mirror of
https://source.quilibrium.com/quilibrium/ceremonyclient.git
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2043 lines
78 KiB
Go
2043 lines
78 KiB
Go
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// Copyright 2020 The LevelDB-Go and Pebble Authors. All rights reserved. Use
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// of this source code is governed by a BSD-style license that can be found in
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// the LICENSE file.
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package manifest
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import (
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"bytes"
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"fmt"
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"math"
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"sort"
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"strings"
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"github.com/cockroachdb/errors"
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"github.com/cockroachdb/pebble/internal/base"
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"github.com/cockroachdb/pebble/internal/invariants"
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stdcmp "github.com/cockroachdb/pebble/shims/cmp"
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"github.com/cockroachdb/pebble/shims/slices"
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)
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// errInvalidL0SublevelsOpt is for use in AddL0Files when the incremental
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// sublevel generation optimization failed, and NewL0Sublevels must be called.
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var errInvalidL0SublevelsOpt = errors.New("pebble: L0 sublevel generation optimization cannot be used")
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// Intervals are of the form [start, end) with no gap between intervals. Each
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// file overlaps perfectly with a sequence of intervals. This perfect overlap
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// occurs because the union of file boundary keys is used to pick intervals.
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// However the largest key in a file is inclusive, so when it is used as
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// an interval, the actual key is ImmediateSuccessor(key). We don't have the
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// ImmediateSuccessor function to do this computation, so we instead keep an
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// isLargest bool to remind the code about this fact. This is used for
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// comparisons in the following manner:
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// - intervalKey{k, false} < intervalKey{k, true}
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// - k1 < k2 -> intervalKey{k1, _} < intervalKey{k2, _}.
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//
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// Note that the file's largest key is exclusive if the internal key
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// has a trailer matching the rangedel sentinel key. In this case, we set
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// isLargest to false for end interval computation.
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//
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// For example, consider three files with bounds [a,e], [b,g], and [e,j]. The
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// interval keys produced would be intervalKey{a, false}, intervalKey{b, false},
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// intervalKey{e, false}, intervalKey{e, true}, intervalKey{g, true} and
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// intervalKey{j, true}, resulting in intervals
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// [a, b), [b, (e, false)), [(e,false), (e, true)), [(e, true), (g, true)) and
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// [(g, true), (j, true)). The first file overlaps with the first three
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// perfectly, the second file overlaps with the second through to fourth
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// intervals, and the third file overlaps with the last three.
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//
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// The intervals are indexed starting from 0, with the index of the interval
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// being the index of the start key of the interval.
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//
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// In addition to helping with compaction picking, we use interval indices
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// to assign each file an interval range once. Subsequent operations, say
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// picking overlapping files for a compaction, only need to use the index
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// numbers and so avoid expensive byte slice comparisons.
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type intervalKey struct {
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key []byte
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isLargest bool
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}
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// intervalKeyTemp is used in the sortAndSweep step. It contains additional metadata
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// which is used to generate the {min,max}IntervalIndex for files.
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type intervalKeyTemp struct {
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intervalKey intervalKey
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fileMeta *FileMetadata
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isEndKey bool
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}
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func (i *intervalKeyTemp) setFileIntervalIndex(idx int) {
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if i.isEndKey {
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// This is the right endpoint of some file interval, so the
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// file.maxIntervalIndex must be j - 1 as maxIntervalIndex is
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// inclusive.
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i.fileMeta.maxIntervalIndex = idx - 1
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return
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}
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// This is the left endpoint for some file interval, so the
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// file.minIntervalIndex must be j.
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i.fileMeta.minIntervalIndex = idx
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}
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func intervalKeyCompare(cmp Compare, a, b intervalKey) int {
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rv := cmp(a.key, b.key)
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if rv == 0 {
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if a.isLargest && !b.isLargest {
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return +1
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}
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if !a.isLargest && b.isLargest {
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return -1
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}
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}
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return rv
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}
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type intervalKeySorter struct {
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keys []intervalKeyTemp
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cmp Compare
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}
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func (s intervalKeySorter) Len() int { return len(s.keys) }
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func (s intervalKeySorter) Less(i, j int) bool {
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return intervalKeyCompare(s.cmp, s.keys[i].intervalKey, s.keys[j].intervalKey) < 0
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}
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func (s intervalKeySorter) Swap(i, j int) {
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s.keys[i], s.keys[j] = s.keys[j], s.keys[i]
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}
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// sortAndSweep will sort the intervalKeys using intervalKeySorter, remove the
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// duplicate fileIntervals, and set the {min, max}IntervalIndex for the files.
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func sortAndSweep(keys []intervalKeyTemp, cmp Compare) []intervalKeyTemp {
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if len(keys) == 0 {
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return nil
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}
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sorter := intervalKeySorter{keys: keys, cmp: cmp}
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sort.Sort(sorter)
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// intervalKeys are generated using the file bounds. Specifically, there are
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// 2 intervalKeys for each file, and len(keys) = 2 * number of files. Each
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// `intervalKeyTemp` stores information about which file it was generated
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// from, and whether the key represents the end key of the file. So, as
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// we're deduplicating the `keys` slice, we're guaranteed to iterate over
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// the interval keys belonging to each of the files. Since the
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// file.{min,max}IntervalIndex points to the position of the files bounds in
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// the deduplicated `keys` slice, we can determine
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// file.{min,max}IntervalIndex during the iteration.
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i := 0
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j := 0
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for i < len(keys) {
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// loop invariant: j <= i
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currKey := keys[i]
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keys[j] = keys[i]
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for {
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keys[i].setFileIntervalIndex(j)
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i++
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if i >= len(keys) || intervalKeyCompare(cmp, currKey.intervalKey, keys[i].intervalKey) != 0 {
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break
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}
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}
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j++
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}
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return keys[:j]
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}
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// A key interval of the form [start, end). The end is not represented here
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// since it is implicit in the start of the next interval. The last interval is
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// an exception but we don't need to ever lookup the end of that interval; the
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// last fileInterval will only act as an end key marker. The set of intervals
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// is const after initialization.
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type fileInterval struct {
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index int
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startKey intervalKey
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// True iff some file in this interval is compacting to base. Such intervals
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// cannot have any files participate in L0 -> Lbase compactions.
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isBaseCompacting bool
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// The min and max intervals index across all the files that overlap with
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// this interval. Inclusive on both sides.
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filesMinIntervalIndex int
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filesMaxIntervalIndex int
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// True if another interval that has a file extending into this interval is
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// undergoing a compaction into Lbase. In other words, this bool is true if
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// any interval in [filesMinIntervalIndex, filesMaxIntervalIndex] has
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// isBaseCompacting set to true. This lets the compaction picker
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// de-prioritize this interval for picking compactions, since there's a high
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// chance that a base compaction with a sufficient height of sublevels
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// rooted at this interval could not be chosen due to the ongoing base
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// compaction in the other interval. If the file straddling the two
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// intervals is at a sufficiently high sublevel (with enough compactible
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// files below it to satisfy minCompactionDepth), this is not an issue, but
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// to optimize for quickly picking base compactions far away from other base
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// compactions, this bool is used as a heuristic (but not as a complete
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// disqualifier).
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intervalRangeIsBaseCompacting bool
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// All files in this interval, in increasing sublevel order.
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files []*FileMetadata
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// len(files) - compactingFileCount is the stack depth that requires
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// starting new compactions. This metric is not precise since the
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// compactingFileCount can include files that are part of N (where N > 1)
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// intra-L0 compactions, so the stack depth after those complete will be
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// len(files) - compactingFileCount + N. We ignore this imprecision since we
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// don't want to track which files are part of which intra-L0 compaction.
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compactingFileCount int
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// Interpolated from files in this interval. For files spanning multiple
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// intervals, we assume an equal distribution of bytes across all those
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// intervals.
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estimatedBytes uint64
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}
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// Helper type for any cases requiring a bool slice.
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type bitSet []bool
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func newBitSet(n int) bitSet {
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return make([]bool, n)
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}
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func (b *bitSet) markBit(i int) {
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(*b)[i] = true
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}
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func (b *bitSet) markBits(start, end int) {
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for i := start; i < end; i++ {
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(*b)[i] = true
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}
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}
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func (b *bitSet) clearAllBits() {
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for i := range *b {
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(*b)[i] = false
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}
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}
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// L0Compaction describes an active compaction with inputs from L0.
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type L0Compaction struct {
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Smallest InternalKey
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Largest InternalKey
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IsIntraL0 bool
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}
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// L0Sublevels represents a sublevel view of SSTables in L0. Tables in one
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// sublevel are non-overlapping in key ranges, and keys in higher-indexed
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// sublevels shadow older versions in lower-indexed sublevels. These invariants
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// are similar to the regular level invariants, except with higher indexed
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// sublevels having newer keys as opposed to lower indexed levels.
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//
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// There is no limit to the number of sublevels that can exist in L0 at any
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// time, however read and compaction performance is best when there are as few
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// sublevels as possible.
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type L0Sublevels struct {
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// Levels are ordered from oldest sublevel to youngest sublevel in the
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// outer slice, and the inner slice contains non-overlapping files for
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// that sublevel in increasing key order. Levels is constructed from
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// levelFiles and is used by callers that require a LevelSlice. The below two
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// fields are treated as immutable once created in NewL0Sublevels.
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Levels []LevelSlice
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levelFiles [][]*FileMetadata
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cmp Compare
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formatKey base.FormatKey
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fileBytes uint64
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// All the L0 files, ordered from oldest to youngest.
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levelMetadata *LevelMetadata
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// The file intervals in increasing key order.
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orderedIntervals []fileInterval
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// Keys to break flushes at.
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flushSplitUserKeys [][]byte
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// Only used to check invariants.
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addL0FilesCalled bool
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}
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type sublevelSorter []*FileMetadata
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// Len implements sort.Interface.
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func (sl sublevelSorter) Len() int {
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return len(sl)
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}
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// Less implements sort.Interface.
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func (sl sublevelSorter) Less(i, j int) bool {
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return sl[i].minIntervalIndex < sl[j].minIntervalIndex
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}
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// Swap implements sort.Interface.
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func (sl sublevelSorter) Swap(i, j int) {
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sl[i], sl[j] = sl[j], sl[i]
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}
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// NewL0Sublevels creates an L0Sublevels instance for a given set of L0 files.
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// These files must all be in L0 and must be sorted by seqnum (see
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// SortBySeqNum). During interval iteration, when flushSplitMaxBytes bytes are
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// exceeded in the range of intervals since the last flush split key, a flush
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// split key is added.
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//
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// This method can be called without DB.mu being held, so any DB.mu protected
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// fields in FileMetadata cannot be accessed here, such as Compacting and
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// IsIntraL0Compacting. Those fields are accessed in InitCompactingFileInfo
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// instead.
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func NewL0Sublevels(
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levelMetadata *LevelMetadata, cmp Compare, formatKey base.FormatKey, flushSplitMaxBytes int64,
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) (*L0Sublevels, error) {
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s := &L0Sublevels{cmp: cmp, formatKey: formatKey}
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s.levelMetadata = levelMetadata
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keys := make([]intervalKeyTemp, 0, 2*s.levelMetadata.Len())
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iter := levelMetadata.Iter()
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for i, f := 0, iter.First(); f != nil; i, f = i+1, iter.Next() {
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f.L0Index = i
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keys = append(keys, intervalKeyTemp{
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intervalKey: intervalKey{key: f.Smallest.UserKey},
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fileMeta: f,
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isEndKey: false,
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})
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keys = append(keys, intervalKeyTemp{
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intervalKey: intervalKey{
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key: f.Largest.UserKey,
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isLargest: !f.Largest.IsExclusiveSentinel(),
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},
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fileMeta: f,
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isEndKey: true,
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})
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}
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keys = sortAndSweep(keys, cmp)
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// All interval indices reference s.orderedIntervals.
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s.orderedIntervals = make([]fileInterval, len(keys))
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for i := range keys {
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s.orderedIntervals[i] = fileInterval{
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index: i,
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startKey: keys[i].intervalKey,
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filesMinIntervalIndex: i,
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filesMaxIntervalIndex: i,
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}
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}
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// Initialize minIntervalIndex and maxIntervalIndex for each file, and use that
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// to update intervals.
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for f := iter.First(); f != nil; f = iter.Next() {
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if err := s.addFileToSublevels(f, false /* checkInvariant */); err != nil {
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return nil, err
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}
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}
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// Sort each sublevel in increasing key order.
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for i := range s.levelFiles {
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sort.Sort(sublevelSorter(s.levelFiles[i]))
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}
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// Construct a parallel slice of sublevel B-Trees.
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// TODO(jackson): Consolidate and only use the B-Trees.
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for _, sublevelFiles := range s.levelFiles {
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tr, ls := makeBTree(btreeCmpSmallestKey(cmp), sublevelFiles)
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s.Levels = append(s.Levels, ls)
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tr.Release()
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}
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s.calculateFlushSplitKeys(flushSplitMaxBytes)
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return s, nil
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}
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// Helper function to merge new intervalKeys into an existing slice of old
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// fileIntervals, into result. Returns the new result and a slice of ints
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// mapping old interval indices to new ones. The added intervalKeys do not need
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// to be sorted; they get sorted and deduped in this function.
