include/ftl/static_vector.h - android_frameworks_native - Gitiles

 /*
  * Copyright 2020 The Android Open Source Project
  *
  * Licensed 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.
  */

 #pragma once

 #include <ftl/array_traits.h>
 #include <ftl/initializer_list.h>

 #include <algorithm>
 #include <cassert>
 #include <iterator>
 #include <memory>
 #include <type_traits>
 #include <utility>

 namespace android::ftl {

 constexpr struct IteratorRangeTag {
 } kIteratorRange;

 // Fixed-capacity, statically allocated counterpart of std::vector. Like std::array, StaticVector
 // allocates contiguous storage for N elements of type T at compile time, but stores at most (rather
 // than exactly) N elements. Unlike std::array, its default constructor does not require T to have a
 // default constructor, since elements are constructed in place as the vector grows. Operations that
 // insert an element (emplace_back, push_back, etc.) fail when the vector is full. The API otherwise
 // adheres to standard containers, except the unstable_erase operation that does not preserve order,
 // and the replace operation that destructively emplaces.
 //
 // StaticVector<T, 1> is analogous to an iterable std::optional.
 // StaticVector<T, 0> is an error.
 //
 // Example usage:
 //
 //   ftl::StaticVector<char, 3> vector;
 //   assert(vector.empty());
 //
 //   vector = {'a', 'b'};
 //   assert(vector.size() == 2u);
 //
 //   vector.push_back('c');
 //   assert(vector.full());
 //
 //   assert(!vector.push_back('d'));
 //   assert(vector.size() == 3u);
 //
 //   vector.unstable_erase(vector.begin());
 //   assert(vector == (ftl::StaticVector{'c', 'b'}));
 //
 //   vector.pop_back();
 //   assert(vector.back() == 'c');
 //
 //   const char array[] = "hi";
 //   vector = ftl::StaticVector(array);
 //   assert(vector == (ftl::StaticVector{'h', 'i', '\0'}));
 //
 //   ftl::StaticVector strings = ftl::init::list<std::string>("abc")("123456", 3u)(3u, '?');
 //   assert(strings.size() == 3u);
 //   assert(strings[0] == "abc");
 //   assert(strings[1] == "123");
 //   assert(strings[2] == "???");
 //
 template <typename T, std::size_t N>
 class StaticVector final : ArrayTraits<T>,
                            ArrayIterators<StaticVector<T, N>, T>,
                            ArrayComparators<StaticVector> {
   static_assert(N > 0);

   using ArrayTraits<T>::construct_at;

   using Iter = ArrayIterators<StaticVector, T>;
   friend Iter;

   // There is ambiguity when constructing from two iterator-like elements like pointers:
   // they could be an iterator range, or arguments for in-place construction. Assume the
   // latter unless they are input iterators and cannot be used to construct elements. If
   // the former is intended, the caller can pass an IteratorRangeTag to disambiguate.
   template <typename I, typename Traits = std::iterator_traits<I>>
   using is_input_iterator =
       std::conjunction<std::is_base_of<std::input_iterator_tag, typename Traits::iterator_category>,
                        std::negation<std::is_constructible<T, I>>>;

  public:
   FTL_ARRAY_TRAIT(T, value_type);
   FTL_ARRAY_TRAIT(T, size_type);
   FTL_ARRAY_TRAIT(T, difference_type);

   FTL_ARRAY_TRAIT(T, pointer);
   FTL_ARRAY_TRAIT(T, reference);
   FTL_ARRAY_TRAIT(T, iterator);
   FTL_ARRAY_TRAIT(T, reverse_iterator);

   FTL_ARRAY_TRAIT(T, const_pointer);
   FTL_ARRAY_TRAIT(T, const_reference);
   FTL_ARRAY_TRAIT(T, const_iterator);
   FTL_ARRAY_TRAIT(T, const_reverse_iterator);

   // Creates an empty vector.
   StaticVector() = default;

   // Copies and moves a vector, respectively.
   StaticVector(const StaticVector& other)
       : StaticVector(kIteratorRange, other.begin(), other.end()) {}

