dc6be68852
"The goal of this patch series is to support reading and writing of a
"promoted index" - the Cassandra 2.* SSTable feature which allows reading
only a part of the partition without needing to read an entire partition
when it is very long. To make a long story short, a "promoted index" is
a sample of each partition's column names, written to the SSTable Index
file with that partition's entry. See a longer explanation of the index
file format, and the promoted index, here:
https://github.com/scylladb/scylla/wiki/SSTables-Index-File
There are two main features in this series - first enabling reading of
parts of partitions (using the promoted index stored in an sstable),
and then enable writing promoted indexes to new sstables. These two
features are broken up into smaller stand-alone pieces to facilitate the
review.
Three features are still missing from this series and are planned to be
developed later:
1. When we fail to parse a partition's promoted index, we silently fall back
to reading the entire partition. We should log (with rate limiting) and
count these errors, to help in debugging sstable problems.
2. The current code only uses the promoted index when looking for a single
contiguous clustering-key range. If the ck range is non-contiguous, we
fall back to reading the entire partition. We should use the promoted
index in that case too.
3. The current code only uses the promoted index when reading a single
partition, via sstable::read_row(). When scanning through all or a
range of partitions (read_rows() or read_range_rows()), we do not yet
use the promoted index; We read contiguously from data file (we do not
even read from the index file, so unsurprisingly we can't use it)."
(cherry picked from commit 700feda0db)
310 lines
9.6 KiB
C++
310 lines
9.6 KiB
C++
/*
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* Copyright (C) 2015 ScyllaDB
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*/
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/*
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* This file is part of Scylla.
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*
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* Scylla is free software: you can redistribute it and/or modify
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* it under the terms of the GNU Affero General Public License as published by
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* the Free Software Foundation, either version 3 of the License, or
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* (at your option) any later version.
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*
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* Scylla is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with Scylla. If not, see <http://www.gnu.org/licenses/>.
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*/
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#pragma once
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#include "disk_types.hh"
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#include "core/enum.hh"
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#include "bytes.hh"
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#include "gc_clock.hh"
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#include "tombstone.hh"
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#include "streaming_histogram.hh"
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#include "estimated_histogram.hh"
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#include "column_name_helper.hh"
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#include "sstables/key.hh"
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#include "db/commitlog/replay_position.hh"
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#include <vector>
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#include <unordered_map>
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#include <type_traits>
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// While the sstable code works with char, bytes_view works with int8_t
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// (signed char). Rather than change all the code, let's do a cast.
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static inline bytes_view to_bytes_view(const temporary_buffer<char>& b) {
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using byte = bytes_view::value_type;
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return bytes_view(reinterpret_cast<const byte*>(b.get()), b.size());
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}
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namespace sstables {
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struct option {
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disk_string<uint16_t> key;
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disk_string<uint16_t> value;
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template <typename Describer>
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auto describe_type(Describer f) { return f(key, value); }
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};
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struct filter {
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uint32_t hashes;
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disk_array<uint32_t, uint64_t> buckets;
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template <typename Describer>
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auto describe_type(Describer f) { return f(hashes, buckets); }
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// Create an always positive filter if nothing else is specified.
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filter() : hashes(0), buckets({}) {}
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explicit filter(int hashes, std::deque<uint64_t> buckets) : hashes(hashes), buckets({std::move(buckets)}) {}
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};
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class index_entry {
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temporary_buffer<char> _key;
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uint64_t _position;
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temporary_buffer<char> _promoted_index;
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public:
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bytes_view get_key_bytes() const {
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return to_bytes_view(_key);
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}
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key_view get_key() const {
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return { get_key_bytes() };
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}
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uint64_t position() const {
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return _position;
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}
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bytes_view get_promoted_index_bytes() const {
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return to_bytes_view(_promoted_index);
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}
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index_entry(temporary_buffer<char>&& key, uint64_t position, temporary_buffer<char>&& promoted_index)
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: _key(std::move(key)), _position(position), _promoted_index(std::move(promoted_index)) {}
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};
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struct summary_entry {
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bytes key;
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uint64_t position;
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key_view get_key() const {
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return { key };
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}
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bool operator==(const summary_entry& x) const {
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return position == x.position && key == x.key;
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}
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};
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// Note: Sampling level is present in versions ka and higher. We ATM only support ka,
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// so it's always there. But we need to make this conditional if we ever want to support
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// other formats.
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struct summary_ka {
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struct header {
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// The minimum possible amount of indexes per group (sampling level)
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uint32_t min_index_interval;
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// The number of entries in the Summary File
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uint32_t size;
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// The memory to be consumed to map the whole Summary into memory.
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uint64_t memory_size;
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// The actual sampling level.
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uint32_t sampling_level;
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// The number of entries the Summary *would* have if the sampling
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// level would be equal to min_index_interval.
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uint32_t size_at_full_sampling;
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} header;
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// The position in the Summary file for each of the indexes.
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// NOTE1 that its actual size is determined by the "size" parameter, not
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// by its preceding size_at_full_sampling
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// NOTE2: They are laid out in *MEMORY* order, not BE.
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// NOTE3: The sizes in this array represent positions in the memory stream,
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// not the file. The memory stream effectively begins after the header,
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// so every position here has to be added of sizeof(header).
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std::deque<uint32_t> positions; // can be large, so use a deque instead of a vector
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std::deque<summary_entry> entries;
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disk_string<uint32_t> first_key;
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disk_string<uint32_t> last_key;
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// Used to determine when a summary entry should be added based on min_index_interval.
