mirror of
https://source.quilibrium.com/quilibrium/ceremonyclient.git
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821 lines
32 KiB
Go
821 lines
32 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 sstable
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import (
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"encoding/binary"
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"fmt"
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"math"
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"sync"
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"unsafe"
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"github.com/cockroachdb/pebble/internal/base"
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"github.com/cockroachdb/pebble/internal/rangekey"
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)
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// Block properties are an optional user-facing feature that can be used to
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// filter data blocks (and whole sstables) from an Iterator before they are
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// loaded. They do not apply to range delete blocks. These are expected to
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// very concisely represent a set of some attribute value contained within the
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// key or value, such that the set includes all the attribute values in the
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// block. This has some similarities with OLAP pruning approaches that
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// maintain min-max attribute values for some column (which concisely
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// represent a set), that is then used to prune at query time. In Pebble's
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// case, data blocks are small, typically 25-50KB, so these properties should
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// reduce their precision in order to be concise -- a good rule of thumb is to
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// not consume more than 50-100 bytes across all properties maintained for a
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// block, i.e., a 500x reduction compared to loading the data block.
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//
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// A block property must be assigned a unique name, which is encoded and
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// stored in the sstable. This name must be unique among all user-properties
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// encoded in an sstable.
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//
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// A property is represented as a []byte. A nil value or empty byte slice are
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// considered semantically identical. The caller is free to choose the
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// semantics of an empty byte slice e.g. they could use it to represent the
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// empty set or the universal set, whichever they think is more common and
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// therefore better to encode more concisely. The serialization of the
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// property for the various Finish*() calls in a BlockPropertyCollector
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// implementation should be identical, since the corresponding
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// BlockPropertyFilter implementation is not told the context in which it is
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// deserializing the property.
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//
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// Block properties are more general than table properties and should be
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// preferred over using table properties. A BlockPropertyCollector can achieve
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// identical behavior to table properties by returning the nil slice from
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// FinishDataBlock and FinishIndexBlock, and interpret them as the universal
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// set in BlockPropertyFilter, and return a non-universal set in FinishTable.
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//
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// Block property filtering is nondeterministic because the separation of keys
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// into blocks is nondeterministic. Clients use block-property filters to
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// implement efficient application of a filter F that applies to key-value pairs
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// (abbreviated as kv-filter). Consider correctness defined as surfacing exactly
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// the same key-value pairs that would be surfaced if one applied the filter F
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// above normal iteration. With this correctness definition, block property
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// filtering may introduce two kinds of errors:
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//
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// a) Block property filtering that uses a kv-filter may produce additional
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// key-value pairs that don't satisfy the filter because of the separation
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// of keys into blocks. Clients may remove these extra key-value pairs by
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// re-applying the kv filter while reading results back from Pebble.
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//
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// b) Block property filtering may surface deleted key-value pairs if the
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// kv filter is not a strict function of the key's user key. A block
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// containing k.DEL may be filtered, while a block containing the deleted
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// key k.SET may not be filtered, if the kv filter applies to one but not
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// the other.
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//
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// This error may be avoided trivially by using a kv filter that is a pure
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// function of the user key. A filter that examines values or key kinds
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// requires care to ensure F(k.SET, <value>) = F(k.DEL) = F(k.SINGLEDEL).
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//
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// The combination of range deletions and filtering by table-level properties
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// add another opportunity for deleted point keys to be surfaced. The pebble
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// Iterator stack takes care to correctly apply filtered tables' range deletions
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// to lower tables, preventing this form of nondeterministic error.
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//
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// In addition to the non-determinism discussed in (b), which limits the use
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// of properties over values, we now have support for values that are not
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// stored together with the key, and may not even be retrieved during
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// compactions. If Pebble is configured with such value separation, block
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// properties must only apply to the key, and will be provided a nil value.
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// BlockPropertyCollector is used when writing a sstable.
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//
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// - All calls to Add are included in the next FinishDataBlock, after which
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// the next data block is expected to start.
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//
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// - The index entry generated for the data block, which contains the return
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// value from FinishDataBlock, is not immediately included in the current
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// index block. It is included when AddPrevDataBlockToIndexBlock is called.
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// An alternative would be to return an opaque handle from FinishDataBlock
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// and pass it to a new AddToIndexBlock method, which requires more
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// plumbing, and passing of an interface{} results in a undesirable heap
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// allocation. AddPrevDataBlockToIndexBlock must be called before keys are
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// added to the new data block.
