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// -*- mode:C++; tab-width:8; c-basic-offset:2; indent-tabs-mode:t -*-
// vim: ts=8 sw=2 smarttab
//
// Ceph - scalable distributed file system
//
// Copyright (C) 2018 Red Hat, Inc.
//
// This is free software; you can redistribute it and/or
// modify it under the terms of the GNU Lesser General Public
// License version 2.1, as published by the Free Software
// Foundation. See file COPYING.
//
#ifndef CEPH_COMMON_CONTAINERS_H
#define CEPH_COMMON_CONTAINERS_H
#include <cstdint>
#include <type_traits>
namespace ceph::containers {
// tiny_vector – CPU friendly, small_vector-like container for mutexes,
// atomics and other non-movable things.
//
// The purpose of the container is to store arbitrary number of objects
// with absolutely minimal requirements regarding constructibility
// and assignability while minimizing memory indirection.
// There is no obligation for MoveConstructibility, CopyConstructibility,
// MoveAssignability, CopyAssignability nor even DefaultConstructibility
// which allows to handle std::mutexes, std::atomics or any type embedding
// them.
//
// Few requirements translate into tiny interface. The container isn't
// Copy- nor MoveConstructible. Although it does offer random access
// iterator, insertion in the middle is not allowed. The maximum number
// of elements must be known at run-time. This shouldn't be an issue in
// the intended use case: sharding.
//
// For the special case of no internal slots (InternalCapacity eq 0),
// tiny_vector doesn't require moving any elements (changing pointers
// is enough), and thus should be MoveConstructibile.
//
// Alternatives:
// 1. std::vector<boost::optional<ValueT>> initialized with the known
// size and emplace_backed(). boost::optional inside provides
// the DefaultConstructibility. Imposes extra memory indirection.
// 2. boost::container::small_vector + boost::optional always
// requires MoveConstructibility.
// 3. boost::container::static_vector feed via emplace_back().
// Good for performance but enforces upper limit on elements count.
// For sharding this means we can't handle arbitrary number of
// shards (weird configs).
// 4. std::unique_ptr<ValueT>: extra indirection together with memory
// fragmentation.
template<typename Value, std::size_t InternalCapacity = 0>
class tiny_vector {
// NOTE: to avoid false sharing consider aligning to cache line
using storage_unit_t = \
std::aligned_storage_t<sizeof(Value), alignof(Value)>;
std::size_t _size = 0;
storage_unit_t* const data = nullptr;
storage_unit_t internal[InternalCapacity];
public:
typedef std::size_t size_type;
typedef std::add_lvalue_reference_t<Value> reference;
typedef std::add_const_t<reference> const_reference;
typedef std::add_pointer_t<Value> pointer;
// emplacer is the piece of weirdness that comes from handling
// unmovable-and-uncopyable things. The only way to instantiate
// such types I know is to create instances in-place perfectly
// forwarding necessary data to constructor.
// Abstracting that is the exact purpose of emplacer.
//
// The usage scenario is:
// 1. The tiny_vector's ctor is provided with a) maximum number
// of instances and b) a callable taking emplacer.
// 2. The callable can (but isn't obliged to!) use emplacer to
// construct an instance without knowing at which address
// in memory it will be put. Callable is also supplied with
// an unique integer from the range <0, maximum number of
// instances).
// 3. If callable decides to instantiate, it calls ::emplace
// of emplacer passing all arguments required by the type
// hold in tiny_vector.
//
// Example:
// ```
// static constexpr const num_internally_allocated_slots = 32;
// tiny_vector<T, num_internally_allocated_slots> mytinyvec {
// num_of_instances,
// [](const size_t i, auto emplacer) {
// emplacer.emplace(argument_for_T_ctor);
// }
// }
// ```
//
// For the sake of supporting the ceph::make_mutex() family of
// factories, which relies on C++17's guaranteed copy elision,
// the emplacer provides `data()` to retrieve the location for
// constructing the instance with placement-new. This is handy
// as the `emplace()` depends on perfect forwarding, and thus
// interfere with the elision for cases like:
// ```
// emplacer.emplace(ceph::make_mutex("mtx-name"));
// ```
// See: https://stackoverflow.com/a/52498826
class emplacer {
friend class tiny_vector;
tiny_vector* parent;
emplacer(tiny_vector* const parent)
: parent(parent) {
}
public:
void* data() {
void* const ret = &parent->data[parent->_size++];
parent = nullptr;
return ret;
}
template<class... Args>
void emplace(Args&&... args) {
if (parent) {
new (data()) Value(std::forward<Args>(args)...);
}
}
};
template<typename F>
tiny_vector(const std::size_t count, F&& f)
: data(count <= InternalCapacity ? internal
: new storage_unit_t[count]) {
for (std::size_t i = 0; i < count; ++i) {
// caller MAY emplace up to `count` elements but it IS NOT
// obliged to do so. The emplacer guarantees that the limit
// will never be exceeded.
f(i, emplacer(this));
}
}
~tiny_vector() {
for (auto& elem : *this) {
elem.~Value();
}
const auto data_addr = reinterpret_cast<std::uintptr_t>(data);
const auto this_addr = reinterpret_cast<std::uintptr_t>(this);
if (data_addr < this_addr ||
data_addr >= this_addr + sizeof(*this)) {
delete[] data;
}
}
reference operator[](size_type pos) {
return reinterpret_cast<reference>(data[pos]);
}
const_reference operator[](size_type pos) const {
return reinterpret_cast<const_reference>(data[pos]);
}
size_type size() const {
return _size;
}
pointer begin() {
return reinterpret_cast<pointer>(&data[0]);
}
pointer end() {
return reinterpret_cast<pointer>(&data[_size]);
}
const pointer begin() const {
return reinterpret_cast<pointer>(&data[0]);
}
const pointer end() const {
return reinterpret_cast<pointer>(&data[_size]);
}
const pointer cbegin() const {
return reinterpret_cast<pointer>(&data[0]);
}
const pointer cend() const {
return reinterpret_cast<pointer>(&data[_size]);
}
};
} // namespace ceph::containers
#endif // CEPH_COMMON_CONTAINERS_H
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