mirror of
https://source.quilibrium.com/quilibrium/ceremonyclient.git
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1150 lines
40 KiB
Go
1150 lines
40 KiB
Go
// Copyright 2021 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 keyspan
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import (
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"context"
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"fmt"
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"github.com/cockroachdb/errors"
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"github.com/cockroachdb/pebble/internal/base"
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"github.com/cockroachdb/pebble/internal/invariants"
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)
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// A SpanMask may be used to configure an interleaving iterator to skip point
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// keys that fall within the bounds of some spans.
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type SpanMask interface {
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// SpanChanged is invoked by an interleaving iterator whenever the current
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// span changes. As the iterator passes into or out of a Span, it invokes
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// SpanChanged, passing the new Span. When the iterator passes out of a
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// span's boundaries and is no longer covered by any span, SpanChanged is
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// invoked with a nil span.
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//
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// SpanChanged is invoked before SkipPoint, and callers may use SpanChanged
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// to recalculate state used by SkipPoint for masking.
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//
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// SpanChanged may be invoked consecutively with identical spans under some
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// circumstances, such as repeatedly absolutely positioning an iterator to
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// positions covered by the same span, or while changing directions.
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SpanChanged(*Span)
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// SkipPoint is invoked by the interleaving iterator whenever the iterator
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// encounters a point key covered by a Span. If SkipPoint returns true, the
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// interleaving iterator skips the point key and all larger keys with the
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// same prefix. This is used during range key iteration to skip over point
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// keys 'masked' by range keys.
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SkipPoint(userKey []byte) bool
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}
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// InterleavingIter combines an iterator over point keys with an iterator over
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// key spans.
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//
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// Throughout Pebble, some keys apply at single discrete points within the user
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// keyspace. Other keys apply over continuous spans of the user key space.
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// Internally, iterators over point keys adhere to the base.InternalIterator
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// interface, and iterators over spans adhere to the keyspan.FragmentIterator
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// interface. The InterleavingIterator wraps a point iterator and span iterator,
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// providing access to all the elements of both iterators.
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//
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// The InterleavingIterator implements the point base.InternalIterator
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// interface. After any of the iterator's methods return a key, a caller may
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// call Span to retrieve the span covering the returned key, if any. A span is
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// considered to 'cover' a returned key if the span's [start, end) bounds
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// include the key's user key.
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//
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// In addition to tracking the current covering span, InterleavingIter returns a
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// special InternalKey at span start boundaries. Start boundaries are surfaced
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// as a synthetic span marker: an InternalKey with the boundary as the user key,
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// the infinite sequence number and a key kind selected from an arbitrary key
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// the infinite sequence number and an arbitrary contained key's kind. Since
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// which of the Span's key's kind is surfaced is undefined, the caller should
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// not use the InternalKey's kind. The caller should only rely on the `Span`
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// method for retrieving information about spanning keys. The interleaved
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// synthetic keys have the infinite sequence number so that they're interleaved
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// before any point keys with the same user key when iterating forward and after
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// when iterating backward.
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//
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// Interleaving the synthetic start key boundaries at the maximum sequence
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// number provides an opportunity for the higher-level, public Iterator to
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// observe the Span, even if no live points keys exist within the boudns of the
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// Span.
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//
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// When returning a synthetic marker key for a start boundary, InterleavingIter
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// will truncate the span's start bound to the SeekGE or SeekPrefixGE search
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// key. For example, a SeekGE("d") that finds a span [a, z) may return a
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// synthetic span marker key `d#72057594037927935,21`.
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//
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// If bounds have been applied to the iterator through SetBounds,
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// InterleavingIter will truncate the bounds of spans returned through Span to
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// the set bounds. The bounds returned through Span are not truncated by a
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// SeekGE or SeekPrefixGE search key. Consider, for example SetBounds('c', 'e'),
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// with an iterator containing the Span [a,z):
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//
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// First() = `c#72057594037927935,21` Span() = [c,e)
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// SeekGE('d') = `d#72057594037927935,21` Span() = [c,e)
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//
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// InterleavedIter does not interleave synthetic markers for spans that do not
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// contain any keys.
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//
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// # SpanMask
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//
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// InterelavingIter takes a SpanMask parameter that may be used to configure the
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// behavior of the iterator. See the documentation on the SpanMask type.
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//
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// All spans containing keys are exposed during iteration.
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type InterleavingIter struct {
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cmp base.Compare
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comparer *base.Comparer
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pointIter base.InternalIterator
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keyspanIter FragmentIterator
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mask SpanMask
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// lower and upper hold the iteration bounds set through SetBounds.
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lower, upper []byte
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// keyBuf is used to copy SeekGE or SeekPrefixGE arguments when they're used
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// to truncate a span. The byte slices backing a SeekGE/SeekPrefixGE search
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// keys can come directly from the end user, so they're copied into keyBuf
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// to ensure key stability.
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keyBuf []byte
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// nextPrefixBuf is used during SeekPrefixGE calls to store the truncated
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// upper bound of the returned spans. SeekPrefixGE truncates the returned
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// spans to an upper bound of the seeked prefix's immediate successor.
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nextPrefixBuf []byte
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pointKey *base.InternalKey
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pointVal base.LazyValue
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// err holds an iterator error from either pointIter or keyspanIter. It's
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// reset to nil on seeks. An overview of error-handling mechanics:
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//
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// Whenever either pointIter or keyspanIter is respositioned and a nil
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// key/span is returned, the code performing the positioning is responsible
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// for checking the iterator's Error() value. This happens in savePoint and
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// saveSpan[Forward,Backward].
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//
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// Once i.err is non-nil, the computation of i.pos must set i.pos =
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// posExhausted. This happens in compute[Smallest|Largest]Pos and
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// [next|prev]Pos. Setting i.pos to posExhausted ensures we'll yield nil to
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// the caller, which they'll interpret as a signal they must check Error().
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//
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// INVARIANTS:
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// i.err != nil => i.pos = posExhausted
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err error
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// prefix records the iterator's current prefix if the iterator is in prefix
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// mode. During prefix mode, Pebble will truncate spans to the next prefix.
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// If the iterator subsequently leaves prefix mode, the existing span cached
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// in i.span must be invalidated because its bounds do not reflect the
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// original span's true bounds.
