mirror of
https://codeberg.org/forgejo/forgejo.git
synced 2024-11-14 05:56:14 +01:00
613 lines
13 KiB
Go
613 lines
13 KiB
Go
package roaring
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import (
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"container/heap"
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"fmt"
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"runtime"
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"sync"
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)
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var defaultWorkerCount = runtime.NumCPU()
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type bitmapContainerKey struct {
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key uint16
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idx int
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bitmap *Bitmap
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}
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type multipleContainers struct {
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key uint16
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containers []container
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idx int
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}
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type keyedContainer struct {
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key uint16
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container container
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idx int
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}
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type bitmapContainerHeap []bitmapContainerKey
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func (h bitmapContainerHeap) Len() int { return len(h) }
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func (h bitmapContainerHeap) Less(i, j int) bool { return h[i].key < h[j].key }
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func (h bitmapContainerHeap) Swap(i, j int) { h[i], h[j] = h[j], h[i] }
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func (h *bitmapContainerHeap) Push(x interface{}) {
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// Push and Pop use pointer receivers because they modify the slice's length,
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// not just its contents.
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*h = append(*h, x.(bitmapContainerKey))
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}
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func (h *bitmapContainerHeap) Pop() interface{} {
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old := *h
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n := len(old)
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x := old[n-1]
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*h = old[0 : n-1]
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return x
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}
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func (h bitmapContainerHeap) Peek() bitmapContainerKey {
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return h[0]
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}
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func (h *bitmapContainerHeap) popIncrementing() (key uint16, container container) {
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k := h.Peek()
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key = k.key
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container = k.bitmap.highlowcontainer.containers[k.idx]
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newIdx := k.idx + 1
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if newIdx < k.bitmap.highlowcontainer.size() {
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k = bitmapContainerKey{
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k.bitmap.highlowcontainer.keys[newIdx],
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newIdx,
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k.bitmap,
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}
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(*h)[0] = k
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heap.Fix(h, 0)
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} else {
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heap.Pop(h)
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}
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return
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}
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func (h *bitmapContainerHeap) Next(containers []container) multipleContainers {
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if h.Len() == 0 {
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return multipleContainers{}
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}
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key, container := h.popIncrementing()
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containers = append(containers, container)
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for h.Len() > 0 && key == h.Peek().key {
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_, container = h.popIncrementing()
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containers = append(containers, container)
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}
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return multipleContainers{
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key,
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containers,
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-1,
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}
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}
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func newBitmapContainerHeap(bitmaps ...*Bitmap) bitmapContainerHeap {
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// Initialize heap
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var h bitmapContainerHeap = make([]bitmapContainerKey, 0, len(bitmaps))
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for _, bitmap := range bitmaps {
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if !bitmap.IsEmpty() {
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key := bitmapContainerKey{
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bitmap.highlowcontainer.keys[0],
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0,
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bitmap,
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}
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h = append(h, key)
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}
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}
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heap.Init(&h)
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return h
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}
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func repairAfterLazy(c container) container {
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switch t := c.(type) {
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case *bitmapContainer:
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if t.cardinality == invalidCardinality {
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t.computeCardinality()
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}
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if t.getCardinality() <= arrayDefaultMaxSize {
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return t.toArrayContainer()
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} else if c.(*bitmapContainer).isFull() {
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return newRunContainer16Range(0, MaxUint16)
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}
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}
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return c
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}
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func toBitmapContainer(c container) container {
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switch t := c.(type) {
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case *arrayContainer:
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return t.toBitmapContainer()
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case *runContainer16:
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if !t.isFull() {
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return t.toBitmapContainer()
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}
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}
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return c
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}
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func appenderRoutine(bitmapChan chan<- *Bitmap, resultChan <-chan keyedContainer, expectedKeysChan <-chan int) {
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expectedKeys := -1
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appendedKeys := 0
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var keys []uint16
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var containers []container
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for appendedKeys != expectedKeys {
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select {
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case item := <-resultChan:
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if len(keys) <= item.idx {
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keys = append(keys, make([]uint16, item.idx-len(keys)+1)...)
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containers = append(containers, make([]container, item.idx-len(containers)+1)...)
