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							// Protocol Buffers - Google's data interchange format
// Copyright 2008 Google Inc.  All rights reserved.
// https://developers.google.com/protocol-buffers/
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
//     * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
//     * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following disclaimer
// in the documentation and/or other materials provided with the
// distribution.
//     * Neither the name of Google Inc. nor the names of its
// contributors may be used to endorse or promote products derived from
// this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

// Author: kenton@google.com (Kenton Varda)
//  Based on original Protocol Buffers design by
//  Sanjay Ghemawat, Jeff Dean, and others.
//
// RepeatedField and RepeatedPtrField are used by generated protocol message
// classes to manipulate repeated fields.  These classes are very similar to
// STL's vector, but include a number of optimizations found to be useful
// specifically in the case of Protocol Buffers.  RepeatedPtrField is
// particularly different from STL vector as it manages ownership of the
// pointers that it contains.
//
// This header covers RepeatedField.

#ifndef GOOGLE_PROTOBUF_REPEATED_FIELD_H__
#define GOOGLE_PROTOBUF_REPEATED_FIELD_H__

#include <algorithm>
#include <iterator>
#include <limits>
#include <string>
#include <type_traits>
#include <utility>

#include <google/protobuf/stubs/logging.h>
#include <google/protobuf/stubs/common.h>
#include <google/protobuf/arena.h>
#include <google/protobuf/port.h>
#include <google/protobuf/message_lite.h>
#include <google/protobuf/repeated_ptr_field.h>

// Must be included last.
#include <google/protobuf/port_def.inc>

#ifdef SWIG
#error "You cannot SWIG proto headers"
#endif

namespace google
{
    namespace protobuf
    {

        class Message;

        namespace internal
        {

            template<typename T, int kRepHeaderSize>
            constexpr int RepeatedFieldLowerClampLimit()
            {
                // The header is padded to be at least `sizeof(T)` when it would be smaller
                // otherwise.
                static_assert(sizeof(T) <= kRepHeaderSize, "");
                // We want to pad the minimum size to be a power of two bytes, including the
                // header.
                // The first allocation is kRepHeaderSize bytes worth of elements for a total
                // of 2*kRepHeaderSize bytes.
                // For an 8-byte header, we allocate 8 bool, 2 ints, or 1 int64.
                return kRepHeaderSize / sizeof(T);
            }

            // kRepeatedFieldUpperClampLimit is the lowest signed integer value that
            // overflows when multiplied by 2 (which is undefined behavior). Sizes above
            // this will clamp to the maximum int value instead of following exponential
            // growth when growing a repeated field.
            constexpr int kRepeatedFieldUpperClampLimit =
                (std::numeric_limits<int>::max() / 2) + 1;

            template<typename Iter>
            inline int CalculateReserve(Iter begin, Iter end, std::forward_iterator_tag)
            {
                return static_cast<int>(std::distance(begin, end));
            }

            template<typename Iter>
            inline int CalculateReserve(Iter /*begin*/, Iter /*end*/, std::input_iterator_tag /*unused*/)
            {
                return -1;
            }

            template<typename Iter>
            inline int CalculateReserve(Iter begin, Iter end)
            {
                typedef typename std::iterator_traits<Iter>::iterator_category Category;
                return CalculateReserve(begin, end, Category());
            }

            // Swaps two blocks of memory of size sizeof(T).
            template<typename T>
            inline void SwapBlock(char* p, char* q)
            {
                T tmp;
                memcpy(&tmp, p, sizeof(T));
                memcpy(p, q, sizeof(T));
                memcpy(q, &tmp, sizeof(T));
            }

            // Swaps two blocks of memory of size kSize:
            //  template <int kSize> void memswap(char* p, char* q);
            template<int kSize>
            inline typename std::enable_if<(kSize == 0), void>::type memswap(char*, char*)
            {
            }

#define PROTO_MEMSWAP_DEF_SIZE(reg_type, max_size)                                         \
    template<int kSize>                                                                    \
    typename std::enable_if<(kSize >= sizeof(reg_type) && kSize < (max_size)), void>::type \
        memswap(char* p, char* q)                                                          \
    {                                                                                      \
        SwapBlock<reg_type>(p, q);                                                         \
        memswap<kSize - sizeof(reg_type)>(p + sizeof(reg_type), q + sizeof(reg_type));     \
    }

            PROTO_MEMSWAP_DEF_SIZE(uint8_t, 2)
            PROTO_MEMSWAP_DEF_SIZE(uint16_t, 4)
            PROTO_MEMSWAP_DEF_SIZE(uint32_t, 8)

#ifdef __SIZEOF_INT128__
            PROTO_MEMSWAP_DEF_SIZE(uint64_t, 16)
            PROTO_MEMSWAP_DEF_SIZE(__uint128_t, (1u << 31))
#else
            PROTO_MEMSWAP_DEF_SIZE(uint64_t, (1u << 31))
#endif

#undef PROTO_MEMSWAP_DEF_SIZE

            template<typename Element>
            class RepeatedIterator;

        }  // namespace internal

        // RepeatedField is used to represent repeated fields of a primitive type (in
        // other words, everything except strings and nested Messages).  Most users will
        // not ever use a RepeatedField directly; they will use the get-by-index,
        // set-by-index, and add accessors that are generated for all repeated fields.
        template<typename Element>
        class RepeatedField final
        {
            static_assert(
                alignof(Arena) >= alignof(Element),
                "We only support types that have an alignment smaller than Arena"
            );

        public:
            constexpr RepeatedField();
            explicit RepeatedField(Arena* arena);