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type BlockPropertyCollector interface {
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// Name returns the name of the block property collector.
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Name() string
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// Add is called with each new entry added to a data block in the sstable.
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// The callee can assume that these are in sorted order.
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Add(key InternalKey, value []byte) error
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// FinishDataBlock is called when all the entries have been added to a
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// data block. Subsequent Add calls will be for the next data block. It
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// returns the property value for the finished block.
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FinishDataBlock(buf []byte) ([]byte, error)
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// AddPrevDataBlockToIndexBlock adds the entry corresponding to the
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// previous FinishDataBlock to the current index block.
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AddPrevDataBlockToIndexBlock()
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// FinishIndexBlock is called when an index block, containing all the
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// key-value pairs since the last FinishIndexBlock, will no longer see new
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// entries. It returns the property value for the index block.
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FinishIndexBlock(buf []byte) ([]byte, error)
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// FinishTable is called when the sstable is finished, and returns the
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// property value for the sstable.
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FinishTable(buf []byte) ([]byte, error)
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}
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// SuffixReplaceableBlockCollector is an extension to the BlockPropertyCollector
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// interface that allows a block property collector to indicate that it supports
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// being *updated* during suffix replacement, i.e. when an existing SST in which
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// all keys have the same key suffix is updated to have a new suffix.
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//
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// A collector which supports being updated in such cases must be able to derive
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// its updated value from its old value and the change being made to the suffix,
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// without needing to be passed each updated K/V.
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//
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// For example, a collector that only inspects values would can simply copy its
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// previously computed property as-is, since key-suffix replacement does not
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// change values, while a collector that depends only on key suffixes, like one
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// which collected mvcc-timestamp bounds from timestamp-suffixed keys, can just
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// set its new bounds from the new suffix, as it is common to all keys, without
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// needing to recompute it from every key.
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//
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// An implementation of DataBlockIntervalCollector can also implement this
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// interface, in which case the BlockPropertyCollector returned by passing it to
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// NewBlockIntervalCollector will also implement this interface automatically.
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type SuffixReplaceableBlockCollector interface {
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// UpdateKeySuffixes is called when a block is updated to change the suffix of
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// all keys in the block, and is passed the old value for that prop, if any,
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// for that block as well as the old and new suffix.
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UpdateKeySuffixes(oldProp []byte, oldSuffix, newSuffix []byte) error
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}
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// BlockPropertyFilter is used in an Iterator to filter sstables and blocks
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// within the sstable. It should not maintain any per-sstable state, and must
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// be thread-safe.
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type BlockPropertyFilter = base.BlockPropertyFilter
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// BoundLimitedBlockPropertyFilter implements the block-property filter but
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// imposes an additional constraint on its usage, requiring that only blocks
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// containing exclusively keys between its lower and upper bounds may be
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// filtered. The bounds may be change during iteration, so the filter doesn't
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// expose the bounds, instead implementing KeyIsWithin[Lower,Upper]Bound methods
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// for performing bound comparisons.
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//
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// To be used, a BoundLimitedBlockPropertyFilter must be supplied directly
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// through NewBlockPropertiesFilterer's dedicated parameter. If supplied through
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// the ordinary slice of block property filters, this filter's bounds will be
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// ignored.
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//
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// The current [lower,upper) bounds of the filter are unknown, because they may
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// be changing. During forward iteration the lower bound is externally
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// guaranteed, meaning Intersects only returns false if the sstable iterator is
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// already known to be positioned at a key ≥ lower. The sstable iterator is then
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// only responsible for ensuring filtered blocks also meet the upper bound, and
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// should only allow a block to be filtered if all its keys are < upper. The
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// sstable iterator may invoke KeyIsWithinUpperBound(key) to perform this check,
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// where key is an inclusive upper bound on the block's keys.
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//
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// During backward iteration the upper bound is externally guaranteed, and
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// Intersects only returns false if the sstable iterator is already known to be
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// positioned at a key < upper. The sstable iterator is responsible for ensuring
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// filtered blocks also meet the lower bound, enforcing that a block is only
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// filtered if all its keys are ≥ lower. This check is made through passing the
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// block's inclusive lower bound to KeyIsWithinLowerBound.
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//
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// Implementations may become active or inactive through implementing Intersects
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// to return true whenever the filter is disabled.
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//
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// Usage of BoundLimitedBlockPropertyFilter is subtle, and Pebble consumers
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// should not implement this interface directly. This interface is an internal
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// detail in the implementation of block-property range-key masking.
