mirror of
https://source.quilibrium.com/quilibrium/ceremonyclient.git
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1253 lines
51 KiB
Go
1253 lines
51 KiB
Go
// Copyright 2018 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 pebble
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import (
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"context"
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"fmt"
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"runtime/debug"
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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/internal/keyspan"
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"github.com/cockroachdb/pebble/internal/manifest"
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"github.com/cockroachdb/pebble/sstable"
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)
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// tableNewIters creates a new point and range-del iterator for the given file
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// number.
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//
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// On success, the internalIterator is not-nil and must be closed; the
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// FragmentIterator can be nil.
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// TODO(radu): always return a non-nil FragmentIterator.
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//
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// On error, the iterators are nil.
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//
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// The only (non-test) implementation of tableNewIters is tableCacheContainer.newIters().
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type tableNewIters func(
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ctx context.Context,
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file *manifest.FileMetadata,
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opts *IterOptions,
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internalOpts internalIterOpts,
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) (internalIterator, keyspan.FragmentIterator, error)
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// tableNewRangeDelIter takes a tableNewIters and returns a TableNewSpanIter
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// for the rangedel iterator returned by tableNewIters.
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func tableNewRangeDelIter(ctx context.Context, newIters tableNewIters) keyspan.TableNewSpanIter {
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return func(file *manifest.FileMetadata, iterOptions keyspan.SpanIterOptions) (keyspan.FragmentIterator, error) {
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iter, rangeDelIter, err := newIters(ctx, file, nil, internalIterOpts{})
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if iter != nil {
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_ = iter.Close()
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}
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if rangeDelIter == nil {
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rangeDelIter = emptyKeyspanIter
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}
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return rangeDelIter, err
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}
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}
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type internalIterOpts struct {
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bytesIterated *uint64
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bufferPool *sstable.BufferPool
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stats *base.InternalIteratorStats
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boundLimitedFilter sstable.BoundLimitedBlockPropertyFilter
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}
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// levelIter provides a merged view of the sstables in a level.
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//
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// levelIter is used during compaction and as part of the Iterator
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// implementation. When used as part of the Iterator implementation, level
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// iteration needs to "pause" at sstable boundaries if a range deletion
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// tombstone is the source of that boundary. We know if a range tombstone is
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// the smallest or largest key in a file because the kind will be
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// InternalKeyKindRangeDeletion. If the boundary key is a range deletion
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// tombstone, we materialize a fake entry to return from levelIter. This
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// prevents mergingIter from advancing past the sstable until the sstable
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// contains the smallest (or largest for reverse iteration) key in the merged
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// heap. Note that mergingIter treats a range deletion tombstone returned by
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// the point iterator as a no-op.
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//
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// SeekPrefixGE presents the need for a second type of pausing. If an sstable
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// iterator returns "not found" for a SeekPrefixGE operation, we don't want to
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// advance to the next sstable as the "not found" does not indicate that all of
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// the keys in the sstable are less than the search key. Advancing to the next
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// sstable would cause us to skip over range tombstones, violating
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// correctness. Instead, SeekPrefixGE creates a synthetic boundary key with the
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// kind InternalKeyKindRangeDeletion which will be used to pause the levelIter
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// at the sstable until the mergingIter is ready to advance past it.
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type levelIter struct {
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// The context is stored here since (a) iterators are expected to be
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// short-lived (since they pin sstables), (b) plumbing a context into every
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// method is very painful, (c) they do not (yet) respect context
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// cancellation and are only used for tracing.
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ctx context.Context
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logger Logger
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comparer *Comparer
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cmp Compare
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split Split
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// The lower/upper bounds for iteration as specified at creation or the most
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// recent call to SetBounds.
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lower []byte
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upper []byte
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// The iterator options for the currently open table. If
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// tableOpts.{Lower,Upper}Bound are nil, the corresponding iteration boundary
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// does not lie within the table bounds.
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tableOpts IterOptions
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// The LSM level this levelIter is initialized for.
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level manifest.Level
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// The keys to return when iterating past an sstable boundary and that
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// boundary is a range deletion tombstone. The boundary could be smallest
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// (i.e. arrived at with Prev), or largest (arrived at with Next).
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smallestBoundary *InternalKey
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largestBoundary *InternalKey
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// combinedIterState may be set when a levelIter is used during user
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// iteration. Although levelIter only iterates over point keys, it's also
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// responsible for lazily constructing the combined range & point iterator
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// when it observes a file containing range keys. If the combined iter
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// state's initialized field is true, the iterator is already using combined
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// iterator, OR the iterator is not configured to use combined iteration. If
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// it's false, the levelIter must set the `triggered` and `key` fields when
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// the levelIter passes over a file containing range keys. See the
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// lazyCombinedIter for more details.
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combinedIterState *combinedIterState
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// A synthetic boundary key to return when SeekPrefixGE finds an sstable
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// which doesn't contain the search key, but which does contain range
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// tombstones.
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syntheticBoundary InternalKey
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// The iter for the current file. It is nil under any of the following conditions:
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// - files.Current() == nil
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// - err != nil
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// - some other constraint, like the bounds in opts, caused the file at index to not
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// be relevant to the iteration.
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iter internalIterator
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// iterFile holds the current file. It is always equal to l.files.Current().
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iterFile *fileMetadata
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// filteredIter is an optional interface that may be implemented by internal
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// iterators that perform filtering of keys. When a new file's iterator is
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// opened, it's tested to see if it implements filteredIter. If it does,
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// it's stored here to allow the level iterator to recognize when keys were
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// omitted from iteration results due to filtering. This is important when a
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// file contains range deletions that may delete keys from other files. The
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// levelIter must not advance to the next file until the mergingIter has
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// advanced beyond the file's bounds. See
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// levelIterBoundaryContext.isIgnorableBoundaryKey.
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filteredIter filteredIter
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newIters tableNewIters
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// When rangeDelIterPtr != nil, the caller requires that *rangeDelIterPtr must
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// point to a range del iterator corresponding to the current file. When this
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// iterator returns nil, *rangeDelIterPtr should also be set to nil. Whenever
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// a non-nil internalIterator is placed in rangeDelIterPtr, a copy is placed
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// in rangeDelIterCopy. This is done for the following special case:
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// when this iterator returns nil because of exceeding the bounds, we don't
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// close iter and *rangeDelIterPtr since we could reuse it in the next seek. But
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// we need to set *rangeDelIterPtr to nil because of the aforementioned contract.
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// This copy is used to revive the *rangeDelIterPtr in the case of reuse.
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rangeDelIterPtr *keyspan.FragmentIterator
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rangeDelIterCopy keyspan.FragmentIterator
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files manifest.LevelIterator
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err error
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// Pointer into this level's entry in `mergingIterLevel::levelIterBoundaryContext`.
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// We populate it with the corresponding bounds for the currently opened file. It is used for
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// two purposes (described for forward iteration. The explanation for backward iteration is
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// similar.)
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// - To limit the optimization that seeks lower-level iterators past keys shadowed by a range
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// tombstone. Limiting this seek to the file largestUserKey is necessary since
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// range tombstones are stored untruncated, while they only apply to keys within their
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// containing file's boundaries. For a detailed example, see comment above `mergingIter`.
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// - To constrain the tombstone to act-within the bounds of the sstable when checking
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// containment. For forward iteration we need the smallestUserKey.