            RepeatedField(const RepeatedField& other);

            template<typename Iter, typename = typename std::enable_if<std::is_constructible<Element, decltype(*std::declval<Iter>())>::value>::type>
            RepeatedField(Iter begin, Iter end);

            ~RepeatedField();

            RepeatedField& operator=(const RepeatedField& other);

            RepeatedField(RepeatedField&& other) noexcept;
            RepeatedField& operator=(RepeatedField&& other) noexcept;

            bool empty() const;
            int size() const;

            const Element& Get(int index) const;
            Element* Mutable(int index);

            const Element& operator[](int index) const
            {
                return Get(index);
            }
            Element& operator[](int index)
            {
                return *Mutable(index);
            }

            const Element& at(int index) const;
            Element& at(int index);

            void Set(int index, const Element& value);
            void Add(const Element& value);
            // Appends a new element and returns a pointer to it.
            // The new element is uninitialized if |Element| is a POD type.
            Element* Add();
            // Appends elements in the range [begin, end) after reserving
            // the appropriate number of elements.
            template<typename Iter>
            void Add(Iter begin, Iter end);

            // Removes the last element in the array.
            void RemoveLast();

            // Extracts elements with indices in "[start .. start+num-1]".
            // Copies them into "elements[0 .. num-1]" if "elements" is not nullptr.
            // Caution: also moves elements with indices [start+num ..].
            // Calling this routine inside a loop can cause quadratic behavior.
            void ExtractSubrange(int start, int num, Element* elements);

            PROTOBUF_ATTRIBUTE_REINITIALIZES void Clear();
            void MergeFrom(const RepeatedField& other);
            PROTOBUF_ATTRIBUTE_REINITIALIZES void CopyFrom(const RepeatedField& other);

            // Replaces the contents with RepeatedField(begin, end).
            template<typename Iter>
            PROTOBUF_ATTRIBUTE_REINITIALIZES void Assign(Iter begin, Iter end);

            // Reserves space to expand the field to at least the given size.  If the
            // array is grown, it will always be at least doubled in size.
            void Reserve(int new_size);

            // Resizes the RepeatedField to a new, smaller size.  This is O(1).
            void Truncate(int new_size);

            void AddAlreadyReserved(const Element& value);
            // Appends a new element and return a pointer to it.
            // The new element is uninitialized if |Element| is a POD type.
            // Should be called only if Capacity() > Size().
            Element* AddAlreadyReserved();
            Element* AddNAlreadyReserved(int elements);
            int Capacity() const;

            // Like STL resize.  Uses value to fill appended elements.
            // Like Truncate() if new_size <= size(), otherwise this is
            // O(new_size - size()).
            void Resize(int new_size, const Element& value);

            // Gets the underlying array.  This pointer is possibly invalidated by
            // any add or remove operation.
            Element* mutable_data();
            const Element* data() const;

            // Swaps entire contents with "other". If they are separate arenas then,
            // copies data between each other.
            void Swap(RepeatedField* other);

            // Swaps entire contents with "other". Should be called only if the caller can
            // guarantee that both repeated fields are on the same arena or are on the
            // heap. Swapping between different arenas is disallowed and caught by a
            // GOOGLE_DCHECK (see API docs for details).
            void UnsafeArenaSwap(RepeatedField* other);

            // Swaps two elements.
            void SwapElements(int index1, int index2);

            // STL-like iterator support
            typedef internal::RepeatedIterator<Element> iterator;
            typedef internal::RepeatedIterator<const Element> const_iterator;
            typedef Element value_type;
            typedef value_type& reference;
            typedef const value_type& const_reference;
            typedef value_type* pointer;
            typedef const value_type* const_pointer;
            typedef int size_type;
            typedef ptrdiff_t difference_type;

            iterator begin();
            const_iterator begin() const;
            const_iterator cbegin() const;
            iterator end();
            const_iterator end() const;
            const_iterator cend() const;

            // Reverse iterator support
            typedef std::reverse_iterator<const_iterator> const_reverse_iterator;
            typedef std::reverse_iterator<iterator> reverse_iterator;
            reverse_iterator rbegin()
            {
                return reverse_iterator(end());
            }
            const_reverse_iterator rbegin() const
            {
                return const_reverse_iterator(end());
            }
            reverse_iterator rend()
            {
                return reverse_iterator(begin());
            }
            const_reverse_iterator rend() const
            {
                return const_reverse_iterator(begin());
            }

            // Returns the number of bytes used by the repeated field, excluding
            // sizeof(*this)
            size_t SpaceUsedExcludingSelfLong() const;

            int SpaceUsedExcludingSelf() const
            {
                return internal::ToIntSize(SpaceUsedExcludingSelfLong());
            }

            // Removes the element referenced by position.
            //
            // Returns an iterator to the element immediately following the removed
            // element.
            //
            // Invalidates all iterators at or after the removed element, including end().
            iterator erase(const_iterator position);

            // Removes the elements in the range [first, last).
            //
            // Returns an iterator to the element immediately following the removed range.
            //
            // Invalidates all iterators at or after the removed range, including end().
            iterator erase(const_iterator first, const_iterator last);

            // Gets the Arena on which this RepeatedField stores its elements.
            inline Arena* GetArena() const
            {
                return GetOwningArena();
            }

            // For internal use only.
            //
            // This is public due to it being called by generated code.
            inline void InternalSwap(RepeatedField* other);

        private:
            template<typename T>
            friend class Arena::InternalHelper;

