mirror of
https://source.quilibrium.com/quilibrium/ceremonyclient.git
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1414 lines
51 KiB
Go
1414 lines
51 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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"context"
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"fmt"
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"unsafe"
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"github.com/cockroachdb/pebble/internal/base"
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"github.com/cockroachdb/pebble/internal/invariants"
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"github.com/cockroachdb/pebble/objstorage"
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"github.com/cockroachdb/pebble/objstorage/objstorageprovider"
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"github.com/cockroachdb/pebble/objstorage/objstorageprovider/objiotracing"
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)
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// singleLevelIterator iterates over an entire table of data. To seek for a given
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// key, it first looks in the index for the block that contains that key, and then
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// looks inside that block.
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type singleLevelIterator struct {
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ctx context.Context
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cmp Compare
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// Global lower/upper bound for the iterator.
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lower []byte
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upper []byte
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bpfs *BlockPropertiesFilterer
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// Per-block lower/upper bound. Nil if the bound does not apply to the block
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// because we determined the block lies completely within the bound.
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blockLower []byte
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blockUpper []byte
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reader *Reader
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// vState will be set iff the iterator is constructed for virtual sstable
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// iteration.
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vState *virtualState
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// endKeyInclusive is set to force the iterator to treat the upper field as
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// inclusive while iterating instead of exclusive.
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endKeyInclusive bool
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index blockIter
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data blockIter
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dataRH objstorage.ReadHandle
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dataRHPrealloc objstorageprovider.PreallocatedReadHandle
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// dataBH refers to the last data block that the iterator considered
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// loading. It may not actually have loaded the block, due to an error or
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// because it was considered irrelevant.
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dataBH BlockHandle
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vbReader *valueBlockReader
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// vbRH is the read handle for value blocks, which are in a different
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// part of the sstable than data blocks.
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vbRH objstorage.ReadHandle
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vbRHPrealloc objstorageprovider.PreallocatedReadHandle
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err error
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closeHook func(i Iterator) error
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// stats and iterStats are slightly different. stats is a shared struct
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// supplied from the outside, and represents stats for the whole iterator
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// tree and can be reset from the outside (e.g. when the pebble.Iterator is
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// being reused). It is currently only provided when the iterator tree is
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// rooted at pebble.Iterator. iterStats is this sstable iterator's private
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// stats that are reported to a CategoryStatsCollector when this iterator is
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// closed. More paths are instrumented with this as the
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// CategoryStatsCollector needed for this is provided by the
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// tableCacheContainer (which is more universally used).
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stats *base.InternalIteratorStats
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iterStats iterStatsAccumulator
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bufferPool *BufferPool
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// boundsCmp and positionedUsingLatestBounds are for optimizing iteration
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// that uses multiple adjacent bounds. The seek after setting a new bound
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// can use the fact that the iterator is either within the previous bounds
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// or exactly one key before or after the bounds. If the new bounds is
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// after/before the previous bounds, and we are already positioned at a
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// block that is relevant for the new bounds, we can try to first position
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// using Next/Prev (repeatedly) instead of doing a more expensive seek.
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//
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// When there are wide files at higher levels that match the bounds
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// but don't have any data for the bound, we will already be
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// positioned at the key beyond the bounds and won't need to do much
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// work -- given that most data is in L6, such files are likely to
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// dominate the performance of the mergingIter, and may be the main
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// benefit of this performance optimization (of course it also helps
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// when the file that has the data has successive seeks that stay in
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// the same block).
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//
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// Specifically, boundsCmp captures the relationship between the previous
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// and current bounds, if the iterator had been positioned after setting
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// the previous bounds. If it was not positioned, i.e., Seek/First/Last
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// were not called, we don't know where it is positioned and cannot
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// optimize.
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//
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// Example: Bounds moving forward, and iterator exhausted in forward direction.
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// bounds = [f, h), ^ shows block iterator position
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// file contents [ a b c d e f g h i j k ]
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// ^
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// new bounds = [j, k). Since positionedUsingLatestBounds=true, boundsCmp is
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// set to +1. SeekGE(j) can use next (the optimization also requires that j
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// is within the block, but that is not for correctness, but to limit the
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// optimization to when it will actually be an optimization).
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//
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// Example: Bounds moving forward.
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// bounds = [f, h), ^ shows block iterator position
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// file contents [ a b c d e f g h i j k ]
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// ^
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// new bounds = [j, k). Since positionedUsingLatestBounds=true, boundsCmp is
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// set to +1. SeekGE(j) can use next.
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//
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// Example: Bounds moving forward, but iterator not positioned using previous
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// bounds.
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// bounds = [f, h), ^ shows block iterator position
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// file contents [ a b c d e f g h i j k ]
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// ^
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// new bounds = [i, j). Iterator is at j since it was never positioned using
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// [f, h). So positionedUsingLatestBounds=false, and boundsCmp is set to 0.
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// SeekGE(i) will not use next.
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//
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// Example: Bounds moving forward and sparse file
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// bounds = [f, h), ^ shows block iterator position
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// file contents [ a z ]
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// ^
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// new bounds = [j, k). Since positionedUsingLatestBounds=true, boundsCmp is
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// set to +1. SeekGE(j) notices that the iterator is already past j and does
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// not need to do anything.
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//
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// Similar examples can be constructed for backward iteration.
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//
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// This notion of exactly one key before or after the bounds is not quite
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// true when block properties are used to ignore blocks. In that case we
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// can't stop precisely at the first block that is past the bounds since
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// we are using the index entries to enforce the bounds.
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//
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// e.g. 3 blocks with keys [b, c] [f, g], [i, j, k] with index entries d,
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// h, l. And let the lower bound be k, and we are reverse iterating. If
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// the block [i, j, k] is ignored due to the block interval annotations we
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// do need to move the index to block [f, g] since the index entry for the
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// [i, j, k] block is l which is not less than the lower bound of k. So we
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// have passed the entries i, j.
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//
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// This behavior is harmless since the block property filters are fixed
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// for the lifetime of the iterator so i, j are irrelevant. In addition,
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// the current code will not load the [f, g] block, so the seek
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// optimization that attempts to use Next/Prev do not apply anyway.
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boundsCmp int
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positionedUsingLatestBounds bool
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// exhaustedBounds represents whether the iterator is exhausted for
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// iteration by reaching the upper or lower bound. +1 when exhausted
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// the upper bound, -1 when exhausted the lower bound, and 0 when
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// neither. exhaustedBounds is also used for the TrySeekUsingNext
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// optimization in twoLevelIterator and singleLevelIterator. Care should be
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// taken in setting this in twoLevelIterator before calling into
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// singleLevelIterator, given that these two iterators share this field.
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exhaustedBounds int8
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// maybeFilteredKeysSingleLevel indicates whether the last iterator
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// positioning operation may have skipped any data blocks due to
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// block-property filters when positioning the index.
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maybeFilteredKeysSingleLevel bool
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// useFilter specifies whether the filter block in this sstable, if present,
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// should be used for prefix seeks or not. In some cases it is beneficial
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// to skip a filter block even if it exists (eg. if probability of a match
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// is high).
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useFilter bool
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lastBloomFilterMatched bool
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hideObsoletePoints bool
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}
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// singleLevelIterator implements the base.InternalIterator interface.
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var _ base.InternalIterator = (*singleLevelIterator)(nil)
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// init initializes a singleLevelIterator for reading from the table. It is
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// synonmous with Reader.NewIter, but allows for reusing of the iterator
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// between different Readers.
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//
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// Note that lower, upper passed into init has nothing to do with virtual sstable
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// bounds. If the virtualState passed in is not nil, then virtual sstable bounds
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// will be enforced.