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//
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// An example is sstable bounds [c#8, g#12] containing a tombstone [b, i)#7.
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// - When doing a SeekGE to user key X, the levelIter is at this sstable because X is either within
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// the sstable bounds or earlier than the start of the sstable (and there is no sstable in
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// between at this level). If X >= smallestUserKey, and the tombstone [b, i) contains X,
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// it is correct to SeekGE the sstables at lower levels to min(g, i) (i.e., min of
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// largestUserKey, tombstone.End) since any user key preceding min(g, i) must be covered by this
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// tombstone (since it cannot have a version younger than this tombstone as it is at a lower
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// level). And even if X = smallestUserKey or equal to the start user key of the tombstone,
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// if the above conditions are satisfied we know that the internal keys corresponding to X at
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// lower levels must have a version smaller than that in this file (again because of the level
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// argument). So we don't need to use sequence numbers for this comparison.
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// - When checking whether this tombstone deletes internal key X we know that the levelIter is at this
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// sstable so (repeating the above) X.UserKey is either within the sstable bounds or earlier than the
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// start of the sstable (and there is no sstable in between at this level).
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// - X is at at a lower level. If X.UserKey >= smallestUserKey, and the tombstone contains
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// X.UserKey, we know X is deleted. This argument also works when X is a user key (we use
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// it when seeking to test whether a user key is deleted).
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// - X is at the same level. X must be within the sstable bounds of the tombstone so the
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// X.UserKey >= smallestUserKey comparison is trivially true. In addition to the tombstone containing
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// X we need to compare the sequence number of X and the tombstone (we don't need to look
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// at how this tombstone is truncated to act-within the file bounds, which are InternalKeys,
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// since X and the tombstone are from the same file).
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//
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// Iterating backwards has one more complication when checking whether a tombstone deletes
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// internal key X at a lower level (the construction we do here also works for a user key X).
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// Consider sstable bounds [c#8, g#InternalRangeDelSentinel] containing a tombstone [b, i)#7.
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// If we are positioned at key g#10 at a lower sstable, the tombstone we will see is [b, i)#7,
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// since the higher sstable is positioned at a key <= g#10. We should not use this tombstone
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// to delete g#10. This requires knowing that the largestUserKey is a range delete sentinel,
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// which we set in a separate bool below.
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//
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// These fields differs from the `*Boundary` fields in a few ways:
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// - `*Boundary` is only populated when the iterator is positioned exactly on the sentinel key.
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// - `*Boundary` can hold either the lower- or upper-bound, depending on the iterator direction.
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// - `*Boundary` is not exposed to the next higher-level iterator, i.e., `mergingIter`.
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boundaryContext *levelIterBoundaryContext
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// internalOpts holds the internal iterator options to pass to the table
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// cache when constructing new table iterators.
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internalOpts internalIterOpts
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// Scratch space for the obsolete keys filter, when there are no other block
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// property filters specified. See the performance note where
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// IterOptions.PointKeyFilters is declared.
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filtersBuf [1]BlockPropertyFilter
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// Disable invariant checks even if they are otherwise enabled. Used by tests
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// which construct "impossible" situations (e.g. seeking to a key before the
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// lower bound).
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disableInvariants bool
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}
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// filteredIter is an additional interface implemented by iterators that may
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// skip over point keys during iteration. The sstable.Iterator implements this
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// interface.
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type filteredIter interface {
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// MaybeFilteredKeys may be called when an iterator is exhausted, indicating
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// whether or not the iterator's last positioning method may have skipped
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// any keys due to low-level filters.
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//
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// When an iterator is configured to use block-property filters, the
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// low-level iterator may skip over blocks or whole sstables of keys.
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// Implementations that implement skipping must implement this interface.
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// Higher-level iterators require it to preserve invariants (eg, a levelIter
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// used in a mergingIter must keep the file's range-del iterator open until
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// the mergingIter has moved past the file's bounds, even if all of the
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// file's point keys were filtered).
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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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}
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// levelIter implements the base.InternalIterator interface.
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var _ base.InternalIterator = (*levelIter)(nil)
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// newLevelIter returns a levelIter. It is permissible to pass a nil split
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// parameter if the caller is never going to call SeekPrefixGE.
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func newLevelIter(
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ctx context.Context,
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opts IterOptions,
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comparer *Comparer,
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newIters tableNewIters,
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files manifest.LevelIterator,
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level manifest.Level,
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internalOpts internalIterOpts,
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) *levelIter {
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l := &levelIter{}
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l.init(ctx, opts, comparer, newIters, files, level, internalOpts)
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return l
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}
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func (l *levelIter) init(
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ctx context.Context,
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opts IterOptions,
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comparer *Comparer,
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newIters tableNewIters,
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files manifest.LevelIterator,
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level manifest.Level,
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internalOpts internalIterOpts,
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) {
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l.ctx = ctx
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l.err = nil
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l.level = level
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l.logger = opts.getLogger()
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l.lower = opts.LowerBound
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l.upper = opts.UpperBound
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l.tableOpts.TableFilter = opts.TableFilter
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l.tableOpts.PointKeyFilters = opts.PointKeyFilters
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if len(opts.PointKeyFilters) == 0 {
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l.tableOpts.PointKeyFilters = l.filtersBuf[:0:1]
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}
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l.tableOpts.UseL6Filters = opts.UseL6Filters
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l.tableOpts.CategoryAndQoS = opts.CategoryAndQoS
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l.tableOpts.level = l.level
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l.tableOpts.snapshotForHideObsoletePoints = opts.snapshotForHideObsoletePoints
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l.comparer = comparer
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l.cmp = comparer.Compare
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l.split = comparer.Split
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l.iterFile = nil
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l.newIters = newIters
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l.files = files
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l.internalOpts = internalOpts
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}
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func (l *levelIter) initRangeDel(rangeDelIter *keyspan.FragmentIterator) {
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l.rangeDelIterPtr = rangeDelIter
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}
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func (l *levelIter) initBoundaryContext(context *levelIterBoundaryContext) {
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l.boundaryContext = context
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}
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func (l *levelIter) initCombinedIterState(state *combinedIterState) {
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l.combinedIterState = state
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}
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func (l *levelIter) maybeTriggerCombinedIteration(file *fileMetadata, dir int) {
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// If we encounter a file that contains range keys, we may need to
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// trigger a switch to combined range-key and point-key iteration,
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// if the *pebble.Iterator is configured for it. This switch is done
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// lazily because range keys are intended to be rare, and
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// constructing the range-key iterator substantially adds to the
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// cost of iterator construction and seeking.
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//
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// If l.combinedIterState.initialized is already true, either the
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// iterator is already using combined iteration or the iterator is not
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// configured to observe range keys. Either way, there's nothing to do.
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// If false, trigger the switch to combined iteration, using the the
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// file's bounds to seek the range-key iterator appropriately.
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//
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// We only need to trigger combined iteration if the file contains
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// RangeKeySets: if there are only Unsets and Dels, the user will observe no
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// range keys regardless. If this file has table stats available, they'll
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// tell us whether the file has any RangeKeySets. Otherwise, we must
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// fallback to assuming it does if HasRangeKeys=true.