            // Gets the Arena on which this RepeatedField stores its elements.
            inline Arena* GetOwningArena() const
            {
                return (total_size_ == 0) ? static_cast<Arena*>(arena_or_elements_) : rep()->arena;
            }

            static constexpr int kInitialSize = 0;
            // A note on the representation here (see also comment below for
            // RepeatedPtrFieldBase's struct Rep):
            //
            // We maintain the same sizeof(RepeatedField) as before we added arena support
            // so that we do not degrade performance by bloating memory usage. Directly
            // adding an arena_ element to RepeatedField is quite costly. By using
            // indirection in this way, we keep the same size when the RepeatedField is
            // empty (common case), and add only an 8-byte header to the elements array
            // when non-empty. We make sure to place the size fields directly in the
            // RepeatedField class to avoid costly cache misses due to the indirection.
            int current_size_;
            int total_size_;
            // Pad the Rep after arena allow for power-of-two byte sizes when
            // sizeof(Element) > sizeof(Arena*). eg for 16-byte objects.
            static PROTOBUF_CONSTEXPR const size_t kRepHeaderSize =
                sizeof(Arena*) < sizeof(Element) ? sizeof(Element) : sizeof(Arena*);
            struct Rep
            {
                Arena* arena;
                Element* elements()
                {
                    return reinterpret_cast<Element*>(reinterpret_cast<char*>(this) + kRepHeaderSize);
                }
            };

            // If total_size_ == 0 this points to an Arena otherwise it points to the
            // elements member of a Rep struct. Using this invariant allows the storage of
            // the arena pointer without an extra allocation in the constructor.
            void* arena_or_elements_;

            // Returns a pointer to elements array.
            // pre-condition: the array must have been allocated.
            Element* elements() const
            {
                GOOGLE_DCHECK_GT(total_size_, 0);
                // Because of above pre-condition this cast is safe.
                return unsafe_elements();
            }

            // Returns a pointer to elements array if it exists; otherwise either null or
            // an invalid pointer is returned. This only happens for empty repeated
            // fields, where you can't dereference this pointer anyway (it's empty).
            Element* unsafe_elements() const
            {
                return static_cast<Element*>(arena_or_elements_);
            }

            // Returns a pointer to the Rep struct.
            // pre-condition: the Rep must have been allocated, ie elements() is safe.
            Rep* rep() const
            {
                return reinterpret_cast<Rep*>(reinterpret_cast<char*>(elements()) - kRepHeaderSize);
            }

            friend class Arena;
            typedef void InternalArenaConstructable_;

            // Moves the contents of |from| into |to|, possibly clobbering |from| in the
            // process.  For primitive types this is just a memcpy(), but it could be
            // specialized for non-primitive types to, say, swap each element instead.
            void MoveArray(Element* to, Element* from, int size);

            // Copies the elements of |from| into |to|.
            void CopyArray(Element* to, const Element* from, int size);

            // Internal helper to delete all elements and deallocate the storage.
            void InternalDeallocate(Rep* rep, int size, bool in_destructor)
            {
                if (rep != nullptr)
                {
                    Element* e = &rep->elements()[0];
                    if (!std::is_trivial<Element>::value)
                    {
                        Element* limit = &rep->elements()[size];
                        for (; e < limit; e++)
                        {
                            e->~Element();
                        }
                    }
                    const size_t bytes = size * sizeof(*e) + kRepHeaderSize;
                    if (rep->arena == nullptr)
                    {
                        internal::SizedDelete(rep, bytes);
                    }
                    else if (!in_destructor)
                    {
                        // If we are in the destructor, we might be being destroyed as part of
                        // the arena teardown. We can't try and return blocks to the arena then.
                        rep->arena->ReturnArrayMemory(rep, bytes);
                    }
                }
            }

            // This class is a performance wrapper around RepeatedField::Add(const T&)
            // function. In general unless a RepeatedField is a local stack variable LLVM
            // has a hard time optimizing Add. The machine code tends to be
            // loop:
            // mov %size, dword ptr [%repeated_field]       // load
            // cmp %size, dword ptr [%repeated_field + 4]
            // jae fallback
            // mov %buffer, qword ptr [%repeated_field + 8]
            // mov dword [%buffer + %size * 4], %value
            // inc %size                                    // increment
            // mov dword ptr [%repeated_field], %size       // store
            // jmp loop
            //
            // This puts a load/store in each iteration of the important loop variable
            // size. It's a pretty bad compile that happens even in simple cases, but
            // largely the presence of the fallback path disturbs the compilers mem-to-reg
            // analysis.
            //
            // This class takes ownership of a repeated field for the duration of its
            // lifetime. The repeated field should not be accessed during this time, ie.
            // only access through this class is allowed. This class should always be a
            // function local stack variable. Intended use
            //
            // void AddSequence(const int* begin, const int* end, RepeatedField<int>* out)
            // {
            //   RepeatedFieldAdder<int> adder(out);  // Take ownership of out
            //   for (auto it = begin; it != end; ++it) {
            //     adder.Add(*it);
            //   }
            // }
            //
            // Typically, due to the fact that adder is a local stack variable, the
            // compiler will be successful in mem-to-reg transformation and the machine
            // code will be loop: cmp %size, %capacity jae fallback mov dword ptr [%buffer
            // + %size * 4], %val inc %size jmp loop
            //
            // The first version executes at 7 cycles per iteration while the second
            // version executes at only 1 or 2 cycles.
            template<int = 0, bool = std::is_trivial<Element>::value>
            class FastAdderImpl
            {
            public:
                explicit FastAdderImpl(RepeatedField* rf) :
                    repeated_field_(rf)
                {
                    index_ = repeated_field_->current_size_;
                    capacity_ = repeated_field_->total_size_;
                    buffer_ = repeated_field_->unsafe_elements();
                }
                ~FastAdderImpl()
                {
                    repeated_field_->current_size_ = index_;
                }

                void Add(Element val)
                {
                    if (index_ == capacity_)
                    {
                        repeated_field_->current_size_ = index_;
                        repeated_field_->Reserve(index_ + 1);
                        capacity_ = repeated_field_->total_size_;
                        buffer_ = repeated_field_->unsafe_elements();
                    }
                    buffer_[index_++] = val;
                }

            private:
                RepeatedField* repeated_field_;
                int index_;
                int capacity_;
                Element* buffer_;

