absl/strings/internal/str_format/arg.h - third_party/abseil-cpp - Git at Google

 #ifndef ABSL_STRINGS_INTERNAL_STR_FORMAT_ARG_H_
 #define ABSL_STRINGS_INTERNAL_STR_FORMAT_ARG_H_

 #include <string.h>
 #include <wchar.h>

 #include <cstdio>
 #include <iomanip>
 #include <limits>
 #include <sstream>
 #include <string>
 #include <type_traits>

 #include "absl/base/port.h"
 #include "absl/meta/type_traits.h"
 #include "absl/numeric/int128.h"
 #include "absl/strings/internal/str_format/extension.h"
 #include "absl/strings/string_view.h"

 class Cord;
 class CordReader;

 namespace absl {
 inline namespace lts_2018_12_18 {

 class FormatCountCapture;
 class FormatSink;

 namespace str_format_internal {

 template <typename T, typename = void>
 struct HasUserDefinedConvert : std::false_type {};

 template <typename T>
 struct HasUserDefinedConvert<
     T, void_t<decltype(AbslFormatConvert(
            std::declval<const T&>(), std::declval<ConversionSpec>(),
            std::declval<FormatSink*>()))>> : std::true_type {};
 template <typename T>
 class StreamedWrapper;

 // If 'v' can be converted (in the printf sense) according to 'conv',
 // then convert it, appending to `sink` and return `true`.
 // Otherwise fail and return `false`.
 // Raw pointers.
 struct VoidPtr {
   VoidPtr() = default;
   template <typename T,
             decltype(reinterpret_cast<uintptr_t>(std::declval<T*>())) = 0>
   VoidPtr(T* ptr)  // NOLINT
       : value(ptr ? reinterpret_cast<uintptr_t>(ptr) : 0) {}
   uintptr_t value;
 };
 ConvertResult<Conv::p> FormatConvertImpl(VoidPtr v, ConversionSpec conv,
                                          FormatSinkImpl* sink);

 // Strings.
 ConvertResult<Conv::s> FormatConvertImpl(const std::string& v, ConversionSpec conv,
                                          FormatSinkImpl* sink);
 ConvertResult<Conv::s> FormatConvertImpl(string_view v, ConversionSpec conv,
                                          FormatSinkImpl* sink);
 ConvertResult<Conv::s | Conv::p> FormatConvertImpl(const char* v,
                                                    ConversionSpec conv,
                                                    FormatSinkImpl* sink);
 template <class AbslCord,
           typename std::enable_if<
               std::is_same<AbslCord, ::Cord>::value>::type* = nullptr,
           class AbslCordReader = ::CordReader>
 ConvertResult<Conv::s> FormatConvertImpl(const AbslCord& value,
                                          ConversionSpec conv,
                                          FormatSinkImpl* sink) {
   if (conv.conv().id() != ConversionChar::s) return {false};

   bool is_left = conv.flags().left;
   size_t space_remaining = 0;

   int width = conv.width();
   if (width >= 0) space_remaining = width;

   size_t to_write = value.size();

   int precision = conv.precision();
   if (precision >= 0)
     to_write = std::min(to_write, static_cast<size_t>(precision));

   space_remaining = Excess(to_write, space_remaining);

   if (space_remaining > 0 && !is_left) sink->Append(space_remaining, ' ');

   string_view piece;
   for (AbslCordReader reader(value);
        to_write > 0 && reader.ReadFragment(&piece); to_write -= piece.size()) {
     if (piece.size() > to_write) piece.remove_suffix(piece.size() - to_write);
     sink->Append(piece);
   }

   if (space_remaining > 0 && is_left) sink->Append(space_remaining, ' ');
   return {true};
 }

 using IntegralConvertResult =
     ConvertResult<Conv::c | Conv::numeric | Conv::star>;
 using FloatingConvertResult = ConvertResult<Conv::floating>;

