package roaring import ( "fmt" "unsafe" ) type bitmapContainer struct { cardinality int bitmap []uint64 } func (bc bitmapContainer) String() string { var s string for it := bc.getShortIterator(); it.hasNext(); { s += fmt.Sprintf("%v, ", it.next()) } return s } func newBitmapContainer() *bitmapContainer { p := new(bitmapContainer) size := (1 << 16) / 64 p.bitmap = make([]uint64, size, size) return p } func newBitmapContainerwithRange(firstOfRun, lastOfRun int) *bitmapContainer { bc := newBitmapContainer() bc.cardinality = lastOfRun - firstOfRun + 1 if bc.cardinality == maxCapacity { fill(bc.bitmap, uint64(0xffffffffffffffff)) } else { firstWord := firstOfRun / 64 lastWord := lastOfRun / 64 zeroPrefixLength := uint64(firstOfRun & 63) zeroSuffixLength := uint64(63 - (lastOfRun & 63)) fillRange(bc.bitmap, firstWord, lastWord+1, uint64(0xffffffffffffffff)) bc.bitmap[firstWord] ^= ((uint64(1) << zeroPrefixLength) - 1) blockOfOnes := (uint64(1) << zeroSuffixLength) - 1 maskOnLeft := blockOfOnes << (uint64(64) - zeroSuffixLength) bc.bitmap[lastWord] ^= maskOnLeft } return bc } func (bc *bitmapContainer) minimum() uint16 { for i := 0; i < len(bc.bitmap); i++ { w := bc.bitmap[i] if w != 0 { r := countTrailingZeros(w) return uint16(r + i*64) } } return MaxUint16 } // i should be non-zero func clz(i uint64) int { n := 1 x := uint32(i >> 32) if x == 0 { n += 32 x = uint32(i) } if x>>16 == 0 { n += 16 x = x << 16 } if x>>24 == 0 { n += 8 x = x << 8 } if x>>28 == 0 { n += 4 x = x << 4 } if x>>30 == 0 { n += 2 x = x << 2 } return n - int(x>>31) } func (bc *bitmapContainer) maximum() uint16 { for i := len(bc.bitmap); i > 0; i-- { w := bc.bitmap[i-1] if w != 0 { r := clz(w) return uint16((i-1)*64 + 63 - r) } } return uint16(0) } func (bc *bitmapContainer) iterate(cb func(x uint16) bool) bool { iterator := bitmapContainerShortIterator{bc, bc.NextSetBit(0)} for iterator.hasNext() { if !cb(iterator.next()) { return false } } return true } type bitmapContainerShortIterator struct { ptr *bitmapContainer i int } func (bcsi *bitmapContainerShortIterator) next() uint16 { j := bcsi.i bcsi.i = bcsi.ptr.NextSetBit(uint(bcsi.i) + 1) return uint16(j) } func (bcsi *bitmapContainerShortIterator) hasNext() bool { return bcsi.i >= 0 } func (bcsi *bitmapContainerShortIterator) peekNext() uint16 { return uint16(bcsi.i) } func (bcsi *bitmapContainerShortIterator) advanceIfNeeded(minval uint16) { if bcsi.hasNext() && bcsi.peekNext() < minval { bcsi.i = bcsi.ptr.NextSetBit(uint(minval)) } } func newBitmapContainerShortIterator(a *bitmapContainer) *bitmapContainerShortIterator { return &bitmapContainerShortIterator{a, a.NextSetBit(0)} } func (bc *bitmapContainer) getShortIterator() shortPeekable { return newBitmapContainerShortIterator(bc) } type reverseBitmapContainerShortIterator struct { ptr *bitmapContainer i int } func (bcsi *reverseBitmapContainerShortIterator) next() uint16 { if bcsi.i == -1 { panic("reverseBitmapContainerShortIterator.next() going beyond what is available") } j := bcsi.i bcsi.i = bcsi.ptr.PrevSetBit(bcsi.i - 1) return uint16(j) } func (bcsi *reverseBitmapContainerShortIterator) hasNext() bool { return bcsi.i >= 0 } func newReverseBitmapContainerShortIterator(a *bitmapContainer) *reverseBitmapContainerShortIterator { if a.cardinality == 0 { return &reverseBitmapContainerShortIterator{a, -1} } return &reverseBitmapContainerShortIterator{a, int(a.maximum())} } func (bc *bitmapContainer) getReverseIterator() shortIterable { return newReverseBitmapContainerShortIterator(bc) } type bitmapContainerManyIterator struct { ptr *bitmapContainer base int bitset uint64 } func (bcmi *bitmapContainerManyIterator) nextMany(hs uint32, buf []uint32) int { n := 0 base := bcmi.base bitset := bcmi.bitset for n < len(buf) { if bitset == 0 { base++ if base >= len(bcmi.ptr.bitmap) { bcmi.base = base bcmi.bitset = bitset return n } bitset = bcmi.ptr.bitmap[base] continue } t := bitset & -bitset buf[n] = uint32(((base * 64) + int(popcount(t-1)))) | hs n = n + 1 bitset ^= t } bcmi.base = base bcmi.bitset = bitset return n } func (bcmi *bitmapContainerManyIterator) nextMany64(hs uint64, buf []uint64) int { n := 0 base := bcmi.base bitset := bcmi.bitset for n < len(buf) { if bitset == 0 { base++ if base >= len(bcmi.ptr.bitmap) { bcmi.base = base bcmi.bitset = bitset return n } bitset = bcmi.ptr.bitmap[base] continue } t := bitset & -bitset buf[n] = uint64(((base * 64) + int(popcount(t-1)))) | hs n = n + 1 bitset ^= t } bcmi.base = base bcmi.bitset = bitset return n } func newBitmapContainerManyIterator(a *bitmapContainer) *bitmapContainerManyIterator { return &bitmapContainerManyIterator{a, -1, 0} } func (bc *bitmapContainer) getManyIterator() manyIterable { return newBitmapContainerManyIterator(bc) } func (bc *bitmapContainer) getSizeInBytes() int { return len(bc.bitmap) * 8 // + bcBaseBytes } func (bc *bitmapContainer) serializedSizeInBytes() int { //return bc.Msgsize()// NOO! This breaks GetSerializedSizeInBytes return len(bc.bitmap) * 8 } const bcBaseBytes = int(unsafe.Sizeof(bitmapContainer{})) // bitmapContainer doesn't depend on card, always fully allocated func bitmapContainerSizeInBytes() int { return bcBaseBytes + (1<<16)/8 } func bitmapEquals(a, b []uint64) bool { if len(a) != len(b) { return false } for i, v := range a { if v != b[i] { return false } } return true } func (bc *bitmapContainer) fillLeastSignificant16bits(x []uint32, i int, mask uint32) { // TODO: should be written as optimized assembly pos := i base := mask for k := 0; k < len(bc.bitmap); k++ { bitset := bc.bitmap[k] for bitset != 0 { t := bitset & -bitset x[pos] = base + uint32(popcount(t-1)) pos++ bitset ^= t } base += 64 } } func (bc *bitmapContainer) equals(o container) bool { srb, ok := o.(*bitmapContainer) if ok { if srb.cardinality != bc.cardinality { return false } return bitmapEquals(bc.bitmap, srb.bitmap) } // use generic comparison if bc.getCardinality() != o.getCardinality() { return false } ait := o.getShortIterator() bit := bc.getShortIterator() for ait.hasNext() { if bit.next() != ait.next() { return false } } return true } func (bc *bitmapContainer) iaddReturnMinimized(i uint16) container { bc.iadd(i) if bc.isFull() { return newRunContainer16Range(0, MaxUint16) } return bc } func (bc *bitmapContainer) iadd(i uint16) bool { x := int(i) previous := bc.bitmap[x/64] mask := uint64(1) << (uint(x) % 64) newb := previous | mask bc.bitmap[x/64] = newb bc.cardinality += int((previous ^ newb) >> (uint(x) % 64)) return newb != previous } func (bc *bitmapContainer) iremoveReturnMinimized(i uint16) container { if bc.iremove(i) { if bc.cardinality == arrayDefaultMaxSize { return bc.toArrayContainer() } } return bc } // iremove returns true if i was found. func (bc *bitmapContainer) iremove(i uint16) bool { if bc.contains(i) { bc.cardinality-- bc.bitmap[i/64] &^= (uint64(1) << (i % 64)) return true } return false } func (bc *bitmapContainer) isFull() bool { return bc.cardinality == int(MaxUint16)+1 } func (bc *bitmapContainer) getCardinality() int { return bc.cardinality } func (bc *bitmapContainer) clone() container { ptr := bitmapContainer{bc.cardinality, make([]uint64, len(bc.bitmap))} copy(ptr.bitmap, bc.bitmap[:]) return &ptr } // add all values in range [firstOfRange,lastOfRange) func (bc *bitmapContainer) iaddRange(firstOfRange, lastOfRange int) container { bc.cardinality += setBitmapRangeAndCardinalityChange(bc.bitmap, firstOfRange, lastOfRange) return bc } // remove all values in range [firstOfRange,lastOfRange) func (bc *bitmapContainer) iremoveRange(firstOfRange, lastOfRange int) container { bc.cardinality += resetBitmapRangeAndCardinalityChange(bc.bitmap, firstOfRange, lastOfRange) if bc.getCardinality() <= arrayDefaultMaxSize { return bc.toArrayContainer() } return bc } // flip all values in range [firstOfRange,endx) func (bc *bitmapContainer) inot(firstOfRange, endx int) container { if endx-firstOfRange == maxCapacity { flipBitmapRange(bc.bitmap, firstOfRange, endx) bc.cardinality = maxCapacity - bc.cardinality } else if endx-firstOfRange > maxCapacity/2 { flipBitmapRange(bc.bitmap, firstOfRange, endx) bc.computeCardinality() } else { bc.cardinality += flipBitmapRangeAndCardinalityChange(bc.bitmap, firstOfRange, endx) } if bc.getCardinality() <= arrayDefaultMaxSize { return bc.toArrayContainer() } return bc } // flip all values in range [firstOfRange,endx) func (bc *bitmapContainer) not(firstOfRange, endx int) container { answer := bc.clone() return answer.inot(firstOfRange, endx) } func (bc *bitmapContainer) or(a container) container { switch x := a.(type) { case *arrayContainer: return bc.orArray(x) case *bitmapContainer: return bc.orBitmap(x) case *runContainer16: if x.isFull() { return x.clone() } return x.orBitmapContainer(bc) } panic("unsupported container type") } func (bc *bitmapContainer) orCardinality(a container) int { switch x := a.(type) { case *arrayContainer: return bc.orArrayCardinality(x) case *bitmapContainer: return bc.orBitmapCardinality(x) case *runContainer16: return x.orBitmapContainerCardinality(bc) } panic("unsupported container type") } func (bc *bitmapContainer) ior(a container) container { switch x := a.(type) { case *arrayContainer: return bc.iorArray(x) case *bitmapContainer: return bc.iorBitmap(x) case *runContainer16: if x.isFull() { return x.clone() } for i := range x.iv { bc.iaddRange(int(x.iv[i].start), int(x.iv[i].last())+1) } if bc.isFull() { return newRunContainer16Range(0, MaxUint16) } //bc.computeCardinality() return bc } panic(fmt.Errorf("unsupported container type %T", a)) } func (bc *bitmapContainer) lazyIOR(a container) container { switch x := a.