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cf193f4b418ff3fb3ef78f4e89a6e09d64e8bbc9
scylladb/cql3/statements/batch_statement.cc
Calle Wilund 0a4edca756 counters/cql: allow wormholing actual counter values (with shards) via cql 
Adds yet another magic function "SCYLLA_COUNTER_SHARD_LIST", indicating that
argument value, which must be a list of tuples <int, UUID, long, long>,
should be inserted as an actual counter value, not update.

This of course to allow counters to be read from sstable loader.

Note that we also need to allow timestamps for counter mutations,
as well as convince the counter code itself to treat the data as
already baked. So ugly wormhole galore.

v2:
* Changed flag names
* More explicit wormholing, bypassing normal counter path, to
  avoid read-before-write etc
* throw exceptions on unhandled shard types in marshalling
v3:
* Added counter id ordering check
* Added batch statement check for mixing normal and raw counter updates
Message-Id: <1487683665-23426-2-git-send-email-calle@scylladb.com>
2017-02-22 09:19:46 +00:00

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/*
* Licensed to the Apache Software Foundation (ASF) under one
* or more contributor license agreements. See the NOTICE file
* distributed with this work for additional information
* regarding copyright ownership. The ASF licenses this file
* to you under the Apache License, Version 2.0 (the
* "License"); you may not use this file except in compliance
* with the License. You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/*
* Modified by ScyllaDB
* 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 "batch_statement.hh"
#include "raw/batch_statement.hh"
#include "db/config.hh"
namespace {
struct mutation_equals_by_key {
bool operator()(const mutation& m1, const mutation& m2) const {
return m1.schema() == m2.schema()
&& m1.decorated_key().equal(*m1.schema(), m2.decorated_key());
}
};
struct mutation_hash_by_key {
size_t operator()(const mutation& m) const {
auto dk_hash = std::hash<dht::decorated_key>();
return dk_hash(m.decorated_key());
}
};
}
namespace cql3 {
namespace statements {
logging::logger batch_statement::_logger("BatchStatement");
batch_statement::batch_statement(int bound_terms, type type_,
std::vector<shared_ptr<modification_statement>> statements,
std::unique_ptr<attributes> attrs,
cql_stats& stats)
: _bound_terms(bound_terms), _type(type_), _statements(std::move(statements))
, _attrs(std::move(attrs))
, _has_conditions(boost::algorithm::any_of(_statements, std::mem_fn(&modification_statement::has_conditions)))
, _stats(stats)
{
}
bool batch_statement::uses_function(const sstring& ks_name, const sstring& function_name) const
{
return _attrs->uses_function(ks_name, function_name)
|| boost::algorithm::any_of(_statements, [&] (auto&& s) { return s->uses_function(ks_name, function_name); });
}
bool batch_statement::depends_on_keyspace(const sstring& ks_name) const
{
return false;
}
bool batch_statement::depends_on_column_family(const sstring& cf_name) const
{
return false;
}
uint32_t batch_statement::get_bound_terms()
{
return _bound_terms;
}
future<> batch_statement::check_access(const service::client_state& state)
{
return parallel_for_each(_statements.begin(), _statements.end(), [&state](auto&& s) {
return s->check_access(state);
});
}
void batch_statement::validate()
{
if (_attrs->is_time_to_live_set()) {
throw exceptions::invalid_request_exception("Global TTL on the BATCH statement is not supported.");
}
bool timestamp_set = _attrs->is_timestamp_set();
if (timestamp_set) {
if (_has_conditions) {
throw exceptions::invalid_request_exception("Cannot provide custom timestamp for conditional BATCH");
}
if (_type == type::COUNTER) {
throw exceptions::invalid_request_exception("Cannot provide custom timestamp for counter BATCH");
}
}
bool has_counters = boost::algorithm::any_of(_statements, std::mem_fn(&modification_statement::is_counter));
bool has_non_counters = !boost::algorithm::all_of(_statements, std::mem_fn(&modification_statement::is_counter));
if (timestamp_set && has_counters) {
throw exceptions::invalid_request_exception("Cannot provide custom timestamp for a BATCH containing counters");
}
if (timestamp_set && boost::algorithm::any_of(_statements, std::mem_fn(&modification_statement::is_timestamp_set))) {
throw exceptions::invalid_request_exception("Timestamp must be set either on BATCH or individual statements");
}
if (_type == type::COUNTER && has_non_counters) {
throw exceptions::invalid_request_exception("Cannot include non-counter statement in a counter batch");
}
if (_type == type::LOGGED && has_counters) {
throw exceptions::invalid_request_exception("Cannot include a counter statement in a logged batch");
}
if (has_counters && has_non_counters) {
throw exceptions::invalid_request_exception("Counter and non-counter mutations cannot exist in the same batch");
}
if (_has_conditions
&& !_statements.empty()
&& (boost::distance(_statements
| boost::adaptors::transformed(std::mem_fn(&modification_statement::keyspace))
| boost::adaptors::uniqued) != 1
|| (boost::distance(_statements
| boost::adaptors::transformed(std::mem_fn(&modification_statement::column_family))
| boost::adaptors::uniqued) != 1))) {
throw exceptions::invalid_request_exception("Batch with conditions cannot span multiple tables");
}
std::experimental::optional<bool> raw_counter;
for (auto& s : _statements) {
if (raw_counter && s->is_raw_counter_shard_write() != *raw_counter) {
throw exceptions::invalid_request_exception("Cannot mix raw and regular counter statements in batch");
}
raw_counter = s->is_raw_counter_shard_write();
}
}
void batch_statement::validate(distributed<service::storage_proxy>& proxy, const service::client_state& state)
{
for (auto&& s : _statements) {
s->validate(proxy, state);
}
}
const std::vector<shared_ptr<modification_statement>>& batch_statement::get_statements()
{
return _statements;
}
future<std::vector<mutation>> batch_statement::get_mutations(distributed<service::storage_proxy>& storage, const query_options& options, bool local, api::timestamp_type now, tracing::trace_state_ptr trace_state) {
// Do not process in parallel because operations like list append/prepend depend on execution order.