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func (i *singleLevelIterator) init(
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ctx context.Context,
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r *Reader,
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v *virtualState,
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lower, upper []byte,
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filterer *BlockPropertiesFilterer,
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useFilter, hideObsoletePoints bool,
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stats *base.InternalIteratorStats,
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categoryAndQoS CategoryAndQoS,
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statsCollector *CategoryStatsCollector,
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rp ReaderProvider,
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bufferPool *BufferPool,
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) error {
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if r.err != nil {
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return r.err
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}
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i.iterStats.init(categoryAndQoS, statsCollector)
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indexH, err := r.readIndex(ctx, stats, &i.iterStats)
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if err != nil {
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return err
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}
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if v != nil {
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i.vState = v
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i.endKeyInclusive, lower, upper = v.constrainBounds(lower, upper, false /* endInclusive */)
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}
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i.ctx = ctx
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i.lower = lower
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i.upper = upper
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i.bpfs = filterer
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i.useFilter = useFilter
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i.reader = r
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i.cmp = r.Compare
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i.stats = stats
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i.hideObsoletePoints = hideObsoletePoints
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i.bufferPool = bufferPool
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err = i.index.initHandle(i.cmp, indexH, r.Properties.GlobalSeqNum, false)
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if err != nil {
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// blockIter.Close releases indexH and always returns a nil error
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_ = i.index.Close()
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return err
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}
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i.dataRH = objstorageprovider.UsePreallocatedReadHandle(ctx, r.readable, &i.dataRHPrealloc)
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if r.tableFormat >= TableFormatPebblev3 {
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if r.Properties.NumValueBlocks > 0 {
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// NB: we cannot avoid this ~248 byte allocation, since valueBlockReader
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// can outlive the singleLevelIterator due to be being embedded in a
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// LazyValue. This consumes ~2% in microbenchmark CPU profiles, but we
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// should only optimize this if it shows up as significant in end-to-end
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// CockroachDB benchmarks, since it is tricky to do so. One possibility
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// is that if many sstable iterators only get positioned at latest
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// versions of keys, and therefore never expose a LazyValue that is
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// separated to their callers, they can put this valueBlockReader into a
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// sync.Pool.
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i.vbReader = &valueBlockReader{
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bpOpen: i,
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rp: rp,
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vbih: r.valueBIH,
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stats: stats,
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}
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i.data.lazyValueHandling.vbr = i.vbReader
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i.vbRH = objstorageprovider.UsePreallocatedReadHandle(ctx, r.readable, &i.vbRHPrealloc)
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}
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i.data.lazyValueHandling.hasValuePrefix = true
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}
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return nil
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}
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// Helper function to check if keys returned from iterator are within global and virtual bounds.
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func (i *singleLevelIterator) maybeVerifyKey(
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iKey *InternalKey, val base.LazyValue,
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) (*InternalKey, base.LazyValue) {
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// maybeVerify key is only used for virtual sstable iterators.
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if invariants.Enabled && i.vState != nil && iKey != nil {
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key := iKey.UserKey
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uc, vuc := i.cmp(key, i.upper), i.cmp(key, i.vState.upper.UserKey)
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lc, vlc := i.cmp(key, i.lower), i.cmp(key, i.vState.lower.UserKey)
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if (i.vState.upper.IsExclusiveSentinel() && vuc == 0) || (!i.endKeyInclusive && uc == 0) || uc > 0 || vuc > 0 || lc < 0 || vlc < 0 {
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panic(fmt.Sprintf("key: %s out of bounds of singleLevelIterator", key))
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}
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}
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return iKey, val
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}
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// setupForCompaction sets up the singleLevelIterator for use with compactionIter.
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// Currently, it skips readahead ramp-up. It should be called after init is called.
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func (i *singleLevelIterator) setupForCompaction() {
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i.dataRH.SetupForCompaction()
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if i.vbRH != nil {
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i.vbRH.SetupForCompaction()
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}
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}
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func (i *singleLevelIterator) resetForReuse() singleLevelIterator {
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return singleLevelIterator{
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index: i.index.resetForReuse(),
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data: i.data.resetForReuse(),
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}
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}
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func (i *singleLevelIterator) initBounds() {
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// Trim the iteration bounds for the current block. We don't have to check
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// the bounds on each iteration if the block is entirely contained within the
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// iteration bounds.
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i.blockLower = i.lower
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if i.blockLower != nil {
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key, _ := i.data.First()
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if key != nil && i.cmp(i.blockLower, key.UserKey) < 0 {
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// The lower-bound is less than the first key in the block. No need
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// to check the lower-bound again for this block.
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i.blockLower = nil
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}
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}
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i.blockUpper = i.upper
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if i.blockUpper != nil && i.cmp(i.blockUpper, i.index.Key().UserKey) > 0 {
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// The upper-bound is greater than the index key which itself is greater
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// than or equal to every key in the block. No need to check the
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// upper-bound again for this block. Even if blockUpper is inclusive
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// because of upper being inclusive, we can still safely set blockUpper
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// to nil here.
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//
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// TODO(bananabrick): We could also set blockUpper to nil for the >=
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// case, if blockUpper is inclusive.
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i.blockUpper = nil
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}
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}
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// Deterministic disabling of the bounds-based optimization that avoids seeking.
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// Uses the iterator pointer, since we want diversity in iterator behavior for
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// the same SetBounds call. Used for tests.
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func disableBoundsOpt(bound []byte, ptr uintptr) bool {
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// Fibonacci hash https://probablydance.com/2018/06/16/fibonacci-hashing-the-optimization-that-the-world-forgot-or-a-better-alternative-to-integer-modulo/
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simpleHash := (11400714819323198485 * uint64(ptr)) >> 63
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return bound[len(bound)-1]&byte(1) == 0 && simpleHash == 0
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}
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// ensureBoundsOptDeterminism provides a facility for disabling of the bounds
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// optimizations performed by disableBoundsOpt for tests that require
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// deterministic iterator behavior. Some unit tests examine internal iterator
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// state and require this behavior to be deterministic.
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var ensureBoundsOptDeterminism bool
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// SetBounds implements internalIterator.SetBounds, as documented in the pebble
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// package. Note that the upper field is exclusive.
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func (i *singleLevelIterator) SetBounds(lower, upper []byte) {
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i.boundsCmp = 0
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if i.vState != nil {
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// If the reader is constructed for a virtual sstable, then we must
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// constrain the bounds of the reader. For physical sstables, the bounds
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// can be wider than the actual sstable's bounds because we won't
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// accidentally expose additional keys as there are no additional keys.
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i.endKeyInclusive, lower, upper = i.vState.constrainBounds(
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lower, upper, false,
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)
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} else {
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// TODO(bananabrick): Figure out the logic here to enable the boundsCmp
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// optimization for virtual sstables.
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if i.positionedUsingLatestBounds {
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if i.upper != nil && lower != nil && i.cmp(i.upper, lower) <= 0 {
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i.boundsCmp = +1
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if invariants.Enabled && !ensureBoundsOptDeterminism &&
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disableBoundsOpt(lower, uintptr(unsafe.Pointer(i))) {
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i.boundsCmp = 0
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}
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} else if i.lower != nil && upper != nil && i.cmp(upper, i.lower) <= 0 {
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i.boundsCmp = -1
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if invariants.Enabled && !ensureBoundsOptDeterminism &&
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disableBoundsOpt(upper, uintptr(unsafe.Pointer(i))) {
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i.boundsCmp = 0
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}
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}
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}
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}
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i.positionedUsingLatestBounds = false
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i.lower = lower
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i.upper = upper
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i.blockLower = nil
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i.blockUpper = nil
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}
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func (i *singleLevelIterator) SetContext(ctx context.Context) {
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i.ctx = ctx
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}
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// loadBlock loads the block at the current index position and leaves i.data
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// unpositioned. If unsuccessful, it sets i.err to any error encountered, which
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// may be nil if we have simply exhausted the entire table.
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func (i *singleLevelIterator) loadBlock(dir int8) loadBlockResult {
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if !i.index.valid() {
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// Ensure the data block iterator is invalidated even if loading of the block
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// fails.
