/*
* 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 .
*/
#pragma once
#include
#include
#include "dht/i_partitioner.hh"
#include "position_in_partition.hh"
#include "mutation_fragment.hh"
#include "tracing/trace_state.hh"
#include
#include
#include "db/timeout_clock.hh"
#include
using seastar::future;
class mutation_source;
GCC6_CONCEPT(
template
concept bool FlatMutationReaderConsumer() {
return requires(Consumer c, mutation_fragment mf) {
{ c(std::move(mf)) } -> stop_iteration;
};
}
)
GCC6_CONCEPT(
template
concept bool FlattenedConsumer() {
return StreamedMutationConsumer() && requires(T obj, const dht::decorated_key& dk) {
obj.consume_new_partition(dk);
obj.consume_end_of_partition();
};
}
template
concept bool PartitionFilter = requires(T filter, const dht::decorated_key& dk) {
{ filter(dk) } -> bool;
};
)
/*
* Allows iteration on mutations using mutation_fragments.
* It iterates over mutations one by one and for each mutation
* it returns:
* 1. partition_start mutation_fragment
* 2. static_row mutation_fragment if one exists
* 3. mutation_fragments for all clustering rows and range tombstones
* in clustering key order
* 4. partition_end mutation_fragment
* The best way to consume those mutation_fragments is to call
* flat_mutation_reader::consume with a consumer that receives the fragments.
*/
class flat_mutation_reader final {
public:
// Causes a stream of reversed mutations to be emitted.
// 1. Static row is still emitted first.
// 2. Range tombstones are ordered by their end position.
// 3. Clustered rows and range tombstones are emitted in descending order.
// Because of 2 and 3 the guarantee that a range tombstone is emitted before
// any mutation fragment affected by it still holds.
// Ordering of partitions themselves remains unchanged.
using consume_reversed_partitions = seastar::bool_class;
class impl {
private:
circular_buffer _buffer;
size_t _buffer_size = 0;
bool _consume_done = false;
protected:
size_t max_buffer_size_in_bytes = 8 * 1024;
bool _end_of_stream = false;
schema_ptr _schema;
friend class flat_mutation_reader;
protected:
template
void push_mutation_fragment(Args&&... args) {
seastar::memory::on_alloc_point(); // for exception safety tests
_buffer.emplace_back(std::forward(args)...);
_buffer_size += _buffer.back().memory_usage(*_schema);
}
void clear_buffer() {
_buffer.erase(_buffer.begin(), _buffer.end());
_buffer_size = 0;
}
void forward_buffer_to(const position_in_partition& pos);
void clear_buffer_to_next_partition();
template
future fill_buffer_from(Source&, db::timeout_clock::time_point);
// When succeeds, makes sure that the next push_mutation_fragment() will not fail.
void reserve_one() {
if (_buffer.capacity() == _buffer.size()) {
_buffer.reserve(_buffer.size() * 2 + 1);
}
}
const circular_buffer& buffer() const {
return _buffer;
}
private:
static flat_mutation_reader reverse_partitions(flat_mutation_reader::impl&);
public:
impl(schema_ptr s) : _schema(std::move(s)) { }
virtual ~impl() {}
virtual future<> fill_buffer(db::timeout_clock::time_point) = 0;
virtual void next_partition() = 0;
bool is_end_of_stream() const { return _end_of_stream; }
bool is_buffer_empty() const { return _buffer.empty(); }
bool is_buffer_full() const { return _buffer_size >= max_buffer_size_in_bytes; }
mutation_fragment pop_mutation_fragment() {
auto mf = std::move(_buffer.front());
_buffer.pop_front();
_buffer_size -= mf.memory_usage(*_schema);
return mf;
}
void unpop_mutation_fragment(mutation_fragment mf) {
const auto memory_usage = mf.memory_usage(*_schema);
_buffer.emplace_front(std::move(mf));
_buffer_size += memory_usage;
}
future operator()(db::timeout_clock::time_point timeout) {
if (is_buffer_empty()) {
if (is_end_of_stream()) {
return make_ready_future();
}
return fill_buffer(timeout).then([this, timeout] { return operator()(timeout); });
}
return make_ready_future(pop_mutation_fragment());
}
template
GCC6_CONCEPT(
requires FlatMutationReaderConsumer()
)
// Stops when consumer returns stop_iteration::yes or end of stream is reached.