using mutation_set_type = std::unordered_set<mutation, mutation_hash_by_key, mutation_equals_by_key>;
return do_with(mutation_set_type(), [this, &storage, &options, now, local, trace_state] (auto& result) {
result.reserve(_statements.size());
_stats.statements_in_batches += _statements.size();
return do_for_each(boost::make_counting_iterator<size_t>(0),
boost::make_counting_iterator<size_t>(_statements.size()),
[this, &storage, &options, now, local, &result, trace_state] (size_t i) {
auto&& statement = _statements[i];
statement->inc_cql_stats();
auto&& statement_options = options.for_statement(i);
auto timestamp = _attrs->get_timestamp(now, statement_options);
return statement->get_mutations(storage, statement_options, local, timestamp, trace_state).then([&result] (auto&& more) {
for (auto&& m : more) {
// We want unordered_set::try_emplace(), but we don't have it
auto pos = result.find(m);
if (pos == result.end()) {
result.emplace(std::move(m));
} else {
const_cast<mutation&>(*pos).apply(std::move(m)); // Won't change key
}
}
});
}).then([&result] {
// can't use range adaptors, because we want to move
auto vresult = std::vector<mutation>();
vresult.reserve(result.size());
for (auto&& m : result) {
vresult.push_back(std::move(m));
}
return vresult;
});
});
}
void batch_statement::verify_batch_size(const std::vector<mutation>& mutations) {
size_t warn_threshold = service::get_local_storage_proxy().get_db().local().get_config().batch_size_warn_threshold_in_kb() * 1024;
class my_partition_visitor : public mutation_partition_visitor {
public:
void accept_partition_tombstone(tombstone) override {}
void accept_static_cell(column_id, atomic_cell_view v) override {
size += v.value().size();
}
void accept_static_cell(column_id, collection_mutation_view v) override {
size += v.data.size();
}
void accept_row_tombstone(const range_tombstone&) override {}
void accept_row(clustering_key_view, tombstone, const row_marker&) override {}
void accept_row_cell(column_id, atomic_cell_view v) override {
size += v.value().size();
}
void accept_row_cell(column_id id, collection_mutation_view v) override {
size += v.data.size();
}
size_t size = 0;
};
my_partition_visitor v;
for (auto&m : mutations) {
m.partition().accept(*m.schema(), v);
}
if (v.size > warn_threshold) {
std::unordered_set<sstring> ks_cf_pairs;
for (auto&& m : mutations) {
ks_cf_pairs.insert(m.schema()->ks_name() + "." + m.schema()->cf_name());
}
_logger.warn(
"Batch of prepared statements for {} is of size {}, exceeding specified threshold of {} by {}.{}",
join(", ", ks_cf_pairs), v.size, warn_threshold,
v.size - warn_threshold, "");
}
}
future<shared_ptr<transport::messages::result_message>> batch_statement::execute(
distributed<service::storage_proxy>& storage, service::query_state& state, const query_options& options) {
++_stats.batches;
return execute(storage, state, options, false, options.get_timestamp(state));
}
future<shared_ptr<transport::messages::result_message>> batch_statement::execute(
distributed<service::storage_proxy>& storage,
service::query_state& query_state, const query_options& options,
bool local, api::timestamp_type now)
{
// FIXME: we don't support nulls here
#if 0
if (options.get_consistency() == null)
throw new InvalidRequestException("Invalid empty consistency level");
if (options.getSerialConsistency() == null)
throw new InvalidRequestException("Invalid empty serial consistency level");
#endif
if (_has_conditions) {
return execute_with_conditions(storage, options, query_state);
}
return get_mutations(storage, options, local, now, query_state.get_trace_state()).then([this, &storage, &options, tr_state = query_state.get_trace_state()] (std::vector<mutation> ms) mutable {
return execute_without_conditions(storage, std::move(ms), options.get_consistency(), std::move(tr_state));
}).then([] {
return make_ready_future<shared_ptr<transport::messages::result_message>>(
make_shared<transport::messages::result_message::void_message>());
});
}
future<> batch_statement::execute_without_conditions(
distributed<service::storage_proxy>& storage,
std::vector<mutation> mutations,
db::consistency_level cl,
tracing::trace_state_ptr tr_state)
{
// FIXME: do we need to do this?
