/*
* Modified by ScyllaDB
* Copyright (C) 2017 ScyllaDB
*/
/*
* This file is part of Scylla.
*
* Scylla is free software: you can redistribute it and/or modify
* it under the terms of the GNU Affero General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* Scylla is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with Scylla. If not, see .
*/
#include
#include
#include
#include
#include
#include "service/storage_service.hh"
#include "utils/div_ceil.hh"
#include "db/config.hh"
#include "service/storage_proxy.hh"
#include "gms/versioned_value.hh"
#include "seastarx.hh"
#include "converting_mutation_partition_applier.hh"
#include "disk-error-handler.hh"
#include "lister.hh"
#include "db/timeout_clock.hh"
using namespace std::literals::chrono_literals;
namespace db {
namespace hints {
static logging::logger manager_logger("hints_manager");
const std::string manager::FILENAME_PREFIX("HintsLog" + commitlog::descriptor::SEPARATOR);
const std::chrono::seconds manager::hint_file_write_timeout = std::chrono::seconds(2);
const std::chrono::seconds manager::hints_flush_period = std::chrono::seconds(10);
manager::manager(sstring hints_directory, std::vector hinted_dcs, int64_t max_hint_window_ms, resource_manager& res_manager, distributed& db)
: _hints_dir(boost::filesystem::path(hints_directory) / format("{:d}", engine().cpu_id()).c_str())
, _hinted_dcs(hinted_dcs.begin(), hinted_dcs.end())
, _local_snitch_ptr(locator::i_endpoint_snitch::get_local_snitch_ptr())
, _max_hint_window_us(max_hint_window_ms * 1000)
, _local_db(db.local())
, _resource_manager(res_manager)
{}
manager::~manager() {
assert(_ep_managers.empty());
}
void manager::register_metrics(const sstring& group_name) {
namespace sm = seastar::metrics;
_metrics.add_group(group_name, {
sm::make_gauge("size_of_hints_in_progress", _stats.size_of_hints_in_progress,
sm::description("Size of hinted mutations that are scheduled to be written.")),
sm::make_derive("written", _stats.written,
sm::description("Number of successfully written hints.")),
sm::make_derive("errors", _stats.errors,
sm::description("Number of errors during hints writes.")),
sm::make_derive("dropped", _stats.dropped,
sm::description("Number of dropped hints.")),
sm::make_derive("sent", _stats.sent,
sm::description("Number of sent hints.")),
});
}
future<> manager::start(shared_ptr proxy_ptr, shared_ptr gossiper_ptr, shared_ptr ss_ptr) {
_proxy_anchor = std::move(proxy_ptr);
_gossiper_anchor = std::move(gossiper_ptr);
_strorage_service_anchor = std::move(ss_ptr);
return lister::scan_dir(_hints_dir, { directory_entry_type::directory }, [this] (lister::path datadir, directory_entry de) {
ep_key_type ep = ep_key_type(de.name);
if (!check_dc_for(ep)) {
return make_ready_future<>();
}
return get_ep_manager(ep).populate_segments_to_replay();
}).then([this] {
return compute_hints_dir_device_id();
}).then([this] {
_strorage_service_anchor->register_subscriber(this);
});
}
future<> manager::stop() {
manager_logger.info("Asked to stop");
if (_strorage_service_anchor) {
_strorage_service_anchor->unregister_subscriber(this);
}
_stopping = true;
return _draining_eps_gate.close().finally([this] {
return parallel_for_each(_ep_managers, [] (auto& pair) {
return pair.second.stop();
}).finally([this] {
_ep_managers.clear();
manager_logger.info("Stopped");
}).discard_result();
});
}
future<> manager::compute_hints_dir_device_id() {
return get_device_id(_hints_dir.native()).then([this](dev_t device_id) {
_hints_dir_device_id = device_id;
}).handle_exception([this](auto ep) {
manager_logger.warn("Failed to stat directory {} for device id: {}", _hints_dir.native(), ep);
return make_exception_future<>(ep);
});
}
void manager::allow_hints() {
boost::for_each(_ep_managers, [] (auto& pair) { pair.second.allow_hints(); });
}
void manager::forbid_hints() {
boost::for_each(_ep_managers, [] (auto& pair) { pair.second.forbid_hints(); });
}
void manager::forbid_hints_for_eps_with_pending_hints() {
manager_logger.trace("space_watchdog: Going to block hints to: {}", _eps_with_pending_hints);
boost::for_each(_ep_managers, [this] (auto& pair) {
end_point_hints_manager& ep_man = pair.second;
if (has_ep_with_pending_hints(ep_man.end_point_key())) {
ep_man.forbid_hints();