                GOOGLE_DISALLOW_EVIL_CONSTRUCTORS(FastAdderImpl);
            };

            // FastAdder is a wrapper for adding fields. The specialization above handles
            // POD types more efficiently than RepeatedField.
            template<int I>
            class FastAdderImpl<I, false>
            {
            public:
                explicit FastAdderImpl(RepeatedField* rf) :
                    repeated_field_(rf)
                {
                }
                void Add(const Element& val)
                {
                    repeated_field_->Add(val);
                }

            private:
                RepeatedField* repeated_field_;
                GOOGLE_DISALLOW_EVIL_CONSTRUCTORS(FastAdderImpl);
            };

            using FastAdder = FastAdderImpl<>;

            friend class TestRepeatedFieldHelper;
            friend class ::google::protobuf::internal::ParseContext;
        };

        namespace internal
        {

            // This is a helper template to copy an array of elements efficiently when they
            // have a trivial copy constructor, and correctly otherwise. This really
            // shouldn't be necessary, but our compiler doesn't optimize std::copy very
            // effectively.
            template<typename Element, bool HasTrivialCopy = std::is_trivial<Element>::value>
            struct ElementCopier
            {
                void operator()(Element* to, const Element* from, int array_size);
            };

        }  // namespace internal

        // implementation ====================================================

        template<typename Element>
        constexpr RepeatedField<Element>::RepeatedField() :
            current_size_(0),
            total_size_(0),
            arena_or_elements_(nullptr)
        {
        }

        template<typename Element>
        inline RepeatedField<Element>::RepeatedField(Arena* arena) :
            current_size_(0),
            total_size_(0),
            arena_or_elements_(arena)
        {
        }

        template<typename Element>
        inline RepeatedField<Element>::RepeatedField(const RepeatedField& other) :
            current_size_(0),
            total_size_(0),
            arena_or_elements_(nullptr)
        {
            if (other.current_size_ != 0)
            {
                Reserve(other.size());
                AddNAlreadyReserved(other.size());
                CopyArray(Mutable(0), &other.Get(0), other.size());
            }
        }

        template<typename Element>
        template<typename Iter, typename>
        RepeatedField<Element>::RepeatedField(Iter begin, Iter end) :
            current_size_(0),
            total_size_(0),
            arena_or_elements_(nullptr)
        {
            Add(begin, end);
        }

        template<typename Element>
        RepeatedField<Element>::~RepeatedField()
        {
#ifndef NDEBUG
            // Try to trigger segfault / asan failure in non-opt builds if arena_
            // lifetime has ended before the destructor.
            auto arena = GetOwningArena();
            if (arena)
                (void)arena->SpaceAllocated();
#endif
            if (total_size_ > 0)
            {
                InternalDeallocate(rep(), total_size_, true);
            }
        }

        template<typename Element>
        inline RepeatedField<Element>& RepeatedField<Element>::operator=(
            const RepeatedField& other
        )
        {
            if (this != &other)
                CopyFrom(other);
            return *this;
        }

        template<typename Element>
        inline RepeatedField<Element>::RepeatedField(RepeatedField&& other) noexcept
            :
            RepeatedField()
        {
#ifdef PROTOBUF_FORCE_COPY_IN_MOVE
            CopyFrom(other);
#else   // PROTOBUF_FORCE_COPY_IN_MOVE
        // We don't just call Swap(&other) here because it would perform 3 copies if
        // other is on an arena. This field can't be on an arena because arena
        // construction always uses the Arena* accepting constructor.
            if (other.GetOwningArena())
            {
                CopyFrom(other);
            }
            else
            {
                InternalSwap(&other);
            }
#endif  // !PROTOBUF_FORCE_COPY_IN_MOVE
        }

        template<typename Element>
        inline RepeatedField<Element>& RepeatedField<Element>::operator=(
            RepeatedField&& other
        ) noexcept
        {
            // We don't just call Swap(&other) here because it would perform 3 copies if
            // the two fields are on different arenas.
            if (this != &other)
            {
                if (GetOwningArena() != other.GetOwningArena()
#ifdef PROTOBUF_FORCE_COPY_IN_MOVE
                    || GetOwningArena() == nullptr
#endif  // !PROTOBUF_FORCE_COPY_IN_MOVE
                )
                {
                    CopyFrom(other);
                }
                else
                {
                    InternalSwap(&other);
                }
            }
            return *this;
        }

        template<typename Element>
        inline bool RepeatedField<Element>::empty() const
        {
            return current_size_ == 0;
        }

        template<typename Element>
        inline int RepeatedField<Element>::size() const
        {
            return current_size_;
        }

        template<typename Element>
        inline int RepeatedField<Element>::Capacity() const
        {
            return total_size_;
        }

        template<typename Element>
        inline void RepeatedField<Element>::AddAlreadyReserved(const Element& value)
        {
            GOOGLE_DCHECK_LT(current_size_, total_size_);
            elements()[current_size_++] = value;
        }