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prefix []byte
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// span holds the span at the keyspanIter's current position. If the span is
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// wholly contained within the iterator bounds, this span is directly
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// returned to the iterator consumer through Span(). If either bound needed
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// to be truncated to the iterator bounds, then truncated is set to true and
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// Span() must return a pointer to truncatedSpan.
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span *Span
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// spanMarker holds the synthetic key that is returned when the iterator
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// passes over a key span's start bound.
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spanMarker base.InternalKey
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// truncated indicates whether or not the span at the current position
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// needed to be truncated. If it did, truncatedSpan holds the truncated
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// span that should be returned.
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truncatedSpan Span
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truncated bool
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// Keeping all of the bools/uint8s together reduces the sizeof the struct.
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// pos encodes the current position of the iterator: exhausted, on the point
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// key, on a keyspan start, or on a keyspan end.
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pos interleavePos
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// withinSpan indicates whether the iterator is currently positioned within
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// the bounds of the current span (i.span). withinSpan must be updated
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// whenever the interleaving iterator's position enters or exits the bounds
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// of a span.
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withinSpan bool
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// spanMarkerTruncated is set by SeekGE/SeekPrefixGE calls that truncate a
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// span's start bound marker to the search key. It's returned to false on
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// the next repositioning of the keyspan iterator.
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spanMarkerTruncated bool
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// maskSpanChangedCalled records whether or not the last call to
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// SpanMask.SpanChanged provided the current span (i.span) or not.
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maskSpanChangedCalled bool
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// dir indicates the direction of iteration: forward (+1) or backward (-1)
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dir int8
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}
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// interleavePos indicates the iterator's current position. Note that both
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// keyspanStart and keyspanEnd positions correspond to their user key boundaries
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// with maximal sequence numbers. This means in the forward direction
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// posKeyspanStart and posKeyspanEnd are always interleaved before a posPointKey
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// with the same user key.
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type interleavePos int8
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const (
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posUninitialized interleavePos = iota
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posExhausted
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posPointKey
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posKeyspanStart
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posKeyspanEnd
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)
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// Assert that *InterleavingIter implements the InternalIterator interface.
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var _ base.InternalIterator = &InterleavingIter{}
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// InterleavingIterOpts holds options configuring the behavior of a
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// InterleavingIter.
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type InterleavingIterOpts struct {
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Mask SpanMask
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LowerBound, UpperBound []byte
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}
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// Init initializes the InterleavingIter to interleave point keys from pointIter
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// with key spans from keyspanIter.
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//
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// The point iterator must already have the bounds provided on opts. Init does
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// not propagate the bounds down the iterator stack.
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func (i *InterleavingIter) Init(
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comparer *base.Comparer,
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pointIter base.InternalIterator,
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keyspanIter FragmentIterator,
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opts InterleavingIterOpts,
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) {
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*i = InterleavingIter{
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cmp: comparer.Compare,
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comparer: comparer,
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pointIter: pointIter,
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keyspanIter: keyspanIter,
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mask: opts.Mask,
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lower: opts.LowerBound,
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upper: opts.UpperBound,
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}
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}
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// InitSeekGE may be called after Init but before any positioning method.
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// InitSeekGE initializes the current position of the point iterator and then
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// performs a SeekGE on the keyspan iterator using the provided key. InitSeekGE
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// returns whichever point or keyspan key is smaller. After InitSeekGE, the
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// iterator is positioned and may be repositioned using relative positioning
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// methods.
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//
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// This method is used specifically for lazily constructing combined iterators.
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// It allows for seeding the iterator with the current position of the point
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// iterator.
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func (i *InterleavingIter) InitSeekGE(
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prefix, key []byte, pointKey *base.InternalKey, pointValue base.LazyValue,
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) (*base.InternalKey, base.LazyValue) {
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i.dir = +1
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i.clearMask()
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i.prefix = prefix
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i.savePoint(pointKey, pointValue)
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// NB: This keyspanSeekGE call will truncate the span to the seek key if
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// necessary. This truncation is important for cases where a switch to
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// combined iteration is made during a user-initiated SeekGE.
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i.keyspanSeekGE(key, prefix)
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i.computeSmallestPos()
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return i.yieldPosition(key, i.nextPos)
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}
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// InitSeekLT may be called after Init but before any positioning method.
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// InitSeekLT initializes the current position of the point iterator and then
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// performs a SeekLT on the keyspan iterator using the provided key. InitSeekLT
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// returns whichever point or keyspan key is larger. After InitSeekLT, the
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// iterator is positioned and may be repositioned using relative positioning
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// methods.
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//
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// This method is used specifically for lazily constructing combined iterators.
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// It allows for seeding the iterator with the current position of the point
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// iterator.
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func (i *InterleavingIter) InitSeekLT(
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key []byte, pointKey *base.InternalKey, pointValue base.LazyValue,
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) (*base.InternalKey, base.LazyValue) {
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i.dir = -1
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i.clearMask()
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i.savePoint(pointKey, pointValue)
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i.keyspanSeekLT(key)
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i.computeLargestPos()
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return i.yieldPosition(i.lower, i.prevPos)
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}
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// SeekGE implements (base.InternalIterator).SeekGE.
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//
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// If there exists a span with a start key ≤ the first matching point key,
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// SeekGE will return a synthetic span marker key for the span. If this span's
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// start key is less than key, the returned marker will be truncated to key.
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// Note that this search-key truncation of the marker's key is not applied to
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// the span returned by Span.
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//
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// NB: In accordance with the base.InternalIterator contract:
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//
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// i.lower ≤ key
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func (i *InterleavingIter) SeekGE(
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key []byte, flags base.SeekGEFlags,
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) (*base.InternalKey, base.LazyValue) {
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i.err = nil
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i.clearMask()
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i.disablePrefixMode()
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i.savePoint(i.pointIter.SeekGE(key, flags))
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// We need to seek the keyspan iterator too. If the keyspan iterator was
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// already positioned at a span, we might be able to avoid the seek if the
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// seek key falls within the existing span's bounds.
