absl/container/fixed_array.h - third_party/abseil-cpp - Git at Google

 // Copyright 2017 The Abseil Authors.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //      http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.
 //
 // -----------------------------------------------------------------------------
 // File: fixed_array.h
 // -----------------------------------------------------------------------------
 //
 // A `FixedArray<T>` represents a non-resizable array of `T` where the length of
 // the array can be determined at run-time. It is a good replacement for
 // non-standard and deprecated uses of `alloca()` and variable length arrays
 // within the GCC extension. (See
 // https://gcc.gnu.org/onlinedocs/gcc/Variable-Length.html).
 //
 // `FixedArray` allocates small arrays inline, keeping performance fast by
 // avoiding heap operations. It also helps reduce the chances of
 // accidentally overflowing your stack if large input is passed to
 // your function.

 #ifndef ABSL_CONTAINER_FIXED_ARRAY_H_
 #define ABSL_CONTAINER_FIXED_ARRAY_H_

 #include <algorithm>
 #include <array>
 #include <cassert>
 #include <cstddef>
 #include <initializer_list>
 #include <iterator>
 #include <limits>
 #include <memory>
 #include <new>
 #include <type_traits>

 #include "absl/algorithm/algorithm.h"
 #include "absl/base/dynamic_annotations.h"
 #include "absl/base/internal/throw_delegate.h"
 #include "absl/base/macros.h"
 #include "absl/base/optimization.h"
 #include "absl/base/port.h"
 #include "absl/memory/memory.h"

 namespace absl {
 inline namespace lts_2018_06_20 {

 constexpr static auto kFixedArrayUseDefault = static_cast<size_t>(-1);

 // -----------------------------------------------------------------------------
 // FixedArray
 // -----------------------------------------------------------------------------
 //
 // A `FixedArray` provides a run-time fixed-size array, allocating small arrays
 // inline for efficiency and correctness.
 //
 // Most users should not specify an `inline_elements` argument and let
 // `FixedArray<>` automatically determine the number of elements
 // to store inline based on `sizeof(T)`. If `inline_elements` is specified, the
 // `FixedArray<>` implementation will inline arrays of
 // length <= `inline_elements`.
 //
 // Note that a `FixedArray` constructed with a `size_type` argument will
 // default-initialize its values by leaving trivially constructible types
 // uninitialized (e.g. int, int[4], double), and others default-constructed.
 // This matches the behavior of c-style arrays and `std::array`, but not
 // `std::vector`.
 //
 // Note that `FixedArray` does not provide a public allocator; if it requires a
 // heap allocation, it will do so with global `::operator new[]()` and
 // `::operator delete[]()`, even if T provides class-scope overrides for these
 // operators.
 template <typename T, size_t inlined = kFixedArrayUseDefault>
 class FixedArray {
   static constexpr size_t kInlineBytesDefault = 256;

   // std::iterator_traits isn't guaranteed to be SFINAE-friendly until C++17,
   // but this seems to be mostly pedantic.
   template <typename Iter>
   using EnableIfForwardIterator = typename std::enable_if<
       std::is_convertible<
           typename std::iterator_traits<Iter>::iterator_category,
           std::forward_iterator_tag>::value,
       int>::type;

  public:
   // For playing nicely with stl:
   using value_type = T;
   using iterator = T*;
   using const_iterator = const T*;
   using reverse_iterator = std::reverse_iterator<iterator>;
   using const_reverse_iterator = std::reverse_iterator<const_iterator>;
   using reference = T&;
   using const_reference = const T&;
   using pointer = T*;
   using const_pointer = const T*;
   using difference_type = ptrdiff_t;
   using size_type = size_t;

   static constexpr size_type inline_elements =
       inlined == kFixedArrayUseDefault
           ? kInlineBytesDefault / sizeof(value_type)
           : inlined;

   FixedArray(const FixedArray& other) : rep_(other.begin(), other.end()) {}
   FixedArray(FixedArray&& other) noexcept(
   // clang-format off
       absl::allocator_is_nothrow<std::allocator<value_type>>::value &&
   // clang-format on
           std::is_nothrow_move_constructible<value_type>::value)
       : rep_(std::make_move_iterator(other.begin()),
              std::make_move_iterator(other.end())) {}

