/*
* Copyright (C) 2014 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 "mutation.hh"
#include "query-result-writer.hh"
#include "flat_mutation_reader.hh"
#include "mutation_rebuilder.hh"
mutation::data::data(dht::decorated_key&& key, schema_ptr&& schema)
: _schema(std::move(schema))
, _dk(std::move(key))
, _p(_schema)
{ }
mutation::data::data(partition_key&& key_, schema_ptr&& schema)
: _schema(std::move(schema))
, _dk(dht::decorate_key(*_schema, std::move(key_)))
, _p(_schema)
{ }
mutation::data::data(schema_ptr&& schema, dht::decorated_key&& key, const mutation_partition& mp)
: _schema(schema)
, _dk(std::move(key))
, _p(*schema, mp)
{ }
mutation::data::data(schema_ptr&& schema, dht::decorated_key&& key, mutation_partition&& mp)
: _schema(std::move(schema))
, _dk(std::move(key))
, _p(std::move(mp))
{ }
void mutation::set_static_cell(const column_definition& def, atomic_cell_or_collection&& value) {
partition().static_row().apply(def, std::move(value));
}
void mutation::set_static_cell(const bytes& name, const data_value& value, api::timestamp_type timestamp, ttl_opt ttl) {
auto column_def = schema()->get_column_definition(name);
if (!column_def) {
throw std::runtime_error(format("no column definition found for '{}'", name));
}
if (!column_def->is_static()) {
throw std::runtime_error(format("column '{}' is not static", name));
}
partition().static_row().apply(*column_def, atomic_cell::make_live(*column_def->type, timestamp, column_def->type->decompose(value), ttl));
}
void mutation::set_clustered_cell(const clustering_key& key, const bytes& name, const data_value& value,
api::timestamp_type timestamp, ttl_opt ttl) {
auto column_def = schema()->get_column_definition(name);
if (!column_def) {
throw std::runtime_error(format("no column definition found for '{}'", name));
}
return set_clustered_cell(key, *column_def, atomic_cell::make_live(*column_def->type, timestamp, column_def->type->decompose(value), ttl));
}
void mutation::set_clustered_cell(const clustering_key& key, const column_definition& def, atomic_cell_or_collection&& value) {
auto& row = partition().clustered_row(*schema(), key).cells();
row.apply(def, std::move(value));
}
void mutation::set_cell(const clustering_key_prefix& prefix, const bytes& name, const data_value& value,
api::timestamp_type timestamp, ttl_opt ttl) {
auto column_def = schema()->get_column_definition(name);
if (!column_def) {
throw std::runtime_error(format("no column definition found for '{}'", name));
}
return set_cell(prefix, *column_def, atomic_cell::make_live(*column_def->type, timestamp, column_def->type->decompose(value), ttl));
}
void mutation::set_cell(const clustering_key_prefix& prefix, const column_definition& def, atomic_cell_or_collection&& value) {
if (def.is_static()) {
set_static_cell(def, std::move(value));
} else if (def.is_regular()) {
set_clustered_cell(prefix, def, std::move(value));
} else {
throw std::runtime_error("attemting to store into a key cell");
}
}
bool mutation::operator==(const mutation& m) const {
return decorated_key().equal(*schema(), m.decorated_key())
&& partition().equal(*schema(), m.partition(), *m.schema());
}
bool mutation::operator!=(const mutation& m) const {
return !(*this == m);
}
void
mutation::query(query::result::builder& builder,
const query::partition_slice& slice,
gc_clock::time_point now,
uint64_t row_limit) &&
{
auto pb = builder.add_partition(*schema(), key());
auto is_reversed = slice.options.contains();
auto always_return_static_content = slice.options.contains();
mutation_partition& p = partition();
auto limit = std::min(row_limit, slice.partition_row_limit());
p.compact_for_query(*schema(), now, slice.row_ranges(*schema(), key()), always_return_static_content, is_reversed, limit);
p.query_compacted(pb, *schema(), limit);
}
query::result
mutation::query(const query::partition_slice& slice,
query::result_memory_accounter&& accounter,
query::result_options opts,
gc_clock::time_point now, uint64_t row_limit) &&
{
query::result::builder builder(slice, opts, std::move(accounter));
std::move(*this).query(builder, slice, now, row_limit);
return builder.build();
}
query::result
mutation::query(const query::partition_slice& slice,
query::result_memory_accounter&& accounter,
query::result_options opts,
gc_clock::time_point now, uint64_t row_limit) const&
