// Copyright 2018 The Abseil Authors. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // https://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #include "y_absl/strings/charconv.h" #include #include #include #include #include #include "y_absl/base/casts.h" #include "y_absl/base/config.h" #include "y_absl/numeric/bits.h" #include "y_absl/numeric/int128.h" #include "y_absl/strings/internal/charconv_bigint.h" #include "y_absl/strings/internal/charconv_parse.h" // The macro Y_ABSL_BIT_PACK_FLOATS is defined on x86-64, where IEEE floating // point numbers have the same endianness in memory as a bitfield struct // containing the corresponding parts. // // When set, we replace calls to ldexp() with manual bit packing, which is // faster and is unaffected by floating point environment. #ifdef Y_ABSL_BIT_PACK_FLOATS #error Y_ABSL_BIT_PACK_FLOATS cannot be directly set #elif defined(__x86_64__) || defined(_M_X64) #define Y_ABSL_BIT_PACK_FLOATS 1 #endif // A note about subnormals: // // The code below talks about "normals" and "subnormals". A normal IEEE float // has a fixed-width mantissa and power of two exponent. For example, a normal // `double` has a 53-bit mantissa. Because the high bit is always 1, it is not // stored in the representation. The implicit bit buys an extra bit of // resolution in the datatype. // // The downside of this scheme is that there is a large gap between DBL_MIN and // zero. (Large, at least, relative to the different between DBL_MIN and the // next representable number). This gap is softened by the "subnormal" numbers, // which have the same power-of-two exponent as DBL_MIN, but no implicit 53rd // bit. An all-bits-zero exponent in the encoding represents subnormals. (Zero // is represented as a subnormal with an all-bits-zero mantissa.) // // The code below, in calculations, represents the mantissa as a uint64_t. The // end result normally has the 53rd bit set. It represents subnormals by using // narrower mantissas. namespace y_absl { Y_ABSL_NAMESPACE_BEGIN namespace { template struct FloatTraits; template <> struct FloatTraits { using mantissa_t = uint64_t; // The number of bits in the given float type. static constexpr int kTargetBits = 64; // The number of exponent bits in the given float type. static constexpr int kTargetExponentBits = 11; // The number of mantissa bits in the given float type. This includes the // implied high bit. static constexpr int kTargetMantissaBits = 53; // The largest supported IEEE exponent, in our integral mantissa // representation. // // If `m` is the largest possible int kTargetMantissaBits bits wide, then // m * 2**kMaxExponent is exactly equal to DBL_MAX. static constexpr int kMaxExponent = 971; // The smallest supported IEEE normal exponent, in our integral mantissa // representation. // // If `m` is the smallest possible int kTargetMantissaBits bits wide, then // m * 2**kMinNormalExponent is exactly equal to DBL_MIN. static constexpr int kMinNormalExponent = -1074; // The IEEE exponent bias. It equals ((1 << (kTargetExponentBits - 1)) - 1). static constexpr int kExponentBias = 1023; // The Eisel-Lemire "Shifting to 54/25 Bits" adjustment. It equals (63 - 1 - // kTargetMantissaBits). static constexpr int kEiselLemireShift = 9; // The Eisel-Lemire high64_mask. It equals ((1 << kEiselLemireShift) - 1). static constexpr uint64_t kEiselLemireMask = uint64_t{0x1FF}; // The smallest negative integer N (smallest negative means furthest from // zero) such that parsing 9999999999999999999eN, with 19 nines, is still // positive. Parsing a smaller (more negative) N will produce zero. // // Adjusting the decimal point and exponent, without adjusting the value, // 9999999999999999999eN equals 9.999999999999999999eM where M = N + 18. // // 9999999999999999999, with 19 nines but no decimal point, is the largest // "repeated nines" integer that fits in a uint64_t. static constexpr int kEiselLemireMinInclusiveExp10 = -324 - 18; // The smallest positive integer N such that parsing 1eN produces infinity. // Parsing a smaller N will produce something finite. static constexpr int kEiselLemireMaxExclusiveExp10 = 309; static double MakeNan(const char* tagp) { #if Y_ABSL_HAVE_BUILTIN(__builtin_nan) // Use __builtin_nan() if available since it has a fix for // https://bugs.llvm.org/show_bug.cgi?id=37778 // std::nan may use the glibc implementation. return __builtin_nan(tagp); #else // Support nan no matter which namespace it's in. Some platforms // incorrectly don't put it in namespace std. using namespace std; // NOLINT return nan(tagp); #endif } // Builds a nonzero floating point number out of the provided parts. // // This is intended to do the same operation as ldexp(mantissa, exponent), // but using purely integer math, to avoid -ffastmath and floating // point environment issues. Using type punning is also faster. We fall back // to ldexp on a per-platform basis for portability. // // `exponent` must be between kMinNormalExponent and kMaxExponent. // // `mantissa` must either be exactly kTargetMantissaBits wide, in which case // a normal value is made, or it must be less narrow than that, in which case // `exponent` must be exactly kMinNormalExponent, and a subnormal value is // made. static double Make(mantissa_t mantissa, int exponent, bool sign) { #ifndef Y_ABSL_BIT_PACK_FLOATS // Support ldexp no matter which namespace it's in. Some platforms // incorrectly don't put it in namespace std. using namespace std; // NOLINT return sign ? -ldexp(mantissa, exponent) : ldexp(mantissa, exponent); #else constexpr uint64_t kMantissaMask = (uint64_t{1} << (kTargetMantissaBits - 1)) - 1; uint64_t dbl = static_cast(sign) << 63; if (mantissa > kMantissaMask) { // Normal value. // Adjust by 1023 for the exponent representation bias, and an additional // 52 due to the implied decimal point in the IEEE mantissa // representation. dbl += static_cast(exponent + 1023 + kTargetMantissaBits - 1) << 52; mantissa &= kMantissaMask; } else { // subnormal value assert(exponent == kMinNormalExponent); } dbl += mantissa; return y_absl::bit_cast(dbl); #endif // Y_ABSL_BIT_PACK_FLOATS } }; // Specialization of floating point traits for the `float` type. See the // FloatTraits specialization above for meaning of each of the following // members and methods. template <> struct FloatTraits { using mantissa_t = uint32_t; static constexpr int kTargetBits = 32; static constexpr int kTargetExponentBits = 8; static constexpr int kTargetMantissaBits = 24; static constexpr int kMaxExponent = 104; static constexpr int kMinNormalExponent = -149; static constexpr int kExponentBias = 127; static constexpr int kEiselLemireShift = 38; static constexpr uint64_t kEiselLemireMask = uint64_t{0x3FFFFFFFFF}; static constexpr int kEiselLemireMinInclusiveExp10 = -46 - 18; static constexpr int kEiselLemireMaxExclusiveExp10 = 39; static float MakeNan(const char* tagp) { #if Y_ABSL_HAVE_BUILTIN(__builtin_nanf) // Use __builtin_nanf() if available since it has a fix for // https://bugs.llvm.org/show_bug.cgi?id=37778 // std::nanf may use the glibc implementation. return __builtin_nanf(tagp); #else // Support nanf no matter which namespace it's in. Some platforms // incorrectly don't put it in namespace std. using namespace std; // NOLINT return std::nanf(tagp); #endif } static float Make(mantissa_t mantissa, int exponent, bool sign) { #ifndef Y_ABSL_BIT_PACK_FLOATS // Support ldexpf no matter which namespace it's in. Some platforms // incorrectly don't put it in namespace std. using namespace std; // NOLINT return sign ? -ldexpf(mantissa, exponent) : ldexpf(mantissa, exponent); #else constexpr uint32_t kMantissaMask = (uint32_t{1} << (kTargetMantissaBits - 1)) - 1; uint32_t flt = static_cast(sign) << 31; if (mantissa > kMantissaMask) { // Normal value. // Adjust by 127 for the exponent representation bias, and an additional // 23 due to the implied decimal point in the IEEE mantissa // representation. flt += static_cast(exponent + 127 + kTargetMantissaBits - 1) << 23; mantissa &= kMantissaMask; } else { // subnormal value assert(exponent == kMinNormalExponent); } flt += mantissa; return y_absl::bit_cast(flt); #endif // Y_ABSL_BIT_PACK_FLOATS } }; // Decimal-to-binary conversions require coercing powers of 10 into a mantissa // and a power of 2. The two helper functions Power10Mantissa(n) and // Power10Exponent(n) perform this task. Together, these represent a hand- // rolled floating point value which is equal to or just less than 10**n. // // The return values satisfy two range guarantees: // // Power10Mantissa(n) * 2**Power10Exponent(n) <= 10**n // < (Power10Mantissa(n) + 1) * 2**Power10Exponent(n) // // 2**63 <= Power10Mantissa(n) < 2**64. // // See the "Table of powers of 10" comment below for a "1e60" example. // // Lookups into the power-of-10 table must first check the Power10Overflow() and // Power10Underflow() functions, to avoid out-of-bounds table access. // // Indexes into these tables are biased by -kPower10TableMinInclusive. Valid // indexes range from kPower10TableMinInclusive to kPower10TableMaxExclusive. extern const uint64_t kPower10MantissaHighTable[]; // High 64 of 128 bits. extern const uint64_t kPower10MantissaLowTable[]; // Low 64 of 128 bits. // The smallest (inclusive) allowed value for use with the Power10Mantissa() // and Power10Exponent() functions below. (If a smaller exponent is needed in // calculations, the end result is guaranteed to underflow.) constexpr int kPower10TableMinInclusive = -342; // The largest (exclusive) allowed value for use with the Power10Mantissa() and // Power10Exponent() functions below. (If a larger-or-equal exponent is needed // in calculations, the end result is guaranteed to overflow.) constexpr int kPower10TableMaxExclusive = 309; uint64_t Power10Mantissa(int n) { return kPower10MantissaHighTable[n - kPower10TableMinInclusive]; } int Power10Exponent(int n) { // The 217706 etc magic numbers encode the results as a formula instead of a // table. Their equivalence (over the kPower10TableMinInclusive .. // kPower10TableMaxExclusive range) is confirmed by // https://github.com/google/wuffs/blob/315b2e52625ebd7b02d8fac13e3cd85ea374fb80/script/print-mpb-powers-of-10.go return (217706 * n >> 16) - 63; } // Returns true if n is large enough that 10**n always results in an IEEE // overflow. bool Power10Overflow(int n) { return n >= kPower10TableMaxExclusive; } // Returns true if n is small enough that 10**n times a ParsedFloat mantissa // always results in an IEEE underflow. bool Power10Underflow(int n) { return n < kPower10TableMinInclusive; } // Returns true if Power10Mantissa(n) * 2**Power10Exponent(n) is exactly equal // to 10**n numerically. Put another way, this returns true if there is no // truncation error in Power10Mantissa(n). bool Power10Exact(int n) { return n >= 0 && n <= 27; } // Sentinel exponent values for representing numbers too large or too close to // zero to represent in a double. constexpr int kOverflow = 99999; constexpr int kUnderflow = -99999; // Struct representing the calculated conversion result of a positive (nonzero) // floating point number. // // The calculated number is mantissa * 2**exponent (mantissa is treated as an // integer.) `mantissa` is chosen to be the correct width for the IEEE float // representation being calculated. (`mantissa` will always have the same bit // width for normal values, and narrower bit widths for subnormals.) // // If the result of conversion was an underflow or overflow, exponent is set // to kUnderflow or kOverflow. struct CalculatedFloat { uint64_t mantissa = 0; int exponent = 0; }; // Returns the bit width of the given uint128. (Equivalently, returns 128 // minus the number of leading zero bits.) int BitWidth(uint128 value) { if (Uint128High64(value) == 0) { // This static_cast is only needed when using a std::bit_width() // implementation that does not have the fix for LWG 3656 applied. return static_cast(bit_width(Uint128Low64(value))); } return 128 - countl_zero(Uint128High64(value)); } // Calculates how far to the right a mantissa needs to be shifted to create a // properly adjusted mantissa for an IEEE floating point number. // // `mantissa_width` is the bit width of the mantissa to be shifted, and // `binary_exponent` is the exponent of the number before the shift. // // This accounts for subnormal values, and will return a larger-than-normal // shift if binary_exponent would otherwise be too low. template int NormalizedShiftSize(int mantissa_width, int binary_exponent) { const int normal_shift = mantissa_width - FloatTraits::kTargetMantissaBits; const int minimum_shift = FloatTraits::kMinNormalExponent - binary_exponent; return std::max(normal_shift, minimum_shift); } // Right shifts a uint128 so that it has the requested bit width. (The // resulting value will have 128 - bit_width leading zeroes.) The initial // `value` must be wider than the requested bit width. // // Returns the number of bits shifted. int TruncateToBitWidth(int bit_width, uint128* value) { const int current_bit_width = BitWidth(*value); const int shift = current_bit_width - bit_width; *value >>= shift; return shift; } // Checks if the given ParsedFloat represents one of the edge cases that are // not dependent on number base: zero, infinity, or NaN. If so, sets *value // the appropriate double, and returns true. template bool HandleEdgeCase(const strings_internal::ParsedFloat& input, bool negative, FloatType* value) { if (input.type == strings_internal::FloatType::kNan) { // A bug in both clang < 7 and gcc would cause the compiler to optimize // away the buffer we are building below. Declaring the buffer volatile // avoids the issue, and