// Formatting library for C++
//
// Copyright (c) 2012 - 2016, Victor Zverovich
// All rights reserved.
//
// For the license information refer to format.h.

#ifndef FMT_FORMAT_INL_H_
#define FMT_FORMAT_INL_H_

#include "format.h"

#include <string.h>

#include <cctype>
#include <cerrno>
#include <climits>
#include <cmath>
#include <cstdarg>
#include <cstddef>  // for std::ptrdiff_t
#include <cstring>  // for std::memmove
#if !defined(FMT_STATIC_THOUSANDS_SEPARATOR)
#  include <locale>
#endif

#if FMT_USE_WINDOWS_H
#  if !defined(FMT_HEADER_ONLY) && !defined(WIN32_LEAN_AND_MEAN)
#    define WIN32_LEAN_AND_MEAN
#  endif
#  if defined(NOMINMAX) || defined(FMT_WIN_MINMAX)
#    include <windows.h>
#  else
#    define NOMINMAX
#    include <windows.h>
#    undef NOMINMAX
#  endif
#endif

#if FMT_EXCEPTIONS
#  define FMT_TRY try
#  define FMT_CATCH(x) catch (x)
#else
#  define FMT_TRY if (true)
#  define FMT_CATCH(x) if (false)
#endif

#ifdef _MSC_VER
#  pragma warning(push)
#  pragma warning(disable : 4127)  // conditional expression is constant
#  pragma warning(disable : 4702)  // unreachable code
// Disable deprecation warning for strerror. The latter is not called but
// MSVC fails to detect it.
#  pragma warning(disable : 4996)
#endif

// Dummy implementations of strerror_r and strerror_s called if corresponding
// system functions are not available.
inline fmt::internal::null<> strerror_r(int, char*, ...) {
  return fmt::internal::null<>();
}
inline fmt::internal::null<> strerror_s(char*, std::size_t, ...) {
  return fmt::internal::null<>();
}

FMT_BEGIN_NAMESPACE

namespace {

#ifndef _MSC_VER
#  define FMT_SNPRINTF snprintf
#else  // _MSC_VER
inline int fmt_snprintf(char* buffer, size_t size, const char* format, ...) {
  va_list args;
  va_start(args, format);
  int result = vsnprintf_s(buffer, size, _TRUNCATE, format, args);
  va_end(args);
  return result;
}
#  define FMT_SNPRINTF fmt_snprintf
#endif  // _MSC_VER

#if defined(_WIN32) && defined(__MINGW32__) && !defined(__NO_ISOCEXT)
#  define FMT_SWPRINTF snwprintf
#else
#  define FMT_SWPRINTF swprintf
#endif  // defined(_WIN32) && defined(__MINGW32__) && !defined(__NO_ISOCEXT)

typedef void (*FormatFunc)(internal::buffer<char>&, int, string_view);

// Portable thread-safe version of strerror.
// Sets buffer to point to a string describing the error code.
// This can be either a pointer to a string stored in buffer,
// or a pointer to some static immutable string.
// Returns one of the following values:
//   0      - success
//   ERANGE - buffer is not large enough to store the error message
//   other  - failure
// Buffer should be at least of size 1.
int safe_strerror(int error_code, char*& buffer,
                  std::size_t buffer_size) FMT_NOEXCEPT {
  FMT_ASSERT(buffer != FMT_NULL && buffer_size != 0, "invalid buffer");

  class dispatcher {
   private:
    int error_code_;
    char*& buffer_;
    std::size_t buffer_size_;

    // A noop assignment operator to avoid bogus warnings.
    void operator=(const dispatcher&) {}

    // Handle the result of XSI-compliant version of strerror_r.
    int handle(int result) {
      // glibc versions before 2.13 return result in errno.
      return result == -1 ? errno : result;
    }

    // Handle the result of GNU-specific version of strerror_r.
    int handle(char* message) {
      // If the buffer is full then the message is probably truncated.
      if (message == buffer_ && strlen(buffer_) == buffer_size_ - 1)
        return ERANGE;
      buffer_ = message;
      return 0;
    }

    // Handle the case when strerror_r is not available.
    int handle(internal::null<>) {
      return fallback(strerror_s(buffer_, buffer_size_, error_code_));
    }

    // Fallback to strerror_s when strerror_r is not available.
    int fallback(int result) {
      // If the buffer is full then the message is probably truncated.
      return result == 0 && strlen(buffer_) == buffer_size_ - 1 ? ERANGE
                                                                : result;
    }