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i.data.invalidate()
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return loadBlockFailed
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}
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// Load the next block.
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v := i.index.value()
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bhp, err := decodeBlockHandleWithProperties(v.InPlaceValue())
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if i.dataBH == bhp.BlockHandle && i.data.valid() {
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// We're already at the data block we want to load. Reset bounds in case
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// they changed since the last seek, but don't reload the block from cache
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// or disk.
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//
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// It's safe to leave i.data in its original state here, as all callers to
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// loadBlock make an absolute positioning call (i.e. a seek, first, or last)
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// to `i.data` right after loadBlock returns loadBlockOK.
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i.initBounds()
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return loadBlockOK
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}
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// Ensure the data block iterator is invalidated even if loading of the block
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// fails.
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i.data.invalidate()
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i.dataBH = bhp.BlockHandle
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if err != nil {
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i.err = errCorruptIndexEntry
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return loadBlockFailed
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}
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if i.bpfs != nil {
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intersects, err := i.bpfs.intersects(bhp.Props)
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if err != nil {
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i.err = errCorruptIndexEntry
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return loadBlockFailed
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}
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if intersects == blockMaybeExcluded {
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intersects = i.resolveMaybeExcluded(dir)
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}
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if intersects == blockExcluded {
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i.maybeFilteredKeysSingleLevel = true
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return loadBlockIrrelevant
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}
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// blockIntersects
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}
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ctx := objiotracing.WithBlockType(i.ctx, objiotracing.DataBlock)
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block, err := i.reader.readBlock(
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ctx, i.dataBH, nil /* transform */, i.dataRH, i.stats, &i.iterStats, i.bufferPool)
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if err != nil {
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i.err = err
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return loadBlockFailed
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}
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i.err = i.data.initHandle(i.cmp, block, i.reader.Properties.GlobalSeqNum, i.hideObsoletePoints)
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if i.err != nil {
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// The block is partially loaded, and we don't want it to appear valid.
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i.data.invalidate()
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return loadBlockFailed
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}
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i.initBounds()
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return loadBlockOK
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}
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// readBlockForVBR implements the blockProviderWhenOpen interface for use by
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// the valueBlockReader.
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func (i *singleLevelIterator) readBlockForVBR(
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h BlockHandle, stats *base.InternalIteratorStats,
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) (bufferHandle, error) {
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ctx := objiotracing.WithBlockType(i.ctx, objiotracing.ValueBlock)
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return i.reader.readBlock(ctx, h, nil, i.vbRH, stats, &i.iterStats, i.bufferPool)
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}
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// resolveMaybeExcluded is invoked when the block-property filterer has found
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// that a block is excluded according to its properties but only if its bounds
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// fall within the filter's current bounds. This function consults the
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// apprioriate bound, depending on the iteration direction, and returns either
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// `blockIntersects` or `blockMaybeExcluded`.
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func (i *singleLevelIterator) resolveMaybeExcluded(dir int8) intersectsResult {
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// TODO(jackson): We could first try comparing to top-level index block's
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// key, and if within bounds avoid per-data block key comparisons.
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// This iterator is configured with a bound-limited block property
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// filter. The bpf determined this block could be excluded from
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// iteration based on the property encoded in the block handle.
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// However, we still need to determine if the block is wholly
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|
// contained within the filter's key bounds.
|
|
//
|
|
// External guarantees ensure all the block's keys are ≥ the
|
|
// filter's lower bound during forward iteration, and that all the
|
|
// block's keys are < the filter's upper bound during backward
|
|
// iteration. We only need to determine if the opposite bound is
|
|
// also met.
|
|
//
|
|
// The index separator in index.Key() provides an inclusive
|
|
// upper-bound for the data block's keys, guaranteeing that all its
|
|
// keys are ≤ index.Key(). For forward iteration, this is all we
|
|
// need.
|
|
if dir > 0 {
|
|
// Forward iteration.
|
|
if i.bpfs.boundLimitedFilter.KeyIsWithinUpperBound(i.index.Key().UserKey) {
|
|
return blockExcluded
|
|
}
|
|
return blockIntersects
|
|
}
|
|
|
|
// Reverse iteration.
|
|
//
|
|
// Because we're iterating in the reverse direction, we don't yet have
|
|
// enough context available to determine if the block is wholly contained
|
|
// within its bounds. This case arises only during backward iteration,
|
|
// because of the way the index is structured.
|
|
//
|
|
// Consider a bound-limited bpf limited to the bounds [b,d), loading the
|
|
// block with separator `c`. During reverse iteration, the guarantee that
|
|
// all the block's keys are < `d` is externally provided, but no guarantee
|
|
// is made on the bpf's lower bound. The separator `c` only provides an
|
|
// inclusive upper bound on the block's keys, indicating that the
|
|
// corresponding block handle points to a block containing only keys ≤ `c`.
|
|
//
|
|
// To establish a lower bound, we step the index backwards to read the
|
|
// previous block's separator, which provides an inclusive lower bound on
|
|
// the original block's keys. Afterwards, we step forward to restore our
|
|
// index position.
|
|
if peekKey, _ := i.index.Prev(); peekKey == nil {
|
|
// The original block points to the first block of this index block. If
|
|
// there's a two-level index, it could potentially provide a lower
|
|
// bound, but the code refactoring necessary to read it doesn't seem
|
|
// worth the payoff. We fall through to loading the block.
|
|
} else if i.bpfs.boundLimitedFilter.KeyIsWithinLowerBound(peekKey.UserKey) {
|
|
// The lower-bound on the original block falls within the filter's
|
|
// bounds, and we can skip the block (after restoring our current index
|
|
// position).
|
|
_, _ = i.index.Next()
|
|
return blockExcluded
|
|
}
|
|
_, _ = i.index.Next()
|
|
return blockIntersects
|
|
}
|
|
|
|
func (i *singleLevelIterator) initBoundsForAlreadyLoadedBlock() {
|
|
if i.data.getFirstUserKey() == nil {
|
|
panic("initBoundsForAlreadyLoadedBlock must not be called on empty or corrupted block")
|
|
}
|
|
i.blockLower = i.lower
|
|
if i.blockLower != nil {
|
|
firstUserKey := i.data.getFirstUserKey()
|
|
if firstUserKey != nil && i.cmp(i.blockLower, firstUserKey) < 0 {
|
|
// The lower-bound is less than the first key in the block. No need
|
|
// to check the lower-bound again for this block.
|
|
i.blockLower = nil
|
|
}
|
|
}
|
|
i.blockUpper = i.upper
|
|
if i.blockUpper != nil && i.cmp(i.blockUpper, i.index.Key().UserKey) > 0 {
|
|
// The upper-bound is greater than the index key which itself is greater
|
|
// than or equal to every key in the block. No need to check the
|
|
// upper-bound again for this block.
|
|
i.blockUpper = nil
|
|
}
|
|
}
|
|
|
|
// The number of times to call Next/Prev in a block before giving up and seeking.
|
|
// The value of 4 is arbitrary.
|
|
// TODO(sumeer): experiment with dynamic adjustment based on the history of
|
|
// seeks for a particular iterator.