has no measurable performance impact in // microbenchmarks. // // https://bugs.llvm.org/show_bug.cgi?id=37778 // https://gcc.gnu.org/bugzilla/show_bug.cgi?id=86113 constexpr ptrdiff_t kNanBufferSize = 128; #if (defined(__GNUC__) && !defined(__clang__)) || \ (defined(__clang__) && __clang_major__ < 7) volatile char n_char_sequence[kNanBufferSize]; #else char n_char_sequence[kNanBufferSize]; #endif if (input.subrange_begin == nullptr) { n_char_sequence[0] = '\0'; } else { ptrdiff_t nan_size = input.subrange_end - input.subrange_begin; nan_size = std::min(nan_size, kNanBufferSize - 1); std::copy_n(input.subrange_begin, nan_size, n_char_sequence); n_char_sequence[nan_size] = '\0'; } char* nan_argument = const_cast(n_char_sequence); *value = negative ? -FloatTraits::MakeNan(nan_argument) : FloatTraits::MakeNan(nan_argument); return true; } if (input.type == strings_internal::FloatType::kInfinity) { *value = negative ? -std::numeric_limits::infinity() : std::numeric_limits::infinity(); return true; } if (input.mantissa == 0) { *value = negative ? -0.0 : 0.0; return true; } return false; } // Given a CalculatedFloat result of a from_chars conversion, generate the // correct output values. // // CalculatedFloat can represent an underflow or overflow, in which case the // error code in *result is set. Otherwise, the calculated floating point // number is stored in *value. template void EncodeResult(const CalculatedFloat& calculated, bool negative, y_absl::from_chars_result* result, FloatType* value) { if (calculated.exponent == kOverflow) { result->ec = std::errc::result_out_of_range; *value = negative ? -std::numeric_limits::max() : std::numeric_limits::max(); return; } else if (calculated.mantissa == 0 || calculated.exponent == kUnderflow) { result->ec = std::errc::result_out_of_range; *value = negative ? -0.0 : 0.0; return; } *value = FloatTraits::Make( static_cast::mantissa_t>( calculated.mantissa), calculated.exponent, negative); } // Returns the given uint128 shifted to the right by `shift` bits, and rounds // the remaining bits using round_to_nearest logic. The value is returned as a // uint64_t, since this is the type used by this library for storing calculated // floating point mantissas. // // It is expected that the width of the input value shifted by `shift` will // be the correct bit-width for the target mantissa, which is strictly narrower // than a uint64_t. // // If `input_exact` is false, then a nonzero error epsilon is assumed. For // rounding purposes, the true value being rounded is strictly greater than the // input value. The error may represent a single lost carry bit. // // When input_exact, shifted bits of the form 1000000... represent a tie, which // is broken by rounding to even -- the rounding direction is chosen so the low // bit of the returned value is 0. // // When !input_exact, shifted bits of the form 10000000... represent a value // strictly greater than one half (due to the error epsilon), and so ties are // always broken by rounding up. // // When !input_exact, shifted bits of the form 01111111... are uncertain; // the true value may or may not be greater than 10000000..., due to the // possible lost carry bit. The correct rounding direction is unknown. In this // case, the result is rounded down, and `output_exact` is set to false. // // Zero and negative values of `shift` are accepted, in which case the word is // shifted left, as necessary. uint64_t ShiftRightAndRound(uint128 value, int shift, bool input_exact, bool* output_exact) { if (shift <= 0) { *output_exact = input_exact; return static_cast(value << -shift); } if (shift >= 128) { // Exponent is so small that we are shifting away all significant bits. // Answer will not be representable, even as a subnormal, so return a zero // mantissa (which represents underflow). *output_exact = true; return 0; } *output_exact = true; const uint128 shift_mask = (uint128(1) << shift) - 1; const uint128 halfway_point = uint128(1) << (shift - 1); const uint128 shifted_bits = value & shift_mask; value >>= shift; if (shifted_bits > halfway_point) { // Shifted bits greater than 10000... require rounding up. return static_cast(value + 1); } if (shifted_bits == halfway_point) { // In exact mode, shifted bits of 10000... mean we're exactly halfway // between two numbers, and we must round to even. So only round up if // the low bit of `value` is set. // // In inexact mode, the nonzero error means the actual value is greater // than the halfway point and we must always round up. if ((value & 1) == 1 || !input_exact) { ++value; } return static_cast(value); } if (!input_exact && shifted_bits == halfway_point - 1) { // Rounding direction is unclear, due to error. *output_exact = false; } // Otherwise, round down. return static_cast(value); } // Checks if a floating point guess needs to be rounded up, using high precision // math. // // `guess_mantissa` and `guess_exponent` represent a candidate guess for the // number represented by `parsed_decimal`. // // The exact number represented by `parsed_decimal` must lie between the two // numbers: // A = `guess_mantissa * 2**guess_exponent` // B = `(guess_mantissa + 1) * 2**guess_exponent` // // This function returns false if `A` is the better guess, and true if `B` is // the better guess, with rounding ties broken by rounding to even. bool MustRoundUp(uint64_t guess_mantissa, int guess_exponent, const strings_internal::ParsedFloat& parsed_decimal) { // 768 is the number of digits needed in the worst case. We could determine a // better limit dynamically based on the value of parsed_decimal.exponent. // This would optimize pathological input cases only. (Sane inputs won't have // hundreds of digits of mantissa.) y_absl::strings_internal::BigUnsigned<84> exact_mantissa; int exact_exponent = exact_mantissa.ReadFloatMantissa(parsed_decimal, 768); // Adjust the `guess` arguments to be halfway between A and B. guess_mantissa = guess_mantissa * 2 + 1; guess_exponent -= 1; // In our comparison: // lhs = exact = exact_mantissa * 10**exact_exponent // = exact_mantissa * 5**exact_exponent * 2**exact_exponent // rhs = guess = guess_mantissa * 2**guess_exponent // // Because we are doing integer math, we can't directly deal with negative // exponents. We instead move these to the other side of the inequality. y_absl::strings_internal::BigUnsigned<84>& lhs = exact_mantissa; int comparison; if (exact_exponent >= 0) { lhs.MultiplyByFiveToTheNth(exact_exponent); y_absl::strings_internal::BigUnsigned<84> rhs(guess_mantissa); // There are powers of 2 on both sides of the inequality; reduce this to // a single bit-shift. if (exact_exponent > guess_exponent) { lhs.ShiftLeft(exact_exponent - guess_exponent); } else { rhs.ShiftLeft(guess_exponent - exact_exponent); } comparison = Compare(lhs, rhs); } else { // Move the power of 5 to