#if !FMT_MSC_VER
    // Fallback to strerror if strerror_r and strerror_s are not available.
    int fallback(internal::null<>) {
      errno = 0;
      buffer_ = strerror(error_code_);
      return errno;
    }
#endif

   public:
    dispatcher(int err_code, char*& buf, std::size_t buf_size)
        : error_code_(err_code), buffer_(buf), buffer_size_(buf_size) {}

    int run() { return handle(strerror_r(error_code_, buffer_, buffer_size_)); }
  };
  return dispatcher(error_code, buffer, buffer_size).run();
}

void format_error_code(internal::buffer<char>& out, int error_code,
                       string_view message) FMT_NOEXCEPT {
  // Report error code making sure that the output fits into
  // inline_buffer_size to avoid dynamic memory allocation and potential
  // bad_alloc.
  out.resize(0);
  static const char SEP[] = ": ";
  static const char ERROR_STR[] = "error ";
  // Subtract 2 to account for terminating null characters in SEP and ERROR_STR.
  std::size_t error_code_size = sizeof(SEP) + sizeof(ERROR_STR) - 2;
  typedef internal::int_traits<int>::main_type main_type;
  main_type abs_value = static_cast<main_type>(error_code);
  if (internal::is_negative(error_code)) {
    abs_value = 0 - abs_value;
    ++error_code_size;
  }
  error_code_size += internal::to_unsigned(internal::count_digits(abs_value));
  writer w(out);
  if (message.size() <= inline_buffer_size - error_code_size) {
    w.write(message);
    w.write(SEP);
  }
  w.write(ERROR_STR);
  w.write(error_code);
  assert(out.size() <= inline_buffer_size);
}

// try an fwrite, FMT_THROW on failure
void fwrite_fully(const void* ptr, size_t size, size_t count, FILE* stream) {
  size_t written = std::fwrite(ptr, size, count, stream);
  if (written < count) {
    FMT_THROW(system_error(errno, "cannot write to file"));
  }
}

void report_error(FormatFunc func, int error_code,
                  string_view message) FMT_NOEXCEPT {
  memory_buffer full_message;
  func(full_message, error_code, message);
  // Use Writer::data instead of Writer::c_str to avoid potential memory
  // allocation.
  fwrite_fully(full_message.data(), 1, full_message.size(), stderr);
  std::fputc('\n', stderr);
}
}  // namespace

FMT_FUNC size_t internal::count_code_points(basic_string_view<char8_t> s) {
  const char8_t* data = s.data();
  size_t num_code_points = 0;
  for (size_t i = 0, size = s.size(); i != size; ++i) {
    if ((data[i] & 0xc0) != 0x80) ++num_code_points;
  }
  return num_code_points;
}

#if !defined(FMT_STATIC_THOUSANDS_SEPARATOR)
namespace internal {

template <typename Locale>
locale_ref::locale_ref(const Locale& loc) : locale_(&loc) {
  static_assert(std::is_same<Locale, std::locale>::value, "");
}

template <typename Locale> Locale locale_ref::get() const {
  static_assert(std::is_same<Locale, std::locale>::value, "");
  return locale_ ? *static_cast<const std::locale*>(locale_) : std::locale();
}

template <typename Char> FMT_FUNC Char thousands_sep_impl(locale_ref loc) {
  return std::use_facet<std::numpunct<Char> >(loc.get<std::locale>())
      .thousands_sep();
}
}  // namespace internal
#else
template <typename Char>
FMT_FUNC Char internal::thousands_sep_impl(locale_ref) {
  return FMT_STATIC_THOUSANDS_SEPARATOR;
}
#endif

FMT_FUNC void system_error::init(int err_code, string_view format_str,
                                 format_args args) {
  error_code_ = err_code;
  memory_buffer buffer;
  format_system_error(buffer, err_code, vformat(format_str, args));
  std::runtime_error& base = *this;
  base = std::runtime_error(to_string(buffer));
}

namespace internal {

template <> FMT_FUNC int count_digits<4>(internal::uintptr_t n) {
  // Assume little endian; pointer formatting is implementation-defined anyway.
  int i = static_cast<int>(sizeof(void*)) - 1;
  while (i > 0 && n.value[i] == 0) --i;
  auto char_digits = std::numeric_limits<unsigned char>::digits / 4;
  return i >= 0 ? i * char_digits + count_digits<4, unsigned>(n.value[i]) : 1;
}

template <typename T>
int format_float(char* buf, std::size_t size, const char* format, int precision,
                 T value) {
  return precision < 0 ? FMT_SNPRINTF(buf, size, format, value)
                       : FMT_SNPRINTF(buf, size, format, precision, value);
}

template <typename T>
const char basic_data<T>::DIGITS[] =
    "0001020304050607080910111213141516171819"
    "2021222324252627282930313233343536373839"
    "4041424344454647484950515253545556575859"
    "6061626364656667686970717273747576777879"
    "8081828384858687888990919293949596979899";

template <typename T>
const char basic_data<T>::HEX_DIGITS[] = "0123456789abcdef";

#define FMT_POWERS_OF_10(factor)                                             \
  factor * 10, factor * 100, factor * 1000, factor * 10000, factor * 100000, \
      factor * 1000000, factor * 10000000, factor * 100000000,               \
      factor * 1000000000

template <typename T>
const uint64_t basic_data<T>::POWERS_OF_10_64[] = {
    1, FMT_POWERS_OF_10(1), FMT_POWERS_OF_10(1000000000ull),
    10000000000000000000ull};

template <typename T>
const uint32_t basic_data<T>::ZERO_OR_POWERS_OF_10_32[] = {0,
                                                           FMT_POWERS_OF_10(1)};

template <typename T>
const uint64_t basic_data<T>::ZERO_OR_POWERS_OF_10_64[] = {
    0, FMT_POWERS_OF_10(1), FMT_POWERS_OF_10(1000000000ull),
    10000000000000000000ull};