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func mergeIntervals(
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old, result []fileInterval, added []intervalKeyTemp, compare Compare,
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) ([]fileInterval, []int) {
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sorter := intervalKeySorter{keys: added, cmp: compare}
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sort.Sort(sorter)
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oldToNewMap := make([]int, len(old))
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i := 0
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j := 0
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for i < len(old) || j < len(added) {
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for j > 0 && j < len(added) && intervalKeyCompare(compare, added[j-1].intervalKey, added[j].intervalKey) == 0 {
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added[j].setFileIntervalIndex(len(result) - 1)
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j++
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}
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if i >= len(old) && j >= len(added) {
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break
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}
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var cmp int
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if i >= len(old) {
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cmp = +1
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}
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if j >= len(added) {
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cmp = -1
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}
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if cmp == 0 {
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cmp = intervalKeyCompare(compare, old[i].startKey, added[j].intervalKey)
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}
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switch {
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case cmp <= 0:
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// Shallow-copy the existing interval.
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newInterval := old[i]
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result = append(result, newInterval)
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oldToNewMap[i] = len(result) - 1
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i++
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if cmp == 0 {
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added[j].setFileIntervalIndex(len(result) - 1)
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j++
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}
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case cmp > 0:
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var prevInterval fileInterval
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|
// Insert a new interval for a newly-added file. prevInterval, if
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// non-zero, will be "inherited"; we copy its files as those extend
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// into this interval.
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if len(result) > 0 {
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prevInterval = result[len(result)-1]
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}
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newInterval := fileInterval{
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index: len(result),
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startKey: added[j].intervalKey,
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filesMinIntervalIndex: len(result),
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|
filesMaxIntervalIndex: len(result),
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|
|
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// estimatedBytes gets recalculated later on, as the number of intervals
|
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// the file bytes are interpolated over has changed.
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estimatedBytes: 0,
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// Copy the below attributes from prevInterval.
|
||
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files: append([]*FileMetadata(nil), prevInterval.files...),
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||
|
isBaseCompacting: prevInterval.isBaseCompacting,
|
||
|
intervalRangeIsBaseCompacting: prevInterval.intervalRangeIsBaseCompacting,
|
||
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compactingFileCount: prevInterval.compactingFileCount,
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||
|
}
|
||
|
result = append(result, newInterval)
|
||
|
added[j].setFileIntervalIndex(len(result) - 1)
|
||
|
j++
|
||
|
}
|
||
|
}
|
||
|
return result, oldToNewMap
|
||
|
}
|
||
|
|
||
|
// AddL0Files incrementally builds a new L0Sublevels for when the only change
|
||
|
// since the receiver L0Sublevels was an addition of the specified files, with
|
||
|
// no L0 deletions. The common case of this is an ingestion or a flush. These
|
||
|
// files can "sit on top" of existing sublevels, creating at most one new
|
||
|
// sublevel for a flush (and possibly multiple for an ingestion), and at most
|
||
|
// 2*len(files) additions to s.orderedIntervals. No files must have been deleted
|
||
|
// from L0, and the added files must all be newer in sequence numbers than
|
||
|
// existing files in L0Sublevels. The files parameter must be sorted in seqnum
|
||
|
// order. The levelMetadata parameter corresponds to the new L0 post addition of
|
||
|
// files. This method is meant to be significantly more performant than
|
||
|
// NewL0Sublevels.
|
||
|
//
|
||
|
// Note that this function can only be called once on a given receiver; it
|
||
|
// appends to some slices in s which is only safe when done once. This is okay,
|
||
|
// as the common case (generating a new L0Sublevels after a flush/ingestion) is
|
||
|
// only going to necessitate one call of this method on a given receiver. The
|
||
|
// returned value, if non-nil, can then have [*L0Sublevels.AddL0Files] called on
|
||
|
// it again, and so on. If [errInvalidL0SublevelsOpt] is returned as an error,
|
||
|
// it likely means the optimization could not be applied (i.e. files added were
|
||
|
// older than files already in the sublevels, which is possible around
|
||
|
// ingestions and in tests). Eg. it can happen when an ingested file was
|
||
|
// ingested without queueing a flush since it did not actually overlap with any
|
||
|
// keys in the memtable. Later on the memtable was flushed, and the memtable had
|
||
|
// keys spanning around the ingested file, producing a flushed file that
|
||
|
// overlapped with the ingested file in file bounds but not in keys. It's
|
||
|
// possible for that flushed file to have a lower LargestSeqNum than the
|
||
|
// ingested file if all the additions after the ingestion were to another
|
||
|
// flushed file that was split into a separate sstable during flush. Any other
|
||
|
// non-nil error means [L0Sublevels] generation failed in the same way as
|
||
|
// [NewL0Sublevels] would likely fail.
|
||
|
func (s *L0Sublevels) AddL0Files(
|
||
|
files []*FileMetadata, flushSplitMaxBytes int64, levelMetadata *LevelMetadata,
|
||
|
) (*L0Sublevels, error) {
|
||
|
if invariants.Enabled && s.addL0FilesCalled {
|
||
|
panic("AddL0Files called twice on the same receiver")
|
||
|
}
|
||
|
s.addL0FilesCalled = true
|
||
|
|
||
|
// Start with a shallow copy of s.
|
||
|
newVal := &L0Sublevels{}
|
||
|
*newVal = *s
|
||
|
|
||
|
newVal.addL0FilesCalled = false
|
||
|
newVal.levelMetadata = levelMetadata
|
||
|
// Deep copy levelFiles and Levels, as they are mutated and sorted below.
|
||
|
// Shallow copies of slices that we just append to, are okay.
|
||
|
newVal.levelFiles = make([][]*FileMetadata, len(s.levelFiles))
|
||
|
for i := range s.levelFiles {
|
||
|
newVal.levelFiles[i] = make([]*FileMetadata, len(s.levelFiles[i]))
|
||
|
copy(newVal.levelFiles[i], s.levelFiles[i])
|
||
|
}
|
||
|
newVal.Levels = make([]LevelSlice, len(s.Levels))
|
||
|
copy(newVal.Levels, s.Levels)
|
||
|
|
||
|
fileKeys := make([]intervalKeyTemp, 0, 2*len(files))
|
||
|
for _, f := range files {
|
||
|
left := intervalKeyTemp{
|
||
|
intervalKey: intervalKey{key: f.Smallest.UserKey},
|
||
|
fileMeta: f,
|
||
|
}
|
||
|
right := intervalKeyTemp{
|
||
|
intervalKey: intervalKey{
|
||
|
key: f.Largest.UserKey,
|
||
|
isLargest: !f.Largest.IsExclusiveSentinel(),
|
||
|
},
|
||
|
fileMeta: f,
|
||
|
isEndKey: true,
|
||
|
}
|
||
|
fileKeys = append(fileKeys, left, right)
|
||
|
}
|
||
|
keys := make([]fileInterval, 0, 2*levelMetadata.Len())
|
||
|
var oldToNewMap []int
|
||
|
// We can avoid the sortAndSweep step on the combined length of
|
||
|
// s.orderedIntervals and fileKeys by treating this as a merge of two sorted
|
||
|
// runs, fileKeys and s.orderedIntervals, into `keys` which will form
|
||
|
// newVal.orderedIntervals.
|
||
|
keys, oldToNewMap = mergeIntervals(s.orderedIntervals, keys, fileKeys, s.cmp)
|
||
|
if invariants.Enabled {
|
||
|
for i := 1; i < len(keys); i++ {
|
||
|
if intervalKeyCompare(newVal.cmp, keys[i-1].startKey, keys[i].startKey) >= 0 {
|
||
|
panic("keys not sorted correctly")
|
||
|
}
|
||
|
}
|
||
|
}
|
||
|
newVal.orderedIntervals = keys
|
||
|
// Update indices in s.orderedIntervals for fileIntervals we retained.
|
||
|
for _, newIdx := range oldToNewMap {
|
||
|
newInterval := &keys[newIdx]
|
||
|
newInterval.index = newIdx
|
||
|
// This code, and related code in the for loop below, adjusts
|
||
|
// files{Min,Max}IntervalIndex just for interval indices shifting due to
|
||
|
// new intervals, and not for any of the new files being added to the
|
||
|
// same intervals. The goal is to produce a state of the system that's
|
||
|
// accurate for all existing files, and has all the new intervals to
|
||
|
// support new files. Once that's done, we can just call
|
||
|
// addFileToSublevel to adjust all relevant intervals for new files.
|
||
|
newInterval.filesMinIntervalIndex = oldToNewMap[newInterval.filesMinIntervalIndex]
|
||
|
// maxIntervalIndexes are special. Since it's an inclusive end bound, we
|
||
|
// actually have to map it to the _next_ old interval's new previous
|
||
|
// interval. This logic is easier to understand if you see
|
||
|
// [f.minIntervalIndex, f.maxIntervalIndex] as [f.minIntervalIndex,
|
||
|
// f.maxIntervalIndex+1). The other case to remember is when the
|
||
|
// interval is completely empty (i.e. len(newInterval.files) == 0); in
|
||
|
// that case we want to refer back to ourselves regardless of additions
|
||
|
// to the right of us.
|
||
|
if newInterval.filesMaxIntervalIndex < len(oldToNewMap)-1 && len(newInterval.files) > 0 {
|
||
|
newInterval.filesMaxIntervalIndex = oldToNewMap[newInterval.filesMaxIntervalIndex+1] - 1
|
||
|
} else {
|
||
|
// newInterval.filesMaxIntervalIndex == len(oldToNewMap)-1.
|
||
|
newInterval.filesMaxIntervalIndex = oldToNewMap[newInterval.filesMaxIntervalIndex]
|
||
|
}
|
||
|
}
|
||
|
// Loop through all instances of new intervals added between two old
|
||
|
// intervals and expand [filesMinIntervalIndex, filesMaxIntervalIndex] of
|
||
|
// new intervals to reflect that of adjacent old intervals.
|
||
|
{
|
||
|
// We can skip cases where new intervals were added to the left of all
|
||
|
// existing intervals (eg. if the first entry in oldToNewMap is
|
||
|
// oldToNewMap[0] >= 1). Those intervals will only contain newly added
|
||
|
// files and will have their parameters adjusted down in
|
||
|
// addFileToSublevels. The same can also be said about new intervals
|
||
|
// that are to the right of all existing intervals.
|
||
|
lastIdx := 0
|
||
|
for _, newIdx := range oldToNewMap {
|
||
|
for i := lastIdx + 1; i < newIdx; i++ {
|
||
|
minIntervalIndex := i
|
||
|
maxIntervalIndex := i
|
||
|
if keys[lastIdx].filesMaxIntervalIndex != lastIdx {
|
||
|
// Last old interval has files extending into keys[i].
|
||
|
minIntervalIndex = keys[lastIdx].filesMinIntervalIndex
|
||
|
maxIntervalIndex = keys[lastIdx].filesMaxIntervalIndex
|
||
|
}
|
||
|
|
||
|
keys[i].filesMinIntervalIndex = minIntervalIndex
|
||
|
keys[i].filesMaxIntervalIndex = maxIntervalIndex
|
||
|
}
|
||
|
lastIdx = newIdx
|
||
|
}
|
||
|
}
|
||
|
// Go through old files and update interval indices.
|
||
|
//
|
||
|
// TODO(bilal): This is the only place in this method where we loop through
|
||
|
// all existing files, which could be much more in number than newly added
|
||
|
// files. See if we can avoid the need for this, either by getting rid of
|
||
|
// f.minIntervalIndex and f.maxIntervalIndex and calculating them on the fly
|
||
|
// with a binary search, or by only looping through files to the right of
|
||
|
// the first interval touched by this method.
|
||
|
for sublevel := range s.Levels {
|
||
|
s.Levels[sublevel].Each(func(f *FileMetadata) {
|
||
|
oldIntervalDelta := f.maxIntervalIndex - f.minIntervalIndex + 1
|
||
|
oldMinIntervalIndex := f.minIntervalIndex
|
||
|
f.minIntervalIndex = oldToNewMap[f.minIntervalIndex]
|
||
|
// maxIntervalIndex is special. Since it's an inclusive end bound,
|
||
|
// we actually have to map it to the _next_ old interval's new
|
||
|
// previous interval. This logic is easier to understand if you see
|
||
|
// [f.minIntervalIndex, f.maxIntervalIndex] as [f.minIntervalIndex,
|
||
|
// f.maxIntervalIndex+1).
|
||
|
f.maxIntervalIndex = oldToNewMap[f.maxIntervalIndex+1] - 1
|
||
|
newIntervalDelta := f.maxIntervalIndex - f.minIntervalIndex + 1
|
||
|
// Recalculate estimatedBytes for all old files across new
|
||
|
// intervals, but only if new intervals were added in between.
|
||
|
if oldIntervalDelta != newIntervalDelta {
|
||
|
// j is incremented so that oldToNewMap[j] points to the next
|
||
|
// old interval. This is used to distinguish between old
|
||
|
// intervals (i.e. ones where we need to subtract
|
||
|
// f.Size/oldIntervalDelta) from new ones (where we don't need
|
||
|
// to subtract). In both cases we need to add
|
||
|
// f.Size/newIntervalDelta.
