glibc/sysdeps/aarch64/fpu/exp10_sve.c

/* Double-precision vector (SVE) exp10 function.

   Copyright (C) 2023-2025 Free Software Foundation, Inc.
   This file is part of the GNU C Library.

   The GNU C Library is free software; you can redistribute it and/or
   modify it under the terms of the GNU Lesser General Public
   License as published by the Free Software Foundation; either
   version 2.1 of the License, or (at your option) any later version.

   The GNU C Library is distributed in the hope that it will be useful,
   but WITHOUT ANY WARRANTY; without even the implied warranty of
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
   Lesser General Public License for more details.

   You should have received a copy of the GNU Lesser General Public
   License along with the GNU C Library; if not, see
   <https://www.gnu.org/licenses/>.  */

#include "sv_math.h"

#define SpecialBound 307.0 /* floor (log10 (2^1023)).  */

static const struct data
{
  double c1, c3, c2, c4, c0;
  double shift, log10_2, log2_10_hi, log2_10_lo, scale_thres, special_bound;
} data = {
  /* Coefficients generated using Remez algorithm.
     rel error: 0x1.9fcb9b3p-60
     abs error: 0x1.a20d9598p-60 in [ -log10(2)/128, log10(2)/128 ]
     max ulp err 0.52 +0.5.  */
  .c0 = 0x1.26bb1bbb55516p1,
  .c1 = 0x1.53524c73cd32ap1,
  .c2 = 0x1.0470591daeafbp1,
  .c3 = 0x1.2bd77b1361ef6p0,
  .c4 = 0x1.142b5d54e9621p-1,
  /* 1.5*2^46+1023. This value is further explained below.  */
  .shift = 0x1.800000000ffc0p+46,
  .log10_2 = 0x1.a934f0979a371p1,     /* 1/log2(10).  */
  .log2_10_hi = 0x1.34413509f79ffp-2, /* log2(10).  */
  .log2_10_lo = -0x1.9dc1da994fd21p-59,
  .scale_thres = 1280.0,
  .special_bound = SpecialBound,
};

#define SpecialOffset 0x6000000000000000 /* 0x1p513.  */
/* SpecialBias1 + SpecialBias1 = asuint(1.0).  */
#define SpecialBias1 0x7000000000000000 /* 0x1p769.  */
#define SpecialBias2 0x3010000000000000 /* 0x1p-254.  */

/* Update of both special and non-special cases, if any special case is
   detected.  */
static inline svfloat64_t
special_case (svbool_t pg, svfloat64_t s, svfloat64_t y, svfloat64_t n,
	      const struct data *d)
{
  /* s=2^n may overflow, break it up into s=s1*s2,
     such that exp = s + s*y can be computed as s1*(s2+s2*y)
     and s1*s1 overflows only if n>0.  */

  /* If n<=0 then set b to 0x6, 0 otherwise.  */
  svbool_t p_sign = svcmple (pg, n, 0.0); /* n <= 0.  */
  svuint64_t b = svdup_u64_z (p_sign, SpecialOffset);

  /* Set s1 to generate overflow depending on sign of exponent n.  */
  svfloat64_t s1 = svreinterpret_f64 (svsubr_x (pg, b, SpecialBias1));
  /* Offset s to avoid overflow in final result if n is below threshold.  */
  svfloat64_t s2 = svreinterpret_f64 (
      svadd_x (pg, svsub_x (pg, svreinterpret_u64 (s), SpecialBias2), b));

  /* |n| > 1280 => 2^(n) overflows.  */
  svbool_t p_cmp = svacgt (pg, n, d->scale_thres);

  svfloat64_t r1 = svmul_x (svptrue_b64 (), s1, s1);
  svfloat64_t r2 = svmla_x (pg, s2, s2, y);
  svfloat64_t r0 = svmul_x (svptrue_b64 (), r2, s1);

  return svsel (p_cmp, r1, r0);
}

/* Fast vector implementation of exp10 using FEXPA instruction.
   Maximum measured error is 1.02 ulp.
   SV_NAME_D1 (exp10)(-0x1.2862fec805e58p+2) got 0x1.885a89551d782p-16
					    want 0x1.885a89551d781p-16.  */
svfloat64_t SV_NAME_D1 (exp10) (svfloat64_t x, svbool_t pg)
{
  const struct data *d = ptr_barrier (&data);
  svbool_t no_big_scale = svacle (pg, x, d->special_bound);
  svbool_t special = svnot_z (pg, no_big_scale);