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if i.span != nil && i.cmp(key, i.span.End) < 0 && i.cmp(key, i.span.Start) >= 0 {
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// We're seeking within the existing span's bounds. We still might need
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// truncate the span to the iterator's bounds.
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i.saveSpanForward(i.span)
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i.savedKeyspan()
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} else {
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i.keyspanSeekGE(key, nil /* prefix */)
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}
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i.dir = +1
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i.computeSmallestPos()
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return i.yieldPosition(key, i.nextPos)
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}
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// SeekPrefixGE implements (base.InternalIterator).SeekPrefixGE.
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//
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// If there exists a span with a start key ≤ the first matching point key,
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// SeekPrefixGE will return a synthetic span marker key for the span. If this
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// span's start key is less than key, the returned marker will be truncated to
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// key. Note that this search-key truncation of the marker's key is not applied
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// to the span returned by Span.
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//
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// NB: In accordance with the base.InternalIterator contract:
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//
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// i.lower ≤ key
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func (i *InterleavingIter) SeekPrefixGE(
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prefix, key []byte, flags base.SeekGEFlags,
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) (*base.InternalKey, base.LazyValue) {
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i.err = nil
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i.clearMask()
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i.prefix = prefix
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i.savePoint(i.pointIter.SeekPrefixGE(prefix, key, flags))
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// We need to seek the keyspan iterator too. If the keyspan iterator was
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// already positioned at a span, we might be able to avoid the seek if the
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// entire seek prefix key falls within the existing span's bounds.
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//
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// During a SeekPrefixGE, Pebble defragments range keys within the bounds of
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// the prefix. For example, a SeekPrefixGE('c', 'c@8') must defragment the
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// any overlapping range keys within the bounds of [c,c\00).
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//
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// If range keys are fragmented within a prefix (eg, because a version
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// within a prefix was chosen as an sstable boundary), then it's possible
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// the seek key falls into the current i.span, but the current i.span does
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// not wholly cover the seek prefix.
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//
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// For example, a SeekPrefixGE('d@5') may only defragment a range key to
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// the bounds of [c@2,e). A subsequent SeekPrefixGE('c@0') must re-seek the
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// keyspan iterator, because although 'c@0' is contained within [c@2,e), the
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// full span of the prefix is not.
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//
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// Similarly, a SeekPrefixGE('a@3') may only defragment a range key to the
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// bounds [a,c@8). A subsequent SeekPrefixGE('c@10') must re-seek the
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// keyspan iterator, because although 'c@10' is contained within [a,c@8),
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// the full span of the prefix is not.
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seekKeyspanIter := true
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if i.span != nil && i.cmp(prefix, i.span.Start) >= 0 {
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if ei := i.comparer.Split(i.span.End); i.cmp(prefix, i.span.End[:ei]) < 0 {
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// We're seeking within the existing span's bounds. We still might need
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// truncate the span to the iterator's bounds.
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i.saveSpanForward(i.span)
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i.savedKeyspan()
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seekKeyspanIter = false
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}
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}
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if seekKeyspanIter {
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i.keyspanSeekGE(key, prefix)
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}
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i.dir = +1
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i.computeSmallestPos()
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return i.yieldPosition(key, i.nextPos)
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}
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// SeekLT implements (base.InternalIterator).SeekLT.
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func (i *InterleavingIter) SeekLT(
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key []byte, flags base.SeekLTFlags,
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) (*base.InternalKey, base.LazyValue) {
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i.err = nil
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i.clearMask()
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i.disablePrefixMode()
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i.savePoint(i.pointIter.SeekLT(key, flags))
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// We need to seek the keyspan iterator too. If the keyspan iterator was
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// already positioned at a span, we might be able to avoid the seek if the
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// seek key falls within the existing span's bounds.
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if i.span != nil && i.cmp(key, i.span.Start) > 0 && i.cmp(key, i.span.End) < 0 {
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// We're seeking within the existing span's bounds. We still might need
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// truncate the span to the iterator's bounds.
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i.saveSpanBackward(i.span)
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// The span's start key is still not guaranteed to be less than key,
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// because of the bounds enforcement. Consider the following example:
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//
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// Bounds are set to [d,e). The user performs a SeekLT(d). The
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// FragmentIterator.SeekLT lands on a span [b,f). This span has a start
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// key less than d, as expected. Above, saveSpanBackward truncates the
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// span to match the iterator's current bounds, modifying the span to
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// [d,e), which does not overlap the search space of [-∞, d).
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//
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// This problem is a consequence of the SeekLT's exclusive search key
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// and the fact that we don't perform bounds truncation at every leaf
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// iterator.
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if i.span != nil && i.truncated && i.cmp(i.truncatedSpan.Start, key) >= 0 {
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i.span = nil
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}
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i.savedKeyspan()
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} else {
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i.keyspanSeekLT(key)
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}
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i.dir = -1
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i.computeLargestPos()
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return i.yieldPosition(i.lower, i.prevPos)
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}
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// First implements (base.InternalIterator).First.
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func (i *InterleavingIter) First() (*base.InternalKey, base.LazyValue) {
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i.err = nil
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i.clearMask()
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i.disablePrefixMode()
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i.savePoint(i.pointIter.First())
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i.saveSpanForward(i.keyspanIter.First())
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i.savedKeyspan()
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i.dir = +1
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i.computeSmallestPos()
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return i.yieldPosition(i.lower, i.nextPos)
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}
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// Last implements (base.InternalIterator).Last.
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func (i *InterleavingIter) Last() (*base.InternalKey, base.LazyValue) {
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i.err = nil
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i.clearMask()
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i.disablePrefixMode()
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i.savePoint(i.pointIter.Last())
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i.saveSpanBackward(i.keyspanIter.Last())
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i.savedKeyspan()
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i.dir = -1
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i.computeLargestPos()
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return i.yieldPosition(i.lower, i.prevPos)
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}
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// Next implements (base.InternalIterator).Next.
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func (i *InterleavingIter) Next() (*base.InternalKey, base.LazyValue) {
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if i.dir == -1 {
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// Switching directions.
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i.dir = +1
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if i.mask != nil {
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// Clear the mask while we reposition the point iterator. While
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// switching directions, we may move the point iterator outside of
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// i.span's bounds.
