//===-- Implementation of hypotf function ---------------------------------===// // // 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 // //===----------------------------------------------------------------------===// #ifndef LLVM_LIBC_SRC_SUPPORT_FPUTIL_HYPOT_H #define LLVM_LIBC_SRC_SUPPORT_FPUTIL_HYPOT_H #include "BasicOperations.h" #include "FEnvImpl.h" #include "FPBits.h" #include "src/__support/CPP/Bit.h" #include "src/__support/CPP/TypeTraits.h" namespace __llvm_libc { namespace fputil { namespace internal { template static inline T find_leading_one(T mant, int &shift_length); // The following overloads are matched based on what is accepted by // __builtin_clz* rather than using the exactly-sized aliases from stdint.h // (such as uint32_t). There are 3 overloads even though 2 will only ever be // used by a specific platform, since unsigned long varies in size depending on // the word size of the architecture. template <> inline unsigned int find_leading_one(unsigned int mant, int &shift_length) { shift_length = 0; if (mant > 0) { shift_length = (sizeof(mant) * 8) - 1 - __builtin_clz(mant); } return 1U << shift_length; } template <> inline unsigned long find_leading_one(unsigned long mant, int &shift_length) { shift_length = 0; if (mant > 0) { shift_length = (sizeof(mant) * 8) - 1 - __builtin_clzl(mant); } return 1UL << shift_length; } template <> inline unsigned long long find_leading_one(unsigned long long mant, int &shift_length) { shift_length = 0; if (mant > 0) { shift_length = (sizeof(mant) * 8) - 1 - __builtin_clzll(mant); } return 1ULL << shift_length; } } // namespace internal template struct DoubleLength; template <> struct DoubleLength { using Type = uint32_t; }; template <> struct DoubleLength { using Type = uint64_t; }; template <> struct DoubleLength { using Type = __uint128_t; }; // Correctly rounded IEEE 754 HYPOT(x, y) with round to nearest, ties to even. // // Algorithm: // - Let a = max(|x|, |y|), b = min(|x|, |y|), then we have that: // a <= sqrt(a^2 + b^2) <= min(a + b, a*sqrt(2)) // 1. So if b < eps(a)/2, then HYPOT(x, y) = a. // // - Moreover, the exponent part of HYPOT(x, y) is either the same or 1 more // than the exponent part of a. // // 2. For the remaining cases, we will use the digit-by-digit (shift-and-add) // algorithm to compute SQRT(Z): // // - For Y = y0.y1...yn... = SQRT(Z), // let Y(n) = y0.y1...yn be the first n fractional digits of Y. // // - The nth scaled residual R(n) is defined to be: // R(n) = 2^n * (Z - Y(n)^2) // // - Since Y(n) = Y(n - 1) + yn * 2^(-n), the scaled residual // satisfies the following recurrence formula: // R(n) = 2*R(n - 1) - yn*(2*Y(n - 1) + 2^(-n)), // with the initial conditions: // Y(0) = y0, and R(0) = Z - y0. // // - So the nth fractional digit of Y = SQRT(Z) can be decided by: // yn = 1 if 2*R(n - 1) >= 2*Y(n - 1) + 2^(-n), // 0 otherwise. // // 3. Precision analysis: // // - Notice that in the decision function: // 2*R(n - 1) >= 2*Y(n - 1) + 2^(-n), // the right hand side only uses up to the 2^(-n)-bit, and both sides are // non-negative, so R(n - 1) can be truncated at the 2^(-(n + 1))-bit, so // that 2*R(n - 1) is corrected up to the 2^(-n)-bit. // // - Thus, in order to round SQRT(a^2 + b^2) correctly up to n-fractional // bits, we need to perform the summation (a^2 + b^2) correctly up to (2n + // 2)-fractional bits, and the remaining bits are sticky bits (i.e. we only // care if they are 0 or > 0), and the comparisons, additions/subtractions // can be done in n-fractional bits precision. // // - For single precision (float), we can use uint64_t to store the sum a^2 + // b^2 exact up to (2n + 2)-fractional bits. // // - Then we can feed this sum into the digit-by-digit algorithm for SQRT(Z) // described above. // // // Special