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| #include "src/math/asin.h" |
| #include "asin_utils.h" |
| #include "src/__support/FPUtil/FEnvImpl.h" |
| #include "src/__support/FPUtil/FPBits.h" |
| #include "src/__support/FPUtil/PolyEval.h" |
| #include "src/__support/FPUtil/double_double.h" |
| #include "src/__support/FPUtil/dyadic_float.h" |
| #include "src/__support/FPUtil/multiply_add.h" |
| #include "src/__support/FPUtil/sqrt.h" |
| #include "src/__support/macros/config.h" |
| #include "src/__support/macros/optimization.h" |
| #include "src/__support/macros/properties/cpu_features.h" |
|
|
| namespace LIBC_NAMESPACE_DECL { |
|
|
| using DoubleDouble = fputil::DoubleDouble; |
| using Float128 = fputil::DyadicFloat<128>; |
|
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| LLVM_LIBC_FUNCTION(double, asin, (double x)) { |
| using FPBits = fputil::FPBits<double>; |
|
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| FPBits xbits(x); |
| int x_exp = xbits.get_biased_exponent(); |
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| if (x_exp < FPBits::EXP_BIAS - 1) { |
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| if (LIBC_UNLIKELY(x_exp < FPBits::EXP_BIAS - 26)) { |
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| #if defined(LIBC_MATH_HAS_SKIP_ACCURATE_PASS) |
| return x; |
| #elif defined(LIBC_TARGET_CPU_HAS_FMA_DOUBLE) |
| return fputil::multiply_add(x, 0x1.0p-54, x); |
| #else |
| if (xbits.abs().uintval() == 0) |
| return x; |
| |
| FPBits eps_bits = FPBits::min_normal(); |
| eps_bits.set_sign(xbits.sign()); |
| double eps = eps_bits.get_val(); |
| double normalize_const = (x_exp == 0) ? eps : 0.0; |
| double scaled_normal = |
| fputil::multiply_add(x + normalize_const, 0x1.0p54, eps); |
| return fputil::multiply_add(scaled_normal, 0x1.0p-54, -normalize_const); |
| #endif |
| } |
|
|
| #ifdef LIBC_MATH_HAS_SKIP_ACCURATE_PASS |
| return x * asin_eval(x * x); |
| #else |
| unsigned idx; |
| DoubleDouble x_sq = fputil::exact_mult(x, x); |
| double err = xbits.abs().get_val() * 0x1.0p-51; |
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| DoubleDouble p = asin_eval(x_sq, idx, err); |
| |
| DoubleDouble r0 = fputil::exact_mult(x, p.hi); |
| double r_lo = fputil::multiply_add(x, p.lo, r0.lo); |
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| double r_upper = r0.hi + (r_lo + err); |
| double r_lower = r0.hi + (r_lo - err); |
|
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| if (LIBC_LIKELY(r_upper == r_lower)) |
| return r_upper; |
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| idx = static_cast<unsigned>(fputil::nearest_integer(x_sq.hi * 0x1.0p6)); |
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| Float128 x_f128(x); |
|
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| #ifdef LIBC_TARGET_CPU_HAS_FMA_DOUBLE |
| |
| Float128 u_hi( |
| fputil::multiply_add(static_cast<double>(idx), -0x1.0p-6, x_sq.hi)); |
| Float128 u = fputil::quick_add(u_hi, Float128(x_sq.lo)); |
| #else |
| Float128 x_sq_f128 = fputil::quick_mul(x_f128, x_f128); |
| Float128 u = fputil::quick_add( |
| x_sq_f128, Float128(static_cast<double>(idx) * (-0x1.0p-6))); |
| #endif |
|
|
| Float128 p_f128 = asin_eval(u, idx); |
| Float128 r = fputil::quick_mul(x_f128, p_f128); |
|
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| return static_cast<double>(r); |
| #endif |
| } |
| |
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| double x_abs = xbits.abs().get_val(); |
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| |
| constexpr double SIGN[2] = {1.0, -1.0}; |
| double x_sign = SIGN[xbits.is_neg()]; |
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| if (LIBC_UNLIKELY(x_exp >= FPBits::EXP_BIAS)) { |