{
return mutation(*this).query(slice, std::move(accounter), opts, now, row_limit);
}
uint64_t
mutation::live_row_count(gc_clock::time_point query_time) const {
return partition().live_row_count(*schema(), query_time);
}
bool
mutation_decorated_key_less_comparator::operator()(const mutation& m1, const mutation& m2) const {
return m1.decorated_key().less_compare(*m1.schema(), m2.decorated_key());
}
boost::iterator_range::const_iterator>
slice(const std::vector& partitions, const dht::partition_range& r) {
struct cmp {
bool operator()(const dht::ring_position& pos, const mutation& m) const {
return m.decorated_key().tri_compare(*m.schema(), pos) > 0;
};
bool operator()(const mutation& m, const dht::ring_position& pos) const {
return m.decorated_key().tri_compare(*m.schema(), pos) < 0;
};
};
return boost::make_iterator_range(
r.start()
? (r.start()->is_inclusive()
? std::lower_bound(partitions.begin(), partitions.end(), r.start()->value(), cmp())
: std::upper_bound(partitions.begin(), partitions.end(), r.start()->value(), cmp()))
: partitions.cbegin(),
r.end()
? (r.end()->is_inclusive()
? std::upper_bound(partitions.begin(), partitions.end(), r.end()->value(), cmp())
: std::lower_bound(partitions.begin(), partitions.end(), r.end()->value(), cmp()))
: partitions.cend());
}
void
mutation::upgrade(const schema_ptr& new_schema) {
if (_ptr->_schema != new_schema) {
schema_ptr s = new_schema;
partition().upgrade(*schema(), *new_schema);
_ptr->_schema = std::move(s);
}
}
void mutation::apply(mutation&& m) {
mutation_application_stats app_stats;
partition().apply(*schema(), std::move(m.partition()), *m.schema(), app_stats);
}
void mutation::apply(const mutation& m) {
mutation_application_stats app_stats;
partition().apply(*schema(), m.partition(), *m.schema(), app_stats);
}
void mutation::apply(const mutation_fragment& mf) {
partition().apply(*schema(), mf);
}
mutation& mutation::operator=(const mutation& m) {
return *this = mutation(m);
}
mutation mutation::operator+(const mutation& other) const {
auto m = *this;
m.apply(other);
return m;
}
mutation& mutation::operator+=(const mutation& other) {
apply(other);
return *this;
}
mutation& mutation::operator+=(mutation&& other) {
apply(std::move(other));
return *this;
}
mutation mutation::sliced(const query::clustering_row_ranges& ranges) const {
return mutation(schema(), decorated_key(), partition().sliced(*schema(), ranges));
}
future read_mutation_from_flat_mutation_reader(flat_mutation_reader& r, db::timeout_clock::time_point timeout) {
if (r.is_buffer_empty()) {
if (r.is_end_of_stream()) {
return make_ready_future();
}
return r.fill_buffer(timeout).then([&r, timeout] {
return read_mutation_from_flat_mutation_reader(r, timeout);
});
}
// r.is_buffer_empty() is always false at this point
struct adapter {
schema_ptr _s;
std::optional _builder;
adapter(schema_ptr s) : _s(std::move(s)) { }
void consume_new_partition(const dht::decorated_key& dk) {
assert(!_builder);
_builder = mutation_rebuilder(dk, std::move(_s));
}
stop_iteration consume(tombstone t) {
assert(_builder);
return _builder->consume(t);
}
stop_iteration consume(range_tombstone&& rt) {
assert(_builder);
return _builder->consume(std::move(rt));
}
stop_iteration consume(static_row&& sr) {
assert(_builder);
return _builder->consume(std::move(sr));
}
stop_iteration consume(clustering_row&& cr) {
assert(_builder);
return _builder->consume(std::move(cr));
}
stop_iteration consume_end_of_partition() {
assert(_builder);
return stop_iteration::yes;
}
mutation_opt consume_end_of_stream() {
if (!_builder) {
return mutation_opt();
}
return _builder->consume_end_of_stream();
}
};
return r.consume(adapter(r.schema()), timeout);
}
std::ostream& operator<<(std::ostream& os, const mutation& m) {
const ::schema& s = *m.schema();
const auto& dk = m.decorated_key();
fmt_print(os, "{{table: '{}.{}', key: {{", s.ks_name(), s.cf_name());
auto type_iterator = dk._key.get_compound_type(s)->types().begin();
auto column_iterator = s.partition_key_columns().begin();
for (auto&& e : dk._key.components(s)) {
os << "'" << column_iterator->name_as_text() << "': " << (*type_iterator)->to_string(to_bytes(e)) << ", ";
++type_iterator;
++column_iterator;
}
fmt_print(os, "token: {}}}, ", dk._token);
os << mutation_partition::printer(s, m.partition()) << "\n}";
return os;
}