// Normalized 64-bit significands of pow(10, k), for k = -348, -340, ..., 340.
// These are generated by support/compute-powers.py.
template <typename T>
const uint64_t basic_data<T>::POW10_SIGNIFICANDS[] = {
    0xfa8fd5a0081c0288, 0xbaaee17fa23ebf76, 0x8b16fb203055ac76,
    0xcf42894a5dce35ea, 0x9a6bb0aa55653b2d, 0xe61acf033d1a45df,
    0xab70fe17c79ac6ca, 0xff77b1fcbebcdc4f, 0xbe5691ef416bd60c,
    0x8dd01fad907ffc3c, 0xd3515c2831559a83, 0x9d71ac8fada6c9b5,
    0xea9c227723ee8bcb, 0xaecc49914078536d, 0x823c12795db6ce57,
    0xc21094364dfb5637, 0x9096ea6f3848984f, 0xd77485cb25823ac7,
    0xa086cfcd97bf97f4, 0xef340a98172aace5, 0xb23867fb2a35b28e,
    0x84c8d4dfd2c63f3b, 0xc5dd44271ad3cdba, 0x936b9fcebb25c996,
    0xdbac6c247d62a584, 0xa3ab66580d5fdaf6, 0xf3e2f893dec3f126,
    0xb5b5ada8aaff80b8, 0x87625f056c7c4a8b, 0xc9bcff6034c13053,
    0x964e858c91ba2655, 0xdff9772470297ebd, 0xa6dfbd9fb8e5b88f,
    0xf8a95fcf88747d94, 0xb94470938fa89bcf, 0x8a08f0f8bf0f156b,
    0xcdb02555653131b6, 0x993fe2c6d07b7fac, 0xe45c10c42a2b3b06,
    0xaa242499697392d3, 0xfd87b5f28300ca0e, 0xbce5086492111aeb,
    0x8cbccc096f5088cc, 0xd1b71758e219652c, 0x9c40000000000000,
    0xe8d4a51000000000, 0xad78ebc5ac620000, 0x813f3978f8940984,
    0xc097ce7bc90715b3, 0x8f7e32ce7bea5c70, 0xd5d238a4abe98068,
    0x9f4f2726179a2245, 0xed63a231d4c4fb27, 0xb0de65388cc8ada8,
    0x83c7088e1aab65db, 0xc45d1df942711d9a, 0x924d692ca61be758,
    0xda01ee641a708dea, 0xa26da3999aef774a, 0xf209787bb47d6b85,
    0xb454e4a179dd1877, 0x865b86925b9bc5c2, 0xc83553c5c8965d3d,
    0x952ab45cfa97a0b3, 0xde469fbd99a05fe3, 0xa59bc234db398c25,
    0xf6c69a72a3989f5c, 0xb7dcbf5354e9bece, 0x88fcf317f22241e2,
    0xcc20ce9bd35c78a5, 0x98165af37b2153df, 0xe2a0b5dc971f303a,
    0xa8d9d1535ce3b396, 0xfb9b7cd9a4a7443c, 0xbb764c4ca7a44410,
    0x8bab8eefb6409c1a, 0xd01fef10a657842c, 0x9b10a4e5e9913129,
    0xe7109bfba19c0c9d, 0xac2820d9623bf429, 0x80444b5e7aa7cf85,
    0xbf21e44003acdd2d, 0x8e679c2f5e44ff8f, 0xd433179d9c8cb841,
    0x9e19db92b4e31ba9, 0xeb96bf6ebadf77d9, 0xaf87023b9bf0ee6b,
};

// Binary exponents of pow(10, k), for k = -348, -340, ..., 340, corresponding
// to significands above.
template <typename T>
const int16_t basic_data<T>::POW10_EXPONENTS[] = {
    -1220, -1193, -1166, -1140, -1113, -1087, -1060, -1034, -1007, -980, -954,
    -927,  -901,  -874,  -847,  -821,  -794,  -768,  -741,  -715,  -688, -661,
    -635,  -608,  -582,  -555,  -529,  -502,  -475,  -449,  -422,  -396, -369,
    -343,  -316,  -289,  -263,  -236,  -210,  -183,  -157,  -130,  -103, -77,
    -50,   -24,   3,     30,    56,    83,    109,   136,   162,   189,  216,
    242,   269,   295,   322,   348,   375,   402,   428,   455,   481,  508,
    534,   561,   588,   614,   641,   667,   694,   720,   747,   774,  800,
    827,   853,   880,   907,   933,   960,   986,   1013,  1039,  1066};

template <typename T>
const char basic_data<T>::FOREGROUND_COLOR[] = "\x1b[38;2;";
template <typename T>
const char basic_data<T>::BACKGROUND_COLOR[] = "\x1b[48;2;";
template <typename T> const char basic_data<T>::RESET_COLOR[] = "\x1b[0m";
template <typename T> const wchar_t basic_data<T>::WRESET_COLOR[] = L"\x1b[0m";

template <typename T> struct bits {
  static FMT_CONSTEXPR_DECL const int value =
      static_cast<int>(sizeof(T) * std::numeric_limits<unsigned char>::digits);
};