(type) { case *arrayContainer: return bc.lazyIORArray(x) case *bitmapContainer: return bc.lazyIORBitmap(x) case *runContainer16: if x.isFull() { return x.clone() } // Manually inlined setBitmapRange function bitmap := bc.bitmap for _, iv := range x.iv { start := int(iv.start) end := int(iv.last()) + 1 if start >= end { continue } firstword := start / 64 endword := (end - 1) / 64 if firstword == endword { bitmap[firstword] |= (^uint64(0) << uint(start%64)) & (^uint64(0) >> (uint(-end) % 64)) continue } bitmap[firstword] |= ^uint64(0) << uint(start%64) for i := firstword + 1; i < endword; i++ { bitmap[i] = ^uint64(0) } bitmap[endword] |= ^uint64(0) >> (uint(-end) % 64) } bc.cardinality = invalidCardinality return bc } panic("unsupported container type") } func (bc *bitmapContainer) lazyOR(a container) container { switch x := a.(type) { case *arrayContainer: return bc.lazyORArray(x) case *bitmapContainer: return bc.lazyORBitmap(x) case *runContainer16: if x.isFull() { return x.clone() } // TODO: implement lazy OR return x.orBitmapContainer(bc) } panic("unsupported container type") } func (bc *bitmapContainer) orArray(value2 *arrayContainer) container { answer := bc.clone().(*bitmapContainer) c := value2.getCardinality() for k := 0; k < c; k++ { v := value2.content[k] i := uint(v) >> 6 bef := answer.bitmap[i] aft := bef | (uint64(1) << (v % 64)) answer.bitmap[i] = aft answer.cardinality += int((bef - aft) >> 63) } return answer } func (bc *bitmapContainer) orArrayCardinality(value2 *arrayContainer) int { answer := 0 c := value2.getCardinality() for k := 0; k < c; k++ { // branchless: v := value2.content[k] i := uint(v) >> 6 bef := bc.bitmap[i] aft := bef | (uint64(1) << (v % 64)) answer += int((bef - aft) >> 63) } return answer } func (bc *bitmapContainer) orBitmap(value2 *bitmapContainer) container { answer := newBitmapContainer() for k := 0; k < len(answer.bitmap); k++ { answer.bitmap[k] = bc.bitmap[k] | value2.bitmap[k] } answer.computeCardinality() if answer.isFull() { return newRunContainer16Range(0, MaxUint16) } return answer } func (bc *bitmapContainer) orBitmapCardinality(value2 *bitmapContainer) int { return int(popcntOrSlice(bc.bitmap, value2.bitmap)) } func (bc *bitmapContainer) andBitmapCardinality(value2 *bitmapContainer) int { return int(popcntAndSlice(bc.bitmap, value2.bitmap)) } func (bc *bitmapContainer) computeCardinality() { bc.cardinality = int(popcntSlice(bc.bitmap)) } func (bc *bitmapContainer) iorArray(ac *arrayContainer) container { for k := range ac.content { vc := ac.content[k] i := uint(vc) >> 6 bef := bc.bitmap[i] aft := bef | (uint64(1) << (vc % 64)) bc.bitmap[i] = aft bc.cardinality += int((bef - aft) >> 63) } if bc.isFull() { return newRunContainer16Range(0, MaxUint16) } return bc } func (bc *bitmapContainer) iorBitmap(value2 *bitmapContainer) container { answer := bc answer.cardinality = 0 for k := 0; k < len(answer.bitmap); k++ { answer.bitmap[k] = bc.bitmap[k] | value2.bitmap[k] } answer.computeCardinality() if bc.isFull() { return newRunContainer16Range(0, MaxUint16) } return answer } func (bc *bitmapContainer) lazyIORArray(value2 *arrayContainer) container { answer := bc c := value2.getCardinality() for k := 0; k+3 < c; k += 4 { content := (*[4]uint16)(unsafe.Pointer(&value2.content[k])) vc0 := content[0] i0 := uint(vc0) >> 6 answer.bitmap[i0] = answer.bitmap[i0] | (uint64(1) << (vc0 % 64)) vc1 := content[1] i1 := uint(vc1) >> 6 answer.bitmap[i1] = answer.bitmap[i1] | (uint64(1) << (vc1 % 64)) vc2 := content[2] i2 := uint(vc2) >> 6 answer.bitmap[i2] = answer.bitmap[i2] | (uint64(1) << (vc2 % 64)) vc3 := content[3] i3 := uint(vc3) >> 6 answer.bitmap[i3] = answer.bitmap[i3] | (uint64(1) << (vc3 % 64)) } for k := c &^ 3; k < c; k++ { vc := value2.content[k] i := uint(vc) >> 6 answer.bitmap[i] = answer.bitmap[i] | (uint64(1) << (vc % 64)) } answer.cardinality = invalidCardinality return answer } func (bc *bitmapContainer) lazyORArray(value2 *arrayContainer) container { answer := bc.clone().