} else {
ep_man.allow_hints();
}
});
}
bool manager::end_point_hints_manager::store_hint(schema_ptr s, lw_shared_ptr fm, tracing::trace_state_ptr tr_state) noexcept {
try {
with_gate(_store_gate, [this, s = std::move(s), fm = std::move(fm), tr_state] () mutable {
++_hints_in_progress;
size_t mut_size = fm->representation().size();
shard_stats().size_of_hints_in_progress += mut_size;
shard_resource_manager().inc_size_of_hints_in_progress(mut_size);
return with_shared(file_update_mutex(), [this, fm, s, tr_state] () mutable -> future<> {
return get_or_load().then([this, fm = std::move(fm), s = std::move(s), tr_state] (hints_store_ptr log_ptr) mutable {
commitlog_entry_writer cew(s, *fm);
return log_ptr->add_entry(s->id(), cew, db::timeout_clock::now() + _shard_manager.hint_file_write_timeout);
}).then([this, tr_state] (db::rp_handle rh) {
rh.release();
++shard_stats().written;
manager_logger.trace("Hint to {} was stored", end_point_key());
tracing::trace(tr_state, "Hint to {} was stored", end_point_key());
}).handle_exception([this, tr_state] (std::exception_ptr eptr) {
++shard_stats().errors;
manager_logger.debug("store_hint(): got the exception when storing a hint to {}: {}", end_point_key(), eptr);
tracing::trace(tr_state, "Failed to store a hint to {}: {}", end_point_key(), eptr);
});
}).finally([this, mut_size, fm, s] {
--_hints_in_progress;
shard_stats().size_of_hints_in_progress -= mut_size;
shard_resource_manager().dec_size_of_hints_in_progress(mut_size);
});;
});
} catch (...) {
manager_logger.trace("Failed to store a hint to {}: {}", end_point_key(), std::current_exception());
tracing::trace(tr_state, "Failed to store a hint to {}: {}", end_point_key(), std::current_exception());
++shard_stats().dropped;
return false;
}
return true;
}
future<> manager::end_point_hints_manager::populate_segments_to_replay() {
return with_lock(file_update_mutex(), [this] {
return get_or_load().discard_result();
});
}
void manager::end_point_hints_manager::start() {
clear_stopped();
allow_hints();
_sender.start();
}
future<> manager::end_point_hints_manager::stop(drain should_drain) noexcept {
if(stopped()) {
return make_exception_future<>(std::logic_error(format("ep_manager[{}]: stop() is called twice", _key).c_str()));
}
return seastar::async([this, should_drain] {
std::exception_ptr eptr;
// This is going to prevent further storing of new hints and will break all sending in progress.
set_stopping();
_store_gate.close().handle_exception([&eptr] (auto e) { eptr = std::move(e); }).get();
_sender.stop(should_drain).handle_exception([&eptr] (auto e) { eptr = std::move(e); }).get();
with_lock(file_update_mutex(), [this] {
if (_hints_store_anchor) {
hints_store_ptr tmp = std::exchange(_hints_store_anchor, nullptr);
return tmp->shutdown().finally([tmp] {});
}
return make_ready_future<>();
}).handle_exception([&eptr] (auto e) { eptr = std::move(e); }).get();
if (eptr) {
manager_logger.error("ep_manager[{}]: exception: {}", _key, eptr);
}
set_stopped();
});
}
manager::end_point_hints_manager::end_point_hints_manager(const key_type& key, manager& shard_manager)
: _key(key)
, _shard_manager(shard_manager)
, _state(state_set::of())
, _hints_dir(_shard_manager.hints_dir() / format("{}", _key).c_str())
, _sender(*this, _shard_manager.local_storage_proxy(), _shard_manager.local_db(), _shard_manager.local_gossiper())
{}
manager::end_point_hints_manager::end_point_hints_manager(end_point_hints_manager&& other)
: _key(other._key)
, _shard_manager(other._shard_manager)
, _state(other._state)
, _hints_dir(std::move(other._hints_dir))
, _sender(other._sender, *this)
{}
manager::end_point_hints_manager::~end_point_hints_manager() {
assert(stopped());
}
future manager::end_point_hints_manager::get_or_load() {
if (!_hints_store_anchor) {
return _shard_manager.store_factory().get_or_load(_key, [this] (const key_type&) noexcept {
return add_store();
}).then([this] (hints_store_ptr log_ptr) {
_hints_store_anchor = log_ptr;
return make_ready_future(std::move(log_ptr));
});
}
return make_ready_future(_hints_store_anchor);
}
manager::end_point_hints_manager& manager::get_ep_manager(ep_key_type ep) {
auto it = find_ep_manager(ep);
if (it == ep_managers_end()) {
manager_logger.trace("Creating an ep_manager for {}", ep);