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i.clearMask()
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}
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// When switching directions, iterator state corresponding to the
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// current iterator position (as indicated by i.pos) is already correct.
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// However any state that has yet to be interleaved describes a position
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// behind the current iterator position and needs to be updated to
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// describe the position ahead of the current iterator position.
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switch i.pos {
|
|
case posExhausted:
|
|
// Nothing to do. The below nextPos call will move both the point
|
|
// key and span to their next positions and return
|
|
// MIN(point,s.Start).
|
|
case posPointKey:
|
|
// If we're currently on a point key, the below nextPos will
|
|
// correctly Next the point key iterator to the next point key.
|
|
// Do we need to move the span forwards? If the current span lies
|
|
// entirely behind the current key (!i.withinSpan), then we
|
|
// need to move it to the first span in the forward direction.
|
|
if !i.withinSpan {
|
|
i.saveSpanForward(i.keyspanIter.Next())
|
|
i.savedKeyspan()
|
|
}
|
|
case posKeyspanStart:
|
|
i.withinSpan = true
|
|
// Since we're positioned on a Span, the pointIter is positioned
|
|
// entirely behind the current iterator position. Reposition it
|
|
// ahead of the current iterator position.
|
|
i.savePoint(i.pointIter.Next())
|
|
case posKeyspanEnd:
|
|
// Since we're positioned on a Span, the pointIter is positioned
|
|
// entirely behind of the current iterator position. Reposition it
|
|
// ahead the current iterator position.
|
|
i.savePoint(i.pointIter.Next())
|
|
}
|
|
// Fallthrough to calling i.nextPos.
|
|
}
|
|
i.nextPos()
|
|
return i.yieldPosition(i.lower, i.nextPos)
|
|
}
|
|
|
|
// NextPrefix implements (base.InternalIterator).NextPrefix.
|
|
func (i *InterleavingIter) NextPrefix(succKey []byte) (*base.InternalKey, base.LazyValue) {
|
|
if i.dir == -1 {
|
|
panic("pebble: cannot switch directions with NextPrefix")
|
|
}
|
|
|
|
switch i.pos {
|
|
case posExhausted:
|
|
return nil, base.LazyValue{}
|
|
case posPointKey:
|
|
i.savePoint(i.pointIter.NextPrefix(succKey))
|
|
if i.withinSpan {
|
|
if i.pointKey == nil || i.cmp(i.span.End, i.pointKey.UserKey) <= 0 {
|
|
i.pos = posKeyspanEnd
|
|
} else {
|
|
i.pos = posPointKey
|
|
}
|
|
} else {
|
|
i.computeSmallestPos()
|
|
}
|
|
case posKeyspanStart, posKeyspanEnd:
|
|
i.nextPos()
|
|
}
|
|
return i.yieldPosition(i.lower, i.nextPos)
|
|
}
|
|
|
|
// Prev implements (base.InternalIterator).Prev.
|
|
func (i *InterleavingIter) Prev() (*base.InternalKey, base.LazyValue) {
|
|
if i.dir == +1 {
|
|
// Switching directions.
|
|
i.dir = -1
|
|
|
|
if i.mask != nil {
|
|
// Clear the mask while we reposition the point iterator. While
|
|
// switching directions, we may move the point iterator outside of
|
|
// i.span's bounds.
|
|
i.clearMask()
|
|
}
|
|
|
|
// When switching directions, iterator state corresponding to the
|
|
// current iterator position (as indicated by i.pos) is already correct.
|
|
// However any state that has yet to be interleaved describes a position
|
|
// ahead of the current iterator position and needs to be updated to
|
|
// describe the position behind the current iterator position.
|
|
switch i.pos {
|
|
case posExhausted:
|
|
// Nothing to do. The below prevPos call will move both the point
|
|
// key and span to previous positions and return MAX(point, s.End).
|
|
case posPointKey:
|
|
// If we're currently on a point key, the point iterator is in the
|
|
// right place and the call to prevPos will correctly Prev the point
|
|
// key iterator to the previous point key. Do we need to move the
|
|
// span backwards? If the current span lies entirely ahead of the
|
|
// current key (!i.withinSpan), then we need to move it to the first
|
|
// span in the reverse direction.
|
|
if !i.withinSpan {
|
|
i.saveSpanBackward(i.keyspanIter.Prev())
|
|
i.savedKeyspan()
|
|
}
|
|
case posKeyspanStart:
|
|
// Since we're positioned on a Span, the pointIter is positioned
|
|
// entirely ahead of the current iterator position. Reposition it
|
|
// behind the current iterator position.
|
|
i.savePoint(i.pointIter.Prev())
|
|
// Without considering truncation of spans to seek keys, the keyspan
|
|
// iterator is already in the right place. But consider span [a, z)
|
|
// and this sequence of iterator calls:
|
|
//
|
|
// SeekGE('c') = c.RANGEKEYSET#72057594037927935
|
|
// Prev() = a.RANGEKEYSET#72057594037927935
|
|
//
|
|
// If the current span's start key was last surfaced truncated due
|
|
// to a SeekGE or SeekPrefixGE call, then it's still relevant in the
|
|
// reverse direction with an untruncated start key.
|
|
if i.spanMarkerTruncated {
|
|
// When we fallthrough to calling prevPos, we want to move to
|
|
// MAX(point, span.Start). We cheat here by claiming we're
|
|
// currently on the end boundary, so that we'll move on to the
|
|
// untruncated start key if necessary.
|
|
i.pos = posKeyspanEnd
|
|
}
|
|
case posKeyspanEnd:
|
|
// Since we're positioned on a Span, the pointIter is positioned
|
|
// entirely ahead of the current iterator position. Reposition it
|
|
// behind the current iterator position.
|
|
i.savePoint(i.pointIter.Prev())
|
|
}
|
|
|
|
if i.spanMarkerTruncated {
|
|
// Save the keyspan again to clear truncation.
|
|
i.savedKeyspan()
|
|
}
|
|
// Fallthrough to calling i.prevPos.