(*bitmapContainer) return answer.lazyIORArray(value2) } func (bc *bitmapContainer) lazyIORBitmap(value2 *bitmapContainer) container { answer := bc for k := 0; k < len(answer.bitmap); k++ { answer.bitmap[k] = bc.bitmap[k] | value2.bitmap[k] } bc.cardinality = invalidCardinality return answer } func (bc *bitmapContainer) lazyORBitmap(value2 *bitmapContainer) container { answer := bc.clone().(*bitmapContainer) return answer.lazyIORBitmap(value2) } func (bc *bitmapContainer) xor(a container) container { switch x := a.(type) { case *arrayContainer: return bc.xorArray(x) case *bitmapContainer: return bc.xorBitmap(x) case *runContainer16: return x.xorBitmap(bc) } panic("unsupported container type") } func (bc *bitmapContainer) xorArray(value2 *arrayContainer) container { answer := bc.clone().(*bitmapContainer) c := value2.getCardinality() for k := 0; k < c; k++ { vc := value2.content[k] index := uint(vc) >> 6 abi := answer.bitmap[index] mask := uint64(1) << (vc % 64) answer.cardinality += 1 - 2*int((abi&mask)>>(vc%64)) answer.bitmap[index] = abi ^ mask } if answer.cardinality <= arrayDefaultMaxSize { return answer.toArrayContainer() } return answer } func (bc *bitmapContainer) rank(x uint16) int { // TODO: rewrite in assembly leftover := (uint(x) + 1) & 63 if leftover == 0 { return int(popcntSlice(bc.bitmap[:(uint(x)+1)/64])) } return int(popcntSlice(bc.bitmap[:(uint(x)+1)/64]) + popcount(bc.bitmap[(uint(x)+1)/64]<<(64-leftover))) } func (bc *bitmapContainer) selectInt(x uint16) int { remaining := x for k := 0; k < len(bc.bitmap); k++ { w := popcount(bc.bitmap[k]) if uint16(w) > remaining { return k*64 + selectBitPosition(bc.bitmap[k], int(remaining)) } remaining -= uint16(w) } return -1 } func (bc *bitmapContainer) xorBitmap(value2 *bitmapContainer) container { newCardinality := int(popcntXorSlice(bc.bitmap, value2.bitmap)) if newCardinality > arrayDefaultMaxSize { answer := newBitmapContainer() for k := 0; k < len(answer.bitmap); k++ { answer.bitmap[k] = bc.bitmap[k] ^ value2.bitmap[k] } answer.cardinality = newCardinality if answer.isFull() { return newRunContainer16Range(0, MaxUint16) } return answer } ac := newArrayContainerSize(newCardinality) fillArrayXOR(ac.content, bc.bitmap, value2.bitmap) ac.content = ac.content[:newCardinality] return ac } func (bc *bitmapContainer) and(a container) container { switch x := a.(type) { case *arrayContainer: return bc.andArray(x) case *bitmapContainer: return bc.andBitmap(x) case *runContainer16: if x.isFull() { return bc.clone() } return x.andBitmapContainer(bc) } panic("unsupported container type") } func (bc *bitmapContainer) andCardinality(a container) int { switch x := a.(type) { case *arrayContainer: return bc.andArrayCardinality(x) case *bitmapContainer: return bc.andBitmapCardinality(x) case *runContainer16: return x.andBitmapContainerCardinality(bc) } panic("unsupported container type") } func (bc *bitmapContainer) intersects(a container) bool { switch x := a.