431a9c00a5
On Linux and macOS, using Clang to compile OpenStarbound produces about 400 MB worth of warnings during the build, making the compiler output unreadable and slowing the build down considerably. 99% of the warnings were unqualified uses of std::move and std::forward, which are now all properly qualified. Fixed a few other minor warnings about non-virtual destructors and some uses of std::move preventing copy elision on temporary objects. Most remaining warnings are now unused parameters.
448 lines
13 KiB
C++
448 lines
13 KiB
C++
#ifndef STAR_SMALL_VECTOR_HPP
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#define STAR_SMALL_VECTOR_HPP
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#include "StarAlgorithm.hpp"
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namespace Star {
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// A vector that is stack allocated up to a maximum size, becoming heap
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// allocated when it grows beyond that size. Always takes up stack space of
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// MaxStackSize * sizeof(Element).
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template <typename Element, size_t MaxStackSize>
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class SmallVector {
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public:
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typedef Element* iterator;
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typedef Element const* const_iterator;
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typedef std::reverse_iterator<iterator> reverse_iterator;
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typedef std::reverse_iterator<const_iterator> const_reverse_iterator;
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typedef Element value_type;
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typedef Element& reference;
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typedef Element const& const_reference;
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SmallVector();
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SmallVector(SmallVector const& other);
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SmallVector(SmallVector&& other);
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template <typename OtherElement, size_t OtherMaxStackSize>
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SmallVector(SmallVector<OtherElement, OtherMaxStackSize> const& other);
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template <class Iterator>
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SmallVector(Iterator first, Iterator last);
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SmallVector(size_t size, Element const& value = Element());
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SmallVector(initializer_list<Element> list);
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~SmallVector();
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SmallVector& operator=(SmallVector const& other);
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SmallVector& operator=(SmallVector&& other);
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SmallVector& operator=(std::initializer_list<Element> list);
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size_t size() const;
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bool empty() const;
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void resize(size_t size, Element const& e = Element());
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void reserve(size_t capacity);
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reference at(size_t i);
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const_reference at(size_t i) const;
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reference operator[](size_t i);
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const_reference operator[](size_t i) const;
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const_iterator begin() const;
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const_iterator end() const;
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iterator begin();
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iterator end();
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const_reverse_iterator rbegin() const;
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const_reverse_iterator rend() const;
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reverse_iterator rbegin();
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reverse_iterator rend();
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// Pointer to internal data, always valid even if empty.
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Element const* ptr() const;
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Element* ptr();
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void push_back(Element e);
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void pop_back();
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iterator insert(iterator pos, Element e);
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template <typename Iterator>
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iterator insert(iterator pos, Iterator begin, Iterator end);
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iterator insert(iterator pos, initializer_list<Element> list);
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template <typename... Args>
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void emplace(iterator pos, Args&&... args);
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template <typename... Args>
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void emplace_back(Args&&... args);
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void clear();
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iterator erase(iterator pos);
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iterator erase(iterator begin, iterator end);
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bool operator==(SmallVector const& other) const;
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bool operator!=(SmallVector const& other) const;
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bool operator<(SmallVector const& other) const;
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private:
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typename std::aligned_storage<MaxStackSize * sizeof(Element), alignof(Element)>::type m_stackElements;
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bool isHeapAllocated() const;
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Element* m_begin;
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Element* m_end;
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Element* m_capacity;
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};
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template <typename Element, size_t MaxStackSize>
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SmallVector<Element, MaxStackSize>::SmallVector() {
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m_begin = (Element*)&m_stackElements;
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m_end = m_begin;
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m_capacity = m_begin + MaxStackSize;
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}
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template <typename Element, size_t MaxStackSize>
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SmallVector<Element, MaxStackSize>::~SmallVector() {
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clear();
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if (isHeapAllocated()) {
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free(m_begin, (m_capacity - m_begin) * sizeof(Element));
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}
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}
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template <typename Element, size_t MaxStackSize>
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SmallVector<Element, MaxStackSize>::SmallVector(SmallVector const& other)
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: SmallVector() {
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insert(begin(), other.begin(), other.end());
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}
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template <typename Element, size_t MaxStackSize>
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SmallVector<Element, MaxStackSize>::SmallVector(SmallVector&& other)
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: SmallVector() {
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for (auto& e : other)
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emplace_back(std::move(e));
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}
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template <typename Element, size_t MaxStackSize>
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template <typename OtherElement, size_t OtherMaxStackSize>
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SmallVector<Element, MaxStackSize>::SmallVector(SmallVector<OtherElement, OtherMaxStackSize> const& other)
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: SmallVector() {
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for (auto const& e : other)
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emplace_back(e);
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}
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template <typename Element, size_t MaxStackSize>
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template <class Iterator>
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SmallVector<Element, MaxStackSize>::SmallVector(Iterator first, Iterator last)
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: SmallVector() {
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insert(begin(), first, last);
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}
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template <typename Element, size_t MaxStackSize>
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SmallVector<Element, MaxStackSize>::SmallVector(size_t size, Element const& value)
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: SmallVector() {
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resize(size, value);
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}
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template <typename Element, size_t MaxStackSize>