the other side of the equation, giving us: // lhs = exact_mantissa * 2**exact_exponent // rhs = guess_mantissa * 5**(-exact_exponent) * 2**guess_exponent y_absl::strings_internal::BigUnsigned<84> rhs = y_absl::strings_internal::BigUnsigned<84>::FiveToTheNth(-exact_exponent); rhs.MultiplyBy(guess_mantissa); if (exact_exponent > guess_exponent) { lhs.ShiftLeft(exact_exponent - guess_exponent); } else { rhs.ShiftLeft(guess_exponent - exact_exponent); } comparison = Compare(lhs, rhs); } if (comparison < 0) { return false; } else if (comparison > 0) { return true; } else { // When lhs == rhs, the decimal input is exactly between A and B. // Round towards even -- round up only if the low bit of the initial // `guess_mantissa` was a 1. We shifted guess_mantissa left 1 bit at // the beginning of this function, so test the 2nd bit here. return (guess_mantissa & 2) == 2; } } // Constructs a CalculatedFloat from a given mantissa and exponent, but // with the following normalizations applied: // // If rounding has caused mantissa to increase just past the allowed bit // width, shift and adjust exponent. // // If exponent is too high, sets kOverflow. // // If mantissa is zero (representing a non-zero value not representable, even // as a subnormal), sets kUnderflow. template CalculatedFloat CalculatedFloatFromRawValues(uint64_t mantissa, int exponent) { CalculatedFloat result; if (mantissa == uint64_t{1} << FloatTraits::kTargetMantissaBits) { mantissa >>= 1; exponent += 1; } if (exponent > FloatTraits::kMaxExponent) { result.exponent = kOverflow; } else if (mantissa == 0) { result.exponent = kUnderflow; } else { result.exponent = exponent; result.mantissa = mantissa; } return result; } template CalculatedFloat CalculateFromParsedHexadecimal( const strings_internal::ParsedFloat& parsed_hex) { uint64_t mantissa = parsed_hex.mantissa; int exponent = parsed_hex.exponent; // This static_cast is only needed when using a std::bit_width() // implementation that does not have the fix for LWG 3656 applied. int mantissa_width = static_cast(bit_width(mantissa)); const int shift = NormalizedShiftSize(mantissa_width, exponent); bool result_exact; exponent += shift; mantissa = ShiftRightAndRound(mantissa, shift, /* input exact= */ true, &result_exact); // ParseFloat handles rounding in the hexadecimal case, so we don't have to // check `result_exact` here. return CalculatedFloatFromRawValues(mantissa, exponent); } template CalculatedFloat CalculateFromParsedDecimal( const strings_internal::ParsedFloat& parsed_decimal) { CalculatedFloat result; // Large or small enough decimal exponents will always result in overflow // or underflow. if (Power10Underflow(parsed_decimal.exponent)) { result.exponent = kUnderflow; return result; } else if (Power10Overflow(parsed_decimal.exponent)) { result.exponent = kOverflow; return result; } // Otherwise convert our power of 10 into a power of 2 times an integer // mantissa, and multiply this by our parsed decimal mantissa. uint128 wide_binary_mantissa = parsed_decimal.mantissa; wide_binary_mantissa *= Power10Mantissa(parsed_decimal.exponent); int binary_exponent = Power10Exponent(parsed_decimal.exponent); // Discard bits that are inaccurate due to truncation error. The magic // `mantissa_width` constants below are justified in // https://abseil.io/about/design/charconv. They represent the number of bits // in `wide_binary_mantissa` that are guaranteed to be unaffected by error // propagation. bool mantissa_exact; int mantissa_width; if (parsed_decimal.subrange_begin) { // Truncated mantissa mantissa_width = 58; mantissa_exact = false; binary_exponent += TruncateToBitWidth(mantissa_width, &wide_binary_mantissa); } else if (!Power10Exact(parsed_decimal.exponent)) { // Exact mantissa, truncated power of ten mantissa_width = 63; mantissa_exact = false; binary_exponent += TruncateToBitWidth(mantissa_width, &wide_binary_mantissa); } else { // Product is exact mantissa_width = BitWidth(wide_binary_mantissa); mantissa_exact = true; } // Shift into an FloatType-sized mantissa, and round to nearest. const int shift = NormalizedShiftSize(mantissa_width, binary_exponent); bool result_exact; binary_exponent += shift; uint64_t binary_mantissa = ShiftRightAndRound(wide_binary_mantissa, shift, mantissa_exact, &result_exact); if (!result_exact) { // We could not determine the rounding direction using int128 math. Use // full resolution math instead. if (MustRoundUp(binary_mantissa, binary_exponent, parsed_decimal)) { binary_mantissa += 1; } } return CalculatedFloatFromRawValues(binary_mantissa, binary_exponent); } // As discussed in https://nigeltao.github.io/blog/2020/eisel-lemire.html the // primary goal of the Eisel-Lemire algorithm is speed, for 99+% of the cases, // not 100% coverage. As long as Eisel-Lemire doesn’t claim false positives, // the combined approach (falling back to an alternative implementation when // this function returns false) is both fast and correct. template bool EiselLemire(const strings_internal::ParsedFloat& input, bool negative, FloatType* value, std::errc* ec) { uint64_t man = input.mantissa; int exp10 = input.exponent; if (exp10 < FloatTraits::kEiselLemireMinInclusiveExp10) { *value = negative ? -0.0 : 0.0; *ec = std::errc::result_out_of_range; return true; } else if (exp10 >= FloatTraits::kEiselLemireMaxExclusiveExp10) { // Return max (a finite value) consistent with from_chars and DR 3081. For // SimpleAtod and SimpleAtof, post-processing will return infinity. *value = negative ? -std::numeric_limits::max() : std::numeric_limits::max(); *ec = std::errc::result_out_of_range; return true; } // Assert kPower10TableMinInclusive <= exp10 < kPower10TableMaxExclusive. // Equivalently, !Power10Underflow(exp10) and !Power10Overflow(exp10). static_assert( FloatTraits::kEiselLemireMinInclusiveExp10 >= kPower10TableMinInclusive, "(exp10-kPower10TableMinInclusive) in kPower10MantissaHighTable bounds"); static_assert( FloatTraits::kEiselLemireMaxExclusiveExp10 <= kPower10TableMaxExclusive, "(exp10-kPower10TableMinInclusive) in kPower10MantissaHighTable bounds"); // The terse (+) comments in this function body refer to sections of the // https://nigeltao.github.io/blog/2020/eisel-lemire.html blog post. // // That blog post discusses double precision (11 exponent bits with a -1023 // bias, 52 mantissa bits), but the same approach applies to single precision // (8 exponent bits with a -127 bias, 23 mantissa bits). Either way, the // computation here happens with 64-bit values (e.g. man) or 128-bit values // (e.g. x) before finally converting to 64- or 32-bit floating point. // // See also "Number Parsing at a Gigabyte per Second, Software: Practice and // Experience 51 (8), 2021" (https://arxiv.org/abs/2101.11408) for detail. // (+) Normalization. int clz = countl_zero(man); man <<= static_cast(clz); // The 