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958 lines
33 KiB
Go
958 lines
33 KiB
Go
// Copyright 2022 The LevelDB-Go and Pebble Authors. All rights reserved. Use
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// of this source code is governed by a BSD-style license that can be found in
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// the LICENSE file.
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package sstable
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import (
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"context"
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"encoding/binary"
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"io"
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"sync"
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"unsafe"
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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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"github.com/cockroachdb/pebble/objstorage/objstorageprovider/objiotracing"
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"golang.org/x/exp/rand"
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)
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// Value blocks are supported in TableFormatPebblev3.
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//
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// 1. Motivation and overview
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//
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// Value blocks are a mechanism designed for sstables storing MVCC data, where
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// there can be many versions of a key that need to be kept, but only the
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// latest value is typically read (see the documentation for Comparer.Split
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// regarding MVCC keys). The goal is faster reads. Unlike Pebble versions,
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// which can be eagerly thrown away (except when there are snapshots), MVCC
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// versions are long-lived (e.g. default CockroachDB garbage collection
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// threshold for older versions is 24 hours) and can significantly slow down
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// reads. We have seen CockroachDB production workloads with very slow reads
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// due to:
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// - 100s of versions for each key in a table.
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//
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// - Tables with mostly MVCC garbage consisting of 2 versions per key -- a
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// real key-value pair, followed by a key-value pair whose value (usually
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// with zero byte length) indicates it is an MVCC tombstone.
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//
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// The value blocks mechanism attempts to improve read throughput in these
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// cases when the key size is smaller than the value sizes of older versions.
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// This is done by moving the value of an older version to a value block in a
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// different part of the sstable. This improves spatial locality of the data
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// being read by the workload, which increases caching effectiveness.
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//
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// Additionally, even when the key size is not smaller than the value of older
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// versions (e.g. secondary indexes in CockroachDB), TableFormatPebblev3
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// stores the result of key comparisons done at write time inside the sstable,
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// which makes stepping from one key prefix to the next prefix (i.e., skipping
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// over older versions of a MVCC key) more efficient by avoiding key
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// comparisons and key decoding. See the results in
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// https://github.com/cockroachdb/pebble/pull/2149 and more details in the
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// comment inside BenchmarkIteratorScanNextPrefix. These improvements are also
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// visible in end-to-end CockroachDB tests, as outlined in
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// https://github.com/cockroachdb/cockroach/pull/96652.
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//
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// In TableFormatPebblev3, each SET has a one byte value prefix that tells us
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// whether the value is in-place or in a value block. This 1 byte prefix
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// encodes additional information:
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//
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// - ShortAttribute: This is an attribute of the value. Currently, CockroachDB
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// uses it to represent whether the value is a tombstone or not. This avoids
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// the need to fetch a value from the value block if the caller only wants
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// to figure out whether it is an MVCC tombstone. The length of the value is
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// another attribute that the caller can be interested in, and it is also
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// accessible without reading the value in the value block (see the value
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// handle in the details section).
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//
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// - SET-same-prefix: this enables the aforementioned optimization when
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// stepping from one key prefix to the next key prefix.
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//
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// We further optimize this iteration over prefixes by using the restart
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// points in a block to encode whether the SET at a restart point has the same
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// prefix since the last restart point. This allows us to skip over restart
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// points within the same block. See the comment in blockWriter, and how both
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// SET-same-prefix and the restart point information is used in
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// blockIter.nextPrefixV3.
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//
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// This flexibility of values that are in-place or in value blocks requires
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// flexibility in the iterator interface. The InternalIterator interface
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// returns a LazyValue instead of a byte slice. Additionally, pebble.Iterator
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// allows the caller to ask for a LazyValue. See lazy_value.go for details,
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// including the memory lifetime management.
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//
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// For historical discussions about this feature, see the issue
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// https://github.com/cockroachdb/pebble/issues/1170 and the prototype in
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// https://github.com/cockroachdb/pebble/pull/1443.
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//
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// The code in this file mainly covers value block and related encodings. We
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// discuss these in the next section.
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//
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// 2. Details
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//
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// Note that the notion of the latest value is local to the sstable. It is
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// possible that that latest value has been deleted by a sstable in a higher
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// level, and what is the latest value from the perspective of the whole LSM
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// is an older MVCC version. This only affects performance and not
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// correctness. This local knowledge is also why we continue to store these
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// older versions in the same sstable -- we need to be able to conveniently
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// read them. The code in this file is agnostic to the policy regarding what
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// should be stored in value blocks -- it allows even the latest MVCC version
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// to be stored in a value block. The policy decision in made in the
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// sstable.Writer. See Writer.makeAddPointDecisionV3.
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//
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// Data blocks contain two kinds of SET keys: those with in-place values and
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// those with a value handle. To distinguish these two cases we use a single
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// byte prefix (valuePrefix). This single byte prefix is split into multiple
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// parts, where nb represents information that is encoded in n bits.
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//
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// +---------------+--------------------+-----------+--------------------+
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// | value-kind 2b | SET-same-prefix 1b | unused 2b | short-attribute 3b |
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// +---------------+--------------------+-----------+--------------------+
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//
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// The 2 bit value-kind specifies whether this is an in-place value or a value
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// handle pointing to a value block. We use 2 bits here for future
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// representation of values that are in separate files. The 1 bit
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// SET-same-prefix is true if this key is a SET and is immediately preceded by
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// a SET that shares the same prefix. The 3 bit short-attribute is described
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// in base.ShortAttribute -- it stores user-defined attributes about the
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// value. It is unused for in-place values.