 // Floats.
 FloatingConvertResult FormatConvertImpl(float v, ConversionSpec conv,
                                         FormatSinkImpl* sink);
 FloatingConvertResult FormatConvertImpl(double v, ConversionSpec conv,
                                         FormatSinkImpl* sink);
 FloatingConvertResult FormatConvertImpl(long double v, ConversionSpec conv,
                                         FormatSinkImpl* sink);

 // Chars.
 IntegralConvertResult FormatConvertImpl(char v, ConversionSpec conv,
                                         FormatSinkImpl* sink);
 IntegralConvertResult FormatConvertImpl(signed char v, ConversionSpec conv,
                                         FormatSinkImpl* sink);
 IntegralConvertResult FormatConvertImpl(unsigned char v, ConversionSpec conv,
                                         FormatSinkImpl* sink);

 // Ints.
 IntegralConvertResult FormatConvertImpl(short v,  // NOLINT
                                         ConversionSpec conv,
                                         FormatSinkImpl* sink);
 IntegralConvertResult FormatConvertImpl(unsigned short v,  // NOLINT
                                         ConversionSpec conv,
                                         FormatSinkImpl* sink);
 IntegralConvertResult FormatConvertImpl(int v, ConversionSpec conv,
                                         FormatSinkImpl* sink);
 IntegralConvertResult FormatConvertImpl(unsigned v, ConversionSpec conv,
                                         FormatSinkImpl* sink);
 IntegralConvertResult FormatConvertImpl(long v,  // NOLINT
                                         ConversionSpec conv,
                                         FormatSinkImpl* sink);
 IntegralConvertResult FormatConvertImpl(unsigned long v,  // NOLINT
                                         ConversionSpec conv,
                                         FormatSinkImpl* sink);
 IntegralConvertResult FormatConvertImpl(long long v,  // NOLINT
                                         ConversionSpec conv,
                                         FormatSinkImpl* sink);
 IntegralConvertResult FormatConvertImpl(unsigned long long v,  // NOLINT
                                         ConversionSpec conv,
                                         FormatSinkImpl* sink);
 IntegralConvertResult FormatConvertImpl(uint128 v, ConversionSpec conv,
                                         FormatSinkImpl* sink);
 template <typename T, enable_if_t<std::is_same<T, bool>::value, int> = 0>
 IntegralConvertResult FormatConvertImpl(T v, ConversionSpec conv,
                                         FormatSinkImpl* sink) {
   return FormatConvertImpl(static_cast<int>(v), conv, sink);
 }

 // We provide this function to help the checker, but it is never defined.
 // FormatArgImpl will use the underlying Convert functions instead.
 template <typename T>
 typename std::enable_if<std::is_enum<T>::value &&
                             !HasUserDefinedConvert<T>::value,
                         IntegralConvertResult>::type
 FormatConvertImpl(T v, ConversionSpec conv, FormatSinkImpl* sink);

 template <typename T>
 ConvertResult<Conv::s> FormatConvertImpl(const StreamedWrapper<T>& v,
                                          ConversionSpec conv,
                                          FormatSinkImpl* out) {
   std::ostringstream oss;
   oss << v.v_;
   if (!oss) return {false};
   return str_format_internal::FormatConvertImpl(oss.str(), conv, out);
 }

 // Use templates and dependent types to delay evaluation of the function
 // until after FormatCountCapture is fully defined.
 struct FormatCountCaptureHelper {
   template <class T = int>
   static ConvertResult<Conv::n> ConvertHelper(const FormatCountCapture& v,
                                               ConversionSpec conv,
                                               FormatSinkImpl* sink) {
     const absl::enable_if_t<sizeof(T) != 0, FormatCountCapture>& v2 = v;

     if (conv.conv().id() != str_format_internal::ConversionChar::n)
       return {false};
     *v2.p_ = static_cast<int>(sink->size());
     return {true};
   }
 };

 template <class T = int>
 ConvertResult<Conv::n> FormatConvertImpl(const FormatCountCapture& v,
                                          ConversionSpec conv,
                                          FormatSinkImpl* sink) {
   return FormatCountCaptureHelper::ConvertHelper(v, conv, sink);
 }