217706 etc magic numbers are from the Power10Exponent function. uint64_t ret_exp2 = static_cast((217706 * exp10 >> 16) + 64 + FloatTraits::kExponentBias - clz); // (+) Multiplication. uint128 x = static_cast(man) * static_cast( kPower10MantissaHighTable[exp10 - kPower10TableMinInclusive]); // (+) Wider Approximation. static constexpr uint64_t high64_mask = FloatTraits::kEiselLemireMask; if (((Uint128High64(x) & high64_mask) == high64_mask) && (man > (std::numeric_limits::max() - Uint128Low64(x)))) { uint128 y = static_cast(man) * static_cast( kPower10MantissaLowTable[exp10 - kPower10TableMinInclusive]); x += Uint128High64(y); // For example, parsing "4503599627370497.5" will take the if-true // branch here (for double precision), since: // - x = 0x8000000000000BFF_FFFFFFFFFFFFFFFF // - y = 0x8000000000000BFF_7FFFFFFFFFFFF400 // - man = 0xA000000000000F00 // Likewise, when parsing "0.0625" for single precision: // - x = 0x7FFFFFFFFFFFFFFF_FFFFFFFFFFFFFFFF // - y = 0x813FFFFFFFFFFFFF_8A00000000000000 // - man = 0x9C40000000000000 if (((Uint128High64(x) & high64_mask) == high64_mask) && ((Uint128Low64(x) + 1) == 0) && (man > (std::numeric_limits::max() - Uint128Low64(y)))) { return false; } } // (+) Shifting to 54 Bits (or for single precision, to 25 bits). uint64_t msb = Uint128High64(x) >> 63; uint64_t ret_man = Uint128High64(x) >> (msb + FloatTraits::kEiselLemireShift); ret_exp2 -= 1 ^ msb; // (+) Half-way Ambiguity. // // For example, parsing "1e+23" will take the if-true branch here (for double // precision), since: // - x = 0x54B40B1F852BDA00_0000000000000000 // - ret_man = 0x002A5A058FC295ED // Likewise, when parsing "20040229.0" for single precision: // - x = 0x4C72894000000000_0000000000000000 // - ret_man = 0x000000000131CA25 if ((Uint128Low64(x) == 0) && ((Uint128High64(x) & high64_mask) == 0) && ((ret_man & 3) == 1)) { return false; } // (+) From 54 to 53 Bits (or for single precision, from 25 to 24 bits). ret_man += ret_man & 1; // Line From54a. ret_man >>= 1; // Line From54b. // Incrementing ret_man (at line From54a) may have overflowed 54 bits (53 // bits after the right shift by 1 at line From54b), so adjust for that. // // For example, parsing "9223372036854775807" will take the if-true branch // here (for double precision), since: // - ret_man = 0x0020000000000000 = (1 << 53) // Likewise, when parsing "2147483647.0" for single precision: // - ret_man = 0x0000000001000000 = (1 << 24) if ((ret_man >> FloatTraits::kTargetMantissaBits) > 0) { ret_exp2 += 1; // Conceptually, we need a "ret_man >>= 1" in this if-block to balance // incrementing ret_exp2 in the line immediately above. However, we only // get here when line From54a overflowed (after adding a 1), so ret_man // here is (1 << 53). Its low 53 bits are therefore all zeroes. The only // remaining use of ret_man is to mask it with ((1 << 52) - 1), so only its // low 52 bits matter. A "ret_man >>= 1" would have no effect in practice. // // We omit the "ret_man >>= 1", even if it is cheap (and this if-branch is // rarely taken) and technically 'more correct', so that mutation tests // that would otherwise modify or omit that "ret_man >>= 1" don't complain // that such code mutations have no observable effect. } // ret_exp2 is a uint64_t. Zero or underflow means that we're in subnormal // space. max_exp2 (0x7FF for double precision, 0xFF for single precision) or // above means that we're in Inf/NaN space. // // The if block is equivalent to (but has fewer branches than): // if ((ret_exp2 <= 0) || (ret_exp2 >= max_exp2)) { etc } // // For example, parsing "4.9406564584124654e-324" will take the if-true // branch here, since ret_exp2 = -51. static constexpr uint64_t max_exp2 = (1 << FloatTraits::kTargetExponentBits) - 1; if ((ret_exp2 - 1) >= (max_exp2 - 1)) { return false; } #ifndef Y_ABSL_BIT_PACK_FLOATS if (FloatTraits::kTargetBits == 64) { *value = FloatTraits::Make( (ret_man & 0x000FFFFFFFFFFFFFu) | 0x0010000000000000u, static_cast(ret_exp2) - 1023 - 52, negative); return true; } else if (FloatTraits::kTargetBits == 32) { *value = FloatTraits::Make( (static_cast(ret_man) & 0x007FFFFFu) | 0x00800000u, static_cast(ret_exp2) - 127 - 23, negative); return true; } #else if (FloatTraits::kTargetBits == 64) { uint64_t ret_bits = (ret_exp2 << 52) | (ret_man & 0x000FFFFFFFFFFFFFu); if (negative) { ret_bits |= 0x8000000000000000u; } *value = y_absl::bit_cast(ret_bits); return true; } else if (FloatTraits::kTargetBits == 32) { uint32_t ret_bits = (static_cast(ret_exp2) << 23) | (static_cast(ret_man) & 0x007FFFFFu); if (negative) { ret_bits |= 0x80000000u; } *value = y_absl::bit_cast(ret_bits); return true; } #endif // Y_ABSL_BIT_PACK_FLOATS return false; } template from_chars_result FromCharsImpl(const char* first, const char* last, FloatType& value, chars_format fmt_flags) { from_chars_result result; result.ptr = first; // overwritten on successful parse result.ec = std::errc(); bool negative = false; if (first != last && *first == '-') { ++first; negative = true; } // If the `hex` flag is *not* set, then we will accept a 0x prefix and try // to parse a hexadecimal float. if ((fmt_flags & chars_format::hex) == chars_format{} && last - first >= 2 && *first == '0' && (first[1] == 'x' || first[1] == 'X')) { const char* hex_first = first + 2; strings_internal::ParsedFloat hex_parse = strings_internal::ParseFloat<16>(hex_first, last, fmt_flags); if (hex_parse.end == nullptr || hex_parse.type != strings_internal::FloatType::kNumber) { // Either we failed to parse a hex float after the "0x", or we read // "0xinf" or "0xnan" which we don't want to match. // // However, a string that begins with "0x" also begins with "0", which // is normally a valid match for the number zero. So we want these // strings to match zero unless fmt_flags is `scientific`. (This flag // means an exponent is required, which the string "0" does not have.) if (fmt_flags == chars_format::scientific) { result.ec = std::errc::invalid_argument; } else { result.ptr = first + 1; value = negative ? -0.0 : 0.0; } return result; } // We matched a value. result.ptr = hex_parse.end; if (HandleEdgeCase(hex_parse, negative, &value)) { return result; } CalculatedFloat calculated = CalculateFromParsedHexadecimal(hex_parse); EncodeResult(calculated, negative, &result, &value); return result; } // Otherwise, we choose the number base based on the flags. if ((fmt_flags & chars_format::hex) == chars_format::hex) { strings_internal::ParsedFloat hex_parse = strings_internal::ParseFloat<16>(first, last, fmt_flags); if (hex_parse.end == nullptr) { result.ec = std::errc::invalid_argument; return result; } result.ptr = hex_parse.end; if (HandleEdgeCase(hex_parse, negative, &value)) { return result; } CalculatedFloat calculated = CalculateFromParsedHexadecimal(hex_parse); EncodeResult(calculated, negative, &result, &value); return