manager::end_point_hints_manager& ep_man = _ep_managers.emplace(ep, end_point_hints_manager(ep, *this)).first->second;
ep_man.start();
return ep_man;
}
return it->second;
}
inline bool manager::have_ep_manager(ep_key_type ep) const noexcept {
return find_ep_manager(ep) != ep_managers_end();
}
bool manager::store_hint(ep_key_type ep, schema_ptr s, lw_shared_ptr fm, tracing::trace_state_ptr tr_state) noexcept {
if (_stopping || !can_hint_for(ep)) {
manager_logger.trace("Can't store a hint to {}", ep);
++_stats.dropped;
return false;
}
try {
manager_logger.trace("Going to store a hint to {}", ep);
tracing::trace(tr_state, "Going to store a hint to {}", ep);
return get_ep_manager(ep).store_hint(std::move(s), std::move(fm), tr_state);
} catch (...) {
manager_logger.trace("Failed to store a hint to {}: {}", ep, std::current_exception());
tracing::trace(tr_state, "Failed to store a hint to {}: {}", ep, std::current_exception());
++_stats.errors;
return false;
}
}
future manager::end_point_hints_manager::add_store() noexcept {
using namespace boost::filesystem;
manager_logger.trace("Going to add a store to {}", _hints_dir.c_str());
return futurize_apply([this] {
return io_check(recursive_touch_directory, _hints_dir.c_str()).then([this] () {
commitlog::config cfg;
cfg.commit_log_location = _hints_dir.c_str();
cfg.commitlog_segment_size_in_mb = resource_manager::hint_segment_size_in_mb;
cfg.commitlog_total_space_in_mb = resource_manager::max_hints_per_ep_size_mb;
cfg.fname_prefix = manager::FILENAME_PREFIX;
cfg.extensions = &_shard_manager.local_db().get_config().extensions();
return commitlog::create_commitlog(std::move(cfg)).then([this] (commitlog l) {
// add_store() is triggered every time hint files are forcefully flushed to I/O (every hints_flush_period).
// When this happens we want to refill _sender's segments only if it has finished with the segments he had before.
if (_sender.have_segments()) {
return make_ready_future(std::move(l));
}
std::vector segs_vec = l.get_segments_to_replay();
std::for_each(segs_vec.begin(), segs_vec.end(), [this] (sstring& seg) {
_sender.add_segment(std::move(seg));
});
return make_ready_future(std::move(l));
});
});
});
}
future<> manager::end_point_hints_manager::flush_current_hints() noexcept {
// flush the currently created hints to disk
if (_hints_store_anchor) {
return futurize_apply([this] {
return with_lock(file_update_mutex(), [this]() -> future<> {
return get_or_load().then([] (hints_store_ptr cptr) {
return cptr->shutdown();
}).then([this] {
// Un-hold the commitlog object. Since we are under the exclusive _file_update_mutex lock there are no
// other hints_store_ptr copies and this would destroy the commitlog shared value.
_hints_store_anchor = nullptr;
// Re-create the commitlog instance - this will re-populate the _segments_to_replay if needed.
return get_or_load().discard_result();
});
});
});
}
return make_ready_future<>();
}
class no_column_mapping : public std::out_of_range {
public:
no_column_mapping(const utils::UUID& id) : std::out_of_range(format("column mapping for CF {} is missing", id)) {}
};
future<> manager::end_point_hints_manager::sender::flush_maybe() noexcept {
auto current_time = clock::now();
if (current_time >= _next_flush_tp) {
return _ep_manager.flush_current_hints().then([this, current_time] {
_next_flush_tp = current_time + hints_flush_period;
}).handle_exception([] (auto eptr) {
manager_logger.trace("flush_maybe() failed: {}", eptr);
return make_ready_future<>();
});
}
return make_ready_future<>();
}
future manager::end_point_hints_manager::sender::get_last_file_modification(const sstring& fname) {
return open_file_dma(fname, open_flags::ro).then([] (file f) {
return do_with(std::move(f), [] (file& f) {
return f.stat();
});
}).then([] (struct stat st) {
return make_ready_future(st.st_mtim);
});
}
future<> manager::end_point_hints_manager::sender::do_send_one_mutation(mutation m, const std::vector& natural_endpoints) noexcept {
return futurize_apply([this, m = std::move(m), &natural_endpoints] () mutable -> future<> {
// The fact that we send with CL::ALL in both cases below ensures that new hints are not going
// to be generated as a result of hints sending.
