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https://github.com/facebook/rocksdb.git
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13e1c32a18
Summary: This PR contains a few follow ups from https://github.com/facebook/rocksdb/issues/12419 and https://github.com/facebook/rocksdb/issues/12428 including: 1) Handle a special case for `WriteBatch::TimedPut`. When the user specified write time is `std::numeric_limits<uint64_t>::max()`, it's not treated as an error, but it instead creates and writes a regular `Put` entry. 2) Update the `InternalIterator::write_unix_time` APIs to handle `kTypeValuePreferredSeqno` entries. 3) FlushJob is updated to use the seqno to time mapping copy in `SuperVersion`. FlushJob currently copy the DB's seqno to time mapping while holding db mutex and only copies the part of interest, a.k.a, the part that only goes back to the earliest sequence number of the to-be-flushed memtables. While updating FlushJob to use the mapping copy in `SuperVersion`, it's given access to the full mapping to help cover the need to convert `kTypeValuePreferredSeqno`'s write time to preferred seqno as much as possible. Test plans: Added unit tests Pull Request resolved: https://github.com/facebook/rocksdb/pull/12455 Reviewed By: pdillinger Differential Revision: D55165422 Pulled By: jowlyzhang fbshipit-source-id: dc022653077f678c24661de5743146a74cce4b47
544 lines
16 KiB
C++
544 lines
16 KiB
C++
// Copyright (c) Meta Platforms, Inc. and affiliates.
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//
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// This source code is licensed under both the GPLv2 (found in the
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// COPYING file in the root directory) and Apache 2.0 License
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// (found in the LICENSE.Apache file in the root directory).
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#include "db/seqno_to_time_mapping.h"
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#include <algorithm>
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#include <cassert>
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#include <cstdint>
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#include <deque>
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#include <functional>
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#include <queue>
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#include <vector>
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#include "db/version_edit.h"
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#include "util/string_util.h"
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namespace ROCKSDB_NAMESPACE {
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SeqnoToTimeMapping::pair_const_iterator SeqnoToTimeMapping::FindGreaterTime(
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uint64_t time) const {
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assert(enforced_);
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return std::upper_bound(pairs_.cbegin(), pairs_.cend(),
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SeqnoTimePair{0, time}, SeqnoTimePair::TimeLess);
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}
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SeqnoToTimeMapping::pair_const_iterator SeqnoToTimeMapping::FindGreaterEqSeqno(
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SequenceNumber seqno) const {
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assert(enforced_);
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return std::lower_bound(pairs_.cbegin(), pairs_.cend(),
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SeqnoTimePair{seqno, 0}, SeqnoTimePair::SeqnoLess);
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}
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SeqnoToTimeMapping::pair_const_iterator SeqnoToTimeMapping::FindGreaterSeqno(
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SequenceNumber seqno) const {
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assert(enforced_);
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return std::upper_bound(pairs_.cbegin(), pairs_.cend(),
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SeqnoTimePair{seqno, 0}, SeqnoTimePair::SeqnoLess);
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}
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uint64_t SeqnoToTimeMapping::GetProximalTimeBeforeSeqno(
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SequenceNumber seqno) const {
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assert(enforced_);
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// Find the last entry with a seqno strictly less than the given seqno.
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// First, find the first entry >= the given seqno (or end)
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auto it = FindGreaterEqSeqno(seqno);
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if (it == pairs_.cbegin()) {
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return kUnknownTimeBeforeAll;
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}
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// Then return data from previous.
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it--;
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return it->time;
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}
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SequenceNumber SeqnoToTimeMapping::GetProximalSeqnoBeforeTime(
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uint64_t time) const {
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assert(enforced_);
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// Find the last entry with a time <= the given time.
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// First, find the first entry > the given time (or end).
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auto it = FindGreaterTime(time);
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if (it == pairs_.cbegin()) {
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return kUnknownSeqnoBeforeAll;
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}
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// Then return data from previous.