   StaticVector(StaticVector&& other) { swap<true>(other); }

   // Copies at most N elements from a smaller convertible vector.
   template <typename U, std::size_t M, typename = std::enable_if_t<M <= N>>
   StaticVector(const StaticVector<U, M>& other)
       : StaticVector(kIteratorRange, other.begin(), other.end()) {}

   // Copies at most N elements from an array.
   template <typename U, std::size_t M>
   explicit StaticVector(U (&array)[M])
       : StaticVector(kIteratorRange, std::begin(array), std::end(array)) {}

   // Copies at most N elements from the range [first, last).
   //
   // IteratorRangeTag disambiguates with initialization from two iterator-like elements.
   //
   template <typename Iterator, typename = std::enable_if_t<is_input_iterator<Iterator>{}>>
   StaticVector(Iterator first, Iterator last) : StaticVector(kIteratorRange, first, last) {
     using V = typename std::iterator_traits<Iterator>::value_type;
     static_assert(std::is_constructible_v<value_type, V>, "Incompatible iterator range");
   }

   template <typename Iterator>
   StaticVector(IteratorRangeTag, Iterator first, Iterator last)
       : size_(std::min(max_size(), static_cast<size_type>(std::distance(first, last)))) {
     std::uninitialized_copy(first, first + size_, begin());
   }

   // Constructs at most N elements. The template arguments T and N are inferred using the
   // deduction guide defined below. Note that T is determined from the first element, and
   // subsequent elements must have convertible types:
   //
   //   ftl::StaticVector vector = {1, 2, 3};
   //   static_assert(std::is_same_v<decltype(vector), ftl::StaticVector<int, 3>>);
   //
   //   const auto copy = "quince"s;
   //   auto move = "tart"s;
   //   ftl::StaticVector vector = {copy, std::move(move)};
   //
   //   static_assert(std::is_same_v<decltype(vector), ftl::StaticVector<std::string, 2>>);
   //
   template <typename E, typename... Es,
             typename = std::enable_if_t<std::is_constructible_v<value_type, E>>>
   StaticVector(E&& element, Es&&... elements)
       : StaticVector(std::index_sequence<0>{}, std::forward<E>(element),
                      std::forward<Es>(elements)...) {
     static_assert(sizeof...(elements) < N, "Too many elements");
   }

   // Constructs at most N elements in place by forwarding per-element constructor arguments. The
   // template arguments T and N are inferred using the deduction guide defined below. The syntax
   // for listing arguments is as follows:
   //
   //   ftl::StaticVector vector = ftl::init::list<std::string>("abc")()(3u, '?');
   //
   //   static_assert(std::is_same_v<decltype(vector), ftl::StaticVector<std::string, 3>>);
   //   assert(vector.full());
   //   assert(vector[0] == "abc");
   //   assert(vector[1].empty());
   //   assert(vector[2] == "???");
   //
   template <typename U, std::size_t Size, std::size_t... Sizes, typename... Types>
   StaticVector(InitializerList<U, std::index_sequence<Size, Sizes...>, Types...>&& list)
       : StaticVector(std::index_sequence<0, 0, Size>{}, std::make_index_sequence<Size>{},
                      std::index_sequence<Sizes...>{}, list.tuple) {}

   ~StaticVector() { std::destroy(begin(), end()); }

   StaticVector& operator=(const StaticVector& other) {
     StaticVector copy(other);
     swap(copy);
     return *this;
   }

   StaticVector& operator=(StaticVector&& other) {
     std::destroy(begin(), end());
     size_ = 0;
     swap<true>(other);
     return *this;
   }

   // IsEmpty enables a fast path when the vector is known to be empty at compile time.
   template <bool IsEmpty = false>
   void swap(StaticVector&);

   static constexpr size_type max_size() { return N; }
   size_type size() const { return size_; }

   bool empty() const { return size() == 0; }
   bool full() const { return size() == max_size(); }

   iterator begin() { return std::launder(reinterpret_cast<pointer>(data_)); }
   iterator end() { return begin() + size(); }

   using Iter::begin;
   using Iter::end;

   using Iter::cbegin;
   using Iter::cend;

   using Iter::rbegin;
   using Iter::rend;

   using Iter::crbegin;
   using Iter::crend;

   using Iter::last;

   using Iter::back;
   using Iter::front;

   using Iter::operator[];