result; } else { strings_internal::ParsedFloat decimal_parse = strings_internal::ParseFloat<10>(first, last, fmt_flags); if (decimal_parse.end == nullptr) { result.ec = std::errc::invalid_argument; return result; } result.ptr = decimal_parse.end; if (HandleEdgeCase(decimal_parse, negative, &value)) { return result; } // A nullptr subrange_begin means that the decimal_parse.mantissa is exact // (not truncated), a precondition of the Eisel-Lemire algorithm. if ((decimal_parse.subrange_begin == nullptr) && EiselLemire(decimal_parse, negative, &value, &result.ec)) { return result; } CalculatedFloat calculated = CalculateFromParsedDecimal(decimal_parse); EncodeResult(calculated, negative, &result, &value); return result; } } } // namespace from_chars_result from_chars(const char* first, const char* last, double& value, chars_format fmt) { return FromCharsImpl(first, last, value, fmt); } from_chars_result from_chars(const char* first, const char* last, float& value, chars_format fmt) { return FromCharsImpl(first, last, value, fmt); } namespace { // Table of powers of 10, from kPower10TableMinInclusive to // kPower10TableMaxExclusive. // // kPower10MantissaHighTable[i - kPower10TableMinInclusive] stores the 64-bit // mantissa. The high bit is always on. // // kPower10MantissaLowTable extends that 64-bit mantissa to 128 bits. // // Power10Exponent(i) calculates the power-of-two exponent. // // For a number i, this gives the unique mantissaHigh and exponent such that // (mantissaHigh * 2**exponent) <= 10**i < ((mantissaHigh + 1) * 2**exponent). // // For example, Python can confirm that the exact hexadecimal value of 1e60 is: // >>> a = 1000000000000000000000000000000000000000000000000000000000000 // >>> hex(a) // '0x9f4f2726179a224501d762422c946590d91000000000000000' // Adding underscores at every 8th hex digit shows 50 hex digits: // '0x9f4f2726_179a2245_01d76242_2c946590_d9100000_00000000_00'. // In this case, the high bit of the first hex digit, 9, is coincidentally set, // so we do not have to do further shifting to deduce the 128-bit mantissa: // - kPower10MantissaHighTable[60 - kP10TMI] = 0x9f4f2726179a2245U // - kPower10MantissaLowTable[ 60 - kP10TMI] = 0x01d762422c946590U // where kP10TMI is kPower10TableMinInclusive. The low 18 of those 50 hex // digits are truncated. // // 50 hex digits (with the high bit set) is 200 bits and mantissaHigh holds 64 // bits, so Power10Exponent(60) = 200 - 64 = 136. Again, Python can confirm: // >>> b = 0x9f4f2726179a2245 // >>> ((b+0)<<136) <= a // True // >>> ((b+1)<<136) <= a // False // // The tables were generated by // https://github.com/google/wuffs/blob/315b2e52625ebd7b02d8fac13e3cd85ea374fb80/script/print-mpb-powers-of-10.go // after re-formatting its output into two arrays of N uint64_t values (instead // of an N element array of uint64_t pairs). const uint64_t kPower10MantissaHighTable[] = { 0xeef453d6923bd65aU, 0x9558b4661b6565f8U, 0xbaaee17fa23ebf76U, 0xe95a99df8ace6f53U, 0x91d8a02bb6c10594U, 0xb64ec836a47146f9U, 0xe3e27a444d8d98b7U, 0x8e6d8c6ab0787f72U, 0xb208ef855c969f4fU, 0xde8b2b66b3bc4723U, 0x8b16fb203055ac76U, 0xaddcb9e83c6b1793U, 0xd953e8624b85dd78U, 0x87d4713d6f33aa6bU, 0xa9c98d8ccb009506U, 0xd43bf0effdc0ba48U, 0x84a57695fe98746dU, 0xa5ced43b7e3e9188U, 0xcf42894a5dce35eaU, 0x818995ce7aa0e1b2U, 0xa1ebfb4219491a1fU, 0xca66fa129f9b60a6U, 0xfd00b897478238d0U, 0x9e20735e8cb16382U, 0xc5a890362fddbc62U, 0xf712b443bbd52b7bU, 0x9a6bb0aa55653b2dU, 0xc1069cd4eabe89f8U, 0xf148440a256e2c76U, 0x96cd2a865764dbcaU, 0xbc807527ed3e12bcU, 0xeba09271e88d976bU, 0x93445b8731587ea3U, 0xb8157268fdae9e4cU, 0xe61acf033d1a45dfU, 0x8fd0c16206306babU, 0xb3c4f1ba87bc8696U, 0xe0b62e2929aba83cU, 0x8c71dcd9ba0b4925U, 0xaf8e5410288e1b6fU, 0xdb71e91432b1a24aU, 0x892731ac9faf056eU, 0xab70fe17c79ac6caU, 0xd64d3d9db981787dU, 0x85f0468293f0eb4eU, 0xa76c582338ed2621U, 0xd1476e2c07286faaU, 0x82cca4db847945caU, 0xa37fce126597973cU, 0xcc5fc196fefd7d0cU, 0xff77b1fcbebcdc4fU, 0x9faacf3df73609b1U, 0xc795830d75038c1dU, 0xf97ae3d0d2446f25U, 0x9becce62836ac577U, 0xc2e801fb244576d5U, 0xf3a20279ed56d48aU, 0x9845418c345644d6U, 0xbe5691ef416bd60cU, 0xedec366b11c6cb8fU, 0x94b3a202eb1c3f39U, 0xb9e08a83a5e34f07U, 0xe858ad248f5c22c9U, 0x91376c36d99995beU, 0xb58547448ffffb2dU, 0xe2e69915b3fff9f9U, 0x8dd01fad907ffc3bU, 0xb1442798f49ffb4aU, 0xdd95317f31c7fa1dU, 0x8a7d3eef7f1cfc52U, 0xad1c8eab5ee43b66U, 0xd863b256369d4a40U, 0x873e4f75e2224e68U, 0xa90de3535aaae202U, 0xd3515c2831559a83U, 0x8412d9991ed58091U, 0xa5178fff668ae0b6U, 0xce5d73ff402d98e3U, 0x80fa687f881c7f8eU, 0xa139029f6a239f72U, 0xc987434744ac874eU, 0xfbe9141915d7a922U, 0x9d71ac8fada6c9b5U, 0xc4ce17b399107c22U, 0xf6019da07f549b2bU, 0x99c102844f94e0fbU, 0xc0314325637a1939U, 0xf03d93eebc589f88U, 0x96267c7535b763b5U, 0xbbb01b9283253ca2U, 0xea9c227723ee8bcbU, 0x92a1958a7675175fU, 0xb749faed14125d36U, 0xe51c79a85916f484U, 0x8f31cc0937ae58d2U, 0xb2fe3f0b8599ef07U, 0xdfbdcece67006ac9U, 0x8bd6a141006042bdU, 0xaecc49914078536dU, 0xda7f5bf590966848U, 0x888f99797a5e012dU, 0xaab37fd7d8f58178U, 0xd5605fcdcf32e1d6U, 0x855c3be0a17fcd26U, 0xa6b34ad8c9dfc06fU, 0xd0601d8efc57b08bU, 0x823c12795db6ce57U, 0xa2cb1717b52481edU, 0xcb7ddcdda26da268U, 0xfe5d54150b090b02U, 0x9efa548d26e5a6e1U, 0xc6b8e9b0709f109aU, 0xf867241c8cc6d4c0U, 0x9b407691d7fc44f8U, 0xc21094364dfb5636U, 0xf294b943e17a2bc4U, 0x979cf3ca6cec5b5aU, 0xbd8430bd08277231U, 0xece53cec4a314ebdU, 0x940f4613ae5ed136U, 0xb913179899f68584U, 0xe757dd7ec07426e5U, 0x9096ea6f3848984fU, 0xb4bca50b065abe63U, 0xe1ebce4dc7f16dfbU, 0x8d3360f09cf6e4bdU, 0xb080392cc4349decU, 0xdca04777f541c567U, 0x89e42caaf9491b60U, 0xac5d37d5b79b6239U, 0xd77485cb25823ac7U, 0x86a8d39ef77164bcU, 0xa8530886b54dbdebU, 0xd267caa862a12d66U, 0x8380dea93da4bc60U, 0xa46116538d0deb78U, 0xcd795be870516656U, 0x806bd9714632dff6U, 0xa086cfcd97bf97f3U, 0xc8a883c0fdaf7df0U, 0xfad2a4b13d1b5d6cU, 0x9cc3a6eec6311a63U, 0xc3f490aa77bd60fcU, 0xf4f1b4d515acb93bU, 0x991711052d8bf3c5U, 0xbf5cd54678eef0b6U, 0xef340a98172aace4U, 0x9580869f0e7aac0eU, 0xbae0a846d2195712U, 0xe998d258869facd7U, 0x91ff83775423cc06U, 0xb67f6455292cbf08U, 0xe41f3d6a7377eecaU, 0x8e938662882af53eU, 0xb23867fb2a35b28dU, 0xdec681f9f4c31f31U, 0x8b3c113c38f9f37eU, 0xae0b158b4738705eU, 0xd98ddaee19068c76U, 0x87f8a8d4cfa417c9U, 0xa9f6d30a038d1dbcU, 0xd47487cc8470652bU, 0x84c8d4dfd2c63f3bU, 0xa5fb0a17c777cf09U, 0xcf79cc9db955c2ccU, 0x81ac1fe293d599bfU, 0xa21727db38cb002fU, 0xca9cf1d206fdc03bU, 0xfd442e4688bd304aU, 0x9e4a9cec15763e2eU, 0xc5dd44271ad3cdbaU, 0xf7549530e188c128U, 0x9a94dd3e8cf578b9U, 0xc13a148e3032d6e7U, 0xf18899b1bc3f8ca1U, 0x96f5600f15a7b7e5U, 0xbcb2b812db11a5deU, 0xebdf661791d60f56U, 0x936b9fcebb25c995U, 0xb84687c269ef3bfbU, 0xe65829b3046b0afaU, 0x8ff71a0fe2c2e6dcU, 0xb3f4e093db73a093U, 0xe0f218b8d25088b8U, 0x8c974f7383725573U, 0xafbd2350644eeacfU, 0xdbac6c247d62a583U, 0x894bc396ce5da772U, 