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--it;
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return it->seqno;
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}
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void SeqnoToTimeMapping::EnforceMaxTimeSpan(uint64_t now) {
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assert(enforced_); // at least sorted
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uint64_t cutoff_time;
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if (pairs_.size() <= 1) {
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return;
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}
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if (now > 0) {
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if (now < max_time_span_) {
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// Nothing eligible to prune / avoid underflow
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return;
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}
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cutoff_time = now - max_time_span_;
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} else {
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const auto& last = pairs_.back();
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if (last.time < max_time_span_) {
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// Nothing eligible to prune / avoid underflow
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return;
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}
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cutoff_time = last.time - max_time_span_;
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}
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// Keep one entry <= cutoff_time
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while (pairs_.size() >= 2 && pairs_[0].time <= cutoff_time &&
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pairs_[1].time <= cutoff_time) {
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pairs_.pop_front();
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}
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}
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void SeqnoToTimeMapping::EnforceCapacity(bool strict) {
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assert(enforced_); // at least sorted
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uint64_t strict_cap = capacity_;
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if (strict_cap == 0) {
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pairs_.clear();
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return;
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}
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// Treat cap of 1 as 2 to work with the below algorithm (etc.)
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if (strict_cap == 1) {
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strict_cap = 2;
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}
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// When !strict, allow being over nominal capacity by a modest fraction.
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uint64_t effective_cap = strict_cap + (strict ? 0 : strict_cap / 8);
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if (effective_cap < strict_cap) {
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// Correct overflow
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effective_cap = UINT64_MAX;
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}
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if (pairs_.size() <= effective_cap) {
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return;
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}
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// The below algorithm expects at least one removal candidate between first
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// and last.
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assert(pairs_.size() >= 3);
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size_t to_remove_count = pairs_.size() - strict_cap;
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struct RemovalCandidate {
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uint64_t new_time_gap;
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std::deque<SeqnoTimePair>::iterator it;
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RemovalCandidate(uint64_t _new_time_gap,
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std::deque<SeqnoTimePair>::iterator _it)
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: new_time_gap(_new_time_gap), it(_it) {}
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bool operator>(const RemovalCandidate& other) const {
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if (new_time_gap == other.new_time_gap) {
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// If same gap, treat the newer entry as less attractive
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// for removal (like larger gap)
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return it->seqno > other.it->seqno;
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}
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return new_time_gap > other.new_time_gap;
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}
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};
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// A priority queue of best removal candidates (smallest time gap remaining
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// after removal)
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using RC = RemovalCandidate;
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using PQ = std::priority_queue<RC, std::vector<RC>, std::greater<RC>>;
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PQ pq;
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// Add all the candidates (not including first and last)
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{
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auto it = pairs_.begin();
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assert(it->time != kUnknownTimeBeforeAll);
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uint64_t prev_prev_time = it->time;
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++it;
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assert(it->time != kUnknownTimeBeforeAll);
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auto prev_it = it;
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++it;
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while (it != pairs_.end()) {
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assert(it->time != kUnknownTimeBeforeAll);
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uint64_t gap = it->time - prev_prev_time;
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pq.emplace(gap, prev_it);
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prev_prev_time = prev_it->time;
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prev_it = it;
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++it;
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}
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}
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// Greedily remove the best candidate, iteratively
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while (to_remove_count > 0) {
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assert(!pq.empty());
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// Remove the candidate with smallest gap
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auto rc = pq.top();
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pq.pop();
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// NOTE: priority_queue does not support updating an existing element,
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// but we can work around that because the gap tracked in pq is only
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// going to be better than actuality, and we can detect and adjust
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// when a better-than-actual gap is found.