        template<typename Element>
        inline Element* RepeatedField<Element>::AddAlreadyReserved()
        {
            GOOGLE_DCHECK_LT(current_size_, total_size_);
            return &elements()[current_size_++];
        }

        template<typename Element>
        inline Element* RepeatedField<Element>::AddNAlreadyReserved(int elements)
        {
            GOOGLE_DCHECK_GE(total_size_ - current_size_, elements)
                << total_size_ << ", " << current_size_;
            // Warning: sometimes people call this when elements == 0 and
            // total_size_ == 0. In this case the return pointer points to a zero size
            // array (n == 0). Hence we can just use unsafe_elements(), because the user
            // cannot dereference the pointer anyway.
            Element* ret = unsafe_elements() + current_size_;
            current_size_ += elements;
            return ret;
        }

        template<typename Element>
        inline void RepeatedField<Element>::Resize(int new_size, const Element& value)
        {
            GOOGLE_DCHECK_GE(new_size, 0);
            if (new_size > current_size_)
            {
                Reserve(new_size);
                std::fill(&elements()[current_size_], &elements()[new_size], value);
            }
            current_size_ = new_size;
        }

        template<typename Element>
        inline const Element& RepeatedField<Element>::Get(int index) const
        {
            GOOGLE_DCHECK_GE(index, 0);
            GOOGLE_DCHECK_LT(index, current_size_);
            return elements()[index];
        }

        template<typename Element>
        inline const Element& RepeatedField<Element>::at(int index) const
        {
            GOOGLE_CHECK_GE(index, 0);
            GOOGLE_CHECK_LT(index, current_size_);
            return elements()[index];
        }

        template<typename Element>
        inline Element& RepeatedField<Element>::at(int index)
        {
            GOOGLE_CHECK_GE(index, 0);
            GOOGLE_CHECK_LT(index, current_size_);
            return elements()[index];
        }

        template<typename Element>
        inline Element* RepeatedField<Element>::Mutable(int index)
        {
            GOOGLE_DCHECK_GE(index, 0);
            GOOGLE_DCHECK_LT(index, current_size_);
            return &elements()[index];
        }

        template<typename Element>
        inline void RepeatedField<Element>::Set(int index, const Element& value)
        {
            GOOGLE_DCHECK_GE(index, 0);
            GOOGLE_DCHECK_LT(index, current_size_);
            elements()[index] = value;
        }

        template<typename Element>
        inline void RepeatedField<Element>::Add(const Element& value)
        {
            uint32_t size = current_size_;
            if (static_cast<int>(size) == total_size_)
            {
                // value could reference an element of the array. Reserving new space will
                // invalidate the reference. So we must make a copy first.
                auto tmp = value;
                Reserve(total_size_ + 1);
                elements()[size] = std::move(tmp);
            }
            else
            {
                elements()[size] = value;
            }
            current_size_ = size + 1;
        }

        template<typename Element>
        inline Element* RepeatedField<Element>::Add()
        {
            uint32_t size = current_size_;
            if (static_cast<int>(size) == total_size_)
                Reserve(total_size_ + 1);
            auto ptr = &elements()[size];
            current_size_ = size + 1;
            return ptr;
        }

        template<typename Element>
        template<typename Iter>
        inline void RepeatedField<Element>::Add(Iter begin, Iter end)
        {
            int reserve = internal::CalculateReserve(begin, end);
            if (reserve != -1)
            {
                if (reserve == 0)
                {
                    return;
                }

                Reserve(reserve + size());
                // TODO(ckennelly):  The compiler loses track of the buffer freshly
                // allocated by Reserve() by the time we call elements, so it cannot
                // guarantee that elements does not alias [begin(), end()).
                //
                // If restrict is available, annotating the pointer obtained from elements()
                // causes this to lower to memcpy instead of memmove.
                std::copy(begin, end, elements() + size());
                current_size_ = reserve + size();
            }
            else
            {
                FastAdder fast_adder(this);
                for (; begin != end; ++begin)
                    fast_adder.Add(*begin);
            }
        }

        template<typename Element>
        inline void RepeatedField<Element>::RemoveLast()
        {
            GOOGLE_DCHECK_GT(current_size_, 0);
            current_size_--;
        }

        template<typename Element>
        void RepeatedField<Element>::ExtractSubrange(int start, int num, Element* elements)
        {
            GOOGLE_DCHECK_GE(start, 0);
            GOOGLE_DCHECK_GE(num, 0);
            GOOGLE_DCHECK_LE(start + num, this->current_size_);

            // Save the values of the removed elements if requested.
            if (elements != nullptr)
            {
                for (int i = 0; i < num; ++i)
                    elements[i] = this->Get(i + start);
            }

            // Slide remaining elements down to fill the gap.
            if (num > 0)
            {
                for (int i = start + num; i < this->current_size_; ++i)
                    this->Set(i - num, this->Get(i));
                this->Truncate(this->current_size_ - num);
            }
        }

        template<typename Element>
        inline void RepeatedField<Element>::Clear()
        {
            current_size_ = 0;
        }

        template<typename Element>
        inline void RepeatedField<Element>::MergeFrom(const RepeatedField& other)
        {
            GOOGLE_DCHECK_NE(&other, this);
            if (other.current_size_ != 0)
            {
                int existing_size = size();
                Reserve(existing_size + other.size());
                AddNAlreadyReserved(other.size());
                CopyArray(Mutable(existing_size), &other.Get(0), other.size());
            }
        }

        template<typename Element>
        inline void RepeatedField<Element>::CopyFrom(const RepeatedField& other)
        {
            if (&other == this)
                return;
            Clear();
            MergeFrom(other);
        }