if (boost::range::find(natural_endpoints, end_point_key()) != natural_endpoints.end()) {
manager_logger.trace("Sending directly to {}", end_point_key());
return _proxy.send_to_endpoint(std::move(m), end_point_key(), { }, write_type::SIMPLE);
} else {
manager_logger.trace("Endpoints set has changed and {} is no longer a replica. Mutating from scratch...", end_point_key());
// FIXME: using 1h as infinite timeout. If a node is down, we should get an
// unavailable exception.
auto timeout = db::timeout_clock::now() + 1h;
return _proxy.mutate({std::move(m)}, consistency_level::ALL, timeout, nullptr);
}
});
}
bool manager::end_point_hints_manager::sender::can_send() noexcept {
if (stopping() && !draining()) {
return false;
}
try {
if (!_gossiper.is_alive(end_point_key())) {
if (!_state.contains(state::ep_state_is_not_normal)) {
_state.set_if(_shard_manager.local_gossiper().get_gossip_status(end_point_key()) != sstring(gms::versioned_value::STATUS_NORMAL));
}
// send the hints out if the destination Node is not in a NORMAL state - we will send to all new replicas in this case
return _state.contains(state::ep_state_is_not_normal);
} else {
_state.remove(state::ep_state_is_not_normal);
return true;
}
} catch (...) {
return false;
}
}
mutation manager::end_point_hints_manager::sender::get_mutation(lw_shared_ptr ctx_ptr, temporary_buffer& buf) {
hint_entry_reader hr(buf);
auto& fm = hr.mutation();
auto& cm = get_column_mapping(std::move(ctx_ptr), fm, hr);
auto& cf = _db.find_column_family(fm.column_family_id());
if (cf.schema()->version() != fm.schema_version()) {
mutation m(cf.schema(), fm.decorated_key(*cf.schema()));
converting_mutation_partition_applier v(cm, *cf.schema(), m.partition());
fm.partition().accept(cm, v);
return std::move(m);
} else {
return fm.unfreeze(cf.schema());
}
}
const column_mapping& manager::end_point_hints_manager::sender::get_column_mapping(lw_shared_ptr ctx_ptr, const frozen_mutation& fm, const hint_entry_reader& hr) {
auto cm_it = ctx_ptr->schema_ver_to_column_mapping.find(fm.schema_version());
if (cm_it == ctx_ptr->schema_ver_to_column_mapping.end()) {
if (!hr.get_column_mapping()) {
throw no_column_mapping(fm.schema_version());
}
manager_logger.debug("new schema version {}", fm.schema_version());
cm_it = ctx_ptr->schema_ver_to_column_mapping.emplace(fm.schema_version(), *hr.get_column_mapping()).first;
}
return cm_it->second;
}
bool manager::too_many_in_flight_hints_for(ep_key_type ep) const noexcept {
// There is no need to check the DC here because if there is an in-flight hint for this end point then this means that
// its DC has already been checked and found to be ok.
return _resource_manager.too_many_hints_in_progress() && !utils::fb_utilities::is_me(ep) && hints_in_progress_for(ep) > 0 && local_gossiper().get_endpoint_downtime(ep) <= _max_hint_window_us;
}
bool manager::can_hint_for(ep_key_type ep) const noexcept {
if (utils::fb_utilities::is_me(ep)) {
return false;
}
auto it = find_ep_manager(ep);
if (it != ep_managers_end() && (it->second.stopping() || !it->second.can_hint())) {
return false;
}
// Don't allow more than one in-flight (to the store) hint to a specific destination when the total size of in-flight
// hints is more than the maximum allowed value.
//
// In the worst case there's going to be (_max_size_of_hints_in_progress + N - 1) in-flight hints, where N is the total number Nodes in the cluster.
if (_resource_manager.too_many_hints_in_progress() && hints_in_progress_for(ep) > 0) {
manager_logger.trace("size_of_hints_in_progress {} hints_in_progress_for({}) {}", _resource_manager.size_of_hints_in_progress(), ep, hints_in_progress_for(ep));
return false;
}
// check that the destination DC is "hintable"
if (!check_dc_for(ep)) {
manager_logger.trace("{}'s DC is not hintable", ep);
return false;
}
// check if the end point has been down for too long
if (local_gossiper().get_endpoint_downtime(ep) > _max_hint_window_us) {
manager_logger.trace("{} is down for {}, not hinting", ep, local_gossiper().get_endpoint_downtime(ep));
return false;
}
return true;
}
bool manager::check_dc_for(ep_key_type ep) const noexcept {
try {
// If target's DC is not a "hintable" DCs - don't hint.