|
|
const numStepsBeforeSeek = 4
|
|
|
|
func (i *singleLevelIterator) trySeekGEUsingNextWithinBlock(
|
|
key []byte,
|
|
) (k *InternalKey, v base.LazyValue, done bool) {
|
|
k, v = i.data.Key(), i.data.value()
|
|
for j := 0; j < numStepsBeforeSeek; j++ {
|
|
curKeyCmp := i.cmp(k.UserKey, key)
|
|
if curKeyCmp >= 0 {
|
|
if i.blockUpper != nil {
|
|
cmp := i.cmp(k.UserKey, i.blockUpper)
|
|
if (!i.endKeyInclusive && cmp >= 0) || cmp > 0 {
|
|
i.exhaustedBounds = +1
|
|
return nil, base.LazyValue{}, true
|
|
}
|
|
}
|
|
return k, v, true
|
|
}
|
|
k, v = i.data.Next()
|
|
if k == nil {
|
|
break
|
|
}
|
|
}
|
|
return k, v, false
|
|
}
|
|
|
|
func (i *singleLevelIterator) trySeekLTUsingPrevWithinBlock(
|
|
key []byte,
|
|
) (k *InternalKey, v base.LazyValue, done bool) {
|
|
k, v = i.data.Key(), i.data.value()
|
|
for j := 0; j < numStepsBeforeSeek; j++ {
|
|
curKeyCmp := i.cmp(k.UserKey, key)
|
|
if curKeyCmp < 0 {
|
|
if i.blockLower != nil && i.cmp(k.UserKey, i.blockLower) < 0 {
|
|
i.exhaustedBounds = -1
|
|
return nil, base.LazyValue{}, true
|
|
}
|
|
return k, v, true
|
|
}
|
|
k, v = i.data.Prev()
|
|
if k == nil {
|
|
break
|
|
}
|
|
}
|
|
return k, v, false
|
|
}
|
|
|
|
func (i *singleLevelIterator) recordOffset() uint64 {
|
|
offset := i.dataBH.Offset
|
|
if i.data.valid() {
|
|
// - i.dataBH.Length/len(i.data.data) is the compression ratio. If
|
|
// uncompressed, this is 1.
|
|
// - i.data.nextOffset is the uncompressed position of the current record
|
|
// in the block.
|
|
// - i.dataBH.Offset is the offset of the block in the sstable before
|
|
// decompression.
|
|
offset += (uint64(i.data.nextOffset) * i.dataBH.Length) / uint64(len(i.data.data))
|
|
} else {
|
|
// Last entry in the block must increment bytes iterated by the size of the block trailer
|
|
// and restart points.
|
|
offset += i.dataBH.Length + blockTrailerLen
|
|
}
|
|
return offset
|
|
}
|
|
|
|
// SeekGE implements internalIterator.SeekGE, as documented in the pebble
|
|
// package. Note that SeekGE only checks the upper bound. It is up to the
|
|
// caller to ensure that key is greater than or equal to the lower bound.
|
|
func (i *singleLevelIterator) SeekGE(
|
|
key []byte, flags base.SeekGEFlags,
|
|
) (*InternalKey, base.LazyValue) {
|
|
if i.vState != nil {
|
|
// Callers of SeekGE don't know about virtual sstable bounds, so we may
|
|
// have to internally restrict the bounds.
|
|
//
|
|
// TODO(bananabrick): We can optimize this check away for the level iter
|
|
// if necessary.
|
|
if i.cmp(key, i.lower) < 0 {
|
|
key = i.lower
|
|
}
|
|
}
|
|
|
|
if flags.TrySeekUsingNext() {
|
|
// The i.exhaustedBounds comparison indicates that the upper bound was
|
|
// reached. The i.data.isDataInvalidated() indicates that the sstable was
|
|
// exhausted.
|
|
if (i.exhaustedBounds == +1 || i.data.isDataInvalidated()) && i.err == nil {
|
|
// Already exhausted, so return nil.
|
|
return nil, base.LazyValue{}
|
|
}
|
|
if i.err != nil {
|
|
// The current iterator position cannot be used.
|
|
flags = flags.DisableTrySeekUsingNext()
|
|
}
|
|
// INVARIANT: flags.TrySeekUsingNext() => i.err == nil &&
|
|
// !i.exhaustedBounds==+1 && !i.data.isDataInvalidated(). That is,
|
|
// data-exhausted and bounds-exhausted, as defined earlier, are both
|
|
// false. Ths makes it safe to clear out i.exhaustedBounds and i.err
|
|
// before calling into seekGEHelper.
|
|
}
|
|
|
|
i.exhaustedBounds = 0
|
|
i.err = nil // clear cached iteration error
|
|
boundsCmp := i.boundsCmp
|
|
// Seek optimization only applies until iterator is first positioned after SetBounds.
|
|
i.boundsCmp = 0
|
|
i.positionedUsingLatestBounds = true
|
|
return i.seekGEHelper(key, boundsCmp, flags)
|
|
}
|
|
|
|
// seekGEHelper contains the common functionality for SeekGE and SeekPrefixGE.
|
|
func (i *singleLevelIterator) seekGEHelper(
|
|
key []byte, boundsCmp int, flags base.SeekGEFlags,
|
|
) (*InternalKey, base.LazyValue) {
|
|
// Invariant: trySeekUsingNext => !i.data.isDataInvalidated() && i.exhaustedBounds != +1
|
|
|
|
// SeekGE performs various step-instead-of-seeking optimizations: eg enabled
|
|
// by trySeekUsingNext, or by monotonically increasing bounds (i.boundsCmp).
|
|
// Care must be taken to ensure that when performing these optimizations and
|
|
// the iterator becomes exhausted, i.maybeFilteredKeys is set appropriately.
|
|
// Consider a previous SeekGE that filtered keys from k until the current
|
|
// iterator position.
|
|
//
|
|
// If the previous SeekGE exhausted the iterator, it's possible keys greater
|
|
// than or equal to the current search key were filtered. We must not reuse
|
|
// the current iterator position without remembering the previous value of
|
|
// maybeFilteredKeys.
|
|
|
|
var dontSeekWithinBlock bool
|
|
if !i.data.isDataInvalidated() && !i.index.isDataInvalidated() && i.data.valid() && i.index.valid() &&
|
|
boundsCmp > 0 && i.cmp(key, i.index.Key().UserKey) <= 0 {
|
|
// Fast-path: The bounds have moved forward and this SeekGE is
|
|
// respecting the lower bound (guaranteed by Iterator). We know that
|
|
// the iterator must already be positioned within or just outside the
|
|
// previous bounds. Therefore it cannot be positioned at a block (or
|
|
// the position within that block) that is ahead of the seek position.
|
|
// However it can be positioned at an earlier block. This fast-path to
|
|
// use Next() on the block is only applied when we are already at the
|
|
// block that the slow-path (the else-clause) would load -- this is
|
|
// the motivation for the i.cmp(key, i.index.Key().UserKey) <= 0
|
|
// predicate.
|
|
i.initBoundsForAlreadyLoadedBlock()
|
|
ikey, val, done := i.trySeekGEUsingNextWithinBlock(key)
|
|
if done {
|
|
return ikey, val
|
|
}
|
|
if ikey == nil {
|
|
// Done with this block.
|
|
dontSeekWithinBlock = true
|
|
}
|
|
} else {
|
|
// Cannot use bounds monotonicity. But may be able to optimize if
|
|
// caller claimed externally known invariant represented by
|
|
// flags.TrySeekUsingNext().
|
|
if flags.TrySeekUsingNext() {
|
|
// seekPrefixGE or SeekGE has already ensured
|
|
// !i.data.isDataInvalidated() && i.exhaustedBounds != +1
|
|
currKey := i.data.Key()
|
|
value := i.data.value()
|
|
less := i.cmp(currKey.UserKey, key) < 0
|
|
// We could be more sophisticated and confirm that the seek
|
|
// position is within the current block before applying this
|
|
// optimization. But there may be some benefit even if it is in
|
|
// the next block, since we can avoid seeking i.index.
|
|
for j := 0; less && j < numStepsBeforeSeek; j++ {
|
|
currKey, value = i.Next()
|
|
if currKey == nil {
|
|
return nil, base.LazyValue{}
|
|
}
|
|
less = i.cmp(currKey.UserKey, key) < 0
|
|
}
|
|
if !less {
|
|
if i.blockUpper != nil {
|
|
cmp := i.cmp(currKey.UserKey, i.blockUpper)
|
|
if (!i.endKeyInclusive && cmp >= 0) || cmp > 0 {
|
|
i.exhaustedBounds = +1
|
|
return nil, base.LazyValue{}
|
|
}
|
|
}
|
|
return currKey, value
|
|
}
|
|
}
|
|
|
|
// Slow-path.