0xab9eb47c81f5114fU, 0xd686619ba27255a2U, 0x8613fd0145877585U, 0xa798fc4196e952e7U, 0xd17f3b51fca3a7a0U, 0x82ef85133de648c4U, 0xa3ab66580d5fdaf5U, 0xcc963fee10b7d1b3U, 0xffbbcfe994e5c61fU, 0x9fd561f1fd0f9bd3U, 0xc7caba6e7c5382c8U, 0xf9bd690a1b68637bU, 0x9c1661a651213e2dU, 0xc31bfa0fe5698db8U, 0xf3e2f893dec3f126U, 0x986ddb5c6b3a76b7U, 0xbe89523386091465U, 0xee2ba6c0678b597fU, 0x94db483840b717efU, 0xba121a4650e4ddebU, 0xe896a0d7e51e1566U, 0x915e2486ef32cd60U, 0xb5b5ada8aaff80b8U, 0xe3231912d5bf60e6U, 0x8df5efabc5979c8fU, 0xb1736b96b6fd83b3U, 0xddd0467c64bce4a0U, 0x8aa22c0dbef60ee4U, 0xad4ab7112eb3929dU, 0xd89d64d57a607744U, 0x87625f056c7c4a8bU, 0xa93af6c6c79b5d2dU, 0xd389b47879823479U, 0x843610cb4bf160cbU, 0xa54394fe1eedb8feU, 0xce947a3da6a9273eU, 0x811ccc668829b887U, 0xa163ff802a3426a8U, 0xc9bcff6034c13052U, 0xfc2c3f3841f17c67U, 0x9d9ba7832936edc0U, 0xc5029163f384a931U, 0xf64335bcf065d37dU, 0x99ea0196163fa42eU, 0xc06481fb9bcf8d39U, 0xf07da27a82c37088U, 0x964e858c91ba2655U, 0xbbe226efb628afeaU, 0xeadab0aba3b2dbe5U, 0x92c8ae6b464fc96fU, 0xb77ada0617e3bbcbU, 0xe55990879ddcaabdU, 0x8f57fa54c2a9eab6U, 0xb32df8e9f3546564U, 0xdff9772470297ebdU, 0x8bfbea76c619ef36U, 0xaefae51477a06b03U, 0xdab99e59958885c4U, 0x88b402f7fd75539bU, 0xaae103b5fcd2a881U, 0xd59944a37c0752a2U, 0x857fcae62d8493a5U, 0xa6dfbd9fb8e5b88eU, 0xd097ad07a71f26b2U, 0x825ecc24c873782fU, 0xa2f67f2dfa90563bU, 0xcbb41ef979346bcaU, 0xfea126b7d78186bcU, 0x9f24b832e6b0f436U, 0xc6ede63fa05d3143U, 0xf8a95fcf88747d94U, 0x9b69dbe1b548ce7cU, 0xc24452da229b021bU, 0xf2d56790ab41c2a2U, 0x97c560ba6b0919a5U, 0xbdb6b8e905cb600fU, 0xed246723473e3813U, 0x9436c0760c86e30bU, 0xb94470938fa89bceU, 0xe7958cb87392c2c2U, 0x90bd77f3483bb9b9U, 0xb4ecd5f01a4aa828U, 0xe2280b6c20dd5232U, 0x8d590723948a535fU, 0xb0af48ec79ace837U, 0xdcdb1b2798182244U, 0x8a08f0f8bf0f156bU, 0xac8b2d36eed2dac5U, 0xd7adf884aa879177U, 0x86ccbb52ea94baeaU, 0xa87fea27a539e9a5U, 0xd29fe4b18e88640eU, 0x83a3eeeef9153e89U, 0xa48ceaaab75a8e2bU, 0xcdb02555653131b6U, 0x808e17555f3ebf11U, 0xa0b19d2ab70e6ed6U, 0xc8de047564d20a8bU, 0xfb158592be068d2eU, 0x9ced737bb6c4183dU, 0xc428d05aa4751e4cU, 0xf53304714d9265dfU, 0x993fe2c6d07b7fabU, 0xbf8fdb78849a5f96U, 0xef73d256a5c0f77cU, 0x95a8637627989aadU, 0xbb127c53b17ec159U, 0xe9d71b689dde71afU, 0x9226712162ab070dU, 0xb6b00d69bb55c8d1U, 0xe45c10c42a2b3b05U, 0x8eb98a7a9a5b04e3U, 0xb267ed1940f1c61cU, 0xdf01e85f912e37a3U, 0x8b61313bbabce2c6U, 0xae397d8aa96c1b77U, 0xd9c7dced53c72255U, 0x881cea14545c7575U, 0xaa242499697392d2U, 0xd4ad2dbfc3d07787U, 0x84ec3c97da624ab4U, 0xa6274bbdd0fadd61U, 0xcfb11ead453994baU, 0x81ceb32c4b43fcf4U, 0xa2425ff75e14fc31U, 0xcad2f7f5359a3b3eU, 0xfd87b5f28300ca0dU, 0x9e74d1b791e07e48U, 0xc612062576589ddaU, 0xf79687aed3eec551U, 0x9abe14cd44753b52U, 0xc16d9a0095928a27U, 0xf1c90080baf72cb1U, 0x971da05074da7beeU, 0xbce5086492111aeaU, 0xec1e4a7db69561a5U, 0x9392ee8e921d5d07U, 0xb877aa3236a4b449U, 0xe69594bec44de15bU, 0x901d7cf73ab0acd9U, 0xb424dc35095cd80fU, 0xe12e13424bb40e13U, 0x8cbccc096f5088cbU, 0xafebff0bcb24aafeU, 0xdbe6fecebdedd5beU, 0x89705f4136b4a597U, 0xabcc77118461cefcU, 0xd6bf94d5e57a42bcU, 0x8637bd05af6c69b5U, 0xa7c5ac471b478423U, 0xd1b71758e219652bU, 0x83126e978d4fdf3bU, 0xa3d70a3d70a3d70aU, 0xccccccccccccccccU, 0x8000000000000000U, 0xa000000000000000U, 0xc800000000000000U, 0xfa00000000000000U, 0x9c40000000000000U, 0xc350000000000000U, 0xf424000000000000U, 0x9896800000000000U, 0xbebc200000000000U, 0xee6b280000000000U, 0x9502f90000000000U, 0xba43b74000000000U, 0xe8d4a51000000000U, 0x9184e72a00000000U, 0xb5e620f480000000U, 0xe35fa931a0000000U, 0x8e1bc9bf04000000U, 0xb1a2bc2ec5000000U, 0xde0b6b3a76400000U, 0x8ac7230489e80000U, 0xad78ebc5ac620000U, 0xd8d726b7177a8000U, 0x878678326eac9000U, 0xa968163f0a57b400U, 0xd3c21bcecceda100U, 0x84595161401484a0U, 0xa56fa5b99019a5c8U, 0xcecb8f27f4200f3aU, 0x813f3978f8940984U, 0xa18f07d736b90be5U, 0xc9f2c9cd04674edeU, 0xfc6f7c4045812296U, 0x9dc5ada82b70b59dU, 0xc5371912364ce305U, 0xf684df56c3e01bc6U, 0x9a130b963a6c115cU, 0xc097ce7bc90715b3U, 0xf0bdc21abb48db20U, 0x96769950b50d88f4U, 0xbc143fa4e250eb31U, 0xeb194f8e1ae525fdU, 0x92efd1b8d0cf37beU, 0xb7abc627050305adU, 0xe596b7b0c643c719U, 0x8f7e32ce7bea5c6fU, 0xb35dbf821ae4f38bU, 0xe0352f62a19e306eU, 0x8c213d9da502de45U, 0xaf298d050e4395d6U, 0xdaf3f04651d47b4cU, 0x88d8762bf324cd0fU, 0xab0e93b6efee0053U, 0xd5d238a4abe98068U, 0x85a36366eb71f041U, 0xa70c3c40a64e6c51U, 0xd0cf4b50cfe20765U, 0x82818f1281ed449fU, 0xa321f2d7226895c7U, 0xcbea6f8ceb02bb39U, 0xfee50b7025c36a08U, 0x9f4f2726179a2245U, 0xc722f0ef9d80aad6U, 0xf8ebad2b84e0d58bU, 0x9b934c3b330c8577U, 0xc2781f49ffcfa6d5U, 0xf316271c7fc3908aU, 0x97edd871cfda3a56U, 0xbde94e8e43d0c8ecU, 0xed63a231d4c4fb27U, 0x945e455f24fb1cf8U, 0xb975d6b6ee39e436U, 0xe7d34c64a9c85d44U, 0x90e40fbeea1d3a4aU, 0xb51d13aea4a488ddU, 0xe264589a4dcdab14U, 0x8d7eb76070a08aecU, 0xb0de65388cc8ada8U, 0xdd15fe86affad912U, 0x8a2dbf142dfcc7abU, 0xacb92ed9397bf996U, 0xd7e77a8f87daf7fbU, 0x86f0ac99b4e8dafdU, 0xa8acd7c0222311bcU, 0xd2d80db02aabd62bU, 0x83c7088e1aab65dbU, 0xa4b8cab1a1563f52U, 0xcde6fd5e09abcf26U, 0x80b05e5ac60b6178U, 0xa0dc75f1778e39d6U, 0xc913936dd571c84cU, 0xfb5878494ace3a5fU, 0x9d174b2dcec0e47bU, 0xc45d1df942711d9aU, 0xf5746577930d6500U, 0x9968bf6abbe85f20U, 0xbfc2ef456ae276e8U, 0xefb3ab16c59b14a2U, 0x95d04aee3b80ece5U, 0xbb445da9ca61281fU, 0xea1575143cf97226U, 0x924d692ca61be758U, 0xb6e0c377cfa2e12eU, 0xe498f455c38b997aU, 0x8edf98b59a373fecU, 0xb2977ee300c50fe7U, 0xdf3d5e9bc0f653e1U, 0x8b865b215899f46cU, 0xae67f1e9aec07187U, 0xda01ee641a708de9U, 0x884134fe908658b2U, 0xaa51823e34a7eedeU, 0xd4e5e2cdc1d1ea96U, 0x850fadc09923329eU, 0xa6539930bf6bff45U, 0xcfe87f7cef46ff16U, 0x81f14fae158c5f6eU, 0xa26da3999aef7749U, 0xcb090c8001ab551cU, 0xfdcb4fa002162a63U, 0x9e9f11c4014dda7eU, 0xc646d63501a1511dU, 0xf7d88bc24209a565U, 0x9ae757596946075fU, 0xc1a12d2fc3978937U, 0xf209787bb47d6b84U, 0x9745eb4d50ce6332U, 0xbd176620a501fbffU, 0xec5d3fa8ce427affU, 0x93ba47c980e98cdfU, 0xb8a8d9bbe123f017U, 0xe6d3102ad96cec1dU, 0x9043ea1ac7e41392U, 0xb454e4a179dd1877U, 0xe16a1dc9d8545e94U, 0x8ce2529e2734bb1dU, 0xb01ae745b101e9e4U, 0xdc21a1171d42645dU, 0x899504ae72497ebaU, 0xabfa45da0edbde69U, 0xd6f8d7509292d603U, 0x865b86925b9bc5c2U, 0xa7f26836f282b732U, 0xd1ef0244af2364ffU, 0x8335616aed761f1fU, 0xa402b9c5a8d3a6e7U, 0xcd036837130890a1U, 0x802221226be55a64U, 0xa02aa96b06deb0fdU, 0xc83553c5c8965d3dU, 0xfa42a8b73abbf48cU, 0x9c69a97284b578d7U, 0xc38413cf25e2d70dU, 0xf46518c2ef5b8cd1U, 0x98bf2f79d5993802U, 0xbeeefb584aff8603U, 0xeeaaba2e5dbf6784U, 0x952ab45cfa97a0b2U, 0xba756174393d88dfU, 0xe912b9d1478ceb17U, 0x91abb422ccb812eeU, 0xb616a12b7fe617aaU, 0xe39c49765fdf9d94U, 0x8e41ade9fbebc27dU, 0xb1d219647ae6b31cU, 0xde469fbd99a05fe3U, 0x8aec23d680043beeU, 0xada72ccc20054ae9U, 0xd910f7ff28069da4U, 0x87aa9aff79042286U, 0xa99541bf57452b28U, 0xd3fa922f2d1675f2U, 0x847c9b5d7c2e09b7U, 