src/__support/integer_to_string.h - llvm-project/libc - Git at Google

 //===-- Utilities to convert integral values to string ----------*- C++ -*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 //
 // Converts an integer to a string.
 //
 // By default, the string is written as decimal to an internal buffer and
 // accessed via the 'view' method.
 //
 //   IntegerToString<int> buffer(42);
 //   cpp::string_view view = buffer.view();
 //
 // The buffer is allocated on the stack and its size is so that the conversion
 // always succeeds.
 //
 // It is also possible to write the data to a preallocated buffer, but this may
 // fail.
 //
 //   char buffer[8];
 //   if (auto maybe_view = IntegerToString<int>::write_to_span(buffer, 42)) {
 //     cpp::string_view view = *maybe_view;
 //   }
 //
 // The first template parameter is the type of the integer.
 // The second template parameter defines how the integer is formatted.
 // Available default are 'radix::Bin', 'radix::Oct', 'radix::Dec' and
 // 'radix::Hex'.
 //
 // For 'radix::Bin', 'radix::Oct' and 'radix::Hex' the value is always
 // interpreted as a positive type but 'radix::Dec' will honor negative values.
 // e.g.,
 //
 //   IntegerToString<int8_t>(-1)             // "-1"
 //   IntegerToString<int8_t, radix::Dec>(-1) // "-1"
 //   IntegerToString<int8_t, radix::Bin>(-1) // "11111111"
 //   IntegerToString<int8_t, radix::Oct>(-1) // "377"
 //   IntegerToString<int8_t, radix::Hex>(-1) // "ff"
 //
 // Additionnally, the format can be changed by navigating the subtypes:
 //  - WithPrefix    : Adds "0b", "0", "0x" for binary, octal and hexadecimal
 //  - WithWidth<XX> : Pad string to XX characters filling leading digits with 0
 //  - Uppercase     : Use uppercase letters (only for HexString)
 //  - WithSign      : Prepend '+' for positive values (only for DecString)
 //
 // Examples
 // --------
 //   IntegerToString<int8_t, radix::Dec::WithWidth<2>::WithSign>(0)     : "+00"
 //   IntegerToString<int8_t, radix::Dec::WithWidth<2>::WithSign>(-1)    : "-01"
 //   IntegerToString<uint8_t, radix::Hex::WithPrefix::Uppercase>(255)   : "0xFF"
 //   IntegerToString<uint8_t, radix::Hex::WithWidth<4>::Uppercase>(255) : "00FF"
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_LIBC_SRC___SUPPORT_INTEGER_TO_STRING_H
 #define LLVM_LIBC_SRC___SUPPORT_INTEGER_TO_STRING_H

 #include <stdint.h>

 #include "src/__support/CPP/algorithm.h" // max
 #include "src/__support/CPP/array.h"
 #include "src/__support/CPP/bit.h"
 #include "src/__support/CPP/limits.h"
 #include "src/__support/CPP/optional.h"
 #include "src/__support/CPP/span.h"
 #include "src/__support/CPP/string_view.h"
 #include "src/__support/CPP/type_traits.h"
 #include "src/__support/big_int.h" // make_integral_or_big_int_unsigned_t
 #include "src/__support/common.h"

 namespace LIBC_NAMESPACE {

 namespace details {

 template <uint8_t base, bool prefix = false, bool force_sign = false,
           bool is_uppercase = false, size_t min_digits = 1>
 struct Fmt {
   static constexpr uint8_t BASE = base;
   static constexpr size_t MIN_DIGITS = min_digits;
   static constexpr bool IS_UPPERCASE = is_uppercase;
   static constexpr bool PREFIX = prefix;
   static constexpr char FORCE_SIGN = force_sign;

   using WithPrefix = Fmt<BASE, true, FORCE_SIGN, IS_UPPERCASE, MIN_DIGITS>;
   using WithSign = Fmt<BASE, PREFIX, true, IS_UPPERCASE, MIN_DIGITS>;
   using Uppercase = Fmt<BASE, PREFIX, FORCE_SIGN, true, MIN_DIGITS>;
   template <size_t value>
   using WithWidth = Fmt<BASE, PREFIX, FORCE_SIGN, IS_UPPERCASE, value>;