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type BoundLimitedBlockPropertyFilter interface {
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BlockPropertyFilter
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// KeyIsWithinLowerBound tests whether the provided internal key falls
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// within the current lower bound of the filter. A true return value
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// indicates that the filter may be used to filter blocks that exclusively
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// contain keys ≥ `key`, so long as the blocks' keys also satisfy the upper
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// bound.
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KeyIsWithinLowerBound(key []byte) bool
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// KeyIsWithinUpperBound tests whether the provided internal key falls
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// within the current upper bound of the filter. A true return value
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// indicates that the filter may be used to filter blocks that exclusively
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// contain keys ≤ `key`, so long as the blocks' keys also satisfy the lower
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// bound.
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KeyIsWithinUpperBound(key []byte) bool
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}
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// BlockIntervalCollector is a helper implementation of BlockPropertyCollector
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// for users who want to represent a set of the form [lower,upper) where both
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// lower and upper are uint64, and lower <= upper.
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//
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// The set is encoded as:
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// - Two varint integers, (lower,upper-lower), when upper-lower > 0
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// - Nil, when upper-lower=0
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//
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// Users must not expect this to preserve differences between empty sets --
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// they will all get turned into the semantically equivalent [0,0).
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//
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// A BlockIntervalCollector that collects over point and range keys needs to
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// have both the point and range DataBlockIntervalCollector specified, since
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// point and range keys are fed to the BlockIntervalCollector in an interleaved
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// fashion, independently of one another. This also implies that the
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// DataBlockIntervalCollectors for point and range keys should be references to
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// independent instances, rather than references to the same collector, as point
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// and range keys are tracked independently.
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type BlockIntervalCollector struct {
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name string
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points DataBlockIntervalCollector
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ranges DataBlockIntervalCollector
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blockInterval interval
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indexInterval interval
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tableInterval interval
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}
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var _ BlockPropertyCollector = &BlockIntervalCollector{}
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// DataBlockIntervalCollector is the interface used by BlockIntervalCollector
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// that contains the actual logic pertaining to the property. It only
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// maintains state for the current data block, and resets that state in
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// FinishDataBlock. This interface can be used to reduce parsing costs.
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type DataBlockIntervalCollector interface {
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// Add is called with each new entry added to a data block in the sstable.
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// The callee can assume that these are in sorted order.
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Add(key InternalKey, value []byte) error
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// FinishDataBlock is called when all the entries have been added to a
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// data block. Subsequent Add calls will be for the next data block. It
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// returns the [lower, upper) for the finished block.
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FinishDataBlock() (lower uint64, upper uint64, err error)
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}
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// NewBlockIntervalCollector constructs a BlockIntervalCollector with the given
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// name. The BlockIntervalCollector makes use of the given point and range key
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// DataBlockIntervalCollectors when encountering point and range keys,
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// respectively.
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//
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// The caller may pass a nil DataBlockIntervalCollector for one of the point or
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// range key collectors, in which case keys of those types will be ignored. This
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// allows for flexible construction of BlockIntervalCollectors that operate on
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// just point keys, just range keys, or both point and range keys.
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//
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// If both point and range keys are to be tracked, two independent collectors
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// should be provided, rather than the same collector passed in twice (see the
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// comment on BlockIntervalCollector for more detail)
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func NewBlockIntervalCollector(
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name string, pointCollector, rangeCollector DataBlockIntervalCollector,
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) BlockPropertyCollector {
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if pointCollector == nil && rangeCollector == nil {
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panic("sstable: at least one interval collector must be provided")
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}
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bic := BlockIntervalCollector{
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name: name,
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points: pointCollector,
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ranges: rangeCollector,
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}
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if _, ok := pointCollector.(SuffixReplaceableBlockCollector); ok {
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return &suffixReplacementBlockCollectorWrapper{bic}
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}
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return &bic
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}
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// Name implements the BlockPropertyCollector interface.
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func (b *BlockIntervalCollector) Name() string {
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return b.name
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}
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// Add implements the BlockPropertyCollector interface.
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func (b *BlockIntervalCollector) Add(key InternalKey, value []byte) error {
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if rangekey.IsRangeKey(key.Kind()) {
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if b.ranges != nil {
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return b.ranges.Add(key, value)
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}
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} else if b.points != nil {
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return b.points.Add(key, value)
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}
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return nil
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}
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// FinishDataBlock implements the BlockPropertyCollector interface.