        template<typename Element>
        template<typename Iter>
        inline void RepeatedField<Element>::Assign(Iter begin, Iter end)
        {
            Clear();
            Add(begin, end);
        }

        template<typename Element>
        inline typename RepeatedField<Element>::iterator RepeatedField<Element>::erase(
            const_iterator position
        )
        {
            return erase(position, position + 1);
        }

        template<typename Element>
        inline typename RepeatedField<Element>::iterator RepeatedField<Element>::erase(
            const_iterator first, const_iterator last
        )
        {
            size_type first_offset = first - cbegin();
            if (first != last)
            {
                Truncate(std::copy(last, cend(), begin() + first_offset) - cbegin());
            }
            return begin() + first_offset;
        }

        template<typename Element>
        inline Element* RepeatedField<Element>::mutable_data()
        {
            return unsafe_elements();
        }

        template<typename Element>
        inline const Element* RepeatedField<Element>::data() const
        {
            return unsafe_elements();
        }

        template<typename Element>
        inline void RepeatedField<Element>::InternalSwap(RepeatedField* other)
        {
            GOOGLE_DCHECK(this != other);

            // Swap all fields at once.
            static_assert(std::is_standard_layout<RepeatedField<Element>>::value, "offsetof() requires standard layout before c++17");
            internal::memswap<offsetof(RepeatedField, arena_or_elements_) + sizeof(this->arena_or_elements_) - offsetof(RepeatedField, current_size_)>(
                reinterpret_cast<char*>(this) + offsetof(RepeatedField, current_size_),
                reinterpret_cast<char*>(other) + offsetof(RepeatedField, current_size_)
            );
        }

        template<typename Element>
        void RepeatedField<Element>::Swap(RepeatedField* other)
        {
            if (this == other)
                return;
#ifdef PROTOBUF_FORCE_COPY_IN_SWAP
            if (GetOwningArena() != nullptr &&
                GetOwningArena() == other->GetOwningArena())
            {
#else   // PROTOBUF_FORCE_COPY_IN_SWAP
            if (GetOwningArena() == other->GetOwningArena())
            {
#endif  // !PROTOBUF_FORCE_COPY_IN_SWAP
                InternalSwap(other);
            }
            else
            {
                RepeatedField<Element> temp(other->GetOwningArena());
                temp.MergeFrom(*this);
                CopyFrom(*other);
                other->UnsafeArenaSwap(&temp);
            }
        }

        template<typename Element>
        void RepeatedField<Element>::UnsafeArenaSwap(RepeatedField* other)
        {
            if (this == other)
                return;
            GOOGLE_DCHECK_EQ(GetOwningArena(), other->GetOwningArena());
            InternalSwap(other);
        }

        template<typename Element>
        void RepeatedField<Element>::SwapElements(int index1, int index2)
        {
            using std::swap;  // enable ADL with fallback
            swap(elements()[index1], elements()[index2]);
        }

        template<typename Element>
        inline typename RepeatedField<Element>::iterator
            RepeatedField<Element>::begin()
        {
            return iterator(unsafe_elements());
        }
        template<typename Element>
        inline typename RepeatedField<Element>::const_iterator
            RepeatedField<Element>::begin() const
        {
            return const_iterator(unsafe_elements());
        }
        template<typename Element>
        inline typename RepeatedField<Element>::const_iterator
            RepeatedField<Element>::cbegin() const
        {
            return const_iterator(unsafe_elements());
        }
        template<typename Element>
        inline typename RepeatedField<Element>::iterator RepeatedField<Element>::end()
        {
            return iterator(unsafe_elements() + current_size_);
        }
        template<typename Element>
        inline typename RepeatedField<Element>::const_iterator
            RepeatedField<Element>::end() const
        {
            return const_iterator(unsafe_elements() + current_size_);
        }
        template<typename Element>
        inline typename RepeatedField<Element>::const_iterator
            RepeatedField<Element>::cend() const
        {
            return const_iterator(unsafe_elements() + current_size_);
        }

        template<typename Element>
        inline size_t RepeatedField<Element>::SpaceUsedExcludingSelfLong() const
        {
            return total_size_ > 0 ? (total_size_ * sizeof(Element) + kRepHeaderSize) : 0;
        }

        namespace internal
        {
            // Returns the new size for a reserved field based on its 'total_size' and the
            // requested 'new_size'. The result is clamped to the closed interval:
            //   [internal::kMinRepeatedFieldAllocationSize,
            //    std::numeric_limits<int>::max()]
            // Requires:
            //     new_size > total_size &&
            //     (total_size == 0 ||
            //      total_size >= kRepeatedFieldLowerClampLimit)
            template<typename T, int kRepHeaderSize>
            inline int CalculateReserveSize(int total_size, int new_size)
            {
                constexpr int lower_limit = RepeatedFieldLowerClampLimit<T, kRepHeaderSize>();
                if (new_size < lower_limit)
                {
                    // Clamp to smallest allowed size.
                    return lower_limit;
                }
                constexpr int kMaxSizeBeforeClamp =
                    (std::numeric_limits<int>::max() - kRepHeaderSize) / 2;
                if (PROTOBUF_PREDICT_FALSE(total_size > kMaxSizeBeforeClamp))
                {
                    return std::numeric_limits<int>::max();
                }
                // We want to double the number of bytes, not the number of elements, to try
                // to stay within power-of-two allocations.
                // The allocation has kRepHeaderSize + sizeof(T) * capacity.
                int doubled_size = 2 * total_size + kRepHeaderSize / sizeof(T);
                return std::max(doubled_size, new_size);
            }
        }  // namespace internal