   // Replaces an element, and returns a reference to it. The iterator must be dereferenceable, so
   // replacing at end() is erroneous.
   //
   // The element is emplaced via move constructor, so type T does not need to define copy/move
   // assignment, e.g. its data members may be const.
   //
   // The arguments may directly or indirectly refer to the element being replaced.
   //
   // Iterators to the replaced element point to its replacement, and others remain valid.
   //
   template <typename... Args>
   reference replace(const_iterator it, Args&&... args) {
     value_type element{std::forward<Args>(args)...};
     std::destroy_at(it);
     // This is only safe because exceptions are disabled.
     return *construct_at(it, std::move(element));
   }

   // Appends an element, and returns an iterator to it. If the vector is full, the element is not
   // inserted, and the end() iterator is returned.
   //
   // On success, the end() iterator is invalidated.
   //
   template <typename... Args>
   iterator emplace_back(Args&&... args) {
     if (full()) return end();
     const iterator it = construct_at(end(), std::forward<Args>(args)...);
     ++size_;
     return it;
   }

   // Appends an element unless the vector is full, and returns whether the element was inserted.
   //
   // On success, the end() iterator is invalidated.
   //
   bool push_back(const value_type& v) {
     // Two statements for sequence point.
     const iterator it = emplace_back(v);
     return it != end();
   }

   bool push_back(value_type&& v) {
     // Two statements for sequence point.
     const iterator it = emplace_back(std::move(v));
     return it != end();
   }

   // Removes the last element. The vector must not be empty, or the call is erroneous.
   //
   // The last() and end() iterators are invalidated.
   //
   void pop_back() { unstable_erase(last()); }

   // Erases an element, but does not preserve order. Rather than shifting subsequent elements,
   // this moves the last element to the slot of the erased element.
   //
   // The last() and end() iterators, as well as those to the erased element, are invalidated.
   //
   void unstable_erase(const_iterator it) {
     std::destroy_at(it);
     if (it != last()) {
       // Move last element and destroy its source for destructor side effects. This is only
       // safe because exceptions are disabled.
       construct_at(it, std::move(back()));
       std::destroy_at(last());
     }
     --size_;
   }

  private:
   // Recursion for variadic constructor.
   template <std::size_t I, typename E, typename... Es>
   StaticVector(std::index_sequence<I>, E&& element, Es&&... elements)
       : StaticVector(std::index_sequence<I + 1>{}, std::forward<Es>(elements)...) {
     construct_at(begin() + I, std::forward<E>(element));
   }

   // Base case for variadic constructor.
   template <std::size_t I>
   explicit StaticVector(std::index_sequence<I>) : size_(I) {}

   // Recursion for in-place constructor.
   //
   // Construct element I by extracting its arguments from the InitializerList tuple. ArgIndex
   // is the position of its first argument in Args, and ArgCount is the number of arguments.
   // The Indices sequence corresponds to [0, ArgCount).
   //
   // The Sizes sequence lists the argument counts for elements after I, so Size is the ArgCount
   // for the next element. The recursion stops when Sizes is empty for the last element.
   //
   template <std::size_t I, std::size_t ArgIndex, std::size_t ArgCount, std::size_t... Indices,
             std::size_t Size, std::size_t... Sizes, typename... Args>
   StaticVector(std::index_sequence<I, ArgIndex, ArgCount>, std::index_sequence<Indices...>,
                std::index_sequence<Size, Sizes...>, std::tuple<Args...>& tuple)
       : StaticVector(std::index_sequence<I + 1, ArgIndex + ArgCount, Size>{},
                      std::make_index_sequence<Size>{}, std::index_sequence<Sizes...>{}, tuple) {
     construct_at(begin() + I, std::move(std::get<ArgIndex + Indices>(tuple))...);
   }

   // Base case for in-place constructor.
   template <std::size_t I, std::size_t ArgIndex, std::size_t ArgCount, std::size_t... Indices,
             typename... Args>
   StaticVector(std::index_sequence<I, ArgIndex, ArgCount>, std::index_sequence<Indices...>,
                std::index_sequence<>, std::tuple<Args...>& tuple)
       : size_(I + 1) {
     construct_at(begin() + I, std::move(std::get<ArgIndex + Indices>(tuple))...);
   }

   size_type size_ = 0;
   std::aligned_storage_t<sizeof(value_type), alignof(value_type)> data_[N];
 };