|
|
}
|
|
i.prevPos()
|
|
return i.yieldPosition(i.lower, i.prevPos)
|
|
}
|
|
|
|
// computeSmallestPos sets i.{pos,withinSpan} to:
|
|
//
|
|
// MIN(i.pointKey, i.span.Start)
|
|
func (i *InterleavingIter) computeSmallestPos() {
|
|
if i.err == nil {
|
|
if i.span != nil && (i.pointKey == nil || i.cmp(i.startKey(), i.pointKey.UserKey) <= 0) {
|
|
i.withinSpan = true
|
|
i.pos = posKeyspanStart
|
|
return
|
|
}
|
|
i.withinSpan = false
|
|
if i.pointKey != nil {
|
|
i.pos = posPointKey
|
|
return
|
|
}
|
|
}
|
|
i.pos = posExhausted
|
|
}
|
|
|
|
// computeLargestPos sets i.{pos,withinSpan} to:
|
|
//
|
|
// MAX(i.pointKey, i.span.End)
|
|
func (i *InterleavingIter) computeLargestPos() {
|
|
if i.err == nil {
|
|
if i.span != nil && (i.pointKey == nil || i.cmp(i.span.End, i.pointKey.UserKey) > 0) {
|
|
i.withinSpan = true
|
|
i.pos = posKeyspanEnd
|
|
return
|
|
}
|
|
i.withinSpan = false
|
|
if i.pointKey != nil {
|
|
i.pos = posPointKey
|
|
return
|
|
}
|
|
}
|
|
i.pos = posExhausted
|
|
}
|
|
|
|
// nextPos advances the iterator one position in the forward direction.
|
|
func (i *InterleavingIter) nextPos() {
|
|
if invariants.Enabled {
|
|
defer func() {
|
|
if i.err != nil && i.pos != posExhausted {
|
|
panic(errors.AssertionFailedf("iterator has accumulated error but i.pos = %d", i.pos))
|
|
}
|
|
}()
|
|
}
|
|
// NB: If i.err != nil or any of the positioning methods performed in this
|
|
// function result in i.err != nil, we must set i.pos = posExhausted. We
|
|
// perform this check explicitly here, but if any of the branches below
|
|
// advance either iterator, they must also check i.err and set posExhausted
|
|
// if necessary.
|
|
if i.err != nil {
|
|
i.pos = posExhausted
|
|
return
|
|
}
|
|
|
|
switch i.pos {
|
|
case posExhausted:
|
|
i.savePoint(i.pointIter.Next())
|
|
i.saveSpanForward(i.keyspanIter.Next())
|
|
i.savedKeyspan()
|
|
i.computeSmallestPos()
|
|
case posPointKey:
|
|
i.savePoint(i.pointIter.Next())
|
|
if i.err != nil {
|
|
i.pos = posExhausted
|
|
return
|
|
}
|
|
// If we're not currently within the span, we want to chose the
|
|
// MIN(pointKey,span.Start), which is exactly the calculation performed
|
|
// by computeSmallestPos.
|
|
if !i.withinSpan {
|
|
i.computeSmallestPos()
|
|
return
|
|
}
|
|
// i.withinSpan=true
|
|
// Since we previously were within the span, we want to choose the
|
|
// MIN(pointKey,span.End).
|
|
switch {
|
|
case i.span == nil:
|
|
panic("i.withinSpan=true and i.span=nil")
|
|
case i.pointKey == nil:
|
|
// Since i.withinSpan=true, we step onto the end boundary of the
|
|
// keyspan.
|
|
i.pos = posKeyspanEnd
|
|
default:
|
|
// i.withinSpan && i.pointKey != nil && i.span != nil
|
|
if i.cmp(i.span.End, i.pointKey.UserKey) <= 0 {
|
|
i.pos = posKeyspanEnd
|
|
} else {
|
|
i.pos = posPointKey
|
|
}
|
|
}
|
|
case posKeyspanStart:
|
|
// Either a point key or the span's end key comes next.
|
|
if i.pointKey != nil && i.cmp(i.pointKey.UserKey, i.span.End) < 0 {
|
|
i.pos = posPointKey
|
|
} else {
|
|
i.pos = posKeyspanEnd
|
|
}
|
|
case posKeyspanEnd:
|
|
i.saveSpanForward(i.keyspanIter.Next())
|
|
i.savedKeyspan()
|
|
i.computeSmallestPos()
|
|
default:
|
|
panic(fmt.Sprintf("unexpected pos=%d", i.pos))
|
|
}
|
|
}
|
|
|
|
// prevPos advances the iterator one position in the reverse direction.
|
|
func (i *InterleavingIter) prevPos() {
|
|
if invariants.Enabled {
|
|
defer func() {
|
|
if i.err != nil && i.pos != posExhausted {
|
|
panic(errors.AssertionFailedf("iterator has accumulated error but i.pos = %d", i.pos))
|
|
}
|
|
}()
|
|
}
|
|
// NB: If i.err != nil or any of the positioning methods performed in this
|
|
// function result in i.err != nil, we must set i.pos = posExhausted. We
|
|
// perform this check explicitly here, but if any of the branches below
|
|
// advance either iterator, they must also check i.err and set posExhausted
|
|
// if necessary.
|
|
if i.err != nil {
|
|
i.pos = posExhausted
|
|
return
|
|
}
|
|
|
|
switch i.pos {
|
|
case posExhausted:
|
|
i.savePoint(i.pointIter.Prev())
|
|
i.saveSpanBackward(i.keyspanIter.Prev())
|
|
i.savedKeyspan()
|
|
i.computeLargestPos()
|
|
case posPointKey:
|
|
i.savePoint(i.pointIter.Prev())
|
|
if i.err != nil {
|
|
i.pos = posExhausted
|
|
return
|
|
}
|
|
// If we're not currently covered by the span, we want to chose the
|
|
// MAX(pointKey,span.End), which is exactly the calculation performed
|
|
// by computeLargestPos.
|
|
if !i.withinSpan {
|
|
i.computeLargestPos()
|
|
return
|
|
}
|
|
switch {
|
|
case i.span == nil:
|
|
panic("withinSpan=true, but i.span == nil")
|
|
case i.pointKey == nil:
|
|
i.pos = posKeyspanEnd
|
|
default:
|
|
// i.withinSpan && i.pointKey != nil && i.span != nil
|
|
if i.cmp(i.span.Start, i.pointKey.UserKey) > 0 {
|
|
i.pos = posKeyspanStart
|
|
} else {
|
|
i.pos = posPointKey
|
|
}
|
|
}
|
|
case posKeyspanStart:
|
|
i.saveSpanBackward(i.keyspanIter.Prev())
|
|
i.savedKeyspan()
|
|
i.computeLargestPos()
|
|
case posKeyspanEnd:
|
|
// Either a point key or the span's start key is previous.