   // Creates an array object that can store `n` elements.
   // Note that trivially constructible elements will be uninitialized.
   explicit FixedArray(size_type n) : rep_(n) {}

   // Creates an array initialized with `n` copies of `val`.
   FixedArray(size_type n, const value_type& val) : rep_(n, val) {}

   // Creates an array initialized with the elements from the input
   // range. The array's size will always be `std::distance(first, last)`.
   // REQUIRES: Iter must be a forward_iterator or better.
   template <typename Iter, EnableIfForwardIterator<Iter> = 0>
   FixedArray(Iter first, Iter last) : rep_(first, last) {}

   // Creates the array from an initializer_list.
   FixedArray(std::initializer_list<T> init_list)
       : FixedArray(init_list.begin(), init_list.end()) {}

   ~FixedArray() {}

   // Assignments are deleted because they break the invariant that the size of a
   // `FixedArray` never changes.
   void operator=(FixedArray&&) = delete;
   void operator=(const FixedArray&) = delete;

   // FixedArray::size()
   //
   // Returns the length of the fixed array.
   size_type size() const { return rep_.size(); }

   // FixedArray::max_size()
   //
   // Returns the largest possible value of `std::distance(begin(), end())` for a
   // `FixedArray<T>`. This is equivalent to the most possible addressable bytes
   // over the number of bytes taken by T.
   constexpr size_type max_size() const {
     return std::numeric_limits<difference_type>::max() / sizeof(value_type);
   }

   // FixedArray::empty()
   //
   // Returns whether or not the fixed array is empty.
   bool empty() const { return size() == 0; }

   // FixedArray::memsize()
   //
   // Returns the memory size of the fixed array in bytes.
   size_t memsize() const { return size() * sizeof(value_type); }

   // FixedArray::data()
   //
   // Returns a const T* pointer to elements of the `FixedArray`. This pointer
   // can be used to access (but not modify) the contained elements.
   const_pointer data() const { return AsValue(rep_.begin()); }

   // Overload of FixedArray::data() to return a T* pointer to elements of the
   // fixed array. This pointer can be used to access and modify the contained
   // elements.
   pointer data() { return AsValue(rep_.begin()); }

   // FixedArray::operator[]
   //
   // Returns a reference the ith element of the fixed array.
   // REQUIRES: 0 <= i < size()
   reference operator[](size_type i) {
     assert(i < size());
     return data()[i];
   }

   // Overload of FixedArray::operator()[] to return a const reference to the
   // ith element of the fixed array.
   // REQUIRES: 0 <= i < size()
   const_reference operator[](size_type i) const {
     assert(i < size());
     return data()[i];
   }

   // FixedArray::at
   //
   // Bounds-checked access.  Returns a reference to the ith element of the
   // fiexed array, or throws std::out_of_range
   reference at(size_type i) {
     if (ABSL_PREDICT_FALSE(i >= size())) {
       base_internal::ThrowStdOutOfRange("FixedArray::at failed bounds check");
     }
     return data()[i];
   }

   // Overload of FixedArray::at() to return a const reference to the ith element
   // of the fixed array.
   const_reference at(size_type i) const {
     if (ABSL_PREDICT_FALSE(i >= size())) {
       base_internal::ThrowStdOutOfRange("FixedArray::at failed bounds check");
     }
     return data()[i];
   }

   // FixedArray::front()
   //
   // Returns a reference to the first element of the fixed array.
   reference front() { return *begin(); }

   // Overload of FixedArray::front() to return a reference to the first element
   // of a fixed array of const values.
   const_reference front() const { return *begin(); }

   // FixedArray::back()
   //
   // Returns a reference to the last element of the fixed array.
   reference back() { return *(end() - 1); }

   // Overload of FixedArray::back() to return a reference to the last element
   // of a fixed array of const values.
   const_reference back() const { return *(end() - 1); }

   // FixedArray::begin()
   //
   // Returns an iterator to the beginning of the fixed array.
   iterator begin() { return data(); }

   // Overload of FixedArray::begin() to return a const iterator to the
   // beginning of the fixed array.
   const_iterator begin() const { return data(); }

   // FixedArray::cbegin()
   //
   // Returns a const iterator to the beginning of the fixed array.
   const_iterator cbegin() const { return begin(); }

   // FixedArray::end()
   //
   // Returns an iterator to the end of the fixed array.
   iterator end() { return data() + size(); }