   // Invariants
   static constexpr uint8_t NUMERICAL_DIGITS = 10;
   static constexpr uint8_t ALPHA_DIGITS = 26;
   static constexpr uint8_t MAX_DIGIT = NUMERICAL_DIGITS + ALPHA_DIGITS;
   static_assert(BASE > 1 && BASE <= MAX_DIGIT);
   static_assert(!IS_UPPERCASE || BASE > 10, "Uppercase is only for radix > 10");
   static_assert(!FORCE_SIGN || BASE == 10, "WithSign is only for radix == 10");
   static_assert(!PREFIX || (BASE == 2 || BASE == 8 || BASE == 16),
                 "WithPrefix is only for radix == 2, 8 or 16");
 };

 // Move this to a separate header since it might be useful elsewhere.
 template <bool forward> class StringBufferWriterImpl {
   cpp::span<char> buffer;
   size_t index = 0;
   bool out_of_range = false;

   LIBC_INLINE size_t location() const {
     return forward ? index : buffer.size() - 1 - index;
   }

 public:
   StringBufferWriterImpl(const StringBufferWriterImpl &) = delete;
   StringBufferWriterImpl(cpp::span<char> buffer) : buffer(buffer) {}

   LIBC_INLINE size_t size() const { return index; }
   LIBC_INLINE size_t remainder_size() const { return buffer.size() - size(); }
   LIBC_INLINE bool empty() const { return size() == 0; }
   LIBC_INLINE bool full() const { return size() == buffer.size(); }
   LIBC_INLINE bool ok() const { return !out_of_range; }

   LIBC_INLINE StringBufferWriterImpl &push(char c) {
     if (ok()) {
       if (!full()) {
         buffer[location()] = c;
         ++index;
       } else {
         out_of_range = true;
       }
     }
     return *this;
   }

   LIBC_INLINE cpp::span<char> remainder_span() const {
     return forward ? buffer.last(remainder_size())
                    : buffer.first(remainder_size());
   }

   LIBC_INLINE cpp::span<char> buffer_span() const {
     return forward ? buffer.first(size()) : buffer.last(size());
   }

   LIBC_INLINE cpp::string_view buffer_view() const {
     const auto s = buffer_span();
     return {s.data(), s.size()};
   }
 };

 using StringBufferWriter = StringBufferWriterImpl<true>;
 using BackwardStringBufferWriter = StringBufferWriterImpl<false>;

 } // namespace details

 namespace radix {

 using Bin = details::Fmt<2>;
 using Oct = details::Fmt<8>;
 using Dec = details::Fmt<10>;
 using Hex = details::Fmt<16>;
 template <size_t radix> using Custom = details::Fmt<radix>;

 } // namespace radix

 // See file header for documentation.
 template <typename T, typename Fmt = radix::Dec> class IntegerToString {
   static_assert(cpp::is_integral_v<T> || is_big_int_v<T>);

   LIBC_INLINE static constexpr size_t compute_buffer_size() {
     constexpr auto MAX_DIGITS = []() -> size_t {
       // We size the string buffer for base 10 using an approximation algorithm:
       //
       //   size = ceil(sizeof(T) * 5 / 2)
       //
       // If sizeof(T) is 1, then size is 3 (actually need 3)
       // If sizeof(T) is 2, then size is 5 (actually need 5)
       // If sizeof(T) is 4, then size is 10 (actually need 10)
       // If sizeof(T) is 8, then size is 20 (actually need 20)
       // If sizeof(T) is 16, then size is 40 (actually need 39)
       //
       // NOTE: The ceil operation is actually implemented as
       //     floor(((sizeof(T) * 5) + 1) / 2)
       // where floor operation is just integer division.
       //
       // This estimation grows slightly faster than the actual value, but the
       // overhead is small enough to tolerate.
       if constexpr (Fmt::BASE == 10)
         return ((sizeof(T) * 5) + 1) / 2;
       // For other bases, we approximate by rounding down to the nearest power
       // of two base, since the space needed is easy to calculate and it won't
       // overestimate by too much.
       constexpr auto FLOOR_LOG_2 = [](size_t num) -> size_t {
         size_t i = 0;
         for (; num > 1; num /= 2)
           ++i;
         return i;
       };
       constexpr size_t BITS_PER_DIGIT = FLOOR_LOG_2(Fmt::BASE);
       return ((sizeof(T) * 8 + (BITS_PER_DIGIT - 1)) / BITS_PER_DIGIT);
     };
     constexpr size_t DIGIT_SIZE = cpp::max(MAX_DIGITS(), Fmt::MIN_DIGITS);
     constexpr size_t SIGN_SIZE = Fmt::BASE == 10 ? 1 : 0;
     constexpr size_t PREFIX_SIZE = Fmt::PREFIX ? 2 : 0;
     return DIGIT_SIZE + SIGN_SIZE + PREFIX_SIZE;
   }

   static constexpr size_t BUFFER_SIZE = compute_buffer_size();
   static_assert(BUFFER_SIZE > 0);