 // Helper friend struct to hide implementation details from the public API of
 // FormatArgImpl.
 struct FormatArgImplFriend {
   template <typename Arg>
   static bool ToInt(Arg arg, int* out) {
     // A value initialized ConversionSpec has a `none` conv, which tells the
     // dispatcher to run the `int` conversion.
     return arg.dispatcher_(arg.data_, {}, out);
   }

   template <typename Arg>
   static bool Convert(Arg arg, str_format_internal::ConversionSpec conv,
                       FormatSinkImpl* out) {
     return arg.dispatcher_(arg.data_, conv, out);
   }

   template <typename Arg>
   static typename Arg::Dispatcher GetVTablePtrForTest(Arg arg) {
     return arg.dispatcher_;
   }
 };

 // A type-erased handle to a format argument.
 class FormatArgImpl {
  private:
   enum { kInlinedSpace = 8 };

   using VoidPtr = str_format_internal::VoidPtr;

   union Data {
     const void* ptr;
     const volatile void* volatile_ptr;
     char buf[kInlinedSpace];
   };

   using Dispatcher = bool (*)(Data, ConversionSpec, void* out);

   template <typename T>
   struct store_by_value
       : std::integral_constant<bool, (sizeof(T) <= kInlinedSpace) &&
                                          (std::is_integral<T>::value ||
                                           std::is_floating_point<T>::value ||
                                           std::is_pointer<T>::value ||
                                           std::is_same<VoidPtr, T>::value)> {};

   enum StoragePolicy { ByPointer, ByVolatilePointer, ByValue };
   template <typename T>
   struct storage_policy
       : std::integral_constant<StoragePolicy,
                                (std::is_volatile<T>::value
                                     ? ByVolatilePointer
                                     : (store_by_value<T>::value ? ByValue
                                                                 : ByPointer))> {
   };

   // To reduce the number of vtables we will decay values before hand.
   // Anything with a user-defined Convert will get its own vtable.
   // For everything else:
   //   - Decay char* and char arrays into `const char*`
   //   - Decay any other pointer to `const void*`
   //   - Decay all enums to their underlying type.
   //   - Decay function pointers to void*.
   template <typename T, typename = void>
   struct DecayType {
     static constexpr bool kHasUserDefined =
         str_format_internal::HasUserDefinedConvert<T>::value;
     using type = typename std::conditional<
         !kHasUserDefined && std::is_convertible<T, const char*>::value,
         const char*,
         typename std::conditional<!kHasUserDefined &&
                                       std::is_convertible<T, VoidPtr>::value,
                                   VoidPtr, const T&>::type>::type;
   };
   template <typename T>
   struct DecayType<T,
                    typename std::enable_if<
                        !str_format_internal::HasUserDefinedConvert<T>::value &&
                        std::is_enum<T>::value>::type> {
     using type = typename std::underlying_type<T>::type;
   };

  public:
   template <typename T>
   explicit FormatArgImpl(const T& value) {
     using D = typename DecayType<T>::type;
     static_assert(
         std::is_same<D, const T&>::value || storage_policy<D>::value == ByValue,
         "Decayed types must be stored by value");
     Init(static_cast<D>(value));
   }

  private:
   friend struct str_format_internal::FormatArgImplFriend;
   template <typename T, StoragePolicy = storage_policy<T>::value>
   struct Manager;

   template <typename T>
   struct Manager<T, ByPointer> {
     static Data SetValue(const T& value) {
       Data data;
       data.ptr = &value;
       return data;
     }

     static const T& Value(Data arg) { return *static_cast<const T*>(arg.ptr); }
   };

   template <typename T>
   struct Manager<T, ByVolatilePointer> {
     static Data SetValue(const T& value) {
       Data data;
       data.volatile_ptr = &value;
       return data;
     }