|
||
|
j := oldMinIntervalIndex
|
||
|
for i := f.minIntervalIndex; i <= f.maxIntervalIndex; i++ {
|
||
|
if oldToNewMap[j] == i {
|
||
|
newVal.orderedIntervals[i].estimatedBytes -= f.Size / uint64(oldIntervalDelta)
|
||
|
j++
|
||
|
}
|
||
|
newVal.orderedIntervals[i].estimatedBytes += f.Size / uint64(newIntervalDelta)
|
||
|
}
|
||
|
}
|
||
|
})
|
||
|
}
|
||
|
updatedSublevels := make([]int, 0)
|
||
|
// Update interval indices for new files.
|
||
|
for i, f := range files {
|
||
|
f.L0Index = s.levelMetadata.Len() + i
|
||
|
if err := newVal.addFileToSublevels(f, true /* checkInvariant */); err != nil {
|
||
|
return nil, err
|
||
|
}
|
||
|
updatedSublevels = append(updatedSublevels, f.SubLevel)
|
||
|
}
|
||
|
|
||
|
// Sort and deduplicate updatedSublevels.
|
||
|
sort.Ints(updatedSublevels)
|
||
|
{
|
||
|
j := 0
|
||
|
for i := 1; i < len(updatedSublevels); i++ {
|
||
|
if updatedSublevels[i] != updatedSublevels[j] {
|
||
|
j++
|
||
|
updatedSublevels[j] = updatedSublevels[i]
|
||
|
}
|
||
|
}
|
||
|
updatedSublevels = updatedSublevels[:j+1]
|
||
|
}
|
||
|
|
||
|
// Sort each updated sublevel in increasing key order.
|
||
|
for _, sublevel := range updatedSublevels {
|
||
|
sort.Sort(sublevelSorter(newVal.levelFiles[sublevel]))
|
||
|
}
|
||
|
|
||
|
// Construct a parallel slice of sublevel B-Trees.
|
||
|
// TODO(jackson): Consolidate and only use the B-Trees.
|
||
|
for _, sublevel := range updatedSublevels {
|
||
|
tr, ls := makeBTree(btreeCmpSmallestKey(newVal.cmp), newVal.levelFiles[sublevel])
|
||
|
if sublevel == len(newVal.Levels) {
|
||
|
newVal.Levels = append(newVal.Levels, ls)
|
||
|
} else {
|
||
|
// sublevel < len(s.Levels). If this panics, updatedSublevels was not
|
||
|
// populated correctly.
|
||
|
newVal.Levels[sublevel] = ls
|
||
|
}
|
||
|
tr.Release()
|
||
|
}
|
||
|
|
||
|
newVal.flushSplitUserKeys = nil
|
||
|
newVal.calculateFlushSplitKeys(flushSplitMaxBytes)
|
||
|
return newVal, nil
|
||
|
}
|
||
|
|
||
|
// addFileToSublevels is called during L0Sublevels generation, and adds f to the
|
||
|
// correct sublevel's levelFiles, the relevant intervals' files slices, and sets
|
||
|
// interval indices on f. This method, if called successively on multiple files,
|
||
|
// _must_ be called on successively newer files (by seqnum). If checkInvariant
|
||
|
// is true, it could check for this in some cases and return
|
||
|
// [errInvalidL0SublevelsOpt] if that invariant isn't held.
|
||
|
func (s *L0Sublevels) addFileToSublevels(f *FileMetadata, checkInvariant bool) error {
|
||
|
// This is a simple and not very accurate estimate of the number of
|
||
|
// bytes this SSTable contributes to the intervals it is a part of.
|
||
|
//
|
||
|
// TODO(bilal): Call EstimateDiskUsage in sstable.Reader with interval
|
||
|
// bounds to get a better estimate for each interval.
|
||
|
interpolatedBytes := f.Size / uint64(f.maxIntervalIndex-f.minIntervalIndex+1)
|
||
|
s.fileBytes += f.Size
|
||
|
subLevel := 0
|
||
|
// Update state in every fileInterval for this file.
|
||
|
for i := f.minIntervalIndex; i <= f.maxIntervalIndex; i++ {
|
||
|
interval := &s.orderedIntervals[i]
|
||
|
if len(interval.files) > 0 {
|
||
|
if checkInvariant && interval.files[len(interval.files)-1].LargestSeqNum > f.LargestSeqNum {
|
||
|
// We are sliding this file "underneath" an existing file. Throw away
|
||
|
// and start over in NewL0Sublevels.
|
||
|
return errInvalidL0SublevelsOpt
|
||
|
}
|
||
|
// interval.files is sorted by sublevels, from lowest to highest.
|
||
|
// AddL0Files can only add files at sublevels higher than existing files
|
||
|
// in the same key intervals.
|
||
|
if maxSublevel := interval.files[len(interval.files)-1].SubLevel; subLevel <= maxSublevel {
|
||
|
subLevel = maxSublevel + 1
|
||
|
}
|
||
|
}
|
||
|
interval.estimatedBytes += interpolatedBytes
|
||
|
if f.minIntervalIndex < interval.filesMinIntervalIndex {
|
||
|
interval.filesMinIntervalIndex = f.minIntervalIndex
|
||
|
}
|
||
|
if f.maxIntervalIndex > interval.filesMaxIntervalIndex {
|
||
|
interval.filesMaxIntervalIndex = f.maxIntervalIndex
|
||
|
}
|
||
|
interval.files = append(interval.files, f)
|
||
|
}
|
||
|
f.SubLevel = subLevel
|
||
|
if subLevel > len(s.levelFiles) {
|
||
|
return errors.Errorf("chose a sublevel beyond allowed range of sublevels: %d vs 0-%d", subLevel, len(s.levelFiles))
|
||
|
}
|
||
|
if subLevel == len(s.levelFiles) {
|
||
|
s.levelFiles = append(s.levelFiles, []*FileMetadata{f})
|
||
|
} else {
|
||
|
s.levelFiles[subLevel] = append(s.levelFiles[subLevel], f)
|
||
|
}
|
||
|
return nil
|
||
|
}
|
||
|
|
||
|
func (s *L0Sublevels) calculateFlushSplitKeys(flushSplitMaxBytes int64) {
|
||
|
var cumulativeBytes uint64
|
||
|
// Multiply flushSplitMaxBytes by the number of sublevels. This prevents
|
||
|
// excessive flush splitting when the number of sublevels increases.
|
||
|
flushSplitMaxBytes *= int64(len(s.levelFiles))
|
||
|
for i := 0; i < len(s.orderedIntervals); i++ {
|
||
|
interval := &s.orderedIntervals[i]
|
||
|
if flushSplitMaxBytes > 0 && cumulativeBytes > uint64(flushSplitMaxBytes) &&
|
||
|
(len(s.flushSplitUserKeys) == 0 ||
|
||
|
!bytes.Equal(interval.startKey.key, s.flushSplitUserKeys[len(s.flushSplitUserKeys)-1])) {
|
||
|
s.flushSplitUserKeys = append(s.flushSplitUserKeys, interval.startKey.key)
|
||
|
cumulativeBytes = 0
|
||
|
}
|
||
|
cumulativeBytes += s.orderedIntervals[i].estimatedBytes
|
||
|
}
|
||
|
}
|
||
|
|
||
|
// InitCompactingFileInfo initializes internal flags relating to compacting
|
||
|
// files. Must be called after sublevel initialization.
|
||
|
//
|
||
|
// Requires DB.mu *and* the manifest lock to be held.
|
||
|
func (s *L0Sublevels) InitCompactingFileInfo(inProgress []L0Compaction) {
|
||
|
for i := range s.orderedIntervals {
|
||
|
s.orderedIntervals[i].compactingFileCount = 0
|
||
|
s.orderedIntervals[i].isBaseCompacting = false
|
||
|
s.orderedIntervals[i].intervalRangeIsBaseCompacting = false
|
||
|
}
|
||
|
|
||
|
iter := s.levelMetadata.Iter()
|
||
|
for f := iter.First(); f != nil; f = iter.Next() {
|
||
|
if invariants.Enabled {
|
||
|
if !bytes.Equal(s.orderedIntervals[f.minIntervalIndex].startKey.key, f.Smallest.UserKey) {
|
||
|
panic(fmt.Sprintf("f.minIntervalIndex in FileMetadata out of sync with intervals in L0Sublevels: %s != %s",
|
||
|
s.formatKey(s.orderedIntervals[f.minIntervalIndex].startKey.key), s.formatKey(f.Smallest.UserKey)))
|
||
|
}
|
||
|
if !bytes.Equal(s.orderedIntervals[f.maxIntervalIndex+1].startKey.key, f.Largest.UserKey) {
|
||
|
panic(fmt.Sprintf("f.maxIntervalIndex in FileMetadata out of sync with intervals in L0Sublevels: %s != %s",
|
||
|
s.formatKey(s.orderedIntervals[f.maxIntervalIndex+1].startKey.key), s.formatKey(f.Smallest.UserKey)))
|
||
|
}
|
||
|
}
|
||
|
if !f.IsCompacting() {
|
||
|
continue
|
||
|
}
|
||
|
if invariants.Enabled {
|
||
|
if s.cmp(s.orderedIntervals[f.minIntervalIndex].startKey.key, f.Smallest.UserKey) != 0 || s.cmp(s.orderedIntervals[f.maxIntervalIndex+1].startKey.key, f.Largest.UserKey) != 0 {
|
||
|
panic(fmt.Sprintf("file %s has inconsistent L0 Sublevel interval bounds: %s-%s, %s-%s", f.FileNum,
|
||
|
s.orderedIntervals[f.minIntervalIndex].startKey.key, s.orderedIntervals[f.maxIntervalIndex+1].startKey.key,
|
||
|
f.Smallest.UserKey, f.Largest.UserKey))
|
||
|
}
|
||
|
}
|
||
|
for i := f.minIntervalIndex; i <= f.maxIntervalIndex; i++ {
|
||
|
interval := &s.orderedIntervals[i]
|
||
|
interval.compactingFileCount++
|
||
|
if !f.IsIntraL0Compacting {
|
||
|
// If f.Compacting && !f.IsIntraL0Compacting, this file is
|
||
|
// being compacted to Lbase.
|
||
|
interval.isBaseCompacting = true
|
||
|
}
|
||
|
}
|
||
|
}
|
||
|
|
||
|
// Some intervals may be base compacting without the files contained within
|
||
|
// those intervals being marked as compacting. This is possible if the files
|
||
|
// were added after the compaction initiated, and the active compaction
|
||
|
// files straddle the input file. Mark these intervals as base compacting.
|
||
|
for _, c := range inProgress {
|
||
|
startIK := intervalKey{key: c.Smallest.UserKey, isLargest: false}
|
||
|
endIK := intervalKey{key: c.Largest.UserKey, isLargest: !c.Largest.IsExclusiveSentinel()}
|
||
|
start, _ := slices.BinarySearchFunc(s.orderedIntervals, startIK, func(a fileInterval, b intervalKey) int {
|
||
|
return intervalKeyCompare(s.cmp, a.startKey, b)
|
||
|
})
|
||
|
end, _ := slices.BinarySearchFunc(s.orderedIntervals, endIK, func(a fileInterval, b intervalKey) int {
|
||
|
return intervalKeyCompare(s.cmp, a.startKey, b)
|
||
|
})
|
||
|
for i := start; i < end && i < len(s.orderedIntervals); i++ {
|
||
|
interval := &s.orderedIntervals[i]
|
||
|
if !c.IsIntraL0 {
|
||
|
interval.isBaseCompacting = true
|
||
|
}
|
||
|
}
|
||
|
}
|
||
|
|
||
|
min := 0
|
||
|
for i := range s.orderedIntervals {
|
||
|
interval := &s.orderedIntervals[i]
|
||
|
if interval.isBaseCompacting {
|
||
|
minIndex := interval.filesMinIntervalIndex
|
||
|
if minIndex < min {
|
||
|
minIndex = min
|
||
|
}
|
||
|
for j := minIndex; j <= interval.filesMaxIntervalIndex; j++ {
|
||
|
min = j
|
||
|
s.orderedIntervals[j].intervalRangeIsBaseCompacting = true
|
||
|
}
|
||
|
}
|
||
|
}
|
||
|
}
|
||
|
|
||
|
// String produces a string containing useful debug information. Useful in test
|
||
|
// code and debugging.
