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rocksdb/db/seqno_to_time_mapping.cc
Jay Zhuang c401f285c3 Add option preserve_internal_time_seconds to preserve the time info (#10747) 
Summary:
Add option `preserve_internal_time_seconds` to preserve the internal
time information.
It's mostly for the migration of the existing data to tiered storage (
`preclude_last_level_data_seconds`). When the tiering feature is just
enabled, the existing data won't have the time information to decide if
it's hot or cold. Enabling this feature will start collect and preserve
the time information for the new data.

Pull Request resolved: https://github.com/facebook/rocksdb/pull/10747

Reviewed By: siying

Differential Revision: D39910141

Pulled By: siying

fbshipit-source-id: 25c21638e37b1a7c44006f636b7d714fe7242138
2022-10-07 18:49:40 -07:00

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// 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).
#include "db/seqno_to_time_mapping.h"
#include "db/version_edit.h"
#include "util/string_util.h"
namespace ROCKSDB_NAMESPACE {
uint64_t SeqnoToTimeMapping::GetOldestApproximateTime(
const SequenceNumber seqno) const {
assert(is_sorted_);
auto it = std::upper_bound(seqno_time_mapping_.begin(),
seqno_time_mapping_.end(), seqno);
if (it == seqno_time_mapping_.begin()) {
return 0;
}
it--;
return it->time;
}
void SeqnoToTimeMapping::Add(SequenceNumber seqno, uint64_t time) {
if (seqno == 0) {
return;
}
is_sorted_ = false;
seqno_time_mapping_.emplace_back(seqno, time);
}
void SeqnoToTimeMapping::TruncateOldEntries(const uint64_t now) {
assert(is_sorted_);
if (max_time_duration_ == 0) {
return;
}
const uint64_t cut_off_time =
now > max_time_duration_ ? now - max_time_duration_ : 0;
assert(cut_off_time <= now); // no overflow
auto it = std::upper_bound(
seqno_time_mapping_.begin(), seqno_time_mapping_.end(), cut_off_time,
[](uint64_t target, const SeqnoTimePair& other) -> bool {
return target < other.time;
});
if (it == seqno_time_mapping_.begin()) {
return;
}
it--;
seqno_time_mapping_.erase(seqno_time_mapping_.begin(), it);
}
SequenceNumber SeqnoToTimeMapping::GetOldestSequenceNum(uint64_t time) {
assert(is_sorted_);
auto it = std::upper_bound(
seqno_time_mapping_.begin(), seqno_time_mapping_.end(), time,
[](uint64_t target, const SeqnoTimePair& other) -> bool {
return target < other.time;
});
if (it == seqno_time_mapping_.begin()) {
return 0;
}
it--;
return it->seqno;
}
// The encoded format is:
// [num_of_entries][[seqno][time],[seqno][time],...]
// ^ ^
// var_int delta_encoded (var_int)
void SeqnoToTimeMapping::Encode(std::string& dest, const SequenceNumber start,
const SequenceNumber end, const uint64_t now,
const uint64_t output_size) const {
assert(is_sorted_);
if (start > end) {
// It could happen when the SST file is empty, the initial value of min
// sequence number is kMaxSequenceNumber and max is 0.
// The empty output file will be removed in the final step of compaction.
return;
}
auto start_it = std::upper_bound(seqno_time_mapping_.begin(),
seqno_time_mapping_.end(), start);
if (start_it != seqno_time_mapping_.begin()) {
start_it--;
}
auto end_it = std::upper_bound(seqno_time_mapping_.begin(),
seqno_time_mapping_.end(), end);
if (end_it == seqno_time_mapping_.begin()) {
return;
}
if (start_it >= end_it) {
return;
}
// truncate old entries that are not needed
if (max_time_duration_ > 0) {
const uint64_t cut_off_time =
now > max_time_duration_ ? now - max_time_duration_ : 0;
while (start_it < end_it && start_it->time < cut_off_time) {
start_it++;
}
}
// to include the first element
if (start_it != seqno_time_mapping_.begin()) {
start_it--;
}
// If there are more data than needed, pick the entries for encoding.
// It's not the most optimized algorithm for selecting the best representative
// entries over the time.
// It starts from the beginning and makes sure the distance is larger than
// `(end - start) / size` before selecting the number. For example, for the
// following list, pick 3 entries (it will pick seqno #1, #6, #8):
// 1 -> 10
// 5 -> 17
// 6 -> 25
// 8 -> 30
// first, it always picks the first one, then there are 2 num_entries_to_fill
// and the time difference between current one vs. the last one is
// (30 - 10) = 20. 20/2 = 10. So it will skip until 10+10 = 20. => it skips
// #5 and pick #6.
// But the most optimized solution is picking #1 #5 #8, as it will be more
// evenly distributed for time. Anyway the following algorithm is simple and
// may over-select new data, which is good. We do want more accurate time
// information for recent data.
std::deque<SeqnoTimePair> output_copy;
if (std::distance(start_it, end_it) > static_cast<int64_t>(output_size)) {
int64_t num_entries_to_fill = static_cast<int64_t>(output_size);
auto last_it = end_it;
last_it--;
uint64_t end_time = last_it->time;
uint64_t skip_until_time = 0;
for (auto it = start_it; it < end_it; it++) {
// skip if it's not reach the skip_until_time yet