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if file != nil && file.HasRangeKeys && l.combinedIterState != nil && !l.combinedIterState.initialized &&
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(l.upper == nil || l.cmp(file.SmallestRangeKey.UserKey, l.upper) < 0) &&
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(l.lower == nil || l.cmp(file.LargestRangeKey.UserKey, l.lower) > 0) &&
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(!file.StatsValid() || file.Stats.NumRangeKeySets > 0) {
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// The file contains range keys, and we're not using combined iteration yet.
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// Trigger a switch to combined iteration. It's possible that a switch has
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// already been triggered if multiple levels encounter files containing
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// range keys while executing a single mergingIter operation. In this case,
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// we need to compare the existing key recorded to l.combinedIterState.key,
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// adjusting it if our key is smaller (forward iteration) or larger
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// (backward iteration) than the existing key.
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//
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// These key comparisons are only required during a single high-level
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// iterator operation. When the high-level iter op completes,
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// iinitialized will be true, and future calls to this function will be
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// no-ops.
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switch dir {
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case +1:
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if !l.combinedIterState.triggered {
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l.combinedIterState.triggered = true
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l.combinedIterState.key = file.SmallestRangeKey.UserKey
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} else if l.cmp(l.combinedIterState.key, file.SmallestRangeKey.UserKey) > 0 {
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l.combinedIterState.key = file.SmallestRangeKey.UserKey
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}
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case -1:
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if !l.combinedIterState.triggered {
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l.combinedIterState.triggered = true
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l.combinedIterState.key = file.LargestRangeKey.UserKey
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} else if l.cmp(l.combinedIterState.key, file.LargestRangeKey.UserKey) < 0 {
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l.combinedIterState.key = file.LargestRangeKey.UserKey
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}
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}
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}
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}
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func (l *levelIter) findFileGE(key []byte, flags base.SeekGEFlags) *fileMetadata {
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// Find the earliest file whose largest key is >= key.
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// NB: if flags.TrySeekUsingNext()=true, the levelIter must respect it. If
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// the levelIter is positioned at the key P, it must return a key ≥ P. If
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// used within a merging iterator, the merging iterator will depend on the
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// levelIter only moving forward to maintain heap invariants.
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// Ordinarily we seek the LevelIterator using SeekGE. In some instances, we
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// Next instead. In other instances, we try Next-ing first, falling back to
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// seek:
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// a) flags.TrySeekUsingNext(): The top-level Iterator knows we're seeking
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// to a key later than the current iterator position. We don't know how
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// much later the seek key is, so it's possible there are many sstables
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// between the current position and the seek key. However in most real-
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// world use cases, the seek key is likely to be nearby. Rather than
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// performing a log(N) seek through the file metadata, we next a few
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// times from from our existing location. If we don't find a file whose
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// largest is >= key within a few nexts, we fall back to seeking.
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//
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// Note that in this case, the file returned by findFileGE may be
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// different than the file returned by a raw binary search (eg, when
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// TrySeekUsingNext=false). This is possible because the most recent
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// positioning operation may have already determined that previous
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// files' keys that are ≥ key are all deleted. This information is
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// encoded within the iterator's current iterator position and is
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// unavailable to a fresh binary search.
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//
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// b) flags.RelativeSeek(): The merging iterator decided to re-seek this
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// level according to a range tombstone. When lazy combined iteration
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// is enabled, the level iterator is responsible for watching for
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// files containing range keys and triggering the switch to combined
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// iteration when such a file is observed. If a range deletion was
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// observed in a higher level causing the merging iterator to seek the
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// level to the range deletion's end key, we need to check whether all
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// of the files between the old position and the new position contain
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// any range keys.
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//
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// In this scenario, we don't seek the LevelIterator and instead we
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// Next it, one file at a time, checking each for range keys. The
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// merging iterator sets this flag to inform us that we're moving
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// forward relative to the existing position and that we must examine
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// each intermediate sstable's metadata for lazy-combined iteration.
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// In this case, we only Next and never Seek. We set nextsUntilSeek=-1
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// to signal this intention.
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//
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// NB: At most one of flags.RelativeSeek() and flags.TrySeekUsingNext() may
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// be set, because the merging iterator re-seeks relative seeks with
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// explicitly only the RelativeSeek flag set.
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var nextsUntilSeek int
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var nextInsteadOfSeek bool
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if flags.TrySeekUsingNext() {
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nextInsteadOfSeek = true
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nextsUntilSeek = 4 // arbitrary
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}
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if flags.RelativeSeek() && l.combinedIterState != nil && !l.combinedIterState.initialized {
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nextInsteadOfSeek = true
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nextsUntilSeek = -1
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}
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var m *fileMetadata
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if nextInsteadOfSeek {
|
|
m = l.iterFile
|
|
} else {
|
|
m = l.files.SeekGE(l.cmp, key)
|
|
}
|
|
// The below loop has a bit of an unusual organization. There are several
|
|
// conditions under which we need to Next to a later file. If none of those
|
|
// conditions are met, the file in `m` is okay to return. The loop body is
|
|
// structured with a series of if statements, each of which may continue the
|
|
// loop to the next file. If none of the statements are met, the end of the
|
|
// loop body is a break.
|
|
for m != nil {
|
|
if m.HasRangeKeys {
|
|
l.maybeTriggerCombinedIteration(m, +1)
|
|
|
|
// Some files may only contain range keys, which we can skip.
|
|
// NB: HasPointKeys=true if the file contains any points or range
|
|
// deletions (which delete points).
|
|
if !m.HasPointKeys {
|
|
m = l.files.Next()
|
|
continue
|
|
}
|
|
}
|
|
|
|
// This file has point keys.
|
|
//
|
|
// However, there are a couple reasons why `m` may not be positioned ≥
|
|
// `key` yet:
|
|
//
|
|
// 1. If SeekGE(key) landed on a file containing range keys, the file
|
|
// may contain range keys ≥ `key` but no point keys ≥ `key`.
|
|
// 2. When nexting instead of seeking, we must check to see whether
|
|
// we've nexted sufficiently far, or we need to next again.
|
|
//
|
|
// If the file does not contain point keys ≥ `key`, next to continue
|
|
// looking for a file that does.
|
|
if (m.HasRangeKeys || nextInsteadOfSeek) && l.cmp(m.LargestPointKey.UserKey, key) < 0 {
|
|
// If nextInsteadOfSeek is set and nextsUntilSeek is non-negative,
|
|
// the iterator has been nexting hoping to discover the relevant
|
|
// file without seeking. It's exhausted the allotted nextsUntilSeek
|
|
// and should seek to the sought key.
|
|
if nextInsteadOfSeek && nextsUntilSeek == 0 {
|
|
nextInsteadOfSeek = false
|
|
m = l.files.SeekGE(l.cmp, key)
|
|
continue
|
|
} else if nextsUntilSeek > 0 {
|
|
nextsUntilSeek--
|
|
}
|
|
m = l.files.Next()
|
|
continue
|
|
}
|
|
|
|
// This file has a point key bound ≥ `key`. But the largest point key
|
|
// bound may still be a range deletion sentinel, which is exclusive. In
|
|
// this case, the file doesn't actually contain any point keys equal to
|
|
// `key`. We next to keep searching for a file that actually contains
|
|
// point keys ≥ key.
|
|
//
|
|
// Additionally, this prevents loading untruncated range deletions from
|
|
// a table which can't possibly contain the target key and is required
|
|
// for correctness by mergingIter.SeekGE (see the comment in that
|
|
// function).
