/* * Double-precision vector asinh(x) function. * * Copyright (c) 2022-2024, Arm Limited. * SPDX-License-Identifier: MIT OR Apache-2.0 WITH LLVM-exception */ #include "test_defs.h" #include "test_sig.h" #include "v_math.h" const static struct data { uint64x2_t huge_bound, abs_mask, off, mask; #if WANT_SIMD_EXCEPT float64x2_t tiny_bound; #endif float64x2_t lc0, lc2; double lc1, lc3, ln2, lc4; float64x2_t c0, c2, c4, c6, c8, c10, c12, c14, c16, c17; double c1, c3, c5, c7, c9, c11, c13, c15; } data = { #if WANT_SIMD_EXCEPT .tiny_bound = V2 (0x1p-26), #endif /* Even terms of polynomial s.t. asinh(x) is approximated by asinh(x) ~= x + x^3 * (C0 + C1 * x + C2 * x^2 + C3 * x^3 + ...). Generated using Remez, f = (asinh(sqrt(x)) - sqrt(x))/x^(3/2). */ .c0 = V2 (-0x1.55555555554a7p-3), .c1 = 0x1.3333333326c7p-4, .c2 = V2 (-0x1.6db6db68332e6p-5), .c3 = 0x1.f1c71b26fb40dp-6, .c4 = V2 (-0x1.6e8b8b654a621p-6), .c5 = 0x1.1c4daa9e67871p-6, .c6 = V2 (-0x1.c9871d10885afp-7), .c7 = 0x1.7a16e8d9d2ecfp-7, .c8 = V2 (-0x1.3ddca533e9f54p-7), .c9 = 0x1.0becef748dafcp-7, .c10 = V2 (-0x1.b90c7099dd397p-8), .c11 = 0x1.541f2bb1ffe51p-8, .c12 = V2 (-0x1.d217026a669ecp-9), .c13 = 0x1.0b5c7977aaf7p-9, .c14 = V2 (-0x1.e0f37daef9127p-11), .c15 = 0x1.388b5fe542a6p-12, .c16 = V2 (-0x1.021a48685e287p-14), .c17 = V2 (0x1.93d4ba83d34dap-18), .lc0 = V2 (-0x1.ffffffffffff7p-2), .lc1 = 0x1.55555555170d4p-2, .lc2 = V2 (-0x1.0000000399c27p-2), .lc3 = 0x1.999b2e90e94cap-3, .lc4 = -0x1.554e550bd501ep-3, .ln2 = 0x1.62e42fefa39efp-1, .off = V2 (0x3fe6900900000000), .huge_bound = V2 (0x5fe0000000000000), .abs_mask = V2 (0x7fffffffffffffff), .mask = V2 (0xfffULL << 52), }; static float64x2_t NOINLINE VPCS_ATTR special_case (float64x2_t x, float64x2_t y, uint64x2_t abs_mask, uint64x2_t special) { /* Copy sign. */ y = vbslq_f64 (abs_mask, y, x); return v_call_f64 (asinh, x, y, special); } #define N (1 << V_LOG_TABLE_BITS) #define IndexMask (N - 1) struct entry { float64x2_t invc; float64x2_t logc; }; static inline struct entry lookup (uint64x2_t i) { /* Since N is a power of 2, n % N = n & (N - 1). */ struct entry e; uint64_t i0 = (vgetq_lane_u64 (i, 0) >> (52 - V_LOG_TABLE_BITS)) & IndexMask; uint64_t i1 = (vgetq_lane_u64 (i, 1) >> (52 - V_LOG_TABLE_BITS)) & IndexMask; float64x2_t e0 = vld1q_f64 (&__v_log_data.table[i0].invc); float64x2_t e1 = vld1q_f64 (&__v_log_data.table[i1].invc); e.invc = vuzp1q_f64 (e0, e1); e.logc = vuzp2q_f64 (e0, e1); return e; } static inline float64x2_t log_inline (float64x2_t xm, const struct data *d) { uint64x2_t