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aa375cd33dff3ff55b2eee233e023dbdca7cb709
scylladb/row_cache.cc
Paweł Dziepak f877be50b0 Merge "Keep wide partition cache entry longer than others" from Piotr 
"Cache entries for wide partitions are usually smaller than other
entries and the cost of recreating them is higher so it makes sense
to keep them longer than ordinary entries."
2016-11-15 20:44:52 +00:00

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/*
* Copyright (C) 2015 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 <http://www.gnu.org/licenses/>.
*/
#include "row_cache.hh"
#include "core/memory.hh"
#include "core/do_with.hh"
#include "core/future-util.hh"
#include <seastar/core/scollectd.hh>
#include <seastar/util/defer.hh>
#include "memtable.hh"
#include <chrono>
#include "utils/move.hh"
#include <boost/version.hpp>
using namespace std::chrono_literals;
namespace stdx = std::experimental;
static logging::logger logger("cache");
thread_local seastar::thread_scheduling_group row_cache::_update_thread_scheduling_group(1ms, 0.2);
enum class is_wide_partition { yes, no };
future<is_wide_partition, mutation_opt>
try_to_read(uint64_t max_cached_partition_size_in_bytes, streamed_mutation_opt&& sm) {
if (!sm) {
return make_ready_future<is_wide_partition, mutation_opt>(is_wide_partition::no, mutation_opt());
}
return mutation_from_streamed_mutation_with_limit(std::move(*sm), max_cached_partition_size_in_bytes).then(
[] (mutation_opt&& omo) mutable {
if (omo) {
return make_ready_future<is_wide_partition, mutation_opt>(is_wide_partition::no, std::move(omo));
} else {
return make_ready_future<is_wide_partition, mutation_opt>(is_wide_partition::yes, mutation_opt());
}
});
}
cache_tracker& global_cache_tracker() {
static thread_local cache_tracker instance;
return instance;
}
cache_tracker::cache_tracker() {
setup_collectd();
_region.make_evictable([this] {
return with_allocator(_region.allocator(), [this] {
// Removing a partition may require reading large keys when we rebalance
// the rbtree, so linearize anything we read
return with_linearized_managed_bytes([&] {
try {
auto evict_last = [this](lru_type& lru) {
cache_entry& ce = lru.back();
auto it = row_cache::partitions_type::s_iterator_to(ce);
clear_continuity(*std::next(it));
lru.pop_back_and_dispose(current_deleter<cache_entry>());
};
if (!_wide_partition_lru.empty() && (_normal_eviction_count == 0 || _lru.empty())) {
evict_last(_wide_partition_lru);
_normal_eviction_count = _normal_large_eviction_ratio;
++_wide_partition_evictions;
} else {
if (_lru.empty()) {
return memory::reclaiming_result::reclaimed_nothing;
}
evict_last(_lru);
if (_normal_eviction_count > 0) {
--_normal_eviction_count;
}
}
--_partitions;
++_evictions;
++_modification_count;
return memory::reclaiming_result::reclaimed_something;
} catch (std::bad_alloc&) {
// Bad luck, linearization during partition removal caused us to
// fail. Drop the entire cache so we can make forward progress.