|
|
if m.LargestPointKey.IsExclusiveSentinel() && l.cmp(m.LargestPointKey.UserKey, key) == 0 {
|
|
m = l.files.Next()
|
|
continue
|
|
}
|
|
|
|
// This file contains point keys ≥ `key`. Break and return it.
|
|
break
|
|
}
|
|
return m
|
|
}
|
|
|
|
func (l *levelIter) findFileLT(key []byte, flags base.SeekLTFlags) *fileMetadata {
|
|
// Find the last file whose smallest key is < ikey.
|
|
|
|
// Ordinarily we seek the LevelIterator using SeekLT.
|
|
//
|
|
// When lazy combined iteration is enabled, there's a complication. The
|
|
// level iterator is responsible for watching for files containing range
|
|
// keys and triggering the switch to combined iteration when such a file is
|
|
// observed. If a range deletion was observed in a higher level causing the
|
|
// merging iterator to seek the level to the range deletion's start key, we
|
|
// need to check whether all of the files between the old position and the
|
|
// new position contain any range keys.
|
|
//
|
|
// In this scenario, we don't seek the LevelIterator and instead we Prev it,
|
|
// one file at a time, checking each for range keys.
|
|
prevInsteadOfSeek := flags.RelativeSeek() && l.combinedIterState != nil && !l.combinedIterState.initialized
|
|
|
|
var m *fileMetadata
|
|
if prevInsteadOfSeek {
|
|
m = l.iterFile
|
|
} else {
|
|
m = l.files.SeekLT(l.cmp, key)
|
|
}
|
|
// The below loop has a bit of an unusual organization. There are several
|
|
// conditions under which we need to Prev to a previous file. If none of
|
|
// those conditions are met, the file in `m` is okay to return. The loop
|
|
// body is structured with a series of if statements, each of which may
|
|
// continue the loop to the previous file. If none of the statements are
|
|
// met, the end of the loop body is a break.
|
|
for m != nil {
|
|
if m.HasRangeKeys {
|
|
l.maybeTriggerCombinedIteration(m, -1)
|
|
|
|
// Some files may only contain range keys, which we can skip.
|
|
// NB: HasPointKeys=true if the file contains any points or range
|
|
// deletions (which delete points).
|
|
if !m.HasPointKeys {
|
|
m = l.files.Prev()
|
|
continue
|
|
}
|
|
}
|
|
|
|
// This file has point keys.
|
|
//
|
|
// However, there are a couple reasons why `m` may not be positioned <
|
|
// `key` yet:
|
|
//
|
|
// 1. If SeekLT(key) landed on a file containing range keys, the file
|
|
// may contain range keys < `key` but no point keys < `key`.
|
|
// 2. When preving instead of seeking, we must check to see whether
|
|
// we've preved sufficiently far, or we need to prev again.
|
|
//
|
|
// If the file does not contain point keys < `key`, prev to continue
|
|
// looking for a file that does.
|
|
if (m.HasRangeKeys || prevInsteadOfSeek) && l.cmp(m.SmallestPointKey.UserKey, key) >= 0 {
|
|
m = l.files.Prev()
|
|
continue
|
|
}
|
|
|
|
// This file contains point keys < `key`. Break and return it.
|
|
break
|
|
}
|
|
return m
|
|
}
|
|
|
|
// Init the iteration bounds for the current table. Returns -1 if the table
|
|
// lies fully before the lower bound, +1 if the table lies fully after the
|
|
// upper bound, and 0 if the table overlaps the iteration bounds.
|
|
func (l *levelIter) initTableBounds(f *fileMetadata) int {
|
|
l.tableOpts.LowerBound = l.lower
|
|
if l.tableOpts.LowerBound != nil {
|
|
if l.cmp(f.LargestPointKey.UserKey, l.tableOpts.LowerBound) < 0 {
|
|
// The largest key in the sstable is smaller than the lower bound.
|
|
return -1
|
|
}
|
|
if l.cmp(l.tableOpts.LowerBound, f.SmallestPointKey.UserKey) <= 0 {
|
|
// The lower bound is smaller or equal to the smallest key in the
|
|
// table. Iteration within the table does not need to check the lower
|
|
// bound.
|
|
l.tableOpts.LowerBound = nil
|
|
}
|
|
}
|
|
l.tableOpts.UpperBound = l.upper
|
|
if l.tableOpts.UpperBound != nil {
|
|
if l.cmp(f.SmallestPointKey.UserKey, l.tableOpts.UpperBound) >= 0 {
|
|
// The smallest key in the sstable is greater than or equal to the upper
|
|
// bound.
|
|
return 1
|
|
}
|
|
if l.cmp(l.tableOpts.UpperBound, f.LargestPointKey.UserKey) > 0 {
|
|
// The upper bound is greater than the largest key in the
|
|
// table. Iteration within the table does not need to check the upper
|
|
// bound. NB: tableOpts.UpperBound is exclusive and f.LargestPointKey is
|
|
// inclusive.
|
|
l.tableOpts.UpperBound = nil
|
|
}
|
|
}
|
|
return 0
|
|
}
|
|
|
|
type loadFileReturnIndicator int8
|
|
|
|
const (
|
|
noFileLoaded loadFileReturnIndicator = iota
|
|
fileAlreadyLoaded
|
|
newFileLoaded
|
|
)
|
|
|
|
func (l *levelIter) loadFile(file *fileMetadata, dir int) loadFileReturnIndicator {
|
|
l.smallestBoundary = nil
|
|
l.largestBoundary = nil
|
|
if l.boundaryContext != nil {
|
|
l.boundaryContext.isSyntheticIterBoundsKey = false
|
|
l.boundaryContext.isIgnorableBoundaryKey = false
|
|
}
|
|
if l.iterFile == file {
|
|
if l.err != nil {
|
|
return noFileLoaded
|
|
}
|
|
if l.iter != nil {
|
|
// We don't bother comparing the file bounds with the iteration bounds when we have
|
|
// an already open iterator. It is possible that the iter may not be relevant given the
|
|
// current iteration bounds, but it knows those bounds, so it will enforce them.
|
|
if l.rangeDelIterPtr != nil {
|
|
*l.rangeDelIterPtr = l.rangeDelIterCopy
|
|
}
|
|
|
|
// There are a few reasons we might not have triggered combined
|
|
// iteration yet, even though we already had `file` open.
|
|
// 1. If the bounds changed, we might have previously avoided
|
|
// switching to combined iteration because the bounds excluded
|
|
// the range keys contained in this file.
|
|
// 2. If an existing iterator was reconfigured to iterate over range
|
|
// keys (eg, using SetOptions), then we wouldn't have triggered
|
|
// the switch to combined iteration yet.
|
|
l.maybeTriggerCombinedIteration(file, dir)
|
|
return fileAlreadyLoaded
|
|
}
|
|
// We were already at file, but don't have an iterator, probably because the file was
|
|
// beyond the iteration bounds. It may still be, but it is also possible that the bounds
|
|
// have changed. We handle that below.
|
|
}
|
|
|
|
// Close both iter and rangeDelIterPtr. While mergingIter knows about
|
|
// rangeDelIterPtr, it can't call Close() on it because it does not know
|
|
// when the levelIter will switch it. Note that levelIter.Close() can be
|
|
// called multiple times.