// A handmade floating-point number f * pow(2, e).
class fp {
 private:
  typedef uint64_t significand_type;

  // All sizes are in bits.
  // Subtract 1 to account for an implicit most significant bit in the
  // normalized form.
  static FMT_CONSTEXPR_DECL const int double_significand_size =
      std::numeric_limits<double>::digits - 1;
  static FMT_CONSTEXPR_DECL const uint64_t implicit_bit =
      1ull << double_significand_size;

 public:
  significand_type f;
  int e;

  static FMT_CONSTEXPR_DECL const int significand_size =
      bits<significand_type>::value;

  fp() : f(0), e(0) {}
  fp(uint64_t f_val, int e_val) : f(f_val), e(e_val) {}

  // Constructs fp from an IEEE754 double. It is a template to prevent compile
  // errors on platforms where double is not IEEE754.
  template <typename Double> explicit fp(Double d) {
    // Assume double is in the format [sign][exponent][significand].
    typedef std::numeric_limits<Double> limits;
    const int exponent_size =
        bits<Double>::value - double_significand_size - 1;  // -1 for sign
    const uint64_t significand_mask = implicit_bit - 1;
    const uint64_t exponent_mask = (~0ull >> 1) & ~significand_mask;
    const int exponent_bias = (1 << exponent_size) - limits::max_exponent - 1;
    auto u = bit_cast<uint64_t>(d);
    auto biased_e = (u & exponent_mask) >> double_significand_size;
    f = u & significand_mask;
    if (biased_e != 0)
      f += implicit_bit;
    else
      biased_e = 1;  // Subnormals use biased exponent 1 (min exponent).
    e = static_cast<int>(biased_e - exponent_bias - double_significand_size);
  }

  // Normalizes the value converted from double and multiplied by (1 << SHIFT).
  template <int SHIFT = 0> void normalize() {
    // Handle subnormals.
    auto shifted_implicit_bit = implicit_bit << SHIFT;
    while ((f & shifted_implicit_bit) == 0) {
      f <<= 1;
      --e;
    }
    // Subtract 1 to account for hidden bit.
    auto offset = significand_size - double_significand_size - SHIFT - 1;
    f <<= offset;
    e -= offset;
  }

  // Compute lower and upper boundaries (m^- and m^+ in the Grisu paper), where
  // a boundary is a value half way between the number and its predecessor
  // (lower) or successor (upper). The upper boundary is normalized and lower
  // has the same exponent but may be not normalized.
  void compute_boundaries(fp& lower, fp& upper) const {
    lower =
        f == implicit_bit ? fp((f << 2) - 1, e - 2) : fp((f << 1) - 1, e - 1);
    upper = fp((f << 1) + 1, e - 1);
    upper.normalize<1>();  // 1 is to account for the exponent shift above.
    lower.f <<= lower.e - upper.e;
    lower.e = upper.e;
  }
};

// Returns an fp number representing x - y. Result may not be normalized.
inline fp operator-(fp x, fp y) {
  FMT_ASSERT(x.f >= y.f && x.e == y.e, "invalid operands");
  return fp(x.f - y.f, x.e);
}

// Computes an fp number r with r.f = x.f * y.f / pow(2, 64) rounded to nearest
// with half-up tie breaking, r.e = x.e + y.e + 64. Result may not be
// normalized.
FMT_FUNC fp operator*(fp x, fp y) {
  int exp = x.e + y.e + 64;
#if FMT_USE_INT128
  auto product = static_cast<__uint128_t>(x.f) * y.f;
  auto f = static_cast<uint64_t>(product >> 64);
  if ((static_cast<uint64_t>(product) & (1ULL << 63)) != 0) ++f;
  return fp(f, exp);
#else
  // Multiply 32-bit parts of significands.
  uint64_t mask = (1ULL << 32) - 1;
  uint64_t a = x.f >> 32, b = x.f & mask;
  uint64_t c = y.f >> 32, d = y.f & mask;
  uint64_t ac = a * c, bc = b * c, ad = a * d, bd = b * d;
  // Compute mid 64-bit of result and round.
  uint64_t mid = (bd >> 32) + (ad & mask) + (bc & mask) + (1U << 31);
  return fp(ac + (ad >> 32) + (bc >> 32) + (mid >> 32), exp);
#endif
}