  /* n = round(x/(log10(2)/N)).  */
  svfloat64_t shift = sv_f64 (d->shift);
  svfloat64_t z = svmla_x (pg, shift, x, d->log10_2);
  svfloat64_t n = svsub_x (pg, z, shift);

  /* r = x - n*log10(2)/N.  */
  svfloat64_t log2_10 = svld1rq (svptrue_b64 (), &d->log2_10_hi);
  svfloat64_t r = x;
  r = svmls_lane (r, n, log2_10, 0);
  r = svmls_lane (r, n, log2_10, 1);

  /* scale = 2^(n/N), computed using FEXPA. FEXPA does not propagate NaNs, so
     for consistent NaN handling we have to manually propagate them. This
     comes at significant performance cost.  */
  svuint64_t u = svreinterpret_u64 (z);
  svfloat64_t scale = svexpa (u);
  svfloat64_t c24 = svld1rq (svptrue_b64 (), &d->c2);
  /* Approximate exp10(r) using polynomial.  */
  svfloat64_t r2 = svmul_x (svptrue_b64 (), r, r);
  svfloat64_t p12 = svmla_lane (sv_f64 (d->c1), r, c24, 0);
  svfloat64_t p34 = svmla_lane (sv_f64 (d->c3), r, c24, 1);
  svfloat64_t p14 = svmla_x (pg, p12, p34, r2);

  svfloat64_t y = svmla_x (pg, svmul_x (svptrue_b64 (), r, d->c0), r2, p14);

  /* Assemble result as exp10(x) = 2^n * exp10(r).  If |x| > SpecialBound
     multiplication may overflow, so use special case routine.  */
  if (__glibc_unlikely (svptest_any (pg, special)))
    {
      /* FEXPA zeroes the sign bit, however the sign is meaningful to the
	 special case function so needs to be copied.
	 e = sign bit of u << 46.  */
      svuint64_t e = svand_x (pg, svlsl_x (pg, u, 46), 0x8000000000000000);
      /* Copy sign to scale.  */
      scale = svreinterpret_f64 (svadd_x (pg, e, svreinterpret_u64 (scale)));
      return special_case (pg, scale, y, n, d);
    }

  /* No special case.  */
  return svmla_x (pg, scale, scale, y);
}
aarch64: Add vector implementations of exp10 routines Double-precision routines either reuse the exp table (AdvSIMD) or use SVE FEXPA intruction. 2023-10-05 16:10:52 +00:00			`/* Double-precision vector (SVE) exp10 function.`

Update copyright dates with scripts/update-copyrights 2025-01-01 18:14:45 +00:00			`Copyright (C) 2023-2025 Free Software Foundation, Inc.`
aarch64: Add vector implementations of exp10 routines Double-precision routines either reuse the exp table (AdvSIMD) or use SVE FEXPA intruction. 2023-10-05 16:10:52 +00:00			`This file is part of the GNU C Library.`

			`The GNU C Library is free software; you can redistribute it and/or`
			`modify it under the terms of the GNU Lesser General Public`
			`License as published by the Free Software Foundation; either`
			`version 2.1 of the License, or (at your option) any later version.`

			`The GNU C Library is distributed in the hope that it will be useful,`
			`but WITHOUT ANY WARRANTY; without even the implied warranty of`
			`MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU`
			`Lesser General Public License for more details.`

			`You should have received a copy of the GNU Lesser General Public`
			`License along with the GNU C Library; if not, see`
			`<https://www.gnu.org/licenses/>. */`