|
|
if err := l.Close(); err != nil {
|
|
return noFileLoaded
|
|
}
|
|
|
|
for {
|
|
l.iterFile = file
|
|
if file == nil {
|
|
return noFileLoaded
|
|
}
|
|
|
|
l.maybeTriggerCombinedIteration(file, dir)
|
|
if !file.HasPointKeys {
|
|
switch dir {
|
|
case +1:
|
|
file = l.files.Next()
|
|
continue
|
|
case -1:
|
|
file = l.files.Prev()
|
|
continue
|
|
}
|
|
}
|
|
|
|
switch l.initTableBounds(file) {
|
|
case -1:
|
|
// The largest key in the sstable is smaller than the lower bound.
|
|
if dir < 0 {
|
|
return noFileLoaded
|
|
}
|
|
file = l.files.Next()
|
|
continue
|
|
case +1:
|
|
// The smallest key in the sstable is greater than or equal to the upper
|
|
// bound.
|
|
if dir > 0 {
|
|
return noFileLoaded
|
|
}
|
|
file = l.files.Prev()
|
|
continue
|
|
}
|
|
|
|
var rangeDelIter keyspan.FragmentIterator
|
|
var iter internalIterator
|
|
iter, rangeDelIter, l.err = l.newIters(l.ctx, l.iterFile, &l.tableOpts, l.internalOpts)
|
|
l.iter = iter
|
|
if l.err != nil {
|
|
return noFileLoaded
|
|
}
|
|
if rangeDelIter != nil {
|
|
if fi, ok := iter.(filteredIter); ok {
|
|
l.filteredIter = fi
|
|
} else {
|
|
l.filteredIter = nil
|
|
}
|
|
} else {
|
|
l.filteredIter = nil
|
|
}
|
|
if l.rangeDelIterPtr != nil {
|
|
*l.rangeDelIterPtr = rangeDelIter
|
|
l.rangeDelIterCopy = rangeDelIter
|
|
} else if rangeDelIter != nil {
|
|
rangeDelIter.Close()
|
|
}
|
|
if l.boundaryContext != nil {
|
|
l.boundaryContext.smallestUserKey = file.Smallest.UserKey
|
|
l.boundaryContext.largestUserKey = file.Largest.UserKey
|
|
l.boundaryContext.isLargestUserKeyExclusive = file.Largest.IsExclusiveSentinel()
|
|
}
|
|
return newFileLoaded
|
|
}
|
|
}
|
|
|
|
// In race builds we verify that the keys returned by levelIter lie within
|
|
// [lower,upper).
|
|
func (l *levelIter) verify(key *InternalKey, val base.LazyValue) (*InternalKey, base.LazyValue) {
|
|
// Note that invariants.Enabled is a compile time constant, which means the
|
|
// block of code will be compiled out of normal builds making this method
|
|
// eligible for inlining. Do not change this to use a variable.
|
|
if invariants.Enabled && !l.disableInvariants && key != nil {
|
|
// We allow returning a boundary key that is outside of the lower/upper
|
|
// bounds as such keys are always range tombstones which will be skipped by
|
|
// the Iterator.
|
|
if l.lower != nil && key != l.smallestBoundary && l.cmp(key.UserKey, l.lower) < 0 {
|
|
l.logger.Fatalf("levelIter %s: lower bound violation: %s < %s\n%s", l.level, key, l.lower, debug.Stack())
|
|
}
|
|
if l.upper != nil && key != l.largestBoundary && l.cmp(key.UserKey, l.upper) > 0 {
|
|
l.logger.Fatalf("levelIter %s: upper bound violation: %s > %s\n%s", l.level, key, l.upper, debug.Stack())
|
|
}
|
|
}
|
|
return key, val
|
|
}
|
|
|
|
func (l *levelIter) SeekGE(key []byte, flags base.SeekGEFlags) (*InternalKey, base.LazyValue) {
|
|
l.err = nil // clear cached iteration error
|
|
if l.boundaryContext != nil {
|
|
l.boundaryContext.isSyntheticIterBoundsKey = false
|
|
l.boundaryContext.isIgnorableBoundaryKey = false
|
|
}
|
|
// NB: the top-level Iterator has already adjusted key based on
|
|
// IterOptions.LowerBound.
|
|
loadFileIndicator := l.loadFile(l.findFileGE(key, flags), +1)
|
|
if loadFileIndicator == noFileLoaded {
|
|
return nil, base.LazyValue{}
|
|
}
|
|
if loadFileIndicator == newFileLoaded {
|
|
// File changed, so l.iter has changed, and that iterator is not
|
|
// positioned appropriately.
|
|
flags = flags.DisableTrySeekUsingNext()
|
|
}
|
|
if ikey, val := l.iter.SeekGE(key, flags); ikey != nil {
|
|
return l.verify(ikey, val)
|
|
}
|
|
return l.verify(l.skipEmptyFileForward())
|
|
}
|
|
|
|
func (l *levelIter) SeekPrefixGE(
|
|
prefix, key []byte, flags base.SeekGEFlags,
|
|
) (*base.InternalKey, base.LazyValue) {
|
|
l.err = nil // clear cached iteration error
|
|
if l.boundaryContext != nil {
|
|
l.boundaryContext.isSyntheticIterBoundsKey = false
|
|
l.boundaryContext.isIgnorableBoundaryKey = false
|
|
}
|
|
|
|
// NB: the top-level Iterator has already adjusted key based on
|
|
// IterOptions.LowerBound.
|
|
loadFileIndicator := l.loadFile(l.findFileGE(key, flags), +1)
|
|
if loadFileIndicator == noFileLoaded {
|
|
return nil, base.LazyValue{}
|
|
}
|
|
if loadFileIndicator == newFileLoaded {
|
|
// File changed, so l.iter has changed, and that iterator is not
|
|
// positioned appropriately.
|
|
flags = flags.DisableTrySeekUsingNext()
|
|
}
|
|
if key, val := l.iter.SeekPrefixGE(prefix, key, flags); key != nil {
|
|
return l.verify(key, val)
|
|
}
|
|
// When SeekPrefixGE returns nil, we have not necessarily reached the end of
|
|
// the sstable. All we know is that a key with prefix does not exist in the
|
|
// current sstable. We do know that the key lies within the bounds of the
|
|
// table as findFileGE found the table where key <= meta.Largest. We return
|
|
// the table's bound with isIgnorableBoundaryKey set.
|
|
if l.rangeDelIterPtr != nil && *l.rangeDelIterPtr != nil {
|
|
if l.tableOpts.UpperBound != nil {
|
|
l.syntheticBoundary.UserKey = l.tableOpts.UpperBound
|
|
l.syntheticBoundary.Trailer = InternalKeyRangeDeleteSentinel
|
|
l.largestBoundary = &l.syntheticBoundary
|
|
if l.boundaryContext != nil {
|
|
l.boundaryContext.isSyntheticIterBoundsKey = true
|
|
l.boundaryContext.isIgnorableBoundaryKey = false
|
|
}
|
|
return l.verify(l.largestBoundary, base.LazyValue{})
|
|
}
|
|
// Return the file's largest bound, ensuring this file stays open until
|
|
// the mergingIter advances beyond the file's bounds. We set
|
|
// isIgnorableBoundaryKey to signal that the actual key returned should
|
|
// be ignored, and does not represent a real key in the database.