// Next call will start from the next mutation_fragment in the stream.
future<> consume_pausable(Consumer consumer, db::timeout_clock::time_point timeout) {
_consume_done = false;
return do_until([this] { return (is_end_of_stream() && is_buffer_empty()) || _consume_done; },
[this, consumer = std::move(consumer), timeout] () mutable {
if (is_buffer_empty()) {
return fill_buffer(timeout);
}
_consume_done = consumer(pop_mutation_fragment()) == stop_iteration::yes;
return make_ready_future<>();
});
}
template
GCC6_CONCEPT(
requires FlatMutationReaderConsumer() && PartitionFilter
)
// A variant of consume_pausable() that expects to be run in
// a seastar::thread.
// Partitions for which filter(decorated_key) returns false are skipped
// entirely and never reach the consumer.
void consume_pausable_in_thread(Consumer consumer, Filter filter, db::timeout_clock::time_point timeout) {
while (true) {
if (need_preempt()) {
seastar::thread::yield();
}
if (is_buffer_empty()) {
if (is_end_of_stream()) {
return;
}
fill_buffer(timeout).get();
continue;
}
auto mf = pop_mutation_fragment();
if (mf.is_partition_start() && !filter(mf.as_partition_start().key())) {
next_partition();
continue;
}
if (consumer(std::move(mf)) == stop_iteration::yes) {
return;
}
}
};
private:
template
struct consumer_adapter {
flat_mutation_reader::impl& _reader;
stdx::optional _decorated_key;
Consumer _consumer;
consumer_adapter(flat_mutation_reader::impl& reader, Consumer c)
: _reader(reader)
, _consumer(std::move(c))
{ }
stop_iteration operator()(mutation_fragment&& mf) {
return std::move(mf).consume(*this);
}
stop_iteration consume(static_row&& sr) {
return handle_result(_consumer.consume(std::move(sr)));
}
stop_iteration consume(clustering_row&& cr) {
return handle_result(_consumer.consume(std::move(cr)));
}
stop_iteration consume(range_tombstone&& rt) {
return handle_result(_consumer.consume(std::move(rt)));
}
stop_iteration consume(partition_start&& ps) {
_decorated_key.emplace(std::move(ps.key()));
_consumer.consume_new_partition(*_decorated_key);
if (ps.partition_tombstone()) {
_consumer.consume(ps.partition_tombstone());
}
return stop_iteration::no;
}
stop_iteration consume(partition_end&& pe) {
return _consumer.consume_end_of_partition();
}
private:
stop_iteration handle_result(stop_iteration si) {
if (si) {
if (_consumer.consume_end_of_partition()) {
return stop_iteration::yes;
}
_reader.next_partition();
}
return stop_iteration::no;
}
};
public:
template
GCC6_CONCEPT(
requires FlattenedConsumer()
)
// Stops when consumer returns stop_iteration::yes from consume_end_of_partition or end of stream is reached.
// Next call will receive fragments from the next partition.
// When consumer returns stop_iteration::yes from methods other than consume_end_of_partition then the read
// of the current partition is ended, consume_end_of_partition is called and if it returns stop_iteration::no
// then the read moves to the next partition.
// Reference to the decorated key that is passed to consume_new_partition() remains valid until after
// the call to consume_end_of_partition().
//
// This method is useful because most of current consumers use this semantic.