clear();
return memory::reclaiming_result::reclaimed_something;
}
});
});
});
}
cache_tracker::~cache_tracker() {
clear();
}
void
cache_tracker::setup_collectd() {
_collectd_registrations = std::make_unique<scollectd::registrations>(scollectd::registrations({
scollectd::add_polled_metric(scollectd::type_instance_id("cache"
, scollectd::per_cpu_plugin_instance
, "bytes", "used")
, scollectd::make_typed(scollectd::data_type::GAUGE, [this] { return _region.occupancy().used_space(); })
),
scollectd::add_polled_metric(scollectd::type_instance_id("cache"
, scollectd::per_cpu_plugin_instance
, "bytes", "total")
, scollectd::make_typed(scollectd::data_type::GAUGE, [this] { return _region.occupancy().total_space(); })
),
scollectd::add_polled_metric(scollectd::type_instance_id("cache"
, scollectd::per_cpu_plugin_instance
, "total_operations", "hits")
, scollectd::make_typed(scollectd::data_type::DERIVE, _hits)
),
scollectd::add_polled_metric(scollectd::type_instance_id("cache"
, scollectd::per_cpu_plugin_instance
, "total_operations", "misses")
, scollectd::make_typed(scollectd::data_type::DERIVE, _misses)
),
scollectd::add_polled_metric(scollectd::type_instance_id("cache"
, scollectd::per_cpu_plugin_instance
, "total_operations", "uncached_wide_partitions")
, scollectd::make_typed(scollectd::data_type::DERIVE, _uncached_wide_partitions)
),
scollectd::add_polled_metric(scollectd::type_instance_id("cache"
, scollectd::per_cpu_plugin_instance
, "total_operations", "insertions")
, scollectd::make_typed(scollectd::data_type::DERIVE, _insertions)
),
scollectd::add_polled_metric(scollectd::type_instance_id("cache"
, scollectd::per_cpu_plugin_instance
, "total_operations", "concurrent_misses_same_key")
, scollectd::make_typed(scollectd::data_type::DERIVE, _concurrent_misses_same_key)
),
scollectd::add_polled_metric(scollectd::type_instance_id("cache"
, scollectd::per_cpu_plugin_instance
, "total_operations", "merges")
, scollectd::make_typed(scollectd::data_type::DERIVE, _merges)
),
scollectd::add_polled_metric(scollectd::type_instance_id("cache"
, scollectd::per_cpu_plugin_instance
, "total_operations", "evictions")
, scollectd::make_typed(scollectd::data_type::DERIVE, _evictions)
),
scollectd::add_polled_metric(scollectd::type_instance_id("cache"
, scollectd::per_cpu_plugin_instance
, "total_operations", "wide_partition_evictions")
, scollectd::make_typed(scollectd::data_type::DERIVE, _wide_partition_evictions)
),
scollectd::add_polled_metric(scollectd::type_instance_id("cache"
, scollectd::per_cpu_plugin_instance
, "total_operations", "removals")
, scollectd::make_typed(scollectd::data_type::DERIVE, _removals)
),
scollectd::add_polled_metric(scollectd::type_instance_id("cache"
, scollectd::per_cpu_plugin_instance
, "objects", "partitions")
, scollectd::make_typed(scollectd::data_type::GAUGE, _partitions)
),
}));
}
void cache_tracker::clear() {
with_allocator(_region.allocator(), [this] {
auto clear = [this] (lru_type& lru) {
while (!lru.empty()) {
cache_entry& ce = lru.back();
auto it = row_cache::partitions_type::s_iterator_to(ce);
while (it->is_evictable()) {
cache_entry& to_remove = *it;
++it;
to_remove._lru_link.unlink();
current_deleter<cache_entry>()(&to_remove);
}
clear_continuity(*it);
}
};
clear(_lru);
clear(_wide_partition_lru);
});
_removals += _partitions;
_partitions = 0;
++_modification_count;
}
void cache_tracker::touch(cache_entry& e) {
auto move_to_front = [this] (lru_type& lru, cache_entry& e) {
lru.erase(lru.iterator_to(e));
lru.push_front(e);
};
move_to_front(e.wide_partition() ? _wide_partition_lru : _lru, e);
}
void cache_tracker::insert(cache_entry& entry) {
++_insertions;
++_partitions;
++_modification_count;
if (entry.wide_partition()) {
_wide_partition_lru.push_front(entry);
} else {
_lru.push_front(entry);
}
}
void cache_tracker::mark_wide(cache_entry& entry) {
if (entry._lru_link.is_linked()) {
entry._lru_link.unlink();
}
entry.set_wide_partition();
_wide_partition_lru.push_front(entry);
}
void cache_tracker::on_erase() {
--_partitions;
++_removals;
++_modification_count;
}
void cache_tracker::on_merge() {
++_merges;
}
void cache_tracker::on_hit() {
++_hits;
}
void cache_tracker::on_miss() {
++_misses;
}
void cache_tracker::on_miss_already_populated() {
++_concurrent_misses_same_key;
}
void cache_tracker::on_uncached_wide_partition() {
++_uncached_wide_partitions;
}
allocation_strategy& cache_tracker::allocator() {
return _region.allocator();
}
logalloc::region& cache_tracker::region() {
return _region;
}
const logalloc::region& cache_tracker::region() const {
return _region;
}
// Reader which populates the cache using data from the delegate.