// Returns cached power (of 10) c_k = c_k.f * pow(2, c_k.e) such that its
// (binary) exponent satisfies min_exponent <= c_k.e <= min_exponent + 28.
FMT_FUNC fp get_cached_power(int min_exponent, int& pow10_exponent) {
  const double one_over_log2_10 = 0.30102999566398114;  // 1 / log2(10)
  int index = static_cast<int>(
      std::ceil((min_exponent + fp::significand_size - 1) * one_over_log2_10));
  // Decimal exponent of the first (smallest) cached power of 10.
  const int first_dec_exp = -348;
  // Difference between 2 consecutive decimal exponents in cached powers of 10.
  const int dec_exp_step = 8;
  index = (index - first_dec_exp - 1) / dec_exp_step + 1;
  pow10_exponent = first_dec_exp + index * dec_exp_step;
  return fp(data::POW10_SIGNIFICANDS[index], data::POW10_EXPONENTS[index]);
}

enum round_direction { unknown, up, down };

// Given the divisor (normally a power of 10), the remainder = v % divisor for
// some number v and the error, returns whether v should be rounded up, down, or
// whether the rounding direction can't be determined due to error.
// error should be less than divisor / 2.
inline round_direction get_round_direction(uint64_t divisor, uint64_t remainder,
                                           uint64_t error) {
  FMT_ASSERT(remainder < divisor, "");  // divisor - remainder won't overflow.
  FMT_ASSERT(error < divisor, "");      // divisor - error won't overflow.
  FMT_ASSERT(error < divisor - error, "");  // error * 2 won't overflow.
  // Round down if (remainder + error) * 2 <= divisor.
  if (remainder <= divisor - remainder && error * 2 <= divisor - remainder * 2)
    return down;
  // Round up if (remainder - error) * 2 >= divisor.
  if (remainder >= error &&
      remainder - error >= divisor - (remainder - error)) {
    return up;
  }
  return unknown;
}

namespace digits {
enum result {
  more,  // Generate more digits.
  done,  // Done generating digits.
  error  // Digit generation cancelled due to an error.
};
}

// Generates output using the Grisu digit-gen algorithm.
// error: the size of the region (lower, upper) outside of which numbers
// definitely do not round to value (Delta in Grisu3).
template <typename Handler>
digits::result grisu_gen_digits(fp value, uint64_t error, int& exp,
                                Handler& handler) {
  fp one(1ull << -value.e, value.e);
  // The integral part of scaled value (p1 in Grisu) = value / one. It cannot be
  // zero because it contains a product of two 64-bit numbers with MSB set (due
  // to normalization) - 1, shifted right by at most 60 bits.
  uint32_t integral = static_cast<uint32_t>(value.f >> -one.e);
  FMT_ASSERT(integral != 0, "");
  FMT_ASSERT(integral == value.f >> -one.e, "");
  // The fractional part of scaled value (p2 in Grisu) c = value % one.
  uint64_t fractional = value.f & (one.f - 1);
  exp = count_digits(integral);  // kappa in Grisu.
  // Divide by 10 to prevent overflow.
  auto result = handler.on_start(data::POWERS_OF_10_64[exp - 1] << -one.e,
                                 value.f / 10, error * 10, exp);
  if (result != digits::more) return result;
  // Generate digits for the integral part. This can produce up to 10 digits.
  do {
    uint32_t digit = 0;
    // This optimization by miloyip reduces the number of integer divisions by
    // one per iteration.
    switch (exp) {
    case 10:
      digit = integral / 1000000000;
      integral %= 1000000000;
      break;
    case 9:
      digit = integral / 100000000;
      integral %= 100000000;
      break;
    case 8:
      digit = integral / 10000000;
      integral %= 10000000;
      break;
    case 7:
      digit = integral / 1000000;
      integral %= 1000000;
      break;
    case 6:
      digit = integral / 100000;
      integral %= 100000;
      break;
    case 5:
      digit = integral / 10000;
      integral %= 10000;
      break;
    case 4:
      digit = integral / 1000;
      integral %= 1000;
      break;
    case 3:
      digit = integral / 100;
      integral %= 100;
      break;
    case 2:
      digit = integral / 10;
      integral %= 10;
      break;
    case 1:
      digit = integral;
      integral = 0;
      break;
    default:
      FMT_ASSERT(false, "invalid number of digits");
    }
    --exp;
    uint64_t remainder =
        (static_cast<uint64_t>(integral) << -one.e) + fractional;
    result = handler.on_digit(static_cast<char>('0' + digit),
                              data::POWERS_OF_10_64[exp] << -one.e, remainder,
                              error, exp, true);
    if (result != digits::more) return result;
  } while (exp > 0);
  // Generate digits for the fractional part.
  for (;;) {
    fractional *= 10;
    error *= 10;
    char digit =
        static_cast<char>('0' + static_cast<char>(fractional >> -one.e));
    fractional &= one.f - 1;
    --exp;
    result = handler.on_digit(digit, one.f, fractional, error, exp, false);
    if (result != digits::more) return result;
  }
}