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}
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keys[item.idx] = item.key
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containers[item.idx] = item.container
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appendedKeys++
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case msg := <-expectedKeysChan:
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expectedKeys = msg
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}
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}
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answer := &Bitmap{
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roaringArray{
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make([]uint16, 0, expectedKeys),
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make([]container, 0, expectedKeys),
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make([]bool, 0, expectedKeys),
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false,
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nil,
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},
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}
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for i := range keys {
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if containers[i] != nil { // in case a resulting container was empty, see ParAnd function
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answer.highlowcontainer.appendContainer(keys[i], containers[i], false)
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}
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}
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bitmapChan <- answer
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}
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// ParHeapOr computes the union (OR) of all provided bitmaps in parallel,
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// where the parameter "parallelism" determines how many workers are to be used
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// (if it is set to 0, a default number of workers is chosen)
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// ParHeapOr uses a heap to compute the union. For rare cases it might be faster than ParOr
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func ParHeapOr(parallelism int, bitmaps ...*Bitmap) *Bitmap {
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bitmapCount := len(bitmaps)
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if bitmapCount == 0 {
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return NewBitmap()
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} else if bitmapCount == 1 {
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return bitmaps[0].Clone()
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}
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if parallelism == 0 {
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parallelism = defaultWorkerCount
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}
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h := newBitmapContainerHeap(bitmaps...)
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bitmapChan := make(chan *Bitmap)
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inputChan := make(chan multipleContainers, 128)
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resultChan := make(chan keyedContainer, 32)
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expectedKeysChan := make(chan int)
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pool := sync.Pool{
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New: func() interface{} {
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return make([]container, 0, len(bitmaps))
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},
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}
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orFunc := func() {
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// Assumes only structs with >=2 containers are passed
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for input := range inputChan {
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c := toBitmapContainer(input.containers[0]).lazyOR(input.containers[1])
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for _, next := range input.containers[2:] {
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c = c.lazyIOR(next)
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}
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c = repairAfterLazy(c)
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kx := keyedContainer{
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input.key,
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c,
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input.idx,
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}
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resultChan <- kx
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pool.Put(input.containers[:0])
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}
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}
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go appenderRoutine(bitmapChan, resultChan, expectedKeysChan)
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for i := 0; i < parallelism; i++ {
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go orFunc()
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}
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idx := 0
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for h.Len() > 0 {
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ck := h.Next(pool.Get().([]container))
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if len(ck.containers) == 1 {
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resultChan <- keyedContainer{
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ck.key,
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ck.containers[0],
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idx,
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}
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pool.Put(ck.containers[:0])
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} else {
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ck.idx = idx
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inputChan <- ck
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}
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idx++
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}
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expectedKeysChan <- idx
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bitmap := <-bitmapChan
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close(inputChan)
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close(resultChan)
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close(expectedKeysChan)
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return bitmap
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}
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// ParAnd computes the intersection (AND) of all provided bitmaps in parallel,
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// where the parameter "parallelism" determines how many workers are to be used
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// (if it is set to 0, a default number of workers is chosen)
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func ParAnd(parallelism int, bitmaps ...*Bitmap) *Bitmap {
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bitmapCount := len(bitmaps)
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if bitmapCount == 0 {
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return NewBitmap()
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} else if bitmapCount == 1 {
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return bitmaps[0].Clone()
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}
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if parallelism == 0 {
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parallelism = defaultWorkerCount
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}
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h := newBitmapContainerHeap(bitmaps...)
