src/base/containers/span.h - gn.git - Git at Google

 // Copyright 2017 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef BASE_CONTAINERS_SPAN_H_
 #define BASE_CONTAINERS_SPAN_H_

 #include <stddef.h>

 #include <algorithm>
 #include <array>
 #include <iterator>
 #include <type_traits>
 #include <utility>

 #include "base/logging.h"
 #include "base/stl_util.h"

 namespace base {

 // [views.constants]
 constexpr size_t dynamic_extent = static_cast<size_t>(-1);

 template <typename T, size_t Extent = dynamic_extent>
 class span;

 namespace internal {

 template <typename T>
 struct IsSpanImpl : std::false_type {};

 template <typename T, size_t Extent>
 struct IsSpanImpl<span<T, Extent>> : std::true_type {};

 template <typename T>
 using IsSpan = IsSpanImpl<std::decay_t<T>>;

 template <typename T>
 struct IsStdArrayImpl : std::false_type {};

 template <typename T, size_t N>
 struct IsStdArrayImpl<std::array<T, N>> : std::true_type {};

 template <typename T>
 using IsStdArray = IsStdArrayImpl<std::decay_t<T>>;

 template <typename T>
 using IsCArray = std::is_array<std::remove_reference_t<T>>;

 template <typename From, typename To>
 using IsLegalDataConversion = std::is_convertible<From (*)[], To (*)[]>;

 template <typename Container, typename T>
 using ContainerHasConvertibleData = IsLegalDataConversion<
     std::remove_pointer_t<decltype(std::data(std::declval<Container>()))>,
     T>;

 template <typename Container>
 using ContainerHasIntegralSize =
     std::is_integral<decltype(std::size(std::declval<Container>()))>;

 template <typename From, size_t FromExtent, typename To, size_t ToExtent>
 using EnableIfLegalSpanConversion =
     std::enable_if_t<(ToExtent == dynamic_extent || ToExtent == FromExtent) &&
                      IsLegalDataConversion<From, To>::value>;

 // SFINAE check if Array can be converted to a span<T>.
 template <typename Array, size_t N, typename T, size_t Extent>
 using EnableIfSpanCompatibleArray =
     std::enable_if_t<(Extent == dynamic_extent || Extent == N) &&
                      ContainerHasConvertibleData<Array, T>::value>;

 // SFINAE check if Container can be converted to a span<T>.
 template <typename Container, typename T>
 using EnableIfSpanCompatibleContainer =
     std::enable_if_t<!internal::IsSpan<Container>::value &&
                      !internal::IsStdArray<Container>::value &&
                      !internal::IsCArray<Container>::value &&
                      ContainerHasConvertibleData<Container, T>::value &&
                      ContainerHasIntegralSize<Container>::value>;