//
//
// This method returns whatever is returned from Consumer::consume_end_of_stream().S
auto consume(Consumer consumer, db::timeout_clock::time_point timeout) {
return do_with(consumer_adapter(*this, std::move(consumer)), [this, timeout] (consumer_adapter& adapter) {
return consume_pausable(std::ref(adapter), timeout).then([this, &adapter] {
return adapter._consumer.consume_end_of_stream();
});
});
}
template
GCC6_CONCEPT(
requires FlattenedConsumer() && PartitionFilter
)
// A variant of consumee() that expects to be run in a seastar::thread.
// Partitions for which filter(decorated_key) returns false are skipped
// entirely and never reach the consumer.
auto consume_in_thread(Consumer consumer, Filter filter, db::timeout_clock::time_point timeout) {
auto adapter = consumer_adapter(*this, std::move(consumer));
consume_pausable_in_thread(std::ref(adapter), std::move(filter), timeout);
return adapter._consumer.consume_end_of_stream();
};
/*
* fast_forward_to is forbidden on flat_mutation_reader created for a single partition.
*/
virtual future<> fast_forward_to(const dht::partition_range&, db::timeout_clock::time_point timeout) = 0;
virtual future<> fast_forward_to(position_range, db::timeout_clock::time_point timeout) = 0;
// Altough for most cases this is a mere getter some readers might have
// one or more subreaders and will need to account for their buffer-size
// as well so we need to allow these readers to override the default
// implementation.
virtual size_t buffer_size() const {
return _buffer_size;
}
circular_buffer detach_buffer() {
_buffer_size = 0;
return std::exchange(_buffer, {});
}
void move_buffer_content_to(impl& other) {
if (other._buffer.empty()) {
std::swap(_buffer, other._buffer);
other._buffer_size = std::exchange(_buffer_size, 0);
} else {
seastar::memory::on_alloc_point(); // for exception safety tests
other._buffer.reserve(other._buffer.size() + _buffer.size());
for (auto&& mf : _buffer) {
other._buffer.emplace_back(std::move(mf));
}
_buffer.clear();
other._buffer_size += std::exchange(_buffer_size, 0);
}
}
};
private:
std::unique_ptr _impl;
flat_mutation_reader() = default;
explicit operator bool() const noexcept { return bool(_impl); }
friend class optimized_optional;
public:
// Documented in mutation_reader::forwarding in mutation_reader.hh.
class partition_range_forwarding_tag;
using partition_range_forwarding = bool_class;
flat_mutation_reader(std::unique_ptr impl) noexcept : _impl(std::move(impl)) {}
future operator()(db::timeout_clock::time_point timeout) {
return _impl->operator()(timeout);
}
template
GCC6_CONCEPT(
requires FlatMutationReaderConsumer()
)
auto consume_pausable(Consumer consumer, db::timeout_clock::time_point timeout) {
return _impl->consume_pausable(std::move(consumer), timeout);
}
template
GCC6_CONCEPT(
requires FlattenedConsumer()
)
auto consume(Consumer consumer,
db::timeout_clock::time_point timeout,
consume_reversed_partitions reversed = consume_reversed_partitions::no) {
if (reversed) {
return do_with(impl::reverse_partitions(*_impl), [&] (auto& reversed_partition_stream) {
return reversed_partition_stream._impl->consume(std::move(consumer), timeout);
});
}
return _impl->consume(std::move(consumer), timeout);
}
template
GCC6_CONCEPT(
requires FlattenedConsumer() && PartitionFilter
)
auto consume_in_thread(Consumer consumer, Filter filter, db::timeout_clock::time_point timeout) {
return _impl->consume_in_thread(std::move(consumer), std::move(filter), timeout);
}
template
GCC6_CONCEPT(
requires FlattenedConsumer()
)
auto consume_in_thread(Consumer consumer, db::timeout_clock::time_point timeout) {
return consume_in_thread(std::move(consumer), [] (const dht::decorated_key&) { return true; }, timeout);
}
void next_partition() { _impl->next_partition(); }
future<> fill_buffer(db::timeout_clock::time_point timeout) { return _impl->fill_buffer(timeout); }
// Changes the range of partitions to pr. The range can only be moved
// forwards. pr.begin() needs to be larger than pr.end() of the previousl
// used range (i.e. either the initial one passed to the constructor or a
// previous fast forward target).