(type) { case *arrayContainer: return bc.intersectsArray(x) case *bitmapContainer: return bc.intersectsBitmap(x) case *runContainer16: return x.intersects(bc) } panic("unsupported container type") } func (bc *bitmapContainer) iand(a container) container { switch x := a.(type) { case *arrayContainer: return bc.iandArray(x) case *bitmapContainer: return bc.iandBitmap(x) case *runContainer16: if x.isFull() { return bc.clone() } return bc.iandRun16(x) } panic("unsupported container type") } func (bc *bitmapContainer) iandRun16(rc *runContainer16) container { rcb := newBitmapContainerFromRun(rc) return bc.iandBitmap(rcb) } func (bc *bitmapContainer) iandArray(ac *arrayContainer) container { acb := ac.toBitmapContainer() return bc.iandBitmap(acb) } func (bc *bitmapContainer) andArray(value2 *arrayContainer) *arrayContainer { answer := newArrayContainerCapacity(len(value2.content)) answer.content = answer.content[:cap(answer.content)] c := value2.getCardinality() pos := 0 for k := 0; k < c; k++ { v := value2.content[k] answer.content[pos] = v pos += int(bc.bitValue(v)) } answer.content = answer.content[:pos] return answer } func (bc *bitmapContainer) andArrayCardinality(value2 *arrayContainer) int { c := value2.getCardinality() pos := 0 for k := 0; k < c; k++ { v := value2.content[k] pos += int(bc.bitValue(v)) } return pos } func (bc *bitmapContainer) getCardinalityInRange(start, end uint) int { if start >= end { return 0 } firstword := start / 64 endword := (end - 1) / 64 const allones = ^uint64(0) if firstword == endword { return int(popcount(bc.bitmap[firstword] & ((allones << (start % 64)) & (allones >> ((64 - end) & 63))))) } answer := popcount(bc.bitmap[firstword] & (allones << (start % 64))) answer += popcntSlice(bc.bitmap[firstword+1 : endword]) answer += popcount(bc.bitmap[endword] & (allones >> ((64 - end) & 63))) return int(answer) } func (bc *bitmapContainer) andBitmap(value2 *bitmapContainer) container { newcardinality := int(popcntAndSlice(bc.bitmap, value2.bitmap)) if newcardinality > arrayDefaultMaxSize { answer := newBitmapContainer() for k := 0; k < len(answer.bitmap); k++ { answer.bitmap[k] = bc.bitmap[k] & value2.bitmap[k] } answer.cardinality = newcardinality return answer } ac := newArrayContainerSize(newcardinality) fillArrayAND(ac.content, bc.bitmap, value2.bitmap) ac.content = ac.content[:newcardinality] //not sure why i need this return ac } func (bc *bitmapContainer) intersectsArray(value2 *arrayContainer) bool { c := value2.getCardinality() for k := 0; k < c; k++ { v := value2.content[k] if bc.contains(v) { return true } } return false } func (bc *bitmapContainer) intersectsBitmap(value2 *bitmapContainer) bool { for k := 0; k < len(bc.bitmap); k++ { if (bc.bitmap[k] & value2.bitmap[k]) != 0 { return true } } return false } func (bc *bitmapContainer) iandBitmap(value2 *bitmapContainer) container { newcardinality := int(popcntAndSlice(bc.bitmap, value2.bitmap)) for k := 0; k < len(bc.bitmap); k++ { bc.bitmap[k] = bc.bitmap[k] & value2.bitmap[k] } bc.cardinality = newcardinality if newcardinality <= arrayDefaultMaxSize { return newArrayContainerFromBitmap(bc) } return bc } func (bc *bitmapContainer) andNot(a container) container { switch x := a.