|
||
|
func (s *L0Sublevels) String() string {
|
||
|
return s.describe(false)
|
||
|
}
|
||
|
|
||
|
func (s *L0Sublevels) describe(verbose bool) string {
|
||
|
var buf strings.Builder
|
||
|
fmt.Fprintf(&buf, "file count: %d, sublevels: %d, intervals: %d\nflush split keys(%d): [",
|
||
|
s.levelMetadata.Len(), len(s.levelFiles), len(s.orderedIntervals), len(s.flushSplitUserKeys))
|
||
|
for i := range s.flushSplitUserKeys {
|
||
|
fmt.Fprintf(&buf, "%s", s.formatKey(s.flushSplitUserKeys[i]))
|
||
|
if i < len(s.flushSplitUserKeys)-1 {
|
||
|
fmt.Fprintf(&buf, ", ")
|
||
|
}
|
||
|
}
|
||
|
fmt.Fprintln(&buf, "]")
|
||
|
numCompactingFiles := 0
|
||
|
for i := len(s.levelFiles) - 1; i >= 0; i-- {
|
||
|
maxIntervals := 0
|
||
|
sumIntervals := 0
|
||
|
var totalBytes uint64
|
||
|
for _, f := range s.levelFiles[i] {
|
||
|
intervals := f.maxIntervalIndex - f.minIntervalIndex + 1
|
||
|
if intervals > maxIntervals {
|
||
|
maxIntervals = intervals
|
||
|
}
|
||
|
sumIntervals += intervals
|
||
|
totalBytes += f.Size
|
||
|
if f.IsCompacting() {
|
||
|
numCompactingFiles++
|
||
|
}
|
||
|
}
|
||
|
fmt.Fprintf(&buf, "0.%d: file count: %d, bytes: %d, width (mean, max): %0.1f, %d, interval range: [%d, %d]\n",
|
||
|
i, len(s.levelFiles[i]), totalBytes, float64(sumIntervals)/float64(len(s.levelFiles[i])), maxIntervals, s.levelFiles[i][0].minIntervalIndex,
|
||
|
s.levelFiles[i][len(s.levelFiles[i])-1].maxIntervalIndex)
|
||
|
for _, f := range s.levelFiles[i] {
|
||
|
intervals := f.maxIntervalIndex - f.minIntervalIndex + 1
|
||
|
if verbose {
|
||
|
fmt.Fprintf(&buf, "\t%s\n", f)
|
||
|
}
|
||
|
if s.levelMetadata.Len() > 50 && intervals*3 > len(s.orderedIntervals) {
|
||
|
var intervalsBytes uint64
|
||
|
for k := f.minIntervalIndex; k <= f.maxIntervalIndex; k++ {
|
||
|
intervalsBytes += s.orderedIntervals[k].estimatedBytes
|
||
|
}
|
||
|
fmt.Fprintf(&buf, "wide file: %d, [%d, %d], byte fraction: %f\n",
|
||
|
f.FileNum, f.minIntervalIndex, f.maxIntervalIndex,
|
||
|
float64(intervalsBytes)/float64(s.fileBytes))
|
||
|
}
|
||
|
}
|
||
|
}
|
||
|
|
||
|
lastCompactingIntervalStart := -1
|
||
|
fmt.Fprintf(&buf, "compacting file count: %d, base compacting intervals: ", numCompactingFiles)
|
||
|
i := 0
|
||
|
foundBaseCompactingIntervals := false
|
||
|
for ; i < len(s.orderedIntervals); i++ {
|
||
|
interval := &s.orderedIntervals[i]
|
||
|
if len(interval.files) == 0 {
|
||
|
continue
|
||
|
}
|
||
|
if !interval.isBaseCompacting {
|
||
|
if lastCompactingIntervalStart != -1 {
|
||
|
if foundBaseCompactingIntervals {
|
||
|
buf.WriteString(", ")
|
||
|
}
|
||
|
fmt.Fprintf(&buf, "[%d, %d]", lastCompactingIntervalStart, i-1)
|
||
|
foundBaseCompactingIntervals = true
|
||
|
}
|
||
|
lastCompactingIntervalStart = -1
|
||
|
} else {
|
||
|
if lastCompactingIntervalStart == -1 {
|
||
|
lastCompactingIntervalStart = i
|
||
|
}
|
||
|
}
|
||
|
}
|
||
|
if lastCompactingIntervalStart != -1 {
|
||
|
if foundBaseCompactingIntervals {
|
||
|
buf.WriteString(", ")
|
||
|
}
|
||
|
fmt.Fprintf(&buf, "[%d, %d]", lastCompactingIntervalStart, i-1)
|
||
|
} else if !foundBaseCompactingIntervals {
|
||
|
fmt.Fprintf(&buf, "none")
|
||
|
}
|
||
|
fmt.Fprintln(&buf, "")
|
||
|
return buf.String()
|
||
|
}
|
||
|
|
||
|
// ReadAmplification returns the contribution of L0Sublevels to the read
|
||
|
// amplification for any particular point key. It is the maximum height of any
|
||
|
// tracked fileInterval. This is always less than or equal to the number of
|
||
|
// sublevels.
|
||
|
func (s *L0Sublevels) ReadAmplification() int {
|
||
|
amp := 0
|
||
|
for i := range s.orderedIntervals {
|
||
|
interval := &s.orderedIntervals[i]
|
||
|
fileCount := len(interval.files)
|
||
|
if amp < fileCount {
|
||
|
amp = fileCount
|
||
|
}
|
||
|
}
|
||
|
return amp
|
||
|
}
|
||
|
|
||
|
// UserKeyRange encodes a key range in user key space. A UserKeyRange's Start
|
||
|
// and End boundaries are both inclusive.
|
||
|
type UserKeyRange struct {
|
||
|
Start, End []byte
|
||
|
}
|
||
|
|
||
|
// InUseKeyRanges returns the merged table bounds of L0 files overlapping the
|
||
|
// provided user key range. The returned key ranges are sorted and
|
||
|
// nonoverlapping.
|
||
|
func (s *L0Sublevels) InUseKeyRanges(smallest, largest []byte) []UserKeyRange {
|
||
|
// Binary search to find the provided keys within the intervals.
|
||
|
startIK := intervalKey{key: smallest, isLargest: false}
|
||
|
endIK := intervalKey{key: largest, isLargest: true}
|
||
|
start := sort.Search(len(s.orderedIntervals), func(i int) bool {
|
||
|
return intervalKeyCompare(s.cmp, s.orderedIntervals[i].startKey, startIK) > 0
|
||
|
})
|
||
|
if start > 0 {
|
||
|
// Back up to the first interval with a start key <= startIK.
|
||
|
start--
|
||
|
}
|
||
|
end := sort.Search(len(s.orderedIntervals), func(i int) bool {
|
||
|
return intervalKeyCompare(s.cmp, s.orderedIntervals[i].startKey, endIK) > 0
|
||
|
})
|
||
|
|
||
|
var keyRanges []UserKeyRange
|
||
|
var curr *UserKeyRange
|
||
|
for i := start; i < end; {
|
||
|
// Intervals with no files are not in use and can be skipped, once we
|
||
|
// end the current UserKeyRange.
|
||
|
if len(s.orderedIntervals[i].files) == 0 {
|
||
|
curr = nil
|
||
|
i++
|
||
|
continue
|
||
|
}
|
||
|
|
||
|
// If curr is nil, start a new in-use key range.
|
||
|
if curr == nil {
|
||
|
keyRanges = append(keyRanges, UserKeyRange{
|
||
|
Start: s.orderedIntervals[i].startKey.key,
|
||
|
})
|
||
|
curr = &keyRanges[len(keyRanges)-1]
|
||
|
}
|
||
|
|
||
|
// If the filesMaxIntervalIndex is not the current index, we can jump to
|
||
|
// the max index, knowing that all intermediary intervals are overlapped
|
||
|
// by some file.
|
||
|
if maxIdx := s.orderedIntervals[i].filesMaxIntervalIndex; maxIdx != i {
|
||
|
// Note that end may be less than or equal to maxIdx if we're
|
||
|
// concerned with a key range that ends before the interval at
|
||
|
// maxIdx starts. We must set curr.End now, before making that leap,
|
||
|
// because this iteration may be the last.
|
||
|
i = maxIdx
|
||
|
curr.End = s.orderedIntervals[i+1].startKey.key
|
||
|
continue
|
||
|
}
|
||
|
|
||
|
// No files overlapping with this interval overlap with the next
|
||
|
// interval. Update the current end to be the next interval's start key.
|
||
|
// Note that curr is not necessarily finished, because there may be an
|
||
|
// abutting non-empty interval.
|
||
|
curr.End = s.orderedIntervals[i+1].startKey.key
|
||
|
i++
|
||
|
}
|
||
|
return keyRanges
|
||
|
}
|
||
|
|
||
|
// FlushSplitKeys returns a slice of user keys to split flushes at. Used by
|
||
|
// flushes to avoid writing sstables that straddle these split keys. These
|
||
|
// should be interpreted as the keys to start the next sstable (not the last key
|
||
|
// to include in the prev sstable). These are user keys so that range tombstones
|
||
|
// can be properly truncated (untruncated range tombstones are not permitted for
|
||
|
// L0 files).
|
||
|
func (s *L0Sublevels) FlushSplitKeys() [][]byte {
|
||
|
return s.flushSplitUserKeys
|
||
|
}
|
||
|
|
||
|
// MaxDepthAfterOngoingCompactions returns an estimate of maximum depth of
|
||
|
// sublevels after all ongoing compactions run to completion. Used by compaction
|
||
|
// picker to decide compaction score for L0. There is no scoring for intra-L0
|
||
|
// compactions -- they only run if L0 score is high but we're unable to pick an
|
||
|
// L0 -> Lbase compaction.
|
||
|
func (s *L0Sublevels) MaxDepthAfterOngoingCompactions() int {
|
||
|
depth := 0
|
||
|
for i := range s.orderedIntervals {
|
||
|
interval := &s.orderedIntervals[i]
|
||
|
intervalDepth := len(interval.files) - interval.compactingFileCount
|
||
|
if depth < intervalDepth {
|
||
|
depth = intervalDepth
|
||
|
}
|
||
|
}
|
||
|
return depth
|
||
|
}
|
||
|
|
||
|
// Only for temporary debugging in the absence of proper tests.
|
||
|
//
|
||
|
// TODO(bilal): Simplify away the debugging statements in this method, and make
|
||
|
// this a pure sanity checker.
|
||
|
//
|
||
|
//lint:ignore U1000 - useful for debugging
|
||
|
func (s *L0Sublevels) checkCompaction(c *L0CompactionFiles) error {
|
||
|
includedFiles := newBitSet(s.levelMetadata.Len())
|
||
|
fileIntervalsByLevel := make([]struct {
|
||
|
min int
|
||
|
max int
|
||
|
}, len(s.levelFiles))
|
||
|
for i := range fileIntervalsByLevel {
|
||
|
fileIntervalsByLevel[i].min = math.MaxInt32
|
||
|
fileIntervalsByLevel[i].max = 0
|
||
|
}
|
||
|
var topLevel int
|
||
|
var increment int
|
||
|
var limitReached func(int) bool
|
||
|
if c.isIntraL0 {
|
||
|
topLevel = len(s.levelFiles) - 1
|
||
|
increment = +1
|
||
|
limitReached = func(level int) bool {
|
||
|
return level == len(s.levelFiles)
|
||
|
}
|
||
|
} else {
|
||
|
topLevel = 0
|
||
|
increment = -1
|
||
|
limitReached = func(level int) bool {
|
||
|
return level < 0
|
||
|
}
|
||
|
}
|
||
|
for _, f := range c.Files {
|
||
|
if fileIntervalsByLevel[f.SubLevel].min > f.minIntervalIndex {
|
||
|
fileIntervalsByLevel[f.SubLevel].min = f.minIntervalIndex
|
||
|
}
|
||
|
if fileIntervalsByLevel[f.SubLevel].max < f.maxIntervalIndex {
|
||
|
fileIntervalsByLevel[f.SubLevel].max = f.maxIntervalIndex
|
||
|
}
|
||
|
includedFiles.markBit(f.L0Index)
|
||
|
if c.isIntraL0 {
|
||
|
if topLevel > f.SubLevel {
|
||
|
topLevel = f.SubLevel
|
||
|
}
|
||
|
} else {
|
||
|
if topLevel < f.SubLevel {
|
||
|
topLevel = f.SubLevel
|
||
|
}
|
||
|
}
|
||
|
}
|
||
|
min := fileIntervalsByLevel[topLevel].min
|
||
|
max := fileIntervalsByLevel[topLevel].max
|
||
|
for level := topLevel; !limitReached(level); level += increment {
|
||
|
if fileIntervalsByLevel[level].min < min {
|
||
|
min = fileIntervalsByLevel[level].min
|
||
|
}
|
||
|
if fileIntervalsByLevel[level].max > max {
|
||
|
max = fileIntervalsByLevel[level].max
|
||
|
}
|
||
|
index, _ := slices.BinarySearchFunc(s.levelFiles[level], min, func(a *FileMetadata, b int) int {
|
||
|
return stdcmp.Compare(a.maxIntervalIndex, b)
|
||
|
})
|
||
|
// start := index
|
||
|
for ; index < len(s.levelFiles[level]); index++ {
|
||
|
f := s.levelFiles[level][index]
|
||
|
if f.minIntervalIndex > max {
|
||
|
break
|
||
|
}
|
||
|
if c.isIntraL0 && f.LargestSeqNum >= c.earliestUnflushedSeqNum {
|
||
|
return errors.Errorf(
|
||
|
"sstable %s in compaction has sequence numbers higher than the earliest unflushed seqnum %d: %d-%d",
|
||
|
f.FileNum, c.earliestUnflushedSeqNum, f.SmallestSeqNum,
|
||
|
f.LargestSeqNum)
|
||
|
}
|
||
|
if !includedFiles[f.L0Index] {
|
||
|
var buf strings.Builder
|
||
|
fmt.Fprintf(&buf, "bug %t, seed interval: %d: level %d, sl index %d, f.index %d, min %d, max %d, pre-min %d, pre-max %d, f.min %d, f.max %d, filenum: %d, isCompacting: %t\n%s\n",
|
||
|
c.isIntraL0, c.seedInterval, level, index, f.L0Index, min, max, c.preExtensionMinInterval, c.preExtensionMaxInterval,
|
||
|
f.minIntervalIndex, f.maxIntervalIndex,
|
||
|
f.FileNum, f.IsCompacting(), s)
|
||
|
fmt.Fprintf(&buf, "files included:\n")
|
||
|
for _, f := range c.Files {
|
||
|
fmt.Fprintf(&buf, "filenum: %d, sl: %d, index: %d, [%d, %d]\n",
|
||
|
f.FileNum, f.SubLevel, f.L0Index, f.minIntervalIndex, f.maxIntervalIndex)
|
||
|
}
|
||
|
fmt.Fprintf(&buf, "files added:\n")
|
||
|
for _, f := range c.filesAdded {
|
||
|
fmt.Fprintf(&buf, "filenum: %d, sl: %d, index: %d, [%d, %d]\n",
|
||
|
f.FileNum, f.SubLevel, f.L0Index, f.minIntervalIndex, f.maxIntervalIndex)
|
||
|
}
|
||
|
return errors.New(buf.String())
|
||
|
}
|
||
|
}
|
||
|
}
|
||
|
return nil
|
||
|
}
|
||
|
|
||
|
// UpdateStateForStartedCompaction updates internal L0Sublevels state for a
|
||
|
// recently started compaction. isBase specifies if this is a base compaction;
|
||
|
// if false, this is assumed to be an intra-L0 compaction. The specified
|
||
|
// compaction must be involving L0 SSTables. It's assumed that the Compacting
|
||
|
// and IsIntraL0Compacting fields are already set on all [FileMetadata]s passed
|
||
|
// in.