0xa59bc234db398c25U, 0xcf02b2c21207ef2eU, 0x8161afb94b44f57dU, 0xa1ba1ba79e1632dcU, 0xca28a291859bbf93U, 0xfcb2cb35e702af78U, 0x9defbf01b061adabU, 0xc56baec21c7a1916U, 0xf6c69a72a3989f5bU, 0x9a3c2087a63f6399U, 0xc0cb28a98fcf3c7fU, 0xf0fdf2d3f3c30b9fU, 0x969eb7c47859e743U, 0xbc4665b596706114U, 0xeb57ff22fc0c7959U, 0x9316ff75dd87cbd8U, 0xb7dcbf5354e9beceU, 0xe5d3ef282a242e81U, 0x8fa475791a569d10U, 0xb38d92d760ec4455U, 0xe070f78d3927556aU, 0x8c469ab843b89562U, 0xaf58416654a6babbU, 0xdb2e51bfe9d0696aU, 0x88fcf317f22241e2U, 0xab3c2fddeeaad25aU, 0xd60b3bd56a5586f1U, 0x85c7056562757456U, 0xa738c6bebb12d16cU, 0xd106f86e69d785c7U, 0x82a45b450226b39cU, 0xa34d721642b06084U, 0xcc20ce9bd35c78a5U, 0xff290242c83396ceU, 0x9f79a169bd203e41U, 0xc75809c42c684dd1U, 0xf92e0c3537826145U, 0x9bbcc7a142b17ccbU, 0xc2abf989935ddbfeU, 0xf356f7ebf83552feU, 0x98165af37b2153deU, 0xbe1bf1b059e9a8d6U, 0xeda2ee1c7064130cU, 0x9485d4d1c63e8be7U, 0xb9a74a0637ce2ee1U, 0xe8111c87c5c1ba99U, 0x910ab1d4db9914a0U, 0xb54d5e4a127f59c8U, 0xe2a0b5dc971f303aU, 0x8da471a9de737e24U, 0xb10d8e1456105dadU, 0xdd50f1996b947518U, 0x8a5296ffe33cc92fU, 0xace73cbfdc0bfb7bU, 0xd8210befd30efa5aU, 0x8714a775e3e95c78U, 0xa8d9d1535ce3b396U, 0xd31045a8341ca07cU, 0x83ea2b892091e44dU, 0xa4e4b66b68b65d60U, 0xce1de40642e3f4b9U, 0x80d2ae83e9ce78f3U, 0xa1075a24e4421730U, 0xc94930ae1d529cfcU, 0xfb9b7cd9a4a7443cU, 0x9d412e0806e88aa5U, 0xc491798a08a2ad4eU, 0xf5b5d7ec8acb58a2U, 0x9991a6f3d6bf1765U, 0xbff610b0cc6edd3fU, 0xeff394dcff8a948eU, 0x95f83d0a1fb69cd9U, 0xbb764c4ca7a4440fU, 0xea53df5fd18d5513U, 0x92746b9be2f8552cU, 0xb7118682dbb66a77U, 0xe4d5e82392a40515U, 0x8f05b1163ba6832dU, 0xb2c71d5bca9023f8U, 0xdf78e4b2bd342cf6U, 0x8bab8eefb6409c1aU, 0xae9672aba3d0c320U, 0xda3c0f568cc4f3e8U, 0x8865899617fb1871U, 0xaa7eebfb9df9de8dU, 0xd51ea6fa85785631U, 0x8533285c936b35deU, 0xa67ff273b8460356U, 0xd01fef10a657842cU, 0x8213f56a67f6b29bU, 0xa298f2c501f45f42U, 0xcb3f2f7642717713U, 0xfe0efb53d30dd4d7U, 0x9ec95d1463e8a506U, 0xc67bb4597ce2ce48U, 0xf81aa16fdc1b81daU, 0x9b10a4e5e9913128U, 0xc1d4ce1f63f57d72U, 0xf24a01a73cf2dccfU, 0x976e41088617ca01U, 0xbd49d14aa79dbc82U, 0xec9c459d51852ba2U, 0x93e1ab8252f33b45U, 0xb8da1662e7b00a17U, 0xe7109bfba19c0c9dU, 0x906a617d450187e2U, 0xb484f9dc9641e9daU, 0xe1a63853bbd26451U, 0x8d07e33455637eb2U, 0xb049dc016abc5e5fU, 0xdc5c5301c56b75f7U, 0x89b9b3e11b6329baU, 0xac2820d9623bf429U, 0xd732290fbacaf133U, 0x867f59a9d4bed6c0U, 0xa81f301449ee8c70U, 0xd226fc195c6a2f8cU, 0x83585d8fd9c25db7U, 0xa42e74f3d032f525U, 0xcd3a1230c43fb26fU, 0x80444b5e7aa7cf85U, 0xa0555e361951c366U, 0xc86ab5c39fa63440U, 0xfa856334878fc150U, 0x9c935e00d4b9d8d2U, 0xc3b8358109e84f07U, 0xf4a642e14c6262c8U, 0x98e7e9cccfbd7dbdU, 0xbf21e44003acdd2cU, 0xeeea5d5004981478U, 0x95527a5202df0ccbU, 0xbaa718e68396cffdU, 0xe950df20247c83fdU, 0x91d28b7416cdd27eU, 0xb6472e511c81471dU, 0xe3d8f9e563a198e5U, 0x8e679c2f5e44ff8fU, }; const uint64_t kPower10MantissaLowTable[] = { 0x113faa2906a13b3fU, 0x4ac7ca59a424c507U, 0x5d79bcf00d2df649U, 0xf4d82c2c107973dcU, 0x79071b9b8a4be869U, 0x9748e2826cdee284U, 0xfd1b1b2308169b25U, 0xfe30f0f5e50e20f7U, 0xbdbd2d335e51a935U, 0xad2c788035e61382U, 0x4c3bcb5021afcc31U, 0xdf4abe242a1bbf3dU, 0xd71d6dad34a2af0dU, 0x8672648c40e5ad68U, 0x680efdaf511f18c2U, 0x0212bd1b2566def2U, 0x014bb630f7604b57U, 0x419ea3bd35385e2dU, 0x52064cac828675b9U, 0x7343efebd1940993U, 0x1014ebe6c5f90bf8U, 0xd41a26e077774ef6U, 0x8920b098955522b4U, 0x55b46e5f5d5535b0U, 0xeb2189f734aa831dU, 0xa5e9ec7501d523e4U, 0x47b233c92125366eU, 0x999ec0bb696e840aU, 0xc00670ea43ca250dU, 0x380406926a5e5728U, 0xc605083704f5ecf2U, 0xf7864a44c633682eU, 0x7ab3ee6afbe0211dU, 0x5960ea05bad82964U, 0x6fb92487298e33bdU, 0xa5d3b6d479f8e056U, 0x8f48a4899877186cU, 0x331acdabfe94de87U, 0x9ff0c08b7f1d0b14U, 0x07ecf0ae5ee44dd9U, 0xc9e82cd9f69d6150U, 0xbe311c083a225cd2U, 0x6dbd630a48aaf406U, 0x092cbbccdad5b108U, 0x25bbf56008c58ea5U, 0xaf2af2b80af6f24eU, 0x1af5af660db4aee1U, 0x50d98d9fc890ed4dU, 0xe50ff107bab528a0U, 0x1e53ed49a96272c8U, 0x25e8e89c13bb0f7aU, 0x77b191618c54e9acU, 0xd59df5b9ef6a2417U, 0x4b0573286b44ad1dU, 0x4ee367f9430aec32U, 0x229c41f793cda73fU, 0x6b43527578c1110fU, 0x830a13896b78aaa9U, 0x23cc986bc656d553U, 0x2cbfbe86b7ec8aa8U, 0x7bf7d71432f3d6a9U, 0xdaf5ccd93fb0cc53U, 0xd1b3400f8f9cff68U, 0x23100809b9c21fa1U, 0xabd40a0c2832a78aU, 0x16c90c8f323f516cU, 0xae3da7d97f6792e3U, 0x99cd11cfdf41779cU, 0x40405643d711d583U, 0x482835ea666b2572U, 0xda3243650005eecfU, 0x90bed43e40076a82U, 0x5a7744a6e804a291U, 0x711515d0a205cb36U, 0x0d5a5b44ca873e03U, 0xe858790afe9486c2U, 0x626e974dbe39a872U, 0xfb0a3d212dc8128fU, 0x7ce66634bc9d0b99U, 0x1c1fffc1ebc44e80U, 0xa327ffb266b56220U, 0x4bf1ff9f0062baa8U, 0x6f773fc3603db4a9U, 0xcb550fb4384d21d3U, 0x7e2a53a146606a48U, 0x2eda7444cbfc426dU, 0xfa911155fefb5308U, 0x793555ab7eba27caU, 0x4bc1558b2f3458deU, 0x9eb1aaedfb016f16U, 0x465e15a979c1cadcU, 0x0bfacd89ec191ec9U, 0xcef980ec671f667bU, 0x82b7e12780e7401aU, 0xd1b2ecb8b0908810U, 0x861fa7e6dcb4aa15U, 0x67a791e093e1d49aU, 0xe0c8bb2c5c6d24e0U, 0x58fae9f773886e18U, 0xaf39a475506a899eU, 0x6d8406c952429603U, 0xc8e5087ba6d33b83U, 0xfb1e4a9a90880a64U, 0x5cf2eea09a55067fU, 0xf42faa48c0ea481eU, 0xf13b94daf124da26U, 0x76c53d08d6b70858U, 0x54768c4b0c64ca6eU, 0xa9942f5dcf7dfd09U, 0xd3f93b35435d7c4cU, 0xc47bc5014a1a6dafU, 0x359ab6419ca1091bU, 0xc30163d203c94b62U, 0x79e0de63425dcf1dU, 0x985915fc12f542e4U, 0x3e6f5b7b17b2939dU, 0xa705992ceecf9c42U, 0x50c6ff782a838353U, 0xa4f8bf5635246428U, 0x871b7795e136be99U, 0x28e2557b59846e3fU, 0x331aeada2fe589cfU, 0x3ff0d2c85def7621U, 0x0fed077a756b53a9U, 0xd3e8495912c62894U, 0x64712dd7abbbd95cU, 0xbd8d794d96aacfb3U, 0xecf0d7a0fc5583a0U, 0xf41686c49db57244U, 0x311c2875c522ced5U, 0x7d633293366b828bU, 0xae5dff9c02033197U, 0xd9f57f830283fdfcU, 0xd072df63c324fd7bU, 0x4247cb9e59f71e6dU, 0x52d9be85f074e608U, 0x67902e276c921f8bU, 0x00ba1cd8a3db53b6U, 0x80e8a40eccd228a4U, 0x6122cd128006b2cdU, 0x796b805720085f81U, 0xcbe3303674053bb0U, 0xbedbfc4411068a9cU, 0xee92fb5515482d44U, 0x751bdd152d4d1c4aU, 0xd262d45a78a0635dU, 0x86fb897116c87c34U, 0xd45d35e6ae3d4da0U, 0x8974836059cca109U, 0x2bd1a438703fc94bU, 0x7b6306a34627ddcfU, 0x1a3bc84c17b1d542U, 0x20caba5f1d9e4a93U, 0x547eb47b7282ee9cU, 0xe99e619a4f23aa43U, 0x6405fa00e2ec94d4U, 0xde83bc408dd3dd04U, 0x9624ab50b148d445U, 0x3badd624dd9b0957U, 0xe54ca5d70a80e5d6U, 0x5e9fcf4ccd211f4cU, 0x7647c3200069671fU, 0x29ecd9f40041e073U, 0xf468107100525890U, 0x7182148d4066eeb4U, 0xc6f14cd848405530U, 0xb8ada00e5a506a7cU, 0xa6d90811f0e4851cU, 0x908f4a166d1da663U, 0x9a598e4e043287feU, 0x40eff1e1853f29fdU, 0xd12bee59e68ef47cU, 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0xe0470a63e6bd56c3U, 0x1858ccfce06cac74U, 0x0f37801e0c43ebc8U, 0xd30560258f54e6baU, 0x47c6b82ef32a2069U, 0x4cdc331d57fa5441U, 0xe0133fe4adf8e952U, 0x58180fddd97723a6U, 0x570f09eaa7ea7648U, }; } // namespace Y_ABSL_NAMESPACE_END } // namespace y_absl