 }  // namespace internal

 // A span is a value type that represents an array of elements of type T. Since
 // it only consists of a pointer to memory with an associated size, it is very
 // light-weight. It is cheap to construct, copy, move and use spans, so that
 // users are encouraged to use it as a pass-by-value parameter. A span does not
 // own the underlying memory, so care must be taken to ensure that a span does
 // not outlive the backing store.
 //
 // span is somewhat analogous to std::string_view, but with arbitrary element
 // types, allowing mutation if T is non-const.
 //
 // span is implicitly convertible from C++ arrays, as well as most [1]
 // container-like types that provide a data() and size() method (such as
 // std::vector<T>). A mutable span<T> can also be implicitly converted to an
 // immutable span<const T>.
 //
 // Consider using a span for functions that take a data pointer and size
 // parameter: it allows the function to still act on an array-like type, while
 // allowing the caller code to be a bit more concise.
 //
 // For read-only data access pass a span<const T>: the caller can supply either
 // a span<const T> or a span<T>, while the callee will have a read-only view.
 // For read-write access a mutable span<T> is required.
 //
 // Without span:
 //   Read-Only:
 //     // std::string HexEncode(const uint8_t* data, size_t size);
 //     std::vector<uint8_t> data_buffer = GenerateData();
 //     std::string r = HexEncode(data_buffer.data(), data_buffer.size());
 //
 //  Mutable:
 //     // ssize_t SafeSNPrintf(char* buf, size_t N, const char* fmt, Args...);
 //     char str_buffer[100];
 //     SafeSNPrintf(str_buffer, sizeof(str_buffer), "Pi ~= %lf", 3.14);
 //
 // With span:
 //   Read-Only:
 //     // std::string HexEncode(base::span<const uint8_t> data);
 //     std::vector<uint8_t> data_buffer = GenerateData();
 //     std::string r = HexEncode(data_buffer);
 //
 //  Mutable:
 //     // ssize_t SafeSNPrintf(base::span<char>, const char* fmt, Args...);
 //     char str_buffer[100];
 //     SafeSNPrintf(str_buffer, "Pi ~= %lf", 3.14);
 //
 // Spans with "const" and pointers
 // -------------------------------
 //
 // Const and pointers can get confusing. Here are vectors of pointers and their
 // corresponding spans:
 //
 //   const std::vector<int*>        =>  base::span<int* const>
 //   std::vector<const int*>        =>  base::span<const int*>
 //   const std::vector<const int*>  =>  base::span<const int* const>
 //
 // Differences from the working group proposal
 // -------------------------------------------
 //
 // https://wg21.link/P0122 is the latest working group proposal, Chromium
 // currently implements R7. Differences between the proposal and the
 // implementation are documented in subsections below.
 //
 // Differences from [span.objectrep]:
 // - as_bytes() and as_writable_bytes() return spans of uint8_t instead of
 //   std::byte
 //
 // Differences in constants and types:
 // - index_type is aliased to size_t
 //
 // Differences from [span.sub]:
 // - using size_t instead of ptrdiff_t for indexing
 //
 // Differences from [span.obs]:
 // - using size_t instead of ptrdiff_t to represent size()
 //
 // Differences from [span.elem]:
 // - using size_t instead of ptrdiff_t for indexing
 //
 // Furthermore, all constructors and methods are marked noexcept due to the lack
 // of exceptions in Chromium.
 //
 // Due to the lack of class template argument deduction guides in C++14
 // appropriate make_span() utility functions are provided.

 // [span], class template span
 template <typename T, size_t Extent>
 class span {
  public:
   using element_type = T;
   using value_type = std::remove_cv_t<T>;
   using index_type = size_t;
   using difference_type = ptrdiff_t;
   using pointer = T*;
   using reference = 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>;
   static constexpr index_type extent = Extent;

   // [span.cons], span constructors, copy, assignment, and destructor
   constexpr span() noexcept : data_(nullptr), size_(0) {
     static_assert(Extent == dynamic_extent || Extent == 0, "Invalid Extent");
   }

   constexpr span(T* data, size_t size) noexcept : data_(data), size_(size) {
     CHECK(Extent == dynamic_extent || Extent == size);
   }

   // Artificially templatized to break ambiguity for span(ptr, 0).
   template <typename = void>
   constexpr span(T* begin, T* end) noexcept : span(begin, end - begin) {
     // Note: CHECK_LE is not constexpr, hence regular CHECK must be used.
     CHECK(begin <= end);
   }

   template <
       size_t N,
       typename = internal::EnableIfSpanCompatibleArray<T (&)[N], N, T, Extent>>
   constexpr span(T (&array)[N]) noexcept : span(std::data(array), N) {}

   template <
       size_t N,
       typename = internal::
           EnableIfSpanCompatibleArray<std::array<value_type, N>&, N, T, Extent>>
   constexpr span(std::array<value_type, N>& array) noexcept
       : span(std::data(array), N) {}

   template <size_t N,
             typename = internal::EnableIfSpanCompatibleArray<
                 const std::array<value_type, N>&,
                 N,
                 T,
                 Extent>>
   constexpr span(const std::array<value_type, N>& array) noexcept
       : span(std::data(array), N) {}