   // An internal stateless structure that handles the number formatting logic.
   struct IntegerWriter {
     static_assert(cpp::is_integral_v<T> || is_big_int_v<T>);
     using UNSIGNED_T = make_integral_or_big_int_unsigned_t<T>;

     LIBC_INLINE static char digit_char(uint8_t digit) {
       if (digit < 10)
         return '0' + static_cast<char>(digit);
       return (Fmt::IS_UPPERCASE ? 'A' : 'a') + static_cast<char>(digit - 10);
     }

     LIBC_INLINE static void
     write_unsigned_number(UNSIGNED_T value,
                           details::BackwardStringBufferWriter &sink) {
       for (; sink.ok() && value != 0; value /= Fmt::BASE) {
         const uint8_t digit(static_cast<uint8_t>(value % Fmt::BASE));
         sink.push(digit_char(digit));
       }
     }

     // Returns the absolute value of 'value' as 'UNSIGNED_T'.
     LIBC_INLINE static UNSIGNED_T abs(T value) {
       if (cpp::is_unsigned_v<T> || value >= 0)
         return value; // already of the right sign.

       // Signed integers are asymmetric (e.g., int8_t ∈ [-128, 127]).
       // Thus negating the type's minimum value would overflow.
       // From C++20 on, signed types are guaranteed to be represented as 2's
       // complement. We take advantage of this representation and negate the
       // value by using the exact same bit representation, e.g.,
       // binary : 0b1000'0000
       // int8_t : -128
       // uint8_t:  128

       // Note: the compiler can completely optimize out the two branches and
       // replace them by a simple negate instruction.
       // https://godbolt.org/z/hE7zahT9W
       if (value == cpp::numeric_limits<T>::min()) {
         return cpp::bit_cast<UNSIGNED_T>(value);
       } else {
         return -value; // legal and representable both as T and UNSIGNED_T.`
       }
     }

     LIBC_INLINE static void write(T value,
                                   details::BackwardStringBufferWriter &sink) {
       if constexpr (Fmt::BASE == 10) {
         write_unsigned_number(abs(value), sink);
       } else {
         write_unsigned_number(static_cast<UNSIGNED_T>(value), sink);
       }
       // width
       while (sink.ok() && sink.size() < Fmt::MIN_DIGITS)
         sink.push('0');
       // sign
       if constexpr (Fmt::BASE == 10) {
         if (value < 0)
           sink.push('-');
         else if (Fmt::FORCE_SIGN)
           sink.push('+');
       }
       // prefix
       if constexpr (Fmt::PREFIX) {
         if constexpr (Fmt::BASE == 2) {
           sink.push('b');
           sink.push('0');
         }
         if constexpr (Fmt::BASE == 16) {
           sink.push('x');
           sink.push('0');
         }
         if constexpr (Fmt::BASE == 8) {
           const cpp::string_view written = sink.buffer_view();
           if (written.empty() || written.front() != '0')
             sink.push('0');
         }
       }
     }
   };

   cpp::array<char, BUFFER_SIZE> array;
   size_t written = 0;

 public:
   IntegerToString(const IntegerToString &) = delete;
   IntegerToString(T value) {
     details::BackwardStringBufferWriter writer(array);
     IntegerWriter::write(value, writer);
     written = writer.size();
   }

   [[nodiscard]] LIBC_INLINE static cpp::optional<cpp::string_view>
   format_to(cpp::span<char> buffer, T value) {
     details::BackwardStringBufferWriter writer(buffer);
     IntegerWriter::write(value, writer);
     if (writer.ok())
       return cpp::string_view(buffer.data() + buffer.size() - writer.size(),
                               writer.size());
     return cpp::nullopt;
   }

   LIBC_INLINE static constexpr size_t buffer_size() { return BUFFER_SIZE; }

   LIBC_INLINE size_t size() const { return written; }
   LIBC_INLINE cpp::string_view view() && = delete;
   LIBC_INLINE cpp::string_view view() const & {
     return cpp::string_view(array.data() + array.size() - size(), size());
   }
 };