(type) { case *arrayContainer: return bc.andNotArray(x) case *bitmapContainer: return bc.andNotBitmap(x) case *runContainer16: return bc.andNotRun16(x) } panic("unsupported container type") } func (bc *bitmapContainer) andNotRun16(rc *runContainer16) container { rcb := rc.toBitmapContainer() return bc.andNotBitmap(rcb) } func (bc *bitmapContainer) iandNot(a container) container { switch x := a.(type) { case *arrayContainer: return bc.iandNotArray(x) case *bitmapContainer: return bc.iandNotBitmapSurely(x) case *runContainer16: return bc.iandNotRun16(x) } panic("unsupported container type") } func (bc *bitmapContainer) iandNotArray(ac *arrayContainer) container { acb := ac.toBitmapContainer() return bc.iandNotBitmapSurely(acb) } func (bc *bitmapContainer) iandNotRun16(rc *runContainer16) container { rcb := rc.toBitmapContainer() return bc.iandNotBitmapSurely(rcb) } func (bc *bitmapContainer) andNotArray(value2 *arrayContainer) container { answer := bc.clone().(*bitmapContainer) c := value2.getCardinality() for k := 0; k < c; k++ { vc := value2.content[k] i := uint(vc) >> 6 oldv := answer.bitmap[i] newv := oldv &^ (uint64(1) << (vc % 64)) answer.bitmap[i] = newv answer.cardinality -= int((oldv ^ newv) >> (vc % 64)) } if answer.cardinality <= arrayDefaultMaxSize { return answer.toArrayContainer() } return answer } func (bc *bitmapContainer) andNotBitmap(value2 *bitmapContainer) container { newCardinality := int(popcntMaskSlice(bc.bitmap, value2.bitmap)) if newCardinality > arrayDefaultMaxSize { answer := newBitmapContainer() for k := 0; k < len(answer.bitmap); k++ { answer.bitmap[k] = bc.bitmap[k] &^ value2.bitmap[k] } answer.cardinality = newCardinality return answer } ac := newArrayContainerSize(newCardinality) fillArrayANDNOT(ac.content, bc.bitmap, value2.bitmap) return ac } func (bc *bitmapContainer) iandNotBitmapSurely(value2 *bitmapContainer) container { newCardinality := int(popcntMaskSlice(bc.bitmap, value2.bitmap)) for k := 0; k < len(bc.bitmap); k++ { bc.bitmap[k] = bc.bitmap[k] &^ value2.bitmap[k] } bc.cardinality = newCardinality if bc.getCardinality() <= arrayDefaultMaxSize { return bc.toArrayContainer() } return bc } func (bc *bitmapContainer) contains(i uint16) bool { //testbit x := uint(i) w := bc.bitmap[x>>6] mask := uint64(1) << (x & 63) return (w & mask) != 0 } func (bc *bitmapContainer) bitValue(i uint16) uint64 { x := uint(i) w := bc.bitmap[x>>6] return (w >> (x & 63)) & 1 } func (bc *bitmapContainer) loadData(arrayContainer *arrayContainer) { bc.cardinality = arrayContainer.getCardinality() c := arrayContainer.getCardinality() for k := 0; k < c; k++ { x := arrayContainer.content[k] i := int(x) / 64 bc.bitmap[i] |= (uint64(1) << uint(x%64)) } } func (bc *bitmapContainer) resetTo(a container) { switch x := a.(type) { case *arrayContainer: fill(bc.bitmap, 0) bc.loadData(x) case *bitmapContainer: bc.cardinality = x.cardinality copy(bc.bitmap, x.bitmap) case *runContainer16: bc.cardinality = len(x.iv) lastEnd := 0 for _, r := range x.iv { bc.cardinality += int(r.length) resetBitmapRange(bc.bitmap, lastEnd, int(r.start)) lastEnd = int(r.start+r.length) + 1 setBitmapRange(bc.bitmap, int(r.start), lastEnd) } resetBitmapRange(bc.bitmap, lastEnd, maxCapacity) default: panic("unsupported container type") } } func (bc *bitmapContainer) toArrayContainer() *arrayContainer { ac := &arrayContainer{} ac.loadData(bc) return