        // Avoid inlining of Reserve(): new, copy, and delete[] lead to a significant
        // amount of code bloat.
        template<typename Element>
        void RepeatedField<Element>::Reserve(int new_size)
        {
            if (total_size_ >= new_size)
                return;
            Rep* old_rep = total_size_ > 0 ? rep() : nullptr;
            Rep* new_rep;
            Arena* arena = GetOwningArena();

            new_size = internal::CalculateReserveSize<Element, kRepHeaderSize>(
                total_size_, new_size
            );

            GOOGLE_DCHECK_LE(
                static_cast<size_t>(new_size),
                (std::numeric_limits<size_t>::max() - kRepHeaderSize) / sizeof(Element)
            )
                << "Requested size is too large to fit into size_t.";
            size_t bytes =
                kRepHeaderSize + sizeof(Element) * static_cast<size_t>(new_size);
            if (arena == nullptr)
            {
                new_rep = static_cast<Rep*>(::operator new(bytes));
            }
            else
            {
                new_rep = reinterpret_cast<Rep*>(Arena::CreateArray<char>(arena, bytes));
            }
            new_rep->arena = arena;
            int old_total_size = total_size_;
            // Already known: new_size >= internal::kMinRepeatedFieldAllocationSize
            // Maintain invariant:
            //     total_size_ == 0 ||
            //     total_size_ >= internal::kMinRepeatedFieldAllocationSize
            total_size_ = new_size;
            arena_or_elements_ = new_rep->elements();
            // Invoke placement-new on newly allocated elements. We shouldn't have to do
            // this, since Element is supposed to be POD, but a previous version of this
            // code allocated storage with "new Element[size]" and some code uses
            // RepeatedField with non-POD types, relying on constructor invocation. If
            // Element has a trivial constructor (e.g., int32_t), gcc (tested with -O2)
            // completely removes this loop because the loop body is empty, so this has no
            // effect unless its side-effects are required for correctness.
            // Note that we do this before MoveArray() below because Element's copy
            // assignment implementation will want an initialized instance first.
            Element* e = &elements()[0];
            Element* limit = e + total_size_;
            for (; e < limit; e++)
            {
                new (e) Element;
            }
            if (current_size_ > 0)
            {
                MoveArray(&elements()[0], old_rep->elements(), current_size_);
            }

            // Likewise, we need to invoke destructors on the old array.
            InternalDeallocate(old_rep, old_total_size, false);
        }

        template<typename Element>
        inline void RepeatedField<Element>::Truncate(int new_size)
        {
            GOOGLE_DCHECK_LE(new_size, current_size_);
            if (current_size_ > 0)
            {
                current_size_ = new_size;
            }
        }

        template<typename Element>
        inline void RepeatedField<Element>::MoveArray(Element* to, Element* from, int array_size)
        {
            CopyArray(to, from, array_size);
        }

        template<typename Element>
        inline void RepeatedField<Element>::CopyArray(Element* to, const Element* from, int array_size)
        {
            internal::ElementCopier<Element>()(to, from, array_size);
        }

        namespace internal
        {

            template<typename Element, bool HasTrivialCopy>
            void ElementCopier<Element, HasTrivialCopy>::operator()(Element* to, const Element* from, int array_size)
            {
                std::copy(from, from + array_size, to);
            }

            template<typename Element>
            struct ElementCopier<Element, true>
            {
                void operator()(Element* to, const Element* from, int array_size)
                {
                    memcpy(to, from, static_cast<size_t>(array_size) * sizeof(Element));
                }
            };

        }  // namespace internal

        // -------------------------------------------------------------------

        // Iterators and helper functions that follow the spirit of the STL
        // std::back_insert_iterator and std::back_inserter but are tailor-made
        // for RepeatedField and RepeatedPtrField. Typical usage would be:
        //
        //   std::copy(some_sequence.begin(), some_sequence.end(),
        //             RepeatedFieldBackInserter(proto.mutable_sequence()));
        //
        // Ported by johannes from util/gtl/proto-array-iterators.h

        namespace internal
        {

            // STL-like iterator implementation for RepeatedField.  You should not
            // refer to this class directly; use RepeatedField<T>::iterator instead.
            //
            // Note: All of the iterator operators *must* be inlined to avoid performance
            // regressions.  This is caused by the extern template declarations below (which
            // are required because of the RepeatedField extern template declarations).  If
            // any of these functions aren't explicitly inlined (e.g. defined in the class),
            // the compiler isn't allowed to inline them.
            template<typename Element>
            class RepeatedIterator
            {
            public:
                using iterator_category = std::random_access_iterator_tag;
                // Note: remove_const is necessary for std::partial_sum, which uses value_type
                // to determine the summation variable type.
                using value_type = typename std::remove_const<Element>::type;
                using difference_type = std::ptrdiff_t;
                using pointer = Element*;
                using reference = Element&;

                constexpr RepeatedIterator() noexcept :
                    it_(nullptr)
                {
                }

                // Allows "upcasting" from RepeatedIterator<T**> to
                // RepeatedIterator<const T*const*>.
                template<typename OtherElement, typename std::enable_if<std::is_convertible<OtherElement*, pointer>::value>::type* = nullptr>
                constexpr RepeatedIterator(
                    const RepeatedIterator<OtherElement>& other
                ) noexcept
                    :
                    it_(other.it_)
                {
                }