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// Determine actual time gap if this entry is removed (zero entries are
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// marked for deletion)
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auto it = rc.it + 1;
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uint64_t after_time = it->time;
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while (after_time == kUnknownTimeBeforeAll) {
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assert(it != pairs_.end());
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++it;
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after_time = it->time;
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}
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it = rc.it - 1;
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uint64_t before_time = it->time;
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while (before_time == kUnknownTimeBeforeAll) {
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assert(it != pairs_.begin());
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--it;
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before_time = it->time;
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}
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// Check whether the gap is still valid (or needs to be recomputed)
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if (rc.new_time_gap == after_time - before_time) {
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// Mark the entry as removed
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rc.it->time = kUnknownTimeBeforeAll;
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--to_remove_count;
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} else {
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// Insert a replacement up-to-date removal candidate
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pq.emplace(after_time - before_time, rc.it);
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}
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}
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// Collapse away entries marked for deletion
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auto from_it = pairs_.begin();
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auto to_it = from_it;
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for (; from_it != pairs_.end(); ++from_it) {
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if (from_it->time != kUnknownTimeBeforeAll) {
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if (from_it != to_it) {
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*to_it = *from_it;
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}
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++to_it;
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}
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}
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// Erase slots freed up
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pairs_.erase(to_it, pairs_.end());
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assert(pairs_.size() == strict_cap);
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}
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bool SeqnoToTimeMapping::SeqnoTimePair::Merge(const SeqnoTimePair& other) {
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assert(seqno <= other.seqno);
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if (seqno == other.seqno) {
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// Favoring GetProximalSeqnoBeforeTime over GetProximalTimeBeforeSeqno
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// by keeping the older time. For example, consider nothing has been
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// written to the DB in some time.
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time = std::min(time, other.time);
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return true;
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} else if (time == other.time) {
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// Favoring GetProximalSeqnoBeforeTime over GetProximalTimeBeforeSeqno
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// by keeping the newer seqno. For example, when a burst of writes ages
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// out, we want the cutoff to be the newest seqno from that burst.
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seqno = std::max(seqno, other.seqno);
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return true;
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} else if (time > other.time) {
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assert(seqno < other.seqno);
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// Need to resolve an inconsistency (clock drift? very rough time?).
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// Given the direction that entries are supposed to err, trust the earlier
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// time entry as more reliable, and this choice ensures we don't
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// accidentally throw out an entry within our time span.
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*this = other;
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return true;
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} else {
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// Not merged
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return false;
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}
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}
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void SeqnoToTimeMapping::SortAndMerge() {
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assert(!enforced_);
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if (!pairs_.empty()) {
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std::sort(pairs_.begin(), pairs_.end());
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auto from_it = pairs_.begin();
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auto to_it = from_it;
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for (++from_it; from_it != pairs_.end(); ++from_it) {
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if (to_it->Merge(*from_it)) {
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// Merged with last entry
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} else {
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// Copy into next entry
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*++to_it = *from_it;
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}
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}
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// Erase slots freed up from merging
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pairs_.erase(to_it + 1, pairs_.end());
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}
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// Mark as "at least sorted"
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enforced_ = true;
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}
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SeqnoToTimeMapping& SeqnoToTimeMapping::SetMaxTimeSpan(uint64_t max_time_span) {
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max_time_span_ = max_time_span;
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if (enforced_) {
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EnforceMaxTimeSpan();
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}
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return *this;
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}
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SeqnoToTimeMapping& SeqnoToTimeMapping::SetCapacity(uint64_t capacity) {
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capacity_ = capacity;
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if (enforced_) {
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EnforceCapacity(/*strict=*/true);
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}
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return *this;
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}
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SeqnoToTimeMapping& SeqnoToTimeMapping::Enforce(uint64_t now) {
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if (!enforced_) {
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SortAndMerge();
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assert(enforced_);
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EnforceMaxTimeSpan(now);
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} else if (now > 0) {
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EnforceMaxTimeSpan(now);
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}
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EnforceCapacity(/*strict=*/true);
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return *this;
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}
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void SeqnoToTimeMapping::AddUnenforced(SequenceNumber seqno, uint64_t time) {
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if (seqno == 0) {
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return;
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}
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enforced_ = false;
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pairs_.emplace_back(seqno, time);
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}
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// The encoded format is:
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// [num_of_entries][[seqno][time],[seqno][time],...]
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// ^ ^
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// var_int delta_encoded (var_int)
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// Except empty string is used for empty mapping. This means the encoding
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// doesn't fully form a prefix code, but that is OK for applications like
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// TableProperties.