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//
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// Value Handle and Value Blocks:
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// valueHandles refer to values in value blocks. Value blocks are simpler than
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// normal data blocks (that contain key-value pairs, and allow for binary
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// search), which makes them cheap for value retrieval purposes. A valueHandle
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// is a tuple (valueLen, blockNum, offsetInBlock), where blockNum is the 0
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// indexed value block number and offsetInBlock is the byte offset in that
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// block containing the value. The valueHandle.valueLen is included since
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// there are multiple use cases in CockroachDB that need the value length but
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// not the value, for which we can avoid reading the value in the value block
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// (see
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// https://github.com/cockroachdb/pebble/issues/1170#issuecomment-958203245).
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//
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// A value block has a checksum like other blocks, and is optionally
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// compressed. An uncompressed value block is a sequence of values with no
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// separator or length (we rely on the valueHandle to demarcate). The
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// valueHandle.offsetInBlock points to the value, of length
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// valueHandle.valueLen. While writing a sstable, all the (possibly
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// compressed) value blocks need to be held in-memory until they can be
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// written. Value blocks are placed after the "meta rangedel" and "meta range
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// key" blocks since value blocks are considered less likely to be read.
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//
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// Meta Value Index Block:
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// Since the (key, valueHandle) pair are written before there is any knowledge
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// of the byte offset of the value block in the file, or its compressed
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// length, we need another lookup to map the valueHandle.blockNum to the
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// information needed to read it from the file. This information is provided
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// by the "value index block". The "value index block" is referred to by the
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// metaindex block. The design intentionally avoids making the "value index
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// block" a general purpose key-value block, since each caller wants to lookup
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// the information for a particular blockNum (there is no need for SeekGE
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// etc.). Instead, this index block stores a sequence of (blockNum,
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// blockOffset, blockLength) tuples, where the blockNums are consecutive
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// integers, and the tuples are encoded with a fixed width encoding. This
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// allows a reader to find the tuple for block K by looking at the offset
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// K*fixed-width. The fixed width for each field is decided by looking at the
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// maximum value of each of these fields. As a concrete example of a large
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// sstable with many value blocks, we constructed a 100MB sstable with many
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// versions and had 2475 value blocks (~32KB each). This sstable had this
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// tuple encoded using 2+4+2=8 bytes, which means the uncompressed value index
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// block was 2475*8=~19KB, which is modest. Therefore, we don't support more
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// than one value index block. Consider the example of 2 byte blockNum, 4 byte
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// blockOffset and 2 byte blockLen. The value index block will look like:
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//
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// +---------------+------------------+---------------+
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// | blockNum (2B) | blockOffset (4B) | blockLen (2B) |
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// +---------------+------------------+---------------+
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// | 0 | 7,123,456 | 30,000 |
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// +---------------+------------------+---------------+
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// | 1 | 7,153,456 | 20,000 |
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// +---------------+------------------+---------------+
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// | 2 | 7,173,456 | 25,567 |
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// +---------------+------------------+---------------+
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// | .... | ... | ... |
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//
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//
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// The metaindex block contains the valueBlocksIndexHandle which in addition
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// to the BlockHandle also specifies the widths of these tuple fields. In the
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// above example, the
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// valueBlockIndexHandle.{blockNumByteLength,blockOffsetByteLength,blockLengthByteLength}
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// will be (2,4,2).
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// valueHandle is stored with a key when the value is in a value block. This
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// handle is the pointer to that value.
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type valueHandle struct {
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valueLen uint32
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blockNum uint32
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offsetInBlock uint32
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}
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// valuePrefix is the single byte prefix for either the in-place value or the
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// encoded valueHandle. It encoded multiple kinds of information.
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type valuePrefix byte
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const (
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// 2 most-significant bits of valuePrefix encodes the value-kind.
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valueKindMask valuePrefix = '\xC0'
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valueKindIsValueHandle valuePrefix = '\x80'
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valueKindIsInPlaceValue valuePrefix = '\x00'
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// 1 bit indicates SET has same key prefix as immediately preceding key that
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// is also a SET. If the immediately preceding key in the same block is a
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// SET, AND this bit is 0, the prefix must have changed.
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//
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// Note that the current policy of only storing older MVCC versions in value
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// blocks means that valueKindIsValueHandle => SET has same prefix. But no
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// code should rely on this behavior. Also, SET has same prefix does *not*
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// imply valueKindIsValueHandle.
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setHasSameKeyPrefixMask valuePrefix = '\x20'
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// 3 least-significant bits for the user-defined base.ShortAttribute.
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// Undefined for valueKindIsInPlaceValue.
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userDefinedShortAttributeMask valuePrefix = '\x07'
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)
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// valueHandle fields are varint encoded, so maximum 5 bytes each, plus 1 byte
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// for the valuePrefix. This could alternatively be group varint encoded, but
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// experiments were inconclusive
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// (https://github.com/cockroachdb/pebble/pull/1443#issuecomment-1270298802).
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const valueHandleMaxLen = 5*3 + 1
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// Assert blockHandleLikelyMaxLen >= valueHandleMaxLen.