     static const T& Value(Data arg) {
       return *static_cast<const T*>(arg.volatile_ptr);
     }
   };

   template <typename T>
   struct Manager<T, ByValue> {
     static Data SetValue(const T& value) {
       Data data;
       memcpy(data.buf, &value, sizeof(value));
       return data;
     }

     static T Value(Data arg) {
       T value;
       memcpy(&value, arg.buf, sizeof(T));
       return value;
     }
   };

   template <typename T>
   void Init(const T& value) {
     data_ = Manager<T>::SetValue(value);
     dispatcher_ = &Dispatch<T>;
   }

   template <typename T>
   static int ToIntVal(const T& val) {
     using CommonType = typename std::conditional<std::is_signed<T>::value,
                                                  int64_t, uint64_t>::type;
     if (static_cast<CommonType>(val) >
         static_cast<CommonType>((std::numeric_limits<int>::max)())) {
       return (std::numeric_limits<int>::max)();
     } else if (std::is_signed<T>::value &&
                static_cast<CommonType>(val) <
                    static_cast<CommonType>((std::numeric_limits<int>::min)())) {
       return (std::numeric_limits<int>::min)();
     }
     return static_cast<int>(val);
   }

   template <typename T>
   static bool ToInt(Data arg, int* out, std::true_type /* is_integral */,
                     std::false_type) {
     *out = ToIntVal(Manager<T>::Value(arg));
     return true;
   }

   template <typename T>
   static bool ToInt(Data arg, int* out, std::false_type,
                     std::true_type /* is_enum */) {
     *out = ToIntVal(static_cast<typename std::underlying_type<T>::type>(
         Manager<T>::Value(arg)));
     return true;
   }

   template <typename T>
   static bool ToInt(Data, int*, std::false_type, std::false_type) {
     return false;
   }

   template <typename T>
   static bool Dispatch(Data arg, ConversionSpec spec, void* out) {
     // A `none` conv indicates that we want the `int` conversion.
     if (ABSL_PREDICT_FALSE(spec.conv().id() == ConversionChar::none)) {
       return ToInt<T>(arg, static_cast<int*>(out), std::is_integral<T>(),
                       std::is_enum<T>());
     }

     return str_format_internal::FormatConvertImpl(
                Manager<T>::Value(arg), spec, static_cast<FormatSinkImpl*>(out))
         .value;
   }

   Data data_;
   Dispatcher dispatcher_;
 };

 #define ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(T, E) \
   E template bool FormatArgImpl::Dispatch<T>(Data, ConversionSpec, void*)

 #define ABSL_INTERNAL_FORMAT_DISPATCH_OVERLOADS_EXPAND_(...)                   \
   ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(str_format_internal::VoidPtr,     \
                                              __VA_ARGS__);                     \
   ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(bool, __VA_ARGS__);               \
   ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(char, __VA_ARGS__);               \
   ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(signed char, __VA_ARGS__);        \
   ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(unsigned char, __VA_ARGS__);      \
   ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(short, __VA_ARGS__); /* NOLINT */ \
   ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(unsigned short,      /* NOLINT */ \
                                              __VA_ARGS__);                     \
   ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(int, __VA_ARGS__);                \
   ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(unsigned int, __VA_ARGS__);       \
   ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(long, __VA_ARGS__); /* NOLINT */  \
   ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(unsigned long,      /* NOLINT */  \
                                              __VA_ARGS__);                     \
   ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(long long, /* NOLINT */           \
                                              __VA_ARGS__);                     \
   ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(unsigned long long, /* NOLINT */  \
                                              __VA_ARGS__);                     \
   ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(uint128, __VA_ARGS__);            \
   ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(float, __VA_ARGS__);              \
   ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(double, __VA_ARGS__);             \
   ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(long double, __VA_ARGS__);        \
   ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(const char*, __VA_ARGS__);        \
   ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(std::string, __VA_ARGS__);             \
   ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(string_view, __VA_ARGS__)

 ABSL_INTERNAL_FORMAT_DISPATCH_OVERLOADS_EXPAND_(extern);