#if 0
// Extract each collection of cfs from it's IMutation and then lazily concatenate all of them into a single Iterable.
Iterable<ColumnFamily> cfs = Iterables.concat(Iterables.transform(mutations, new Function<IMutation, Collection<ColumnFamily>>()
{
public Collection<ColumnFamily> apply(IMutation im)
{
return im.getColumnFamilies();
}
}));
#endif
verify_batch_size(mutations);
bool mutate_atomic = true;
if (_type != type::LOGGED) {
_stats.batches_pure_unlogged += 1;
mutate_atomic = false;
} else {
if (mutations.size() > 1) {
_stats.batches_pure_logged += 1;
} else {
_stats.batches_unlogged_from_logged += 1;
mutate_atomic = false;
}
}
return storage.local().mutate_with_triggers(std::move(mutations), cl, mutate_atomic, std::move(tr_state));
}
future<shared_ptr<transport::messages::result_message>> batch_statement::execute_with_conditions(
distributed<service::storage_proxy>& storage,
const query_options& options,
service::query_state& state)
{
fail(unimplemented::cause::LWT);
#if 0
auto now = state.get_timestamp();
ByteBuffer key = null;
String ksName = null;
String cfName = null;
CQL3CasRequest casRequest = null;
Set<ColumnDefinition> columnsWithConditions = new LinkedHashSet<>();
for (int i = 0; i < statements.size(); i++)
{
ModificationStatement statement = statements.get(i);
QueryOptions statementOptions = options.forStatement(i);
long timestamp = attrs.getTimestamp(now, statementOptions);
List<ByteBuffer> pks = statement.buildPartitionKeyNames(statementOptions);
if (pks.size() > 1)
throw new IllegalArgumentException("Batch with conditions cannot span multiple partitions (you cannot use IN on the partition key)");
if (key == null)
{
key = pks.get(0);
ksName = statement.cfm.ksName;
cfName = statement.cfm.cfName;
casRequest = new CQL3CasRequest(statement.cfm, key, true);
}
else if (!key.equals(pks.get(0)))
{
throw new InvalidRequestException("Batch with conditions cannot span multiple partitions");
}
Composite clusteringPrefix = statement.createClusteringPrefix(statementOptions);
if (statement.hasConditions())
{
statement.addConditions(clusteringPrefix, casRequest, statementOptions);
// As soon as we have a ifNotExists, we set columnsWithConditions to null so that everything is in the resultSet
if (statement.hasIfNotExistCondition() || statement.hasIfExistCondition())
columnsWithConditions = null;
else if (columnsWithConditions != null)
Iterables.addAll(columnsWithConditions, statement.getColumnsWithConditions());
}
casRequest.addRowUpdate(clusteringPrefix, statement, statementOptions, timestamp);
}
ColumnFamily result = StorageProxy.cas(ksName, cfName, key, casRequest, options.getSerialConsistency(), options.getConsistency(), state.getClientState());
return new ResultMessage.Rows(ModificationStatement.buildCasResultSet(ksName, key, cfName, result, columnsWithConditions, true, options.forStatement(0)));
#endif
}
future<shared_ptr<transport::messages::result_message>> batch_statement::execute_internal(
distributed<service::storage_proxy>& proxy,
service::query_state& query_state, const query_options& options)
{
throw std::runtime_error(sprint("%s not implemented", __PRETTY_FUNCTION__));
#if 0
assert !hasConditions;
for (IMutation mutation : getMutations(BatchQueryOptions.withoutPerStatementVariables(options), true, queryState.getTimestamp()))
{
// We don't use counters internally.
assert mutation instanceof Mutation;
((Mutation) mutation).apply();
}
return null;
#endif
}
namespace raw {
shared_ptr<prepared_statement>
batch_statement::prepare(database& db, cql_stats& stats) {
auto&& bound_names = get_bound_variables();
std::vector<shared_ptr<cql3::statements::modification_statement>> statements;
for (auto&& parsed : _parsed_statements) {
statements.push_back(parsed->prepare(db, bound_names, stats));
}
auto&& prep_attrs = _attrs->prepare(db, "[batch]", "[batch]");
prep_attrs->collect_marker_specification(bound_names);
cql3::statements::batch_statement batch_statement_(bound_names->size(), _type, std::move(statements), std::move(prep_attrs), stats);
batch_statement_.validate();
return ::make_shared<prepared>(make_shared(std::move(batch_statement_)),
bound_names->get_specifications());
}
}
}
}
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