   // Conversion from a container that has compatible std::data() and integral
   // std::size().
   template <typename Container,
             typename = internal::EnableIfSpanCompatibleContainer<Container&, T>>
   constexpr span(Container& container) noexcept
       : span(std::data(container), std::size(container)) {}

   template <
       typename Container,
       typename = internal::EnableIfSpanCompatibleContainer<const Container&, T>>
   span(const Container& container) noexcept
       : span(std::data(container), std::size(container)) {}

   constexpr span(const span& other) noexcept = default;

   // Conversions from spans of compatible types and extents: this allows a
   // span<T> to be seamlessly used as a span<const T>, but not the other way
   // around. If extent is not dynamic, OtherExtent has to be equal to Extent.
   template <
       typename U,
       size_t OtherExtent,
       typename =
           internal::EnableIfLegalSpanConversion<U, OtherExtent, T, Extent>>
   constexpr span(const span<U, OtherExtent>& other)
       : span(other.data(), other.size()) {}

   constexpr span& operator=(const span& other) noexcept = default;
   ~span() noexcept = default;

   // [span.sub], span subviews
   template <size_t Count>
   constexpr span<T, Count> first() const noexcept {
     static_assert(Extent == dynamic_extent || Count <= Extent,
                   "Count must not exceed Extent");
     CHECK(Extent != dynamic_extent || Count <= size());
     return {data(), Count};
   }

   template <size_t Count>
   constexpr span<T, Count> last() const noexcept {
     static_assert(Extent == dynamic_extent || Count <= Extent,
                   "Count must not exceed Extent");
     CHECK(Extent != dynamic_extent || Count <= size());
     return {data() + (size() - Count), Count};
   }

   template <size_t Offset, size_t Count = dynamic_extent>
   constexpr span<T,
                  (Count != dynamic_extent
                       ? Count
                       : (Extent != dynamic_extent ? Extent - Offset
                                                   : dynamic_extent))>
   subspan() const noexcept {
     static_assert(Extent == dynamic_extent || Offset <= Extent,
                   "Offset must not exceed Extent");
     static_assert(Extent == dynamic_extent || Count == dynamic_extent ||
                       Count <= Extent - Offset,
                   "Count must not exceed Extent - Offset");
     CHECK(Extent != dynamic_extent || Offset <= size());
     CHECK(Extent != dynamic_extent || Count == dynamic_extent ||
           Count <= size() - Offset);
     return {data() + Offset, Count != dynamic_extent ? Count : size() - Offset};
   }

   constexpr span<T, dynamic_extent> first(size_t count) const noexcept {
     // Note: CHECK_LE is not constexpr, hence regular CHECK must be used.
     CHECK(count <= size());
     return {data(), count};
   }

   constexpr span<T, dynamic_extent> last(size_t count) const noexcept {
     // Note: CHECK_LE is not constexpr, hence regular CHECK must be used.
     CHECK(count <= size());
     return {data() + (size() - count), count};
   }

   constexpr span<T, dynamic_extent> subspan(size_t offset,
                                             size_t count = dynamic_extent) const
       noexcept {
     // Note: CHECK_LE is not constexpr, hence regular CHECK must be used.
     CHECK(offset <= size());
     CHECK(count == dynamic_extent || count <= size() - offset);
     return {data() + offset, count != dynamic_extent ? count : size() - offset};
   }

   // [span.obs], span observers
   constexpr size_t size() const noexcept { return size_; }
   constexpr size_t size_bytes() const noexcept { return size() * sizeof(T); }
   constexpr bool empty() const noexcept { return size() == 0; }

   // [span.elem], span element access
   constexpr T& operator[](size_t idx) const noexcept {
     // Note: CHECK_LT is not constexpr, hence regular CHECK must be used.
     CHECK(idx < size());
     return *(data() + idx);
   }

   constexpr T& operator()(size_t idx) const noexcept {
     // Note: CHECK_LT is not constexpr, hence regular CHECK must be used.
     CHECK(idx < size());
     return *(data() + idx);
   }

   constexpr T* data() const noexcept { return data_; }

   // [span.iter], span iterator support
   constexpr iterator begin() const noexcept { return data(); }
   constexpr iterator end() const noexcept { return data() + size(); }

   constexpr const_iterator cbegin() const noexcept { return begin(); }
   constexpr const_iterator cend() const noexcept { return end(); }

   constexpr reverse_iterator rbegin() const noexcept {
     return reverse_iterator(end());
   }
   constexpr reverse_iterator rend() const noexcept {
     return reverse_iterator(begin());
   }

   constexpr const_reverse_iterator crbegin() const noexcept {
     return const_reverse_iterator(cend());
   }
   constexpr const_reverse_iterator crend() const noexcept {
     return const_reverse_iterator(cbegin());
   }

  private:
   T* data_;
   size_t size_;
 };