class single_partition_populating_reader final : public mutation_reader::impl {
schema_ptr _schema;
row_cache& _cache;
mutation_source& _underlying;
mutation_reader _delegate;
const io_priority_class _pc;
const query::partition_slice& _slice;
query::partition_range _large_partition_range;
mutation_reader _large_partition_reader;
tracing::trace_state_ptr _trace_state;
public:
single_partition_populating_reader(schema_ptr s, row_cache& cache, mutation_source& underlying,
mutation_reader delegate, const io_priority_class pc, const query::partition_slice& slice, tracing::trace_state_ptr trace_state)
: _schema(std::move(s))
, _cache(cache)
, _underlying(underlying)
, _delegate(std::move(delegate))
, _pc(pc)
, _slice(slice)
, _trace_state(std::move(trace_state))
{ }
virtual future<streamed_mutation_opt> operator()() override {
auto op = _cache._populate_phaser.start();
return _delegate().then([this, op = std::move(op)] (auto sm) mutable {
if (!sm) {
return make_ready_future<streamed_mutation_opt>(streamed_mutation_opt());
}
dht::decorated_key dk = sm->decorated_key();
return try_to_read(_cache._max_cached_partition_size_in_bytes, std::move(sm)).then(
[this, op = std::move(op), dk = std::move(dk)]
(is_wide_partition wide_partition, mutation_opt&& mo) {
if (wide_partition == is_wide_partition::no) {
if (mo) {
_cache.populate(*mo);
mo->upgrade(_schema);
auto ck_ranges = query::clustering_key_filter_ranges::get_ranges(*_schema, _slice, mo->key());
auto filtered_partition = mutation_partition(std::move(mo->partition()), *(mo->schema()), std::move(ck_ranges));
mo->partition() = std::move(filtered_partition);
return make_ready_future<streamed_mutation_opt>(streamed_mutation_from_mutation(std::move(*mo)));
}
return make_ready_future<streamed_mutation_opt>(streamed_mutation_opt());
} else {
_cache.on_uncached_wide_partition();
_cache.mark_partition_as_wide(dk);
_large_partition_range = query::partition_range::make_singular(std::move(dk));
_large_partition_reader = _underlying(_schema, _large_partition_range, _slice, _pc, _trace_state);
return _large_partition_reader();
}
});
});
}
};
void cache_tracker::clear_continuity(cache_entry& ce) {
ce.set_continuous(false);
}
void row_cache::on_hit() {
_stats.hits.mark();
_tracker.on_hit();
}
void row_cache::on_miss() {
_stats.misses.mark();
_tracker.on_miss();
}
void row_cache::on_uncached_wide_partition() {
_tracker.on_uncached_wide_partition();
}
class just_cache_scanning_reader final {
schema_ptr _schema;
row_cache& _cache;
row_cache::partitions_type::iterator _it;
row_cache::partitions_type::iterator _end;
const query::partition_range& _range;
stdx::optional<dht::decorated_key> _last;
uint64_t _last_reclaim_count;
size_t _last_modification_count;
const query::partition_slice& _slice;
const io_priority_class _pc;
private:
void update_iterators() {
auto cmp = cache_entry::compare(_cache._schema);
auto update_end = [&] {
if (_range.end()) {
if (_range.end()->is_inclusive()) {
_end = _cache._partitions.upper_bound(_range.end()->value(), cmp);
} else {
_end = _cache._partitions.lower_bound(_range.end()->value(), cmp);
}
} else {
_end = _cache.partitions_end();
}
};
auto reclaim_count = _cache.get_cache_tracker().region().reclaim_counter();
auto modification_count = _cache.get_cache_tracker().modification_count();
if (!_last) {
if (_range.start()) {
if (_range.start()->is_inclusive()) {
_it = _cache._partitions.lower_bound(_range.start()->value(), cmp);
} else {
_it = _cache._partitions.upper_bound(_range.start()->value(), cmp);
}
} else {
_it = _cache._partitions.begin();
}
update_end();
} else if (reclaim_count != _last_reclaim_count || modification_count != _last_modification_count) {
_it = _cache._partitions.upper_bound(*_last, cmp);
update_end();
}
_last_reclaim_count = reclaim_count;
_last_modification_count = modification_count;
}
public:
struct cache_data {
streamed_mutation_opt mut;
bool continuous;
};
just_cache_scanning_reader(schema_ptr s, row_cache& cache, const query::partition_range& range,
const query::partition_slice& slice, const io_priority_class& pc)
: _schema(std::move(s)), _cache(cache), _range(range), _slice(slice), _pc(pc)
{ }
future<cache_data> operator()() {
return _cache._read_section(_cache._tracker.region(), [this] {
return with_linearized_managed_bytes([&] {
update_iterators();
if (_it == _end) {
return make_ready_future<cache_data>(cache_data { {}, _it->continuous() });
}
auto& ce = *_it;
++_it;
_last = ce.key();
_cache.upgrade_entry(ce);
_cache._tracker.touch(ce);
_cache.on_hit();
cache_data cd { { }, ce.continuous() };
if (ce.wide_partition()) {