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const _ = uint(blockHandleLikelyMaxLen - valueHandleMaxLen)
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func encodeValueHandle(dst []byte, v valueHandle) int {
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n := 0
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n += binary.PutUvarint(dst[n:], uint64(v.valueLen))
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n += binary.PutUvarint(dst[n:], uint64(v.blockNum))
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n += binary.PutUvarint(dst[n:], uint64(v.offsetInBlock))
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return n
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}
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func makePrefixForValueHandle(setHasSameKeyPrefix bool, attribute base.ShortAttribute) valuePrefix {
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prefix := valueKindIsValueHandle | valuePrefix(attribute)
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if setHasSameKeyPrefix {
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prefix = prefix | setHasSameKeyPrefixMask
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}
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return prefix
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}
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func makePrefixForInPlaceValue(setHasSameKeyPrefix bool) valuePrefix {
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prefix := valueKindIsInPlaceValue
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if setHasSameKeyPrefix {
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prefix = prefix | setHasSameKeyPrefixMask
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}
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return prefix
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}
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func isValueHandle(b valuePrefix) bool {
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return b&valueKindMask == valueKindIsValueHandle
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}
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// REQUIRES: isValueHandle(b)
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func getShortAttribute(b valuePrefix) base.ShortAttribute {
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return base.ShortAttribute(b & userDefinedShortAttributeMask)
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}
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func setHasSamePrefix(b valuePrefix) bool {
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return b&setHasSameKeyPrefixMask == setHasSameKeyPrefixMask
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}
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func decodeLenFromValueHandle(src []byte) (uint32, []byte) {
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ptr := unsafe.Pointer(&src[0])
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var v uint32
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if a := *((*uint8)(ptr)); a < 128 {
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v = uint32(a)
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src = src[1:]
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} else if a, b := a&0x7f, *((*uint8)(unsafe.Pointer(uintptr(ptr) + 1))); b < 128 {
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v = uint32(b)<<7 | uint32(a)
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src = src[2:]
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} else if b, c := b&0x7f, *((*uint8)(unsafe.Pointer(uintptr(ptr) + 2))); c < 128 {
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v = uint32(c)<<14 | uint32(b)<<7 | uint32(a)
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src = src[3:]
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} else if c, d := c&0x7f, *((*uint8)(unsafe.Pointer(uintptr(ptr) + 3))); d < 128 {
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v = uint32(d)<<21 | uint32(c)<<14 | uint32(b)<<7 | uint32(a)
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src = src[4:]
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} else {
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d, e := d&0x7f, *((*uint8)(unsafe.Pointer(uintptr(ptr) + 4)))
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v = uint32(e)<<28 | uint32(d)<<21 | uint32(c)<<14 | uint32(b)<<7 | uint32(a)
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src = src[5:]
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}
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return v, src
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}
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func decodeRemainingValueHandle(src []byte) valueHandle {
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var vh valueHandle
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ptr := unsafe.Pointer(&src[0])
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// Manually inlined uvarint decoding. Saves ~25% in benchmarks. Unrolling
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// a loop for i:=0; i<2; i++, saves ~6%.
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var v uint32
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if a := *((*uint8)(ptr)); a < 128 {
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v = uint32(a)
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ptr = unsafe.Pointer(uintptr(ptr) + 1)
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} else if a, b := a&0x7f, *((*uint8)(unsafe.Pointer(uintptr(ptr) + 1))); b < 128 {
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v = uint32(b)<<7 | uint32(a)
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ptr = unsafe.Pointer(uintptr(ptr) + 2)
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} else if b, c := b&0x7f, *((*uint8)(unsafe.Pointer(uintptr(ptr) + 2))); c < 128 {
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v = uint32(c)<<14 | uint32(b)<<7 | uint32(a)
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ptr = unsafe.Pointer(uintptr(ptr) + 3)
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} else if c, d := c&0x7f, *((*uint8)(unsafe.Pointer(uintptr(ptr) + 3))); d < 128 {
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v = uint32(d)<<21 | uint32(c)<<14 | uint32(b)<<7 | uint32(a)
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ptr = unsafe.Pointer(uintptr(ptr) + 4)
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} else {
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d, e := d&0x7f, *((*uint8)(unsafe.Pointer(uintptr(ptr) + 4)))
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v = uint32(e)<<28 | uint32(d)<<21 | uint32(c)<<14 | uint32(b)<<7 | uint32(a)
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ptr = unsafe.Pointer(uintptr(ptr) + 5)
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}
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vh.blockNum = v
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if a := *((*uint8)(ptr)); a < 128 {
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v = uint32(a)
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} else if a, b := a&0x7f, *((*uint8)(unsafe.Pointer(uintptr(ptr) + 1))); b < 128 {
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v = uint32(b)<<7 | uint32(a)
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} else if b, c := b&0x7f, *((*uint8)(unsafe.Pointer(uintptr(ptr) + 2))); c < 128 {
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v = uint32(c)<<14 | uint32(b)<<7 | uint32(a)
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} else if c, d := c&0x7f, *((*uint8)(unsafe.Pointer(uintptr(ptr) + 3))); d < 128 {
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v = uint32(d)<<21 | uint32(c)<<14 | uint32(b)<<7 | uint32(a)
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} else {
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d, e := d&0x7f, *((*uint8)(unsafe.Pointer(uintptr(ptr) + 4)))
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v = uint32(e)<<28 | uint32(d)<<21 | uint32(c)<<14 | uint32(b)<<7 | uint32(a)
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}
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vh.offsetInBlock = v
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return vh
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}
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func decodeValueHandle(src []byte) valueHandle {
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valLen, src := decodeLenFromValueHandle(src)
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vh := decodeRemainingValueHandle(src)
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vh.valueLen = valLen
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return vh
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}
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// valueBlocksIndexHandle is placed in the metaindex if there are any value
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// blocks. If there are no value blocks, there is no value blocks index, and
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// no entry in the metaindex. Note that the lack of entry in the metaindex
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// should not be used to ascertain whether the values are prefixed, since the
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// former is an emergent property of the data that was written and not known
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// until all the key-value pairs in the sstable are written.