   // Overload of FixedArray::end() to return a const iterator to the end of the
   // fixed array.
   const_iterator end() const { return data() + size(); }

   // FixedArray::cend()
   //
   // Returns a const iterator to the end of the fixed array.
   const_iterator cend() const { return end(); }

   // FixedArray::rbegin()
   //
   // Returns a reverse iterator from the end of the fixed array.
   reverse_iterator rbegin() { return reverse_iterator(end()); }

   // Overload of FixedArray::rbegin() to return a const reverse iterator from
   // the end of the fixed array.
   const_reverse_iterator rbegin() const {
     return const_reverse_iterator(end());
   }

   // FixedArray::crbegin()
   //
   // Returns a const reverse iterator from the end of the fixed array.
   const_reverse_iterator crbegin() const { return rbegin(); }

   // FixedArray::rend()
   //
   // Returns a reverse iterator from the beginning of the fixed array.
   reverse_iterator rend() { return reverse_iterator(begin()); }

   // Overload of FixedArray::rend() for returning a const reverse iterator
   // from the beginning of the fixed array.
   const_reverse_iterator rend() const {
     return const_reverse_iterator(begin());
   }

   // FixedArray::crend()
   //
   // Returns a reverse iterator from the beginning of the fixed array.
   const_reverse_iterator crend() const { return rend(); }

   // FixedArray::fill()
   //
   // Assigns the given `value` to all elements in the fixed array.
   void fill(const T& value) { std::fill(begin(), end(), value); }

   // Relational operators. Equality operators are elementwise using
   // `operator==`, while order operators order FixedArrays lexicographically.
   friend bool operator==(const FixedArray& lhs, const FixedArray& rhs) {
     return absl::equal(lhs.begin(), lhs.end(), rhs.begin(), rhs.end());
   }

   friend bool operator!=(const FixedArray& lhs, const FixedArray& rhs) {
     return !(lhs == rhs);
   }

   friend bool operator<(const FixedArray& lhs, const FixedArray& rhs) {
     return std::lexicographical_compare(lhs.begin(), lhs.end(), rhs.begin(),
                                         rhs.end());
   }

   friend bool operator>(const FixedArray& lhs, const FixedArray& rhs) {
     return rhs < lhs;
   }

   friend bool operator<=(const FixedArray& lhs, const FixedArray& rhs) {
     return !(rhs < lhs);
   }

   friend bool operator>=(const FixedArray& lhs, const FixedArray& rhs) {
     return !(lhs < rhs);
   }

  private:
   // HolderTraits
   //
   // Wrapper to hold elements of type T for the case where T is an array type.
   // If 'T' is an array type, HolderTraits::type is a struct with a 'T v;'.
   // Otherwise, HolderTraits::type is simply 'T'.
   //
   // Maintainer's Note: The simpler solution would be to simply wrap T in a
   // struct whether it's an array or not: 'struct Holder { T v; };', but
   // that causes some paranoid diagnostics to misfire about uses of data(),
   // believing that 'data()' (aka '&rep_.begin().v') is a pointer to a single
   // element, rather than the packed array that it really is.
   // e.g.:
   //
   //     FixedArray<char> buf(1);
   //     sprintf(buf.data(), "foo");
   //
   //     error: call to int __builtin___sprintf_chk(etc...)
   //     will always overflow destination buffer [-Werror]
   //
   class HolderTraits {
     template <typename U>
     struct SelectImpl {
       using type = U;
       static pointer AsValue(type* p) { return p; }
     };

     // Partial specialization for elements of array type.
     template <typename U, size_t N>
     struct SelectImpl<U[N]> {
       struct Holder { U v[N]; };
       using type = Holder;
       static pointer AsValue(type* p) { return &p->v; }
     };
     using Impl = SelectImpl<value_type>;

    public:
     using type = typename Impl::type;

     static pointer AsValue(type *p) { return Impl::AsValue(p); }

     // TODO(billydonahue): fix the type aliasing violation
     // this assertion hints at.
     static_assert(sizeof(type) == sizeof(value_type),
                   "Holder must be same size as value_type");
   };

   using Holder = typename HolderTraits::type;
   static pointer AsValue(Holder *p) { return HolderTraits::AsValue(p); }