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func (b *BlockIntervalCollector) FinishDataBlock(buf []byte) ([]byte, error) {
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if b.points == nil {
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return buf, nil
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}
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var err error
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b.blockInterval.lower, b.blockInterval.upper, err = b.points.FinishDataBlock()
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if err != nil {
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return buf, err
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}
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buf = b.blockInterval.encode(buf)
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b.tableInterval.union(b.blockInterval)
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return buf, nil
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}
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// AddPrevDataBlockToIndexBlock implements the BlockPropertyCollector
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// interface.
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func (b *BlockIntervalCollector) AddPrevDataBlockToIndexBlock() {
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b.indexInterval.union(b.blockInterval)
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b.blockInterval = interval{}
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}
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// FinishIndexBlock implements the BlockPropertyCollector interface.
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func (b *BlockIntervalCollector) FinishIndexBlock(buf []byte) ([]byte, error) {
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buf = b.indexInterval.encode(buf)
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b.indexInterval = interval{}
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return buf, nil
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}
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// FinishTable implements the BlockPropertyCollector interface.
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func (b *BlockIntervalCollector) FinishTable(buf []byte) ([]byte, error) {
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// If the collector is tracking range keys, the range key interval is union-ed
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// with the point key interval for the table.
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if b.ranges != nil {
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var rangeInterval interval
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var err error
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rangeInterval.lower, rangeInterval.upper, err = b.ranges.FinishDataBlock()
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if err != nil {
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return buf, err
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}
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b.tableInterval.union(rangeInterval)
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}
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return b.tableInterval.encode(buf), nil
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}
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type interval struct {
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lower uint64
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upper uint64
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}
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func (i interval) encode(buf []byte) []byte {
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if i.lower < i.upper {
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var encoded [binary.MaxVarintLen64 * 2]byte
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n := binary.PutUvarint(encoded[:], i.lower)
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n += binary.PutUvarint(encoded[n:], i.upper-i.lower)
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buf = append(buf, encoded[:n]...)
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}
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return buf
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}
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func (i *interval) decode(buf []byte) error {
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if len(buf) == 0 {
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*i = interval{}
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return nil
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}
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var n int
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i.lower, n = binary.Uvarint(buf)
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if n <= 0 || n >= len(buf) {
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return base.CorruptionErrorf("cannot decode interval from buf %x", buf)
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}
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pos := n
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i.upper, n = binary.Uvarint(buf[pos:])
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pos += n
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if pos != len(buf) || n <= 0 {
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return base.CorruptionErrorf("cannot decode interval from buf %x", buf)
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}
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// Delta decode.
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i.upper += i.lower
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if i.upper < i.lower {
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return base.CorruptionErrorf("unexpected overflow, upper %d < lower %d", i.upper, i.lower)
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}
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return nil
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}
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func (i *interval) union(x interval) {
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if x.lower >= x.upper {
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// x is the empty set.
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return
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}
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if i.lower >= i.upper {
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// i is the empty set.
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*i = x
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return
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}
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// Both sets are non-empty.
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if x.lower < i.lower {
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i.lower = x.lower
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}
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if x.upper > i.upper {
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i.upper = x.upper
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}
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}
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func (i interval) intersects(x interval) bool {
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if i.lower >= i.upper || x.lower >= x.upper {
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// At least one of the sets is empty.
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return false
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}
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// Neither set is empty.
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return i.upper > x.lower && i.lower < x.upper
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}
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type suffixReplacementBlockCollectorWrapper struct {
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BlockIntervalCollector
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}
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// UpdateKeySuffixes implements the SuffixReplaceableBlockCollector interface.
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func (w *suffixReplacementBlockCollectorWrapper) UpdateKeySuffixes(
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oldProp []byte, from, to []byte,
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) error {
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return w.BlockIntervalCollector.points.(SuffixReplaceableBlockCollector).UpdateKeySuffixes(oldProp, from, to)
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}
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// BlockIntervalFilter is an implementation of BlockPropertyFilter when the
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// corresponding collector is a BlockIntervalCollector. That is, the set is of
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// the form [lower, upper).
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type BlockIntervalFilter struct {
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name string
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filterInterval interval
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}
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var _ BlockPropertyFilter = (*BlockIntervalFilter)(nil)
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// NewBlockIntervalFilter constructs a BlockPropertyFilter that filters blocks
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// based on an interval property collected by BlockIntervalCollector and the
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// given [lower, upper) bounds. The given name specifies the
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// BlockIntervalCollector's properties to read.