return ce.read_wide(_cache, _schema, _slice, _pc).then([this, cd = std::move(cd)] (auto smopt) mutable {
if (smopt) {
cd.mut = std::move(*smopt);
} else {
cd.mut = streamed_mutation_from_mutation(mutation(*_last, _schema));
}
return std::move(cd);
});
}
cd.mut = ce.read(_cache, _schema, _slice);
return make_ready_future<cache_data>(std::move(cd));
});
});
}
};
class range_populating_reader {
row_cache& _cache;
schema_ptr _schema;
query::partition_range _range;
const query::partition_slice& _slice;
utils::phased_barrier::phase_type _populate_phase;
const io_priority_class& _pc;
tracing::trace_state_ptr _trace_state;
mutation_reader _reader;
bool _reader_created = false;
row_cache::previous_entry_pointer _last_key;
query::partition_range _large_partition_range;
mutation_reader _large_partition_reader;
private:
void update_reader() {
// TODO: allow updating sstables without fully recreating the reader
if (_populate_phase != _cache._populate_phaser.phase()) {
_populate_phase = _cache._populate_phaser.phase();
if (_last_key._key) {
auto cmp = dht::ring_position_comparator(*_schema);
auto&& new_range = _range.split_after(*_last_key._key, cmp);
if (new_range) {
_range = std::move(new_range).value();
} else {
_reader = make_empty_reader();
_reader_created = false;
return;
}
}
_reader = _cache._underlying(_cache._schema, _range, query::full_slice, _pc, _trace_state);
}
}
future<streamed_mutation_opt> handle_large_partition(dht::decorated_key&& dk) {
_cache.on_uncached_wide_partition();
_cache.mark_partition_as_wide(dk, &_last_key);
_last_key.reset(dk, _populate_phase);
_large_partition_range = query::partition_range::make_singular(dk);
_large_partition_reader = _cache._underlying(_schema, _large_partition_range, _slice, _pc, _trace_state);
return _large_partition_reader().then([this, dk = std::move(dk)] (auto smopt) mutable -> streamed_mutation_opt {
_large_partition_reader = {};
if (!smopt) {
// We cannot emit disengaged optional since this is a part of range
// read and it would incorrectly interpreted as end of stream.
// Produce empty mutation instead.
return streamed_mutation_from_mutation(mutation(std::move(dk), _schema));
}
return smopt;
});
}
void handle_end_of_stream() {
if (_last_key._populate_phase != _populate_phase) {
return;
}
if (!_range.end() || !_range.end()->is_inclusive()) {
cache_entry::compare cmp(_cache._schema);
auto it = _range.end() ? _cache._partitions.find(_range.end()->value(), cmp)
: std::prev(_cache._partitions.end());
if (it != _cache._partitions.end()) {
if (it == _cache._partitions.begin()) {
if (!_last_key._key) {
it->set_continuous(true);
}
} else {
auto prev = std::prev(it);
if (prev->key().equal(*_cache._schema, *_last_key._key)) {
it->set_continuous(true);
}
}
}
}
}
public:
range_populating_reader(
row_cache& cache,
schema_ptr schema,
const query::partition_slice& slice,
const io_priority_class& pc,
tracing::trace_state_ptr trace_state)
: _cache(cache)
, _schema(std::move(schema))
, _slice(slice)
, _pc(pc)
, _trace_state(std::move(trace_state))
{}
future<streamed_mutation_opt> operator()() {
update_reader();
return _reader().then([this, op = _cache._populate_phaser.start()] (streamed_mutation_opt smopt) mutable {
dht::decorated_key dk = smopt ? smopt->decorated_key() : dht::decorated_key{ {}, partition_key::make_empty() };
return try_to_read(_cache._max_cached_partition_size_in_bytes, std::move(smopt)).then(
[this, op = std::move(op), dk = std::move(dk)] (is_wide_partition is_wide, mutation_opt&& mo) mutable {
if (is_wide == is_wide_partition::yes) {
_cache.on_miss();
return handle_large_partition(std::move(dk));
}
if (!mo) {
handle_end_of_stream();
return make_ready_future<streamed_mutation_opt>();
}
_cache.on_miss();
_cache.populate(*mo, &_last_key);
_last_key.reset(mo->decorated_key(), _populate_phase);
mo->upgrade(_schema);
auto ck_ranges = query::clustering_key_filter_ranges::get_ranges(*_schema, _slice, mo->key());
auto filtered_partition = mutation_partition(std::move(mo->partition()), *mo->schema(), std::move(ck_ranges));
mo->partition() = std::move(filtered_partition);
return make_ready_future<streamed_mutation_opt>(streamed_mutation_from_mutation(std::move(*mo)));
});
});
}
future<> fast_forward_to(const query::partition_range& pr) {
_range = pr;
auto phase = _cache._populate_phaser.phase();
if (!_range.start()) {
_last_key.reset({ }, phase);
} else if (!_range.start()->is_inclusive() && _range.start()->value().has_key()) {
_last_key.reset(_range.start()->value().as_decorated_key(), phase);
} else {
// Inclusive start bound, cannot set continuity flag.