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bitmapChan := make(chan *Bitmap)
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inputChan := make(chan multipleContainers, 128)
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resultChan := make(chan keyedContainer, 32)
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expectedKeysChan := make(chan int)
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andFunc := func() {
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// Assumes only structs with >=2 containers are passed
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for input := range inputChan {
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c := input.containers[0].and(input.containers[1])
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for _, next := range input.containers[2:] {
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if c.getCardinality() == 0 {
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break
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}
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c = c.iand(next)
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}
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// Send a nil explicitly if the result of the intersection is an empty container
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if c.getCardinality() == 0 {
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c = nil
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}
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kx := keyedContainer{
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input.key,
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c,
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input.idx,
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}
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resultChan <- kx
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}
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}
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go appenderRoutine(bitmapChan, resultChan, expectedKeysChan)
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for i := 0; i < parallelism; i++ {
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go andFunc()
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}
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idx := 0
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for h.Len() > 0 {
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ck := h.Next(make([]container, 0, 4))
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if len(ck.containers) == bitmapCount {
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ck.idx = idx
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inputChan <- ck
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idx++
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}
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}
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expectedKeysChan <- idx
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bitmap := <-bitmapChan
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close(inputChan)
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close(resultChan)
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close(expectedKeysChan)
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return bitmap
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}
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// ParOr computes the union (OR) of all provided bitmaps in parallel,
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// where the parameter "parallelism" determines how many workers are to be used
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// (if it is set to 0, a default number of workers is chosen)
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func ParOr(parallelism int, bitmaps ...*Bitmap) *Bitmap {
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var lKey uint16 = MaxUint16
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var hKey uint16
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bitmapsFiltered := bitmaps[:0]
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for _, b := range bitmaps {
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if !b.IsEmpty() {
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bitmapsFiltered = append(bitmapsFiltered, b)
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}
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}
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bitmaps = bitmapsFiltered
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for _, b := range bitmaps {
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lKey = minOfUint16(lKey, b.highlowcontainer.keys[0])
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hKey = maxOfUint16(hKey, b.highlowcontainer.keys[b.highlowcontainer.size()-1])
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}
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if lKey == MaxUint16 && hKey == 0 {
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return New()
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} else if len(bitmaps) == 1 {
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return bitmaps[0]
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}
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keyRange := hKey - lKey + 1
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if keyRange == 1 {
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// revert to FastOr. Since the key range is 0
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// no container-level aggregation parallelism is achievable
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return FastOr(bitmaps...)
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}
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if parallelism == 0 {
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parallelism = defaultWorkerCount
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}
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var chunkSize int
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var chunkCount int
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if parallelism*4 > int(keyRange) {
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chunkSize = 1
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chunkCount = int(keyRange)
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} else {
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chunkCount = parallelism * 4
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chunkSize = (int(keyRange) + chunkCount - 1) / chunkCount
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}
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if chunkCount*chunkSize < int(keyRange) {
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// it's fine to panic to indicate an implementation error
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panic(fmt.Sprintf("invariant check failed: chunkCount * chunkSize < keyRange, %d * %d < %d", chunkCount, chunkSize, keyRange))
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}
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chunks := make([]*roaringArray, chunkCount)
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chunkSpecChan := make(chan parChunkSpec, minOfInt(maxOfInt(64, 2*parallelism), int(chunkCount)))
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chunkChan := make(chan parChunk, minOfInt(32, int(chunkCount)))
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orFunc := func() {
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for spec := range chunkSpecChan {
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ra := lazyOrOnRange(&bitmaps[0].highlowcontainer, &bitmaps[1].highlowcontainer, spec.start, spec.end)
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for _, b := range bitmaps[2:] {
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ra = lazyIOrOnRange(ra, &b.highlowcontainer, spec.start, spec.end)
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}
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for i, c := range ra.containers {
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ra.containers[i] = repairAfterLazy(c)
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}
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chunkChan <- parChunk{ra, spec.idx}
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}
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}
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for i := 0; i < parallelism; i++ {
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go orFunc()
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}
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go func() {
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for i := 0; i < chunkCount; i++ {
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spec := parChunkSpec{
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start: uint16(int(lKey) + i*chunkSize),
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end: uint16(minOfInt(int(lKey)+(i+1)*chunkSize-1, int(hKey))),
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idx: int(i),
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}
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chunkSpecChan <- spec
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}
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}()
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chunksRemaining := chunkCount
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for chunk := range chunkChan {
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chunks[chunk.idx] = chunk.ra
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chunksRemaining--
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if chunksRemaining == 0 {
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break
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}
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}
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close(chunkChan)
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close(chunkSpecChan)
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containerCount := 0