|
|
if i.pointKey != nil && i.cmp(i.pointKey.UserKey, i.span.Start) >= 0 {
|
|
i.pos = posPointKey
|
|
} else {
|
|
i.pos = posKeyspanStart
|
|
}
|
|
default:
|
|
panic(fmt.Sprintf("unexpected pos=%d", i.pos))
|
|
}
|
|
}
|
|
|
|
func (i *InterleavingIter) yieldPosition(
|
|
lowerBound []byte, advance func(),
|
|
) (*base.InternalKey, base.LazyValue) {
|
|
// This loop returns the first visible position in the current iteration
|
|
// direction. Some positions are not visible and skipped. For example, if
|
|
// masking is enabled and the iterator is positioned over a masked point
|
|
// key, this loop skips the position. If a span's start key should be
|
|
// interleaved next, but the span is empty, the loop continues to the next
|
|
// key. Currently, span end keys are also always skipped, and are used only
|
|
// for maintaining internal state.
|
|
for {
|
|
switch i.pos {
|
|
case posExhausted:
|
|
return i.yieldNil()
|
|
case posPointKey:
|
|
if i.pointKey == nil {
|
|
panic("i.pointKey is nil")
|
|
}
|
|
|
|
if i.mask != nil {
|
|
i.maybeUpdateMask()
|
|
if i.withinSpan && i.mask.SkipPoint(i.pointKey.UserKey) {
|
|
// The span covers the point key. If a SkipPoint hook is
|
|
// configured, ask it if we should skip this point key.
|
|
if i.prefix != nil {
|
|
// During prefix-iteration node, once a point is masked,
|
|
// all subsequent keys with the same prefix must also be
|
|
// masked according to the key ordering. We can stop and
|
|
// return nil.
|
|
//
|
|
// NB: The above is not just an optimization. During
|
|
// prefix-iteration mode, the internal iterator contract
|
|
// prohibits us from Next-ing beyond the first key
|
|
// beyond the iteration prefix. If we didn't already
|
|
// stop early, we would need to check if this masked
|
|
// point is already beyond the prefix.
|
|
return i.yieldNil()
|
|
}
|
|
// TODO(jackson): If we thread a base.Comparer through to
|
|
// InterleavingIter so that we have access to
|
|
// ImmediateSuccessor, we could use NextPrefix. We'd need to
|
|
// tweak the SpanMask interface slightly.
|
|
|
|
// Advance beyond the masked point key.
|
|
advance()
|
|
continue
|
|
}
|
|
}
|
|
return i.yieldPointKey()
|
|
case posKeyspanEnd:
|
|
// Don't interleave end keys; just advance.
|
|
advance()
|
|
continue
|
|
case posKeyspanStart:
|
|
// Don't interleave an empty span.
|
|
if i.span.Empty() {
|
|
advance()
|
|
continue
|
|
}
|
|
return i.yieldSyntheticSpanMarker(lowerBound)
|
|
default:
|
|
panic(fmt.Sprintf("unexpected interleavePos=%d", i.pos))
|
|
}
|
|
}
|
|
}
|
|
|
|
// keyspanSeekGE seeks the keyspan iterator to the first span covering a key ≥ k.
|
|
func (i *InterleavingIter) keyspanSeekGE(k []byte, prefix []byte) {
|
|
i.saveSpanForward(i.keyspanIter.SeekGE(k))
|
|
i.savedKeyspan()
|
|
}
|
|
|
|
// keyspanSeekLT seeks the keyspan iterator to the last span covering a key < k.
|
|
func (i *InterleavingIter) keyspanSeekLT(k []byte) {
|
|
i.saveSpanBackward(i.keyspanIter.SeekLT(k))
|
|
// The current span's start key is not guaranteed to be less than key,
|
|
// because of the bounds enforcement. Consider the following example:
|
|
//
|
|
// Bounds are set to [d,e). The user performs a SeekLT(d). The
|
|
// FragmentIterator.SeekLT lands on a span [b,f). This span has a start key
|
|
// less than d, as expected. Above, saveSpanBackward truncates the span to
|
|
// match the iterator's current bounds, modifying the span to [d,e), which
|
|
// does not overlap the search space of [-∞, d).
|
|
//
|
|
// This problem is a consequence of the SeekLT's exclusive search key and
|
|
// the fact that we don't perform bounds truncation at every leaf iterator.
|
|
if i.span != nil && i.truncated && i.cmp(i.truncatedSpan.Start, k) >= 0 {
|
|
i.span = nil
|
|
}
|
|
i.savedKeyspan()
|
|
}
|
|
|
|
func (i *InterleavingIter) saveSpanForward(span *Span) {
|
|
i.span = span
|
|
i.truncated = false
|
|
i.truncatedSpan = Span{}
|
|
if i.span == nil {
|
|
i.err = firstError(i.err, i.keyspanIter.Error())
|
|
return
|
|
}
|
|
if invariants.Enabled {
|
|
if err := i.keyspanIter.Error(); err != nil {
|
|
panic(errors.WithSecondaryError(
|
|
errors.AssertionFailedf("pebble: %T keyspan iterator returned non-nil span %s while iter has error", i.keyspanIter, i.span),
|
|
err))
|
|
}
|
|
}
|
|
// Check the upper bound if we have one.
|
|
if i.upper != nil && i.cmp(i.span.Start, i.upper) >= 0 {
|
|
i.span = nil
|
|
return
|
|
}
|
|
|
|
// TODO(jackson): The key comparisons below truncate bounds whenever the
|
|
// keyspan iterator is repositioned. We could perform this lazily, and do it
|
|
// the first time the user actually asks for this span's bounds in
|
|
// SpanBounds. This would reduce work in the case where there's no span
|
|
// covering the point and the keyspan iterator is non-empty.