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type valueBlocksIndexHandle struct {
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h BlockHandle
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blockNumByteLength uint8
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blockOffsetByteLength uint8
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blockLengthByteLength uint8
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}
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const valueBlocksIndexHandleMaxLen = blockHandleMaxLenWithoutProperties + 3
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// Assert blockHandleLikelyMaxLen >= valueBlocksIndexHandleMaxLen.
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const _ = uint(blockHandleLikelyMaxLen - valueBlocksIndexHandleMaxLen)
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func encodeValueBlocksIndexHandle(dst []byte, v valueBlocksIndexHandle) int {
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n := encodeBlockHandle(dst, v.h)
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dst[n] = v.blockNumByteLength
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n++
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dst[n] = v.blockOffsetByteLength
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n++
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dst[n] = v.blockLengthByteLength
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n++
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return n
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}
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func decodeValueBlocksIndexHandle(src []byte) (valueBlocksIndexHandle, int, error) {
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var vbih valueBlocksIndexHandle
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var n int
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vbih.h, n = decodeBlockHandle(src)
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if n <= 0 {
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return vbih, 0, errors.Errorf("bad BlockHandle %x", src)
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}
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if len(src) != n+3 {
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return vbih, 0, errors.Errorf("bad BlockHandle %x", src)
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}
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vbih.blockNumByteLength = src[n]
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vbih.blockOffsetByteLength = src[n+1]
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vbih.blockLengthByteLength = src[n+2]
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return vbih, n + 3, nil
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}
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type valueBlocksAndIndexStats struct {
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numValueBlocks uint64
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numValuesInValueBlocks uint64
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// Includes both value blocks and value index block.
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valueBlocksAndIndexSize uint64
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}
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// valueBlockWriter writes a sequence of value blocks, and the value blocks
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// index, for a sstable.
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type valueBlockWriter struct {
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// The configured uncompressed block size and size threshold
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blockSize, blockSizeThreshold int
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// Configured compression.
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compression Compression
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// checksummer with configured checksum type.
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checksummer checksummer
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// Block finished callback.
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blockFinishedFunc func(compressedSize int)
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// buf is the current block being written to (uncompressed).
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buf *blockBuffer
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// compressedBuf is used for compressing the block.
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compressedBuf *blockBuffer
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// Sequence of blocks that are finished.
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blocks []blockAndHandle
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// Cumulative value block bytes written so far.
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totalBlockBytes uint64
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numValues uint64
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}
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type blockAndHandle struct {
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block *blockBuffer
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handle BlockHandle
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compressed bool
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}
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type blockBuffer struct {
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b []byte
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}
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// Pool of block buffers that should be roughly the blockSize.
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var uncompressedValueBlockBufPool = sync.Pool{
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New: func() interface{} {
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return &blockBuffer{}
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},
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}
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// Pool of block buffers for compressed value blocks. These may widely vary in
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// size based on compression ratios.
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var compressedValueBlockBufPool = sync.Pool{
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New: func() interface{} {
|
|
return &blockBuffer{}
|
|
},
|
|
}
|
|
|
|
func releaseToValueBlockBufPool(pool *sync.Pool, b *blockBuffer) {
|
|
// Don't pool buffers larger than 128KB, in case we had some rare large
|
|
// values.
|
|
if len(b.b) > 128*1024 {
|
|
return
|
|
}
|
|
if invariants.Enabled {
|
|
// Set the bytes to a random value. Cap the number of bytes being
|
|
// randomized to prevent test timeouts.
|
|
length := cap(b.b)
|
|
if length > 1000 {
|
|
length = 1000
|
|
}
|
|
b.b = b.b[:length:length]
|
|
rand.Read(b.b)
|
|
}
|
|
pool.Put(b)
|
|
}
|
|
|
|
var valueBlockWriterPool = sync.Pool{
|
|
New: func() interface{} {
|
|
return &valueBlockWriter{}
|
|
},
|
|
}
|
|
|
|
func newValueBlockWriter(
|
|
blockSize int,
|
|
blockSizeThreshold int,
|
|
compression Compression,
|
|
checksumType ChecksumType,
|
|
// compressedSize should exclude the block trailer.