 // span<T, Extent>::extent can not be declared inline prior to C++17, hence this
 // definition is required.
 template <class T, size_t Extent>
 constexpr size_t span<T, Extent>::extent;

 // [span.comparison], span comparison operators
 // Relational operators. Equality is a element-wise comparison.
 template <typename T, size_t X, typename U, size_t Y>
 constexpr bool operator==(span<T, X> lhs, span<U, Y> rhs) noexcept {
   return std::equal(lhs.cbegin(), lhs.cend(), rhs.cbegin(), rhs.cend());
 }

 template <typename T, size_t X, typename U, size_t Y>
 constexpr bool operator!=(span<T, X> lhs, span<U, Y> rhs) noexcept {
   return !(lhs == rhs);
 }

 template <typename T, size_t X, typename U, size_t Y>
 constexpr bool operator<(span<T, X> lhs, span<U, Y> rhs) noexcept {
   return std::lexicographical_compare(lhs.cbegin(), lhs.cend(), rhs.cbegin(),
                                       rhs.cend());
 }

 template <typename T, size_t X, typename U, size_t Y>
 constexpr bool operator<=(span<T, X> lhs, span<U, Y> rhs) noexcept {
   return !(rhs < lhs);
 }

 template <typename T, size_t X, typename U, size_t Y>
 constexpr bool operator>(span<T, X> lhs, span<U, Y> rhs) noexcept {
   return rhs < lhs;
 }

 template <typename T, size_t X, typename U, size_t Y>
 constexpr bool operator>=(span<T, X> lhs, span<U, Y> rhs) noexcept {
   return !(lhs < rhs);
 }

 // [span.objectrep], views of object representation
 template <typename T, size_t X>
 span<const uint8_t, (X == dynamic_extent ? dynamic_extent : sizeof(T) * X)>
 as_bytes(span<T, X> s) noexcept {
   return {reinterpret_cast<const uint8_t*>(s.data()), s.size_bytes()};
 }

 template <typename T,
           size_t X,
           typename = std::enable_if_t<!std::is_const<T>::value>>
 span<uint8_t, (X == dynamic_extent ? dynamic_extent : sizeof(T) * X)>
 as_writable_bytes(span<T, X> s) noexcept {
   return {reinterpret_cast<uint8_t*>(s.data()), s.size_bytes()};
 }

 // Type-deducing helpers for constructing a span.
 template <typename T>
 constexpr span<T> make_span(T* data, size_t size) noexcept {
   return {data, size};
 }

 template <typename T>
 constexpr span<T> make_span(T* begin, T* end) noexcept {
   return {begin, end};
 }

 template <typename T, size_t N>
 constexpr span<T, N> make_span(T (&array)[N]) noexcept {
   return array;
 }

 template <typename T, size_t N>
 constexpr span<T, N> make_span(std::array<T, N>& array) noexcept {
   return array;
 }

 template <typename T, size_t N>
 constexpr span<const T, N> make_span(const std::array<T, N>& array) noexcept {
   return array;
 }

 template <typename Container,
           typename T = typename Container::value_type,
           typename = internal::EnableIfSpanCompatibleContainer<Container&, T>>
 constexpr span<T> make_span(Container& container) noexcept {
   return container;
 }

 template <
     typename Container,
     typename T = const typename Container::value_type,
     typename = internal::EnableIfSpanCompatibleContainer<const Container&, T>>
 constexpr span<T> make_span(const Container& container) noexcept {
   return container;
 }

 template <typename T, size_t X>
 constexpr span<T, X> make_span(const span<T, X>& span) noexcept {
   return span;
 }