// If there is an end point manager then DC has already been checked and found to be ok.
return _hinted_dcs.empty() || have_ep_manager(ep) ||
_hinted_dcs.find(_local_snitch_ptr->get_datacenter(ep)) != _hinted_dcs.end();
} catch (...) {
// if we failed to check the DC - block this hint
return false;
}
}
void manager::drain_for(gms::inet_address endpoint) {
if (_stopping) {
return;
}
manager_logger.trace("on_leave_cluster: {} is removed/decommissioned", endpoint);
with_gate(_draining_eps_gate, [this, endpoint] {
return futurize_apply([this, endpoint] () {
if (utils::fb_utilities::is_me(endpoint)) {
return parallel_for_each(_ep_managers, [] (auto& pair) {
return pair.second.stop(drain::yes).finally([&pair] {
return remove_file(pair.second.hints_dir().c_str());
});
}).finally([this] {
_ep_managers.clear();
});
} else {
ep_managers_map_type::iterator ep_manager_it = find_ep_manager(endpoint);
if (ep_manager_it != ep_managers_end()) {
return ep_manager_it->second.stop(drain::yes).finally([this, endpoint, hints_dir = ep_manager_it->second.hints_dir()] {
_ep_managers.erase(endpoint);
return remove_file(hints_dir.c_str());
});
}
return make_ready_future<>();
}
}).handle_exception([endpoint] (auto eptr) {
manager_logger.error("Exception when draining {}: {}", endpoint, eptr);
});
});
}
manager::end_point_hints_manager::sender::sender(end_point_hints_manager& parent, service::storage_proxy& local_storage_proxy, database& local_db, gms::gossiper& local_gossiper) noexcept
: _stopped(make_ready_future<>())
, _ep_key(parent.end_point_key())
, _ep_manager(parent)
, _shard_manager(_ep_manager._shard_manager)
, _resource_manager(_shard_manager._resource_manager)
, _proxy(local_storage_proxy)
, _db(local_db)
, _gossiper(local_gossiper)
, _file_update_mutex(_ep_manager.file_update_mutex())
{}
manager::end_point_hints_manager::sender::sender(const sender& other, end_point_hints_manager& parent) noexcept
: _stopped(make_ready_future<>())
, _ep_key(parent.end_point_key())
, _ep_manager(parent)
, _shard_manager(_ep_manager._shard_manager)
, _resource_manager(_shard_manager._resource_manager)
, _proxy(other._proxy)
, _db(other._db)
, _gossiper(other._gossiper)
, _file_update_mutex(_ep_manager.file_update_mutex())
{}
future<> manager::end_point_hints_manager::sender::stop(drain should_drain) noexcept {
return seastar::async([this, should_drain] {
set_stopping();
_stopped.get();
if (should_drain == drain::yes) {
// "Draining" is performed by a sequence of following calls:
// set_draining() -> send_hints_maybe() -> flush_current_hints() -> send_hints_maybe()
//
// Before sender::stop() is called the storing path for this end point is blocked and no new hints
// will be generated when this method is running.
//
// send_hints_maybe() in a "draining" mode is going to send all hints from segments in the
// _segments_to_replay.
//
// Therefore after the first call for send_hints_maybe() the _segments_to_replay is going to become empty
// and the following flush_current_hints() is going to store all in-memory hints to the disk and re-populate
// the _segments_to_replay.
//
// The next call for send_hints_maybe() will send the last hints to the current end point and when it is
// done there is going to be no more pending hints and the corresponding hints directory may be removed.
manager_logger.trace("Draining for {}: start", end_point_key());
set_draining();
send_hints_maybe();
_ep_manager.flush_current_hints().handle_exception([] (auto e) {
manager_logger.error("Failed to flush pending hints: {}. Ignoring...", e);
}).get();
send_hints_maybe();
manager_logger.trace("Draining for {}: end", end_point_key());
}
manager_logger.trace("ep_manager({})::sender: exiting", end_point_key());
});
}
void manager::end_point_hints_manager::sender::add_segment(sstring seg_name) {
_segments_to_replay.emplace_back(std::move(seg_name));
}
manager::end_point_hints_manager::sender::clock::duration manager::end_point_hints_manager::sender::next_sleep_duration() const {
clock::time_point current_time = clock::now();
clock::time_point next_flush_tp = std::max(_next_flush_tp, current_time);
clock::time_point next_retry_tp = std::max(_next_send_retry_tp, current_time);
clock::duration d = std::min(next_flush_tp, next_retry_tp) - current_time;
// Don't sleep for less than 10 ticks of the "clock" if we are planning to sleep at all - the sleep() function is not perfect.
return clock::duration(10 * div_ceil(d.count(), 10));
}
void manager::end_point_hints_manager::sender::start() {
_stopped = seastar::async([this] {
manager_logger.trace("ep_manager({})::sender: started", end_point_key());
while (!stopping()) {
try {
flush_maybe().get();
send_hints_maybe();
// If we got here means that either there are no more hints to send or we failed to send hints we have.