|
|
blockFinishedFunc func(compressedSize int),
|
|
) *valueBlockWriter {
|
|
w := valueBlockWriterPool.Get().(*valueBlockWriter)
|
|
*w = valueBlockWriter{
|
|
blockSize: blockSize,
|
|
blockSizeThreshold: blockSizeThreshold,
|
|
compression: compression,
|
|
checksummer: checksummer{
|
|
checksumType: checksumType,
|
|
},
|
|
blockFinishedFunc: blockFinishedFunc,
|
|
buf: uncompressedValueBlockBufPool.Get().(*blockBuffer),
|
|
compressedBuf: compressedValueBlockBufPool.Get().(*blockBuffer),
|
|
blocks: w.blocks[:0],
|
|
}
|
|
w.buf.b = w.buf.b[:0]
|
|
w.compressedBuf.b = w.compressedBuf.b[:0]
|
|
return w
|
|
}
|
|
|
|
func releaseValueBlockWriter(w *valueBlockWriter) {
|
|
for i := range w.blocks {
|
|
if w.blocks[i].compressed {
|
|
releaseToValueBlockBufPool(&compressedValueBlockBufPool, w.blocks[i].block)
|
|
} else {
|
|
releaseToValueBlockBufPool(&uncompressedValueBlockBufPool, w.blocks[i].block)
|
|
}
|
|
w.blocks[i].block = nil
|
|
}
|
|
if w.buf != nil {
|
|
releaseToValueBlockBufPool(&uncompressedValueBlockBufPool, w.buf)
|
|
}
|
|
if w.compressedBuf != nil {
|
|
releaseToValueBlockBufPool(&compressedValueBlockBufPool, w.compressedBuf)
|
|
}
|
|
*w = valueBlockWriter{
|
|
blocks: w.blocks[:0],
|
|
}
|
|
valueBlockWriterPool.Put(w)
|
|
}
|
|
|
|
func (w *valueBlockWriter) addValue(v []byte) (valueHandle, error) {
|
|
if invariants.Enabled && len(v) == 0 {
|
|
return valueHandle{}, errors.Errorf("cannot write empty value to value block")
|
|
}
|
|
w.numValues++
|
|
blockLen := len(w.buf.b)
|
|
valueLen := len(v)
|
|
if blockLen >= w.blockSize ||
|
|
(blockLen > w.blockSizeThreshold && blockLen+valueLen > w.blockSize) {
|
|
// Block is not currently empty and adding this value will become too big,
|
|
// so finish this block.
|
|
w.compressAndFlush()
|
|
blockLen = len(w.buf.b)
|
|
if invariants.Enabled && blockLen != 0 {
|
|
panic("blockLen of new block should be 0")
|
|
}
|
|
}
|
|
vh := valueHandle{
|
|
valueLen: uint32(valueLen),
|
|
blockNum: uint32(len(w.blocks)),
|
|
offsetInBlock: uint32(blockLen),
|
|
}
|
|
blockLen = int(vh.offsetInBlock + vh.valueLen)
|
|
if cap(w.buf.b) < blockLen {
|
|
size := 2 * cap(w.buf.b)
|
|
if size < 1024 {
|
|
size = 1024
|
|
}
|
|
for size < blockLen {
|
|
size *= 2
|
|
}
|
|
buf := make([]byte, blockLen, size)
|
|
_ = copy(buf, w.buf.b)
|
|
w.buf.b = buf
|
|
} else {
|
|
w.buf.b = w.buf.b[:blockLen]
|
|
}
|
|
buf := w.buf.b[vh.offsetInBlock:]
|
|
n := copy(buf, v)
|
|
if n != len(buf) {
|
|
panic("incorrect length computation")
|
|
}
|
|
return vh, nil
|
|
}
|
|
|
|
func (w *valueBlockWriter) compressAndFlush() {
|
|
// Compress the buffer, discarding the result if the improvement isn't at
|
|
// least 12.5%.
|
|
blockType := noCompressionBlockType
|
|
b := w.buf
|
|
if w.compression != NoCompression {
|
|
blockType, w.compressedBuf.b =
|
|
compressBlock(w.compression, w.buf.b, w.compressedBuf.b[:cap(w.compressedBuf.b)])
|
|
if len(w.compressedBuf.b) < len(w.buf.b)-len(w.buf.b)/8 {
|
|
b = w.compressedBuf
|
|
} else {
|
|
blockType = noCompressionBlockType
|
|
}
|
|
}
|
|
n := len(b.b)
|
|
if n+blockTrailerLen > cap(b.b) {
|
|
block := make([]byte, n+blockTrailerLen)
|
|
copy(block, b.b)
|
|
b.b = block
|
|
} else {
|
|
b.b = b.b[:n+blockTrailerLen]
|
|
}
|
|
b.b[n] = byte(blockType)
|
|
w.computeChecksum(b.b)
|
|
bh := BlockHandle{Offset: w.totalBlockBytes, Length: uint64(n)}
|
|
w.totalBlockBytes += uint64(len(b.b))
|
|
// blockFinishedFunc length excludes the block trailer.
|
|
w.blockFinishedFunc(n)
|
|
compressed := blockType != noCompressionBlockType
|
|
w.blocks = append(w.blocks, blockAndHandle{
|
|
block: b,
|
|
handle: bh,
|
|
compressed: compressed,
|
|
})
|
|
// Handed off a buffer to w.blocks, so need get a new one.