|
|
// Since we're re-seeking the iterator, the previous value of
|
|
// maybeFilteredKeysSingleLevel is irrelevant. If we filter out blocks
|
|
// during seeking, loadBlock will set it to true.
|
|
i.maybeFilteredKeysSingleLevel = false
|
|
|
|
var ikey *InternalKey
|
|
if ikey, _ = i.index.SeekGE(key, flags.DisableTrySeekUsingNext()); ikey == nil {
|
|
// The target key is greater than any key in the index block.
|
|
// Invalidate the block iterator so that a subsequent call to Prev()
|
|
// will return the last key in the table.
|
|
i.data.invalidate()
|
|
return nil, base.LazyValue{}
|
|
}
|
|
result := i.loadBlock(+1)
|
|
if result == loadBlockFailed {
|
|
return nil, base.LazyValue{}
|
|
}
|
|
if result == loadBlockIrrelevant {
|
|
// Enforce the upper bound here since don't want to bother moving
|
|
// to the next block if upper bound is already exceeded. Note that
|
|
// the next block starts with keys >= ikey.UserKey since even
|
|
// though this is the block separator, the same user key can span
|
|
// multiple blocks. If upper is exclusive we use >= below, else
|
|
// we use >.
|
|
if i.upper != nil {
|
|
cmp := i.cmp(ikey.UserKey, i.upper)
|
|
if (!i.endKeyInclusive && cmp >= 0) || cmp > 0 {
|
|
i.exhaustedBounds = +1
|
|
return nil, base.LazyValue{}
|
|
}
|
|
}
|
|
// Want to skip to the next block.
|
|
dontSeekWithinBlock = true
|
|
}
|
|
}
|
|
if !dontSeekWithinBlock {
|
|
if ikey, val := i.data.SeekGE(key, flags.DisableTrySeekUsingNext()); ikey != nil {
|
|
if i.blockUpper != nil {
|
|
cmp := i.cmp(ikey.UserKey, i.blockUpper)
|
|
if (!i.endKeyInclusive && cmp >= 0) || cmp > 0 {
|
|
i.exhaustedBounds = +1
|
|
return nil, base.LazyValue{}
|
|
}
|
|
}
|
|
return ikey, val
|
|
}
|
|
}
|
|
return i.skipForward()
|
|
}
|
|
|
|
// SeekPrefixGE implements internalIterator.SeekPrefixGE, as documented in the
|
|
// pebble package. Note that SeekPrefixGE only checks the upper bound. It is up
|
|
// to the caller to ensure that key is greater than or equal to the lower bound.
|
|
func (i *singleLevelIterator) SeekPrefixGE(
|
|
prefix, key []byte, flags base.SeekGEFlags,
|
|
) (*base.InternalKey, base.LazyValue) {
|
|
if i.vState != nil {
|
|
// Callers of SeekPrefixGE aren't aware of virtual sstable bounds, so
|
|
// we may have to internally restrict the bounds.
|
|
//
|
|
// TODO(bananabrick): We can optimize away this check for the level iter
|
|
// if necessary.
|
|
if i.cmp(key, i.lower) < 0 {
|
|
key = i.lower
|
|
}
|
|
}
|
|
return i.seekPrefixGE(prefix, key, flags, i.useFilter)
|
|
}
|
|
|
|
func (i *singleLevelIterator) seekPrefixGE(
|
|
prefix, key []byte, flags base.SeekGEFlags, checkFilter bool,
|
|
) (k *InternalKey, value base.LazyValue) {
|
|
// NOTE: prefix is only used for bloom filter checking and not later work in
|
|
// this method. Hence, we can use the existing iterator position if the last
|
|
// SeekPrefixGE did not fail bloom filter matching.
|
|
|
|
err := i.err
|
|
i.err = nil // clear cached iteration error
|
|
if checkFilter && i.reader.tableFilter != nil {
|
|
if !i.lastBloomFilterMatched {
|
|
// Iterator is not positioned based on last seek.
|
|
flags = flags.DisableTrySeekUsingNext()
|
|
}
|
|
i.lastBloomFilterMatched = false
|
|
// Check prefix bloom filter.
|
|
var dataH bufferHandle
|
|
dataH, i.err = i.reader.readFilter(i.ctx, i.stats, &i.iterStats)
|
|
if i.err != nil {
|
|
i.data.invalidate()
|
|
return nil, base.LazyValue{}
|
|
}
|
|
mayContain := i.reader.tableFilter.mayContain(dataH.Get(), prefix)
|
|
dataH.Release()
|
|
if !mayContain {
|
|
// This invalidation may not be necessary for correctness, and may
|
|
// be a place to optimize later by reusing the already loaded
|
|
// block. It was necessary in earlier versions of the code since
|
|
// the caller was allowed to call Next when SeekPrefixGE returned
|
|
// nil. This is no longer allowed.
|
|
i.data.invalidate()
|
|
return nil, base.LazyValue{}
|
|
}
|
|
i.lastBloomFilterMatched = true
|
|
}
|
|
if flags.TrySeekUsingNext() {
|
|
// The i.exhaustedBounds comparison indicates that the upper bound was
|
|
// reached. The i.data.isDataInvalidated() indicates that the sstable was
|
|
// exhausted.
|
|
if (i.exhaustedBounds == +1 || i.data.isDataInvalidated()) && err == nil {
|
|
// Already exhausted, so return nil.
|
|
return nil, base.LazyValue{}
|
|
}
|
|
if err != nil {
|
|
// The current iterator position cannot be used.
|
|
flags = flags.DisableTrySeekUsingNext()
|
|
}
|
|
// INVARIANT: flags.TrySeekUsingNext() => err == nil &&
|
|
// !i.exhaustedBounds==+1 && !i.data.isDataInvalidated(). That is,
|
|
// data-exhausted and bounds-exhausted, as defined earlier, are both
|
|
// false. Ths makes it safe to clear out i.exhaustedBounds and i.err
|
|
// before calling into seekGEHelper.
|
|
}
|
|
// Bloom filter matches, or skipped, so this method will position the
|
|
// iterator.
|
|
i.exhaustedBounds = 0
|
|
boundsCmp := i.boundsCmp
|
|
// Seek optimization only applies until iterator is first positioned after SetBounds.
|
|
i.boundsCmp = 0
|
|
i.positionedUsingLatestBounds = true
|
|
k, value = i.seekGEHelper(key, boundsCmp, flags)
|
|
return i.maybeVerifyKey(k, value)
|
|
}
|
|
|
|
// virtualLast should only be called if i.vReader != nil.
|
|
func (i *singleLevelIterator) virtualLast() (*InternalKey, base.LazyValue) {
|
|
if i.vState == nil {
|
|
panic("pebble: invalid call to virtualLast")
|
|
}
|
|
|
|
// Seek to the first internal key.
|
|
ikey, _ := i.SeekGE(i.upper, base.SeekGEFlagsNone)
|
|
if i.endKeyInclusive {
|
|
// Let's say the virtual sstable upper bound is c#1, with the keys c#3, c#2,
|
|
// c#1, d, e, ... in the sstable. So, the last key in the virtual sstable is
|
|
// c#1. We can perform SeekGE(i.upper) and then keep nexting until we find
|
|
// the last key with userkey == i.upper.
|
|
//
|
|
// TODO(bananabrick): Think about how to improve this. If many internal keys
|
|
// with the same user key at the upper bound then this could be slow, but
|
|
// maybe the odds of having many internal keys with the same user key at the
|
|
// upper bound are low.
|
|
for ikey != nil && i.cmp(ikey.UserKey, i.upper) == 0 {
|
|
ikey, _ = i.Next()
|
|
}
|
|
return i.Prev()
|
|
}
|
|
|
|
// We seeked to the first key >= i.upper.
