapacity(desiredcapacity)
answer.content = answer.content[:desiredcapacity]
pos := 0
for _, v := range ac.content {
if value2.contains(v) {
answer.content[pos] = v
pos++
}
}
answer.content = answer.content[:pos]
return answer
}
func (ac *arrayContainer) iandNotBitmap(value2 *bitmapContainer) container {
pos := 0
for _, v := range ac.content {
if !value2.contains(v) {
ac.content[pos] = v
pos++
}
}
ac.content = ac.content[:pos]
return ac
}
func copyOf(array []uint16, size int) []uint16 {
result := make([]uint16, size)
for i, x := range array {
if i == size {
break
}
result[i] = x
}
return result
}
// flip the values in the range [firstOfRange,lastOfRange)
func (ac *arrayContainer) inot(firstOfRange, lastOfRange int) container {
if firstOfRange >= lastOfRange {
return ac
}
return ac.inotClose(firstOfRange, lastOfRange-1) // remove everything in [firstOfRange,lastOfRange-1]
}
// flip the values in the range [firstOfRange,lastOfRange]
func (ac *arrayContainer) inotClose(firstOfRange, lastOfRange int) container {
if firstOfRange > lastOfRange { // unlike add and remove, not uses an inclusive range [firstOfRange,lastOfRange]
return ac
}
// determine the span of array indices to be affected
startIndex := binarySearch(ac.content, uint16(firstOfRange))
if startIndex < 0 {
startIndex = -startIndex - 1
}
lastIndex := binarySearch(ac.content, uint16(lastOfRange))
if lastIndex < 0 {
lastIndex = -lastIndex - 1 - 1
}
currentValuesInRange := lastIndex - startIndex + 1
spanToBeFlipped := lastOfRange - firstOfRange + 1
newValuesInRange := spanToBeFlipped - currentValuesInRange
buffer := make([]uint16, newValuesInRange)
cardinalityChange := newValuesInRange - currentValuesInRange
newCardinality := len(ac.content) + cardinalityChange
if cardinalityChange > 0 {
if newCardinality > len(ac.content) {
if newCardinality > arrayDefaultMaxSize {
return ac.toBitmapContainer().inot(firstOfRange, lastOfRange+1)
}
ac.content = copyOf(ac.content, newCardinality)
}
base := lastIndex + 1
copy(ac.content[lastIndex+1+cardinalityChange:], ac.content[base:base+len(ac.content)-1-lastIndex])
ac.negateRange(buffer, startIndex, lastIndex, firstOfRange, lastOfRange)
} else { // no expansion needed
ac.negateRange(buffer, startIndex, lastIndex, firstOfRange, lastOfRange)
if cardinalityChange < 0 {
for i := startIndex + newValuesInRange; i < newCardinality; i++ {
ac.content[i] = ac.content[i-cardinalityChange]
}
}
}
ac.content = ac.content[:newCardinality]
return ac
}
func (ac *arrayContainer) negateRange(buffer []uint16, startIndex, lastIndex, startRange, lastRange int) {
// compute the negation into buffer
outPos := 0
inPos := startIndex // value here always >= valInRange,
// until it is exhausted
// n.b., we can start initially exhausted.
valInRange := startRange
for ; valInRange <= lastRange && inPos <= lastIndex; valInRange++ {
if uint16(valInRange) != ac.content[inPos] {
buffer[outPos] = uint16(valInRange)
outPos++
} else {
inPos++
}
}
// if there are extra items (greater than the biggest
// pre-existing one in range), buffer them
for ; valInRange <= lastRange; valInRange++ {
buffer[outPos] = uint16(valInRange)
outPos++
}
if outPos != len(buffer) {
//panic("negateRange: outPos " + outPos + " whereas buffer.length=" + len(buffer))
panic("negateRange: outPos whereas buffer.length=")
}
for i, item := range buffer {
ac.content[i] = item
}
}
func min(a, b int) int {
if a < b {
return a
}
return b
}
func (ac *arrayContainer) andArray(value2 *arrayContainer) *arrayContainer {
desiredcapacity := min(ac.getCardinality(), value2.getCardinality())
answer := newArrayContainerCapacity(desiredcapacity)
length := intersection2by2(
ac.content,
value2.content,
answer.content)
answer.content = answer.content[:length]
return answer
}
func (ac *arrayContainer) intersectsArray(value2 *arrayContainer) bool {
return intersects2by2(
ac.content,
value2.content)
}
func (ac *arrayContainer) iandArray(value2 *arrayContainer) *arrayContainer {
length := intersection2by2(
ac.content,
value2.content,
ac.content)
ac.content = ac.content[:length]
return ac
}
func (ac *arrayContainer) getCardinality() int {
return len(ac.content)
}
func (ac *arrayContainer) rank(x uint16) int {
answer := binarySearch(ac.content, x)
if answer >= 0 {
return answer + 1
}
return -answer - 1
}
func (ac *arrayContainer) selectInt(x uint16) int {
return int(ac.content[x])
}
func (ac *arrayContainer) clone() container {
ptr := arrayContainer{make([]uint16, len(ac.content))}
copy(ptr.content, ac.content[:])
return &ptr
}
func (ac *arrayContainer) contains(x uint16) bool {
return binarySearch(ac.content, x) >= 0
}
func (ac *arrayContainer) loadData(bitmapContainer *bitmapContainer) {
ac.content = make([]uint16, bitmapContainer.cardinality, bitmapContainer.cardinality)
bitmapContainer.fillArray(ac.content)
}
func newArrayContainer() *arrayContainer {
p := new(arrayContainer)
return p
}
func newArrayContainerCapacity(size int) *arrayContainer {
p := new(arrayContainer)
p.content = make([]uint16, 0, size)
return p
}
func newArrayContainerSize(size int) *arrayContainer {
p := new(arrayContainer)
p.content = make([]uint16, size, size)
return p
}
func newArrayContainerRange(firstOfRun, lastOfRun int) *arrayContainer {
valuesInRange := lastOfRun - firstOfRun + 1
this := newArrayContainerCapacity(valuesInRange)
for i := 0; i < valuesInRange; i++ {
this.content = append(this.content, uint16(firstOfRun+i))
}
return this
}