|
|
if compressed {
|
|
w.compressedBuf = compressedValueBlockBufPool.Get().(*blockBuffer)
|
|
} else {
|
|
w.buf = uncompressedValueBlockBufPool.Get().(*blockBuffer)
|
|
}
|
|
w.buf.b = w.buf.b[:0]
|
|
}
|
|
|
|
func (w *valueBlockWriter) computeChecksum(block []byte) {
|
|
n := len(block) - blockTrailerLen
|
|
checksum := w.checksummer.checksum(block[:n], block[n:n+1])
|
|
binary.LittleEndian.PutUint32(block[n+1:], checksum)
|
|
}
|
|
|
|
func (w *valueBlockWriter) finish(
|
|
writer io.Writer, fileOffset uint64,
|
|
) (valueBlocksIndexHandle, valueBlocksAndIndexStats, error) {
|
|
if len(w.buf.b) > 0 {
|
|
w.compressAndFlush()
|
|
}
|
|
n := len(w.blocks)
|
|
if n == 0 {
|
|
return valueBlocksIndexHandle{}, valueBlocksAndIndexStats{}, nil
|
|
}
|
|
largestOffset := uint64(0)
|
|
largestLength := uint64(0)
|
|
for i := range w.blocks {
|
|
_, err := writer.Write(w.blocks[i].block.b)
|
|
if err != nil {
|
|
return valueBlocksIndexHandle{}, valueBlocksAndIndexStats{}, err
|
|
}
|
|
w.blocks[i].handle.Offset += fileOffset
|
|
largestOffset = w.blocks[i].handle.Offset
|
|
if largestLength < w.blocks[i].handle.Length {
|
|
largestLength = w.blocks[i].handle.Length
|
|
}
|
|
}
|
|
vbihOffset := fileOffset + w.totalBlockBytes
|
|
|
|
vbih := valueBlocksIndexHandle{
|
|
h: BlockHandle{
|
|
Offset: vbihOffset,
|
|
},
|
|
blockNumByteLength: uint8(lenLittleEndian(uint64(n - 1))),
|
|
blockOffsetByteLength: uint8(lenLittleEndian(largestOffset)),
|
|
blockLengthByteLength: uint8(lenLittleEndian(largestLength)),
|
|
}
|
|
var err error
|
|
if vbih, err = w.writeValueBlocksIndex(writer, vbih); err != nil {
|
|
return valueBlocksIndexHandle{}, valueBlocksAndIndexStats{}, err
|
|
}
|
|
stats := valueBlocksAndIndexStats{
|
|
numValueBlocks: uint64(n),
|
|
numValuesInValueBlocks: w.numValues,
|
|
valueBlocksAndIndexSize: w.totalBlockBytes + vbih.h.Length + blockTrailerLen,
|
|
}
|
|
return vbih, stats, err
|
|
}
|
|
|
|
func (w *valueBlockWriter) writeValueBlocksIndex(
|
|
writer io.Writer, h valueBlocksIndexHandle,
|
|
) (valueBlocksIndexHandle, error) {
|
|
blockLen :=
|
|
int(h.blockNumByteLength+h.blockOffsetByteLength+h.blockLengthByteLength) * len(w.blocks)
|
|
h.h.Length = uint64(blockLen)
|
|
blockLen += blockTrailerLen
|
|
var buf []byte
|
|
if cap(w.buf.b) < blockLen {
|
|
buf = make([]byte, blockLen)
|
|
w.buf.b = buf
|
|
} else {
|
|
buf = w.buf.b[:blockLen]
|
|
}
|
|
b := buf
|
|
for i := range w.blocks {
|
|
littleEndianPut(uint64(i), b, int(h.blockNumByteLength))
|
|
b = b[int(h.blockNumByteLength):]
|
|
littleEndianPut(w.blocks[i].handle.Offset, b, int(h.blockOffsetByteLength))
|
|
b = b[int(h.blockOffsetByteLength):]
|
|
littleEndianPut(w.blocks[i].handle.Length, b, int(h.blockLengthByteLength))
|
|
b = b[int(h.blockLengthByteLength):]
|
|
}
|
|
if len(b) != blockTrailerLen {
|
|
panic("incorrect length calculation")
|
|
}
|
|
b[0] = byte(noCompressionBlockType)
|
|
w.computeChecksum(buf)
|
|
if _, err := writer.Write(buf); err != nil {
|
|
return valueBlocksIndexHandle{}, err
|
|
}
|
|
return h, nil
|
|
}
|
|
|
|
// littleEndianPut writes v to b using little endian encoding, under the
|
|
// assumption that v can be represented using n bytes.
|
|
func littleEndianPut(v uint64, b []byte, n int) {
|
|
_ = b[n-1] // bounds check
|
|
for i := 0; i < n; i++ {
|
|
b[i] = byte(v)
|
|
v = v >> 8
|
|
}
|
|
}
|
|
|
|
// lenLittleEndian returns the minimum number of bytes needed to encode v
|
|
// using little endian encoding.
|
|
func lenLittleEndian(v uint64) int {
|
|
n := 0
|
|
for i := 0; i < 8; i++ {
|
|
n++
|
|
v = v >> 8
|
|
if v == 0 {
|
|
break
|
|
}
|
|
}
|
|
return n
|
|
}
|
|
|
|
func littleEndianGet(b []byte, n int) uint64 {
|
|
_ = b[n-1] // bounds check
|
|
v := uint64(b[0])
|
|
for i := 1; i < n; i++ {
|
|
v |= uint64(b[i]) << (8 * i)
|
|
}
|
|
return v
|
|
}
|
|
|
|
// UserKeyPrefixBound represents a [Lower,Upper) bound of user key prefixes.
|
|
// If both are nil, there is no bound specified. Else, Compare(Lower,Upper)
|
|
// must be < 0.