   // InlineSpace
   //
   // Allocate some space, not an array of elements of type T, so that we can
   // skip calling the T constructors and destructors for space we never use.
   // How many elements should we store inline?
   //   a. If not specified, use a default of kInlineBytesDefault bytes (This is
   //   currently 256 bytes, which seems small enough to not cause stack overflow
   //   or unnecessary stack pollution, while still allowing stack allocation for
   //   reasonably long character arrays).
   //   b. Never use 0 length arrays (not ISO C++)
   //
   template <size_type N, typename = void>
   class InlineSpace {
    public:
     Holder* data() { return reinterpret_cast<Holder*>(space_.data()); }
     void AnnotateConstruct(size_t n) const { Annotate(n, true); }
     void AnnotateDestruct(size_t n) const { Annotate(n, false); }

    private:
 #ifndef ADDRESS_SANITIZER
     void Annotate(size_t, bool) const { }
 #else
     void Annotate(size_t n, bool creating) const {
       if (!n) return;
       const void* bot = &left_redzone_;
       const void* beg = space_.data();
       const void* end = space_.data() + n;
       const void* top = &right_redzone_ + 1;
       // args: (beg, end, old_mid, new_mid)
       if (creating) {
         ANNOTATE_CONTIGUOUS_CONTAINER(beg, top, top, end);
         ANNOTATE_CONTIGUOUS_CONTAINER(bot, beg, beg, bot);
       } else {
         ANNOTATE_CONTIGUOUS_CONTAINER(beg, top, end, top);
         ANNOTATE_CONTIGUOUS_CONTAINER(bot, beg, bot, beg);
       }
     }
 #endif  // ADDRESS_SANITIZER

     using Buffer =
         typename std::aligned_storage<sizeof(Holder), alignof(Holder)>::type;

     ADDRESS_SANITIZER_REDZONE(left_redzone_);
     std::array<Buffer, N> space_;
     ADDRESS_SANITIZER_REDZONE(right_redzone_);
   };

   // specialization when N = 0.
   template <typename U>
   class InlineSpace<0, U> {
    public:
     Holder* data() { return nullptr; }
     void AnnotateConstruct(size_t) const {}
     void AnnotateDestruct(size_t) const {}
   };

   // Rep
   //
   // A const Rep object holds FixedArray's size and data pointer.
   //
   class Rep : public InlineSpace<inline_elements> {
    public:
     Rep(size_type n, const value_type& val) : n_(n), p_(MakeHolder(n)) {
       std::uninitialized_fill_n(p_, n, val);
     }

     explicit Rep(size_type n) : n_(n), p_(MakeHolder(n)) {
       // Loop optimizes to nothing for trivially constructible T.
       for (Holder* p = p_; p != p_ + n; ++p)
         // Note: no parens: default init only.
         // Also note '::' to avoid Holder class placement new operator.
         ::new (static_cast<void*>(p)) Holder;
     }

     template <typename Iter>
     Rep(Iter first, Iter last)
         : n_(std::distance(first, last)), p_(MakeHolder(n_)) {
       std::uninitialized_copy(first, last, AsValue(p_));
     }

     ~Rep() {
       // Destruction must be in reverse order.
       // Loop optimizes to nothing for trivially destructible T.
       for (Holder* p = end(); p != begin();) (--p)->~Holder();
       if (IsAllocated(size())) {
         std::allocator<Holder>().deallocate(p_, n_);
       } else {
         this->AnnotateDestruct(size());
       }
     }
     Holder* begin() const { return p_; }
     Holder* end() const { return p_ + n_; }
     size_type size() const { return n_; }

    private:
     Holder* MakeHolder(size_type n) {
       if (IsAllocated(n)) {
         return std::allocator<Holder>().allocate(n);
       } else {
         this->AnnotateConstruct(n);
         return this->data();
       }
     }

     bool IsAllocated(size_type n) const { return n > inline_elements; }

     const size_type n_;
     Holder* const p_;
   };


   // Data members
   Rep rep_;
 };

 template <typename T, size_t N>
 constexpr size_t FixedArray<T, N>::inline_elements;

 template <typename T, size_t N>
 constexpr size_t FixedArray<T, N>::kInlineBytesDefault;

