// Copyright (c) Meta Platforms, Inc. and affiliates. // // This source code is licensed under both the GPLv2 (found in the // COPYING file in the root directory) and Apache 2.0 License // (found in the LICENSE.Apache file in the root directory). #pragma once #include #include #include #include #include #include #include "rocksdb/status.h" #include "rocksdb/types.h" namespace ROCKSDB_NAMESPACE { constexpr uint64_t kUnknownSeqnoTime = 0; // SeqnoToTimeMapping stores the sequence number to time mapping, so given a // sequence number it can estimate the oldest possible time for that sequence // number. For example: // 10 -> 100 // 50 -> 300 // then if a key has seqno 19, the OldestApproximateTime would be 100, for 51 it // would be 300. // As it's a sorted list, the new entry is inserted from the back. The old data // will be popped from the front if they're no longer used. class SeqnoToTimeMapping { public: // Maximum number of entries can be encoded into SST. The data is delta encode // so the maximum data usage for each SST is < 0.3K static constexpr uint64_t kMaxSeqnoTimePairsPerSST = 100; // Maximum number of entries per CF. If there's only CF with this feature on, // the max duration divided by this number, so for example, if // preclude_last_level_data_seconds = 100000 (~1day), then it will sample the // seqno -> time every 1000 seconds (~17minutes). Then the maximum entry it // needs is 100. // When there are multiple CFs having this feature on, the sampling cadence is // determined by the smallest setting, the capacity is determined the largest // setting, also it's caped by kMaxSeqnoTimePairsPerCF * 10. static constexpr uint64_t kMaxSeqnoTimePairsPerCF = 100; // A simple struct for sequence number to time pair struct SeqnoTimePair { SequenceNumber seqno = 0; uint64_t time = 0; SeqnoTimePair() = default; SeqnoTimePair(SequenceNumber _seqno, uint64_t _time) : seqno(_seqno), time(_time) {} // Encode to dest string void Encode(std::string& dest) const; // Decode the value from input Slice and remove it from the input Status Decode(Slice& input); // subtraction of 2 SeqnoTimePair SeqnoTimePair operator-(const SeqnoTimePair& other) const; // Add 2 values together void Add(const SeqnoTimePair& obj) { seqno += obj.seqno; time += obj.time; } // Compare SeqnoTimePair with a sequence number, used for binary search a // sequence number in a list of SeqnoTimePair bool operator<(const SequenceNumber& other) const { return seqno < other; } // Compare 2 SeqnoTimePair bool operator<(const SeqnoTimePair& other) const { return std::tie(seqno, time) < std::tie(other.seqno, other.time); } // Check if 2 SeqnoTimePair is the same bool operator==(const SeqnoTimePair& other) const { return std::tie(seqno, time) == std::tie(other.seqno, other.time); } }; // constractor of SeqnoToTimeMapping // max_time_duration is the maximum time it should track. For example, if // preclude_last_level_data_seconds is 1 day, then if an entry is older than 1 // day, then it can be removed. // max_capacity is the maximum number of entry it can hold. For single CF, // it's caped at 100 (kMaxSeqnoTimePairsPerCF), otherwise // kMaxSeqnoTimePairsPerCF * 10. // If it's set to 0, means it won't truncate any old data. explicit SeqnoToTimeMapping(uint64_t max_time_duration = 0, uint64_t max_capacity = 0) : max_time_duration_(max_time_duration), max_capacity_(max_capacity) {} // Append a new entry to the list. The new entry should be newer than the // existing ones. It maintains the internal sorted status. bool Append(SequenceNumber seqno, uint64_t time); // Given a sequence number, estimate it's oldest time uint64_t GetOldestApproximateTime(SequenceNumber seqno) const; // Truncate the old entries based on the current time and max_time_duration_ SequenceNumber TruncateOldEntries(uint64_t now); // Encode to a binary string void Encode(std::string& des, SequenceNumber start, SequenceNumber end, uint64_t now, uint64_t output_size = kMaxSeqnoTimePairsPerSST) const; // Add a new random entry, unlike Append(), it can be any data, but also makes // the list un-sorted. void Add(SequenceNumber seqno, uint64_t time); // Decode and add the entries to the current obj. The list will be unsorted Status Add(const std::string& seqno_time_mapping_str); // Return the number of entries size_t Size() const { return seqno_time_mapping_.size(); } // Reduce the size of internal list bool Resize(uint64_t min_time_duration, uint64_t max_time_duration); // Override the max_time_duration_ void SetMaxTimeDuration(uint64_t max_time_duration) { max_time_duration_ = max_time_duration; } uint64_t GetCapacity() const { return max_capacity_; } // Sort the list, which also remove the redundant entries, useless entries, // which makes sure the seqno is sorted, but also the time Status Sort(); // copy the current obj from the given smallest_seqno. SeqnoToTimeMapping Copy(SequenceNumber smallest_seqno) const; // If the internal list is empty bool Empty() const { return seqno_time_mapping_.empty(); } // clear all entries void Clear() { seqno_time_mapping_.clear(); } // return the string for user message // Note: Not efficient, okay for print std::string ToHumanString() const; #ifndef NDEBUG const std::deque& TEST_GetInternalMapping() const { return seqno_time_mapping_; } #endif private: static constexpr uint64_t kMaxSeqnoToTimeEntries = kMaxSeqnoTimePairsPerCF * 10; uint64_t max_time_duration_; uint64_t max_capacity_; std::deque seqno_time_mapping_; bool is_sorted_ = true; static uint64_t CalculateMaxCapacity(uint64_t min_time_duration, uint64_t max_time_duration); SeqnoTimePair& Last() { assert(!Empty()); return seqno_time_mapping_.back(); } }; // for searching the sequence number from SeqnoToTimeMapping inline bool operator<(const SequenceNumber& seqno, const SeqnoToTimeMapping::SeqnoTimePair& other) { return seqno < other.seqno; } } // namespace ROCKSDB_NAMESPACE