                // dereferenceable
                constexpr reference operator*() const noexcept
                {
                    return *it_;
                }
                constexpr pointer operator->() const noexcept
                {
                    return it_;
                }

            private:
                // Helper alias to hide the internal type.
                using iterator = RepeatedIterator<Element>;

            public:
                // {inc,dec}rementable
                iterator& operator++() noexcept
                {
                    ++it_;
                    return *this;
                }
                iterator operator++(int) noexcept
                {
                    return iterator(it_++);
                }
                iterator& operator--() noexcept
                {
                    --it_;
                    return *this;
                }
                iterator operator--(int) noexcept
                {
                    return iterator(it_--);
                }

                // equality_comparable
                friend constexpr bool operator==(const iterator& x, const iterator& y) noexcept
                {
                    return x.it_ == y.it_;
                }
                friend constexpr bool operator!=(const iterator& x, const iterator& y) noexcept
                {
                    return x.it_ != y.it_;
                }

                // less_than_comparable
                friend constexpr bool operator<(const iterator& x, const iterator& y) noexcept
                {
                    return x.it_ < y.it_;
                }
                friend constexpr bool operator<=(const iterator& x, const iterator& y) noexcept
                {
                    return x.it_ <= y.it_;
                }
                friend constexpr bool operator>(const iterator& x, const iterator& y) noexcept
                {
                    return x.it_ > y.it_;
                }
                friend constexpr bool operator>=(const iterator& x, const iterator& y) noexcept
                {
                    return x.it_ >= y.it_;
                }

                // addable, subtractable
                iterator& operator+=(difference_type d) noexcept
                {
                    it_ += d;
                    return *this;
                }
                constexpr iterator operator+(difference_type d) const noexcept
                {
                    return iterator(it_ + d);
                }
                friend constexpr iterator operator+(const difference_type d, iterator it) noexcept
                {
                    return it + d;
                }

                iterator& operator-=(difference_type d) noexcept
                {
                    it_ -= d;
                    return *this;
                }
                iterator constexpr operator-(difference_type d) const noexcept
                {
                    return iterator(it_ - d);
                }

                // indexable
                constexpr reference operator[](difference_type d) const noexcept
                {
                    return it_[d];
                }

                // random access iterator
                friend constexpr difference_type operator-(iterator it1, iterator it2) noexcept
                {
                    return it1.it_ - it2.it_;
                }

            private:
                template<typename OtherElement>
                friend class RepeatedIterator;

                // Allow construction from RepeatedField.
                friend class RepeatedField<value_type>;
                explicit RepeatedIterator(Element* it) noexcept :
                    it_(it)
                {
                }

                // The internal iterator.
                Element* it_;
            };

            // A back inserter for RepeatedField objects.
            template<typename T>
            class RepeatedFieldBackInsertIterator
            {
            public:
                using iterator_category = std::output_iterator_tag;
                using value_type = T;
                using pointer = void;
                using reference = void;
                using difference_type = std::ptrdiff_t;

                explicit RepeatedFieldBackInsertIterator(
                    RepeatedField<T>* const mutable_field
                ) :
                    field_(mutable_field)
                {
                }
                RepeatedFieldBackInsertIterator<T>& operator=(const T& value)
                {
                    field_->Add(value);
                    return *this;
                }
                RepeatedFieldBackInsertIterator<T>& operator*()
                {
                    return *this;
                }
                RepeatedFieldBackInsertIterator<T>& operator++()
                {
                    return *this;
                }
                RepeatedFieldBackInsertIterator<T>& operator++(int /* unused */)
                {
                    return *this;
                }

            private:
                RepeatedField<T>* field_;
            };

        }  // namespace internal

        // Provides a back insert iterator for RepeatedField instances,
        // similar to std::back_inserter().
        template<typename T>
        internal::RepeatedFieldBackInsertIterator<T> RepeatedFieldBackInserter(
            RepeatedField<T>* const mutable_field
        )
        {
            return internal::RepeatedFieldBackInsertIterator<T>(mutable_field);
        }

        // Extern declarations of common instantiations to reduce library bloat.
        extern template class PROTOBUF_EXPORT_TEMPLATE_DECLARE RepeatedField<bool>;
        extern template class PROTOBUF_EXPORT_TEMPLATE_DECLARE RepeatedField<int32_t>;
        extern template class PROTOBUF_EXPORT_TEMPLATE_DECLARE RepeatedField<uint32_t>;
        extern template class PROTOBUF_EXPORT_TEMPLATE_DECLARE RepeatedField<int64_t>;
        extern template class PROTOBUF_EXPORT_TEMPLATE_DECLARE RepeatedField<uint64_t>;
        extern template class PROTOBUF_EXPORT_TEMPLATE_DECLARE RepeatedField<float>;
        extern template class PROTOBUF_EXPORT_TEMPLATE_DECLARE RepeatedField<double>;

        namespace internal
        {
            extern template class PROTOBUF_EXPORT_TEMPLATE_DECLARE RepeatedIterator<bool>;
            extern template class PROTOBUF_EXPORT_TEMPLATE_DECLARE
                RepeatedIterator<int32_t>;
            extern template class PROTOBUF_EXPORT_TEMPLATE_DECLARE
                RepeatedIterator<uint32_t>;
            extern template class PROTOBUF_EXPORT_TEMPLATE_DECLARE
                RepeatedIterator<int64_t>;
            extern template class PROTOBUF_EXPORT_TEMPLATE_DECLARE
                RepeatedIterator<uint64_t>;
            extern template class PROTOBUF_EXPORT_TEMPLATE_DECLARE RepeatedIterator<float>;
            extern template class PROTOBUF_EXPORT_TEMPLATE_DECLARE RepeatedIterator<double>;
        }  // namespace internal

    }  // namespace protobuf
}  // namespace google

#include <google/protobuf/port_undef.inc>

#endif  // GOOGLE_PROTOBUF_REPEATED_FIELD_H__