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void SeqnoToTimeMapping::EncodeTo(std::string& dest) const {
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assert(enforced_);
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// Can use empty string for empty mapping
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if (pairs_.empty()) {
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return;
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}
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// Encode number of entries
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PutVarint64(&dest, pairs_.size());
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SeqnoTimePair base;
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for (auto& cur : pairs_) {
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assert(base < cur);
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// Delta encode each entry
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SeqnoTimePair val = cur.ComputeDelta(base);
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base = cur;
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val.Encode(dest);
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}
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}
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namespace {
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Status DecodeImpl(Slice& input,
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std::deque<SeqnoToTimeMapping::SeqnoTimePair>& pairs) {
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if (input.empty()) {
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return Status::OK();
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}
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uint64_t count;
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if (!GetVarint64(&input, &count)) {
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return Status::Corruption("Invalid sequence number time size");
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}
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SeqnoToTimeMapping::SeqnoTimePair base;
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for (uint64_t i = 0; i < count; i++) {
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SeqnoToTimeMapping::SeqnoTimePair val;
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Status s = val.Decode(input);
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if (!s.ok()) {
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return s;
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}
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val.ApplyDelta(base);
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pairs.emplace_back(val);
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base = val;
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}
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if (!input.empty()) {
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return Status::Corruption(
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"Extra bytes at end of sequence number time mapping");
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}
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return Status::OK();
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}
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} // namespace
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Status SeqnoToTimeMapping::DecodeFrom(const std::string& pairs_str) {
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size_t orig_size = pairs_.size();
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Slice input(pairs_str);
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Status s = DecodeImpl(input, pairs_);
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if (!s.ok()) {
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// Roll back in case of corrupted data
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pairs_.resize(orig_size);
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} else if (orig_size > 0 || max_time_span_ < UINT64_MAX ||
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capacity_ < UINT64_MAX) {
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enforced_ = false;
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}
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return s;
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}
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void SeqnoToTimeMapping::SeqnoTimePair::Encode(std::string& dest) const {
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PutVarint64Varint64(&dest, seqno, time);
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}
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Status SeqnoToTimeMapping::SeqnoTimePair::Decode(Slice& input) {
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if (!GetVarint64(&input, &seqno)) {
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return Status::Corruption("Invalid sequence number");
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}
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if (!GetVarint64(&input, &time)) {
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return Status::Corruption("Invalid time");
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}
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return Status::OK();
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}
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void SeqnoToTimeMapping::CopyFromSeqnoRange(const SeqnoToTimeMapping& src,
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SequenceNumber from_seqno,
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SequenceNumber to_seqno) {
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bool orig_empty = Empty();
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auto src_it = src.FindGreaterEqSeqno(from_seqno);
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// Allow nonsensical ranges like [1000, 0] which might show up e.g. for
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// an SST file with no entries.
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auto src_it_end =
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to_seqno < from_seqno ? src_it : src.FindGreaterSeqno(to_seqno);
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// To best answer GetProximalTimeBeforeSeqno(from_seqno) we need an entry
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// with a seqno before that (if available)
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if (src_it != src.pairs_.begin()) {
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--src_it;
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}
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assert(src_it <= src_it_end);
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std::copy(src_it, src_it_end, std::back_inserter(pairs_));
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if (!orig_empty || max_time_span_ < UINT64_MAX || capacity_ < UINT64_MAX) {
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enforced_ = false;
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}
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}
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bool SeqnoToTimeMapping::Append(SequenceNumber seqno, uint64_t time) {
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if (capacity_ == 0) {
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return false;
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}
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bool added = false;
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if (seqno == 0) {
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// skip seq number 0, which may have special meaning, like zeroed out data
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// TODO: consider changing?
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} else if (pairs_.empty()) {
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enforced_ = true;
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pairs_.emplace_back(seqno, time);
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// skip normal enforced check below
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return true;
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} else {
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auto& last = pairs_.back();
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// We can attempt to merge with the last entry if the new entry sorts with
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// it.