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func NewBlockIntervalFilter(name string, lower uint64, upper uint64) *BlockIntervalFilter {
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b := new(BlockIntervalFilter)
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b.Init(name, lower, upper)
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return b
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}
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// Init initializes (or re-initializes, clearing previous state) an existing
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// BLockPropertyFilter to filter blocks based on an interval property collected
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// by BlockIntervalCollector and the given [lower, upper) bounds. The given name
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// specifies the BlockIntervalCollector's properties to read.
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func (b *BlockIntervalFilter) Init(name string, lower, upper uint64) {
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*b = BlockIntervalFilter{
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name: name,
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filterInterval: interval{lower: lower, upper: upper},
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}
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}
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// Name implements the BlockPropertyFilter interface.
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func (b *BlockIntervalFilter) Name() string {
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return b.name
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}
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// Intersects implements the BlockPropertyFilter interface.
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func (b *BlockIntervalFilter) Intersects(prop []byte) (bool, error) {
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var i interval
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if err := i.decode(prop); err != nil {
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return false, err
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}
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return i.intersects(b.filterInterval), nil
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}
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// SetInterval adjusts the [lower, upper) bounds used by the filter. It is not
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// generally safe to alter the filter while it's in use, except as part of the
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// implementation of BlockPropertyFilterMask.SetSuffix used for range-key
|
|
// masking.
|
|
func (b *BlockIntervalFilter) SetInterval(lower, upper uint64) {
|
|
b.filterInterval = interval{lower: lower, upper: upper}
|
|
}
|
|
|
|
// When encoding block properties for each block, we cannot afford to encode
|
|
// the name. Instead, the name is mapped to a shortID, in the scope of that
|
|
// sstable, and the shortID is encoded. Since we use a uint8, there is a limit
|
|
// of 256 block property collectors per sstable.
|
|
type shortID uint8
|
|
|
|
type blockPropertiesEncoder struct {
|
|
propsBuf []byte
|
|
scratch []byte
|
|
}
|
|
|
|
func (e *blockPropertiesEncoder) getScratchForProp() []byte {
|
|
return e.scratch[:0]
|
|
}
|
|
|
|
func (e *blockPropertiesEncoder) resetProps() {
|
|
e.propsBuf = e.propsBuf[:0]
|
|
}
|
|
|
|
func (e *blockPropertiesEncoder) addProp(id shortID, scratch []byte) {
|
|
const lenID = 1
|
|
lenProp := uvarintLen(uint32(len(scratch)))
|
|
n := lenID + lenProp + len(scratch)
|
|
if cap(e.propsBuf)-len(e.propsBuf) < n {
|
|
size := len(e.propsBuf) + 2*n
|
|
if size < 2*cap(e.propsBuf) {
|
|
size = 2 * cap(e.propsBuf)
|
|
}
|
|
buf := make([]byte, len(e.propsBuf), size)
|
|
copy(buf, e.propsBuf)
|
|
e.propsBuf = buf
|
|
}
|
|
pos := len(e.propsBuf)
|
|
b := e.propsBuf[pos : pos+lenID]
|
|
b[0] = byte(id)
|
|
pos += lenID
|
|
b = e.propsBuf[pos : pos+lenProp]
|
|
n = binary.PutUvarint(b, uint64(len(scratch)))
|
|
pos += n
|
|
b = e.propsBuf[pos : pos+len(scratch)]
|
|
pos += len(scratch)
|
|
copy(b, scratch)
|
|
e.propsBuf = e.propsBuf[0:pos]
|
|
e.scratch = scratch
|
|
}
|
|
|
|
func (e *blockPropertiesEncoder) unsafeProps() []byte {
|
|
return e.propsBuf
|
|
}
|
|
|
|
func (e *blockPropertiesEncoder) props() []byte {
|
|
buf := make([]byte, len(e.propsBuf))
|
|
copy(buf, e.propsBuf)
|
|
return buf
|
|
}
|
|
|
|
type blockPropertiesDecoder struct {
|
|
props []byte
|
|
}
|
|
|
|
func (d *blockPropertiesDecoder) done() bool {
|
|
return len(d.props) == 0
|
|
}
|
|
|
|
// REQUIRES: !done()
|
|
func (d *blockPropertiesDecoder) next() (id shortID, prop []byte, err error) {
|
|
const lenID = 1
|
|
id = shortID(d.props[0])
|
|
propLen, m := binary.Uvarint(d.props[lenID:])
|
|
n := lenID + m
|
|
if m <= 0 || propLen == 0 || (n+int(propLen)) > len(d.props) {
|
|
return 0, nil, base.CorruptionErrorf("corrupt block property length")
|
|
}
|
|
prop = d.props[n : n+int(propLen)]
|
|
d.props = d.props[n+int(propLen):]
|
|
return id, prop, nil
|
|
}
|
|
|
|
// BlockPropertiesFilterer provides filtering support when reading an sstable
|
|
// in the context of an iterator that has a slice of BlockPropertyFilters.