|
|
|
|
// NB: These truncations don't require setting `keyspanMarkerTruncated`:
|
|
// That flag only applies to truncated span marker keys.
|
|
if i.lower != nil && i.cmp(i.span.Start, i.lower) < 0 {
|
|
i.truncated = true
|
|
i.truncatedSpan = *i.span
|
|
i.truncatedSpan.Start = i.lower
|
|
}
|
|
if i.upper != nil && i.cmp(i.upper, i.span.End) < 0 {
|
|
if !i.truncated {
|
|
i.truncated = true
|
|
i.truncatedSpan = *i.span
|
|
}
|
|
i.truncatedSpan.End = i.upper
|
|
}
|
|
// If this is a part of a SeekPrefixGE call, we may also need to truncate to
|
|
// the prefix's bounds.
|
|
if i.prefix != nil {
|
|
if !i.truncated {
|
|
i.truncated = true
|
|
i.truncatedSpan = *i.span
|
|
}
|
|
if i.cmp(i.prefix, i.truncatedSpan.Start) > 0 {
|
|
i.truncatedSpan.Start = i.prefix
|
|
}
|
|
i.nextPrefixBuf = i.comparer.ImmediateSuccessor(i.nextPrefixBuf[:0], i.prefix)
|
|
if i.truncated && i.cmp(i.nextPrefixBuf, i.truncatedSpan.End) < 0 {
|
|
i.truncatedSpan.End = i.nextPrefixBuf
|
|
}
|
|
}
|
|
|
|
if i.truncated && i.comparer.Equal(i.truncatedSpan.Start, i.truncatedSpan.End) {
|
|
i.span = nil
|
|
}
|
|
}
|
|
|
|
func (i *InterleavingIter) saveSpanBackward(span *Span) {
|
|
i.span = span
|
|
i.truncated = false
|
|
i.truncatedSpan = Span{}
|
|
if i.span == nil {
|
|
i.err = firstError(i.err, i.keyspanIter.Error())
|
|
return
|
|
}
|
|
if invariants.Enabled {
|
|
if err := i.keyspanIter.Error(); err != nil {
|
|
panic(errors.WithSecondaryError(
|
|
errors.AssertionFailedf("pebble: %T keyspan iterator returned non-nil span %s while iter has error", i.keyspanIter, i.span),
|
|
err))
|
|
}
|
|
}
|
|
|
|
// Check the lower bound if we have one.
|
|
if i.lower != nil && i.cmp(i.span.End, i.lower) <= 0 {
|
|
i.span = nil
|
|
return
|
|
}
|
|
|
|
// TODO(jackson): The key comparisons below truncate bounds whenever the
|
|
// keyspan iterator is repositioned. We could perform this lazily, and do it
|
|
// the first time the user actually asks for this span's bounds in
|
|
// SpanBounds. This would reduce work in the case where there's no span
|
|
// covering the point and the keyspan iterator is non-empty.
|
|
|
|
// NB: These truncations don't require setting `keyspanMarkerTruncated`:
|
|
// That flag only applies to truncated span marker keys.
|
|
if i.lower != nil && i.cmp(i.span.Start, i.lower) < 0 {
|
|
i.truncated = true
|
|
i.truncatedSpan = *i.span
|
|
i.truncatedSpan.Start = i.lower
|
|
}
|
|
if i.upper != nil && i.cmp(i.upper, i.span.End) < 0 {
|
|
if !i.truncated {
|
|
i.truncated = true
|
|
i.truncatedSpan = *i.span
|
|
}
|
|
i.truncatedSpan.End = i.upper
|
|
}
|
|
if i.truncated && i.comparer.Equal(i.truncatedSpan.Start, i.truncatedSpan.End) {
|
|
i.span = nil
|
|
}
|
|
}
|
|
|
|
func (i *InterleavingIter) yieldNil() (*base.InternalKey, base.LazyValue) {
|
|
i.withinSpan = false
|
|
i.clearMask()
|
|
return i.verify(nil, base.LazyValue{})
|
|
}
|
|
|
|
func (i *InterleavingIter) yieldPointKey() (*base.InternalKey, base.LazyValue) {
|
|
return i.verify(i.pointKey, i.pointVal)
|
|
}
|
|
|
|
func (i *InterleavingIter) yieldSyntheticSpanMarker(
|
|
lowerBound []byte,
|
|
) (*base.InternalKey, base.LazyValue) {
|
|
i.spanMarker.UserKey = i.startKey()
|
|
i.spanMarker.Trailer = base.MakeTrailer(base.InternalKeySeqNumMax, i.span.Keys[0].Kind())
|
|
|
|
// Truncate the key we return to our lower bound if we have one. Note that
|
|
// we use the lowerBound function parameter, not i.lower. The lowerBound
|
|
// argument is guaranteed to be ≥ i.lower. It may be equal to the SetBounds
|
|
// lower bound, or it could come from a SeekGE or SeekPrefixGE search key.
|
|
if lowerBound != nil && i.cmp(lowerBound, i.startKey()) > 0 {
|
|
// Truncating to the lower bound may violate the upper bound if
|
|
// lowerBound == i.upper. For example, a SeekGE(k) uses k as a lower
|
|
// bound for truncating a span. The span a-z will be truncated to [k,
|
|
// z). If i.upper == k, we'd mistakenly try to return a span [k, k), an
|
|
// invariant violation.
|
|
if i.comparer.Equal(lowerBound, i.upper) {
|
|
return i.yieldNil()
|
|
}
|
|
|
|
// If the lowerBound argument came from a SeekGE or SeekPrefixGE
|
|
// call, and it may be backed by a user-provided byte slice that is not
|
|
// guaranteed to be stable.
|
|
//
|
|
// If the lowerBound argument is the lower bound set by SetBounds,
|
|
// Pebble owns the slice's memory. However, consider two successive
|
|
// calls to SetBounds(). The second may overwrite the lower bound.
|
|
// Although the external contract requires a seek after a SetBounds,
|
|
// Pebble's tests don't always. For this reason and to simplify
|
|
// reasoning around lifetimes, always copy the bound into keyBuf when
|
|
// truncating.
|
|
i.keyBuf = append(i.keyBuf[:0], lowerBound...)