 }  // inline namespace lts_2018_06_20
 }  // namespace absl
 #endif  // ABSL_CONTAINER_FIXED_ARRAY_H_
	// Copyright 2017 The Abseil Authors.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.
	//
	// -----------------------------------------------------------------------------
	// File: fixed_array.h
	// -----------------------------------------------------------------------------
	//
	// A `FixedArray<T>` represents a non-resizable array of `T` where the length of
	// the array can be determined at run-time. It is a good replacement for
	// non-standard and deprecated uses of `alloca()` and variable length arrays
	// within the GCC extension. (See
	// https://gcc.gnu.org/onlinedocs/gcc/Variable-Length.html).
	//
	// `FixedArray` allocates small arrays inline, keeping performance fast by
	// avoiding heap operations. It also helps reduce the chances of
	// accidentally overflowing your stack if large input is passed to
	// your function.

	#ifndef ABSL_CONTAINER_FIXED_ARRAY_H_
	#define ABSL_CONTAINER_FIXED_ARRAY_H_

	#include <algorithm>
	#include <array>
	#include <cassert>
	#include <cstddef>
	#include <initializer_list>
	#include <iterator>
	#include <limits>
	#include <memory>
	#include <new>
	#include <type_traits>

	#include "absl/algorithm/algorithm.h"
	#include "absl/base/dynamic_annotations.h"
	#include "absl/base/internal/throw_delegate.h"
	#include "absl/base/macros.h"
	#include "absl/base/optimization.h"
	#include "absl/base/port.h"
	#include "absl/memory/memory.h"

	namespace absl {
	inline namespace lts_2018_06_20 {

	constexpr static auto kFixedArrayUseDefault = static_cast<size_t>(-1);

	// -----------------------------------------------------------------------------
	// FixedArray
	// -----------------------------------------------------------------------------
	//
	// A `FixedArray` provides a run-time fixed-size array, allocating small arrays
	// inline for efficiency and correctness.
	//
	// Most users should not specify an `inline_elements` argument and let
	// `FixedArray<>` automatically determine the number of elements
	// to store inline based on `sizeof(T)`. If `inline_elements` is specified, the
	// `FixedArray<>` implementation will inline arrays of
	// length <= `inline_elements`.
	//
	// Note that a `FixedArray` constructed with a `size_type` argument will
	// default-initialize its values by leaving trivially constructible types
	// uninitialized (e.g. int, int[4], double), and others default-constructed.
	// This matches the behavior of c-style arrays and `std::array`, but not
	// `std::vector`.
	//
	// Note that `FixedArray` does not provide a public allocator; if it requires a
	// heap allocation, it will do so with global `::operator new[]()` and
	// `::operator delete[]()`, even if T provides class-scope overrides for these
	// operators.
	template <typename T, size_t inlined = kFixedArrayUseDefault>
	class FixedArray {
	static constexpr size_t kInlineBytesDefault = 256;

	// std::iterator_traits isn't guaranteed to be SFINAE-friendly until C++17,
	// but this seems to be mostly pedantic.
	template <typename Iter>
	using EnableIfForwardIterator = typename std::enable_if<
	std::is_convertible<
	typename std::iterator_traits<Iter>::iterator_category,
	std::forward_iterator_tag>::value,
	int>::type;

	public:
	// For playing nicely with stl:
	using value_type = T;
	using iterator = T*;
	using const_iterator = const T*;
	using reverse_iterator = std::reverse_iterator<iterator>;
	using const_reverse_iterator = std::reverse_iterator<const_iterator>;
	using reference = T&;
	using const_reference = const T&;
	using pointer = T*;
	using const_pointer = const T*;
	using difference_type = ptrdiff_t;
	using size_type = size_t;

	static constexpr size_type inline_elements =
	inlined == kFixedArrayUseDefault
	? kInlineBytesDefault / sizeof(value_type)
	: inlined;

	FixedArray(const FixedArray& other) : rep_(other.begin(), other.end()) {}
	FixedArray(FixedArray&& other) noexcept(
	// clang-format off
	absl::allocator_is_nothrow<std::allocator<value_type>>::value &&
	// clang-format on
	std::is_nothrow_move_constructible<value_type>::value)
	: rep_(std::make_move_iterator(other.begin()),
	std::make_move_iterator(other.end())) {}