|
|
return i.Prev()
|
|
}
|
|
|
|
// SeekLT implements internalIterator.SeekLT, as documented in the pebble
|
|
// package. Note that SeekLT only checks the lower bound. It is up to the
|
|
// caller to ensure that key is less than or equal to the upper bound.
|
|
func (i *singleLevelIterator) SeekLT(
|
|
key []byte, flags base.SeekLTFlags,
|
|
) (*InternalKey, base.LazyValue) {
|
|
if i.vState != nil {
|
|
// Might have to fix upper bound since virtual sstable bounds are not
|
|
// known to callers of SeekLT.
|
|
//
|
|
// TODO(bananabrick): We can optimize away this check for the level iter
|
|
// if necessary.
|
|
cmp := i.cmp(key, i.upper)
|
|
// key == i.upper is fine. We'll do the right thing and return the
|
|
// first internal key with user key < key.
|
|
if cmp > 0 {
|
|
// Return the last key in the virtual sstable.
|
|
return i.virtualLast()
|
|
}
|
|
}
|
|
|
|
i.exhaustedBounds = 0
|
|
i.err = nil // clear cached iteration error
|
|
boundsCmp := i.boundsCmp
|
|
// Seek optimization only applies until iterator is first positioned after SetBounds.
|
|
i.boundsCmp = 0
|
|
|
|
// Seeking operations perform various step-instead-of-seeking optimizations:
|
|
// eg by considering monotonically increasing bounds (i.boundsCmp). Care
|
|
// must be taken to ensure that when performing these optimizations and the
|
|
// iterator becomes exhausted i.maybeFilteredKeysSingleLevel is set
|
|
// appropriately. Consider a previous SeekLT that filtered keys from k
|
|
// until the current iterator position.
|
|
//
|
|
// If the previous SeekLT did exhausted the iterator, it's possible keys
|
|
// less than the current search key were filtered. We must not reuse the
|
|
// current iterator position without remembering the previous value of
|
|
// maybeFilteredKeysSingleLevel.
|
|
|
|
i.positionedUsingLatestBounds = true
|
|
|
|
var dontSeekWithinBlock bool
|
|
if !i.data.isDataInvalidated() && !i.index.isDataInvalidated() && i.data.valid() && i.index.valid() &&
|
|
boundsCmp < 0 && i.cmp(i.data.getFirstUserKey(), key) < 0 {
|
|
// Fast-path: The bounds have moved backward, and this SeekLT is
|
|
// respecting the upper bound (guaranteed by Iterator). We know that
|
|
// the iterator must already be positioned within or just outside the
|
|
// previous bounds. Therefore it cannot be positioned at a block (or
|
|
// the position within that block) that is behind the seek position.
|
|
// However it can be positioned at a later block. This fast-path to
|
|
// use Prev() on the block is only applied when we are already at the
|
|
// block that can satisfy this seek -- this is the motivation for the
|
|
// the i.cmp(i.data.firstKey.UserKey, key) < 0 predicate.
|
|
i.initBoundsForAlreadyLoadedBlock()
|
|
ikey, val, done := i.trySeekLTUsingPrevWithinBlock(key)
|
|
if done {
|
|
return ikey, val
|
|
}
|
|
if ikey == nil {
|
|
// Done with this block.
|
|
dontSeekWithinBlock = true
|
|
}
|
|
} else {
|
|
// Slow-path.
|
|
i.maybeFilteredKeysSingleLevel = false
|
|
var ikey *InternalKey
|
|
|
|
// NB: If a bound-limited block property filter is configured, it's
|
|
// externally ensured that the filter is disabled (through returning
|
|
// Intersects=false irrespective of the block props provided) during
|
|
// seeks.
|
|
if ikey, _ = i.index.SeekGE(key, base.SeekGEFlagsNone); ikey == nil {
|
|
ikey, _ = i.index.Last()
|
|
if ikey == nil {
|
|
return nil, base.LazyValue{}
|
|
}
|
|
}
|
|
// INVARIANT: ikey != nil.
|
|
result := i.loadBlock(-1)
|
|
if result == loadBlockFailed {
|
|
return nil, base.LazyValue{}
|
|
}
|
|
if result == loadBlockIrrelevant {
|
|
// Enforce the lower bound here since don't want to bother moving
|
|
// to the previous block if lower bound is already exceeded. Note
|
|
// that the previous block starts with keys <= ikey.UserKey since
|
|
// even though this is the current block's separator, the same
|
|
// user key can span multiple blocks.
|
|
if i.lower != nil && i.cmp(ikey.UserKey, i.lower) < 0 {
|
|
i.exhaustedBounds = -1
|
|
return nil, base.LazyValue{}
|
|
}
|
|
// Want to skip to the previous block.
|
|
dontSeekWithinBlock = true
|
|
}
|
|
}
|
|
if !dontSeekWithinBlock {
|
|
if ikey, val := i.data.SeekLT(key, flags); ikey != nil {
|
|
if i.blockLower != nil && i.cmp(ikey.UserKey, i.blockLower) < 0 {
|
|
i.exhaustedBounds = -1
|
|
return nil, base.LazyValue{}
|
|
}
|
|
return ikey, val
|
|
}
|
|
}
|
|
// The index contains separator keys which may lie between
|
|
// user-keys. Consider the user-keys:
|
|
//
|
|
// complete
|
|
// ---- new block ---
|
|
// complexion
|
|
//
|
|
// If these two keys end one block and start the next, the index key may
|
|
// be chosen as "compleu". The SeekGE in the index block will then point
|
|
// us to the block containing "complexion". If this happens, we want the
|
|
// last key from the previous data block.
|
|
return i.maybeVerifyKey(i.skipBackward())
|
|
}
|
|
|
|
// First implements internalIterator.First, as documented in the pebble
|
|
// package. Note that First only checks the upper bound. It is up to the caller
|
|
// to ensure that key is greater than or equal to the lower bound (e.g. via a
|
|
// call to SeekGE(lower)).
|
|
func (i *singleLevelIterator) First() (*InternalKey, base.LazyValue) {
|
|
// If the iterator was created on a virtual sstable, we will SeekGE to the
|
|
// lower bound instead of using First, because First does not respect
|
|
// bounds.
|
|
if i.vState != nil {
|
|
return i.SeekGE(i.lower, base.SeekGEFlagsNone)
|
|
}
|
|
|
|
if i.lower != nil {
|
|
panic("singleLevelIterator.First() used despite lower bound")
|
|
}
|
|
i.positionedUsingLatestBounds = true
|
|
i.maybeFilteredKeysSingleLevel = false
|
|
|
|
return i.firstInternal()
|
|
}
|
|
|
|
// firstInternal is a helper used for absolute positioning in a single-level
|
|
// index file, or for positioning in the second-level index in a two-level
|
|
// index file. For the latter, one cannot make any claims about absolute
|
|
// positioning.
|
|
func (i *singleLevelIterator) firstInternal() (*InternalKey, base.LazyValue) {
|
|
i.exhaustedBounds = 0
|
|
i.err = nil // clear cached iteration error
|
|
// Seek optimization only applies until iterator is first positioned after SetBounds.
|
|
i.boundsCmp = 0
|
|
|
|
var ikey *InternalKey
|
|
if ikey, _ = i.index.First(); ikey == nil {
|
|
i.data.invalidate()
|
|
return nil, base.LazyValue{}
|
|
}
|
|
result := i.loadBlock(+1)
|
|
if result == loadBlockFailed {
|
|
return nil, base.LazyValue{}
|
|
}
|
|
if result == loadBlockOK {
|
|
if ikey, val := i.data.First(); ikey != nil {
|
|
if i.blockUpper != nil {
|
|
cmp := i.cmp(ikey.UserKey, i.blockUpper)
|
|
if (!i.endKeyInclusive && cmp >= 0) || cmp > 0 {
|
|
i.exhaustedBounds = +1
|
|
return nil, base.LazyValue{}
|
|
}
|
|
}
|
|
return ikey, val
|
|
}
|
|
// Else fall through to skipForward.