// pr needs to be valid until the reader is destroyed or fast_forward_to()
// is called again.
future<> fast_forward_to(const dht::partition_range& pr, db::timeout_clock::time_point timeout) {
return _impl->fast_forward_to(pr, timeout);
}
// Skips to a later range of rows.
// The new range must not overlap with the current range.
//
// In forwarding mode the stream does not return all fragments right away,
// but only those belonging to the current clustering range. Initially
// current range only covers the static row. The stream can be forwarded
// (even before end-of- stream) to a later range with fast_forward_to().
// Forwarding doesn't change initial restrictions of the stream, it can
// only be used to skip over data.
//
// Monotonicity of positions is preserved by forwarding. That is fragments
// emitted after forwarding will have greater positions than any fragments
// emitted before forwarding.
//
// For any range, all range tombstones relevant for that range which are
// present in the original stream will be emitted. Range tombstones
// emitted before forwarding which overlap with the new range are not
// necessarily re-emitted.
//
// When forwarding mode is not enabled, fast_forward_to()
// cannot be used.
future<> fast_forward_to(position_range cr, db::timeout_clock::time_point timeout) {
return _impl->fast_forward_to(std::move(cr), timeout);
}
bool is_end_of_stream() const { return _impl->is_end_of_stream(); }
bool is_buffer_empty() const { return _impl->is_buffer_empty(); }
bool is_buffer_full() const { return _impl->is_buffer_full(); }
mutation_fragment pop_mutation_fragment() { return _impl->pop_mutation_fragment(); }
void unpop_mutation_fragment(mutation_fragment mf) { _impl->unpop_mutation_fragment(std::move(mf)); }
const schema_ptr& schema() const { return _impl->_schema; }
void set_max_buffer_size(size_t size) {
_impl->max_buffer_size_in_bytes = size;
}
// Resolves with a pointer to the next fragment in the stream without consuming it from the stream,
// or nullptr if there are no more fragments.
// The returned pointer is invalidated by any other non-const call to this object.
future peek(db::timeout_clock::time_point timeout) {
if (!is_buffer_empty()) {
return make_ready_future(&_impl->_buffer.front());
}
if (is_end_of_stream()) {
return make_ready_future(nullptr);
}
return fill_buffer(timeout).then([this, timeout] {
return peek(timeout);
});
}
// A peek at the next fragment in the buffer.
// Cannot be called if is_buffer_empty() returns true.
const mutation_fragment& peek_buffer() const { return _impl->_buffer.front(); }
// The actual buffer size of the reader.
// Altough we consistently refer to this as buffer size throught the code
// we really use "buffer size" as the size of the collective memory
// used by all the mutation fragments stored in the buffer of the reader.
size_t buffer_size() const {
return _impl->buffer_size();
}
// Detach the internal buffer of the reader.
// Roughly equivalent to depleting it by calling pop_mutation_fragment()
// until is_buffer_empty() returns true.
// The reader will need to allocate a new buffer on the next fill_buffer()
// call.
circular_buffer detach_buffer() {
return _impl->detach_buffer();
}
// Moves the buffer content to `other`.
//
// If the buffer of `other` is empty this is very efficient as the buffers
// are simply swapped. Otherwise the content of the buffer is moved
// fragmuent-by-fragment.
// Allows efficient implementation of wrapping readers that do no
// transformation to the fragment stream.
void move_buffer_content_to(impl& other) {
_impl->move_buffer_content_to(other);
}
};
using flat_mutation_reader_opt = optimized_optional;
template
flat_mutation_reader make_flat_mutation_reader(Args &&... args) {
return flat_mutation_reader(std::make_unique(std::forward(args)...));
}
// Consumes mutation fragments until StopCondition is true.