|
|
i.spanMarker.UserKey = i.keyBuf
|
|
i.spanMarkerTruncated = true
|
|
}
|
|
i.maybeUpdateMask()
|
|
return i.verify(&i.spanMarker, base.LazyValue{})
|
|
}
|
|
|
|
func (i *InterleavingIter) disablePrefixMode() {
|
|
if i.prefix != nil {
|
|
i.prefix = nil
|
|
// Clear the existing span. It may not hold the true end bound of the
|
|
// underlying span.
|
|
i.span = nil
|
|
}
|
|
}
|
|
|
|
func (i *InterleavingIter) verify(
|
|
k *base.InternalKey, v base.LazyValue,
|
|
) (*base.InternalKey, base.LazyValue) {
|
|
// Wrap the entire function body in the invariants build tag, so that
|
|
// production builds elide this entire function.
|
|
if invariants.Enabled {
|
|
switch {
|
|
case i.dir == -1 && i.spanMarkerTruncated:
|
|
panic("pebble: invariant violation: truncated span key in reverse iteration")
|
|
case k != nil && i.lower != nil && i.cmp(k.UserKey, i.lower) < 0:
|
|
panic("pebble: invariant violation: key < lower bound")
|
|
case k != nil && i.upper != nil && i.cmp(k.UserKey, i.upper) >= 0:
|
|
panic("pebble: invariant violation: key ≥ upper bound")
|
|
case i.err != nil && k != nil:
|
|
panic("pebble: invariant violation: accumulated error swallowed")
|
|
case i.err == nil && i.pointIter.Error() != nil:
|
|
panic("pebble: invariant violation: pointIter swallowed")
|
|
case i.err == nil && i.keyspanIter.Error() != nil:
|
|
panic("pebble: invariant violation: keyspanIter error swallowed")
|
|
}
|
|
}
|
|
return k, v
|
|
}
|
|
|
|
func (i *InterleavingIter) savedKeyspan() {
|
|
i.spanMarkerTruncated = false
|
|
i.maskSpanChangedCalled = false
|
|
}
|
|
|
|
// updateMask updates the current mask, if a mask is configured and the mask
|
|
// hasn't been updated with the current keyspan yet.
|
|
func (i *InterleavingIter) maybeUpdateMask() {
|
|
switch {
|
|
case i.mask == nil, i.maskSpanChangedCalled:
|
|
return
|
|
case !i.withinSpan || i.span.Empty():
|
|
i.clearMask()
|
|
case i.truncated:
|
|
i.mask.SpanChanged(&i.truncatedSpan)
|
|
i.maskSpanChangedCalled = true
|
|
default:
|
|
i.mask.SpanChanged(i.span)
|
|
i.maskSpanChangedCalled = true
|
|
}
|
|
}
|
|
|
|
// clearMask clears the current mask, if a mask is configured and no mask should
|
|
// be active.
|
|
func (i *InterleavingIter) clearMask() {
|
|
if i.mask != nil {
|
|
i.maskSpanChangedCalled = false
|
|
i.mask.SpanChanged(nil)
|
|
}
|
|
}
|
|
|
|
func (i *InterleavingIter) startKey() []byte {
|
|
if i.truncated {
|
|
return i.truncatedSpan.Start
|
|
}
|
|
return i.span.Start
|
|
}
|
|
|
|
func (i *InterleavingIter) savePoint(key *base.InternalKey, value base.LazyValue) {
|
|
i.pointKey, i.pointVal = key, value
|
|
if key == nil {
|
|
i.err = firstError(i.err, i.pointIter.Error())
|
|
}
|
|
if invariants.Enabled {
|
|
if err := i.pointIter.Error(); key != nil && err != nil {
|
|
panic(errors.WithSecondaryError(
|
|
errors.AssertionFailedf("pebble: %T point iterator returned non-nil key %q while iter has error", i.pointIter, key),
|
|
err))
|
|
}
|
|
}
|
|
}
|
|
|
|
// Span returns the span covering the last key returned, if any. A span key is
|
|
// considered to 'cover' a key if the key falls within the span's user key
|
|
// bounds. The returned span is owned by the InterleavingIter. The caller is
|
|
// responsible for copying if stability is required.
|
|
//
|
|
// Span will never return an invalid or empty span.
|
|
func (i *InterleavingIter) Span() *Span {
|
|
if !i.withinSpan || len(i.span.Keys) == 0 {
|
|
return nil
|
|
} else if i.truncated {
|
|
return &i.truncatedSpan
|
|
}
|
|
return i.span
|
|
}
|
|
|
|
// SetBounds implements (base.InternalIterator).SetBounds.
|
|
func (i *InterleavingIter) SetBounds(lower, upper []byte) {
|
|
i.lower, i.upper = lower, upper
|
|
i.pointIter.SetBounds(lower, upper)
|
|
i.Invalidate()
|
|
}
|
|
|
|
// SetContext implements (base.InternalIterator).SetContext.
|
|
func (i *InterleavingIter) SetContext(ctx context.Context) {
|
|
i.pointIter.SetContext(ctx)
|
|
}
|
|
|
|
// Invalidate invalidates the interleaving iterator's current position, clearing
|
|
// its state. This prevents optimizations such as reusing the current span on
|
|
// seek.
|
|
func (i *InterleavingIter) Invalidate() {
|
|
i.span = nil
|
|
i.pointKey = nil
|
|
i.pointVal = base.LazyValue{}
|
|
}
|
|
|
|
// Error implements (base.InternalIterator).Error.
|
|
func (i *InterleavingIter) Error() error {
|
|
return i.err
|
|
}
|
|
|
|
// Close implements (base.InternalIterator).Close.
|
|
func (i *InterleavingIter) Close() error {
|
|
perr := i.pointIter.Close()
|
|
rerr := i.keyspanIter.Close()
|
|
return firstError(perr, rerr)
|
|
}
|
|
|
|
// String implements (base.InternalIterator).String.
|
|
func (i *InterleavingIter) String() string {
|
|
return fmt.Sprintf("keyspan-interleaving(%q)", i.pointIter.String())
|
|
}
|
|
|
|
func firstError(err0, err1 error) error {
|
|
if err0 != nil {
|
|
return err0
|
|
}
|
|
return err1
|
|
}
|