| |
| if (x_abs == 1.0) { |
| |
| return fputil::multiply_add(x_sign, PI_OVER_TWO.hi, |
| x_sign * PI_OVER_TWO.lo); |
| } |
| |
| if (xbits.is_quiet_nan()) |
| return x; |
|
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| |
| if (!xbits.is_nan()) |
| fputil::set_errno_if_required(EDOM); |
|
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| fputil::raise_except_if_required(FE_INVALID); |
| return FPBits::quiet_nan().get_val(); |
| } |
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| double u = fputil::multiply_add(x_abs, -0.5, 0.5); |
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| double v_hi = fputil::sqrt<double>(u); |
|
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| #ifdef LIBC_MATH_HAS_SKIP_ACCURATE_PASS |
| double p = asin_eval(u); |
| double r = x_sign * fputil::multiply_add(-2.0 * v_hi, p, PI_OVER_TWO.hi); |
| return r; |
| #else |
|
|
| #ifdef LIBC_TARGET_CPU_HAS_FMA_DOUBLE |
| double h = fputil::multiply_add(v_hi, -v_hi, u); |
| #else |
| DoubleDouble v_hi_sq = fputil::exact_mult(v_hi, v_hi); |
| double h = (u - v_hi_sq.hi) - v_hi_sq.lo; |
| #endif |
|
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| |
| double vh = v_hi * 2.0; |
| double vl = h / v_hi; |
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| |
| unsigned idx; |
| double err = vh * 0x1.0p-51; |
|
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| DoubleDouble p = asin_eval(DoubleDouble{0.0, u}, idx, err); |
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| |
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| DoubleDouble r0 = fputil::quick_mult(DoubleDouble{vl, vh}, p); |
| DoubleDouble r = fputil::exact_add(PI_OVER_TWO.hi, -r0.hi); |
|
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| double r_lo = PI_OVER_TWO.lo - r0.lo + r.lo; |
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| #ifdef LIBC_TARGET_CPU_HAS_FMA_DOUBLE |
| double r_upper = fputil::multiply_add( |
| r.hi, x_sign, fputil::multiply_add(r_lo, x_sign, err)); |
| double r_lower = fputil::multiply_add( |
| r.hi, x_sign, fputil::multiply_add(r_lo, x_sign, -err)); |
| #else |
| r_lo *= x_sign; |
| r.hi *= x_sign; |
| double r_upper = r.hi + (r_lo + err); |
| double r_lower = r.hi + (r_lo - err); |
| #endif |
|
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| if (LIBC_LIKELY(r_upper == r_lower)) |
| return r_upper; |
|
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| idx = static_cast<unsigned>(fputil::nearest_integer(u * 0x1.0p6)); |
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| #ifdef LIBC_TARGET_CPU_HAS_FMA_DOUBLE |
| double vl_lo = fputil::multiply_add(-v_hi, vl, h) / v_hi; |
| #else |
| DoubleDouble vh_vl = fputil::exact_mult(v_hi, vl); |
| double vl_lo = ((h - vh_vl.hi) - vh_vl.lo) / v_hi; |
| #endif |
| |
| double t = h * (-0.25) / u; |
| double vll = fputil::multiply_add(vl, t, vl_lo); |
| |
| Float128 m_v = fputil::quick_add( |
| Float128(vh), fputil::quick_add(Float128(vl), Float128(vll))); |
| m_v.sign = Sign::NEG; |
|
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| |
| |
| Float128 y_f128(fputil::multiply_add(static_cast<double>(idx), -0x1.0p-6, u)); |
|
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| Float128 p_f128 = asin_eval(y_f128, idx); |
| Float128 r0_f128 = fputil::quick_mul(m_v, p_f128); |
| Float128 r_f128 = fputil::quick_add(PI_OVER_TWO_F128, r0_f128); |
|
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| if (xbits.is_neg()) |
| r_f128.sign = Sign::NEG; |
|
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| return static_cast<double>(r_f128); |
| #endif |
| } |
|
|
| } |
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