// In both cases it makes sense to wait a little before continuing.
sleep_abortable(next_sleep_duration()).get();
} catch (seastar::sleep_aborted&) {
break;
} catch (...) {
// log and keep on spinning
manager_logger.trace("sender: got the exception: {}", std::current_exception());
}
}
});
}
future<> manager::end_point_hints_manager::sender::send_one_mutation(mutation m) {
keyspace& ks = _db.find_keyspace(m.schema()->ks_name());
auto& rs = ks.get_replication_strategy();
std::vector natural_endpoints = rs.get_natural_endpoints(m.token());
return do_send_one_mutation(std::move(m), natural_endpoints);
}
future<> manager::end_point_hints_manager::sender::send_one_hint(lw_shared_ptr ctx_ptr, temporary_buffer buf, db::replay_position rp, gc_clock::duration secs_since_file_mod, const sstring& fname) {
return _resource_manager.get_send_units_for(buf.size()).then([this, secs_since_file_mod, &fname, buf = std::move(buf), rp, ctx_ptr] (auto units) mutable {
with_gate(ctx_ptr->file_send_gate, [this, secs_since_file_mod, &fname, buf = std::move(buf), rp, ctx_ptr] () mutable {
try {
try {
ctx_ptr->rps_set.emplace(rp);
} catch (...) {
// if we failed to insert the rp into the set then its contents can't be trusted and we have to re-send the current file from the beginning
ctx_ptr->state.set(send_state::restart_segment);
ctx_ptr->state.set(send_state::segment_replay_failed);
return make_ready_future<>();
}
mutation m = this->get_mutation(ctx_ptr, buf);
gc_clock::duration gc_grace_sec = m.schema()->gc_grace_seconds();
// The hint is too old - drop it.
//
// Files are aggregated for at most manager::hints_timer_period therefore the oldest hint there is
// (last_modification - manager::hints_timer_period) old.
if (gc_clock::now().time_since_epoch() - secs_since_file_mod > gc_grace_sec - manager::hints_flush_period) {
return make_ready_future<>();
}
return this->send_one_mutation(std::move(m)).then([this, rp, ctx_ptr] {
ctx_ptr->rps_set.erase(rp);
++this->shard_stats().sent;
}).handle_exception([this, ctx_ptr] (auto eptr) {
manager_logger.trace("send_one_hint(): failed to send to {}: {}", end_point_key(), eptr);
ctx_ptr->state.set(send_state::segment_replay_failed);
});
// ignore these errors and move on - probably this hint is too old and the KS/CF has been deleted...
} catch (no_such_column_family& e) {
manager_logger.debug("send_hints(): no_such_column_family: {}", e.what());
} catch (no_such_keyspace& e) {
manager_logger.debug("send_hints(): no_such_keyspace: {}", e.what());
} catch (no_column_mapping& e) {
manager_logger.debug("send_hints(): {}: {}", fname, e.what());
}
return make_ready_future<>();
}).finally([units = std::move(units), ctx_ptr] {});
}).handle_exception([this, ctx_ptr] (auto eptr) {
manager_logger.trace("send_one_file(): Hmmm. Something bad had happend: {}", eptr);
ctx_ptr->state.set(send_state::segment_replay_failed);
});
}
// runs in a seastar::async context
bool manager::end_point_hints_manager::sender::send_one_file(const sstring& fname) {
timespec last_mod = get_last_file_modification(fname).get0();
gc_clock::duration secs_since_file_mod = std::chrono::seconds(last_mod.tv_sec);
lw_shared_ptr ctx_ptr = make_lw_shared();
try {
auto s = commitlog::read_log_file(fname, [this, secs_since_file_mod, &fname, ctx_ptr] (temporary_buffer buf, db::replay_position rp) mutable {
// Check that we can still send the next hint. Don't try to send it if the destination host
// is DOWN or if we have already failed to send some of the previous hints.
if (!draining() && ctx_ptr->state.contains(send_state::segment_replay_failed)) {
return make_ready_future<>();
}
// Break early if stop() was called or the destination node went down.
if (!can_send()) {
ctx_ptr->state.set(send_state::segment_replay_failed);
return make_ready_future<>();
}
return flush_maybe().finally([this, ctx_ptr, buf = std::move(buf), rp, secs_since_file_mod, &fname] () mutable {
return send_one_hint(std::move(ctx_ptr), std::move(buf), rp, secs_since_file_mod, fname);
});
}, _last_not_complete_rp.pos, &_db.get_config().extensions()).get0();
s->done().get();
} catch (...) {
manager_logger.trace("sending of {} failed: {}", fname, std::current_exception());
ctx_ptr->state.set(send_state::segment_replay_failed);
}
// wait till all background hints sending is complete
ctx_ptr->file_send_gate.close().get();
// If we are draining ignore failures and drop the segment even if we failed to send it.