cases: // - HYPOT(x, y) is +Inf if x or y is +Inf or -Inf; else // - HYPOT(x, y) is NaN if x or y is NaN. // template ::Value, int> = 0> static inline T hypot(T x, T y) { using FPBits_t = FPBits; using UIntType = typename FPBits::UIntType; using DUIntType = typename DoubleLength::Type; FPBits_t x_bits(x), y_bits(y); if (x_bits.is_inf() || y_bits.is_inf()) { return T(FPBits_t::inf()); } if (x_bits.is_nan()) { return x; } if (y_bits.is_nan()) { return y; } uint16_t x_exp = x_bits.get_unbiased_exponent(); uint16_t y_exp = y_bits.get_unbiased_exponent(); uint16_t exp_diff = (x_exp > y_exp) ? (x_exp - y_exp) : (y_exp - x_exp); if ((exp_diff >= MantissaWidth::VALUE + 2) || (x == 0) || (y == 0)) { return abs(x) + abs(y); } uint16_t a_exp, b_exp, out_exp; UIntType a_mant, b_mant; DUIntType a_mant_sq, b_mant_sq; bool sticky_bits; if (abs(x) >= abs(y)) { a_exp = x_exp; a_mant = x_bits.get_mantissa(); b_exp = y_exp; b_mant = y_bits.get_mantissa(); } else { a_exp = y_exp; a_mant = y_bits.get_mantissa(); b_exp = x_exp; b_mant = x_bits.get_mantissa(); } out_exp = a_exp; // Add an extra bit to simplify the final rounding bit computation. constexpr UIntType ONE = UIntType(1) << (MantissaWidth::VALUE + 1); a_mant <<= 1; b_mant <<= 1; UIntType leading_one; int y_mant_width; if (a_exp != 0) { leading_one = ONE; a_mant |= ONE; y_mant_width = MantissaWidth::VALUE + 1; } else { leading_one = internal::find_leading_one(a_mant, y_mant_width); a_exp = 1; } if (b_exp != 0) { b_mant |= ONE; } else { b_exp = 1; } a_mant_sq = static_cast(a_mant) * a_mant; b_mant_sq = static_cast(b_mant) * b_mant; // At this point, a_exp >= b_exp > a_exp - 25, so in order to line up aSqMant // and bSqMant, we need to shift bSqMant to the right by (a_exp - b_exp) bits. // But before that, remember to store the losing bits to sticky. // The shift length is for a^2 and b^2, so it's double of the exponent // difference between a and b. uint16_t shift_length = 2 * (a_exp - b_exp); sticky_bits = ((b_mant_sq & ((DUIntType(1) << shift_length) - DUIntType(1))) != DUIntType(0)); b_mant_sq >>= shift_length; DUIntType sum = a_mant_sq + b_mant_sq; if (sum >= (DUIntType(1) << (2 * y_mant_width + 2))) { // a^2 + b^2 >= 4* leading_one^2, so we will need an extra bit to the left. if (leading_one == ONE) { // For normal result, we discard the last 2 bits of the sum and increase // the exponent. sticky_bits = sticky_bits || ((sum & 0x3U) != 0); sum >>= 2; ++out_exp; if (out_exp >= FPBits_t::MAX_EXPONENT) { return T(FPBits_t::inf()); } } else { // For denormal result, we simply move the leading bit of the result to // the left by 1. leading_one <<= 1; ++y_mant_width; } } UIntType y_new = leading_one; UIntType r = static_cast(sum >> y_mant_width) - leading_one; UIntType tail_bits = static_cast(sum) & (leading_one - 1); for (UIntType current_bit = leading_one >> 1; current_bit; current_bit >>= 1) { r = (r << 1) + ((tail_bits & current_bit) ? 1 : 0); UIntType tmp = (y_new << 1) + current_bit; // 2*y_new(n - 1) + 2^(-n) if (r >= tmp) { r -= tmp; y_new += current_bit; } } bool round_bit = y_new & UIntType(1); bool lsb = y_new & UIntType(2); if (y_new >= ONE) { y_new -= ONE; if (out_exp == 0) { out_exp = 1; } } y_new >>= 1; // Round to the nearest, tie to even. switch (get_round()) { case FE_TONEAREST: // Round to nearest, ties to even if (round_bit && (lsb || sticky_bits || (r != 0))) ++y_new; break; case FE_UPWARD: if (round_bit || sticky_bits || (r != 0)) ++y_new; break; } if (y_new >= (ONE >> 1)) { y_new -= ONE >> 1; ++out_exp; if (out_exp >= FPBits_t::MAX_EXPONENT) { return T(FPBits_t::inf()); } } y_new |= static_cast(out_exp) << MantissaWidth::VALUE; return __llvm_libc::bit_cast(y_new); } } // namespace fputil } // namespace __llvm_libc #endif // LLVM_LIBC_SRC_SUPPORT_FPUTIL_HYPOT_H