|
||
|
func (s *L0Sublevels) UpdateStateForStartedCompaction(inputs []LevelSlice, isBase bool) error {
|
||
|
minIntervalIndex := -1
|
||
|
maxIntervalIndex := 0
|
||
|
for i := range inputs {
|
||
|
iter := inputs[i].Iter()
|
||
|
for f := iter.First(); f != nil; f = iter.Next() {
|
||
|
for i := f.minIntervalIndex; i <= f.maxIntervalIndex; i++ {
|
||
|
interval := &s.orderedIntervals[i]
|
||
|
interval.compactingFileCount++
|
||
|
}
|
||
|
if f.minIntervalIndex < minIntervalIndex || minIntervalIndex == -1 {
|
||
|
minIntervalIndex = f.minIntervalIndex
|
||
|
}
|
||
|
if f.maxIntervalIndex > maxIntervalIndex {
|
||
|
maxIntervalIndex = f.maxIntervalIndex
|
||
|
}
|
||
|
}
|
||
|
}
|
||
|
if isBase {
|
||
|
for i := minIntervalIndex; i <= maxIntervalIndex; i++ {
|
||
|
interval := &s.orderedIntervals[i]
|
||
|
interval.isBaseCompacting = isBase
|
||
|
for j := interval.filesMinIntervalIndex; j <= interval.filesMaxIntervalIndex; j++ {
|
||
|
s.orderedIntervals[j].intervalRangeIsBaseCompacting = true
|
||
|
}
|
||
|
}
|
||
|
}
|
||
|
return nil
|
||
|
}
|
||
|
|
||
|
// L0CompactionFiles represents a candidate set of L0 files for compaction. Also
|
||
|
// referred to as "lcf". Contains state information useful for generating the
|
||
|
// compaction (such as Files), as well as for picking between candidate
|
||
|
// compactions (eg. fileBytes and seedIntervalStackDepthReduction).
|
||
|
type L0CompactionFiles struct {
|
||
|
Files []*FileMetadata
|
||
|
|
||
|
FilesIncluded bitSet
|
||
|
// A "seed interval" is an interval with a high stack depth that was chosen
|
||
|
// to bootstrap this compaction candidate. seedIntervalStackDepthReduction
|
||
|
// is the number of sublevels that have a file in the seed interval that is
|
||
|
// a part of this compaction.
|
||
|
seedIntervalStackDepthReduction int
|
||
|
// For base compactions, seedIntervalMinLevel is 0, and for intra-L0
|
||
|
// compactions, seedIntervalMaxLevel is len(s.Files)-1 i.e. the highest
|
||
|
// sublevel.
|
||
|
seedIntervalMinLevel int
|
||
|
seedIntervalMaxLevel int
|
||
|
// Index of the seed interval.
|
||
|
seedInterval int
|
||
|
// Sum of file sizes for all files in this compaction.
|
||
|
fileBytes uint64
|
||
|
// Intervals with index [minIntervalIndex, maxIntervalIndex] are
|
||
|
// participating in this compaction; it's the union set of all intervals
|
||
|
// overlapped by participating files.
|
||
|
minIntervalIndex int
|
||
|
maxIntervalIndex int
|
||
|
|
||
|
// Set for intra-L0 compactions. SSTables with sequence numbers greater
|
||
|
// than earliestUnflushedSeqNum cannot be a part of intra-L0 compactions.
|
||
|
isIntraL0 bool
|
||
|
earliestUnflushedSeqNum uint64
|
||
|
|
||
|
// For debugging purposes only. Used in checkCompaction().
|
||
|
preExtensionMinInterval int
|
||
|
preExtensionMaxInterval int
|
||
|
filesAdded []*FileMetadata
|
||
|
}
|
||
|
|
||
|
// Clone allocates a new L0CompactionFiles, with the same underlying data. Note
|
||
|
// that the two fileMetadata slices contain values that point to the same
|
||
|
// underlying fileMetadata object. This is safe because these objects are read
|
||
|
// only.
|
||
|
func (l *L0CompactionFiles) Clone() *L0CompactionFiles {
|
||
|
oldLcf := *l
|
||
|
return &oldLcf
|
||
|
}
|
||
|
|
||
|
// String merely prints the starting address of the first file, if it exists.
|
||
|
func (l *L0CompactionFiles) String() string {
|
||
|
if len(l.Files) > 0 {
|
||
|
return fmt.Sprintf("First File Address: %p", &l.Files[0])
|
||
|
}
|
||
|
return ""
|
||
|
}
|
||
|
|
||
|
// addFile adds the specified file to the LCF.
|
||
|
func (l *L0CompactionFiles) addFile(f *FileMetadata) {
|
||
|
if l.FilesIncluded[f.L0Index] {
|
||
|
return
|
||
|
}
|
||
|
l.FilesIncluded.markBit(f.L0Index)
|
||
|
l.Files = append(l.Files, f)
|
||
|
l.filesAdded = append(l.filesAdded, f)
|
||
|
l.fileBytes += f.Size
|
||
|
if f.minIntervalIndex < l.minIntervalIndex {
|
||
|
l.minIntervalIndex = f.minIntervalIndex
|
||
|
}
|
||
|
if f.maxIntervalIndex > l.maxIntervalIndex {
|
||
|
l.maxIntervalIndex = f.maxIntervalIndex
|
||
|
}
|
||
|
}
|
||
|
|
||
|
// Helper to order intervals being considered for compaction.
|
||
|
type intervalAndScore struct {
|
||
|
interval int
|
||
|
score int
|
||
|
}
|
||
|
type intervalSorterByDecreasingScore []intervalAndScore
|
||
|
|
||
|
func (is intervalSorterByDecreasingScore) Len() int { return len(is) }
|
||
|
func (is intervalSorterByDecreasingScore) Less(i, j int) bool {
|
||
|
return is[i].score > is[j].score
|
||
|
}
|
||
|
func (is intervalSorterByDecreasingScore) Swap(i, j int) {
|
||
|
is[i], is[j] = is[j], is[i]
|
||
|
}
|
||
|
|
||
|
// Compactions:
|
||
|
//
|
||
|
// The sub-levels and intervals can be visualized in 2 dimensions as the X axis
|
||
|
// containing intervals in increasing order and the Y axis containing sub-levels
|
||
|
// (older to younger). The intervals can be sparse wrt sub-levels. We observe
|
||
|
// that the system is typically under severe pressure in L0 during large numbers
|
||
|
// of ingestions where most files added to L0 are narrow and non-overlapping.
|
||
|
//
|
||
|
// L0.1 d---g
|
||
|
// L0.0 c--e g--j o--s u--x
|
||
|
//
|
||
|
// As opposed to a case with a lot of wide, overlapping L0 files:
|
||
|
//
|
||
|
// L0.3 d-----------r
|
||
|
// L0.2 c--------o
|
||
|
// L0.1 b-----------q
|
||
|
// L0.0 a----------------x
|
||
|
//
|
||
|
// In that case we expect the rectangle represented in the good visualization
|
||
|
// above (i.e. the first one) to be wide and short, and not too sparse (most
|
||
|
// intervals will have fileCount close to the sub-level count), which would make
|
||
|
// it amenable to concurrent L0 -> Lbase compactions.
|
||
|
//
|
||
|
// L0 -> Lbase: The high-level goal of a L0 -> Lbase compaction is to reduce
|
||
|
// stack depth, by compacting files in the intervals with the highest (fileCount
|
||
|
// - compactingCount). Additionally, we would like compactions to not involve a
|
||
|
// huge number of files, so that they finish quickly, and to allow for
|
||
|
// concurrent L0 -> Lbase compactions when needed. In order to achieve these
|
||
|
// goals we would like compactions to visualize as capturing thin and tall
|
||
|
// rectangles. The approach below is to consider intervals in some order and
|
||
|
// then try to construct a compaction using the interval. The first interval we
|
||
|
// can construct a compaction for is the compaction that is started. There can
|
||
|
// be multiple heuristics in choosing the ordering of the intervals -- the code
|
||
|
// uses one heuristic that worked well for a large ingestion stemming from a
|
||
|
// cockroachdb import, but additional experimentation is necessary to pick a
|
||
|
// general heuristic. Additionally, the compaction that gets picked may be not
|
||
|
// as desirable as one that could be constructed later in terms of reducing
|
||
|
// stack depth (since adding more files to the compaction can get blocked by
|
||
|
// needing to encompass files that are already being compacted). So an
|
||
|
// alternative would be to try to construct more than one compaction and pick
|
||
|
// the best one.
|
||
|
//
|
||
|
// Here's a visualization of an ideal L0->LBase compaction selection:
|
||
|
//
|
||
|
// L0.3 a--d g-j
|
||
|
// L0.2 f--j r-t
|
||
|
// L0.1 b-d e---j
|
||
|
// L0.0 a--d f--j l--o p-----x
|
||
|
//
|
||
|
// Lbase a--------i m---------w
|
||
|
//
|
||
|
// The [g,j] interval has the highest stack depth, so it would have the highest
|
||
|
// priority for selecting a base compaction candidate. Assuming none of the
|
||
|
// files are already compacting, this is the compaction that will be chosen:
|
||
|
//
|
||
|
// _______
|
||
|
// L0.3 a--d | g-j|
|
||
|
// L0.2 | f--j| r-t
|
||
|
// L0.1 b-d |e---j|
|
||
|
// L0.0 a--d | f--j| l--o p-----x
|
||
|
//
|
||
|
// Lbase a--------i m---------w
|
||
|
//
|
||
|
// Note that running this compaction will mark the a--i file in Lbase as
|
||
|
// compacting, and when ExtendL0ForBaseCompactionTo is called with the bounds of
|
||
|
// that base file, it'll expand the compaction to also include all L0 files in
|
||
|
// the a-d interval. The resultant compaction would then be:
|
||
|
//
|
||
|
// _____________
|
||
|
// L0.3 |a--d g-j|
|
||
|
// L0.2 | f--j| r-t
|
||
|
// L0.1 | b-d e---j|
|
||
|
// L0.0 |a--d f--j| l--o p-----x
|
||
|
//
|
||
|
// Lbase a--------i m---------w
|
||
|
//
|
||
|
// The next best interval for base compaction would therefore be the one
|
||
|
// including r--t in L0.2 and p--x in L0.0, and both this compaction and the one
|
||
|
// picked earlier can run in parallel. This is assuming minCompactionDepth >= 2,
|
||
|
// otherwise the second compaction has too little depth to pick.