 }  // namespace str_format_internal
 }  // inline namespace lts_2018_12_18
 }  // namespace absl

 #endif  // ABSL_STRINGS_INTERNAL_STR_FORMAT_ARG_H_
	#ifndef ABSL_STRINGS_INTERNAL_STR_FORMAT_ARG_H_
	#define ABSL_STRINGS_INTERNAL_STR_FORMAT_ARG_H_

	#include <string.h>
	#include <wchar.h>

	#include <cstdio>
	#include <iomanip>
	#include <limits>
	#include <sstream>
	#include <string>
	#include <type_traits>

	#include "absl/base/port.h"
	#include "absl/meta/type_traits.h"
	#include "absl/numeric/int128.h"
	#include "absl/strings/internal/str_format/extension.h"
	#include "absl/strings/string_view.h"

	class Cord;
	class CordReader;

	namespace absl {
	inline namespace lts_2018_12_18 {

	class FormatCountCapture;
	class FormatSink;

	namespace str_format_internal {

	template <typename T, typename = void>
	struct HasUserDefinedConvert : std::false_type {};

	template <typename T>
	struct HasUserDefinedConvert<
	T, void_t<decltype(AbslFormatConvert(
	std::declval<const T&>(), std::declval<ConversionSpec>(),
	std::declval<FormatSink*>()))>> : std::true_type {};
	template <typename T>
	class StreamedWrapper;

	// If 'v' can be converted (in the printf sense) according to 'conv',
	// then convert it, appending to `sink` and return `true`.
	// Otherwise fail and return `false`.
	// Raw pointers.
	struct VoidPtr {
	VoidPtr() = default;
	template <typename T,
	decltype(reinterpret_cast<uintptr_t>(std::declval<T*>())) = 0>
	VoidPtr(T* ptr) // NOLINT
	: value(ptr ? reinterpret_cast<uintptr_t>(ptr) : 0) {}
	uintptr_t value;
	};
	ConvertResult<Conv::p> FormatConvertImpl(VoidPtr v, ConversionSpec conv,
	FormatSinkImpl* sink);

	// Strings.
	ConvertResult<Conv::s> FormatConvertImpl(const std::string& v, ConversionSpec conv,
	FormatSinkImpl* sink);
	ConvertResult<Conv::s> FormatConvertImpl(string_view v, ConversionSpec conv,
	FormatSinkImpl* sink);
	ConvertResult<Conv::s \| Conv::p> FormatConvertImpl(const char* v,
	ConversionSpec conv,
	FormatSinkImpl* sink);
	template <class AbslCord,
	typename std::enable_if<
	std::is_same<AbslCord, ::Cord>::value>::type* = nullptr,
	class AbslCordReader = ::CordReader>
	ConvertResult<Conv::s> FormatConvertImpl(const AbslCord& value,
	ConversionSpec conv,
	FormatSinkImpl* sink) {
	if (conv.conv().id() != ConversionChar::s) return {false};

	bool is_left = conv.flags().left;
	size_t space_remaining = 0;

	int width = conv.width();
	if (width >= 0) space_remaining = width;

	size_t to_write = value.size();

	int precision = conv.precision();
	if (precision >= 0)
	to_write = std::min(to_write, static_cast<size_t>(precision));

	space_remaining = Excess(to_write, space_remaining);

	if (space_remaining > 0 && !is_left) sink->Append(space_remaining, ' ');

	string_view piece;
	for (AbslCordReader reader(value);
	to_write > 0 && reader.ReadFragment(&piece); to_write -= piece.size()) {
	if (piece.size() > to_write) piece.remove_suffix(piece.size() - to_write);
	sink->Append(piece);
	}

	if (space_remaining > 0 && is_left) sink->Append(space_remaining, ' ');
	return {true};
	}

	using IntegralConvertResult =
	ConvertResult<Conv::c \| Conv::numeric \| Conv::star>;
	using FloatingConvertResult = ConvertResult<Conv::floating>;