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if (last.seqno <= seqno) {
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bool merged = last.Merge({seqno, time});
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if (!merged) {
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if (enforced_ && (seqno <= last.seqno || time <= last.time)) {
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// Out of order append should not happen, except in case of clock
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// reset
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assert(false);
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} else {
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pairs_.emplace_back(seqno, time);
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added = true;
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}
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}
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} else if (!enforced_) {
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// Treat like AddUnenforced and fix up below
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pairs_.emplace_back(seqno, time);
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added = true;
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} else {
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// Out of order append attempted
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assert(false);
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}
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}
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// Similar to Enforce() but not quite
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if (!enforced_) {
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SortAndMerge();
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assert(enforced_);
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}
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EnforceMaxTimeSpan();
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EnforceCapacity(/*strict=*/false);
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return added;
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}
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bool SeqnoToTimeMapping::PrePopulate(SequenceNumber from_seqno,
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SequenceNumber to_seqno,
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uint64_t from_time, uint64_t to_time) {
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assert(Empty());
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assert(from_seqno > 0);
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assert(to_seqno > from_seqno);
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assert(from_time > kUnknownTimeBeforeAll);
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assert(to_time >= from_time);
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// TODO: smartly limit this to max_capacity_ representative samples
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for (auto i = from_seqno; i <= to_seqno; i++) {
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uint64_t t = from_time + (to_time - from_time) * (i - from_seqno) /
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(to_seqno - from_seqno);
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pairs_.emplace_back(i, t);
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}
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return /*success*/ true;
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}
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std::string SeqnoToTimeMapping::ToHumanString() const {
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std::string ret;
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for (const auto& seq_time : pairs_) {
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AppendNumberTo(&ret, seq_time.seqno);
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ret.append("->");
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AppendNumberTo(&ret, seq_time.time);
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ret.append(",");
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}
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return ret;
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}
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Slice PackValueAndWriteTime(const Slice& value, uint64_t unix_write_time,
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|
std::string* buf) {
|
|
buf->assign(value.data(), value.size());
|
|
PutFixed64(buf, unix_write_time);
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|
return Slice(*buf);
|
|
}
|
|
|
|
Slice PackValueAndSeqno(const Slice& value, SequenceNumber seqno,
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|
std::string* buf) {
|
|
buf->assign(value.data(), value.size());
|
|
PutFixed64(buf, seqno);
|
|
return Slice(*buf);
|
|
}
|
|
|
|
uint64_t ParsePackedValueForWriteTime(const Slice& value) {
|
|
assert(value.size() >= sizeof(uint64_t));
|
|
Slice write_time_slice(value.data() + value.size() - sizeof(uint64_t),
|
|
sizeof(uint64_t));
|
|
uint64_t write_time;
|
|
[[maybe_unused]] auto res = GetFixed64(&write_time_slice, &write_time);
|
|
assert(res);
|
|
return write_time;
|
|
}
|
|
|
|
std::tuple<Slice, uint64_t> ParsePackedValueWithWriteTime(const Slice& value) {
|
|
return std::make_tuple(Slice(value.data(), value.size() - sizeof(uint64_t)),
|
|
ParsePackedValueForWriteTime(value));
|
|
}
|
|
|
|
SequenceNumber ParsePackedValueForSeqno(const Slice& value) {
|
|
assert(value.size() >= sizeof(SequenceNumber));
|
|
Slice seqno_slice(value.data() + value.size() - sizeof(uint64_t),
|
|
sizeof(uint64_t));
|
|
SequenceNumber seqno;
|
|
[[maybe_unused]] auto res = GetFixed64(&seqno_slice, &seqno);
|
|
assert(res);
|
|
return seqno;
|
|
}
|
|
|
|
std::tuple<Slice, SequenceNumber> ParsePackedValueWithSeqno(
|
|
const Slice& value) {
|
|
return std::make_tuple(
|
|
Slice(value.data(), value.size() - sizeof(SequenceNumber)),
|
|
ParsePackedValueForSeqno(value));
|
|
}
|
|
|
|
Slice ParsePackedValueForValue(const Slice& value) {
|
|
assert(value.size() >= sizeof(uint64_t));
|
|
return Slice(value.data(), value.size() - sizeof(uint64_t));
|
|
}
|
|
} // namespace ROCKSDB_NAMESPACE
|