|
|
type UserKeyPrefixBound struct {
|
|
// Lower is a lower bound user key prefix.
|
|
Lower []byte
|
|
// Upper is an upper bound user key prefix.
|
|
Upper []byte
|
|
}
|
|
|
|
// IsEmpty returns true iff the bound is empty.
|
|
func (ukb *UserKeyPrefixBound) IsEmpty() bool {
|
|
return len(ukb.Lower) == 0 && len(ukb.Upper) == 0
|
|
}
|
|
|
|
type blockProviderWhenOpen interface {
|
|
readBlockForVBR(
|
|
h BlockHandle, stats *base.InternalIteratorStats,
|
|
) (bufferHandle, error)
|
|
}
|
|
|
|
type blockProviderWhenClosed struct {
|
|
rp ReaderProvider
|
|
r *Reader
|
|
}
|
|
|
|
func (bpwc *blockProviderWhenClosed) open() error {
|
|
var err error
|
|
bpwc.r, err = bpwc.rp.GetReader()
|
|
return err
|
|
}
|
|
|
|
func (bpwc *blockProviderWhenClosed) close() {
|
|
bpwc.rp.Close()
|
|
bpwc.r = nil
|
|
}
|
|
|
|
func (bpwc blockProviderWhenClosed) readBlockForVBR(
|
|
h BlockHandle, stats *base.InternalIteratorStats,
|
|
) (bufferHandle, error) {
|
|
// This is rare, since most block reads happen when the corresponding
|
|
// sstable iterator is open. So we are willing to sacrifice a proper context
|
|
// for tracing.
|
|
//
|
|
// TODO(sumeer): consider fixing this. See
|
|
// https://github.com/cockroachdb/pebble/pull/3065#issue-1991175365 for an
|
|
// alternative.
|
|
ctx := objiotracing.WithBlockType(context.Background(), objiotracing.ValueBlock)
|
|
// TODO(jackson,sumeer): Consider whether to use a buffer pool in this case.
|
|
// The bpwc is not allowed to outlive the iterator tree, so it cannot
|
|
// outlive the buffer pool.
|
|
return bpwc.r.readBlock(
|
|
ctx, h, nil, nil, stats, nil /* iterStats */, nil /* buffer pool */)
|
|
}
|
|
|
|
// ReaderProvider supports the implementation of blockProviderWhenClosed.
|
|
// GetReader and Close can be called multiple times in pairs.
|
|
type ReaderProvider interface {
|
|
GetReader() (r *Reader, err error)
|
|
Close()
|
|
}
|
|
|
|
// TrivialReaderProvider implements ReaderProvider for a Reader that will
|
|
// outlive the top-level iterator in the iterator tree.
|
|
type TrivialReaderProvider struct {
|
|
*Reader
|
|
}
|
|
|
|
var _ ReaderProvider = TrivialReaderProvider{}
|
|
|
|
// GetReader implements ReaderProvider.
|
|
func (trp TrivialReaderProvider) GetReader() (*Reader, error) {
|
|
return trp.Reader, nil
|
|
}
|
|
|
|
// Close implements ReaderProvider.
|
|
func (trp TrivialReaderProvider) Close() {}
|
|
|
|
// valueBlockReader is used to retrieve values in value
|
|
// blocks. It is used when the sstable was written with
|
|
// Properties.ValueBlocksAreEnabled.
|
|
type valueBlockReader struct {
|
|
bpOpen blockProviderWhenOpen
|
|
rp ReaderProvider
|
|
vbih valueBlocksIndexHandle
|
|
stats *base.InternalIteratorStats
|
|
|
|
// The value blocks index is lazily retrieved the first time the reader
|
|
// needs to read a value that resides in a value block.
|
|
vbiBlock []byte
|
|
vbiCache bufferHandle
|
|
// When sequentially iterating through all key-value pairs, the cost of
|
|
// repeatedly getting a block that is already in the cache and releasing the
|
|
// bufferHandle can be ~40% of the cpu overhead. So the reader remembers the
|
|
// last value block it retrieved, in case there is locality of access, and
|
|
// this value block can be used for the next value retrieval.
|
|
valueBlockNum uint32
|
|
valueBlock []byte
|
|
valueBlockPtr unsafe.Pointer
|
|
valueCache bufferHandle
|
|
lazyFetcher base.LazyFetcher
|
|
closed bool
|
|
bufToMangle []byte
|
|
}
|
|
|
|
func (r *valueBlockReader) getLazyValueForPrefixAndValueHandle(handle []byte) base.LazyValue {
|
|
fetcher := &r.lazyFetcher
|
|
valLen, h := decodeLenFromValueHandle(handle[1:])
|
|
*fetcher = base.LazyFetcher{
|
|
Fetcher: r,
|
|
Attribute: base.AttributeAndLen{
|
|
ValueLen: int32(valLen),
|
|
ShortAttribute: getShortAttribute(valuePrefix(handle[0])),
|
|
},
|
|
}
|
|
if r.stats != nil {
|
|
r.stats.SeparatedPointValue.Count++
|
|
r.stats.SeparatedPointValue.ValueBytes += uint64(valLen)
|
|
}
|
|
return base.LazyValue{
|
|
ValueOrHandle: h,
|
|
Fetcher: fetcher,
|
|
}
|
|
}
|
|
|
|
func (r *valueBlockReader) close() {
|
|
r.bpOpen = nil
|
|
r.vbiBlock = nil
|
|
r.vbiCache.Release()
|
|
// Set the handle to empty since Release does not nil the Handle.value. If
|
|
// we were to reopen this valueBlockReader and retrieve the same
|
|
// Handle.value from the cache, we don't want to accidentally unref it when
|
|
// attempting to unref the old handle.