	// Floats.
	FloatingConvertResult FormatConvertImpl(float v, ConversionSpec conv,
	FormatSinkImpl* sink);
	FloatingConvertResult FormatConvertImpl(double v, ConversionSpec conv,
	FormatSinkImpl* sink);
	FloatingConvertResult FormatConvertImpl(long double v, ConversionSpec conv,
	FormatSinkImpl* sink);

	// Chars.
	IntegralConvertResult FormatConvertImpl(char v, ConversionSpec conv,
	FormatSinkImpl* sink);
	IntegralConvertResult FormatConvertImpl(signed char v, ConversionSpec conv,
	FormatSinkImpl* sink);
	IntegralConvertResult FormatConvertImpl(unsigned char v, ConversionSpec conv,
	FormatSinkImpl* sink);

	// Ints.
	IntegralConvertResult FormatConvertImpl(short v, // NOLINT
	ConversionSpec conv,
	FormatSinkImpl* sink);
	IntegralConvertResult FormatConvertImpl(unsigned short v, // NOLINT
	ConversionSpec conv,
	FormatSinkImpl* sink);
	IntegralConvertResult FormatConvertImpl(int v, ConversionSpec conv,
	FormatSinkImpl* sink);
	IntegralConvertResult FormatConvertImpl(unsigned v, ConversionSpec conv,
	FormatSinkImpl* sink);
	IntegralConvertResult FormatConvertImpl(long v, // NOLINT
	ConversionSpec conv,
	FormatSinkImpl* sink);
	IntegralConvertResult FormatConvertImpl(unsigned long v, // NOLINT
	ConversionSpec conv,
	FormatSinkImpl* sink);
	IntegralConvertResult FormatConvertImpl(long long v, // NOLINT
	ConversionSpec conv,
	FormatSinkImpl* sink);
	IntegralConvertResult FormatConvertImpl(unsigned long long v, // NOLINT
	ConversionSpec conv,
	FormatSinkImpl* sink);
	IntegralConvertResult FormatConvertImpl(uint128 v, ConversionSpec conv,
	FormatSinkImpl* sink);
	template <typename T, enable_if_t<std::is_same<T, bool>::value, int> = 0>
	IntegralConvertResult FormatConvertImpl(T v, ConversionSpec conv,
	FormatSinkImpl* sink) {
	return FormatConvertImpl(static_cast<int>(v), conv, sink);
	}

	// We provide this function to help the checker, but it is never defined.
	// FormatArgImpl will use the underlying Convert functions instead.
	template <typename T>
	typename std::enable_if<std::is_enum<T>::value &&
	!HasUserDefinedConvert<T>::value,
	IntegralConvertResult>::type
	FormatConvertImpl(T v, ConversionSpec conv, FormatSinkImpl* sink);

	template <typename T>
	ConvertResult<Conv::s> FormatConvertImpl(const StreamedWrapper<T>& v,
	ConversionSpec conv,
	FormatSinkImpl* out) {
	std::ostringstream oss;
	oss << v.v_;
	if (!oss) return {false};
	return str_format_internal::FormatConvertImpl(oss.str(), conv, out);
	}

	// Use templates and dependent types to delay evaluation of the function
	// until after FormatCountCapture is fully defined.
	struct FormatCountCaptureHelper {
	template <class T = int>
	static ConvertResult<Conv::n> ConvertHelper(const FormatCountCapture& v,
	ConversionSpec conv,
	FormatSinkImpl* sink) {
	const absl::enable_if_t<sizeof(T) != 0, FormatCountCapture>& v2 = v;

	if (conv.conv().id() != str_format_internal::ConversionChar::n)
	return {false};
	*v2.p_ = static_cast<int>(sink->size());
	return {true};
	}
	};

	template <class T = int>
	ConvertResult<Conv::n> FormatConvertImpl(const FormatCountCapture& v,
	ConversionSpec conv,
	FormatSinkImpl* sink) {
	return FormatCountCaptureHelper::ConvertHelper(v, conv, sink);
	}