// The fixed precision digit handler.
struct fixed_handler {
  char* buf;
  int size;
  int precision;
  int exp10;
  bool fixed;

  digits::result on_start(uint64_t divisor, uint64_t remainder, uint64_t error,
                          int& exp) {
    // Non-fixed formats require at least one digit and no precision adjustment.
    if (!fixed) return digits::more;
    // Adjust fixed precision by exponent because it is relative to decimal
    // point.
    precision += exp + exp10;
    // Check if precision is satisfied just by leading zeros, e.g.
    // format("{:.2f}", 0.001) gives "0.00" without generating any digits.
    if (precision > 0) return digits::more;
    auto dir = get_round_direction(divisor, remainder, error);
    if (dir == unknown) return digits::error;
    buf[size++] = dir == up ? '1' : '0';
    return digits::done;
  }

  digits::result on_digit(char digit, uint64_t divisor, uint64_t remainder,
                          uint64_t error, int, bool integral) {
    FMT_ASSERT(remainder < divisor, "");
    buf[size++] = digit;
    if (size < precision) return digits::more;
    if (!integral) {
      // Check if error * 2 < divisor with overflow prevention.
      // The check is not needed for the integral part because error = 1
      // and divisor > (1 << 32) there.
      if (error >= divisor || error >= divisor - error) return digits::error;
    } else {
      FMT_ASSERT(error == 1 && divisor > 2, "");
    }
    auto dir = get_round_direction(divisor, remainder, error);
    if (dir != up) return dir == down ? digits::done : digits::error;
    ++buf[size - 1];
    for (int i = size - 1; i > 0 && buf[i] > '9'; --i) {
      buf[i] = '0';
      ++buf[i - 1];
    }
    if (buf[0] > '9') {
      buf[0] = '1';
      buf[size++] = '0';
    }
    return digits::done;
  }
};

// The shortest representation digit handler.
template <int GRISU_VERSION> struct grisu_shortest_handler {
  char* buf;
  int size;
  // Distance between scaled value and upper bound (wp_W in Grisu3).
  uint64_t diff;

  digits::result on_start(uint64_t, uint64_t, uint64_t, int&) {
    return digits::more;
  }

  // This implements Grisu3's round_weed.
  digits::result on_digit(char digit, uint64_t divisor, uint64_t remainder,
                          uint64_t error, int exp, bool integral) {
    buf[size++] = digit;
    if (remainder >= error) return digits::more;
    if (GRISU_VERSION != 3) {
      uint64_t d = integral ? diff : diff * data::POWERS_OF_10_64[-exp];
      while (remainder < d && error - remainder >= divisor &&
             (remainder + divisor < d ||
              d - remainder >= remainder + divisor - d)) {
        --buf[size - 1];
        remainder += divisor;
      }
      return digits::done;
    }
    uint64_t unit = integral ? 1 : data::POWERS_OF_10_64[-exp];
    uint64_t up = (diff - 1) * unit;  // wp_Wup
    while (remainder < up && error - remainder >= divisor &&
           (remainder + divisor < up ||
            up - remainder >= remainder + divisor - up)) {
      --buf[size - 1];
      remainder += divisor;
    }
    uint64_t down = (diff + 1) * unit;  // wp_Wdown
    if (remainder < down && error - remainder >= divisor &&
        (remainder + divisor < down ||
         down - remainder > remainder + divisor - down)) {
      return digits::error;
    }
    return 2 * unit <= remainder && remainder <= error - 4 * unit
               ? digits::done
               : digits::error;
  }
};

template <typename Double, FMT_ENABLE_IF_T(sizeof(Double) == sizeof(uint64_t))>
FMT_API bool grisu_format(Double value, buffer<char>& buf, int precision,
                          unsigned options, int& exp) {
  FMT_ASSERT(value >= 0, "value is negative");
  bool fixed = (options & grisu_options::fixed) != 0;
  if (value <= 0) {  // <= instead of == to silence a warning.
    if (precision < 0 || !fixed) {
      exp = 0;
      buf.push_back('0');
    } else {
      exp = -precision;
      buf.resize(precision);
      std::uninitialized_fill_n(buf.data(), precision, '0');
    }
    return true;
  }

