prometheus/tsdb/chunkenc/histo_meta.go

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// Copyright 2021 The Prometheus Authors
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package chunkenc
import "github.com/prometheus/prometheus/pkg/histogram"
func writeHistoChunkMeta(b *bstream, schema int32, posSpans, negSpans []histogram.Span) {
putInt64VBBucket(b, int64(schema))
putHistoChunkMetaSpans(b, posSpans)
putHistoChunkMetaSpans(b, negSpans)
}
func putHistoChunkMetaSpans(b *bstream, spans []histogram.Span) {
putInt64VBBucket(b, int64(len(spans)))
for _, s := range spans {
putInt64VBBucket(b, int64(s.Length))
putInt64VBBucket(b, int64(s.Offset))
}
}
func readHistoChunkMeta(b *bstreamReader) (int32, []histogram.Span, []histogram.Span, error) {
v, err := readInt64VBBucket(b)
if err != nil {
return 0, nil, nil, err
}
schema := int32(v)
posSpans, err := readHistoChunkMetaSpans(b)
if err != nil {
return 0, nil, nil, err
}
negSpans, err := readHistoChunkMetaSpans(b)
if err != nil {
return 0, nil, nil, err
}
return schema, posSpans, negSpans, nil
}
func readHistoChunkMetaSpans(b *bstreamReader) ([]histogram.Span, error) {
var spans []histogram.Span
num, err := readInt64VBBucket(b)
if err != nil {
return nil, err
}
for i := 0; i < int(num); i++ {
length, err := readInt64VBBucket(b)
if err != nil {
return nil, err
}
offset, err := readInt64VBBucket(b)
if err != nil {
return nil, err
}
spans = append(spans, histogram.Span{
Length: uint32(length),
Offset: int32(offset),
})
}
return spans, nil
}
type bucketIterator struct {
spans []histogram.Span
span int // span position of last yielded bucket
bucket int // bucket position within span of last yielded bucket
idx int // bucket index (globally across all spans) of last yielded bucket
}
func newBucketIterator(spans []histogram.Span) *bucketIterator {
b := bucketIterator{
spans: spans,
span: 0,
bucket: -1,
idx: -1,
}
if len(spans) > 0 {
b.idx += int(spans[0].Offset)
}
return &b
}
func (b *bucketIterator) Next() (int, bool) {
// we're already out of bounds
if b.span >= len(b.spans) {
return 0, false
}
try:
if b.bucket < int(b.spans[b.span].Length-1) { // try to move within same span.
b.bucket++
b.idx++
return b.idx, true
} else if b.span < len(b.spans)-1 { // try to move from one span to the next
b.span++
b.idx += int(b.spans[b.span].Offset + 1)
b.bucket = 0
if b.spans[b.span].Length == 0 {
// pathological case that should never happen. We can't use this span, let's try again.
goto try
}
return b.idx, true
}
// we're out of options
return 0, false
}
// Interjection describes that num new buckets are introduced before processing the pos'th delta from the original slice
type Interjection struct {
pos int
num int
}
// compareSpans returns the interjections to convert a slice of deltas to a new slice representing an expanded set of buckets, or false if incompatible (e.g. if buckets were removed)
// For example:
// Let's say the old buckets look like this:
// span syntax: [offset, length]
// spans : [ 0 , 2 ] [2,1] [ 3 , 2 ] [3,1] [1,1]
// bucket idx : [0] [1] 2 3 [4] 5 6 7 [8] [9] 10 11 12 [13] 14 [15]
// raw values 6 3 3 2 4 5 1
// deltas 6 -3 0 -1 2 1 -4
// But now we introduce a new bucket layout. (carefully chosen example where we have a span appended, one unchanged[*], one prepended, and two merge - in that order)
// [*] unchanged in terms of which bucket indices they represent. but to achieve that, their offset needs to change if "disrupted" by spans changing ahead of them
// \/ this one is "unchanged"
// spans : [ 0 , 3 ] [1,1] [ 1 , 4 ] [ 3 , 3 ]
// bucket idx : [0] [1] [2] 3 [4] 5 [6] [7] [8] [9] 10 11 12 [13] [14] [15]
// raw values 6 3 0 3 0 0 2 4 5 0 1
// deltas 6 -3 -3 3 -3 0 2 2 1 -5 1
// delta mods: / \ / \ / \
// note that whenever any new buckets are introduced, the subsequent "old" bucket needs to readjust its delta to the new base of 0
// thus, for the caller, who wants to transform the set of original deltas to a new set of deltas to match a new span layout that adds buckets, we simply
// need to generate a list of interjections
// note: within compareSpans we don't have to worry about the changes to the spans themselves,
// thanks to the iterators, we get to work with the more useful bucket indices (which of course directly correspond to the buckets we have to adjust)
func compareSpans(a, b []histogram.Span) ([]Interjection, bool) {
ai := newBucketIterator(a)
bi := newBucketIterator(b)
var interjections []Interjection
// when inter.num becomes > 0, this becomes a valid interjection that should be yielded when we finish a streak of new buckets
var inter Interjection
av, aok := ai.Next()
bv, bok := bi.Next()
loop:
for {
switch {
case aok && bok:
switch {
case av == bv: // Both have an identical value. move on!
// Finish WIP interjection and reset.
if inter.num > 0 {
interjections = append(interjections, inter)
}
inter.num = 0
av, aok = ai.Next()
bv, bok = bi.Next()
inter.pos++
case av < bv: // b misses a value that is in a.
return interjections, false
case av > bv: // a misses a value that is in b. Forward b and recompare.
inter.num++
bv, bok = bi.Next()
}
case aok && !bok: // b misses a value that is in a.
return interjections, false
case !aok && bok: // a misses a value that is in b. Forward b and recompare.
inter.num++
bv, bok = bi.Next()
default: // Both iterators ran out. We're done.
if inter.num > 0 {
interjections = append(interjections, inter)
}
break loop
}
}
return interjections, true
}
// interject merges 'in' with the provided interjections and writes them into
// 'out', which must already have the appropriate length.
func interject(in, out []int64, interjections []Interjection) []int64 {
var j int // Position in out.
var v int64 // The last value seen.
var interj int // The next interjection to process.
for i, d := range in {
if interj < len(interjections) && i == interjections[interj].pos {
// We have an interjection!
// Add interjection.num new delta values such that their
// bucket values equate 0.
out[j] = int64(-v)
j++
for x := 1; x < interjections[interj].num; x++ {
out[j] = 0
j++
}
interj++
// Now save the value from the input. The delta value we
// should save is the original delta value + the last
// value of the point before the interjection (to undo
// the delta that was introduced by the interjection).
out[j] = d + v
j++
v = d + v
continue
}
// If there was no interjection, the original delta is still
// valid.
out[j] = d
j++
v += d
}
switch interj {
case len(interjections):
// All interjections processed. Nothing more to do.
case len(interjections) - 1:
// One more interjection to process at the end.
out[j] = int64(-v)
j++
for x := 1; x < interjections[interj].num; x++ {
out[j] = 0
j++
}
default:
panic("unprocessed interjections left")
}
return out
}