	// Helper friend struct to hide implementation details from the public API of
	// FormatArgImpl.
	struct FormatArgImplFriend {
	template <typename Arg>
	static bool ToInt(Arg arg, int* out) {
	// A value initialized ConversionSpec has a `none` conv, which tells the
	// dispatcher to run the `int` conversion.
	return arg.dispatcher_(arg.data_, {}, out);
	}

	template <typename Arg>
	static bool Convert(Arg arg, str_format_internal::ConversionSpec conv,
	FormatSinkImpl* out) {
	return arg.dispatcher_(arg.data_, conv, out);
	}

	template <typename Arg>
	static typename Arg::Dispatcher GetVTablePtrForTest(Arg arg) {
	return arg.dispatcher_;
	}
	};

	// A type-erased handle to a format argument.
	class FormatArgImpl {
	private:
	enum { kInlinedSpace = 8 };

	using VoidPtr = str_format_internal::VoidPtr;

	union Data {
	const void* ptr;
	const volatile void* volatile_ptr;
	char buf[kInlinedSpace];
	};

	using Dispatcher = bool ()(Data, ConversionSpec, void out);

	template <typename T>
	struct store_by_value
	: std::integral_constant<bool, (sizeof(T) <= kInlinedSpace) &&
	(std::is_integral<T>::value \|\|
	std::is_floating_point<T>::value \|\|
	std::is_pointer<T>::value \|\|
	std::is_same<VoidPtr, T>::value)> {};

	enum StoragePolicy { ByPointer, ByVolatilePointer, ByValue };
	template <typename T>
	struct storage_policy
	: std::integral_constant<StoragePolicy,
	(std::is_volatile<T>::value
	? ByVolatilePointer
	: (store_by_value<T>::value ? ByValue
	: ByPointer))> {
	};

	// To reduce the number of vtables we will decay values before hand.
	// Anything with a user-defined Convert will get its own vtable.
	// For everything else:
	// - Decay char* and char arrays into `const char*`
	// - Decay any other pointer to `const void*`
	// - Decay all enums to their underlying type.
	// - Decay function pointers to void*.
	template <typename T, typename = void>
	struct DecayType {
	static constexpr bool kHasUserDefined =
	str_format_internal::HasUserDefinedConvert<T>::value;
	using type = typename std::conditional<
	!kHasUserDefined && std::is_convertible<T, const char*>::value,
	const char*,
	typename std::conditional<!kHasUserDefined &&
	std::is_convertible<T, VoidPtr>::value,
	VoidPtr, const T&>::type>::type;
	};
	template <typename T>
	struct DecayType<T,
	typename std::enable_if<
	!str_format_internal::HasUserDefinedConvert<T>::value &&
	std::is_enum<T>::value>::type> {
	using type = typename std::underlying_type<T>::type;
	};

	public:
	template <typename T>
	explicit FormatArgImpl(const T& value) {
	using D = typename DecayType<T>::type;
	static_assert(
	std::is_same<D, const T&>::value \|\| storage_policy<D>::value == ByValue,
	"Decayed types must be stored by value");
	Init(static_cast<D>(value));
	}

	private:
	friend struct str_format_internal::FormatArgImplFriend;
	template <typename T, StoragePolicy = storage_policy<T>::value>
	struct Manager;

	template <typename T>
	struct Manager<T, ByPointer> {
	static Data SetValue(const T& value) {
	Data data;
	data.ptr = &value;
	return data;
	}

	static const T& Value(Data arg) { return static_cast<const T>(arg.ptr); }
	};

	template <typename T>
	struct Manager<T, ByVolatilePointer> {
	static Data SetValue(const T& value) {
	Data data;
	data.volatile_ptr = &value;
	return data;
	}

	static const T& Value(Data arg) {
	return static_cast<const T>(arg.volatile_ptr);
	}
	};