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for _, chunk := range chunks {
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containerCount += chunk.size()
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}
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result := Bitmap{
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roaringArray{
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containers: make([]container, containerCount),
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keys: make([]uint16, containerCount),
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needCopyOnWrite: make([]bool, containerCount),
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},
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}
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resultOffset := 0
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for _, chunk := range chunks {
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copy(result.highlowcontainer.containers[resultOffset:], chunk.containers)
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copy(result.highlowcontainer.keys[resultOffset:], chunk.keys)
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copy(result.highlowcontainer.needCopyOnWrite[resultOffset:], chunk.needCopyOnWrite)
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resultOffset += chunk.size()
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}
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return &result
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}
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type parChunkSpec struct {
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start uint16
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end uint16
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idx int
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}
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type parChunk struct {
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ra *roaringArray
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idx int
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}
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func (c parChunk) size() int {
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return c.ra.size()
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}
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func parNaiveStartAt(ra *roaringArray, start uint16, last uint16) int {
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for idx, key := range ra.keys {
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if key >= start && key <= last {
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return idx
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} else if key > last {
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break
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}
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}
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return ra.size()
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}
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func lazyOrOnRange(ra1, ra2 *roaringArray, start, last uint16) *roaringArray {
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answer := newRoaringArray()
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length1 := ra1.size()
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length2 := ra2.size()
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idx1 := parNaiveStartAt(ra1, start, last)
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idx2 := parNaiveStartAt(ra2, start, last)
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var key1 uint16
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var key2 uint16
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if idx1 < length1 && idx2 < length2 {
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key1 = ra1.getKeyAtIndex(idx1)
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key2 = ra2.getKeyAtIndex(idx2)
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for key1 <= last && key2 <= last {
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if key1 < key2 {
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answer.appendCopy(*ra1, idx1)
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idx1++
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if idx1 == length1 {
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break
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}
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key1 = ra1.getKeyAtIndex(idx1)
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} else if key1 > key2 {
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answer.appendCopy(*ra2, idx2)
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idx2++
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if idx2 == length2 {
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break
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}
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key2 = ra2.getKeyAtIndex(idx2)
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} else {
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c1 := ra1.getFastContainerAtIndex(idx1, false)
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answer.appendContainer(key1, c1.lazyOR(ra2.getContainerAtIndex(idx2)), false)
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idx1++
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idx2++
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if idx1 == length1 || idx2 == length2 {
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break
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}
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key1 = ra1.getKeyAtIndex(idx1)
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key2 = ra2.getKeyAtIndex(idx2)
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}
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}
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}
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if idx2 < length2 {
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key2 = ra2.getKeyAtIndex(idx2)
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for key2 <= last {
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answer.appendCopy(*ra2, idx2)
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idx2++
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if idx2 == length2 {
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break
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}
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key2 = ra2.getKeyAtIndex(idx2)
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}
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}
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if idx1 < length1 {
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key1 = ra1.getKeyAtIndex(idx1)
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for key1 <= last {
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answer.appendCopy(*ra1, idx1)
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idx1++
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if idx1 == length1 {
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break
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}
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key1 = ra1.getKeyAtIndex(idx1)
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}
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}
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return answer
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}
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func lazyIOrOnRange(ra1, ra2 *roaringArray, start, last uint16) *roaringArray {
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length1 := ra1.size()
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length2 := ra2.size()
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idx1 := 0
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idx2 := parNaiveStartAt(ra2, start, last)
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var key1 uint16
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var key2 uint16
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if idx1 < length1 && idx2 < length2 {
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key1 = ra1.getKeyAtIndex(idx1)
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key2 = ra2.getKeyAtIndex(idx2)
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for key1 <= last && key2 <= last {
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if key1 < key2 {
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idx1++
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if idx1 >= length1 {
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break
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}
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key1 = ra1.getKeyAtIndex(idx1)
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} else if key1 > key2 {
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ra1.insertNewKeyValueAt(idx1, key2, ra2.getContainerAtIndex(idx2))
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ra1.needCopyOnWrite[idx1] = true
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idx2++
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idx1++
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length1++
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if idx2 >= length2 {
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break
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}
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key2 = ra2.getKeyAtIndex(idx2)
|
|
} else {
|
|
c1 := ra1.getFastContainerAtIndex(idx1, true)
|
|
|
|
ra1.containers[idx1] = c1.lazyIOR(ra2.getContainerAtIndex(idx2))
|
|
ra1.needCopyOnWrite[idx1] = false
|
|
idx1++
|
|
idx2++
|
|
if idx1 >= length1 || idx2 >= length2 {
|
|
break
|
|
}
|
|
|
|
key1 = ra1.getKeyAtIndex(idx1)
|
|
key2 = ra2.getKeyAtIndex(idx2)
|
|
}
|
|
}
|
|
}
|
|
if idx2 < length2 {
|
|
key2 = ra2.getKeyAtIndex(idx2)
|
|
for key2 <= last {
|
|
ra1.appendCopy(*ra2, idx2)
|
|
idx2++
|
|
if idx2 >= length2 {
|
|
break
|
|
}
|
|
key2 = ra2.getKeyAtIndex(idx2)
|
|
}
|
|
}
|
|
return ra1
|
|
}
|