 } // namespace LIBC_NAMESPACE

 #endif // LLVM_LIBC_SRC___SUPPORT_INTEGER_TO_STRING_H
	//===-- Utilities to convert integral values to string ----------- C++ --===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	//
	// Converts an integer to a string.
	//
	// By default, the string is written as decimal to an internal buffer and
	// accessed via the 'view' method.
	//
	// IntegerToString<int> buffer(42);
	// cpp::string_view view = buffer.view();
	//
	// The buffer is allocated on the stack and its size is so that the conversion
	// always succeeds.
	//
	// It is also possible to write the data to a preallocated buffer, but this may
	// fail.
	//
	// char buffer[8];
	// if (auto maybe_view = IntegerToString<int>::write_to_span(buffer, 42)) {
	// cpp::string_view view = *maybe_view;
	// }
	//
	// The first template parameter is the type of the integer.
	// The second template parameter defines how the integer is formatted.
	// Available default are 'radix::Bin', 'radix::Oct', 'radix::Dec' and
	// 'radix::Hex'.
	//
	// For 'radix::Bin', 'radix::Oct' and 'radix::Hex' the value is always
	// interpreted as a positive type but 'radix::Dec' will honor negative values.
	// e.g.,
	//
	// IntegerToString<int8_t>(-1) // "-1"
	// IntegerToString<int8_t, radix::Dec>(-1) // "-1"
	// IntegerToString<int8_t, radix::Bin>(-1) // "11111111"
	// IntegerToString<int8_t, radix::Oct>(-1) // "377"
	// IntegerToString<int8_t, radix::Hex>(-1) // "ff"
	//
	// Additionnally, the format can be changed by navigating the subtypes:
	// - WithPrefix : Adds "0b", "0", "0x" for binary, octal and hexadecimal
	// - WithWidth<XX> : Pad string to XX characters filling leading digits with 0
	// - Uppercase : Use uppercase letters (only for HexString)
	// - WithSign : Prepend '+' for positive values (only for DecString)
	//
	// Examples
	// --------
	// IntegerToString<int8_t, radix::Dec::WithWidth<2>::WithSign>(0) : "+00"
	// IntegerToString<int8_t, radix::Dec::WithWidth<2>::WithSign>(-1) : "-01"
	// IntegerToString<uint8_t, radix::Hex::WithPrefix::Uppercase>(255) : "0xFF"
	// IntegerToString<uint8_t, radix::Hex::WithWidth<4>::Uppercase>(255) : "00FF"
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_LIBC_SRC___SUPPORT_INTEGER_TO_STRING_H
	#define LLVM_LIBC_SRC___SUPPORT_INTEGER_TO_STRING_H

	#include <stdint.h>

	#include "src/__support/CPP/algorithm.h" // max
	#include "src/__support/CPP/array.h"
	#include "src/__support/CPP/bit.h"
	#include "src/__support/CPP/limits.h"
	#include "src/__support/CPP/optional.h"
	#include "src/__support/CPP/span.h"
	#include "src/__support/CPP/string_view.h"
	#include "src/__support/CPP/type_traits.h"
	#include "src/__support/big_int.h" // make_integral_or_big_int_unsigned_t
	#include "src/__support/common.h"

	namespace LIBC_NAMESPACE {

	namespace details {

	template <uint8_t base, bool prefix = false, bool force_sign = false,
	bool is_uppercase = false, size_t min_digits = 1>
	struct Fmt {
	static constexpr uint8_t BASE = base;
	static constexpr size_t MIN_DIGITS = min_digits;
	static constexpr bool IS_UPPERCASE = is_uppercase;
	static constexpr bool PREFIX = prefix;
	static constexpr char FORCE_SIGN = force_sign;

	using WithPrefix = Fmt<BASE, true, FORCE_SIGN, IS_UPPERCASE, MIN_DIGITS>;
	using WithSign = Fmt<BASE, PREFIX, true, IS_UPPERCASE, MIN_DIGITS>;
	using Uppercase = Fmt<BASE, PREFIX, FORCE_SIGN, true, MIN_DIGITS>;
	template <size_t value>
	using WithWidth = Fmt<BASE, PREFIX, FORCE_SIGN, IS_UPPERCASE, value>;