	template <typename T>
	struct Manager<T, ByValue> {
	static Data SetValue(const T& value) {
	Data data;
	memcpy(data.buf, &value, sizeof(value));
	return data;
	}

	static T Value(Data arg) {
	T value;
	memcpy(&value, arg.buf, sizeof(T));
	return value;
	}
	};

	template <typename T>
	void Init(const T& value) {
	data_ = Manager<T>::SetValue(value);
	dispatcher_ = &Dispatch<T>;
	}

	template <typename T>
	static int ToIntVal(const T& val) {
	using CommonType = typename std::conditional<std::is_signed<T>::value,
	int64_t, uint64_t>::type;
	if (static_cast<CommonType>(val) >
	static_cast<CommonType>((std::numeric_limits<int>::max)())) {
	return (std::numeric_limits<int>::max)();
	} else if (std::is_signed<T>::value &&
	static_cast<CommonType>(val) <
	static_cast<CommonType>((std::numeric_limits<int>::min)())) {
	return (std::numeric_limits<int>::min)();
	}
	return static_cast<int>(val);
	}

	template <typename T>
	static bool ToInt(Data arg, int* out, std::true_type /* is_integral */,
	std::false_type) {
	*out = ToIntVal(Manager<T>::Value(arg));
	return true;
	}

	template <typename T>
	static bool ToInt(Data arg, int* out, std::false_type,
	std::true_type /* is_enum */) {
	*out = ToIntVal(static_cast<typename std::underlying_type<T>::type>(
	Manager<T>::Value(arg)));
	return true;
	}

	template <typename T>
	static bool ToInt(Data, int*, std::false_type, std::false_type) {
	return false;
	}

	template <typename T>
	static bool Dispatch(Data arg, ConversionSpec spec, void* out) {
	// A `none` conv indicates that we want the `int` conversion.
	if (ABSL_PREDICT_FALSE(spec.conv().id() == ConversionChar::none)) {
	return ToInt<T>(arg, static_cast<int*>(out), std::is_integral<T>(),
	std::is_enum<T>());
	}

	return str_format_internal::FormatConvertImpl(
	Manager<T>::Value(arg), spec, static_cast<FormatSinkImpl*>(out))
	.value;
	}

	Data data_;
	Dispatcher dispatcher_;
	};

	#define ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(T, E) \
	E template bool FormatArgImpl::Dispatch<T>(Data, ConversionSpec, void*)

	#define ABSL_INTERNAL_FORMAT_DISPATCH_OVERLOADS_EXPAND_(...) \
	ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(str_format_internal::VoidPtr, \
	__VA_ARGS__); \
	ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(bool, __VA_ARGS__); \
	ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(char, __VA_ARGS__); \
	ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(signed char, __VA_ARGS__); \
	ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(unsigned char, __VA_ARGS__); \
	ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(short, __VA_ARGS__); /* NOLINT */ \
	ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(unsigned short, /* NOLINT */ \
	__VA_ARGS__); \
	ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(int, __VA_ARGS__); \
	ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(unsigned int, __VA_ARGS__); \
	ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(long, __VA_ARGS__); /* NOLINT */ \
	ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(unsigned long, /* NOLINT */ \
	__VA_ARGS__); \
	ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(long long, /* NOLINT */ \
	__VA_ARGS__); \
	ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(unsigned long long, /* NOLINT */ \
	__VA_ARGS__); \
	ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(uint128, __VA_ARGS__); \
	ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(float, __VA_ARGS__); \
	ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(double, __VA_ARGS__); \
	ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(long double, __VA_ARGS__); \
	ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(const char*, __VA_ARGS__); \
	ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(std::string, __VA_ARGS__); \
	ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(string_view, __VA_ARGS__)

	ABSL_INTERNAL_FORMAT_DISPATCH_OVERLOADS_EXPAND_(extern);

	} // namespace str_format_internal
	} // inline namespace lts_2018_12_18
	} // namespace absl

	#endif // ABSL_STRINGS_INTERNAL_STR_FORMAT_ARG_H_