|
|
} else {
|
|
// result == loadBlockIrrelevant. Enforce the upper bound here since
|
|
// don't want to bother moving to the next block if upper bound is
|
|
// already exceeded. Note that the next block starts with keys >=
|
|
// ikey.UserKey since even though this is the block separator, the
|
|
// same user key can span multiple blocks. If upper is exclusive we
|
|
// use >= below, else we use >.
|
|
if i.upper != nil {
|
|
cmp := i.cmp(ikey.UserKey, i.upper)
|
|
if (!i.endKeyInclusive && cmp >= 0) || cmp > 0 {
|
|
i.exhaustedBounds = +1
|
|
return nil, base.LazyValue{}
|
|
}
|
|
}
|
|
// Else fall through to skipForward.
|
|
}
|
|
|
|
return i.skipForward()
|
|
}
|
|
|
|
// Last implements internalIterator.Last, as documented in the pebble
|
|
// package. Note that Last only checks the lower bound. It is up to the caller
|
|
// to ensure that key is less than the upper bound (e.g. via a call to
|
|
// SeekLT(upper))
|
|
func (i *singleLevelIterator) Last() (*InternalKey, base.LazyValue) {
|
|
if i.vState != nil {
|
|
return i.virtualLast()
|
|
}
|
|
|
|
if i.upper != nil {
|
|
panic("singleLevelIterator.Last() used despite upper bound")
|
|
}
|
|
i.positionedUsingLatestBounds = true
|
|
i.maybeFilteredKeysSingleLevel = false
|
|
return i.lastInternal()
|
|
}
|
|
|
|
// lastInternal is a helper used for absolute positioning in a single-level
|
|
// index file, or for positioning in the second-level index in a two-level
|
|
// index file. For the latter, one cannot make any claims about absolute
|
|
// positioning.
|
|
func (i *singleLevelIterator) lastInternal() (*InternalKey, base.LazyValue) {
|
|
i.exhaustedBounds = 0
|
|
i.err = nil // clear cached iteration error
|
|
// Seek optimization only applies until iterator is first positioned after SetBounds.
|
|
i.boundsCmp = 0
|
|
|
|
var ikey *InternalKey
|
|
if ikey, _ = i.index.Last(); ikey == nil {
|
|
i.data.invalidate()
|
|
return nil, base.LazyValue{}
|
|
}
|
|
result := i.loadBlock(-1)
|
|
if result == loadBlockFailed {
|
|
return nil, base.LazyValue{}
|
|
}
|
|
if result == loadBlockOK {
|
|
if ikey, val := i.data.Last(); ikey != nil {
|
|
if i.blockLower != nil && i.cmp(ikey.UserKey, i.blockLower) < 0 {
|
|
i.exhaustedBounds = -1
|
|
return nil, base.LazyValue{}
|
|
}
|
|
return ikey, val
|
|
}
|
|
// Else fall through to skipBackward.
|
|
} else {
|
|
// result == loadBlockIrrelevant. Enforce the lower bound here since
|
|
// don't want to bother moving to the previous block if lower bound is
|
|
// already exceeded. Note that the previous block starts with keys <=
|
|
// key.UserKey since even though this is the current block's
|
|
// separator, the same user key can span multiple blocks.
|
|
if i.lower != nil && i.cmp(ikey.UserKey, i.lower) < 0 {
|
|
i.exhaustedBounds = -1
|
|
return nil, base.LazyValue{}
|
|
}
|
|
}
|
|
|
|
return i.skipBackward()
|
|
}
|
|
|
|
// Next implements internalIterator.Next, as documented in the pebble
|
|
// package.
|
|
// Note: compactionIterator.Next mirrors the implementation of Iterator.Next
|
|
// due to performance. Keep the two in sync.
|
|
func (i *singleLevelIterator) Next() (*InternalKey, base.LazyValue) {
|
|
if i.exhaustedBounds == +1 {
|
|
panic("Next called even though exhausted upper bound")
|
|
}
|
|
i.exhaustedBounds = 0
|
|
i.maybeFilteredKeysSingleLevel = false
|
|
// Seek optimization only applies until iterator is first positioned after SetBounds.
|
|
i.boundsCmp = 0
|
|
|
|
if i.err != nil {
|
|
// TODO(jackson): Can this case be turned into a panic? Once an error is
|
|
// encountered, the iterator must be re-seeked.
|
|
return nil, base.LazyValue{}
|
|
}
|
|
if key, val := i.data.Next(); key != nil {
|
|
if i.blockUpper != nil {
|
|
cmp := i.cmp(key.UserKey, i.blockUpper)
|
|
if (!i.endKeyInclusive && cmp >= 0) || cmp > 0 {
|
|
i.exhaustedBounds = +1
|
|
return nil, base.LazyValue{}
|
|
}
|
|
}
|
|
return key, val
|
|
}
|
|
return i.skipForward()
|
|
}
|
|
|
|
// NextPrefix implements (base.InternalIterator).NextPrefix.
|
|
func (i *singleLevelIterator) NextPrefix(succKey []byte) (*InternalKey, base.LazyValue) {
|
|
if i.exhaustedBounds == +1 {
|
|
panic("NextPrefix called even though exhausted upper bound")
|
|
}
|
|
i.exhaustedBounds = 0
|
|
i.maybeFilteredKeysSingleLevel = false
|
|
// Seek optimization only applies until iterator is first positioned after SetBounds.
|
|
i.boundsCmp = 0
|
|
if i.err != nil {
|
|
// TODO(jackson): Can this case be turned into a panic? Once an error is
|
|
// encountered, the iterator must be re-seeked.
|
|
return nil, base.LazyValue{}
|
|
}
|
|
if key, val := i.data.NextPrefix(succKey); key != nil {
|
|
if i.blockUpper != nil {
|
|
cmp := i.cmp(key.UserKey, i.blockUpper)
|
|
if (!i.endKeyInclusive && cmp >= 0) || cmp > 0 {
|
|
i.exhaustedBounds = +1
|
|
return nil, base.LazyValue{}
|
|
}
|
|
}
|
|
return key, val
|
|
}
|
|
// Did not find prefix in the existing data block. This is the slow-path
|
|
// where we effectively seek the iterator.
|
|
var ikey *InternalKey
|
|
// The key is likely to be in the next data block, so try one step.
|
|
if ikey, _ = i.index.Next(); ikey == nil {
|
|
// The target key is greater than any key in the index block.
|
|
// Invalidate the block iterator so that a subsequent call to Prev()
|
|
// will return the last key in the table.
|
|
i.data.invalidate()
|
|
return nil, base.LazyValue{}
|
|
}
|
|
if i.cmp(succKey, ikey.UserKey) > 0 {
|
|
// Not in the next data block, so seek the index.
|
|
if ikey, _ = i.index.SeekGE(succKey, base.SeekGEFlagsNone); ikey == nil {
|
|
// The target key is greater than any key in the index block.
|
|
// Invalidate the block iterator so that a subsequent call to Prev()
|
|
// will return the last key in the table.
|
|
i.data.invalidate()
|
|
return nil, base.LazyValue{}
|
|
}
|
|
}
|
|
result := i.loadBlock(+1)
|
|
if result == loadBlockFailed {
|
|
return nil, base.LazyValue{}
|
|
}
|
|
if result == loadBlockIrrelevant {
|
|
// Enforce the upper bound here since don't want to bother moving
|
|
// to the next block if upper bound is already exceeded. Note that
|
|
// the next block starts with keys >= ikey.UserKey since even
|
|
// though this is the block separator, the same user key can span
|
|
// multiple blocks. If upper is exclusive we use >= below, else we use
|
|
// >.
