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292 lines
10 KiB
Go
292 lines
10 KiB
Go
// Copyright 2011 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 sstable
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import (
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"fmt"
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"os"
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"sync"
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"github.com/cockroachdb/pebble/internal/base"
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"github.com/cockroachdb/pebble/internal/invariants"
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)
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// Iterator iterates over an entire table of data.
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type Iterator interface {
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base.InternalIterator
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// NextPrefix implements (base.InternalIterator).NextPrefix.
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NextPrefix(succKey []byte) (*InternalKey, base.LazyValue)
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// MaybeFilteredKeys may be called when an iterator is exhausted to indicate
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// whether or not the last positioning method may have skipped any keys due
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// to block-property filters. This is used by the Pebble levelIter to
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// control when an iterator steps to the next sstable.
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//
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// MaybeFilteredKeys may always return false positives, that is it may
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// return true when no keys were filtered. It should only be called when the
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// iterator is exhausted. It must never return false negatives when the
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// iterator is exhausted.
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MaybeFilteredKeys() bool
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SetCloseHook(fn func(i Iterator) error)
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}
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// Iterator positioning optimizations and singleLevelIterator and
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// twoLevelIterator:
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//
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// An iterator is absolute positioned using one of the Seek or First or Last
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// calls. After absolute positioning, there can be relative positioning done
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// by stepping using Prev or Next.
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//
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// We implement optimizations below where an absolute positioning call can in
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// some cases use the current position to do less work. To understand these,
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// we first define some terms. An iterator is bounds-exhausted if the bounds
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// (upper of lower) have been reached. An iterator is data-exhausted if it has
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// the reached the end of the data (forward or reverse) in the sstable. A
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// singleLevelIterator only knows a local-data-exhausted property since when
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// it is used as part of a twoLevelIterator, the twoLevelIterator can step to
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// the next lower-level index block.
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//
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// The bounds-exhausted property is tracked by
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// singleLevelIterator.exhaustedBounds being +1 (upper bound reached) or -1
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// (lower bound reached). The same field is reused by twoLevelIterator. Either
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// may notice the exhaustion of the bound and set it. Note that if
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// singleLevelIterator sets this property, it is not a local property (since
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// the bound has been reached regardless of whether this is in the context of
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// the twoLevelIterator or not).
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//
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// The data-exhausted property is tracked in a more subtle manner. We define
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// two predicates:
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// - partial-local-data-exhausted (PLDE):
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// i.data.isDataInvalidated() || !i.data.valid()
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// - partial-global-data-exhausted (PGDE):
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// i.index.isDataInvalidated() || !i.index.valid() || i.data.isDataInvalidated() ||
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// !i.data.valid()
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//
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// PLDE is defined for a singleLevelIterator. PGDE is defined for a
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// twoLevelIterator. Oddly, in our code below the singleLevelIterator does not
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// know when it is part of a twoLevelIterator so it does not know when its
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// property is local or global.
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//
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// Now to define data-exhausted:
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// - Prerequisite: we must know that the iterator has been positioned and
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// i.err is nil.
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// - bounds-exhausted must not be true:
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// If bounds-exhausted is true, we have incomplete knowledge of
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// data-exhausted since PLDE or PGDE could be true because we could have
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// chosen not to load index block or data block and figured out that the
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// bound is exhausted (due to block property filters filtering out index and
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// data blocks and going past the bound on the top level index block). Note
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// that if we tried to separate out the BPF case from others we could
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// develop more knowledge here.
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// - PGDE is true for twoLevelIterator. PLDE is true if it is a standalone
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// singleLevelIterator. !PLDE or !PGDE of course imply that data-exhausted
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// is not true.
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//
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// An implication of the above is that if we are going to somehow utilize
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// knowledge of data-exhausted in an optimization, we must not forget the
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// existing value of bounds-exhausted since by forgetting the latter we can
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// erroneously think that data-exhausted is true. Bug #2036 was due to this
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// forgetting.
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//
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// Now to the two categories of optimizations we currently have:
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// - Monotonic bounds optimization that reuse prior iterator position when
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// doing seek: These only work with !data-exhausted. We could choose to make
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// these work with data-exhausted but have not bothered because in the
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// context of a DB if data-exhausted were true, the DB would move to the
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// next file in the level. Note that this behavior of moving to the next
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// file is not necessarily true for L0 files, so there could be some benefit
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// in the future in this optimization. See the WARNING-data-exhausted
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// comments if trying to optimize this in the future.
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// - TrySeekUsingNext optimizations: these work regardless of exhaustion
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// state.
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//
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// Implementation detail: In the code PLDE only checks that
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// i.data.isDataInvalidated(). This narrower check is safe, since this is a
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// subset of the set expressed by the OR expression. Also, it is not a
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// de-optimization since whenever we exhaust the iterator we explicitly call
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// i.data.invalidate(). PGDE checks i.index.isDataInvalidated() &&
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// i.data.isDataInvalidated(). Again, this narrower check is safe, and not a
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// de-optimization since whenever we exhaust the iterator we explicitly call
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// i.index.invalidate() and i.data.invalidate(). The && is questionable -- for
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// now this is a bit of defensive code. We should seriously consider removing
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// it, since defensive code suggests we are not confident about our invariants
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// (and if we are not confident, we need more invariant assertions, not
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// defensive code).
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//
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// TODO(sumeer): remove the aforementioned defensive code.
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var singleLevelIterPool = sync.Pool{
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New: func() interface{} {
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i := &singleLevelIterator{}
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// Note: this is a no-op if invariants are disabled or race is enabled.