|
||
|
//
|
||
|
// _____________
|
||
|
// L0.3 |a--d g-j| _________
|
||
|
// L0.2 | f--j| | r-t |
|
||
|
// L0.1 | b-d e---j| | |
|
||
|
// L0.0 |a--d f--j| l--o |p-----x|
|
||
|
//
|
||
|
// Lbase a--------i m---------w
|
||
|
//
|
||
|
// Note that when ExtendL0ForBaseCompactionTo is called, the compaction expands
|
||
|
// to the following, given that the [l,o] file can be added without including
|
||
|
// additional files in Lbase:
|
||
|
//
|
||
|
// _____________
|
||
|
// L0.3 |a--d g-j| _________
|
||
|
// L0.2 | f--j| | r-t |
|
||
|
// L0.1 | b-d e---j|______| |
|
||
|
// L0.0 |a--d f--j||l--o p-----x|
|
||
|
//
|
||
|
// Lbase a--------i m---------w
|
||
|
//
|
||
|
// If an additional file existed in LBase that overlapped with [l,o], it would
|
||
|
// be excluded from the compaction. Concretely:
|
||
|
//
|
||
|
// _____________
|
||
|
// L0.3 |a--d g-j| _________
|
||
|
// L0.2 | f--j| | r-t |
|
||
|
// L0.1 | b-d e---j| | |
|
||
|
// L0.0 |a--d f--j| l--o |p-----x|
|
||
|
//
|
||
|
// Lbase a--------ij--lm---------w
|
||
|
//
|
||
|
// Intra-L0: If the L0 score is high, but PickBaseCompaction() is unable to pick
|
||
|
// a compaction, PickIntraL0Compaction will be used to pick an intra-L0
|
||
|
// compaction. Similar to L0 -> Lbase compactions, we want to allow for multiple
|
||
|
// intra-L0 compactions and not generate wide output files that hinder later
|
||
|
// concurrency of L0 -> Lbase compactions. Also compactions that produce wide
|
||
|
// files don't reduce stack depth -- they represent wide rectangles in our
|
||
|
// visualization, which means many intervals have their depth reduced by a small
|
||
|
// amount. Typically, L0 files have non-overlapping sequence numbers, and
|
||
|
// sticking to that invariant would require us to consider intra-L0 compactions
|
||
|
// that proceed from youngest to oldest files, which could result in the
|
||
|
// aforementioned undesirable wide rectangle shape. But this non-overlapping
|
||
|
// sequence number is already relaxed in RocksDB -- sstables are primarily
|
||
|
// ordered by their largest sequence number. So we can arrange for intra-L0
|
||
|
// compactions to capture thin and tall rectangles starting with the top of the
|
||
|
// stack (youngest files). Like the L0 -> Lbase case we order the intervals
|
||
|
// using a heuristic and consider each in turn. The same comment about better L0
|
||
|
// -> Lbase heuristics and not being greedy applies here.
|
||
|
//
|
||
|
// Going back to a modified version of our example from earlier, let's say these
|
||
|
// are the base compactions in progress:
|
||
|
// _______
|
||
|
// L0.3 a--d | g-j| _________
|
||
|
// L0.2 | f--j| | r-t |
|
||
|
// L0.1 b-d |e---j| | |
|
||
|
// L0.0 a--d | f--j| l--o |p-----x|
|
||
|
//
|
||
|
// Lbase a---------i m---------w
|
||
|
//
|
||
|
// Since both LBase files are compacting, the only L0 compaction that can be
|
||
|
// picked is an intra-L0 compaction. For this, the b--d interval has the highest
|
||
|
// stack depth (3), and starting with a--d in L0.3 as the seed file, we can
|
||
|
// iterate downward and build this compaction, assuming all files in that
|
||
|
// interval are not compacting and have a highest sequence number less than
|
||
|
// earliestUnflushedSeqNum:
|
||
|
//
|
||
|
// _______
|
||
|
// L0.3 |a--d| | g-j| _________
|
||
|
// L0.2 | | | f--j| | r-t |
|
||
|
// L0.1 | b-d| |e---j| | |
|
||
|
// L0.0 |a--d| | f--j| l--o |p-----x|
|
||
|
// ------
|
||
|
// Lbase a---------i m---------w
|
||
|
//
|
||
|
|
||
|
// PickBaseCompaction picks a base compaction based on the above specified
|
||
|
// heuristics, for the specified Lbase files and a minimum depth of overlapping
|
||
|
// files that can be selected for compaction. Returns nil if no compaction is
|
||
|
// possible.
|
||
|
func (s *L0Sublevels) PickBaseCompaction(
|
||
|
minCompactionDepth int, baseFiles LevelSlice,
|
||
|
) (*L0CompactionFiles, error) {
|
||
|
// For LBase compactions, we consider intervals in a greedy manner in the
|
||
|
// following order:
|
||
|
// - Intervals that are unlikely to be blocked due
|
||
|
// to ongoing L0 -> Lbase compactions. These are the ones with
|
||
|
// !isBaseCompacting && !intervalRangeIsBaseCompacting.
|
||
|
// - Intervals that are !isBaseCompacting && intervalRangeIsBaseCompacting.
|
||
|
//
|
||
|
// The ordering heuristic exists just to avoid wasted work. Ideally,
|
||
|
// we would consider all intervals with isBaseCompacting = false and
|
||
|
// construct a compaction for it and compare the constructed compactions
|
||
|
// and pick the best one. If microbenchmarks show that we can afford
|
||
|
// this cost we can eliminate this heuristic.
|
||
|
scoredIntervals := make([]intervalAndScore, 0, len(s.orderedIntervals))
|
||
|
sublevelCount := len(s.levelFiles)
|
||
|
for i := range s.orderedIntervals {
|
||
|
interval := &s.orderedIntervals[i]
|
||
|
depth := len(interval.files) - interval.compactingFileCount
|
||
|
if interval.isBaseCompacting || minCompactionDepth > depth {
|
||
|
continue
|
||
|
}
|
||
|
if interval.intervalRangeIsBaseCompacting {
|
||
|
scoredIntervals = append(scoredIntervals, intervalAndScore{interval: i, score: depth})
|
||
|
} else {
|
||
|
// Prioritize this interval by incrementing the score by the number
|
||
|
// of sublevels.
|
||
|
scoredIntervals = append(scoredIntervals, intervalAndScore{interval: i, score: depth + sublevelCount})
|
||
|
}
|
||
|
}
|
||
|
sort.Sort(intervalSorterByDecreasingScore(scoredIntervals))
|
||
|
|
||
|
// Optimization to avoid considering different intervals that
|
||
|
// are likely to choose the same seed file. Again this is just
|
||
|
// to reduce wasted work.
|
||
|
consideredIntervals := newBitSet(len(s.orderedIntervals))
|
||
|
for _, scoredInterval := range scoredIntervals {
|
||
|
interval := &s.orderedIntervals[scoredInterval.interval]
|
||
|
if consideredIntervals[interval.index] {
|
||
|
continue
|
||
|
}
|
||
|
|
||
|
// Pick the seed file for the interval as the file
|
||
|
// in the lowest sub-level.
|
||
|
f := interval.files[0]
|
||
|
// Don't bother considering the intervals that are covered by the seed
|
||
|
// file since they are likely nearby. Note that it is possible that
|
||
|
// those intervals have seed files at lower sub-levels so could be
|
||
|
// viable for compaction.
|
||
|
if f == nil {
|
||
|
return nil, errors.New("no seed file found in sublevel intervals")
|
||
|
}
|
||
|
consideredIntervals.markBits(f.minIntervalIndex, f.maxIntervalIndex+1)
|
||
|
if f.IsCompacting() {
|
||
|
if f.IsIntraL0Compacting {
|
||
|
// If we're picking a base compaction and we came across a seed
|
||
|
// file candidate that's being intra-L0 compacted, skip the
|
||
|
// interval instead of erroring out.
|
||
|
continue
|
||
|
}
|
||
|
// We chose a compaction seed file that should not be compacting.
|
||
|
// Usually means the score is not accurately accounting for files
|
||
|
// already compacting, or internal state is inconsistent.
|
||
|
return nil, errors.Errorf("file %s chosen as seed file for compaction should not be compacting", f.FileNum)
|
||
|
}
|
||
|
|
||
|
c := s.baseCompactionUsingSeed(f, interval.index, minCompactionDepth)
|
||
|
if c != nil {
|
||
|
// Check if the chosen compaction overlaps with any files in Lbase
|
||
|
// that have Compacting = true. If that's the case, this compaction
|
||
|
// cannot be chosen.
|
||
|
baseIter := baseFiles.Iter()
|
||
|
// An interval starting at ImmediateSuccessor(key) can never be the
|
||
|
// first interval of a compaction since no file can start at that
|
||
|
// interval.
|
||
|
m := baseIter.SeekGE(s.cmp, s.orderedIntervals[c.minIntervalIndex].startKey.key)
|
||
|
|
||
|
var baseCompacting bool
|
||
|
for ; m != nil && !baseCompacting; m = baseIter.Next() {
|
||
|
cmp := s.cmp(m.Smallest.UserKey, s.orderedIntervals[c.maxIntervalIndex+1].startKey.key)
|
||
|
// Compaction is ending at exclusive bound of c.maxIntervalIndex+1
|
||
|
if cmp > 0 || (cmp == 0 && !s.orderedIntervals[c.maxIntervalIndex+1].startKey.isLargest) {
|
||
|
break
|
||
|
}
|
||
|
baseCompacting = baseCompacting || m.IsCompacting()
|
||
|
}
|
||
|
if baseCompacting {
|
||
|
continue
|
||
|
}
|
||
|
return c, nil
|
||
|
}
|
||
|
}
|
||
|
return nil, nil
|
||
|
}
|
||
|
|
||
|
// Helper function for building an L0 -> Lbase compaction using a seed interval
|
||
|
// and seed file in that seed interval.
|
||
|
func (s *L0Sublevels) baseCompactionUsingSeed(
|
||
|
f *FileMetadata, intervalIndex int, minCompactionDepth int,
|
||
|
) *L0CompactionFiles {
|
||
|
c := &L0CompactionFiles{
|
||
|
FilesIncluded: newBitSet(s.levelMetadata.Len()),
|
||
|
seedInterval: intervalIndex,
|
||
|
seedIntervalMinLevel: 0,
|
||
|
minIntervalIndex: f.minIntervalIndex,
|
||
|
maxIntervalIndex: f.maxIntervalIndex,
|
||
|
}
|
||
|
c.addFile(f)
|
||
|
|
||
|
// The first iteration of this loop builds the compaction at the seed file's
|
||
|
// sublevel. Future iterations expand on this compaction by stacking more
|
||
|
// files from intervalIndex and repeating. This is an optional activity so
|
||
|
// when it fails we can fallback to the last successful candidate.
|
||
|
var lastCandidate *L0CompactionFiles
|
||
|
interval := &s.orderedIntervals[intervalIndex]
|
||
|
|
||
|
for i := 0; i < len(interval.files); i++ {
|
||
|
f2 := interval.files[i]
|
||
|
sl := f2.SubLevel
|
||
|
c.seedIntervalStackDepthReduction++
|
||
|
c.seedIntervalMaxLevel = sl
|
||
|
c.addFile(f2)
|
||
|
// The seed file is in the lowest sublevel in the seed interval, but it
|
||
|
// may overlap with other files in even lower sublevels. For correctness
|
||
|
// we need to grow our interval to include those files, and capture all
|
||
|
// files in the next level that fall in this extended interval and so
|
||
|
// on. This can result in a triangular shape like the following where
|
||
|
// again the X axis is the key intervals and the Y axis is oldest to
|
||
|
// youngest. Note that it is not necessary for correctness to fill out
|
||
|
// the shape at the higher sub-levels to make it more rectangular since
|
||
|
// the invariant only requires that younger versions of a key not be
|
||
|
// moved to Lbase while leaving behind older versions.
|
||
|
// -
|
||
|
// ---
|
||
|
// -----
|
||
|
// It may be better for performance to have a more rectangular shape
|
||
|
// since the files being left behind will overlap with the same Lbase
|
||
|
// key range as that of this compaction. But there is also the danger
|
||
|
// that in trying to construct a more rectangular shape we will be
|
||
|
// forced to pull in a file that is already compacting. We expect
|
||
|
// extendCandidateToRectangle to eventually be called on this compaction
|
||
|
// if it's chosen, at which point we would iterate backward and choose
|
||
|
// those files. This logic is similar to compaction.grow for non-L0
|
||
|
// compactions.
|
||
|
done := false
|
||
|
for currLevel := sl - 1; currLevel >= 0; currLevel-- {
|
||
|
if !s.extendFiles(currLevel, math.MaxUint64, c) {
|
||
|
// Failed to extend due to ongoing compaction.
|
||
|
done = true
|
||
|
break
|
||
|
}
|
||
|
}
|
||
|
if done {
|
||
|
break
|
||
|
}
|
||
|
// Observed some compactions using > 1GB from L0 in an import
|
||
|
// experiment. Very long running compactions are not great as they
|
||
|
// reduce concurrency while they run, and take a while to produce
|
||
|
// results, though they're sometimes unavoidable. There is a tradeoff
|
||
|
// here in that adding more depth is more efficient in reducing stack
|
||
|
// depth, but long running compactions reduce flexibility in what can
|
||
|
// run concurrently in L0 and even Lbase -> Lbase+1. An increase more
|
||
|
// than 150% in bytes since the last candidate compaction (along with a
|
||
|
// total compaction size in excess of 100mb), or a total compaction size
|
||
|
// beyond a hard limit of 500mb, is criteria for rejecting this
|
||
|
// candidate. This lets us prefer slow growths as we add files, while
|
||
|
// still having a hard limit. Note that if this is the first compaction
|
||
|
// candidate to reach a stack depth reduction of minCompactionDepth or
|
||
|
// higher, this candidate will be chosen regardless.