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// NOTE: keys_written isn't part of on-disk format of summary.
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size_t keys_written;
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// NOTE4: There is a structure written by Cassandra into the end of the Summary
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// file, after the field last_key, that we haven't understand yet, but we know
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// that its content isn't related to the summary itself.
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// The structure is basically as follow:
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// struct { disk_string<uint16_t>; uint32_t; uint64_t; disk_string<uint16_t>; }
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// Another interesting fact about this structure is that it is apparently always
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// filled with the same data. It's too early to judge that the data is useless.
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// However, it was tested that Cassandra loads successfully a Summary file with
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// this structure removed from it. Anyway, let's pay attention to it.
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/*
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* Returns total amount of memory used by the summary
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* Similar to origin off heap size
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*/
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uint64_t memory_footprint() const {
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return sizeof(summary_entry) * entries.size() + sizeof(uint32_t) * positions.size() + sizeof(*this);
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}
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explicit operator bool() const {
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return entries.size();
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}
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};
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using summary = summary_ka;
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struct metadata {
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virtual ~metadata() {}
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};
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struct validation_metadata : public metadata {
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disk_string<uint16_t> partitioner;
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double filter_chance;
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size_t serialized_size() {
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return sizeof(uint16_t) + partitioner.value.size() + sizeof(filter_chance);
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}
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template <typename Describer>
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auto describe_type(Describer f) { return f(partitioner, filter_chance); }
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};
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struct compaction_metadata : public metadata {
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disk_array<uint32_t, uint32_t> ancestors;
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disk_array<uint32_t, uint8_t> cardinality;
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size_t serialized_size() {
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return sizeof(uint32_t) + (ancestors.elements.size() * sizeof(uint32_t)) +
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sizeof(uint32_t) + (cardinality.elements.size() * sizeof(uint8_t));
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}
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template <typename Describer>
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auto describe_type(Describer f) { return f(ancestors, cardinality); }
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};
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struct ka_stats_metadata : public metadata {
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estimated_histogram estimated_row_size;
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estimated_histogram estimated_column_count;
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db::replay_position position;
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int64_t min_timestamp;
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int64_t max_timestamp;
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int32_t max_local_deletion_time;
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double compression_ratio;
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streaming_histogram estimated_tombstone_drop_time;
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uint32_t sstable_level;
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uint64_t repaired_at;
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disk_array<uint32_t, disk_string<uint16_t>> min_column_names;
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disk_array<uint32_t, disk_string<uint16_t>> max_column_names;
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bool has_legacy_counter_shards;
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template <typename Describer>
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auto describe_type(Describer f) {
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return f(
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estimated_row_size,
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estimated_column_count,
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position,
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min_timestamp,
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max_timestamp,
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max_local_deletion_time,
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compression_ratio,
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estimated_tombstone_drop_time,
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sstable_level,
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repaired_at,
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min_column_names,
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max_column_names,
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has_legacy_counter_shards
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);
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}
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};
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using stats_metadata = ka_stats_metadata;
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// Numbers are found on disk, so they do matter. Also, setting their sizes of
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// that of an uint32_t is a bit wasteful, but it simplifies the code a lot
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// since we can now still use a strongly typed enum without introducing a
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// notion of "disk-size" vs "memory-size".
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enum class metadata_type : uint32_t {
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Validation = 0,
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Compaction = 1,
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Stats = 2,
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};
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static constexpr int DEFAULT_CHUNK_SIZE = 65536;
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// checksums are generated using adler32 algorithm.
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struct checksum {
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uint32_t chunk_size;
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std::deque<uint32_t> checksums;
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template <typename Describer>
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auto describe_type(Describer f) { return f(chunk_size, checksums); }
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};
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}
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namespace std {
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template <>
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struct hash<sstables::metadata_type> : enum_hash<sstables::metadata_type> {};
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}
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namespace sstables {
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struct statistics {
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disk_hash<uint32_t, metadata_type, uint32_t> hash;
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std::unordered_map<metadata_type, std::unique_ptr<metadata>> contents;
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};
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struct deletion_time {
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int32_t local_deletion_time;
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int64_t marked_for_delete_at;
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template <typename Describer>
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auto describe_type(Describer f) { return f(local_deletion_time, marked_for_delete_at); }
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bool live() const {
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return (local_deletion_time == std::numeric_limits<int32_t>::max()) &&
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(marked_for_delete_at == std::numeric_limits<int64_t>::min());
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}
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bool operator==(const deletion_time& d) {
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return local_deletion_time == d.local_deletion_time &&
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marked_for_delete_at == d.marked_for_delete_at;
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}
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bool operator!=(const deletion_time& d) {
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return !(*this == d);
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}
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explicit operator tombstone() {
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return !live() ? tombstone(marked_for_delete_at, gc_clock::time_point(gc_clock::duration(local_deletion_time))) : tombstone();
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}
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};
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enum class column_mask : uint8_t {
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none = 0x0,
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deletion = 0x01,
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expiration = 0x02,
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counter = 0x04,
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counter_update = 0x08,
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range_tombstone = 0x10,
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};
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inline column_mask operator&(column_mask m1, column_mask m2) {
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return column_mask(static_cast<uint8_t>(m1) & static_cast<uint8_t>(m2));
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}
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inline column_mask operator|(column_mask m1, column_mask m2) {
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return column_mask(static_cast<uint8_t>(m1) | static_cast<uint8_t>(m2));
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}
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}
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