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invariants.SetFinalizer(i, checkSingleLevelIterator)
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return i
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},
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}
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var twoLevelIterPool = sync.Pool{
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New: func() interface{} {
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i := &twoLevelIterator{}
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// Note: this is a no-op if invariants are disabled or race is enabled.
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invariants.SetFinalizer(i, checkTwoLevelIterator)
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return i
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},
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}
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// TODO(jackson): rangedel fragmentBlockIters can't be pooled because of some
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// code paths that double Close the iters. Fix the double close and pool the
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// *fragmentBlockIter type directly.
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var rangeKeyFragmentBlockIterPool = sync.Pool{
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New: func() interface{} {
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i := &rangeKeyFragmentBlockIter{}
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// Note: this is a no-op if invariants are disabled or race is enabled.
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invariants.SetFinalizer(i, checkRangeKeyFragmentBlockIterator)
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return i
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},
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}
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func checkSingleLevelIterator(obj interface{}) {
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i := obj.(*singleLevelIterator)
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if p := i.data.handle.Get(); p != nil {
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fmt.Fprintf(os.Stderr, "singleLevelIterator.data.handle is not nil: %p\n", p)
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os.Exit(1)
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}
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if p := i.index.handle.Get(); p != nil {
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fmt.Fprintf(os.Stderr, "singleLevelIterator.index.handle is not nil: %p\n", p)
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os.Exit(1)
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}
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}
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func checkTwoLevelIterator(obj interface{}) {
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i := obj.(*twoLevelIterator)
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if p := i.data.handle.Get(); p != nil {
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fmt.Fprintf(os.Stderr, "singleLevelIterator.data.handle is not nil: %p\n", p)
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os.Exit(1)
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}
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if p := i.index.handle.Get(); p != nil {
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fmt.Fprintf(os.Stderr, "singleLevelIterator.index.handle is not nil: %p\n", p)
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os.Exit(1)
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}
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}
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func checkRangeKeyFragmentBlockIterator(obj interface{}) {
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i := obj.(*rangeKeyFragmentBlockIter)
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if p := i.blockIter.handle.Get(); p != nil {
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fmt.Fprintf(os.Stderr, "fragmentBlockIter.blockIter.handle is not nil: %p\n", p)
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os.Exit(1)
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}
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}
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// compactionIterator is similar to Iterator but it increments the number of
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// bytes that have been iterated through.
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type compactionIterator struct {
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*singleLevelIterator
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bytesIterated *uint64
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prevOffset uint64
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}
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// compactionIterator implements the base.InternalIterator interface.
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var _ base.InternalIterator = (*compactionIterator)(nil)
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func (i *compactionIterator) String() string {
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if i.vState != nil {
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return i.vState.fileNum.String()
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}
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return i.reader.fileNum.String()
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}
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func (i *compactionIterator) SeekGE(
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key []byte, flags base.SeekGEFlags,
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) (*InternalKey, base.LazyValue) {
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panic("pebble: SeekGE unimplemented")
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}
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func (i *compactionIterator) SeekPrefixGE(
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prefix, key []byte, flags base.SeekGEFlags,
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) (*base.InternalKey, base.LazyValue) {
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panic("pebble: SeekPrefixGE unimplemented")
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}
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func (i *compactionIterator) SeekLT(
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key []byte, flags base.SeekLTFlags,
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) (*InternalKey, base.LazyValue) {
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panic("pebble: SeekLT unimplemented")
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}
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func (i *compactionIterator) First() (*InternalKey, base.LazyValue) {
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i.err = nil // clear cached iteration error
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return i.skipForward(i.singleLevelIterator.First())
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}
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func (i *compactionIterator) Last() (*InternalKey, base.LazyValue) {
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panic("pebble: Last unimplemented")
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}
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// Note: compactionIterator.Next mirrors the implementation of Iterator.Next
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// due to performance. Keep the two in sync.
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func (i *compactionIterator) Next() (*InternalKey, base.LazyValue) {
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if i.err != nil {
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return nil, base.LazyValue{}
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}
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return i.skipForward(i.data.Next())
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}
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func (i *compactionIterator) NextPrefix(succKey []byte) (*InternalKey, base.LazyValue) {
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panic("pebble: NextPrefix unimplemented")
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}
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func (i *compactionIterator) Prev() (*InternalKey, base.LazyValue) {
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panic("pebble: Prev unimplemented")
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}
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func (i *compactionIterator) skipForward(
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key *InternalKey, val base.LazyValue,
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) (*InternalKey, base.LazyValue) {
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if key == nil {
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for {
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if key, _ := i.index.Next(); key == nil {
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break
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}
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result := i.loadBlock(+1)
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if result != loadBlockOK {
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if i.err != nil {
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break
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}
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switch result {
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case loadBlockFailed:
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// We checked that i.index was at a valid entry, so
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// loadBlockFailed could not have happened due to to i.index
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// being exhausted, and must be due to an error.
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panic("loadBlock should not have failed with no error")
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case loadBlockIrrelevant:
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panic("compactionIter should not be using block intervals for skipping")
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default:
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panic(fmt.Sprintf("unexpected case %d", result))
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}
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}
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// result == loadBlockOK
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if key, val = i.data.First(); key != nil {
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break
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}
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}
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}
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curOffset := i.recordOffset()
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*i.bytesIterated += uint64(curOffset - i.prevOffset)
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i.prevOffset = curOffset
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if i.vState != nil && key != nil {
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cmp := i.cmp(key.UserKey, i.vState.upper.UserKey)
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if cmp > 0 || (i.vState.upper.IsExclusiveSentinel() && cmp == 0) {
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return nil, base.LazyValue{}
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}
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}
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return key, val
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}
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