379 lines
11 KiB
C
379 lines
11 KiB
C
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#pragma once
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#include "Memory.h"
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#include <algorithm> // std::max
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#include <memory> // std::uninitialized_fill
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// dynamic_array - simplified version of std::vector<T>
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//
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// features:
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// . always uses memcpy for copying elements. Your data structures must be simple and can't have internal pointers / rely on copy constructor.
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// . EASTL like push_back(void) implementation
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// Existing std STL implementations implement insertion operations by copying from an element.
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// For example, resize(size() + 1) creates a throw-away temporary object.
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// There is no way in existing std STL implementations to add an element to a container without implicitly or
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// explicitly providing one to copy from (aside from some existing POD optimizations).
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// For expensive-to-construct objects this creates a potentially serious performance problem.
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// . grows X2 on reallocation
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// . small code footprint
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// . clear actually deallocates memory
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// . resize does NOT initialize members!
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//
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// Changelog:
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// Added pop_back()
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// Added assign()
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// Added clear() - frees the data, use resize(0) to clear w/o freeing
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// zero allocation for empty array
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//
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namespace il2cpp
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{
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namespace utils
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{
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template<typename T>
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struct AlignOfType
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{
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enum
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{
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align = ALIGN_OF(T)
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};
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};
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template<typename T, size_t ALIGN = AlignOfType<T>::align>
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struct dynamic_array
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{
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public:
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enum
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{
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align = ALIGN
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};
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typedef T *iterator;
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typedef const T *const_iterator;
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typedef T value_type;
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typedef size_t size_type;
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typedef size_t difference_type;
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typedef T &reference;
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typedef const T &const_reference;
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public:
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dynamic_array() : m_data(NULL), m_size(0), m_capacity(0)
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{
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}
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explicit dynamic_array(size_t size)
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: m_size(size), m_capacity(size)
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{
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m_data = allocate(size);
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}
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dynamic_array(size_t size, T const &init_value)
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: m_size(size), m_capacity(size)
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{
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m_data = allocate(size);
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std::uninitialized_fill(m_data, m_data + size, init_value);
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}
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~dynamic_array()
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{
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if (owns_data())
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m_data = deallocate(m_data);
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}
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dynamic_array(const dynamic_array &other) : m_size(0), m_capacity(0)
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{
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m_data = NULL;
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assign(other.begin(), other.end());
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}
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dynamic_array &operator=(const dynamic_array &other)
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{
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// should not allocate memory unless we have to
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if (&other != this)
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assign(other.begin(), other.end());
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return *this;
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}
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void clear()
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{
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if (owns_data())
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m_data = deallocate(m_data);
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m_size = 0;
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m_capacity = 0;
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}
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void assign(const_iterator begin, const_iterator end)
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{
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Assert(begin <= end);
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resize_uninitialized(end - begin);
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memcpy(m_data, begin, m_size * sizeof(T));
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}
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iterator erase(iterator input_begin, iterator input_end)
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{
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Assert(input_begin <= input_end);
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Assert(input_begin >= begin());
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Assert(input_end <= end());
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size_t leftOverSize = end() - input_end;
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memmove(input_begin, input_end, leftOverSize * sizeof(T));
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m_size -= input_end - input_begin;
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return input_begin;
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}
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iterator erase(iterator it)
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{
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return erase(it, it + 1);
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}
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iterator erase_swap_back(iterator it)
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{
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m_size--;
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memcpy(it, end(), sizeof(T));
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return it;
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}
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iterator insert(iterator insert_before, const_iterator input_begin, const_iterator input_end)
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{
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Assert(input_begin <= input_end);
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Assert(insert_before >= begin());
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Assert(insert_before <= end());
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// resize (make sure that insertBefore does not get invalid in the meantime because of a reallocation)
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size_t insert_before_index = insert_before - begin();
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size_t elements_to_be_moved = size() - insert_before_index;
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resize_uninitialized((input_end - input_begin) + size(), true);
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insert_before = begin() + insert_before_index;
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size_t insertsize = input_end - input_begin;
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// move to the end of where the inserted data will be
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memmove(insert_before + insertsize, insert_before, elements_to_be_moved * sizeof(T));
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// inject input data in the hole we just created
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memcpy(insert_before, input_begin, insertsize * sizeof(T));
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return insert_before;
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}
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iterator insert(iterator insertBefore, const T &t) { return insert(insertBefore, &t, &t + 1); }
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void swap(dynamic_array &other) throw ()
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{
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std::swap(m_data, other.m_data);
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std::swap(m_size, other.m_size);
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std::swap(m_capacity, other.m_capacity);
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}
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// Returns the memory to the object.
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// This does not call the constructor for the newly added element.
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// You are expected to initialize all member variables of the returned data.