|
|
// After the call to NewBlockPropertiesFilterer, the caller must call
|
|
// IntersectsUserPropsAndFinishInit to check if the sstable intersects with
|
|
// the filters. If it does intersect, this function also finishes initializing
|
|
// the BlockPropertiesFilterer using the shortIDs for the relevant filters.
|
|
// Subsequent checks for relevance of a block should use the intersects
|
|
// method.
|
|
type BlockPropertiesFilterer struct {
|
|
filters []BlockPropertyFilter
|
|
// Maps shortID => index in filters. This can be sparse, and shortIDs for
|
|
// which there is no filter are represented with an index of -1. The
|
|
// length of this can be shorter than the shortIDs allocated in the
|
|
// sstable. e.g. if the sstable used shortIDs 0, 1, 2, 3, and the iterator
|
|
// has two filters, corresponding to shortIDs 2, 0, this would be:
|
|
// len(shortIDToFiltersIndex)==3, 0=>1, 1=>-1, 2=>0.
|
|
shortIDToFiltersIndex []int
|
|
|
|
// boundLimitedFilter, if non-nil, holds a single block-property filter with
|
|
// additional constraints on its filtering. A boundLimitedFilter may only
|
|
// filter blocks that are wholly contained within its bounds. During forward
|
|
// iteration the lower bound (and during backward iteration the upper bound)
|
|
// must be externally guaranteed, with Intersects only returning false if
|
|
// that bound is met. The opposite bound is verified during iteration by the
|
|
// sstable iterator.
|
|
//
|
|
// boundLimitedFilter is permitted to be defined on a property (`Name()`)
|
|
// for which another filter exists in filters. In this case both filters
|
|
// will be consulted, and either filter may exclude block(s). Only a single
|
|
// bound-limited block-property filter may be set.
|
|
//
|
|
// The boundLimitedShortID field contains the shortID of the filter's
|
|
// property within the sstable. It's set to -1 if the property was not
|
|
// collected when the table was built.
|
|
boundLimitedFilter BoundLimitedBlockPropertyFilter
|
|
boundLimitedShortID int
|
|
}
|
|
|
|
var blockPropertiesFiltererPool = sync.Pool{
|
|
New: func() interface{} {
|
|
return &BlockPropertiesFilterer{}
|
|
},
|
|
}
|
|
|
|
// newBlockPropertiesFilterer returns a partially initialized filterer. To complete
|
|
// initialization, call IntersectsUserPropsAndFinishInit.
|
|
func newBlockPropertiesFilterer(
|
|
filters []BlockPropertyFilter, limited BoundLimitedBlockPropertyFilter,
|
|
) *BlockPropertiesFilterer {
|
|
filterer := blockPropertiesFiltererPool.Get().(*BlockPropertiesFilterer)
|
|
*filterer = BlockPropertiesFilterer{
|
|
filters: filters,
|
|
shortIDToFiltersIndex: filterer.shortIDToFiltersIndex[:0],
|
|
boundLimitedFilter: limited,
|
|
boundLimitedShortID: -1,
|
|
}
|
|
return filterer
|
|
}
|
|
|
|
func releaseBlockPropertiesFilterer(filterer *BlockPropertiesFilterer) {
|
|
*filterer = BlockPropertiesFilterer{
|
|
shortIDToFiltersIndex: filterer.shortIDToFiltersIndex[:0],
|
|
}
|
|
blockPropertiesFiltererPool.Put(filterer)
|
|
}
|
|
|
|
// IntersectsTable evaluates the provided block-property filter against the
|
|
// provided set of table-level properties. If there is no intersection between
|
|
// the filters and the table or an error is encountered, IntersectsTable returns
|
|
// a nil filterer (and possibly an error). If there is an intersection,
|
|
// IntersectsTable returns a non-nil filterer that may be used by an iterator
|
|
// reading the table.