// The consumer will stop iff StopCondition returns true, in particular
// reaching the end of stream alone won't stop the reader.
template
GCC6_CONCEPT(requires requires(StopCondition stop, ConsumeMutationFragment consume_mf, ConsumeEndOfStream consume_eos, mutation_fragment mf) {
{ stop() } -> bool;
{ consume_mf(std::move(mf)) } -> void;
{ consume_eos() } -> future<>;
})
future<> consume_mutation_fragments_until(
flat_mutation_reader& r,
StopCondition&& stop,
ConsumeMutationFragment&& consume_mf,
ConsumeEndOfStream&& consume_eos,
db::timeout_clock::time_point timeout) {
return do_until([stop] { return stop(); }, [&r, stop, consume_mf, consume_eos, timeout] {
while (!r.is_buffer_empty()) {
consume_mf(r.pop_mutation_fragment());
if (stop()) {
return make_ready_future<>();
}
}
if (r.is_end_of_stream()) {
return consume_eos();
}
return r.fill_buffer(timeout);
});
}
// Creates a stream which is like r but with transformation applied to the elements.
template
GCC6_CONCEPT(
requires StreamedMutationTranformer()
)
flat_mutation_reader transform(flat_mutation_reader r, T t) {
class transforming_reader : public flat_mutation_reader::impl {
flat_mutation_reader _reader;
T _t;
struct consumer {
transforming_reader* _owner;
stop_iteration operator()(mutation_fragment&& mf) {
_owner->push_mutation_fragment(_owner->_t(std::move(mf)));
return stop_iteration(_owner->is_buffer_full());
}
};
public:
transforming_reader(flat_mutation_reader&& r, T&& t)
: impl(t(r.schema()))
, _reader(std::move(r))
, _t(std::move(t))
{}
virtual future<> fill_buffer(db::timeout_clock::time_point timeout) override {
if (_end_of_stream) {
return make_ready_future<>();
}
return _reader.consume_pausable(consumer{this}, timeout).then([this] {
if (_reader.is_end_of_stream() && _reader.is_buffer_empty()) {
_end_of_stream = true;
}
});
}
virtual void next_partition() override {
clear_buffer_to_next_partition();
if (is_buffer_empty()) {
_reader.next_partition();
}
}
virtual future<> fast_forward_to(const dht::partition_range& pr, db::timeout_clock::time_point timeout) override {
clear_buffer();
_end_of_stream = false;
return _reader.fast_forward_to(pr, timeout);
}
virtual future<> fast_forward_to(position_range pr, db::timeout_clock::time_point timeout) override {
forward_buffer_to(pr.start());
_end_of_stream = false;
return _reader.fast_forward_to(std::move(pr), timeout);
}
virtual size_t buffer_size() const override {
return flat_mutation_reader::impl::buffer_size() + _reader.buffer_size();
}
};
return make_flat_mutation_reader(std::move(r), std::move(t));
}
inline flat_mutation_reader& to_reference(flat_mutation_reader& r) { return r; }
inline const flat_mutation_reader& to_reference(const flat_mutation_reader& r) { return r; }
template
class delegating_reader : public flat_mutation_reader::impl {
Underlying _underlying;
public:
delegating_reader(Underlying&& r) : impl(to_reference(r).schema()), _underlying(std::forward(r)) { }
virtual future<> fill_buffer(db::timeout_clock::time_point timeout) override {
return fill_buffer_from(to_reference(_underlying), timeout).then([this] (bool underlying_finished) {
_end_of_stream = underlying_finished;
});
}
virtual future<> fast_forward_to(position_range pr, db::timeout_clock::time_point timeout) override {
_end_of_stream = false;
forward_buffer_to(pr.start());
return to_reference(_underlying).fast_forward_to(std::move(pr), timeout);
}
virtual void next_partition() override {
clear_buffer_to_next_partition();
if (is_buffer_empty()) {
to_reference(_underlying).next_partition();
}
_end_of_stream = to_reference(_underlying).is_end_of_stream() && to_reference(_underlying).is_buffer_empty();
}