 // Deduction guide for array constructor.
 template <typename T, std::size_t N>
 StaticVector(T (&)[N]) -> StaticVector<std::remove_cv_t<T>, N>;

 // Deduction guide for variadic constructor.
 template <typename T, typename... Us, typename V = std::decay_t<T>,
           typename = std::enable_if_t<(std::is_constructible_v<V, Us> && ...)>>
 StaticVector(T&&, Us&&...) -> StaticVector<V, 1 + sizeof...(Us)>;

 // Deduction guide for in-place constructor.
 template <typename T, std::size_t... Sizes, typename... Types>
 StaticVector(InitializerList<T, std::index_sequence<Sizes...>, Types...>&&)
     -> StaticVector<T, sizeof...(Sizes)>;

 template <typename T, std::size_t N>
 template <bool IsEmpty>
 void StaticVector<T, N>::swap(StaticVector& other) {
   auto [to, from] = std::make_pair(this, &other);
   if (from == this) return;

   // Assume this vector has fewer elements, so the excess of the other vector will be moved to it.
   auto [min, max] = std::make_pair(size(), other.size());

   // No elements to swap if moving into an empty vector.
   if constexpr (IsEmpty) {
     assert(min == 0);
   } else {
     if (min > max) {
       std::swap(from, to);
       std::swap(min, max);
     }

     // Swap elements [0, min).
     std::swap_ranges(begin(), begin() + min, other.begin());

     // No elements to move if sizes are equal.
     if (min == max) return;
   }

   // Move elements [min, max) and destroy their source for destructor side effects.
   const auto [first, last] = std::make_pair(from->begin() + min, from->begin() + max);
   std::uninitialized_move(first, last, to->begin() + min);
   std::destroy(first, last);

   std::swap(size_, other.size_);
 }

 template <typename T, std::size_t N>
 inline void swap(StaticVector<T, N>& lhs, StaticVector<T, N>& rhs) {
   lhs.swap(rhs);
 }

 }  // namespace android::ftl
	/*
	* Copyright 2020 The Android Open Source Project
	*
	* Licensed 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.
	*/

	#pragma once

	#include <ftl/array_traits.h>
	#include <ftl/initializer_list.h>

	#include <algorithm>
	#include <cassert>
	#include <iterator>
	#include <memory>
	#include <type_traits>
	#include <utility>

	namespace android::ftl {

	constexpr struct IteratorRangeTag {
	} kIteratorRange;

	// Fixed-capacity, statically allocated counterpart of std::vector. Like std::array, StaticVector
	// allocates contiguous storage for N elements of type T at compile time, but stores at most (rather
	// than exactly) N elements. Unlike std::array, its default constructor does not require T to have a
	// default constructor, since elements are constructed in place as the vector grows. Operations that
	// insert an element (emplace_back, push_back, etc.) fail when the vector is full. The API otherwise
	// adheres to standard containers, except the unstable_erase operation that does not preserve order,
	// and the replace operation that destructively emplaces.
	//
	// StaticVector<T, 1> is analogous to an iterable std::optional.
	// StaticVector<T, 0> is an error.
	//
	// Example usage:
	//
	// ftl::StaticVector<char, 3> vector;
	// assert(vector.empty());
	//
	// vector = {'a', 'b'};
	// assert(vector.size() == 2u);
	//
	// vector.push_back('c');
	// assert(vector.full());
	//
	// assert(!vector.push_back('d'));
	// assert(vector.size() == 3u);
	//
	// vector.unstable_erase(vector.begin());
	// assert(vector == (ftl::StaticVector{'c', 'b'}));
	//
	// vector.pop_back();
	// assert(vector.back() == 'c');
	//
	// const char array[] = "hi";
	// vector = ftl::StaticVector(array);
	// assert(vector == (ftl::StaticVector{'h', 'i', '\0'}));
	//
	// ftl::StaticVector strings = ftl::init::list<std::string>("abc")("123456", 3u)(3u, '?');
	// assert(strings.size() == 3u);
	// assert(strings[0] == "abc");
	// assert(strings[1] == "123");
	// assert(strings[2] == "???");
	//
	template <typename T, std::size_t N>
	class StaticVector final : ArrayTraits<T>,
	ArrayIterators<StaticVector<T, N>, T>,
	ArrayComparators<StaticVector> {
	static_assert(N > 0);

	using ArrayTraits<T>::construct_at;

	using Iter = ArrayIterators<StaticVector, T>;
	friend Iter;