|
||
|
if lastCandidate == nil {
|
||
|
lastCandidate = &L0CompactionFiles{}
|
||
|
} else if lastCandidate.seedIntervalStackDepthReduction >= minCompactionDepth &&
|
||
|
c.fileBytes > 100<<20 &&
|
||
|
(float64(c.fileBytes)/float64(lastCandidate.fileBytes) > 1.5 || c.fileBytes > 500<<20) {
|
||
|
break
|
||
|
}
|
||
|
*lastCandidate = *c
|
||
|
}
|
||
|
if lastCandidate != nil && lastCandidate.seedIntervalStackDepthReduction >= minCompactionDepth {
|
||
|
lastCandidate.FilesIncluded.clearAllBits()
|
||
|
for _, f := range lastCandidate.Files {
|
||
|
lastCandidate.FilesIncluded.markBit(f.L0Index)
|
||
|
}
|
||
|
return lastCandidate
|
||
|
}
|
||
|
return nil
|
||
|
}
|
||
|
|
||
|
// Expands fields in the provided L0CompactionFiles instance (cFiles) to
|
||
|
// include overlapping files in the specified sublevel. Returns true if the
|
||
|
// compaction is possible (i.e. does not conflict with any base/intra-L0
|
||
|
// compacting files).
|
||
|
func (s *L0Sublevels) extendFiles(
|
||
|
sl int, earliestUnflushedSeqNum uint64, cFiles *L0CompactionFiles,
|
||
|
) bool {
|
||
|
index, _ := slices.BinarySearchFunc(s.levelFiles[sl], cFiles.minIntervalIndex, func(a *FileMetadata, b int) int {
|
||
|
return stdcmp.Compare(a.maxIntervalIndex, b)
|
||
|
})
|
||
|
for ; index < len(s.levelFiles[sl]); index++ {
|
||
|
f := s.levelFiles[sl][index]
|
||
|
if f.minIntervalIndex > cFiles.maxIntervalIndex {
|
||
|
break
|
||
|
}
|
||
|
if f.IsCompacting() {
|
||
|
return false
|
||
|
}
|
||
|
// Skip over files that are newer than earliestUnflushedSeqNum. This is
|
||
|
// okay because this compaction can just pretend these files are not in
|
||
|
// L0 yet. These files must be in higher sublevels than any overlapping
|
||
|
// files with f.LargestSeqNum < earliestUnflushedSeqNum, and the output
|
||
|
// of the compaction will also go in a lower (older) sublevel than this
|
||
|
// file by definition.
|
||
|
if f.LargestSeqNum >= earliestUnflushedSeqNum {
|
||
|
continue
|
||
|
}
|
||
|
cFiles.addFile(f)
|
||
|
}
|
||
|
return true
|
||
|
}
|
||
|
|
||
|
// PickIntraL0Compaction picks an intra-L0 compaction for files in this
|
||
|
// sublevel. This method is only called when a base compaction cannot be chosen.
|
||
|
// See comment above [PickBaseCompaction] for heuristics involved in this
|
||
|
// selection.
|
||
|
func (s *L0Sublevels) PickIntraL0Compaction(
|
||
|
earliestUnflushedSeqNum uint64, minCompactionDepth int,
|
||
|
) (*L0CompactionFiles, error) {
|
||
|
scoredIntervals := make([]intervalAndScore, len(s.orderedIntervals))
|
||
|
for i := range s.orderedIntervals {
|
||
|
interval := &s.orderedIntervals[i]
|
||
|
depth := len(interval.files) - interval.compactingFileCount
|
||
|
if minCompactionDepth > depth {
|
||
|
continue
|
||
|
}
|
||
|
scoredIntervals[i] = intervalAndScore{interval: i, score: depth}
|
||
|
}
|
||
|
sort.Sort(intervalSorterByDecreasingScore(scoredIntervals))
|
||
|
|
||
|
// Optimization to avoid considering different intervals that are likely to
|
||
|
// choose the same seed file. Again this is just to reduce wasted work.
|
||
|
consideredIntervals := newBitSet(len(s.orderedIntervals))
|
||
|
for _, scoredInterval := range scoredIntervals {
|
||
|
interval := &s.orderedIntervals[scoredInterval.interval]
|
||
|
if consideredIntervals[interval.index] {
|
||
|
continue
|
||
|
}
|
||
|
|
||
|
var f *FileMetadata
|
||
|
// Pick the seed file for the interval as the file in the highest
|
||
|
// sub-level.
|
||
|
stackDepthReduction := scoredInterval.score
|
||
|
for i := len(interval.files) - 1; i >= 0; i-- {
|
||
|
f = interval.files[i]
|
||
|
if f.IsCompacting() {
|
||
|
break
|
||
|
}
|
||
|
consideredIntervals.markBits(f.minIntervalIndex, f.maxIntervalIndex+1)
|
||
|
// Can this be the seed file? Files with newer sequence numbers than
|
||
|
// earliestUnflushedSeqNum cannot be in the compaction.
|
||
|
if f.LargestSeqNum >= earliestUnflushedSeqNum {
|
||
|
stackDepthReduction--
|
||
|
if stackDepthReduction == 0 {
|
||
|
break
|
||
|
}
|
||
|
} else {
|
||
|
break
|
||
|
}
|
||
|
}
|
||
|
if stackDepthReduction < minCompactionDepth {
|
||
|
// Can't use this interval.
|
||
|
continue
|
||
|
}
|
||
|
|
||
|
if f == nil {
|
||
|
return nil, errors.New("no seed file found in sublevel intervals")
|
||
|
}
|
||
|
if f.IsCompacting() {
|
||
|
// This file could be in a concurrent intra-L0 or base compaction.
|
||
|
// Try another interval.
|
||
|
continue
|
||
|
}
|
||
|
|
||
|
// We have a seed file. Build a compaction off of that seed.
|
||
|
c := s.intraL0CompactionUsingSeed(
|
||
|
f, interval.index, earliestUnflushedSeqNum, minCompactionDepth)
|
||
|
if c != nil {
|
||
|
return c, nil
|
||
|
}
|
||
|
}
|
||
|
return nil, nil
|
||
|
}
|
||
|
|
||
|
func (s *L0Sublevels) intraL0CompactionUsingSeed(
|
||
|
f *FileMetadata, intervalIndex int, earliestUnflushedSeqNum uint64, minCompactionDepth int,
|
||
|
) *L0CompactionFiles {
|
||
|
// We know that all the files that overlap with intervalIndex have
|
||
|
// LargestSeqNum < earliestUnflushedSeqNum, but for other intervals
|
||
|
// we need to exclude files >= earliestUnflushedSeqNum
|
||
|
|
||
|
c := &L0CompactionFiles{
|
||
|
FilesIncluded: newBitSet(s.levelMetadata.Len()),
|
||
|
seedInterval: intervalIndex,
|
||
|
seedIntervalMaxLevel: len(s.levelFiles) - 1,
|
||
|
minIntervalIndex: f.minIntervalIndex,
|
||
|
maxIntervalIndex: f.maxIntervalIndex,
|
||
|
isIntraL0: true,
|
||
|
earliestUnflushedSeqNum: earliestUnflushedSeqNum,
|
||
|
}
|
||
|
c.addFile(f)
|
||
|
|
||
|
var lastCandidate *L0CompactionFiles
|
||
|
interval := &s.orderedIntervals[intervalIndex]
|
||
|
slIndex := len(interval.files) - 1
|
||
|
for {
|
||
|
if interval.files[slIndex] == f {
|
||
|
break
|
||
|
}
|
||
|
slIndex--
|
||
|
}
|
||
|
// The first iteration of this loop produces an intra-L0 compaction at the
|
||
|
// seed level. Iterations after that optionally add to the compaction by
|
||
|
// stacking more files from intervalIndex and repeating. This is an optional
|
||
|
// activity so when it fails we can fallback to the last successful
|
||
|
// candidate. The code stops adding when it can't add more, or when
|
||
|
// fileBytes grows too large.
|
||
|
for ; slIndex >= 0; slIndex-- {
|
||
|
f2 := interval.files[slIndex]
|
||
|
sl := f2.SubLevel
|
||
|
if f2.IsCompacting() {
|
||
|
break
|
||
|
}
|
||
|
c.seedIntervalStackDepthReduction++
|
||
|
c.seedIntervalMinLevel = sl
|
||
|
c.addFile(f2)
|
||
|
// The seed file captures all files in the higher level that fall in the
|
||
|
// range of intervals. That may extend the range of intervals so for
|
||
|
// correctness we need to capture all files in the next higher level
|
||
|
// that fall in this extended interval and so on. This can result in an
|
||
|
// inverted triangular shape like the following where again the X axis
|
||
|
// is the key intervals and the Y axis is oldest to youngest. Note that
|
||
|
// it is not necessary for correctness to fill out the shape at lower
|
||
|
// sub-levels to make it more rectangular since the invariant only
|
||
|
// requires that if we move an older seqnum for key k into a file that
|
||
|
// has a higher seqnum, we also move all younger seqnums for that key k
|
||
|
// into that file.
|
||
|
// -----
|
||
|
// ---
|
||
|
// -
|
||
|
// It may be better for performance to have a more rectangular shape
|
||
|
// since it will reduce the stack depth for more intervals. But there is
|
||
|
// also the danger that in explicitly trying to construct a more
|
||
|
// rectangular shape we will be forced to pull in a file that is already
|
||
|
// compacting. We assume that the performance concern is not a practical
|
||
|
// issue.
|
||
|
done := false
|
||
|
for currLevel := sl + 1; currLevel < len(s.levelFiles); currLevel++ {
|
||
|
if !s.extendFiles(currLevel, earliestUnflushedSeqNum, c) {
|
||
|
// Failed to extend due to ongoing compaction.
|
||
|
done = true
|
||
|
break
|
||
|
}
|
||
|
}
|
||
|
if done {
|
||
|
break
|
||
|
}
|
||
|
if lastCandidate == nil {
|
||
|
lastCandidate = &L0CompactionFiles{}
|
||
|
} else if lastCandidate.seedIntervalStackDepthReduction >= minCompactionDepth &&
|
||
|
c.fileBytes > 100<<20 &&
|
||
|
(float64(c.fileBytes)/float64(lastCandidate.fileBytes) > 1.5 || c.fileBytes > 500<<20) {
|
||
|
break
|
||
|
}
|
||
|
*lastCandidate = *c
|
||
|
}
|
||
|
if lastCandidate != nil && lastCandidate.seedIntervalStackDepthReduction >= minCompactionDepth {
|
||
|
lastCandidate.FilesIncluded.clearAllBits()
|
||
|
for _, f := range lastCandidate.Files {
|
||
|
lastCandidate.FilesIncluded.markBit(f.L0Index)
|
||
|
}
|
||
|
s.extendCandidateToRectangle(
|
||
|
lastCandidate.minIntervalIndex, lastCandidate.maxIntervalIndex, lastCandidate, false)
|
||
|
return lastCandidate
|
||
|
}
|
||
|
return nil
|
||
|
}
|
||
|
|
||
|
// ExtendL0ForBaseCompactionTo extends the specified base compaction candidate
|
||
|
// L0CompactionFiles to optionally cover more files in L0 without "touching" any
|
||
|
// of the passed-in keys (i.e. the smallest/largest bounds are exclusive), as
|
||
|
// including any user keys for those internal keys could require choosing more
|
||
|
// files in LBase which is undesirable. Unbounded start/end keys are indicated
|
||
|
// by passing in the InvalidInternalKey.
|
||
|
func (s *L0Sublevels) ExtendL0ForBaseCompactionTo(
|
||
|
smallest, largest InternalKey, candidate *L0CompactionFiles,
|
||
|
) bool {
|
||
|
firstIntervalIndex := 0
|
||
|
lastIntervalIndex := len(s.orderedIntervals) - 1
|
||
|
if smallest.Kind() != base.InternalKeyKindInvalid {
|
||
|
if smallest.Trailer == base.InternalKeyRangeDeleteSentinel {
|
||
|
// Starting at smallest.UserKey == interval.startKey is okay.
|
||
|
firstIntervalIndex = sort.Search(len(s.orderedIntervals), func(i int) bool {
|
||
|
return s.cmp(smallest.UserKey, s.orderedIntervals[i].startKey.key) <= 0
|
||
|
})
|
||
|
} else {
|
||
|
firstIntervalIndex = sort.Search(len(s.orderedIntervals), func(i int) bool {
|
||
|
// Need to start at >= smallest since if we widen too much we may miss
|
||
|
// an Lbase file that overlaps with an L0 file that will get picked in
|
||
|
// this widening, which would be bad. This interval will not start with
|
||
|
// an immediate successor key.
|
||
|
return s.cmp(smallest.UserKey, s.orderedIntervals[i].startKey.key) < 0
|
||
|
})
|
||
|
}
|
||
|
}
|
||
|
if largest.Kind() != base.InternalKeyKindInvalid {
|
||
|
// First interval that starts at or beyond the largest. This interval will not
|
||
|
// start with an immediate successor key.
|
||
|
lastIntervalIndex = sort.Search(len(s.orderedIntervals), func(i int) bool {
|
||
|
return s.cmp(largest.UserKey, s.orderedIntervals[i].startKey.key) <= 0
|
||
|
})
|
||
|
// Right now, lastIntervalIndex has a startKey that extends beyond largest.