|
|
l.largestBoundary = &l.iterFile.LargestPointKey
|
|
if l.boundaryContext != nil {
|
|
l.boundaryContext.isSyntheticIterBoundsKey = false
|
|
l.boundaryContext.isIgnorableBoundaryKey = true
|
|
}
|
|
return l.verify(l.largestBoundary, base.LazyValue{})
|
|
}
|
|
// It is possible that we are here because bloom filter matching failed. In
|
|
// that case it is likely that all keys matching the prefix are wholly
|
|
// within the current file and cannot be in the subsequent file. In that
|
|
// case we don't want to go to the next file, since loading and seeking in
|
|
// there has some cost. Additionally, for sparse key spaces, loading the
|
|
// next file will defeat the optimization for the next SeekPrefixGE that is
|
|
// called with flags.TrySeekUsingNext(), since for sparse key spaces it is
|
|
// likely that the next key will also be contained in the current file.
|
|
var n int
|
|
if l.split != nil {
|
|
// If the split function is specified, calculate the prefix length accordingly.
|
|
n = l.split(l.iterFile.LargestPointKey.UserKey)
|
|
} else {
|
|
// If the split function is not specified, the entire key is used as the
|
|
// prefix. This case can occur when getIter uses SeekPrefixGE.
|
|
n = len(l.iterFile.LargestPointKey.UserKey)
|
|
}
|
|
if l.cmp(prefix, l.iterFile.LargestPointKey.UserKey[:n]) < 0 {
|
|
return nil, base.LazyValue{}
|
|
}
|
|
return l.verify(l.skipEmptyFileForward())
|
|
}
|
|
|
|
func (l *levelIter) SeekLT(key []byte, flags base.SeekLTFlags) (*InternalKey, base.LazyValue) {
|
|
l.err = nil // clear cached iteration error
|
|
if l.boundaryContext != nil {
|
|
l.boundaryContext.isSyntheticIterBoundsKey = false
|
|
l.boundaryContext.isIgnorableBoundaryKey = false
|
|
}
|
|
|
|
// NB: the top-level Iterator has already adjusted key based on
|
|
// IterOptions.UpperBound.
|
|
if l.loadFile(l.findFileLT(key, flags), -1) == noFileLoaded {
|
|
return nil, base.LazyValue{}
|
|
}
|
|
if key, val := l.iter.SeekLT(key, flags); key != nil {
|
|
return l.verify(key, val)
|
|
}
|
|
return l.verify(l.skipEmptyFileBackward())
|
|
}
|
|
|
|
func (l *levelIter) First() (*InternalKey, base.LazyValue) {
|
|
l.err = nil // clear cached iteration error
|
|
if l.boundaryContext != nil {
|
|
l.boundaryContext.isSyntheticIterBoundsKey = false
|
|
l.boundaryContext.isIgnorableBoundaryKey = false
|
|
}
|
|
|
|
// NB: the top-level Iterator will call SeekGE if IterOptions.LowerBound is
|
|
// set.
|
|
if l.loadFile(l.files.First(), +1) == noFileLoaded {
|
|
return nil, base.LazyValue{}
|
|
}
|
|
if key, val := l.iter.First(); key != nil {
|
|
return l.verify(key, val)
|
|
}
|
|
return l.verify(l.skipEmptyFileForward())
|
|
}
|
|
|
|
func (l *levelIter) Last() (*InternalKey, base.LazyValue) {
|
|
l.err = nil // clear cached iteration error
|
|
if l.boundaryContext != nil {
|
|
l.boundaryContext.isSyntheticIterBoundsKey = false
|
|
l.boundaryContext.isIgnorableBoundaryKey = false
|
|
}
|
|
|
|
// NB: the top-level Iterator will call SeekLT if IterOptions.UpperBound is
|
|
// set.
|
|
if l.loadFile(l.files.Last(), -1) == noFileLoaded {
|
|
return nil, base.LazyValue{}
|
|
}
|
|
if key, val := l.iter.Last(); key != nil {
|
|
return l.verify(key, val)
|
|
}
|
|
return l.verify(l.skipEmptyFileBackward())
|
|
}
|
|
|
|
func (l *levelIter) Next() (*InternalKey, base.LazyValue) {
|
|
if l.err != nil || l.iter == nil {
|
|
return nil, base.LazyValue{}
|
|
}
|
|
if l.boundaryContext != nil {
|
|
l.boundaryContext.isSyntheticIterBoundsKey = false
|
|
l.boundaryContext.isIgnorableBoundaryKey = false
|
|
}
|
|
|
|
switch {
|
|
case l.largestBoundary != nil:
|
|
if l.tableOpts.UpperBound != nil {
|
|
// The UpperBound was within this file, so don't load the next
|
|
// file. We leave the largestBoundary unchanged so that subsequent
|
|
// calls to Next() stay at this file. If a Seek/First/Last call is
|
|
// made and this file continues to be relevant, loadFile() will
|
|
// set the largestBoundary to nil.
|
|
if l.rangeDelIterPtr != nil {
|
|
*l.rangeDelIterPtr = nil
|
|
}
|
|
return nil, base.LazyValue{}
|
|
}
|
|
// We're stepping past the boundary key, so now we can load the next file.
|
|
if l.loadFile(l.files.Next(), +1) != noFileLoaded {
|
|
if key, val := l.iter.First(); key != nil {
|
|
return l.verify(key, val)
|
|
}
|
|
return l.verify(l.skipEmptyFileForward())
|
|
}
|
|
return nil, base.LazyValue{}
|
|
|
|
default:
|
|
// Reset the smallest boundary since we're moving away from it.
|
|
l.smallestBoundary = nil
|
|
if key, val := l.iter.Next(); key != nil {
|
|
return l.verify(key, val)
|
|
}
|
|
}
|
|
return l.verify(l.skipEmptyFileForward())
|
|
}
|
|
|
|
func (l *levelIter) NextPrefix(succKey []byte) (*InternalKey, base.LazyValue) {
|
|
if l.err != nil || l.iter == nil {
|
|
return nil, base.LazyValue{}
|
|
}
|
|
if l.boundaryContext != nil {
|
|
l.boundaryContext.isSyntheticIterBoundsKey = false
|
|
l.boundaryContext.isIgnorableBoundaryKey = false
|
|
}
|
|
|
|
switch {
|
|
case l.largestBoundary != nil:
|
|
if l.tableOpts.UpperBound != nil {
|
|
// The UpperBound was within this file, so don't load the next
|
|
// file. We leave the largestBoundary unchanged so that subsequent
|
|
// calls to Next() stay at this file. If a Seek/First/Last call is
|
|
// made and this file continues to be relevant, loadFile() will
|
|
// set the largestBoundary to nil.
|
|
if l.rangeDelIterPtr != nil {
|
|
*l.rangeDelIterPtr = nil
|
|
}
|
|
return nil, base.LazyValue{}
|
|
}
|
|
// We're stepping past the boundary key, so we need to load a later
|
|
// file.
|
|
|
|
default:
|
|
// Reset the smallest boundary since we're moving away from it.
|
|
l.smallestBoundary = nil
|
|
|
|
if key, val := l.iter.NextPrefix(succKey); key != nil {
|
|
return l.verify(key, val)
|
|
}
|
|
// Fall through to seeking.