	// There is ambiguity when constructing from two iterator-like elements like pointers:
	// they could be an iterator range, or arguments for in-place construction. Assume the
	// latter unless they are input iterators and cannot be used to construct elements. If
	// the former is intended, the caller can pass an IteratorRangeTag to disambiguate.
	template <typename I, typename Traits = std::iterator_traits<I>>
	using is_input_iterator =
	std::conjunction<std::is_base_of<std::input_iterator_tag, typename Traits::iterator_category>,
	std::negation<std::is_constructible<T, I>>>;

	public:
	FTL_ARRAY_TRAIT(T, value_type);
	FTL_ARRAY_TRAIT(T, size_type);
	FTL_ARRAY_TRAIT(T, difference_type);

	FTL_ARRAY_TRAIT(T, pointer);
	FTL_ARRAY_TRAIT(T, reference);
	FTL_ARRAY_TRAIT(T, iterator);
	FTL_ARRAY_TRAIT(T, reverse_iterator);

	FTL_ARRAY_TRAIT(T, const_pointer);
	FTL_ARRAY_TRAIT(T, const_reference);
	FTL_ARRAY_TRAIT(T, const_iterator);
	FTL_ARRAY_TRAIT(T, const_reverse_iterator);

	// Creates an empty vector.
	StaticVector() = default;

	// Copies and moves a vector, respectively.
	StaticVector(const StaticVector& other)
	: StaticVector(kIteratorRange, other.begin(), other.end()) {}

	StaticVector(StaticVector&& other) { swap<true>(other); }

	// Copies at most N elements from a smaller convertible vector.
	template <typename U, std::size_t M, typename = std::enable_if_t<M <= N>>
	StaticVector(const StaticVector<U, M>& other)
	: StaticVector(kIteratorRange, other.begin(), other.end()) {}

	// Copies at most N elements from an array.
	template <typename U, std::size_t M>
	explicit StaticVector(U (&array)[M])
	: StaticVector(kIteratorRange, std::begin(array), std::end(array)) {}

	// Copies at most N elements from the range [first, last).
	//
	// IteratorRangeTag disambiguates with initialization from two iterator-like elements.
	//
	template <typename Iterator, typename = std::enable_if_t<is_input_iterator<Iterator>{}>>
	StaticVector(Iterator first, Iterator last) : StaticVector(kIteratorRange, first, last) {
	using V = typename std::iterator_traits<Iterator>::value_type;
	static_assert(std::is_constructible_v<value_type, V>, "Incompatible iterator range");
	}

	template <typename Iterator>
	StaticVector(IteratorRangeTag, Iterator first, Iterator last)
	: size_(std::min(max_size(), static_cast<size_type>(std::distance(first, last)))) {
	std::uninitialized_copy(first, first + size_, begin());
	}

	// Constructs at most N elements. The template arguments T and N are inferred using the
	// deduction guide defined below. Note that T is determined from the first element, and
	// subsequent elements must have convertible types:
	//
	// ftl::StaticVector vector = {1, 2, 3};
	// static_assert(std::is_same_v<decltype(vector), ftl::StaticVector<int, 3>>);
	//
	// const auto copy = "quince"s;
	// auto move = "tart"s;
	// ftl::StaticVector vector = {copy, std::move(move)};
	//
	// static_assert(std::is_same_v<decltype(vector), ftl::StaticVector<std::string, 2>>);
	//
	template <typename E, typename... Es,
	typename = std::enable_if_t<std::is_constructible_v<value_type, E>>>
	StaticVector(E&& element, Es&&... elements)
	: StaticVector(std::index_sequence<0>{}, std::forward<E>(element),
	std::forward<Es>(elements)...) {
	static_assert(sizeof...(elements) < N, "Too many elements");
	}