	// Invariants
	static constexpr uint8_t NUMERICAL_DIGITS = 10;
	static constexpr uint8_t ALPHA_DIGITS = 26;
	static constexpr uint8_t MAX_DIGIT = NUMERICAL_DIGITS + ALPHA_DIGITS;
	static_assert(BASE > 1 && BASE <= MAX_DIGIT);
	static_assert(!IS_UPPERCASE \|\| BASE > 10, "Uppercase is only for radix > 10");
	static_assert(!FORCE_SIGN \|\| BASE == 10, "WithSign is only for radix == 10");
	static_assert(!PREFIX \|\| (BASE == 2 \|\| BASE == 8 \|\| BASE == 16),
	"WithPrefix is only for radix == 2, 8 or 16");
	};

	// Move this to a separate header since it might be useful elsewhere.
	template <bool forward> class StringBufferWriterImpl {
	cpp::span<char> buffer;
	size_t index = 0;
	bool out_of_range = false;

	LIBC_INLINE size_t location() const {
	return forward ? index : buffer.size() - 1 - index;
	}

	public:
	StringBufferWriterImpl(const StringBufferWriterImpl &) = delete;
	StringBufferWriterImpl(cpp::span<char> buffer) : buffer(buffer) {}

	LIBC_INLINE size_t size() const { return index; }
	LIBC_INLINE size_t remainder_size() const { return buffer.size() - size(); }
	LIBC_INLINE bool empty() const { return size() == 0; }
	LIBC_INLINE bool full() const { return size() == buffer.size(); }
	LIBC_INLINE bool ok() const { return !out_of_range; }

	LIBC_INLINE StringBufferWriterImpl &push(char c) {
	if (ok()) {
	if (!full()) {
	buffer[location()] = c;
	++index;
	} else {
	out_of_range = true;
	}
	}
	return *this;
	}

	LIBC_INLINE cpp::span<char> remainder_span() const {
	return forward ? buffer.last(remainder_size())
	: buffer.first(remainder_size());
	}

	LIBC_INLINE cpp::span<char> buffer_span() const {
	return forward ? buffer.first(size()) : buffer.last(size());
	}

	LIBC_INLINE cpp::string_view buffer_view() const {
	const auto s = buffer_span();
	return {s.data(), s.size()};
	}
	};

	using StringBufferWriter = StringBufferWriterImpl<true>;
	using BackwardStringBufferWriter = StringBufferWriterImpl<false>;

	} // namespace details

	namespace radix {

	using Bin = details::Fmt<2>;
	using Oct = details::Fmt<8>;
	using Dec = details::Fmt<10>;
	using Hex = details::Fmt<16>;
	template <size_t radix> using Custom = details::Fmt<radix>;

	} // namespace radix

	// See file header for documentation.
	template <typename T, typename Fmt = radix::Dec> class IntegerToString {
	static_assert(cpp::is_integral_v<T> \|\| is_big_int_v<T>);

	LIBC_INLINE static constexpr size_t compute_buffer_size() {
	constexpr auto MAX_DIGITS = []() -> size_t {
	// We size the string buffer for base 10 using an approximation algorithm:
	//
	// size = ceil(sizeof(T) * 5 / 2)
	//
	// If sizeof(T) is 1, then size is 3 (actually need 3)
	// If sizeof(T) is 2, then size is 5 (actually need 5)
	// If sizeof(T) is 4, then size is 10 (actually need 10)
	// If sizeof(T) is 8, then size is 20 (actually need 20)
	// If sizeof(T) is 16, then size is 40 (actually need 39)
	//
	// NOTE: The ceil operation is actually implemented as
	// floor(((sizeof(T) * 5) + 1) / 2)
	// where floor operation is just integer division.
	//
	// This estimation grows slightly faster than the actual value, but the
	// overhead is small enough to tolerate.
	if constexpr (Fmt::BASE == 10)
	return ((sizeof(T) * 5) + 1) / 2;
	// For other bases, we approximate by rounding down to the nearest power
	// of two base, since the space needed is easy to calculate and it won't
	// overestimate by too much.
	constexpr auto FLOOR_LOG_2 = [](size_t num) -> size_t {
	size_t i = 0;
	for (; num > 1; num /= 2)
	++i;
	return i;
	};
	constexpr size_t BITS_PER_DIGIT = FLOOR_LOG_2(Fmt::BASE);
	return ((sizeof(T) * 8 + (BITS_PER_DIGIT - 1)) / BITS_PER_DIGIT);
	};
	constexpr size_t DIGIT_SIZE = cpp::max(MAX_DIGITS(), Fmt::MIN_DIGITS);
	constexpr size_t SIGN_SIZE = Fmt::BASE == 10 ? 1 : 0;
	constexpr size_t PREFIX_SIZE = Fmt::PREFIX ? 2 : 0;
	return DIGIT_SIZE + SIGN_SIZE + PREFIX_SIZE;
	}

	static constexpr size_t BUFFER_SIZE = compute_buffer_size();
	static_assert(BUFFER_SIZE > 0);

