@ -846,18 +846,17 @@ func FindIntersectingPostings(p Postings, candidates []Postings) (indexes []int,
return nil , it . Err ( )
}
}
if len ( h ) == 0 {
if h . empty ( ) {
return nil , nil
}
h . Init ( )
for len ( h ) > 0 {
for ! h . empty ( ) {
if ! p . Seek ( h . At ( ) ) {
return indexes , p . Err ( )
}
if p . At ( ) == h . At ( ) {
found := heap . Pop ( & h ) . ( postingsWithIndex )
indexes = append ( indexes , found . index )
indexes = append ( indexes , h . popIndex ( ) )
} else if err := h . Next ( ) ; err != nil {
return nil , err
}
@ -869,10 +868,29 @@ func FindIntersectingPostings(p Postings, candidates []Postings) (indexes []int,
type postingsWithIndex struct {
index int
p Postings
// popped means that this postings shouldn't be considered anymore.
// See popIndex() comment to understand why we need this.
popped bool
}
type postingsWithIndexHeap [ ] postingsWithIndex
// empty checks whether the heap is empty, which is true if it has no elements, of if the smallest element is popped.
func ( h * postingsWithIndexHeap ) empty ( ) bool {
return len ( * h ) == 0 || ( * h ) [ 0 ] . popped
}
// popIndex pops the smallest heap element and returns its index.
// In our implementation we don't actually do heap.Pop(), instead we mark the element as `popped` and fix its position, which
// should be after all the non-popped elements according to our sorting strategy.
// By skipping the `heap.Pop()` call we avoid an extra allocation in this heap's Pop() implementation which returns an interface{}.
func ( h * postingsWithIndexHeap ) popIndex ( ) int {
index := ( * h ) [ 0 ] . index
( * h ) [ 0 ] . popped = true
heap . Fix ( h , 0 )
return index
}
func ( h * postingsWithIndexHeap ) Init ( ) { heap . Init ( h ) }
func ( h postingsWithIndexHeap ) At ( ) storage . SeriesRef { return h [ 0 ] . p . At ( ) }
func ( h * postingsWithIndexHeap ) Next ( ) error {
@ -886,13 +904,17 @@ func (h *postingsWithIndexHeap) Next() error {
if err := pi . p . Err ( ) ; err != nil {
return errors . Wrapf ( err , "postings %d" , pi . index )
}
heap . Pop ( h )
h . popIndex ( )
return nil
}
func ( h postingsWithIndexHeap ) Len ( ) int { return len ( h ) }
func ( h postingsWithIndexHeap ) Less ( i , j int ) bool { return h [ i ] . p . At ( ) < h [ j ] . p . At ( ) }
func ( h postingsWithIndexHeap ) Less ( i , j int ) bool {
if h [ i ] . popped != h [ j ] . popped {
return h [ j ] . popped
}
return h [ i ] . p . At ( ) < h [ j ] . p . At ( )
}
func ( h * postingsWithIndexHeap ) Swap ( i , j int ) { ( * h ) [ i ] , ( * h ) [ j ] = ( * h ) [ j ] , ( * h ) [ i ] }
func ( h * postingsWithIndexHeap ) Push ( x interface { } ) {
@ -901,6 +923,7 @@ func (h *postingsWithIndexHeap) Push(x interface{}) {
// Pop implements heap.Interface and pops the last element, which is NOT the min element,
// so this doesn't return the same heap.Pop()
// Although this method is implemented for correctness, we don't expect it to be used, see popIndex() method for details.
func ( h * postingsWithIndexHeap ) Pop ( ) interface { } {
old := * h
n := len ( old )