|
|
}
|
|
|
|
// Seek the manifest level iterator using TrySeekUsingNext=true and
|
|
// RelativeSeek=true so that we take advantage of the knowledge that
|
|
// `succKey` can only be contained in later files.
|
|
metadataSeekFlags := base.SeekGEFlagsNone.EnableTrySeekUsingNext().EnableRelativeSeek()
|
|
if l.loadFile(l.findFileGE(succKey, metadataSeekFlags), +1) != noFileLoaded {
|
|
// NB: The SeekGE on the file's iterator must not set TrySeekUsingNext,
|
|
// because l.iter is unpositioned.
|
|
if key, val := l.iter.SeekGE(succKey, base.SeekGEFlagsNone); key != nil {
|
|
return l.verify(key, val)
|
|
}
|
|
return l.verify(l.skipEmptyFileForward())
|
|
}
|
|
return nil, base.LazyValue{}
|
|
}
|
|
|
|
func (l *levelIter) Prev() (*InternalKey, base.LazyValue) {
|
|
if l.err != nil || l.iter == nil {
|
|
return nil, base.LazyValue{}
|
|
}
|
|
if l.boundaryContext != nil {
|
|
l.boundaryContext.isSyntheticIterBoundsKey = false
|
|
l.boundaryContext.isIgnorableBoundaryKey = false
|
|
}
|
|
|
|
switch {
|
|
case l.smallestBoundary != nil:
|
|
if l.tableOpts.LowerBound != nil {
|
|
// The LowerBound was within this file, so don't load the previous
|
|
// file. We leave the smallestBoundary unchanged so that
|
|
// subsequent calls to Prev() stay at this file. If a
|
|
// Seek/First/Last call is made and this file continues to be
|
|
// relevant, loadFile() will set the smallestBoundary to nil.
|
|
if l.rangeDelIterPtr != nil {
|
|
*l.rangeDelIterPtr = nil
|
|
}
|
|
return nil, base.LazyValue{}
|
|
}
|
|
// We're stepping past the boundary key, so now we can load the prev file.
|
|
if l.loadFile(l.files.Prev(), -1) != noFileLoaded {
|
|
if key, val := l.iter.Last(); key != nil {
|
|
return l.verify(key, val)
|
|
}
|
|
return l.verify(l.skipEmptyFileBackward())
|
|
}
|
|
return nil, base.LazyValue{}
|
|
|
|
default:
|
|
// Reset the largest boundary since we're moving away from it.
|
|
l.largestBoundary = nil
|
|
if key, val := l.iter.Prev(); key != nil {
|
|
return l.verify(key, val)
|
|
}
|
|
}
|
|
return l.verify(l.skipEmptyFileBackward())
|
|
}
|
|
|
|
func (l *levelIter) skipEmptyFileForward() (*InternalKey, base.LazyValue) {
|
|
var key *InternalKey
|
|
var val base.LazyValue
|
|
// The first iteration of this loop starts with an already exhausted
|
|
// l.iter. The reason for the exhaustion is either that we iterated to the
|
|
// end of the sstable, or our iteration was terminated early due to the
|
|
// presence of an upper-bound or the use of SeekPrefixGE. If
|
|
// l.rangeDelIterPtr is non-nil, we may need to pretend the iterator is
|
|
// not exhausted to allow for the merging to finish consuming the
|
|
// l.rangeDelIterPtr before levelIter switches the rangeDelIter from
|
|
// under it. This pretense is done by either generating a synthetic
|
|
// boundary key or returning the largest key of the file, depending on the
|
|
// exhaustion reason.
|
|
|
|
// Subsequent iterations will examine consecutive files such that the first
|
|
// file that does not have an exhausted iterator causes the code to return
|
|
// that key, else the behavior described above if there is a corresponding
|
|
// rangeDelIterPtr.
|
|
for ; key == nil; key, val = l.iter.First() {
|
|
if l.rangeDelIterPtr != nil {
|
|
// We're being used as part of a mergingIter and we've exhausted the
|
|
// current sstable. If an upper bound is present and the upper bound lies
|
|
// within the current sstable, then we will have reached the upper bound
|
|
// rather than the end of the sstable. We need to return a synthetic
|
|
// boundary key so that mergingIter can use the range tombstone iterator
|
|
// until the other levels have reached this boundary.
|
|
//
|
|
// It is safe to set the boundary key to the UpperBound user key
|
|
// with the RANGEDEL sentinel since it is the smallest InternalKey
|
|
// that matches the exclusive upper bound, and does not represent
|
|
// a real key.
|
|
if l.tableOpts.UpperBound != nil {
|
|
if *l.rangeDelIterPtr != nil {
|
|
l.syntheticBoundary.UserKey = l.tableOpts.UpperBound
|
|
l.syntheticBoundary.Trailer = InternalKeyRangeDeleteSentinel
|
|
l.largestBoundary = &l.syntheticBoundary
|
|
if l.boundaryContext != nil {
|
|
l.boundaryContext.isSyntheticIterBoundsKey = true
|
|
}
|
|
return l.largestBoundary, base.LazyValue{}
|
|
}
|
|
// Else there are no range deletions in this sstable. This
|
|
// helps with performance when many levels are populated with
|
|
// sstables and most don't have any actual keys within the
|
|
// bounds.
|
|
return nil, base.LazyValue{}
|
|
}
|
|
// If the boundary is a range deletion tombstone, return that key.
|
|
if l.iterFile.LargestPointKey.Kind() == InternalKeyKindRangeDelete {
|
|
l.largestBoundary = &l.iterFile.LargestPointKey
|
|
if l.boundaryContext != nil {
|
|
l.boundaryContext.isIgnorableBoundaryKey = true
|
|
}
|
|
return l.largestBoundary, base.LazyValue{}
|
|
}
|
|
// If the last point iterator positioning op might've skipped keys,
|
|
// it's possible the file's range deletions are still relevant to
|
|
// other levels. Return the largest boundary as a special ignorable
|
|
// marker to avoid advancing to the next file.
|
|
//
|
|
// The sstable iterator cannot guarantee that keys were skipped. A
|
|
// SeekGE that lands on a index separator k only knows that the
|
|
// block at the index entry contains keys ≤ k. We can't know whether
|
|
// there were actually keys between the seek key and the index
|
|
// separator key. If the block is then excluded due to block
|
|
// property filters, the iterator does not know whether keys were
|
|
// actually skipped by the block's exclusion.
|
|
//
|
|
// Since MaybeFilteredKeys cannot guarantee that keys were skipped,
|
|
// it's possible l.iterFile.Largest was already returned. Returning
|
|
// l.iterFile.Largest again is a violation of the strict
|
|
// monotonicity normally provided. The mergingIter's heap can
|
|
// tolerate this repeat key and in this case will keep the level at
|
|
// the top of the heap and immediately skip the entry, advancing to
|
|
// the next file.
|
|
if *l.rangeDelIterPtr != nil && l.filteredIter != nil &&
|
|
l.filteredIter.MaybeFilteredKeys() {
|
|
l.largestBoundary = &l.iterFile.Largest
|
|
if l.boundaryContext != nil {
|
|
l.boundaryContext.isIgnorableBoundaryKey = true
|
|
}
|
|
return l.largestBoundary, base.LazyValue{}
|
|
}
|
|
}
|
|
|
|
// Current file was exhausted. Move to the next file.