 }  // namespace base

 #endif  // BASE_CONTAINERS_SPAN_H_
	// Copyright 2017 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef BASE_CONTAINERS_SPAN_H_
	#define BASE_CONTAINERS_SPAN_H_

	#include <stddef.h>

	#include <algorithm>
	#include <array>
	#include <iterator>
	#include <type_traits>
	#include <utility>

	#include "base/logging.h"
	#include "base/stl_util.h"

	namespace base {

	// [views.constants]
	constexpr size_t dynamic_extent = static_cast<size_t>(-1);

	template <typename T, size_t Extent = dynamic_extent>
	class span;

	namespace internal {

	template <typename T>
	struct IsSpanImpl : std::false_type {};

	template <typename T, size_t Extent>
	struct IsSpanImpl<span<T, Extent>> : std::true_type {};

	template <typename T>
	using IsSpan = IsSpanImpl<std::decay_t<T>>;

	template <typename T>
	struct IsStdArrayImpl : std::false_type {};

	template <typename T, size_t N>
	struct IsStdArrayImpl<std::array<T, N>> : std::true_type {};

	template <typename T>
	using IsStdArray = IsStdArrayImpl<std::decay_t<T>>;

	template <typename T>
	using IsCArray = std::is_array<std::remove_reference_t<T>>;

	template <typename From, typename To>
	using IsLegalDataConversion = std::is_convertible<From ()[], To ()[]>;

	template <typename Container, typename T>
	using ContainerHasConvertibleData = IsLegalDataConversion<
	std::remove_pointer_t<decltype(std::data(std::declval<Container>()))>,
	T>;

	template <typename Container>
	using ContainerHasIntegralSize =
	std::is_integral<decltype(std::size(std::declval<Container>()))>;

	template <typename From, size_t FromExtent, typename To, size_t ToExtent>
	using EnableIfLegalSpanConversion =
	std::enable_if_t<(ToExtent == dynamic_extent \|\| ToExtent == FromExtent) &&
	IsLegalDataConversion<From, To>::value>;

	// SFINAE check if Array can be converted to a span<T>.
	template <typename Array, size_t N, typename T, size_t Extent>
	using EnableIfSpanCompatibleArray =
	std::enable_if_t<(Extent == dynamic_extent \|\| Extent == N) &&
	ContainerHasConvertibleData<Array, T>::value>;

	// SFINAE check if Container can be converted to a span<T>.
	template <typename Container, typename T>
	using EnableIfSpanCompatibleContainer =
	std::enable_if_t<!internal::IsSpan<Container>::value &&
	!internal::IsStdArray<Container>::value &&
	!internal::IsCArray<Container>::value &&
	ContainerHasConvertibleData<Container, T>::value &&
	ContainerHasIntegralSize<Container>::value>;

