rocksdb/db/multi_cf_iterator_impl.h
Levi Tamasi 917e98ff9e Templatize MultiCfIteratorImpl to avoid std::function's overhead (#13052)
Summary:
Pull Request resolved: https://github.com/facebook/rocksdb/pull/13052

Currently, `MultiCfIteratorImpl` uses `std::function`s for `reset_func_` and `populate_func_`, which uses type erasure and has a performance overhead. The patch turns `MultiCfIteratorImpl` into a template that takes the two function object types as template parameters, and changes `AttributeGroupIteratorImpl` and `CoalescingIterator` so they pass in function objects of named types (as opposed to lambdas).

Reviewed By: jaykorean

Differential Revision: D63802598

fbshipit-source-id: e202f6d80c9054335e5b2571051a67a9e012c2d0
2024-10-02 19:18:15 -07:00

296 lines
9.2 KiB
C++

// Copyright (c) Meta Platforms, Inc. and affiliates.
// This source code is licensed under both the GPLv2 (found in the
// COPYING file in the root directory) and Apache 2.0 License
// (found in the LICENSE.Apache file in the root directory).
#pragma once
#include <functional>
#include <variant>
#include "rocksdb/comparator.h"
#include "rocksdb/iterator.h"
#include "rocksdb/options.h"
#include "util/heap.h"
namespace ROCKSDB_NAMESPACE {
struct MultiCfIteratorInfo {
ColumnFamilyHandle* cfh;
Iterator* iterator;
int order;
};
template <typename ResetFunc, typename PopulateFunc>
class MultiCfIteratorImpl {
public:
MultiCfIteratorImpl(const Comparator* comparator,
const std::vector<ColumnFamilyHandle*>& column_families,
const std::vector<Iterator*>& child_iterators,
ResetFunc reset_func, PopulateFunc populate_func)
: comparator_(comparator),
heap_(MultiCfMinHeap(
MultiCfHeapItemComparator<std::greater<int>>(comparator_))),
reset_func_(std::move(reset_func)),
populate_func_(std::move(populate_func)) {
assert(column_families.size() > 0 &&
column_families.size() == child_iterators.size());
cfh_iter_pairs_.reserve(column_families.size());
for (size_t i = 0; i < column_families.size(); ++i) {
cfh_iter_pairs_.emplace_back(
column_families[i], std::unique_ptr<Iterator>(child_iterators[i]));
}
}
~MultiCfIteratorImpl() { status_.PermitUncheckedError(); }
// No copy allowed
MultiCfIteratorImpl(const MultiCfIteratorImpl&) = delete;
MultiCfIteratorImpl& operator=(const MultiCfIteratorImpl&) = delete;
Slice key() const {
assert(Valid());
return current()->key();
}
bool Valid() const {
if (std::holds_alternative<MultiCfMaxHeap>(heap_)) {
auto& max_heap = std::get<MultiCfMaxHeap>(heap_);
return !max_heap.empty() && status_.ok();
}
auto& min_heap = std::get<MultiCfMinHeap>(heap_);
return !min_heap.empty() && status_.ok();
}
Status status() const { return status_; }
void SeekToFirst() {
auto& min_heap = GetHeap<MultiCfMinHeap>([this]() { InitMinHeap(); });
SeekCommon(min_heap, [](Iterator* iter) { iter->SeekToFirst(); });
}
void Seek(const Slice& target) {
auto& min_heap = GetHeap<MultiCfMinHeap>([this]() { InitMinHeap(); });
SeekCommon(min_heap, [&target](Iterator* iter) { iter->Seek(target); });
}
void SeekToLast() {
auto& max_heap = GetHeap<MultiCfMaxHeap>([this]() { InitMaxHeap(); });
SeekCommon(max_heap, [](Iterator* iter) { iter->SeekToLast(); });
}
void SeekForPrev(const Slice& target) {
auto& max_heap = GetHeap<MultiCfMaxHeap>([this]() { InitMaxHeap(); });
SeekCommon(max_heap,
[&target](Iterator* iter) { iter->SeekForPrev(target); });
}
void Next() {
assert(Valid());
auto& min_heap = GetHeap<MultiCfMinHeap>([this]() {
std::string target(key().data(), key().size());
InitMinHeap();
Seek(target);
});
AdvanceIterator(min_heap, [](Iterator* iter) { iter->Next(); });
}
void Prev() {
assert(Valid());
auto& max_heap = GetHeap<MultiCfMaxHeap>([this]() {
std::string target(key().data(), key().size());
InitMaxHeap();
SeekForPrev(target);
});
AdvanceIterator(max_heap, [](Iterator* iter) { iter->Prev(); });
}
private:
std::vector<std::pair<ColumnFamilyHandle*, std::unique_ptr<Iterator>>>
cfh_iter_pairs_;
Status status_;
template <typename CompareOp>
class MultiCfHeapItemComparator {
public:
explicit MultiCfHeapItemComparator(const Comparator* comparator)
: comparator_(comparator) {}
bool operator()(const MultiCfIteratorInfo& a,
const MultiCfIteratorInfo& b) const {
assert(a.iterator);
assert(b.iterator);
assert(a.iterator->Valid());
assert(b.iterator->Valid());
int c = comparator_->Compare(a.iterator->key(), b.iterator->key());
assert(c != 0 || a.order != b.order);