|
|
if l.loadFile(l.files.Next(), +1) == noFileLoaded {
|
|
return nil, base.LazyValue{}
|
|
}
|
|
}
|
|
return key, val
|
|
}
|
|
|
|
func (l *levelIter) skipEmptyFileBackward() (*InternalKey, base.LazyValue) {
|
|
var key *InternalKey
|
|
var val base.LazyValue
|
|
// The first iteration of this loop starts with an already exhausted
|
|
// l.iter. The reason for the exhaustion is either that we iterated to the
|
|
// end of the sstable, or our iteration was terminated early due to the
|
|
// presence of a lower-bound. If l.rangeDelIterPtr is non-nil, we may need
|
|
// to pretend the iterator is not exhausted to allow for the merging to
|
|
// finish consuming the l.rangeDelIterPtr before levelIter switches the
|
|
// rangeDelIter from under it. This pretense is done by either generating
|
|
// a synthetic boundary key or returning the smallest key of the file,
|
|
// depending on the exhaustion reason.
|
|
|
|
// Subsequent iterations will examine consecutive files such that the first
|
|
// file that does not have an exhausted iterator causes the code to return
|
|
// that key, else the behavior described above if there is a corresponding
|
|
// rangeDelIterPtr.
|
|
for ; key == nil; key, val = l.iter.Last() {
|
|
if l.rangeDelIterPtr != nil {
|
|
// We're being used as part of a mergingIter and we've exhausted the
|
|
// current sstable. If a lower bound is present and the lower bound lies
|
|
// within the current sstable, then we will have reached the lower bound
|
|
// rather than the beginning of the sstable. We need to return a
|
|
// synthetic boundary key so that mergingIter can use the range tombstone
|
|
// iterator until the other levels have reached this boundary.
|
|
//
|
|
// It is safe to set the boundary key to the LowerBound user key
|
|
// with the RANGEDEL sentinel since it is the smallest InternalKey
|
|
// that is within the inclusive lower bound, and does not
|
|
// represent a real key.
|
|
if l.tableOpts.LowerBound != nil {
|
|
if *l.rangeDelIterPtr != nil {
|
|
l.syntheticBoundary.UserKey = l.tableOpts.LowerBound
|
|
l.syntheticBoundary.Trailer = InternalKeyRangeDeleteSentinel
|
|
l.smallestBoundary = &l.syntheticBoundary
|
|
if l.boundaryContext != nil {
|
|
l.boundaryContext.isSyntheticIterBoundsKey = true
|
|
}
|
|
return l.smallestBoundary, base.LazyValue{}
|
|
}
|
|
// Else there are no range deletions in this sstable. This
|
|
// helps with performance when many levels are populated with
|
|
// sstables and most don't have any actual keys within the
|
|
// bounds.
|
|
return nil, base.LazyValue{}
|
|
}
|
|
// If the boundary is a range deletion tombstone, return that key.
|
|
if l.iterFile.SmallestPointKey.Kind() == InternalKeyKindRangeDelete {
|
|
l.smallestBoundary = &l.iterFile.SmallestPointKey
|
|
if l.boundaryContext != nil {
|
|
l.boundaryContext.isIgnorableBoundaryKey = true
|
|
}
|
|
return l.smallestBoundary, base.LazyValue{}
|
|
}
|
|
// If the last point iterator positioning op skipped keys, it's
|
|
// possible the file's range deletions are still relevant to other
|
|
// levels. Return the smallest boundary as a special ignorable key
|
|
// to avoid advancing to the next file.
|
|
//
|
|
// The sstable iterator cannot guarantee that keys were skipped. A
|
|
// SeekGE that lands on a index separator k only knows that the
|
|
// block at the index entry contains keys ≤ k. We can't know whether
|
|
// there were actually keys between the seek key and the index
|
|
// separator key. If the block is then excluded due to block
|
|
// property filters, the iterator does not know whether keys were
|
|
// actually skipped by the block's exclusion.
|
|
//
|
|
// Since MaybeFilteredKeys cannot guarantee that keys were skipped,
|
|
// it's possible l.iterFile.Smallest was already returned. Returning
|
|
// l.iterFile.Smallest again is a violation of the strict
|
|
// monotonicity normally provided. The mergingIter's heap can
|
|
// tolerate this repeat key and in this case will keep the level at
|
|
// the top of the heap and immediately skip the entry, advancing to
|
|
// the next file.
|
|
if *l.rangeDelIterPtr != nil && l.filteredIter != nil && l.filteredIter.MaybeFilteredKeys() {
|
|
l.smallestBoundary = &l.iterFile.Smallest
|
|
if l.boundaryContext != nil {
|
|
l.boundaryContext.isIgnorableBoundaryKey = true
|
|
}
|
|
return l.smallestBoundary, base.LazyValue{}
|
|
}
|
|
}
|
|
|
|
// Current file was exhausted. Move to the previous file.
|
|
if l.loadFile(l.files.Prev(), -1) == noFileLoaded {
|
|
return nil, base.LazyValue{}
|
|
}
|
|
}
|
|
return key, val
|
|
}
|
|
|
|
func (l *levelIter) Error() error {
|
|
if l.err != nil || l.iter == nil {
|
|
return l.err
|
|
}
|
|
return l.iter.Error()
|
|
}
|
|
|
|
func (l *levelIter) Close() error {
|
|
if l.iter != nil {
|
|
l.err = l.iter.Close()
|
|
l.iter = nil
|
|
}
|
|
if l.rangeDelIterPtr != nil {
|
|
if t := l.rangeDelIterCopy; t != nil {
|
|
l.err = firstError(l.err, t.Close())
|
|
}
|
|
*l.rangeDelIterPtr = nil
|
|
l.rangeDelIterCopy = nil
|
|
}
|
|
return l.err
|
|
}
|
|
|
|
func (l *levelIter) SetBounds(lower, upper []byte) {
|
|
l.lower = lower
|
|
l.upper = upper
|
|
|
|
if l.iter == nil {
|
|
return
|
|
}
|
|
|
|
// Update tableOpts.{Lower,Upper}Bound in case the new boundaries fall within
|
|
// the boundaries of the current table.
|
|
if l.initTableBounds(l.iterFile) != 0 {
|
|
// The table does not overlap the bounds. Close() will set levelIter.err if
|
|
// an error occurs.
|
|
_ = l.Close()
|
|
return
|
|
}
|
|
|
|
l.iter.SetBounds(l.tableOpts.LowerBound, l.tableOpts.UpperBound)
|
|
}
|
|
|
|
func (l *levelIter) SetContext(ctx context.Context) {
|
|
l.ctx = ctx
|
|
if l.iter != nil {
|
|
// TODO(sumeer): this is losing the ctx = objiotracing.WithLevel(ctx,
|
|
// manifest.LevelToInt(opts.level)) that happens in table_cache.go.
|
|
l.iter.SetContext(ctx)
|
|
}
|
|
}
|
|
|
|
func (l *levelIter) String() string {
|
|
if l.iterFile != nil {
|
|
return fmt.Sprintf("%s: fileNum=%s", l.level, l.iter.String())
|
|
}
|
|
return fmt.Sprintf("%s: fileNum=<nil>", l.level)
|
|
}
|
|
|
|
var _ internalIterator = &levelIter{}
|