_last_key.reset(stdx::nullopt, phase - 1);
}
if (!_reader_created || phase != _populate_phase) {
_populate_phase = _cache._populate_phaser.phase();
_reader = _cache._underlying(_cache._schema, _range, query::full_slice, _pc, _trace_state);
_reader_created = true;
return make_ready_future();
}
return _reader.fast_forward_to(_range);
}
};
class scanning_and_populating_reader final : public mutation_reader::impl {
const query::partition_range& _pr;
schema_ptr _schema;
query::partition_range _secondary_range;
just_cache_scanning_reader _primary_reader;
range_populating_reader _secondary_reader;
streamed_mutation_opt _next_primary;
bool _secondary_in_progress = false;
bool _first_element = true;
stdx::optional<dht::decorated_key> _last_key;
private:
void update_last_key(const streamed_mutation_opt& smopt) {
if (smopt) {
_last_key = smopt->decorated_key();
}
}
bool is_inclusive_start_bound(const dht::decorated_key& dk) {
if (!_first_element) {
return false;
}
return _pr.start() && _pr.start()->is_inclusive() && _pr.start()->value().equal(*_schema, dk);
}
future<streamed_mutation_opt> read_from_primary() {
return _primary_reader().then([this] (just_cache_scanning_reader::cache_data cd) {
auto& smopt = cd.mut;
if (cd.continuous || (smopt && is_inclusive_start_bound(smopt->decorated_key()))) {
_first_element = false;
update_last_key(smopt);
return make_ready_future<streamed_mutation_opt>(std::move(smopt));
} else {
_next_primary = std::move(smopt);
if (!_next_primary) {
if (!_last_key) {
_secondary_range = _pr;
} else {
dht::ring_position_comparator cmp(*_schema);
auto&& new_range = _pr.split_after(*_last_key, cmp);
if (!new_range) {
return make_ready_future<streamed_mutation_opt>();
}
_secondary_range = std::move(*new_range);
}
} else {
if (_last_key) {
_secondary_range = query::partition_range::make({ *_last_key, false }, { _next_primary->decorated_key(), false });
} else {
if (!_pr.start()) {
_secondary_range = query::partition_range::make_ending_with({ _next_primary->decorated_key(), false });
} else {
_secondary_range = query::partition_range::make(*_pr.start(), { _next_primary->decorated_key(), false });
}
}
}
_secondary_in_progress = true;
return _secondary_reader.fast_forward_to(_secondary_range).then([this] {
return read_from_secondary();
});
}
});
}
future<streamed_mutation_opt> read_from_secondary() {
return _secondary_reader().then([this] (streamed_mutation_opt smopt) {
if (smopt) {
return smopt;
} else {
_secondary_in_progress = false;
update_last_key(_next_primary);
return std::move(_next_primary);
}
});
}
public:
scanning_and_populating_reader(schema_ptr s,
row_cache& cache,
const query::partition_range& range,
const query::partition_slice& slice,
const io_priority_class& pc,
tracing::trace_state_ptr trace_state)
: _pr(range)
, _schema(s)
, _primary_reader(s, cache, range, slice, pc)
, _secondary_reader(cache, s, slice, pc, trace_state)
{ }
future<streamed_mutation_opt> operator()() {
if (_secondary_in_progress) {
return read_from_secondary();
} else {
return read_from_primary();
}
}
};
mutation_reader
row_cache::make_scanning_reader(schema_ptr s,
const query::partition_range& range,
const io_priority_class& pc,
const query::partition_slice& slice,
tracing::trace_state_ptr trace_state) {
return make_mutation_reader<scanning_and_populating_reader>(std::move(s), *this, range, slice, pc, std::move(trace_state));
}
mutation_reader
row_cache::make_reader(schema_ptr s,
const query::partition_range& range,
const query::partition_slice& slice,
const io_priority_class& pc,