u = vreinterpretq_u64_f64 (xm); uint64x2_t u_off = vsubq_u64 (u, d->off); int64x2_t k = vshrq_n_s64 (vreinterpretq_s64_u64 (u_off), 52); uint64x2_t iz = vsubq_u64 (u, vandq_u64 (u_off, d->mask)); float64x2_t z = vreinterpretq_f64_u64 (iz); struct entry e = lookup (u_off); /* log(x) = log1p(z/c-1) + log(c) + k*Ln2. */ float64x2_t r = vfmaq_f64 (v_f64 (-1.0), z, e.invc); float64x2_t kd = vcvtq_f64_s64 (k); /* hi = r + log(c) + k*Ln2. */ float64x2_t ln2_and_lc4 = vld1q_f64 (&d->ln2); float64x2_t hi = vfmaq_laneq_f64 (vaddq_f64 (e.logc, r), kd, ln2_and_lc4, 0); /* y = r2*(A0 + r*A1 + r2*(A2 + r*A3 + r2*A4)) + hi. */ float64x2_t odd_coeffs = vld1q_f64 (&d->lc1); float64x2_t r2 = vmulq_f64 (r, r); float64x2_t y = vfmaq_laneq_f64 (d->lc2, r, odd_coeffs, 1); float64x2_t p = vfmaq_laneq_f64 (d->lc0, r, odd_coeffs, 0); y = vfmaq_laneq_f64 (y, r2, ln2_and_lc4, 1); y = vfmaq_f64 (p, r2, y); return vfmaq_f64 (hi, y, r2); } /* Double-precision implementation of vector asinh(x). asinh is very sensitive around 1, so it is impractical to devise a single low-cost algorithm which is sufficiently accurate on a wide range of input. Instead we use two different algorithms: asinh(x) = sign(x) * log(|x| + sqrt(x^2 + 1) if |x| >= 1 = sign(x) * (|x| + |x|^3 * P(x^2)) otherwise where log(x) is an optimized log approximation, and P(x) is a polynomial shared with the scalar routine. The greatest observed error 2.79 ULP, in |x| >= 1: _ZGVnN2v_asinh(0x1.2cd9d73ea76a6p+0) got 0x1.ffffd003219dap-1 want 0x1.ffffd003219ddp-1. */ VPCS_ATTR float64x2_t V_NAME_D1 (asinh) (float64x2_t x) { const struct data *d = ptr_barrier (&data); float64x2_t ax = vabsq_f64 (x); uint64x2_t gt1 = vcgeq_f64 (ax, v_f64 (1)); #if WANT_SIMD_EXCEPT uint64x2_t iax = vreinterpretq_u64_f64 (ax); uint64x2_t special = vcgeq_u64 (iax, (d->huge_bound)); uint64x2_t tiny = vcltq_f64 (ax, d->tiny_bound); special = vorrq_u64 (special, tiny); #else uint64x2_t special = vcgeq_f64 (ax, vreinterpretq_f64_u64 (d->huge_bound)); #endif /* Option 1: |x| >= 1. Compute asinh(x) according by asinh(x) = log(x + sqrt(x^2 + 1)). If WANT_SIMD_EXCEPT is enabled, sidestep special values, which will overflow, by setting special lanes to 1. These will be fixed later. */ float64x2_t option_1 = v_f64 (0); if (likely (v_any_u64 (gt1))) { #if WANT_SIMD_EXCEPT float64x2_t xm = v_zerofy_f64 (ax, special); #else float64x2_t xm = ax; #endif option_1 = log_inline ( vaddq_f64 (xm, vsqrtq_f64 (vfmaq_f64 (v_f64 (1), xm, xm))), d); } /* Option 2: |x| < 1. Compute asinh(x) using a polynomial. If