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T &push_back()
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{
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if (++m_size > capacity())
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reserve(std::max<size_t>(capacity() * 2, 1));
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return back();
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}
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// push_back but it also calls the constructor for the newly added element.
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T &push_back_construct()
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{
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if (++m_size > capacity())
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reserve(std::max<size_t>(capacity() * 2, 1));
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// construct
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T *ptr = &back();
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new(ptr)T;
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return *ptr;
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}
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// push_back but assigns /t/ to the newly added element.
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void push_back(const T &t)
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{
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push_back() = t;
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}
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void pop_back()
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{
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Assert(m_size >= 1);
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m_size--;
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}
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void resize_uninitialized(size_t size, bool double_on_resize = false)
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{
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m_size = size;
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if (m_size <= capacity())
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return;
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if (double_on_resize && size < capacity() * 2)
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size = capacity() * 2;
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reserve(size);
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}
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void resize_initialized(size_t size, const T &t = T(), bool double_on_resize = false)
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{
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if (size > capacity())
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{
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size_t requested_size = size;
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if (double_on_resize && size < capacity() * 2)
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requested_size = capacity() * 2;
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reserve(requested_size);
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}
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if (size > m_size)
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std::uninitialized_fill(m_data + m_size, m_data + size, t);
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m_size = size;
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}
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void reserve(size_t inCapacity)
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{
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if (capacity() >= inCapacity)
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return;
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if (owns_data())
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{
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Assert((inCapacity & k_reference_bit) == 0 && "Dynamic array capacity overflow");
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m_capacity = inCapacity;
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m_data = reallocate(m_data, inCapacity);
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}
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else
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{
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T *newData = allocate(inCapacity);
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memcpy(newData, m_data, m_size * sizeof(T));
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// Invalidate old non-owned data, since using the data from two places is most likely a really really bad idea.
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#if IL2CPP_DEBUG
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memset(m_data, 0xCD, capacity() * sizeof(T));
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#endif
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m_capacity = inCapacity; // and clear reference bit
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m_data = newData;
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}
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}
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void assign_external(T *begin, T *end)
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{
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if (owns_data())
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m_data = deallocate(m_data);
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m_size = m_capacity = reinterpret_cast<value_type *>(end) - reinterpret_cast<value_type *>(begin);
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Assert(m_size < k_reference_bit);
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m_capacity |= k_reference_bit;
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m_data = begin;
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}
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void set_owns_data(bool ownsData)
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{
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if (ownsData)
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m_capacity &= ~k_reference_bit;
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else
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m_capacity |= k_reference_bit;
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}
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void shrink_to_fit()
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{
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if (owns_data())
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{
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m_capacity = m_size;
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m_data = reallocate(m_data, m_size);
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}
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}
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const T &back() const
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{
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Assert(m_size != 0);
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return m_data[m_size - 1];
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}
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const T &front() const
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{
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Assert(m_size != 0);
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return m_data[0];
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}
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T &back()
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{
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Assert(m_size != 0);
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return m_data[m_size - 1];
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}
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T &front()
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{
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Assert(m_size != 0);
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return m_data[0];
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}
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T *data() { return m_data; }
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T const *data() const { return m_data; }
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bool empty() const { return m_size == 0; }
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size_t size() const { return m_size; }
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size_t capacity() const { return m_capacity & ~k_reference_bit; }
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T const &operator[](size_t index) const
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{
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Assert(index < m_size);
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return m_data[index];
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}
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T &operator[](size_t index)
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{
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Assert(index < m_size);
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return m_data[index];
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}
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T const *begin() const { return m_data; }
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T *begin() { return m_data; }
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T const *end() const { return m_data + m_size; }
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T *end() { return m_data + m_size; }
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bool owns_data() { return (m_capacity & k_reference_bit) == 0; }
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bool equals(const dynamic_array &other) const
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{
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if (m_size != other.m_size)
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return false;
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for (int i = 0; i < m_size; i++)
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{
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if (!(m_data[i] == other.m_data[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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private:
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static const size_t k_reference_bit = (size_t)1 << (sizeof(size_t) * 8 - 1);
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T *allocate(size_t size)
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{
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return static_cast<T *>(IL2CPP_MALLOC_ALIGNED(size * sizeof(T), align));
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}
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T *deallocate(T *data)
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{
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Assert(owns_data());
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IL2CPP_FREE_ALIGNED(data);
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return NULL;
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}
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T *reallocate(T *data, size_t size)
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{
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Assert(owns_data());
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return static_cast<T *>(IL2CPP_REALLOC_ALIGNED(data, size * sizeof(T), align));
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}
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T *m_data;
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size_t m_size;
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size_t m_capacity;
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};
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} //namespace il2cpp
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} //namespace utils
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