tracing::trace_state_ptr trace_state) {
if (range.is_singular()) {
const query::ring_position& pos = range.start()->value();
if (!pos.has_key()) {
return make_scanning_reader(std::move(s), range, pc, slice, std::move(trace_state));
}
return _read_section(_tracker.region(), [&] {
return with_linearized_managed_bytes([&] {
const dht::decorated_key& dk = pos.as_decorated_key();
auto i = _partitions.find(dk, cache_entry::compare(_schema));
if (i != _partitions.end()) {
cache_entry& e = *i;
_tracker.touch(e);
upgrade_entry(e);
mutation_reader reader;
if (e.wide_partition()) {
reader = _underlying(s, range, slice, pc, std::move(trace_state));
_tracker.on_uncached_wide_partition();
} else {
reader = make_reader_returning(e.read(*this, s, slice));
}
on_hit();
return reader;
} else {
auto reader = make_mutation_reader<single_partition_populating_reader>(s, *this, _underlying,
_underlying(_schema, range, query::full_slice, pc, trace_state), pc, slice, trace_state);
on_miss();
return reader;
}
});
});
}
return make_scanning_reader(std::move(s), range, pc, slice, std::move(trace_state));
}
row_cache::~row_cache() {
with_allocator(_tracker.allocator(), [this] {
_partitions.clear_and_dispose([this, deleter = current_deleter<cache_entry>()] (auto&& p) mutable {
if (!p->is_dummy_entry()) {
_tracker.on_erase();
}
deleter(p);
});
});
}
void row_cache::clear_now() noexcept {
with_allocator(_tracker.allocator(), [this] {
auto it = _partitions.erase_and_dispose(_partitions.begin(), partitions_end(), [this, deleter = current_deleter<cache_entry>()] (auto&& p) mutable {
_tracker.on_erase();
deleter(p);
});
_tracker.clear_continuity(*it);
});
}
template<typename CreateEntry, typename VisitEntry>
//requires requires(CreateEntry create, VisitEntry visit, row_cache::partitions_type::iterator it) {
// { create(it) } -> row_cache::partitions_type::iterator;
// { visit(it) } -> void;
// }
void row_cache::do_find_or_create_entry(const dht::decorated_key& key,
const previous_entry_pointer* previous, CreateEntry&& create_entry, VisitEntry&& visit_entry)
{
with_allocator(_tracker.allocator(), [&] {
_populate_section(_tracker.region(), [&] {
with_linearized_managed_bytes([&] {
auto i = _partitions.lower_bound(key, cache_entry::compare(_schema));
if (i == _partitions.end() || !i->key().equal(*_schema, key)) {
i = create_entry(i);
} else {
visit_entry(i);
}
if (!previous || previous->_populate_phase != _populate_phaser.phase()) {
return;
}
if ((!previous->_key && i == _partitions.begin())
|| (previous->_key && i != _partitions.begin()
&& std::prev(i)->key().equal(*_schema, *previous->_key))) {
i->set_continuous(true);
}
});
});
});
}
void row_cache::mark_partition_as_wide(const dht::decorated_key& key, const previous_entry_pointer* previous) {
do_find_or_create_entry(key, previous, [&] (auto i) {
cache_entry* entry = current_allocator().construct<cache_entry>(
_schema, key, cache_entry::wide_partition_tag{});
_tracker.insert(*entry);
return _partitions.insert(i, *entry);
}, [&] (auto i) {
_tracker.mark_wide(*i);
});
}
void row_cache::populate(const mutation& m, const previous_entry_pointer* previous) {
do_find_or_create_entry(m.decorated_key(), previous, [&] (auto i) {
cache_entry* entry = current_allocator().construct<cache_entry>(
m.schema(), m.decorated_key(), m.partition());
upgrade_entry(*entry);
_tracker.insert(*entry);
return _partitions.insert(i, *entry);
}, [&] (auto i) {
_tracker.touch(*i);
// We cache whole partitions right now, so if cache already has this partition,
// it must be complete, so do nothing.