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SmallVector<Element, MaxStackSize>::SmallVector(initializer_list<Element> list)
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: SmallVector() {
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for (auto const& e : list)
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emplace_back(e);
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}
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template <typename Element, size_t MaxStackSize>
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auto SmallVector<Element, MaxStackSize>::operator=(SmallVector const& other) -> SmallVector& {
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if (this == &other)
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return *this;
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resize(other.size());
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for (size_t i = 0; i < size(); ++i)
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operator[](i) = other[i];
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return *this;
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}
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template <typename Element, size_t MaxStackSize>
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auto SmallVector<Element, MaxStackSize>::operator=(SmallVector&& other) -> SmallVector& {
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resize(other.size());
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for (size_t i = 0; i < size(); ++i)
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operator[](i) = std::move(other[i]);
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return *this;
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}
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template <typename Element, size_t MaxStackSize>
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auto SmallVector<Element, MaxStackSize>::operator=(std::initializer_list<Element> list) -> SmallVector& {
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resize(list.size());
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for (size_t i = 0; i < size(); ++i)
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operator[](i) = std::move(list[i]);
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return *this;
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}
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template <typename Element, size_t MaxStackSize>
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size_t SmallVector<Element, MaxStackSize>::size() const {
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return m_end - m_begin;
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}
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template <typename Element, size_t MaxStackSize>
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bool SmallVector<Element, MaxStackSize>::empty() const {
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return m_begin == m_end;
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}
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template <typename Element, size_t MaxStackSize>
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void SmallVector<Element, MaxStackSize>::resize(size_t size, Element const& e) {
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reserve(size);
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for (size_t i = this->size(); i > size; --i)
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pop_back();
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for (size_t i = this->size(); i < size; ++i)
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emplace_back(e);
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}
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template <typename Element, size_t MaxStackSize>
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void SmallVector<Element, MaxStackSize>::reserve(size_t newCapacity) {
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size_t oldCapacity = m_capacity - m_begin;
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if (newCapacity > oldCapacity) {
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newCapacity = max(oldCapacity * 2, newCapacity);
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auto newMem = (Element*)Star::malloc(newCapacity * sizeof(Element));
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if (!newMem)
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throw MemoryException::format("Could not set new SmallVector capacity {}\n", newCapacity);
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size_t size = m_end - m_begin;
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auto oldMem = m_begin;
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auto oldHeapAllocated = isHeapAllocated();
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// We assume that move constructors can never throw.
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for (size_t i = 0; i < size; ++i) {
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new (&newMem[i]) Element(std::move(oldMem[i]));
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}
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m_begin = newMem;
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m_end = m_begin + size;
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m_capacity = m_begin + newCapacity;
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auto freeOldMem = finally([=]() {
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if (oldHeapAllocated)
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Star::free(oldMem, oldCapacity * sizeof(Element));
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});
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for (size_t i = 0; i < size; ++i) {
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oldMem[i].~Element();
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}
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}
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}
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template <typename Element, size_t MaxStackSize>
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auto SmallVector<Element, MaxStackSize>::at(size_t i) -> reference {
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if (i >= size())
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throw OutOfRangeException::format("out of range in SmallVector::at({})", i);
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return m_begin[i];
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}
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template <typename Element, size_t MaxStackSize>
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auto SmallVector<Element, MaxStackSize>::at(size_t i) const -> const_reference {
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if (i >= size())
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throw OutOfRangeException::format("out of range in SmallVector::at({})", i);
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return m_begin[i];
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}
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template <typename Element, size_t MaxStackSize>
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auto SmallVector<Element, MaxStackSize>::operator[](size_t i) -> reference {
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starAssert(i < size());
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return m_begin[i];
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}
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template <typename Element, size_t MaxStackSize>
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auto SmallVector<Element, MaxStackSize>::operator[](size_t i) const -> const_reference {
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starAssert(i < size());
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return m_begin[i];
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}
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template <typename Element, size_t MaxStackSize>
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auto SmallVector<Element, MaxStackSize>::begin() const -> const_iterator {
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return m_begin;
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}
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template <typename Element, size_t MaxStackSize>
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auto SmallVector<Element, MaxStackSize>::end() const -> const_iterator {
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return m_end;
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}
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template <typename Element, size_t MaxStackSize>
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auto SmallVector<Element, MaxStackSize>::begin() -> iterator {
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return m_begin;
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}
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template <typename Element, size_t MaxStackSize>
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auto SmallVector<Element, MaxStackSize>::end() -> iterator {
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return m_end;
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}
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template <typename Element, size_t MaxStackSize>
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auto SmallVector<Element, MaxStackSize>::rbegin() const -> const_reverse_iterator {
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return const_reverse_iterator(end());
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}
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template <typename Element, size_t MaxStackSize>
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auto SmallVector<Element, MaxStackSize>::rend() const -> const_reverse_iterator {
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return const_reverse_iterator(begin());
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}
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template <typename Element, size_t MaxStackSize>
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auto SmallVector<Element, MaxStackSize>::rbegin() -> reverse_iterator {
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return reverse_iterator(end());
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}