	} // namespace internal

	// A span is a value type that represents an array of elements of type T. Since
	// it only consists of a pointer to memory with an associated size, it is very
	// light-weight. It is cheap to construct, copy, move and use spans, so that
	// users are encouraged to use it as a pass-by-value parameter. A span does not
	// own the underlying memory, so care must be taken to ensure that a span does
	// not outlive the backing store.
	//
	// span is somewhat analogous to std::string_view, but with arbitrary element
	// types, allowing mutation if T is non-const.
	//
	// span is implicitly convertible from C++ arrays, as well as most [1]
	// container-like types that provide a data() and size() method (such as
	// std::vector<T>). A mutable span<T> can also be implicitly converted to an
	// immutable span<const T>.
	//
	// Consider using a span for functions that take a data pointer and size
	// parameter: it allows the function to still act on an array-like type, while
	// allowing the caller code to be a bit more concise.
	//
	// For read-only data access pass a span<const T>: the caller can supply either
	// a span<const T> or a span<T>, while the callee will have a read-only view.
	// For read-write access a mutable span<T> is required.
	//
	// Without span:
	// Read-Only:
	// // std::string HexEncode(const uint8_t* data, size_t size);
	// std::vector<uint8_t> data_buffer = GenerateData();
	// std::string r = HexEncode(data_buffer.data(), data_buffer.size());
	//
	// Mutable:
	// // ssize_t SafeSNPrintf(char* buf, size_t N, const char* fmt, Args...);
	// char str_buffer[100];
	// SafeSNPrintf(str_buffer, sizeof(str_buffer), "Pi ~= %lf", 3.14);
	//
	// With span:
	// Read-Only:
	// // std::string HexEncode(base::span<const uint8_t> data);
	// std::vector<uint8_t> data_buffer = GenerateData();
	// std::string r = HexEncode(data_buffer);
	//
	// Mutable:
	// // ssize_t SafeSNPrintf(base::span<char>, const char* fmt, Args...);
	// char str_buffer[100];
	// SafeSNPrintf(str_buffer, "Pi ~= %lf", 3.14);
	//
	// Spans with "const" and pointers
	// -------------------------------
	//
	// Const and pointers can get confusing. Here are vectors of pointers and their
	// corresponding spans:
	//
	// const std::vector<int> => base::span<int const>
	// std::vector<const int> => base::span<const int>
	// const std::vector<const int> => base::span<const int const>
	//
	// Differences from the working group proposal
	// -------------------------------------------
	//
	// https://wg21.link/P0122 is the latest working group proposal, Chromium
	// currently implements R7. Differences between the proposal and the
	// implementation are documented in subsections below.
	//
	// Differences from [span.objectrep]:
	// - as_bytes() and as_writable_bytes() return spans of uint8_t instead of
	// std::byte
	//
	// Differences in constants and types:
	// - index_type is aliased to size_t
	//
	// Differences from [span.sub]:
	// - using size_t instead of ptrdiff_t for indexing
	//
	// Differences from [span.obs]:
	// - using size_t instead of ptrdiff_t to represent size()
	//
	// Differences from [span.elem]:
	// - using size_t instead of ptrdiff_t for indexing
	//
	// Furthermore, all constructors and methods are marked noexcept due to the lack
	// of exceptions in Chromium.
	//
	// Due to the lack of class template argument deduction guides in C++14
	// appropriate make_span() utility functions are provided.

	// [span], class template span
	template <typename T, size_t Extent>
	class span {
	public:
	using element_type = T;
	using value_type = std::remove_cv_t<T>;
	using index_type = size_t;
	using difference_type = ptrdiff_t;
	using pointer = T*;
	using reference = 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>;
	static constexpr index_type extent = Extent;

	// [span.cons], span constructors, copy, assignment, and destructor
	constexpr span() noexcept : data_(nullptr), size_(0) {
	static_assert(Extent == dynamic_extent \|\| Extent == 0, "Invalid Extent");
	}

	constexpr span(T* data, size_t size) noexcept : data_(data), size_(size) {
	CHECK(Extent == dynamic_extent \|\| Extent == size);
	}

	// Artificially templatized to break ambiguity for span(ptr, 0).
	template <typename = void>
	constexpr span(T* begin, T* end) noexcept : span(begin, end - begin) {
	// Note: CHECK_LE is not constexpr, hence regular CHECK must be used.
	CHECK(begin <= end);
	}

	template <
	size_t N,
	typename = internal::EnableIfSpanCompatibleArray<T (&)[N], N, T, Extent>>
	constexpr span(T (&array)[N]) noexcept : span(std::data(array), N) {}

	template <
	size_t N,
	typename = internal::
	EnableIfSpanCompatibleArray<std::array<value_type, N>&, N, T, Extent>>
	constexpr span(std::array<value_type, N>& array) noexcept
	: span(std::data(array), N) {}

	template <size_t N,
	typename = internal::EnableIfSpanCompatibleArray<
	const std::array<value_type, N>&,
	N,
	T,
	Extent>>
	constexpr span(const std::array<value_type, N>& array) noexcept
	: span(std::data(array), N) {}

	// Conversion from a container that has compatible std::data() and integral
	// std::size().
	template <typename Container,
	typename = internal::EnableIfSpanCompatibleContainer<Container&, T>>
	constexpr span(Container& container) noexcept
	: span(std::data(container), std::size(container)) {}

	template <
	typename Container,
	typename = internal::EnableIfSpanCompatibleContainer<const Container&, T>>
	span(const Container& container) noexcept
	: span(std::data(container), std::size(container)) {}

	constexpr span(const span& other) noexcept = default;