|
||
|
// The previous interval, by definition, has an end key higher than largest.
|
||
|
// Iterate back twice to get the last interval that's completely within
|
||
|
// (smallest, largest). Except in the case where we went past the end of the
|
||
|
// list; in that case, the last interval to include is the very last
|
||
|
// interval in the list.
|
||
|
if lastIntervalIndex < len(s.orderedIntervals) {
|
||
|
lastIntervalIndex--
|
||
|
}
|
||
|
lastIntervalIndex--
|
||
|
}
|
||
|
if lastIntervalIndex < firstIntervalIndex {
|
||
|
return false
|
||
|
}
|
||
|
return s.extendCandidateToRectangle(firstIntervalIndex, lastIntervalIndex, candidate, true)
|
||
|
}
|
||
|
|
||
|
// Best-effort attempt to make the compaction include more files in the
|
||
|
// rectangle defined by [minIntervalIndex, maxIntervalIndex] on the X axis and
|
||
|
// bounded on the Y axis by seedIntervalMinLevel and seedIntervalMaxLevel.
|
||
|
//
|
||
|
// This is strictly an optional extension; at any point where we can't feasibly
|
||
|
// add more files, the sublevel iteration can be halted early and candidate will
|
||
|
// still be a correct compaction candidate.
|
||
|
//
|
||
|
// Consider this scenario (original candidate is inside the rectangle), with
|
||
|
// isBase = true and interval bounds a-j (from the union of base file bounds and
|
||
|
// that of compaction candidate):
|
||
|
//
|
||
|
// _______
|
||
|
// L0.3 a--d | g-j|
|
||
|
// L0.2 | f--j| r-t
|
||
|
// L0.1 b-d |e---j|
|
||
|
// L0.0 a--d | f--j| l--o p-----x
|
||
|
//
|
||
|
// Lbase a--------i m---------w
|
||
|
//
|
||
|
// This method will iterate from the bottom up. At L0.0, it will add a--d since
|
||
|
// it's in the bounds, then add b-d, then a--d, and so on, to produce this:
|
||
|
//
|
||
|
// _____________
|
||
|
// L0.3 |a--d g-j|
|
||
|
// L0.2 | f--j| r-t
|
||
|
// L0.1 | b-d e---j|
|
||
|
// L0.0 |a--d f--j| l--o p-----x
|
||
|
//
|
||
|
// Lbase a-------i m---------w
|
||
|
//
|
||
|
// Let's assume that, instead of a--d in the top sublevel, we had 3 files, a-b,
|
||
|
// bb-c, and cc-d, of which bb-c is compacting. Let's also add another sublevel
|
||
|
// L0.4 with some files, all of which aren't compacting:
|
||
|
//
|
||
|
// L0.4 a------c ca--d _______
|
||
|
// L0.3 a-b bb-c cc-d | g-j|
|
||
|
// L0.2 | f--j| r-t
|
||
|
// L0.1 b----------d |e---j|
|
||
|
// L0.0 a------------d | f--j| l--o p-----x
|
||
|
//
|
||
|
// Lbase a------------------i m---------w
|
||
|
//
|
||
|
// This method then needs to choose between the left side of L0.3 bb-c (i.e.
|
||
|
// a-b), or the right side (i.e. cc-d and g-j) for inclusion in this compaction.
|
||
|
// Since the right side has more files as well as one file that has already been
|
||
|
// picked, it gets chosen at that sublevel, resulting in this intermediate
|
||
|
// compaction:
|
||
|
//
|
||
|
// L0.4 a------c ca--d
|
||
|
// ______________
|
||
|
// L0.3 a-b bb-c| cc-d g-j|
|
||
|
// L0.2 _________| f--j| r-t
|
||
|
// L0.1 | b----------d e---j|
|
||
|
// L0.0 |a------------d f--j| l--o p-----x
|
||
|
//
|
||
|
// Lbase a------------------i m---------w
|
||
|
//
|
||
|
// Since bb-c had to be excluded at L0.3, the interval bounds for L0.4 are
|
||
|
// actually ca-j, since ca is the next interval start key after the end interval
|
||
|
// of bb-c. This would result in only ca-d being chosen at that sublevel, even
|
||
|
// though a--c is also not compacting. This is the final result:
|
||
|
//
|
||
|
// ______________
|
||
|
// L0.4 a------c|ca--d |
|
||
|
// L0.3 a-b bb-c| cc-d g-j|
|
||
|
// L0.2 _________| f--j| r-t
|
||
|
// L0.1 | b----------d e---j|
|
||
|
// L0.0 |a------------d f--j| l--o p-----x
|
||
|
//
|
||
|
// Lbase a------------------i m---------w
|
||
|
//
|
||
|
// TODO(bilal): Add more targeted tests for this method, through
|
||
|
// ExtendL0ForBaseCompactionTo and intraL0CompactionUsingSeed.
|
||
|
func (s *L0Sublevels) extendCandidateToRectangle(
|
||
|
minIntervalIndex int, maxIntervalIndex int, candidate *L0CompactionFiles, isBase bool,
|
||
|
) bool {
|
||
|
candidate.preExtensionMinInterval = candidate.minIntervalIndex
|
||
|
candidate.preExtensionMaxInterval = candidate.maxIntervalIndex
|
||
|
// Extend {min,max}IntervalIndex to include all of the candidate's current
|
||
|
// bounds.
|
||
|
if minIntervalIndex > candidate.minIntervalIndex {
|
||
|
minIntervalIndex = candidate.minIntervalIndex
|
||
|
}
|
||
|
if maxIntervalIndex < candidate.maxIntervalIndex {
|
||
|
maxIntervalIndex = candidate.maxIntervalIndex
|
||
|
}
|
||
|
var startLevel, increment, endLevel int
|
||
|
if isBase {
|
||
|
startLevel = 0
|
||
|
increment = +1
|
||
|
// seedIntervalMaxLevel is inclusive, while endLevel is exclusive.
|
||
|
endLevel = candidate.seedIntervalMaxLevel + 1
|
||
|
} else {
|
||
|
startLevel = len(s.levelFiles) - 1
|
||
|
increment = -1
|
||
|
// seedIntervalMinLevel is inclusive, while endLevel is exclusive.
|
||
|
endLevel = candidate.seedIntervalMinLevel - 1
|
||
|
}
|
||
|
// Stats for files.
|
||
|
addedCount := 0
|
||
|
// Iterate from the oldest sub-level for L0 -> Lbase and youngest sub-level
|
||
|
// for intra-L0. The idea here is that anything that can't be included from
|
||
|
// that level constrains what can be included from the next level. This
|
||
|
// change in constraint is directly incorporated into minIntervalIndex,
|
||
|
// maxIntervalIndex.
|
||
|
for sl := startLevel; sl != endLevel; sl += increment {
|
||
|
files := s.levelFiles[sl]
|
||
|
// Find the first file that overlaps with minIntervalIndex.
|
||
|
index := sort.Search(len(files), func(i int) bool {
|
||
|
return minIntervalIndex <= files[i].maxIntervalIndex
|
||
|
})
|
||
|
// Track the files that are fully within the current constraint of
|
||
|
// [minIntervalIndex, maxIntervalIndex].
|
||
|
firstIndex := -1
|
||
|
lastIndex := -1
|
||
|
for ; index < len(files); index++ {
|
||
|
f := files[index]
|
||
|
if f.minIntervalIndex > maxIntervalIndex {
|
||
|
break
|
||
|
}
|
||
|
include := true
|
||
|
// Extends out on the left so can't be included. This narrows what
|
||
|
// we can included in the next level.
|
||
|
if f.minIntervalIndex < minIntervalIndex {
|
||
|
include = false
|
||
|
minIntervalIndex = f.maxIntervalIndex + 1
|
||
|
}
|
||
|
// Extends out on the right so can't be included.
|
||
|
if f.maxIntervalIndex > maxIntervalIndex {
|
||
|
include = false
|
||
|
maxIntervalIndex = f.minIntervalIndex - 1
|
||
|
}
|
||
|
if !include {
|
||
|
continue
|
||
|
}
|
||
|
if firstIndex == -1 {
|
||
|
firstIndex = index
|
||
|
}
|
||
|
lastIndex = index
|
||
|
}
|
||
|
if minIntervalIndex > maxIntervalIndex {
|
||
|
// We excluded files that prevent continuation.
|
||
|
break
|
||
|
}
|
||
|
if firstIndex < 0 {
|
||
|
// No files to add in this sub-level.
|
||
|
continue
|
||
|
}
|
||
|
// We have the files in [firstIndex, lastIndex] as potential for
|
||
|
// inclusion. Some of these may already have been picked. Some of them
|
||
|
// may be already compacting. The latter is tricky since we have to
|
||
|
// decide whether to contract minIntervalIndex or maxIntervalIndex when
|
||
|
// we encounter an already compacting file. We pick the longest sequence
|
||
|
// between firstIndex and lastIndex of non-compacting files -- this is
|
||
|
// represented by [candidateNonCompactingFirst,
|
||
|
// candidateNonCompactingLast].
|
||
|
nonCompactingFirst := -1
|
||
|
currentRunHasAlreadyPickedFiles := false
|
||
|
candidateNonCompactingFirst := -1
|
||
|
candidateNonCompactingLast := -1
|
||
|
candidateHasAlreadyPickedFiles := false
|
||
|
for index = firstIndex; index <= lastIndex; index++ {
|
||
|
f := files[index]
|
||
|
if f.IsCompacting() {
|
||
|
if nonCompactingFirst != -1 {
|
||
|
last := index - 1
|
||
|
// Prioritize runs of consecutive non-compacting files that
|
||
|
// have files that have already been picked. That is to say,
|
||
|
// if candidateHasAlreadyPickedFiles == true, we stick with
|
||
|
// it, and if currentRunHasAlreadyPickedfiles == true, we
|
||
|
// pick that run even if it contains fewer files than the
|
||
|
// previous candidate.
|
||
|
if !candidateHasAlreadyPickedFiles && (candidateNonCompactingFirst == -1 ||
|
||
|
currentRunHasAlreadyPickedFiles ||
|
||
|
(last-nonCompactingFirst) > (candidateNonCompactingLast-candidateNonCompactingFirst)) {
|
||
|
candidateNonCompactingFirst = nonCompactingFirst
|
||
|
candidateNonCompactingLast = last
|
||
|
candidateHasAlreadyPickedFiles = currentRunHasAlreadyPickedFiles
|
||
|
}
|
||
|
}
|
||
|
nonCompactingFirst = -1
|
||
|
currentRunHasAlreadyPickedFiles = false
|
||
|
continue
|
||
|
}
|
||
|
if nonCompactingFirst == -1 {
|
||
|
nonCompactingFirst = index
|
||
|
}
|
||
|
if candidate.FilesIncluded[f.L0Index] {
|
||
|
currentRunHasAlreadyPickedFiles = true
|
||
|
}
|
||
|
}
|
||
|
// Logic duplicated from inside the for loop above.
|
||
|
if nonCompactingFirst != -1 {
|
||
|
last := index - 1
|
||
|
if !candidateHasAlreadyPickedFiles && (candidateNonCompactingFirst == -1 ||
|
||
|
currentRunHasAlreadyPickedFiles ||
|
||
|
(last-nonCompactingFirst) > (candidateNonCompactingLast-candidateNonCompactingFirst)) {
|
||
|
candidateNonCompactingFirst = nonCompactingFirst
|
||
|
candidateNonCompactingLast = last
|
||
|
}
|
||
|
}
|
||
|
if candidateNonCompactingFirst == -1 {
|
||
|
// All files are compacting. There will be gaps that we could
|
||
|
// exploit to continue, but don't bother.
|
||
|
break
|
||
|
}
|
||
|
// May need to shrink [minIntervalIndex, maxIntervalIndex] for the next level.
|
||
|
if candidateNonCompactingFirst > firstIndex {
|
||
|
minIntervalIndex = files[candidateNonCompactingFirst-1].maxIntervalIndex + 1
|
||
|
}
|
||
|
if candidateNonCompactingLast < lastIndex {
|
||
|
maxIntervalIndex = files[candidateNonCompactingLast+1].minIntervalIndex - 1
|
||
|
}
|
||
|
for index := candidateNonCompactingFirst; index <= candidateNonCompactingLast; index++ {
|
||
|
f := files[index]
|
||
|
if f.IsCompacting() {
|
||
|
// TODO(bilal): Do a logger.Fatalf instead of a panic, for
|
||
|
// cleaner unwinding and error messages.
|
||
|
panic(fmt.Sprintf("expected %s to not be compacting", f.FileNum))
|
||
|
}
|
||
|
if candidate.isIntraL0 && f.LargestSeqNum >= candidate.earliestUnflushedSeqNum {
|
||
|
continue
|
||
|
}
|
||
|
if !candidate.FilesIncluded[f.L0Index] {
|
||
|
addedCount++
|
||
|
candidate.addFile(f)
|
||
|
}
|
||
|
}
|
||
|
}
|
||
|
return addedCount > 0
|
||
|
}
|