	// Creates an array object that can store `n` elements.
	// Note that trivially constructible elements will be uninitialized.
	explicit FixedArray(size_type n) : rep_(n) {}

	// Creates an array initialized with `n` copies of `val`.
	FixedArray(size_type n, const value_type& val) : rep_(n, val) {}

	// Creates an array initialized with the elements from the input
	// range. The array's size will always be `std::distance(first, last)`.
	// REQUIRES: Iter must be a forward_iterator or better.
	template <typename Iter, EnableIfForwardIterator<Iter> = 0>
	FixedArray(Iter first, Iter last) : rep_(first, last) {}

	// Creates the array from an initializer_list.
	FixedArray(std::initializer_list<T> init_list)
	: FixedArray(init_list.begin(), init_list.end()) {}

	~FixedArray() {}

	// Assignments are deleted because they break the invariant that the size of a
	// `FixedArray` never changes.
	void operator=(FixedArray&&) = delete;
	void operator=(const FixedArray&) = delete;

	// FixedArray::size()
	//
	// Returns the length of the fixed array.
	size_type size() const { return rep_.size(); }

	// FixedArray::max_size()
	//
	// Returns the largest possible value of `std::distance(begin(), end())` for a
	// `FixedArray<T>`. This is equivalent to the most possible addressable bytes
	// over the number of bytes taken by T.
	constexpr size_type max_size() const {
	return std::numeric_limits<difference_type>::max() / sizeof(value_type);
	}

	// FixedArray::empty()
	//
	// Returns whether or not the fixed array is empty.
	bool empty() const { return size() == 0; }

	// FixedArray::memsize()
	//
	// Returns the memory size of the fixed array in bytes.
	size_t memsize() const { return size() * sizeof(value_type); }

	// FixedArray::data()
	//
	// Returns a const T* pointer to elements of the `FixedArray`. This pointer
	// can be used to access (but not modify) the contained elements.
	const_pointer data() const { return AsValue(rep_.begin()); }

	// Overload of FixedArray::data() to return a T* pointer to elements of the
	// fixed array. This pointer can be used to access and modify the contained
	// elements.
	pointer data() { return AsValue(rep_.begin()); }

	// FixedArray::operator[]
	//
	// Returns a reference the ith element of the fixed array.
	// REQUIRES: 0 <= i < size()
	reference operator[](size_type i) {
	assert(i < size());
	return data()[i];
	}

	// Overload of FixedArray::operator()[] to return a const reference to the
	// ith element of the fixed array.
	// REQUIRES: 0 <= i < size()
	const_reference operator[](size_type i) const {
	assert(i < size());
	return data()[i];
	}

	// FixedArray::at
	//
	// Bounds-checked access. Returns a reference to the ith element of the
	// fiexed array, or throws std::out_of_range
	reference at(size_type i) {
	if (ABSL_PREDICT_FALSE(i >= size())) {
	base_internal::ThrowStdOutOfRange("FixedArray::at failed bounds check");
	}
	return data()[i];
	}

	// Overload of FixedArray::at() to return a const reference to the ith element
	// of the fixed array.
	const_reference at(size_type i) const {
	if (ABSL_PREDICT_FALSE(i >= size())) {
	base_internal::ThrowStdOutOfRange("FixedArray::at failed bounds check");
	}
	return data()[i];
	}

	// FixedArray::front()
	//
	// Returns a reference to the first element of the fixed array.
	reference front() { return *begin(); }

	// Overload of FixedArray::front() to return a reference to the first element
	// of a fixed array of const values.
	const_reference front() const { return *begin(); }

	// FixedArray::back()
	//
	// Returns a reference to the last element of the fixed array.
	reference back() { return *(end() - 1); }

	// Overload of FixedArray::back() to return a reference to the last element
	// of a fixed array of const values.
	const_reference back() const { return *(end() - 1); }

	// FixedArray::begin()
	//
	// Returns an iterator to the beginning of the fixed array.
	iterator begin() { return data(); }

	// Overload of FixedArray::begin() to return a const iterator to the
	// beginning of the fixed array.
	const_iterator begin() const { return data(); }

	// FixedArray::cbegin()
	//
	// Returns a const iterator to the beginning of the fixed array.
	const_iterator cbegin() const { return begin(); }

	// FixedArray::end()
	//
	// Returns an iterator to the end of the fixed array.
	iterator end() { return data() + size(); }