if (std::distance(it, end_it) > num_entries_to_fill &&
it->time < skip_until_time) {
continue;
}
output_copy.push_back(*it);
num_entries_to_fill--;
if (std::distance(it, end_it) > num_entries_to_fill &&
num_entries_to_fill > 0) {
// If there are more entries than we need, re-calculate the
// skip_until_time, which means skip until that time
skip_until_time =
it->time + ((end_time - it->time) / num_entries_to_fill);
}
}
// Make sure all entries are filled
assert(num_entries_to_fill == 0);
start_it = output_copy.begin();
end_it = output_copy.end();
}
// Delta encode the data
uint64_t size = std::distance(start_it, end_it);
PutVarint64(&dest, size);
SeqnoTimePair base;
for (auto it = start_it; it < end_it; it++) {
assert(base < *it);
SeqnoTimePair val = *it - base;
base = *it;
val.Encode(dest);
}
}
Status SeqnoToTimeMapping::Add(const std::string& seqno_time_mapping_str) {
Slice input(seqno_time_mapping_str);
if (input.empty()) {
return Status::OK();
}
uint64_t size;
if (!GetVarint64(&input, &size)) {
return Status::Corruption("Invalid sequence number time size");
}
is_sorted_ = false;
SeqnoTimePair base;
for (uint64_t i = 0; i < size; i++) {
SeqnoTimePair val;
Status s = val.Decode(input);
if (!s.ok()) {
return s;
}
val.Add(base);
seqno_time_mapping_.emplace_back(val);
base = val;
}
return Status::OK();
}
void SeqnoToTimeMapping::SeqnoTimePair::Encode(std::string& dest) const {
PutVarint64Varint64(&dest, seqno, time);
}
Status SeqnoToTimeMapping::SeqnoTimePair::Decode(Slice& input) {
if (!GetVarint64(&input, &seqno)) {
return Status::Corruption("Invalid sequence number");
}
if (!GetVarint64(&input, &time)) {
return Status::Corruption("Invalid time");
}
return Status::OK();
}
bool SeqnoToTimeMapping::Append(SequenceNumber seqno, uint64_t time) {
assert(is_sorted_);
// skip seq number 0, which may have special meaning, like zeroed out data
if (seqno == 0) {
return false;
}
if (!Empty()) {
if (seqno < Last().seqno || time < Last().time) {
return false;
}
if (seqno == Last().seqno) {
Last().time = time;
return true;
}
if (time == Last().time) {
// new sequence has the same time as old one, no need to add new mapping
return false;
}
}
seqno_time_mapping_.emplace_back(seqno, time);
if (seqno_time_mapping_.size() > max_capacity_) {
seqno_time_mapping_.pop_front();
}
return true;
}
bool SeqnoToTimeMapping::Resize(uint64_t min_time_duration,
uint64_t max_time_duration) {
uint64_t new_max_capacity =
CalculateMaxCapacity(min_time_duration, max_time_duration);
if (new_max_capacity == max_capacity_) {
return false;
} else if (new_max_capacity < seqno_time_mapping_.size()) {
uint64_t delta = seqno_time_mapping_.size() - new_max_capacity;
seqno_time_mapping_.erase(seqno_time_mapping_.begin(),
seqno_time_mapping_.begin() + delta);
}
max_capacity_ = new_max_capacity;
return true;
}
Status SeqnoToTimeMapping::Sort() {
if (is_sorted_) {
return Status::OK();
}
if (seqno_time_mapping_.empty()) {
is_sorted_ = true;
return Status::OK();
}
std::deque<SeqnoTimePair> copy = std::move(seqno_time_mapping_);
std::sort(copy.begin(), copy.end());
seqno_time_mapping_.clear();
// remove seqno = 0, which may have special meaning, like zeroed out data
while (copy.front().seqno == 0) {
copy.pop_front();
}
SeqnoTimePair prev = copy.front();
for (const auto& it : copy) {
// If sequence number is the same, pick the one with larger time, which is
// more accurate than the older time.
if (it.seqno == prev.seqno) {
assert(it.time >= prev.time);
prev.time = it.time;
} else {
assert(it.seqno > prev.seqno);
// If a larger sequence number has an older time which is not useful, skip
if (it.time > prev.time) {
seqno_time_mapping_.push_back(prev);
prev = it;
}
}
}
seqno_time_mapping_.emplace_back(prev);
is_sorted_ = true;
return Status::OK();
}
std::string SeqnoToTimeMapping::ToHumanString() const {
std::string ret;
for (const auto& seq_time : seqno_time_mapping_) {
AppendNumberTo(&ret, seq_time.seqno);
ret.append("->");
AppendNumberTo(&ret, seq_time.time);
ret.append(",");
}
return ret;
}
SeqnoToTimeMapping SeqnoToTimeMapping::Copy(
SequenceNumber smallest_seqno) const {
SeqnoToTimeMapping ret;
auto it = std::upper_bound(seqno_time_mapping_.begin(),
seqno_time_mapping_.end(), smallest_seqno);
if (it != seqno_time_mapping_.begin()) {
it--;
}
std::copy(it, seqno_time_mapping_.end(),
std::back_inserter(ret.seqno_time_mapping_));
return ret;
}
uint64_t SeqnoToTimeMapping::CalculateMaxCapacity(uint64_t min_time_duration,
uint64_t max_time_duration) {
if (min_time_duration == 0) {
return 0;
}
return std::min(
kMaxSeqnoToTimeEntries,
max_time_duration * kMaxSeqnoTimePairsPerCF / min_time_duration);
}
SeqnoToTimeMapping::SeqnoTimePair SeqnoToTimeMapping::SeqnoTimePair::operator-(
const SeqnoTimePair& other) const {
SeqnoTimePair res;
res.seqno = seqno - other.seqno;
res.time = time - other.time;
return res;
}
} // namespace ROCKSDB_NAMESPACE
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