  fp fp_value(value);
  const int min_exp = -60;  // alpha in Grisu.
  int cached_exp10 = 0;     // K in Grisu.
  if (precision != -1) {
    if (precision > 17) return false;
    fp_value.normalize();
    auto cached_pow = get_cached_power(
        min_exp - (fp_value.e + fp::significand_size), cached_exp10);
    fp_value = fp_value * cached_pow;
    fixed_handler handler{buf.data(), 0, precision, -cached_exp10, fixed};
    if (grisu_gen_digits(fp_value, 1, exp, handler) == digits::error)
      return false;
    buf.resize(to_unsigned(handler.size));
  } else {
    fp lower, upper;  // w^- and w^+ in the Grisu paper.
    fp_value.compute_boundaries(lower, upper);
    // Find a cached power of 10 such that multiplying upper by it will bring
    // the exponent in the range [min_exp, -32].
    auto cached_pow = get_cached_power(  // \tilde{c}_{-k} in Grisu.
        min_exp - (upper.e + fp::significand_size), cached_exp10);
    fp_value.normalize();
    fp_value = fp_value * cached_pow;
    lower = lower * cached_pow;  // \tilde{M}^- in Grisu.
    upper = upper * cached_pow;  // \tilde{M}^+ in Grisu.
    assert(min_exp <= upper.e && upper.e <= -32);
    auto result = digits::result();
    int size = 0;
    if ((options & grisu_options::grisu3) != 0) {
      --lower.f;  // \tilde{M}^- - 1 ulp -> M^-_{\downarrow}.
      ++upper.f;  // \tilde{M}^+ + 1 ulp -> M^+_{\uparrow}.
      // Numbers outside of (lower, upper) definitely do not round to value.
      grisu_shortest_handler<3> handler{buf.data(), 0, (upper - fp_value).f};
      result = grisu_gen_digits(upper, upper.f - lower.f, exp, handler);
      size = handler.size;
    } else {
      ++lower.f;  // \tilde{M}^- + 1 ulp -> M^-_{\uparrow}.
      --upper.f;  // \tilde{M}^+ - 1 ulp -> M^+_{\downarrow}.
      grisu_shortest_handler<2> handler{buf.data(), 0, (upper - fp_value).f};
      result = grisu_gen_digits(upper, upper.f - lower.f, exp, handler);
      size = handler.size;
    }
    if (result == digits::error) return false;
    buf.resize(to_unsigned(size));
  }
  exp -= cached_exp10;
  return true;
}

template <typename Double>
void sprintf_format(Double value, internal::buffer<char>& buf,
                    core_format_specs spec) {
  // Buffer capacity must be non-zero, otherwise MSVC's vsnprintf_s will fail.
  FMT_ASSERT(buf.capacity() != 0, "empty buffer");

  // Build format string.
  enum { max_format_size = 10 };  // longest format: %#-*.*Lg
  char format[max_format_size];
  char* format_ptr = format;
  *format_ptr++ = '%';
  if (spec.has(HASH_FLAG) || !spec.type) *format_ptr++ = '#';
  if (spec.precision >= 0) {
    *format_ptr++ = '.';
    *format_ptr++ = '*';
  }
  if (std::is_same<Double, long double>::value) *format_ptr++ = 'L';

  char type = spec.type;

  if (type == '%')
    type = 'f';
  else if (type == 0)
    type = 'g';
#if FMT_MSC_VER
  if (type == 'F') {
    // MSVC's printf doesn't support 'F'.
    type = 'f';
  }
#endif
  *format_ptr++ = type;
  *format_ptr = '\0';

  // Format using snprintf.
  char* start = FMT_NULL;
  for (;;) {
    std::size_t buffer_size = buf.capacity();
    start = &buf[0];
    int result =
        format_float(start, buffer_size, format, spec.precision, value);
    if (result >= 0) {
      unsigned n = internal::to_unsigned(result);
      if (n < buf.capacity()) {
        // Find the decimal point.
        auto p = buf.data(), end = p + n;
        if (*p == '+' || *p == '-') ++p;
        if (spec.type == 'a' || spec.type == 'A') p += 2;  // Skip "0x".
        while (p < end && *p >= '0' && *p <= '9') ++p;
        if (p < end && *p != 'e' && *p != 'E') {
          if (*p != '.') *p = '.';
          if (!spec.type) {
            // Keep only one trailing zero after the decimal point.
            ++p;
            if (*p == '0') ++p;
            while (p != end && *p >= '1' && *p <= '9') ++p;
            char* where = p;
            while (p != end && *p == '0') ++p;
            if (p == end || *p < '0' || *p > '9') {
              if (p != end) std::memmove(where, p, to_unsigned(end - p));
              n -= static_cast<unsigned>(p - where);
            }
          }
        }
        buf.resize(n);
        break;  // The buffer is large enough - continue with formatting.
      }
      buf.reserve(n + 1);
    } else {
      // If result is negative we ask to increase the capacity by at least 1,
      // but as std::vector, the buffer grows exponentially.
      buf.reserve(buf.capacity() + 1);
    }
  }
}
}  // namespace internal

#if FMT_USE_WINDOWS_H

FMT_FUNC internal::utf8_to_utf16::utf8_to_utf16(string_view s) {
  static const char ERROR_MSG[] = "cannot convert string from UTF-8 to UTF-16";
  if (s.size() > INT_MAX)
    FMT_THROW(windows_error(ERROR_INVALID_PARAMETER, ERROR_MSG));
  int s_size = static_cast<int>(s.size());
  if (s_size == 0) {
    // MultiByteToWideChar does not support zero length, handle separately.
    buffer_.resize(1);
    buffer_[0] = 0;
    return;
  }

  int length = MultiByteToWideChar(CP_UTF8, MB_ERR_INVALID_CHARS, s.data(),
                                   s_size, FMT_NULL, 0);
  if (length == 0) FMT_THROW(windows_error(GetLastError(), ERROR_MSG));
  buffer_.resize(length + 1);
  length = MultiByteToWideChar(CP_UTF8, MB_ERR_INVALID_CHARS, s.data(), s_size,
                               &buffer_[0], length);
  if (length == 0) FMT_THROW(windows_error(GetLastError(), ERROR_MSG));
  buffer_[length] = 0;
}