|
|
r.vbiCache = bufferHandle{}
|
|
r.valueBlock = nil
|
|
r.valueBlockPtr = nil
|
|
r.valueCache.Release()
|
|
// See comment above.
|
|
r.valueCache = bufferHandle{}
|
|
r.closed = true
|
|
// rp, vbih, stats remain valid, so that LazyFetcher.ValueFetcher can be
|
|
// implemented.
|
|
}
|
|
|
|
// Fetch implements base.ValueFetcher.
|
|
func (r *valueBlockReader) Fetch(
|
|
handle []byte, valLen int32, buf []byte,
|
|
) (val []byte, callerOwned bool, err error) {
|
|
if !r.closed {
|
|
val, err := r.getValueInternal(handle, valLen)
|
|
if invariants.Enabled {
|
|
val = r.doValueMangling(val)
|
|
}
|
|
return val, false, err
|
|
}
|
|
|
|
bp := blockProviderWhenClosed{rp: r.rp}
|
|
err = bp.open()
|
|
if err != nil {
|
|
return nil, false, err
|
|
}
|
|
defer bp.close()
|
|
defer r.close()
|
|
r.bpOpen = bp
|
|
var v []byte
|
|
v, err = r.getValueInternal(handle, valLen)
|
|
if err != nil {
|
|
return nil, false, err
|
|
}
|
|
buf = append(buf[:0], v...)
|
|
return buf, true, nil
|
|
}
|
|
|
|
// doValueMangling attempts to uncover violations of the contract listed in
|
|
// the declaration comment of LazyValue. It is expensive, hence only called
|
|
// when invariants.Enabled.
|
|
func (r *valueBlockReader) doValueMangling(v []byte) []byte {
|
|
// Randomly set the bytes in the previous retrieved value to 0, since
|
|
// property P1 only requires the valueBlockReader to maintain the memory of
|
|
// one fetched value.
|
|
if rand.Intn(2) == 0 {
|
|
for i := range r.bufToMangle {
|
|
r.bufToMangle[i] = 0
|
|
}
|
|
}
|
|
// Store the current value in a new buffer for future mangling.
|
|
r.bufToMangle = append([]byte(nil), v...)
|
|
return r.bufToMangle
|
|
}
|
|
|
|
func (r *valueBlockReader) getValueInternal(handle []byte, valLen int32) (val []byte, err error) {
|
|
vh := decodeRemainingValueHandle(handle)
|
|
vh.valueLen = uint32(valLen)
|
|
if r.vbiBlock == nil {
|
|
ch, err := r.bpOpen.readBlockForVBR(r.vbih.h, r.stats)
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
r.vbiCache = ch
|
|
r.vbiBlock = ch.Get()
|
|
}
|
|
if r.valueBlock == nil || r.valueBlockNum != vh.blockNum {
|
|
vbh, err := r.getBlockHandle(vh.blockNum)
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
vbCacheHandle, err := r.bpOpen.readBlockForVBR(vbh, r.stats)
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
r.valueBlockNum = vh.blockNum
|
|
r.valueCache.Release()
|
|
r.valueCache = vbCacheHandle
|
|
r.valueBlock = vbCacheHandle.Get()
|
|
r.valueBlockPtr = unsafe.Pointer(&r.valueBlock[0])
|
|
}
|
|
if r.stats != nil {
|
|
r.stats.SeparatedPointValue.ValueBytesFetched += uint64(valLen)
|
|
}
|
|
return r.valueBlock[vh.offsetInBlock : vh.offsetInBlock+vh.valueLen], nil
|
|
}
|
|
|
|
func (r *valueBlockReader) getBlockHandle(blockNum uint32) (BlockHandle, error) {
|
|
indexEntryLen :=
|
|
int(r.vbih.blockNumByteLength + r.vbih.blockOffsetByteLength + r.vbih.blockLengthByteLength)
|
|
offsetInIndex := indexEntryLen * int(blockNum)
|
|
if len(r.vbiBlock) < offsetInIndex+indexEntryLen {
|
|
return BlockHandle{}, errors.Errorf(
|
|
"cannot read at offset %d and length %d from block of length %d",
|
|
offsetInIndex, indexEntryLen, len(r.vbiBlock))
|
|
}
|
|
b := r.vbiBlock[offsetInIndex : offsetInIndex+indexEntryLen]
|
|
n := int(r.vbih.blockNumByteLength)
|
|
bn := littleEndianGet(b, n)
|
|
if uint32(bn) != blockNum {
|
|
return BlockHandle{},
|
|
errors.Errorf("expected block num %d but found %d", blockNum, bn)
|
|
}
|
|
b = b[n:]
|
|
n = int(r.vbih.blockOffsetByteLength)
|
|
blockOffset := littleEndianGet(b, n)
|
|
b = b[n:]
|
|
n = int(r.vbih.blockLengthByteLength)
|
|
blockLen := littleEndianGet(b, n)
|
|
return BlockHandle{Offset: blockOffset, Length: blockLen}, nil
|
|
}
|