	// Constructs at most N elements in place by forwarding per-element constructor arguments. The
	// template arguments T and N are inferred using the deduction guide defined below. The syntax
	// for listing arguments is as follows:
	//
	// ftl::StaticVector vector = ftl::init::list<std::string>("abc")()(3u, '?');
	//
	// static_assert(std::is_same_v<decltype(vector), ftl::StaticVector<std::string, 3>>);
	// assert(vector.full());
	// assert(vector[0] == "abc");
	// assert(vector[1].empty());
	// assert(vector[2] == "???");
	//
	template <typename U, std::size_t Size, std::size_t... Sizes, typename... Types>
	StaticVector(InitializerList<U, std::index_sequence<Size, Sizes...>, Types...>&& list)
	: StaticVector(std::index_sequence<0, 0, Size>{}, std::make_index_sequence<Size>{},
	std::index_sequence<Sizes...>{}, list.tuple) {}

	~StaticVector() { std::destroy(begin(), end()); }

	StaticVector& operator=(const StaticVector& other) {
	StaticVector copy(other);
	swap(copy);
	return *this;
	}

	StaticVector& operator=(StaticVector&& other) {
	std::destroy(begin(), end());
	size_ = 0;
	swap<true>(other);
	return *this;
	}

	// IsEmpty enables a fast path when the vector is known to be empty at compile time.
	template <bool IsEmpty = false>
	void swap(StaticVector&);

	static constexpr size_type max_size() { return N; }
	size_type size() const { return size_; }

	bool empty() const { return size() == 0; }
	bool full() const { return size() == max_size(); }

	iterator begin() { return std::launder(reinterpret_cast<pointer>(data_)); }
	iterator end() { return begin() + size(); }

	using Iter::begin;
	using Iter::end;

	using Iter::cbegin;
	using Iter::cend;

	using Iter::rbegin;
	using Iter::rend;

	using Iter::crbegin;
	using Iter::crend;

	using Iter::last;

	using Iter::back;
	using Iter::front;

	using Iter::operator[];

	// Replaces an element, and returns a reference to it. The iterator must be dereferenceable, so
	// replacing at end() is erroneous.
	//
	// The element is emplaced via move constructor, so type T does not need to define copy/move
	// assignment, e.g. its data members may be const.
	//
	// The arguments may directly or indirectly refer to the element being replaced.
	//
	// Iterators to the replaced element point to its replacement, and others remain valid.
	//
	template <typename... Args>
	reference replace(const_iterator it, Args&&... args) {
	value_type element{std::forward<Args>(args)...};
	std::destroy_at(it);
	// This is only safe because exceptions are disabled.
	return *construct_at(it, std::move(element));
	}

	// Appends an element, and returns an iterator to it. If the vector is full, the element is not
	// inserted, and the end() iterator is returned.
	//
	// On success, the end() iterator is invalidated.
	//
	template <typename... Args>
	iterator emplace_back(Args&&... args) {
	if (full()) return end();
	const iterator it = construct_at(end(), std::forward<Args>(args)...);
	++size_;
	return it;
	}

	// Appends an element unless the vector is full, and returns whether the element was inserted.
	//
	// On success, the end() iterator is invalidated.
	//
	bool push_back(const value_type& v) {
	// Two statements for sequence point.
	const iterator it = emplace_back(v);
	return it != end();
	}

	bool push_back(value_type&& v) {
	// Two statements for sequence point.
	const iterator it = emplace_back(std::move(v));
	return it != end();
	}

	// Removes the last element. The vector must not be empty, or the call is erroneous.
	//
	// The last() and end() iterators are invalidated.
	//
	void pop_back() { unstable_erase(last()); }

	// Erases an element, but does not preserve order. Rather than shifting subsequent elements,
	// this moves the last element to the slot of the erased element.
	//
	// The last() and end() iterators, as well as those to the erased element, are invalidated.
	//
	void unstable_erase(const_iterator it) {
	std::destroy_at(it);
	if (it != last()) {
	// Move last element and destroy its source for destructor side effects. This is only
	// safe because exceptions are disabled.
	construct_at(it, std::move(back()));
	std::destroy_at(last());
	}
	--size_;
	}

	private:
	// Recursion for variadic constructor.
	template <std::size_t I, typename E, typename... Es>
	StaticVector(std::index_sequence<I>, E&& element, Es&&... elements)
	: StaticVector(std::index_sequence<I + 1>{}, std::forward<Es>(elements)...) {
	construct_at(begin() + I, std::forward<E>(element));
	}