ac } func (bc *bitmapContainer) fillArray(container []uint16) { //TODO: rewrite in assembly pos := 0 base := 0 for k := 0; k < len(bc.bitmap); k++ { bitset := bc.bitmap[k] for bitset != 0 { t := bitset & -bitset container[pos] = uint16((base + int(popcount(t-1)))) pos = pos + 1 bitset ^= t } base += 64 } } func (bc *bitmapContainer) NextSetBit(i uint) int { var ( x = i / 64 length = uint(len(bc.bitmap)) ) if x >= length { return -1 } w := bc.bitmap[x] w = w >> uint(i%64) if w != 0 { return int(i) + countTrailingZeros(w) } x++ for ; x < length; x++ { if bc.bitmap[x] != 0 { return int(x*64) + countTrailingZeros(bc.bitmap[x]) } } return -1 } func (bc *bitmapContainer) PrevSetBit(i int) int { if i < 0 { return -1 } x := i / 64 if x >= len(bc.bitmap) { return -1 } w := bc.bitmap[x] b := i % 64 w = w << uint(63-b) if w != 0 { return i - countLeadingZeros(w) } x-- for ; x >= 0; x-- { if bc.bitmap[x] != 0 { return (x * 64) + 63 - countLeadingZeros(bc.bitmap[x]) } } return -1 } // reference the java implementation // https://github.com/RoaringBitmap/RoaringBitmap/blob/master/src/main/java/org/roaringbitmap/BitmapContainer.java#L875-L892 // func (bc *bitmapContainer) numberOfRuns() int { if bc.cardinality == 0 { return 0 } var numRuns uint64 nextWord := bc.bitmap[0] for i := 0; i < len(bc.bitmap)-1; i++ { word := nextWord nextWord = bc.bitmap[i+1] numRuns += popcount((^word)&(word<<1)) + ((word >> 63) &^ nextWord) } word := nextWord numRuns += popcount((^word) & (word << 1)) if (word & 0x8000000000000000) != 0 { numRuns++ } return int(numRuns) } // convert to run or array *if needed* func (bc *bitmapContainer) toEfficientContainer() container { numRuns := bc.numberOfRuns() sizeAsRunContainer := runContainer16SerializedSizeInBytes(numRuns) sizeAsBitmapContainer := bitmapContainerSizeInBytes() card := bc.getCardinality() sizeAsArrayContainer := arrayContainerSizeInBytes(card) if sizeAsRunContainer <= minOfInt(sizeAsBitmapContainer, sizeAsArrayContainer) { return newRunContainer16FromBitmapContainer(bc) } if card <= arrayDefaultMaxSize { return bc.toArrayContainer() } return bc } func newBitmapContainerFromRun(rc *runContainer16) *bitmapContainer { if len(rc.iv) == 1 { return newBitmapContainerwithRange(int(rc.iv[0].start), int(rc.iv[0].last())) } bc := newBitmapContainer() for i := range rc.iv { setBitmapRange(bc.bitmap, int(rc.iv[i].start), int(rc.iv[i].last())+1) bc.cardinality += int(rc.iv[i].last()) + 1 - int(rc.iv[i].start) } //bc.computeCardinality() return bc } func (bc *bitmapContainer) containerType() contype { return bitmapContype } func (bc *bitmapContainer) addOffset(x uint16) []container { low := newBitmapContainer() high := newBitmapContainer() b := uint32(x) >> 6 i := uint32(x) % 64 end := uint32(1024) - b if i == 0 { copy(low.bitmap[b:], bc.bitmap[:end]) copy(high.bitmap[:b], bc.bitmap[end:]) } else { low.bitmap[b] = bc.bitmap[0] << i for k := uint32(1); k < end; k++ { newval := bc.bitmap[k] << i if newval == 0 { newval = bc.bitmap[k-1] >> (64 - i) } low.bitmap[b+k] = newval } for k := end; k < 1024; k++ { newval := bc.bitmap[k] << i if newval == 0 { newval = bc.bitmap[k-1] >> (64 - i) } high.bitmap[k-end] = newval } high.bitmap[b] = bc.bitmap[1023] >> (64 - i) } low.computeCardinality() high.computeCardinality() return []container{low, high} }