FMT_FUNC internal::utf16_to_utf8::utf16_to_utf8(wstring_view s) {
  if (int error_code = convert(s)) {
    FMT_THROW(windows_error(error_code,
                            "cannot convert string from UTF-16 to UTF-8"));
  }
}

FMT_FUNC int internal::utf16_to_utf8::convert(wstring_view s) {
  if (s.size() > INT_MAX) return ERROR_INVALID_PARAMETER;
  int s_size = static_cast<int>(s.size());
  if (s_size == 0) {
    // WideCharToMultiByte does not support zero length, handle separately.
    buffer_.resize(1);
    buffer_[0] = 0;
    return 0;
  }

  int length = WideCharToMultiByte(CP_UTF8, 0, s.data(), s_size, FMT_NULL, 0,
                                   FMT_NULL, FMT_NULL);
  if (length == 0) return GetLastError();
  buffer_.resize(length + 1);
  length = WideCharToMultiByte(CP_UTF8, 0, s.data(), s_size, &buffer_[0],
                               length, FMT_NULL, FMT_NULL);
  if (length == 0) return GetLastError();
  buffer_[length] = 0;
  return 0;
}

FMT_FUNC void windows_error::init(int err_code, string_view format_str,
                                  format_args args) {
  error_code_ = err_code;
  memory_buffer buffer;
  internal::format_windows_error(buffer, err_code, vformat(format_str, args));
  std::runtime_error& base = *this;
  base = std::runtime_error(to_string(buffer));
}

FMT_FUNC void internal::format_windows_error(internal::buffer<char>& out,
                                             int error_code,
                                             string_view message) FMT_NOEXCEPT {
  FMT_TRY {
    wmemory_buffer buf;
    buf.resize(inline_buffer_size);
    for (;;) {
      wchar_t* system_message = &buf[0];
      int result = FormatMessageW(
          FORMAT_MESSAGE_FROM_SYSTEM | FORMAT_MESSAGE_IGNORE_INSERTS, FMT_NULL,
          error_code, MAKELANGID(LANG_NEUTRAL, SUBLANG_DEFAULT), system_message,
          static_cast<uint32_t>(buf.size()), FMT_NULL);
      if (result != 0) {
        utf16_to_utf8 utf8_message;
        if (utf8_message.convert(system_message) == ERROR_SUCCESS) {
          writer w(out);
          w.write(message);
          w.write(": ");
          w.write(utf8_message);
          return;
        }
        break;
      }
      if (GetLastError() != ERROR_INSUFFICIENT_BUFFER)
        break;  // Can't get error message, report error code instead.
      buf.resize(buf.size() * 2);
    }
  }
  FMT_CATCH(...) {}
  format_error_code(out, error_code, message);
}

#endif  // FMT_USE_WINDOWS_H

FMT_FUNC void format_system_error(internal::buffer<char>& out, int error_code,
                                  string_view message) FMT_NOEXCEPT {
  FMT_TRY {
    memory_buffer buf;
    buf.resize(inline_buffer_size);
    for (;;) {
      char* system_message = &buf[0];
      int result = safe_strerror(error_code, system_message, buf.size());
      if (result == 0) {
        writer w(out);
        w.write(message);
        w.write(": ");
        w.write(system_message);
        return;
      }
      if (result != ERANGE)
        break;  // Can't get error message, report error code instead.
      buf.resize(buf.size() * 2);
    }
  }
  FMT_CATCH(...) {}
  format_error_code(out, error_code, message);
}

FMT_FUNC void internal::error_handler::on_error(const char* message) {
  FMT_THROW(format_error(message));
}

FMT_FUNC void report_system_error(int error_code,
                                  fmt::string_view message) FMT_NOEXCEPT {
  report_error(format_system_error, error_code, message);
}

#if FMT_USE_WINDOWS_H
FMT_FUNC void report_windows_error(int error_code,
                                   fmt::string_view message) FMT_NOEXCEPT {
  report_error(internal::format_windows_error, error_code, message);
}
#endif

FMT_FUNC void vprint(std::FILE* f, string_view format_str, format_args args) {
  memory_buffer buffer;
  internal::vformat_to(buffer, format_str,
                       basic_format_args<buffer_context<char>::type>(args));
  fwrite_fully(buffer.data(), 1, buffer.size(), f);
}

FMT_FUNC void vprint(std::FILE* f, wstring_view format_str, wformat_args args) {
  wmemory_buffer buffer;
  internal::vformat_to(buffer, format_str, args);
  fwrite_fully(buffer.data(), sizeof(wchar_t), buffer.size(), f);
}

FMT_FUNC void vprint(string_view format_str, format_args args) {
  vprint(stdout, format_str, args);
}

FMT_FUNC void vprint(wstring_view format_str, wformat_args args) {
  vprint(stdout, format_str, args);
}

FMT_END_NAMESPACE

#ifdef _MSC_VER
#  pragma warning(pop)
#endif

#endif  // FMT_FORMAT_INL_H_