return c == 0 ? a.order - b.order > 0 : CompareOp()(c, 0);
}
private:
const Comparator* comparator_;
};
const Comparator* comparator_;
using MultiCfMinHeap =
BinaryHeap<MultiCfIteratorInfo,
MultiCfHeapItemComparator<std::greater<int>>>;
using MultiCfMaxHeap = BinaryHeap<MultiCfIteratorInfo,
MultiCfHeapItemComparator<std::less<int>>>;
using MultiCfIterHeap = std::variant<MultiCfMinHeap, MultiCfMaxHeap>;
MultiCfIterHeap heap_;
ResetFunc reset_func_;
PopulateFunc populate_func_;
Iterator* current() const {
if (std::holds_alternative<MultiCfMaxHeap>(heap_)) {
auto& max_heap = std::get<MultiCfMaxHeap>(heap_);
return max_heap.top().iterator;
}
auto& min_heap = std::get<MultiCfMinHeap>(heap_);
return min_heap.top().iterator;
}
void considerStatus(Status s) {
if (!s.ok() && status_.ok()) {
status_ = std::move(s);
}
}
template <typename HeapType, typename InitFunc>
HeapType& GetHeap(InitFunc initFunc) {
if (!std::holds_alternative<HeapType>(heap_)) {
initFunc();
}
return std::get<HeapType>(heap_);
}
void InitMinHeap() {
heap_.template emplace<MultiCfMinHeap>(
MultiCfHeapItemComparator<std::greater<int>>(comparator_));
}
void InitMaxHeap() {
heap_.template emplace<MultiCfMaxHeap>(
MultiCfHeapItemComparator<std::less<int>>(comparator_));
}
template <typename BinaryHeap, typename ChildSeekFuncType>
void SeekCommon(BinaryHeap& heap, ChildSeekFuncType child_seek_func) {
reset_func_();
heap.clear();
int i = 0;
for (auto& [cfh, iter] : cfh_iter_pairs_) {
child_seek_func(iter.get());
if (iter->Valid()) {
assert(iter->status().ok());
heap.push(MultiCfIteratorInfo{cfh, iter.get(), i});
} else {
considerStatus(iter->status());
if (!status_.ok()) {
// Non-OK status from the iterator. Bail out early
heap.clear();
break;
}
}
++i;
}
if (!heap.empty()) {
PopulateIterator(heap);
}
}
template <typename BinaryHeap, typename AdvanceFuncType>
void AdvanceIterator(BinaryHeap& heap, AdvanceFuncType advance_func) {
reset_func_();
// It is possible for one or more child iters are at invalid keys due to
// manual prefix iteration. For such cases, we consider the result of the
// multi-cf-iter is also undefined.
// https://github.com/facebook/rocksdb/wiki/Prefix-Seek#manual-prefix-iterating
// for details about manual prefix iteration
if (heap.empty()) {
return;
}
// 1. Keep the top iterator (by popping it from the heap)
// 2. Make sure all others have iterated past the top iterator key slice
// 3. Advance the top iterator, and add it back to the heap if valid
auto top = heap.top();
heap.pop();
if (!heap.empty()) {
auto current = heap.top();
assert(current.iterator);
while (current.iterator->Valid() &&
comparator_->Compare(top.iterator->key(),
current.iterator->key()) == 0) {
assert(current.iterator->status().ok());
advance_func(current.iterator);
if (current.iterator->Valid()) {
heap.replace_top(heap.top());
} else {
considerStatus(current.iterator->status());
if (!status_.ok()) {
heap.clear();
return;
} else {
heap.pop();
}
}
if (!heap.empty()) {
current = heap.top();
}
}
}
advance_func(top.iterator);
if (top.iterator->Valid()) {
assert(top.iterator->status().ok());
heap.push(top);
} else {
considerStatus(top.iterator->status());
if (!status_.ok()) {
heap.clear();
return;
}
}
if (!heap.empty()) {
PopulateIterator(heap);
}
}
template <typename BinaryHeap>
void PopulateIterator(BinaryHeap& heap) {
// 1. Keep the top iterator (by popping it from the heap) and add it to list
// to populate
// 2. For all non-top iterators having the same key as top iter popped
// from the previous step, add them to the same list and pop it
// temporarily from the heap
// 3. Once no other iters have the same key as the top iter from step 1,
// populate the value/columns and attribute_groups from the list
// collected in step 1 and 2 and add all the iters back to the heap
assert(!heap.empty());
auto top = heap.top();
heap.pop();
autovector<MultiCfIteratorInfo> to_populate;
to_populate.push_back(top);
if (!heap.empty()) {
auto current = heap.top();
assert(current.iterator);
while (current.iterator->Valid() &&
comparator_->Compare(top.iterator->key(),
current.iterator->key()) == 0) {
assert(current.iterator->status().ok());
to_populate.push_back(current);
heap.pop();
if (!heap.empty()) {
current = heap.top();
} else {
break;
}
}
}
// Add the items back to the heap
for (auto& item : to_populate) {
heap.push(item);
}
populate_func_(to_populate);
}
};
} // namespace ROCKSDB_NAMESPACE