_tracker.on_miss_already_populated(); // #1534
});
}
future<> row_cache::clear() {
return invalidate(query::full_partition_range);
}
future<> row_cache::update(memtable& m, partition_presence_checker presence_checker) {
_tracker.region().merge(m); // Now all data in memtable belongs to cache
auto attr = seastar::thread_attributes();
attr.scheduling_group = &_update_thread_scheduling_group;
auto t = seastar::thread(attr, [this, &m, presence_checker = std::move(presence_checker)] {
auto cleanup = defer([&] {
with_allocator(_tracker.allocator(), [&m, this] () {
logalloc::reclaim_lock _(_tracker.region());
bool blow_cache = false;
// Note: clear_and_dispose() ought not to look up any keys, so it doesn't require
// with_linearized_managed_bytes(), but invalidate() does.
m.partitions.clear_and_dispose([this, deleter = current_deleter<memtable_entry>(), &blow_cache] (memtable_entry* entry) {
with_linearized_managed_bytes([&] {
try {
invalidate_locked(entry->key());
} catch (...) {
blow_cache = true;
}
deleter(entry);
});
});
if (blow_cache) {
// We failed to invalidate the key, presumably due to with_linearized_managed_bytes()
// running out of memory. Recover using clear_now(), which doesn't throw.
clear_now();
}
});
});
_populate_phaser.advance_and_await().get();
while (!m.partitions.empty()) {
with_allocator(_tracker.allocator(), [this, &m, &presence_checker] () {
unsigned quota = 30;
auto cmp = cache_entry::compare(_schema);
{
_update_section(_tracker.region(), [&] {
auto i = m.partitions.begin();
while (i != m.partitions.end() && quota) {
with_linearized_managed_bytes([&] {
{
memtable_entry& mem_e = *i;
// FIXME: Optimize knowing we lookup in-order.
auto cache_i = _partitions.lower_bound(mem_e.key(), cmp);
// If cache doesn't contain the entry we cannot insert it because the mutation may be incomplete.
// FIXME: keep a bitmap indicating which sstables we do cover, so we don't have to
// search it.
if (cache_i != partitions_end() && cache_i->key().equal(*_schema, mem_e.key())) {
if (!cache_i->wide_partition()) {
cache_entry& entry = *cache_i;
upgrade_entry(entry);
entry.partition().apply(*_schema, std::move(mem_e.partition()), *mem_e.schema());
_tracker.touch(entry);
_tracker.on_merge();
}
} else if (presence_checker(mem_e.key().key()) ==
partition_presence_checker_result::definitely_doesnt_exist) {
cache_entry* entry = current_allocator().construct<cache_entry>(
mem_e.schema(), std::move(mem_e.key()), std::move(mem_e.partition()));
_tracker.insert(*entry);
_partitions.insert(cache_i, *entry);
} else {
_tracker.clear_continuity(*cache_i);
}
i = m.partitions.erase(i);
current_allocator().destroy(&mem_e);
--quota;
}
});
}
});
if (quota == 0 && seastar::thread::should_yield()) {
return;
}
}
});
seastar::thread::yield();
}
});
return do_with(std::move(t), [] (seastar::thread& t) {
return t.join();
});
}
void row_cache::touch(const dht::decorated_key& dk) {
_read_section(_tracker.region(), [&] {
with_linearized_managed_bytes([&] {
auto i = _partitions.find(dk, cache_entry::compare(_schema));
if (i != _partitions.end()) {
_tracker.touch(*i);
}
});
});
}
void row_cache::invalidate_locked(const dht::decorated_key& dk) {
auto pos = _partitions.lower_bound(dk, cache_entry::compare(_schema));
if (pos == partitions_end() || !pos->key().equal(*_schema, dk)) {
_tracker.clear_continuity(*pos);
} else {
auto it = _partitions.erase_and_dispose(pos,
[this, &dk, deleter = current_deleter<cache_entry>()](auto&& p) mutable {
_tracker.on_erase();
deleter(p);
});
_tracker.clear_continuity(*it);
}
}
future<> row_cache::invalidate(const dht::decorated_key& dk) {
return _populate_phaser.advance_and_await().then([this, &dk] {
_read_section(_tracker.region(), [&] {
with_allocator(_tracker.allocator(), [this, &dk] {
with_linearized_managed_bytes([&] {
invalidate_locked(dk);
});
});
});
});
}
future<> row_cache::invalidate(const query::partition_range& range) {
return _populate_phaser.advance_and_await().then([this, &range] {
with_linearized_managed_bytes([&] {
invalidate_unwrapped(range);
});
});
}