	// Overload of FixedArray::end() to return a const iterator to the end of the
	// fixed array.
	const_iterator end() const { return data() + size(); }

	// FixedArray::cend()
	//
	// Returns a const iterator to the end of the fixed array.
	const_iterator cend() const { return end(); }

	// FixedArray::rbegin()
	//
	// Returns a reverse iterator from the end of the fixed array.
	reverse_iterator rbegin() { return reverse_iterator(end()); }

	// Overload of FixedArray::rbegin() to return a const reverse iterator from
	// the end of the fixed array.
	const_reverse_iterator rbegin() const {
	return const_reverse_iterator(end());
	}

	// FixedArray::crbegin()
	//
	// Returns a const reverse iterator from the end of the fixed array.
	const_reverse_iterator crbegin() const { return rbegin(); }

	// FixedArray::rend()
	//
	// Returns a reverse iterator from the beginning of the fixed array.
	reverse_iterator rend() { return reverse_iterator(begin()); }

	// Overload of FixedArray::rend() for returning a const reverse iterator
	// from the beginning of the fixed array.
	const_reverse_iterator rend() const {
	return const_reverse_iterator(begin());
	}

	// FixedArray::crend()
	//
	// Returns a reverse iterator from the beginning of the fixed array.
	const_reverse_iterator crend() const { return rend(); }

	// FixedArray::fill()
	//
	// Assigns the given `value` to all elements in the fixed array.
	void fill(const T& value) { std::fill(begin(), end(), value); }

	// Relational operators. Equality operators are elementwise using
	// `operator==`, while order operators order FixedArrays lexicographically.
	friend bool operator==(const FixedArray& lhs, const FixedArray& rhs) {
	return absl::equal(lhs.begin(), lhs.end(), rhs.begin(), rhs.end());
	}

	friend bool operator!=(const FixedArray& lhs, const FixedArray& rhs) {
	return !(lhs == rhs);
	}

	friend bool operator<(const FixedArray& lhs, const FixedArray& rhs) {
	return std::lexicographical_compare(lhs.begin(), lhs.end(), rhs.begin(),
	rhs.end());
	}

	friend bool operator>(const FixedArray& lhs, const FixedArray& rhs) {
	return rhs < lhs;
	}

	friend bool operator<=(const FixedArray& lhs, const FixedArray& rhs) {
	return !(rhs < lhs);
	}

	friend bool operator>=(const FixedArray& lhs, const FixedArray& rhs) {
	return !(lhs < rhs);
	}

	private:
	// HolderTraits
	//
	// Wrapper to hold elements of type T for the case where T is an array type.
	// If 'T' is an array type, HolderTraits::type is a struct with a 'T v;'.
	// Otherwise, HolderTraits::type is simply 'T'.
	//
	// Maintainer's Note: The simpler solution would be to simply wrap T in a
	// struct whether it's an array or not: 'struct Holder { T v; };', but
	// that causes some paranoid diagnostics to misfire about uses of data(),
	// believing that 'data()' (aka '&rep_.begin().v') is a pointer to a single
	// element, rather than the packed array that it really is.
	// e.g.:
	//
	// FixedArray<char> buf(1);
	// sprintf(buf.data(), "foo");
	//
	// error: call to int __builtin___sprintf_chk(etc...)
	// will always overflow destination buffer [-Werror]
	//
	class HolderTraits {
	template <typename U>
	struct SelectImpl {
	using type = U;
	static pointer AsValue(type* p) { return p; }
	};

	// Partial specialization for elements of array type.
	template <typename U, size_t N>
	struct SelectImpl<U[N]> {
	struct Holder { U v[N]; };
	using type = Holder;
	static pointer AsValue(type* p) { return &p->v; }
	};
	using Impl = SelectImpl<value_type>;

	public:
	using type = typename Impl::type;

	static pointer AsValue(type *p) { return Impl::AsValue(p); }

	// TODO(billydonahue): fix the type aliasing violation
	// this assertion hints at.
	static_assert(sizeof(type) == sizeof(value_type),
	"Holder must be same size as value_type");
	};

	using Holder = typename HolderTraits::type;
	static pointer AsValue(Holder *p) { return HolderTraits::AsValue(p); }

