tdlight/tddb/td/db/binlog/ConcurrentBinlog.cpp
2023-01-16 12:47:37 +03:00

207 lines
6.5 KiB
C++

//
// Copyright Aliaksei Levin (levlam@telegram.org), Arseny Smirnov (arseny30@gmail.com) 2014-2023
//
// Distributed under the Boost Software License, Version 1.0. (See accompanying
// file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
//
#include "td/db/binlog/ConcurrentBinlog.h"
#include "td/utils/logging.h"
#include "td/utils/OrderedEventsProcessor.h"
#include "td/utils/SliceBuilder.h"
#include "td/utils/Time.h"
#include <map>
namespace td {
namespace detail {
class BinlogActor final : public Actor {
public:
BinlogActor(unique_ptr<Binlog> binlog, uint64 seq_no) : binlog_(std::move(binlog)), processor_(seq_no) {
}
void close(Promise<> promise) {
binlog_->close().ensure();
LOG(INFO) << "Finished to close binlog";
stop();
promise.set_value(Unit()); // setting promise can complete closing and destroy the current actor context
}
void close_and_destroy(Promise<> promise) {
binlog_->close_and_destroy().ensure();
LOG(INFO) << "Finished to destroy binlog";
stop();
promise.set_value(Unit()); // setting promise can complete closing and destroy the current actor context
}
struct Event {
BufferSlice raw_event;
Promise<> sync_promise;
BinlogDebugInfo debug_info;
};
void add_raw_event(uint64 seq_no, BufferSlice &&raw_event, Promise<> &&promise, BinlogDebugInfo info) {
processor_.add(seq_no, Event{std::move(raw_event), std::move(promise), info}, [&](uint64 event_id, Event &&event) {
if (!event.raw_event.empty()) {
do_add_raw_event(std::move(event.raw_event), event.debug_info);
}
do_lazy_sync(std::move(event.sync_promise));
});
flush_immediate_sync();
try_flush();
}
void force_sync(Promise<> &&promise) {
auto seq_no = processor_.max_unfinished_seq_no();
if (processor_.max_finished_seq_no() == seq_no) {
do_immediate_sync(std::move(promise));
} else {
immediate_sync_promises_.emplace(seq_no, std::move(promise));
}
}
void force_flush() {
// TODO: use same logic as in force_sync
binlog_->flush();
flush_flag_ = false;
}
void change_key(DbKey db_key, Promise<> promise) {
binlog_->change_key(std::move(db_key));
promise.set_value(Unit());
}
private:
unique_ptr<Binlog> binlog_;
OrderedEventsProcessor<Event> processor_;
std::multimap<uint64, Promise<>> immediate_sync_promises_;
std::vector<Promise<>> sync_promises_;
bool force_sync_flag_ = false;
bool lazy_sync_flag_ = false;
bool flush_flag_ = false;
double wakeup_at_ = 0;
static constexpr double FLUSH_TIMEOUT = 0.001; // 1ms
void wakeup_after(double after) {
auto now = Time::now_cached();
wakeup_at(now + after);
}
void wakeup_at(double at) {
if (wakeup_at_ == 0 || wakeup_at_ > at) {
wakeup_at_ = at;
set_timeout_at(wakeup_at_);
}
}
void do_add_raw_event(BufferSlice &&raw_event, BinlogDebugInfo info) {
binlog_->add_raw_event(std::move(raw_event), info);
}
void try_flush() {
auto need_flush_since = binlog_->need_flush_since();
auto now = Time::now_cached();
if (now > need_flush_since + FLUSH_TIMEOUT - 1e-9) {
binlog_->flush();
} else {
if (!force_sync_flag_) {
flush_flag_ = true;
wakeup_at(need_flush_since + FLUSH_TIMEOUT);
}
}
}
void flush_immediate_sync() {
auto seq_no = processor_.max_finished_seq_no();
for (auto it = immediate_sync_promises_.begin(), end = immediate_sync_promises_.end();
it != end && it->first <= seq_no; it = immediate_sync_promises_.erase(it)) {
do_immediate_sync(std::move(it->second));
}
}
void do_immediate_sync(Promise<> &&promise) {
if (promise) {
sync_promises_.emplace_back(std::move(promise));
}
if (!force_sync_flag_) {
force_sync_flag_ = true;
wakeup_after(0.003);
}
}
void do_lazy_sync(Promise<> &&promise) {
if (!promise) {
return;
}
sync_promises_.emplace_back(std::move(promise));
if (!lazy_sync_flag_ && !force_sync_flag_) {
wakeup_after(30);
lazy_sync_flag_ = true;
}
}
void timeout_expired() final {
bool need_sync = lazy_sync_flag_ || force_sync_flag_;
lazy_sync_flag_ = false;
force_sync_flag_ = false;
bool need_flush = flush_flag_;
flush_flag_ = false;
wakeup_at_ = 0;
if (need_sync) {
binlog_->sync();
// LOG(ERROR) << "BINLOG SYNC";
set_promises(sync_promises_);
} else if (need_flush) {
try_flush();
// LOG(ERROR) << "BINLOG FLUSH";
}
}
};
} // namespace detail
ConcurrentBinlog::ConcurrentBinlog() = default;
ConcurrentBinlog::~ConcurrentBinlog() = default;
ConcurrentBinlog::ConcurrentBinlog(unique_ptr<Binlog> binlog, int scheduler_id) {
init_impl(std::move(binlog), scheduler_id);
}
Result<BinlogInfo> ConcurrentBinlog::init(string path, const Callback &callback, DbKey db_key, DbKey old_db_key,
int scheduler_id) {
auto binlog = make_unique<Binlog>();
TRY_STATUS(binlog->init(std::move(path), callback, std::move(db_key), std::move(old_db_key)));
auto info = binlog->get_info();
init_impl(std::move(binlog), scheduler_id);
return info;
}
void ConcurrentBinlog::init_impl(unique_ptr<Binlog> binlog, int32 scheduler_id) {
path_ = binlog->get_path().str();
last_event_id_ = binlog->peek_next_event_id();
binlog_actor_ = create_actor_on_scheduler<detail::BinlogActor>(PSLICE() << "Binlog " << path_, scheduler_id,
std::move(binlog), last_event_id_);
}
void ConcurrentBinlog::close_impl(Promise<> promise) {
send_closure(std::move(binlog_actor_), &detail::BinlogActor::close, std::move(promise));
}
void ConcurrentBinlog::close_and_destroy_impl(Promise<> promise) {
send_closure(std::move(binlog_actor_), &detail::BinlogActor::close_and_destroy, std::move(promise));
}
void ConcurrentBinlog::add_raw_event_impl(uint64 event_id, BufferSlice &&raw_event, Promise<> promise,
BinlogDebugInfo info) {
send_closure(binlog_actor_, &detail::BinlogActor::add_raw_event, event_id, std::move(raw_event), std::move(promise),
info);
}
void ConcurrentBinlog::force_sync(Promise<> promise) {
send_closure(binlog_actor_, &detail::BinlogActor::force_sync, std::move(promise));
}
void ConcurrentBinlog::force_flush() {
send_closure(binlog_actor_, &detail::BinlogActor::force_flush);
}
void ConcurrentBinlog::change_key(DbKey db_key, Promise<> promise) {
send_closure(binlog_actor_, &detail::BinlogActor::change_key, std::move(db_key), std::move(promise));
}
} // namespace td