virtual future<> fast_forward_to(const dht::partition_range& pr, db::timeout_clock::time_point timeout) override {
_end_of_stream = false;
clear_buffer();
return to_reference(_underlying).fast_forward_to(pr, timeout);
}
virtual size_t buffer_size() const override {
return flat_mutation_reader::impl::buffer_size() + to_reference(_underlying).buffer_size();
}
};
flat_mutation_reader make_delegating_reader(flat_mutation_reader&);
flat_mutation_reader make_forwardable(flat_mutation_reader m);
flat_mutation_reader make_nonforwardable(flat_mutation_reader, bool);
flat_mutation_reader make_empty_flat_reader(schema_ptr s);
flat_mutation_reader flat_mutation_reader_from_mutations(std::vector, const dht::partition_range& pr = query::full_partition_range, streamed_mutation::forwarding fwd = streamed_mutation::forwarding::no);
inline flat_mutation_reader flat_mutation_reader_from_mutations(std::vector ms, streamed_mutation::forwarding fwd) {
return flat_mutation_reader_from_mutations(std::move(ms), query::full_partition_range, fwd);
}
flat_mutation_reader
flat_mutation_reader_from_mutations(std::vector ms,
const query::partition_slice& slice,
streamed_mutation::forwarding fwd = streamed_mutation::forwarding::no);
/// Make a reader that enables the wrapped reader to work with multiple ranges.
///
/// \param ranges An range vector that has to contain strictly monotonic
/// partition ranges, such that successively calling
/// `flat_mutation_reader::fast_forward_to()` with each one is valid.
/// An range vector range with 0 or 1 elements is also valid.
/// \param fwd_mr It is only respected when `ranges` contains 0 or 1 partition
/// ranges. Otherwise the reader is created with
/// mutation_reader::forwarding::yes.
flat_mutation_reader
make_flat_multi_range_reader(schema_ptr s, mutation_source source, const dht::partition_range_vector& ranges,
const query::partition_slice& slice, const io_priority_class& pc = default_priority_class(),
tracing::trace_state_ptr trace_state = nullptr,
flat_mutation_reader::partition_range_forwarding fwd_mr = flat_mutation_reader::partition_range_forwarding::yes);
/// Make a reader that enables the wrapped reader to work with multiple ranges.
///
/// Generator overload. The ranges returned by the generator have to satisfy the
/// same requirements as the `ranges` param of the vector overload.
flat_mutation_reader
make_flat_multi_range_reader(
schema_ptr s,
mutation_source source,
std::function()> generator,
const query::partition_slice& slice,
const io_priority_class& pc = default_priority_class(),
tracing::trace_state_ptr trace_state = nullptr,
flat_mutation_reader::partition_range_forwarding fwd_mr = flat_mutation_reader::partition_range_forwarding::yes);
flat_mutation_reader
make_flat_mutation_reader_from_fragments(schema_ptr, std::deque);
// Calls the consumer for each element of the reader's stream until end of stream
// is reached or the consumer requests iteration to stop by returning stop_iteration::yes.
// The consumer should accept mutation as the argument and return stop_iteration.
// The returned future<> resolves when consumption ends.
template
inline
future<> consume_partitions(flat_mutation_reader& reader, Consumer consumer, db::timeout_clock::time_point timeout) {
static_assert(std::is_same, futurize_t>>::value, "bad Consumer signature");
using futurator = futurize>;
return do_with(std::move(consumer), [&reader, timeout] (Consumer& c) -> future<> {
return repeat([&reader, &c, timeout] () {
return read_mutation_from_flat_mutation_reader(reader, timeout).then([&c] (mutation_opt&& mo) -> future {
if (!mo) {
return make_ready_future(stop_iteration::yes);
}
return futurator::apply(c, std::move(*mo));
});
});
});
}