	// Base case for variadic constructor.
	template <std::size_t I>
	explicit StaticVector(std::index_sequence<I>) : size_(I) {}

	// Recursion for in-place constructor.
	//
	// Construct element I by extracting its arguments from the InitializerList tuple. ArgIndex
	// is the position of its first argument in Args, and ArgCount is the number of arguments.
	// The Indices sequence corresponds to [0, ArgCount).
	//
	// The Sizes sequence lists the argument counts for elements after I, so Size is the ArgCount
	// for the next element. The recursion stops when Sizes is empty for the last element.
	//
	template <std::size_t I, std::size_t ArgIndex, std::size_t ArgCount, std::size_t... Indices,
	std::size_t Size, std::size_t... Sizes, typename... Args>
	StaticVector(std::index_sequence<I, ArgIndex, ArgCount>, std::index_sequence<Indices...>,
	std::index_sequence<Size, Sizes...>, std::tuple<Args...>& tuple)
	: StaticVector(std::index_sequence<I + 1, ArgIndex + ArgCount, Size>{},
	std::make_index_sequence<Size>{}, std::index_sequence<Sizes...>{}, tuple) {
	construct_at(begin() + I, std::move(std::get<ArgIndex + Indices>(tuple))...);
	}

	// Base case for in-place constructor.
	template <std::size_t I, std::size_t ArgIndex, std::size_t ArgCount, std::size_t... Indices,
	typename... Args>
	StaticVector(std::index_sequence<I, ArgIndex, ArgCount>, std::index_sequence<Indices...>,
	std::index_sequence<>, std::tuple<Args...>& tuple)
	: size_(I + 1) {
	construct_at(begin() + I, std::move(std::get<ArgIndex + Indices>(tuple))...);
	}

	size_type size_ = 0;
	std::aligned_storage_t<sizeof(value_type), alignof(value_type)> data_[N];
	};

	// Deduction guide for array constructor.
	template <typename T, std::size_t N>
	StaticVector(T (&)[N]) -> StaticVector<std::remove_cv_t<T>, N>;

	// Deduction guide for variadic constructor.
	template <typename T, typename... Us, typename V = std::decay_t<T>,
	typename = std::enable_if_t<(std::is_constructible_v<V, Us> && ...)>>
	StaticVector(T&&, Us&&...) -> StaticVector<V, 1 + sizeof...(Us)>;

	// Deduction guide for in-place constructor.
	template <typename T, std::size_t... Sizes, typename... Types>
	StaticVector(InitializerList<T, std::index_sequence<Sizes...>, Types...>&&)
	-> StaticVector<T, sizeof...(Sizes)>;

	template <typename T, std::size_t N>
	template <bool IsEmpty>
	void StaticVector<T, N>::swap(StaticVector& other) {
	auto [to, from] = std::make_pair(this, &other);
	if (from == this) return;

	// Assume this vector has fewer elements, so the excess of the other vector will be moved to it.
	auto [min, max] = std::make_pair(size(), other.size());

	// No elements to swap if moving into an empty vector.
	if constexpr (IsEmpty) {
	assert(min == 0);
	} else {
	if (min > max) {
	std::swap(from, to);
	std::swap(min, max);
	}

	// Swap elements [0, min).
	std::swap_ranges(begin(), begin() + min, other.begin());

	// No elements to move if sizes are equal.
	if (min == max) return;
	}

	// Move elements [min, max) and destroy their source for destructor side effects.
	const auto [first, last] = std::make_pair(from->begin() + min, from->begin() + max);
	std::uninitialized_move(first, last, to->begin() + min);
	std::destroy(first, last);

	std::swap(size_, other.size_);
	}

	template <typename T, std::size_t N>
	inline void swap(StaticVector<T, N>& lhs, StaticVector<T, N>& rhs) {
	lhs.swap(rhs);
	}

	} // namespace android::ftl