WANT_SIMD_EXCEPT is enabled, sidestep special lanes, which will overflow, and tiny lanes, which will underflow, by setting them to 0. They will be fixed later, either by selecting x or falling back to the scalar special-case. The largest observed error in this region is 1.47 ULPs: _ZGVnN2v_asinh(0x1.fdfcd00cc1e6ap-1) got 0x1.c1d6bf874019bp-1 want 0x1.c1d6bf874019cp-1. */ float64x2_t option_2 = v_f64 (0); if (likely (v_any_u64 (vceqzq_u64 (gt1)))) { #if WANT_SIMD_EXCEPT ax = v_zerofy_f64 (ax, vorrq_u64 (tiny, gt1)); #endif float64x2_t x2 = vmulq_f64 (ax, ax), z2 = vmulq_f64 (x2, x2); /* Order-17 Pairwise Horner scheme. */ float64x2_t c13 = vld1q_f64 (&d->c1); float64x2_t c57 = vld1q_f64 (&d->c5); float64x2_t c911 = vld1q_f64 (&d->c9); float64x2_t c1315 = vld1q_f64 (&d->c13); float64x2_t p01 = vfmaq_laneq_f64 (d->c0, x2, c13, 0); float64x2_t p23 = vfmaq_laneq_f64 (d->c2, x2, c13, 1); float64x2_t p45 = vfmaq_laneq_f64 (d->c4, x2, c57, 0); float64x2_t p67 = vfmaq_laneq_f64 (d->c6, x2, c57, 1); float64x2_t p89 = vfmaq_laneq_f64 (d->c8, x2, c911, 0); float64x2_t p1011 = vfmaq_laneq_f64 (d->c10, x2, c911, 1); float64x2_t p1213 = vfmaq_laneq_f64 (d->c12, x2, c1315, 0); float64x2_t p1415 = vfmaq_laneq_f64 (d->c14, x2, c1315, 1); float64x2_t p1617 = vfmaq_f64 (d->c16, x2, d->c17); float64x2_t p = vfmaq_f64 (p1415, z2, p1617); p = vfmaq_f64 (p1213, z2, p); p = vfmaq_f64 (p1011, z2, p); p = vfmaq_f64 (p89, z2, p); p = vfmaq_f64 (p67, z2, p); p = vfmaq_f64 (p45, z2, p); p = vfmaq_f64 (p23, z2, p); p = vfmaq_f64 (p01, z2, p); option_2 = vfmaq_f64 (ax, p, vmulq_f64 (ax, x2)); #if WANT_SIMD_EXCEPT option_2 = vbslq_f64 (tiny, x, option_2); #endif } /* Choose the right option for each lane. */ float64x2_t y = vbslq_f64 (gt1, option_1, option_2); if (unlikely (v_any_u64 (special))) { return special_case (x, y, d->abs_mask, special); } /* Copy sign. */ return vbslq_f64 (d->abs_mask, y, x); } TEST_SIG (V, D, 1, asinh, -10.0, 10.0) TEST_ULP (V_NAME_D1 (asinh), 2.29) TEST_DISABLE_FENV_IF_NOT (V_NAME_D1 (asinh), WANT_SIMD_EXCEPT) TEST_SYM_INTERVAL (V_NAME_D1 (asinh), 0, 0x1p-26, 50000) TEST_SYM_INTERVAL (V_NAME_D1 (asinh), 0x1p-26, 1, 50000) TEST_SYM_INTERVAL (V_NAME_D1 (asinh), 1, 0x1p511, 50000) TEST_SYM_INTERVAL (V_NAME_D1 (asinh), 0x1p511, inf, 40000) /* Test vector asinh 3 times, with control lane < 1, > 1 and special. Ensures the v_sel is choosing the right option in all cases. */ TEST_CONTROL_VALUE (V_NAME_D1 (asinh), 0.5) TEST_CONTROL_VALUE (V_NAME_D1 (asinh), 2) TEST_CONTROL_VALUE (V_NAME_D1 (asinh), 0x1p600)