|
|
if i.upper != nil {
|
|
cmp := i.cmp(ikey.UserKey, i.upper)
|
|
if (!i.endKeyInclusive && cmp >= 0) || cmp > 0 {
|
|
i.exhaustedBounds = +1
|
|
return nil, base.LazyValue{}
|
|
}
|
|
}
|
|
} else if key, val := i.data.SeekGE(succKey, base.SeekGEFlagsNone); key != nil {
|
|
if i.blockUpper != nil {
|
|
cmp := i.cmp(key.UserKey, i.blockUpper)
|
|
if (!i.endKeyInclusive && cmp >= 0) || cmp > 0 {
|
|
i.exhaustedBounds = +1
|
|
return nil, base.LazyValue{}
|
|
}
|
|
}
|
|
return i.maybeVerifyKey(key, val)
|
|
}
|
|
|
|
return i.skipForward()
|
|
}
|
|
|
|
// Prev implements internalIterator.Prev, as documented in the pebble
|
|
// package.
|
|
func (i *singleLevelIterator) Prev() (*InternalKey, base.LazyValue) {
|
|
if i.exhaustedBounds == -1 {
|
|
panic("Prev called even though exhausted lower bound")
|
|
}
|
|
i.exhaustedBounds = 0
|
|
i.maybeFilteredKeysSingleLevel = false
|
|
// Seek optimization only applies until iterator is first positioned after SetBounds.
|
|
i.boundsCmp = 0
|
|
|
|
if i.err != nil {
|
|
return nil, base.LazyValue{}
|
|
}
|
|
if key, val := i.data.Prev(); key != nil {
|
|
if i.blockLower != nil && i.cmp(key.UserKey, i.blockLower) < 0 {
|
|
i.exhaustedBounds = -1
|
|
return nil, base.LazyValue{}
|
|
}
|
|
return key, val
|
|
}
|
|
return i.skipBackward()
|
|
}
|
|
|
|
func (i *singleLevelIterator) skipForward() (*InternalKey, base.LazyValue) {
|
|
for {
|
|
var key *InternalKey
|
|
if key, _ = i.index.Next(); key == nil {
|
|
i.data.invalidate()
|
|
break
|
|
}
|
|
result := i.loadBlock(+1)
|
|
if result != loadBlockOK {
|
|
if i.err != nil {
|
|
break
|
|
}
|
|
if result == loadBlockFailed {
|
|
// We checked that i.index was at a valid entry, so
|
|
// loadBlockFailed could not have happened due to to i.index
|
|
// being exhausted, and must be due to an error.
|
|
panic("loadBlock should not have failed with no error")
|
|
}
|
|
// result == loadBlockIrrelevant. Enforce the upper bound here
|
|
// since don't want to bother moving to the next block if upper
|
|
// bound is already exceeded. Note that the next block starts with
|
|
// keys >= key.UserKey since even though this is the block
|
|
// separator, the same user key can span multiple blocks. If upper
|
|
// is exclusive we use >= below, else we use >.
|
|
if i.upper != nil {
|
|
cmp := i.cmp(key.UserKey, i.upper)
|
|
if (!i.endKeyInclusive && cmp >= 0) || cmp > 0 {
|
|
i.exhaustedBounds = +1
|
|
return nil, base.LazyValue{}
|
|
}
|
|
}
|
|
continue
|
|
}
|
|
if key, val := i.data.First(); key != nil {
|
|
if i.blockUpper != nil {
|
|
cmp := i.cmp(key.UserKey, i.blockUpper)
|
|
if (!i.endKeyInclusive && cmp >= 0) || cmp > 0 {
|
|
i.exhaustedBounds = +1
|
|
return nil, base.LazyValue{}
|
|
}
|
|
}
|
|
return i.maybeVerifyKey(key, val)
|
|
}
|
|
}
|
|
return nil, base.LazyValue{}
|
|
}
|
|
|
|
func (i *singleLevelIterator) skipBackward() (*InternalKey, base.LazyValue) {
|
|
for {
|
|
var key *InternalKey
|
|
if key, _ = i.index.Prev(); key == nil {
|
|
i.data.invalidate()
|
|
break
|
|
}
|
|
result := i.loadBlock(-1)
|
|
if result != loadBlockOK {
|
|
if i.err != nil {
|
|
break
|
|
}
|
|
if result == loadBlockFailed {
|
|
// We checked that i.index was at a valid entry, so
|
|
// loadBlockFailed could not have happened due to to i.index
|
|
// being exhausted, and must be due to an error.
|
|
panic("loadBlock should not have failed with no error")
|
|
}
|
|
// result == loadBlockIrrelevant. Enforce the lower bound here
|
|
// since don't want to bother moving to the previous block if lower
|
|
// bound is already exceeded. Note that the previous block starts with
|
|
// keys <= key.UserKey since even though this is the current block's
|
|
// separator, the same user key can span multiple blocks.
|
|
if i.lower != nil && i.cmp(key.UserKey, i.lower) < 0 {
|
|
i.exhaustedBounds = -1
|
|
return nil, base.LazyValue{}
|
|
}
|
|
continue
|
|
}
|
|
key, val := i.data.Last()
|
|
if key == nil {
|
|
return nil, base.LazyValue{}
|
|
}
|
|
if i.blockLower != nil && i.cmp(key.UserKey, i.blockLower) < 0 {
|
|
i.exhaustedBounds = -1
|
|
return nil, base.LazyValue{}
|
|
}
|
|
return i.maybeVerifyKey(key, val)
|
|
}
|
|
return nil, base.LazyValue{}
|
|
}
|
|
|
|
// Error implements internalIterator.Error, as documented in the pebble
|
|
// package.
|
|
func (i *singleLevelIterator) Error() error {
|
|
if err := i.data.Error(); err != nil {
|
|
return err
|
|
}
|
|
return i.err
|
|
}
|
|
|
|
// MaybeFilteredKeys may be called when an iterator is exhausted to indicate
|
|
// whether or not the last positioning method may have skipped any keys due to
|
|
// block-property filters.
|
|
func (i *singleLevelIterator) MaybeFilteredKeys() bool {
|
|
return i.maybeFilteredKeysSingleLevel
|
|
}
|
|
|
|
// SetCloseHook sets a function that will be called when the iterator is
|
|
// closed.
|
|
func (i *singleLevelIterator) SetCloseHook(fn func(i Iterator) error) {
|
|
i.closeHook = fn
|
|
}
|
|
|
|
func firstError(err0, err1 error) error {
|
|
if err0 != nil {
|
|
return err0
|
|
}
|
|
return err1
|
|
}
|
|
|
|
// Close implements internalIterator.Close, as documented in the pebble
|
|
// package.
|
|
func (i *singleLevelIterator) Close() error {
|
|
i.iterStats.close()
|
|
var err error
|
|
if i.closeHook != nil {
|
|
err = firstError(err, i.closeHook(i))
|
|
}
|
|
err = firstError(err, i.data.Close())
|
|
err = firstError(err, i.index.Close())
|
|
if i.dataRH != nil {
|
|
err = firstError(err, i.dataRH.Close())
|
|
i.dataRH = nil
|
|
}
|
|
err = firstError(err, i.err)
|
|
if i.bpfs != nil {
|
|
releaseBlockPropertiesFilterer(i.bpfs)
|
|
}
|
|
if i.vbReader != nil {
|
|
i.vbReader.close()
|
|
}
|
|
if i.vbRH != nil {
|
|
err = firstError(err, i.vbRH.Close())
|
|
i.vbRH = nil
|
|
}
|
|
*i = i.resetForReuse()
|
|
singleLevelIterPool.Put(i)
|
|
return err
|
|
}
|
|
|
|
func (i *singleLevelIterator) String() string {
|
|
if i.vState != nil {
|
|
return i.vState.fileNum.String()
|
|
}
|
|
return i.reader.fileNum.String()
|
|
}
|