	// Conversions from spans of compatible types and extents: this allows a
	// span<T> to be seamlessly used as a span<const T>, but not the other way
	// around. If extent is not dynamic, OtherExtent has to be equal to Extent.
	template <
	typename U,
	size_t OtherExtent,
	typename =
	internal::EnableIfLegalSpanConversion<U, OtherExtent, T, Extent>>
	constexpr span(const span<U, OtherExtent>& other)
	: span(other.data(), other.size()) {}

	constexpr span& operator=(const span& other) noexcept = default;
	~span() noexcept = default;

	// [span.sub], span subviews
	template <size_t Count>
	constexpr span<T, Count> first() const noexcept {
	static_assert(Extent == dynamic_extent \|\| Count <= Extent,
	"Count must not exceed Extent");
	CHECK(Extent != dynamic_extent \|\| Count <= size());
	return {data(), Count};
	}

	template <size_t Count>
	constexpr span<T, Count> last() const noexcept {
	static_assert(Extent == dynamic_extent \|\| Count <= Extent,
	"Count must not exceed Extent");
	CHECK(Extent != dynamic_extent \|\| Count <= size());
	return {data() + (size() - Count), Count};
	}

	template <size_t Offset, size_t Count = dynamic_extent>
	constexpr span<T,
	(Count != dynamic_extent
	? Count
	: (Extent != dynamic_extent ? Extent - Offset
	: dynamic_extent))>
	subspan() const noexcept {
	static_assert(Extent == dynamic_extent \|\| Offset <= Extent,
	"Offset must not exceed Extent");
	static_assert(Extent == dynamic_extent \|\| Count == dynamic_extent \|\|
	Count <= Extent - Offset,
	"Count must not exceed Extent - Offset");
	CHECK(Extent != dynamic_extent \|\| Offset <= size());
	CHECK(Extent != dynamic_extent \|\| Count == dynamic_extent \|\|
	Count <= size() - Offset);
	return {data() + Offset, Count != dynamic_extent ? Count : size() - Offset};
	}

	constexpr span<T, dynamic_extent> first(size_t count) const noexcept {
	// Note: CHECK_LE is not constexpr, hence regular CHECK must be used.
	CHECK(count <= size());
	return {data(), count};
	}

	constexpr span<T, dynamic_extent> last(size_t count) const noexcept {
	// Note: CHECK_LE is not constexpr, hence regular CHECK must be used.
	CHECK(count <= size());
	return {data() + (size() - count), count};
	}

	constexpr span<T, dynamic_extent> subspan(size_t offset,
	size_t count = dynamic_extent) const
	noexcept {
	// Note: CHECK_LE is not constexpr, hence regular CHECK must be used.
	CHECK(offset <= size());
	CHECK(count == dynamic_extent \|\| count <= size() - offset);
	return {data() + offset, count != dynamic_extent ? count : size() - offset};
	}

	// [span.obs], span observers
	constexpr size_t size() const noexcept { return size_; }
	constexpr size_t size_bytes() const noexcept { return size() * sizeof(T); }
	constexpr bool empty() const noexcept { return size() == 0; }

	// [span.elem], span element access
	constexpr T& operator[](size_t idx) const noexcept {
	// Note: CHECK_LT is not constexpr, hence regular CHECK must be used.
	CHECK(idx < size());
	return *(data() + idx);
	}

	constexpr T& operator()(size_t idx) const noexcept {
	// Note: CHECK_LT is not constexpr, hence regular CHECK must be used.
	CHECK(idx < size());
	return *(data() + idx);
	}

	constexpr T* data() const noexcept { return data_; }

	// [span.iter], span iterator support
	constexpr iterator begin() const noexcept { return data(); }
	constexpr iterator end() const noexcept { return data() + size(); }

	constexpr const_iterator cbegin() const noexcept { return begin(); }
	constexpr const_iterator cend() const noexcept { return end(); }

	constexpr reverse_iterator rbegin() const noexcept {
	return reverse_iterator(end());
	}
	constexpr reverse_iterator rend() const noexcept {
	return reverse_iterator(begin());
	}

	constexpr const_reverse_iterator crbegin() const noexcept {
	return const_reverse_iterator(cend());
	}
	constexpr const_reverse_iterator crend() const noexcept {
	return const_reverse_iterator(cbegin());
	}

	private:
	T* data_;
	size_t size_;
	};