	// An internal stateless structure that handles the number formatting logic.
	struct IntegerWriter {
	static_assert(cpp::is_integral_v<T> \|\| is_big_int_v<T>);
	using UNSIGNED_T = make_integral_or_big_int_unsigned_t<T>;

	LIBC_INLINE static char digit_char(uint8_t digit) {
	if (digit < 10)
	return '0' + static_cast<char>(digit);
	return (Fmt::IS_UPPERCASE ? 'A' : 'a') + static_cast<char>(digit - 10);
	}

	LIBC_INLINE static void
	write_unsigned_number(UNSIGNED_T value,
	details::BackwardStringBufferWriter &sink) {
	for (; sink.ok() && value != 0; value /= Fmt::BASE) {
	const uint8_t digit(static_cast<uint8_t>(value % Fmt::BASE));
	sink.push(digit_char(digit));
	}
	}

	// Returns the absolute value of 'value' as 'UNSIGNED_T'.
	LIBC_INLINE static UNSIGNED_T abs(T value) {
	if (cpp::is_unsigned_v<T> \|\| value >= 0)
	return value; // already of the right sign.

	// Signed integers are asymmetric (e.g., int8_t ∈ [-128, 127]).
	// Thus negating the type's minimum value would overflow.
	// From C++20 on, signed types are guaranteed to be represented as 2's
	// complement. We take advantage of this representation and negate the
	// value by using the exact same bit representation, e.g.,
	// binary : 0b1000'0000
	// int8_t : -128
	// uint8_t: 128

	// Note: the compiler can completely optimize out the two branches and
	// replace them by a simple negate instruction.
	// https://godbolt.org/z/hE7zahT9W
	if (value == cpp::numeric_limits<T>::min()) {
	return cpp::bit_cast<UNSIGNED_T>(value);
	} else {
	return -value; // legal and representable both as T and UNSIGNED_T.`
	}
	}

	LIBC_INLINE static void write(T value,
	details::BackwardStringBufferWriter &sink) {
	if constexpr (Fmt::BASE == 10) {
	write_unsigned_number(abs(value), sink);
	} else {
	write_unsigned_number(static_cast<UNSIGNED_T>(value), sink);
	}
	// width
	while (sink.ok() && sink.size() < Fmt::MIN_DIGITS)
	sink.push('0');
	// sign
	if constexpr (Fmt::BASE == 10) {
	if (value < 0)
	sink.push('-');
	else if (Fmt::FORCE_SIGN)
	sink.push('+');
	}
	// prefix
	if constexpr (Fmt::PREFIX) {
	if constexpr (Fmt::BASE == 2) {
	sink.push('b');
	sink.push('0');
	}
	if constexpr (Fmt::BASE == 16) {
	sink.push('x');
	sink.push('0');
	}
	if constexpr (Fmt::BASE == 8) {
	const cpp::string_view written = sink.buffer_view();
	if (written.empty() \|\| written.front() != '0')
	sink.push('0');
	}
	}
	}
	};

	cpp::array<char, BUFFER_SIZE> array;
	size_t written = 0;

	public:
	IntegerToString(const IntegerToString &) = delete;
	IntegerToString(T value) {
	details::BackwardStringBufferWriter writer(array);
	IntegerWriter::write(value, writer);
	written = writer.size();
	}

	[[nodiscard]] LIBC_INLINE static cpp::optional<cpp::string_view>
	format_to(cpp::span<char> buffer, T value) {
	details::BackwardStringBufferWriter writer(buffer);
	IntegerWriter::write(value, writer);
	if (writer.ok())
	return cpp::string_view(buffer.data() + buffer.size() - writer.size(),
	writer.size());
	return cpp::nullopt;
	}

	LIBC_INLINE static constexpr size_t buffer_size() { return BUFFER_SIZE; }

	LIBC_INLINE size_t size() const { return written; }
	LIBC_INLINE cpp::string_view view() && = delete;
	LIBC_INLINE cpp::string_view view() const & {
	return cpp::string_view(array.data() + array.size() - size(), size());
	}
	};

	} // namespace LIBC_NAMESPACE

	#endif // LLVM_LIBC_SRC___SUPPORT_INTEGER_TO_STRING_H