if (draining() && ctx_ptr->state.contains(send_state::segment_replay_failed)) {
manager_logger.trace("send_one_file(): we are draining so we are going to delete the segment anyway");
ctx_ptr->state.remove(send_state::segment_replay_failed);
}
// update the next iteration replay position if needed
if (ctx_ptr->state.contains(send_state::segment_replay_failed)) {
if (ctx_ptr->state.contains(send_state::restart_segment)) {
// if _rps_set contents is inconsistent simply re-start the current file from the beginning
_last_not_complete_rp = replay_position();
} else if (!ctx_ptr->rps_set.empty()) {
_last_not_complete_rp = *std::min_element(ctx_ptr->rps_set.begin(), ctx_ptr->rps_set.end());
}
manager_logger.trace("send_one_file(): error while sending hints from {}, last RP is {}", fname, _last_not_complete_rp);
return false;
}
// If we got here we are done with the current segment and we can remove it.
with_shared(_file_update_mutex, [&fname, this] {
auto p = _ep_manager.get_or_load().get0();
return p->delete_segments({ fname });
}).get();
// clear the replay position - we are going to send the next segment...
_last_not_complete_rp = replay_position();
manager_logger.trace("send_one_file(): segment {} was sent in full and deleted", fname);
return true;
}
// Runs in the seastar::async context
void manager::end_point_hints_manager::sender::send_hints_maybe() noexcept {
using namespace std::literals::chrono_literals;
manager_logger.trace("send_hints(): going to send hints to {}, we have {} segment to replay", end_point_key(), _segments_to_replay.size());
int replayed_segments_count = 0;
try {
while (have_segments()) {
if (!send_one_file(*_segments_to_replay.begin())) {
break;
}
_segments_to_replay.pop_front();
++replayed_segments_count;
}
// Ignore exceptions, we will retry sending this file from where we left off the next time.
// Exceptions are not expected here during the regular operation, so just log them.
} catch (...) {
manager_logger.trace("send_hints(): got the exception: {}", std::current_exception());
}
if (have_segments()) {
// TODO: come up with something more sophisticated here
_next_send_retry_tp = clock::now() + 1s;
} else {
// if there are no segments to send we want to retry when we maybe have some (after flushing)
_next_send_retry_tp = _next_flush_tp;
}
manager_logger.trace("send_hints(): we handled {} segments", replayed_segments_count);
}
// runs in seastar::async context
manager::hints_segments_map manager::get_current_hints_segments(const sstring& hints_directory) {
hints_segments_map current_hints_segments;
// shards level
lister::scan_dir(hints_directory, { directory_entry_type::directory }, [¤t_hints_segments] (lister::path dir, directory_entry de) {
unsigned shard_id = std::stoi(de.name.c_str());
manager_logger.trace("shard_id = {}", shard_id);
// IPs level
return lister::scan_dir(dir / de.name.c_str(), { directory_entry_type::directory }, [¤t_hints_segments, shard_id] (lister::path dir, directory_entry de) {
manager_logger.trace("\tIP: {}", de.name);
// hints files
return lister::scan_dir(dir / de.name.c_str(), { directory_entry_type::regular }, [¤t_hints_segments, shard_id, ep_addr = de.name] (lister::path dir, directory_entry de) {
manager_logger.trace("\t\tfile: {}", de.name);
current_hints_segments[ep_addr][shard_id].emplace_back(dir / de.name.c_str());
return make_ready_future<>();
});
});
}).get();
return current_hints_segments;
}
// runs in seastar::async context
void manager::rebalance_segments(const sstring& hints_directory, hints_segments_map& segments_map) {
// Count how many hints segments to each destination we have.
std::unordered_map per_ep_hints;
for (auto& ep_info : segments_map) {
per_ep_hints[ep_info.first] = boost::accumulate(ep_info.second | boost::adaptors::map_values | boost::adaptors::transformed(std::mem_fn(&std::list::size)), 0);
manager_logger.trace("{}: total files: {}", ep_info.first, per_ep_hints[ep_info.first]);
}
// Create a map of lists of segments that we will move (for each destination end point): if a shard has segments
// then we will NOT move q = int(N/S) segments out of them, where N is a total number of segments to the current
// destination and S is a current number of shards.