|
|
func IntersectsTable(
|
|
filters []BlockPropertyFilter,
|
|
limited BoundLimitedBlockPropertyFilter,
|
|
userProperties map[string]string,
|
|
) (*BlockPropertiesFilterer, error) {
|
|
f := newBlockPropertiesFilterer(filters, limited)
|
|
ok, err := f.intersectsUserPropsAndFinishInit(userProperties)
|
|
if !ok || err != nil {
|
|
releaseBlockPropertiesFilterer(f)
|
|
return nil, err
|
|
}
|
|
return f, nil
|
|
}
|
|
|
|
// intersectsUserPropsAndFinishInit is called with the user properties map for
|
|
// the sstable and returns whether the sstable intersects the filters. It
|
|
// additionally initializes the shortIDToFiltersIndex for the filters that are
|
|
// relevant to this sstable.
|
|
func (f *BlockPropertiesFilterer) intersectsUserPropsAndFinishInit(
|
|
userProperties map[string]string,
|
|
) (bool, error) {
|
|
for i := range f.filters {
|
|
props, ok := userProperties[f.filters[i].Name()]
|
|
if !ok {
|
|
// Collector was not used when writing this file, so it is
|
|
// considered intersecting.
|
|
continue
|
|
}
|
|
if len(props) < 1 {
|
|
return false, base.CorruptionErrorf(
|
|
"block properties for %s is corrupted", f.filters[i].Name())
|
|
}
|
|
shortID := shortID(props[0])
|
|
{
|
|
// Use an unsafe conversion to avoid allocating. Intersects() is not
|
|
// supposed to modify the given slice.
|
|
// Note that unsafe.StringData only works if the string is not empty
|
|
// (which we already checked).
|
|
byteProps := unsafe.Slice(unsafe.StringData(props), len(props))
|
|
intersects, err := f.filters[i].Intersects(byteProps[1:])
|
|
if err != nil || !intersects {
|
|
return false, err
|
|
}
|
|
}
|
|
// Intersects the sstable, so need to use this filter when
|
|
// deciding whether to read blocks.
|
|
n := len(f.shortIDToFiltersIndex)
|
|
if n <= int(shortID) {
|
|
if cap(f.shortIDToFiltersIndex) <= int(shortID) {
|
|
index := make([]int, shortID+1, 2*(shortID+1))
|
|
copy(index, f.shortIDToFiltersIndex)
|
|
f.shortIDToFiltersIndex = index
|
|
} else {
|
|
f.shortIDToFiltersIndex = f.shortIDToFiltersIndex[:shortID+1]
|
|
}
|
|
for j := n; j < int(shortID); j++ {
|
|
f.shortIDToFiltersIndex[j] = -1
|
|
}
|
|
}
|
|
f.shortIDToFiltersIndex[shortID] = i
|
|
}
|
|
if f.boundLimitedFilter == nil {
|
|
return true, nil
|
|
}
|
|
|
|
// There's a bound-limited filter. Find its shortID. It's possible that
|
|
// there's an existing filter in f.filters on the same property. That's
|
|
// okay. Both filters will be consulted whenever a relevant prop is decoded.
|
|
props, ok := userProperties[f.boundLimitedFilter.Name()]
|
|
if !ok {
|
|
// The collector was not used when writing this file, so it's
|
|
// intersecting. We leave f.boundLimitedShortID=-1, so the filter will
|
|
// be unused within this file.
|
|
return true, nil
|
|
}
|
|
if len(props) < 1 {
|
|
return false, base.CorruptionErrorf(
|
|
"block properties for %s is corrupted", f.boundLimitedFilter.Name())
|
|
}
|
|
f.boundLimitedShortID = int(props[0])
|
|
|
|
// We don't check for table-level intersection for the bound-limited filter.
|
|
// The bound-limited filter is treated as vacuously intersecting.
|
|
//
|
|
// NB: If a block-property filter needs to be toggled inactive/active, it
|
|
// should be implemented within the Intersects implementation.
|
|
//
|
|
// TODO(jackson): We could filter at the table-level by threading the table
|
|
// smallest and largest bounds here.
|
|
|
|
// The bound-limited filter isn't included in shortIDToFiltersIndex.
|
|
//
|
|
// When determining intersection, we decode props only up to the shortID
|
|
// len(shortIDToFiltersIndex). If f.limitedShortID is greater than any of
|
|
// the existing filters' shortIDs, we need to grow shortIDToFiltersIndex.
|
|
// Growing the index with -1s ensures we're able to consult the index
|
|
// without length checks.