	// InlineSpace
	//
	// Allocate some space, not an array of elements of type T, so that we can
	// skip calling the T constructors and destructors for space we never use.
	// How many elements should we store inline?
	// a. If not specified, use a default of kInlineBytesDefault bytes (This is
	// currently 256 bytes, which seems small enough to not cause stack overflow
	// or unnecessary stack pollution, while still allowing stack allocation for
	// reasonably long character arrays).
	// b. Never use 0 length arrays (not ISO C++)
	//
	template <size_type N, typename = void>
	class InlineSpace {
	public:
	Holder* data() { return reinterpret_cast<Holder*>(space_.data()); }
	void AnnotateConstruct(size_t n) const { Annotate(n, true); }
	void AnnotateDestruct(size_t n) const { Annotate(n, false); }

	private:
	#ifndef ADDRESS_SANITIZER
	void Annotate(size_t, bool) const { }
	#else
	void Annotate(size_t n, bool creating) const {
	if (!n) return;
	const void* bot = &left_redzone_;
	const void* beg = space_.data();
	const void* end = space_.data() + n;
	const void* top = &right_redzone_ + 1;
	// args: (beg, end, old_mid, new_mid)
	if (creating) {
	ANNOTATE_CONTIGUOUS_CONTAINER(beg, top, top, end);
	ANNOTATE_CONTIGUOUS_CONTAINER(bot, beg, beg, bot);
	} else {
	ANNOTATE_CONTIGUOUS_CONTAINER(beg, top, end, top);
	ANNOTATE_CONTIGUOUS_CONTAINER(bot, beg, bot, beg);
	}
	}
	#endif // ADDRESS_SANITIZER

	using Buffer =
	typename std::aligned_storage<sizeof(Holder), alignof(Holder)>::type;

	ADDRESS_SANITIZER_REDZONE(left_redzone_);
	std::array<Buffer, N> space_;
	ADDRESS_SANITIZER_REDZONE(right_redzone_);
	};

	// specialization when N = 0.
	template <typename U>
	class InlineSpace<0, U> {
	public:
	Holder* data() { return nullptr; }
	void AnnotateConstruct(size_t) const {}
	void AnnotateDestruct(size_t) const {}
	};

	// Rep
	//
	// A const Rep object holds FixedArray's size and data pointer.
	//
	class Rep : public InlineSpace<inline_elements> {
	public:
	Rep(size_type n, const value_type& val) : n_(n), p_(MakeHolder(n)) {
	std::uninitialized_fill_n(p_, n, val);
	}

	explicit Rep(size_type n) : n_(n), p_(MakeHolder(n)) {
	// Loop optimizes to nothing for trivially constructible T.
	for (Holder* p = p_; p != p_ + n; ++p)
	// Note: no parens: default init only.
	// Also note '::' to avoid Holder class placement new operator.
	::new (static_cast<void*>(p)) Holder;
	}

	template <typename Iter>
	Rep(Iter first, Iter last)
	: n_(std::distance(first, last)), p_(MakeHolder(n_)) {
	std::uninitialized_copy(first, last, AsValue(p_));
	}

	~Rep() {
	// Destruction must be in reverse order.
	// Loop optimizes to nothing for trivially destructible T.
	for (Holder* p = end(); p != begin();) (--p)->~Holder();
	if (IsAllocated(size())) {
	std::allocator<Holder>().deallocate(p_, n_);
	} else {
	this->AnnotateDestruct(size());
	}
	}
	Holder* begin() const { return p_; }
	Holder* end() const { return p_ + n_; }
	size_type size() const { return n_; }

	private:
	Holder* MakeHolder(size_type n) {
	if (IsAllocated(n)) {
	return std::allocator<Holder>().allocate(n);
	} else {
	this->AnnotateConstruct(n);
	return this->data();
	}
	}

	bool IsAllocated(size_type n) const { return n > inline_elements; }

	const size_type n_;
	Holder* const p_;
	};


	// Data members
	Rep rep_;
	};

	template <typename T, size_t N>
	constexpr size_t FixedArray<T, N>::inline_elements;

	template <typename T, size_t N>
	constexpr size_t FixedArray<T, N>::kInlineBytesDefault;

	} // inline namespace lts_2018_06_20
	} // namespace absl
	#endif // ABSL_CONTAINER_FIXED_ARRAY_H_