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template <typename Element, size_t MaxStackSize>
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auto SmallVector<Element, MaxStackSize>::rend() -> reverse_iterator {
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return reverse_iterator(begin());
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}
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template <typename Element, size_t MaxStackSize>
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Element const* SmallVector<Element, MaxStackSize>::ptr() const {
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return m_begin;
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}
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template <typename Element, size_t MaxStackSize>
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Element* SmallVector<Element, MaxStackSize>::ptr() {
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return m_begin;
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}
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template <typename Element, size_t MaxStackSize>
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void SmallVector<Element, MaxStackSize>::push_back(Element e) {
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emplace_back(std::move(e));
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}
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template <typename Element, size_t MaxStackSize>
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void SmallVector<Element, MaxStackSize>::pop_back() {
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if (m_begin == m_end)
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throw OutOfRangeException("SmallVector::pop_back called on empty SmallVector");
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--m_end;
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m_end->~Element();
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}
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template <typename Element, size_t MaxStackSize>
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auto SmallVector<Element, MaxStackSize>::insert(iterator pos, Element e) -> iterator {
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emplace(pos, std::move(e));
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return pos;
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}
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template <typename Element, size_t MaxStackSize>
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template <typename Iterator>
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auto SmallVector<Element, MaxStackSize>::insert(iterator pos, Iterator begin, Iterator end) -> iterator {
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size_t toAdd = std::distance(begin, end);
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size_t startIndex = pos - m_begin;
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size_t endIndex = startIndex + toAdd;
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size_t toShift = size() - startIndex;
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resize(size() + toAdd);
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for (size_t i = toShift; i != 0; --i)
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operator[](endIndex + i - 1) = std::move(operator[](startIndex + i - 1));
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for (size_t i = 0; i != toAdd; ++i)
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operator[](startIndex + i) = *begin++;
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return pos;
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}
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template <typename Element, size_t MaxStackSize>
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auto SmallVector<Element, MaxStackSize>::insert(iterator pos, initializer_list<Element> list) -> iterator {
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return insert(pos, list.begin(), list.end());
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}
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template <typename Element, size_t MaxStackSize>
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template <typename... Args>
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void SmallVector<Element, MaxStackSize>::emplace(iterator pos, Args&&... args) {
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size_t index = pos - m_begin;
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emplace_back(Element());
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for (size_t i = size() - 1; i != index; --i)
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operator[](i) = std::move(operator[](i - 1));
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operator[](index) = Element(std::forward<Args>(args)...);
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}
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template <typename Element, size_t MaxStackSize>
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template <typename... Args>
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void SmallVector<Element, MaxStackSize>::emplace_back(Args&&... args) {
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if (m_end == m_capacity)
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reserve(size() + 1);
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new (m_end) Element(std::forward<Args>(args)...);
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++m_end;
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}
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template <typename Element, size_t MaxStackSize>
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void SmallVector<Element, MaxStackSize>::clear() {
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while (m_begin != m_end)
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pop_back();
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}
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template <typename Element, size_t MaxStackSize>
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auto SmallVector<Element, MaxStackSize>::erase(iterator pos) -> iterator {
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size_t index = pos - ptr();
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for (size_t i = index; i < size() - 1; ++i)
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operator[](i) = std::move(operator[](i + 1));
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pop_back();
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return pos;
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}
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template <typename Element, size_t MaxStackSize>
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auto SmallVector<Element, MaxStackSize>::erase(iterator begin, iterator end) -> iterator {
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size_t startIndex = begin - ptr();
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size_t endIndex = end - ptr();
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size_t toRemove = endIndex - startIndex;
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for (size_t i = endIndex; i < size(); ++i)
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operator[](startIndex + (i - endIndex)) = std::move(operator[](i));
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resize(size() - toRemove);
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return begin;
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}
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template <typename Element, size_t MaxStackSize>
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bool SmallVector<Element, MaxStackSize>::operator==(SmallVector const& other) const {
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if (this == &other)
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return true;
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if (size() != other.size())
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return false;
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for (size_t i = 0; i < size(); ++i) {
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if (operator[](i) != other[i])
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return false;
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}
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return true;
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}
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template <typename Element, size_t MaxStackSize>
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bool SmallVector<Element, MaxStackSize>::operator!=(SmallVector const& other) const {
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return !operator==(other);
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}
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template <typename Element, size_t MaxStackSize>
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bool SmallVector<Element, MaxStackSize>::operator<(SmallVector const& other) const {
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for (size_t i = 0; i < size(); ++i) {
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if (i >= other.size())
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return false;
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Element const& a = operator[](i);
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Element const& b = other[i];
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if (a < b)
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return true;
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else if (b < a)
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return false;
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}
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return size() < other.size();
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}
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template <typename Element, size_t MaxStackSize>
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bool SmallVector<Element, MaxStackSize>::isHeapAllocated() const {
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return m_begin != (Element*)&m_stackElements;
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}
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}
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#endif
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