|
|
if n := len(f.shortIDToFiltersIndex); n <= f.boundLimitedShortID {
|
|
if cap(f.shortIDToFiltersIndex) <= f.boundLimitedShortID {
|
|
index := make([]int, f.boundLimitedShortID+1)
|
|
copy(index, f.shortIDToFiltersIndex)
|
|
f.shortIDToFiltersIndex = index
|
|
} else {
|
|
f.shortIDToFiltersIndex = f.shortIDToFiltersIndex[:f.boundLimitedShortID+1]
|
|
}
|
|
for j := n; j <= f.boundLimitedShortID; j++ {
|
|
f.shortIDToFiltersIndex[j] = -1
|
|
}
|
|
}
|
|
return true, nil
|
|
}
|
|
|
|
type intersectsResult int8
|
|
|
|
const (
|
|
blockIntersects intersectsResult = iota
|
|
blockExcluded
|
|
// blockMaybeExcluded is returned by BlockPropertiesFilterer.intersects when
|
|
// no filters unconditionally exclude the block, but the bound-limited block
|
|
// property filter will exclude it if the block's bounds fall within the
|
|
// filter's current bounds. See the reader's
|
|
// {single,two}LevelIterator.resolveMaybeExcluded methods.
|
|
blockMaybeExcluded
|
|
)
|
|
|
|
func (f *BlockPropertiesFilterer) intersects(props []byte) (ret intersectsResult, err error) {
|
|
i := 0
|
|
decoder := blockPropertiesDecoder{props: props}
|
|
ret = blockIntersects
|
|
for i < len(f.shortIDToFiltersIndex) {
|
|
var id int
|
|
var prop []byte
|
|
if !decoder.done() {
|
|
var shortID shortID
|
|
var err error
|
|
shortID, prop, err = decoder.next()
|
|
if err != nil {
|
|
return ret, err
|
|
}
|
|
id = int(shortID)
|
|
} else {
|
|
id = math.MaxUint8 + 1
|
|
}
|
|
for i < len(f.shortIDToFiltersIndex) && id > i {
|
|
// The property for this id is not encoded for this block, but there
|
|
// may still be a filter for this id.
|
|
if intersects, err := f.intersectsFilter(i, nil); err != nil {
|
|
return ret, err
|
|
} else if intersects == blockExcluded {
|
|
return blockExcluded, nil
|
|
} else if intersects == blockMaybeExcluded {
|
|
ret = blockMaybeExcluded
|
|
}
|
|
i++
|
|
}
|
|
if i >= len(f.shortIDToFiltersIndex) {
|
|
return ret, nil
|
|
}
|
|
// INVARIANT: id <= i. And since i is always incremented by 1, id==i.
|
|
if id != i {
|
|
panic(fmt.Sprintf("%d != %d", id, i))
|
|
}
|
|
if intersects, err := f.intersectsFilter(i, prop); err != nil {
|
|
return ret, err
|
|
} else if intersects == blockExcluded {
|
|
return blockExcluded, nil
|
|
} else if intersects == blockMaybeExcluded {
|
|
ret = blockMaybeExcluded
|
|
}
|
|
i++
|
|
}
|
|
// ret == blockIntersects || ret == blockMaybeExcluded
|
|
return ret, nil
|
|
}
|
|
|
|
func (f *BlockPropertiesFilterer) intersectsFilter(i int, prop []byte) (intersectsResult, error) {
|
|
if f.shortIDToFiltersIndex[i] >= 0 {
|
|
intersects, err := f.filters[f.shortIDToFiltersIndex[i]].Intersects(prop)
|
|
if err != nil {
|
|
return blockIntersects, err
|
|
}
|
|
if !intersects {
|
|
return blockExcluded, nil
|
|
}
|
|
}
|
|
if i == f.boundLimitedShortID {
|
|
// The bound-limited filter uses this id.
|
|
//
|
|
// The bound-limited filter only applies within a keyspan interval. We
|
|
// expect the Intersects call to be cheaper than bounds checks. If
|
|
// Intersects determines that there is no intersection, we return
|
|
// `blockMaybeExcluded` if no other bpf unconditionally excludes the
|
|
// block.
|
|
intersects, err := f.boundLimitedFilter.Intersects(prop)
|
|
if err != nil {
|
|
return blockIntersects, err
|
|
} else if !intersects {
|
|
return blockMaybeExcluded, nil
|
|
}
|
|
}
|
|
return blockIntersects, nil
|
|
}
|