	// span<T, Extent>::extent can not be declared inline prior to C++17, hence this
	// definition is required.
	template <class T, size_t Extent>
	constexpr size_t span<T, Extent>::extent;

	// [span.comparison], span comparison operators
	// Relational operators. Equality is a element-wise comparison.
	template <typename T, size_t X, typename U, size_t Y>
	constexpr bool operator==(span<T, X> lhs, span<U, Y> rhs) noexcept {
	return std::equal(lhs.cbegin(), lhs.cend(), rhs.cbegin(), rhs.cend());
	}

	template <typename T, size_t X, typename U, size_t Y>
	constexpr bool operator!=(span<T, X> lhs, span<U, Y> rhs) noexcept {
	return !(lhs == rhs);
	}

	template <typename T, size_t X, typename U, size_t Y>
	constexpr bool operator<(span<T, X> lhs, span<U, Y> rhs) noexcept {
	return std::lexicographical_compare(lhs.cbegin(), lhs.cend(), rhs.cbegin(),
	rhs.cend());
	}

	template <typename T, size_t X, typename U, size_t Y>
	constexpr bool operator<=(span<T, X> lhs, span<U, Y> rhs) noexcept {
	return !(rhs < lhs);
	}

	template <typename T, size_t X, typename U, size_t Y>
	constexpr bool operator>(span<T, X> lhs, span<U, Y> rhs) noexcept {
	return rhs < lhs;
	}

	template <typename T, size_t X, typename U, size_t Y>
	constexpr bool operator>=(span<T, X> lhs, span<U, Y> rhs) noexcept {
	return !(lhs < rhs);
	}

	// [span.objectrep], views of object representation
	template <typename T, size_t X>
	span<const uint8_t, (X == dynamic_extent ? dynamic_extent : sizeof(T) * X)>
	as_bytes(span<T, X> s) noexcept {
	return {reinterpret_cast<const uint8_t*>(s.data()), s.size_bytes()};
	}

	template <typename T,
	size_t X,
	typename = std::enable_if_t<!std::is_const<T>::value>>
	span<uint8_t, (X == dynamic_extent ? dynamic_extent : sizeof(T) * X)>
	as_writable_bytes(span<T, X> s) noexcept {
	return {reinterpret_cast<uint8_t*>(s.data()), s.size_bytes()};
	}

	// Type-deducing helpers for constructing a span.
	template <typename T>
	constexpr span<T> make_span(T* data, size_t size) noexcept {
	return {data, size};
	}

	template <typename T>
	constexpr span<T> make_span(T* begin, T* end) noexcept {
	return {begin, end};
	}

	template <typename T, size_t N>
	constexpr span<T, N> make_span(T (&array)[N]) noexcept {
	return array;
	}

	template <typename T, size_t N>
	constexpr span<T, N> make_span(std::array<T, N>& array) noexcept {
	return array;
	}

	template <typename T, size_t N>
	constexpr span<const T, N> make_span(const std::array<T, N>& array) noexcept {
	return array;
	}

	template <typename Container,
	typename T = typename Container::value_type,
	typename = internal::EnableIfSpanCompatibleContainer<Container&, T>>
	constexpr span<T> make_span(Container& container) noexcept {
	return container;
	}

	template <
	typename Container,
	typename T = const typename Container::value_type,
	typename = internal::EnableIfSpanCompatibleContainer<const Container&, T>>
	constexpr span<T> make_span(const Container& container) noexcept {
	return container;
	}

	template <typename T, size_t X>
	constexpr span<T, X> make_span(const span<T, X>& span) noexcept {
	return span;
	}

	} // namespace base

	#endif // BASE_CONTAINERS_SPAN_H_