void row_cache::invalidate_unwrapped(const query::partition_range& range) {
logalloc::reclaim_lock _(_tracker.region());
auto cmp = cache_entry::compare(_schema);
auto begin = _partitions.begin();
if (range.start()) {
if (range.start()->is_inclusive()) {
begin = _partitions.lower_bound(range.start()->value(), cmp);
} else {
begin = _partitions.upper_bound(range.start()->value(), cmp);
}
}
auto end = partitions_end();
if (range.end()) {
if (range.end()->is_inclusive()) {
end = _partitions.upper_bound(range.end()->value(), cmp);
} else {
end = _partitions.lower_bound(range.end()->value(), cmp);
}
}
with_allocator(_tracker.allocator(), [this, begin, end] {
auto it = _partitions.erase_and_dispose(begin, end, [this, deleter = current_deleter<cache_entry>()] (auto&& p) mutable {
_tracker.on_erase();
deleter(p);
});
assert(it != _partitions.end());
_tracker.clear_continuity(*it);
});
}
row_cache::row_cache(schema_ptr s, mutation_source fallback_factory,
cache_tracker& tracker, uint64_t max_cached_partition_size_in_bytes)
: _tracker(tracker)
, _schema(std::move(s))
, _partitions(cache_entry::compare(_schema))
, _underlying(std::move(fallback_factory))
, _max_cached_partition_size_in_bytes(max_cached_partition_size_in_bytes)
{
with_allocator(_tracker.allocator(), [this] {
cache_entry* entry = current_allocator().construct<cache_entry>(cache_entry::dummy_entry_tag());
_partitions.insert(*entry);
});
}
cache_entry::cache_entry(cache_entry&& o) noexcept
: _schema(std::move(o._schema))
, _key(std::move(o._key))
, _pe(std::move(o._pe))
, _flags(o._flags)
, _lru_link()
, _cache_link()
{
if (o._lru_link.is_linked()) {
auto prev = o._lru_link.prev_;
o._lru_link.unlink();
cache_tracker::lru_type::node_algorithms::link_after(prev, _lru_link.this_ptr());
}
{
using container_type = row_cache::partitions_type;
container_type::node_algorithms::replace_node(o._cache_link.this_ptr(), _cache_link.this_ptr());
container_type::node_algorithms::init(o._cache_link.this_ptr());
}
}
void row_cache::set_schema(schema_ptr new_schema) noexcept {
_schema = std::move(new_schema);
}
future<streamed_mutation_opt> cache_entry::read_wide(row_cache& rc, schema_ptr s, const query::partition_slice& slice, const io_priority_class& pc) {
struct range_and_underlyig_reader {
query::partition_range _range;
mutation_reader _reader;
range_and_underlyig_reader(row_cache& rc, schema_ptr s, query::partition_range pr,
const query::partition_slice& slice, const io_priority_class& pc)
: _range(std::move(pr))
, _reader(rc._underlying(s, _range, slice, pc))
{ }
};
rc._tracker.on_uncached_wide_partition();
auto pr = query::partition_range::make_singular(_key);
return do_with(range_and_underlyig_reader(rc, s, std::move(pr), slice, pc), [] (auto& r_a_ur) {
return r_a_ur._reader();
});
}
streamed_mutation cache_entry::read(row_cache& rc, const schema_ptr& s) {
return read(rc, s, query::full_slice);
}
streamed_mutation cache_entry::read(row_cache& rc, const schema_ptr& s, const query::partition_slice& slice) {
assert(!wide_partition());
if (_schema->version() != s->version()) {
auto ck_ranges = query::clustering_key_filter_ranges::get_ranges(*s, slice, _key.key());
auto mp = mutation_partition(_pe.squashed(_schema, s), *s, std::move(ck_ranges));
auto m = mutation(s, _key, std::move(mp));
return streamed_mutation_from_mutation(std::move(m));
}
auto ckr = query::clustering_key_filter_ranges::get_ranges(*s, slice, _key.key());
auto snp = _pe.read(_schema);
return make_partition_snapshot_reader(_schema, _key, std::move(ckr), snp, rc._tracker.region(), rc._read_section, { });
}
const schema_ptr& row_cache::schema() const {
return _schema;
}
void row_cache::upgrade_entry(cache_entry& e) {
if (e._schema != _schema) {
if (e.wide_partition()) {
e._schema = _schema;
return;
}
auto& r = _tracker.region();
assert(!r.reclaiming_enabled());
with_allocator(r.allocator(), [this, &e] {
with_linearized_managed_bytes([&] {
e.partition().upgrade(e._schema, _schema);
e._schema = _schema;
});
});
}
}
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