std::unordered_map> segments_to_move;
for (auto& [ep, ep_segments] : segments_map) {
size_t q = per_ep_hints[ep] / smp::count;
auto& current_segments_to_move = segments_to_move[ep];
for (auto& [shard_id, shard_segments] : ep_segments) {
// Move all segments from the shards that are no longer relevant (re-sharding to the lower number of shards)
if (shard_id >= smp::count) {
current_segments_to_move.splice(current_segments_to_move.end(), shard_segments);
} else if (shard_segments.size() > q) {
current_segments_to_move.splice(current_segments_to_move.end(), shard_segments, std::next(shard_segments.begin(), q), shard_segments.end());
}
}
}
// Since N (a total number of segments to a specific destination) may be not a multiple of S (a current number of
// shards) we will distribute files in two passes:
// * if N = S * q + r, then
// * one pass for segments_per_shard = q
// * another one for segments_per_shard = q + 1.
//
// This way we will ensure as close to the perfect distribution as possible.
//
// Right till this point we haven't moved any segments. However we have created a logical separation of segments
// into two groups:
// * Segments that are not going to be moved: segments in the segments_map.
// * Segments that are going to be moved: segments in the segments_to_move.
//
// rebalance_segments_for() is going to consume segments from segments_to_move and move them to corresponding
// lists in the segments_map AND actually move segments to the corresponding shard's sub-directory till the requested
// segments_per_shard level is reached (see more details in the description of rebalance_segments_for()).
for (auto& [ep, N] : per_ep_hints) {
size_t q = N / smp::count;
size_t r = N - q * smp::count;
auto& current_segments_to_move = segments_to_move[ep];
auto& current_segments_map = segments_map[ep];
if (q) {
rebalance_segments_for(ep, q, hints_directory, current_segments_map, current_segments_to_move);
}
if (r) {
rebalance_segments_for(ep, q + 1, hints_directory, current_segments_map, current_segments_to_move);
}
}
}
// runs in seastar::async context
void manager::rebalance_segments_for(
const sstring& ep,
size_t segments_per_shard,
const sstring& hints_directory,
hints_ep_segments_map& ep_segments,
std::list& segments_to_move)
{
manager_logger.trace("{}: segments_per_shard: {}, total number of segments to move: {}", ep, segments_per_shard, segments_to_move.size());
// sanity check
if (segments_to_move.empty() || !segments_per_shard) {
return;
}
for (unsigned i = 0; i < smp::count && !segments_to_move.empty(); ++i) {
lister::path shard_path_dir(lister::path(hints_directory.c_str()) / seastar::format("{:d}", i).c_str() / ep.c_str());
std::list& current_shard_segments = ep_segments[i];
// Make sure that the shard_path_dir exists and if not - create it
io_check(recursive_touch_directory, shard_path_dir.c_str()).get();
while (current_shard_segments.size() < segments_per_shard && !segments_to_move.empty()) {
auto seg_path_it = segments_to_move.begin();
lister::path new_path(shard_path_dir / seg_path_it->filename());
// Don't move the file to the same location - it's pointless.
if (*seg_path_it != new_path) {
manager_logger.trace("going to move: {} -> {}", *seg_path_it, new_path);
io_check(rename_file, seg_path_it->native(), new_path.native()).get();
} else {
manager_logger.trace("skipping: {}", *seg_path_it);
}
current_shard_segments.splice(current_shard_segments.end(), segments_to_move, seg_path_it, std::next(seg_path_it));
}
}
}
// runs in seastar::async context
void manager::remove_irrelevant_shards_directories(const sstring& hints_directory) {
// shards level
lister::scan_dir(hints_directory, { directory_entry_type::directory }, [] (lister::path dir, directory_entry de) {
unsigned shard_id = std::stoi(de.name.c_str());
if (shard_id >= smp::count) {
// IPs level
return lister::scan_dir(dir / de.name.c_str(), { directory_entry_type::directory, directory_entry_type::regular }, lister::show_hidden::yes, [] (lister::path dir, directory_entry de) {
return io_check(remove_file, (dir / de.name.c_str()).native());
}).then([shard_base_dir = dir, shard_entry = de] {
return io_check(remove_file, (shard_base_dir / shard_entry.name.c_str()).native());
});
}
return make_ready_future<>();
}).get();
}
future<> manager::rebalance(sstring hints_directory) {
return seastar::async([hints_directory = std::move(hints_directory)] {
// Scan currently present hints segments.
hints_segments_map current_hints_segments = get_current_hints_segments(hints_directory);
// Move segments to achieve an even distribution of files among all present shards.
rebalance_segments(hints_directory, current_hints_segments);
// Remove the directories of shards that are not present anymore - they should not have any segments by now
remove_irrelevant_shards_directories(hints_directory);
});
}
}
}