			`#include "sv_math.h"`

			`#define SpecialBound 307.0 /* floor (log10 (2^1023)). */`

			`static const struct data`
			`{`
Aarch64: Improve codegen in SVE exp and users, and update expf_inline Use unpredicted muls, and improve memory access. 7%, 3% and 1% improvement in throughput microbenchmark on Neoverse V1, for exp, exp2 and cosh respectively. Reviewed-by: Wilco Dijkstra <Wilco.Dijkstra@arm.com> 2025-02-13 17:54:46 +00:00			`double c1, c3, c2, c4, c0;`
aarch64: Add vector implementations of exp10 routines Double-precision routines either reuse the exp table (AdvSIMD) or use SVE FEXPA intruction. 2023-10-05 16:10:52 +00:00			`double shift, log10_2, log2_10_hi, log2_10_lo, scale_thres, special_bound;`
			`} data = {`
			`/* Coefficients generated using Remez algorithm.`
			`rel error: 0x1.9fcb9b3p-60`
			`abs error: 0x1.a20d9598p-60 in [ -log10(2)/128, log10(2)/128 ]`
			`max ulp err 0.52 +0.5. */`
Aarch64: Improve codegen in SVE exp and users, and update expf_inline Use unpredicted muls, and improve memory access. 7%, 3% and 1% improvement in throughput microbenchmark on Neoverse V1, for exp, exp2 and cosh respectively. Reviewed-by: Wilco Dijkstra <Wilco.Dijkstra@arm.com> 2025-02-13 17:54:46 +00:00			`.c0 = 0x1.26bb1bbb55516p1,`
			`.c1 = 0x1.53524c73cd32ap1,`
			`.c2 = 0x1.0470591daeafbp1,`
			`.c3 = 0x1.2bd77b1361ef6p0,`
			`.c4 = 0x1.142b5d54e9621p-1,`
aarch64: Add vector implementations of exp10 routines Double-precision routines either reuse the exp table (AdvSIMD) or use SVE FEXPA intruction. 2023-10-05 16:10:52 +00:00			`/* 1.52^46+1023. This value is further explained below. /`
			`.shift = 0x1.800000000ffc0p+46,`
			`.log10_2 = 0x1.a934f0979a371p1, /* 1/log2(10). */`
			`.log2_10_hi = 0x1.34413509f79ffp-2, /* log2(10). */`
			`.log2_10_lo = -0x1.9dc1da994fd21p-59,`
			`.scale_thres = 1280.0,`
			`.special_bound = SpecialBound,`
			`};`

			`#define SpecialOffset 0x6000000000000000 /* 0x1p513. */`
			`/* SpecialBias1 + SpecialBias1 = asuint(1.0). */`
			`#define SpecialBias1 0x7000000000000000 /* 0x1p769. */`
			`#define SpecialBias2 0x3010000000000000 /* 0x1p-254. */`

			`/* Update of both special and non-special cases, if any special case is`
			`detected. */`
			`static inline svfloat64_t`
			`special_case (svbool_t pg, svfloat64_t s, svfloat64_t y, svfloat64_t n,`
			`const struct data *d)`
			`{`
			`/* s=2^n may overflow, break it up into s=s1*s2,`
			`such that exp = s + sy can be computed as s1(s2+s2*y)`
			`and s1s1 overflows only if n>0. /`

			`/* If n<=0 then set b to 0x6, 0 otherwise. */`
			`svbool_t p_sign = svcmple (pg, n, 0.0); /* n <= 0. */`
			`svuint64_t b = svdup_u64_z (p_sign, SpecialOffset);`

			`/* Set s1 to generate overflow depending on sign of exponent n. */`
			`svfloat64_t s1 = svreinterpret_f64 (svsubr_x (pg, b, SpecialBias1));`
			`/* Offset s to avoid overflow in final result if n is below threshold. */`
			`svfloat64_t s2 = svreinterpret_f64 (`
			`svadd_x (pg, svsub_x (pg, svreinterpret_u64 (s), SpecialBias2), b));`

			`/* \|n\| > 1280 => 2^(n) overflows. */`
			`svbool_t p_cmp = svacgt (pg, n, d->scale_thres);`

Aarch64: Improve codegen in SVE exp and users, and update expf_inline Use unpredicted muls, and improve memory access. 7%, 3% and 1% improvement in throughput microbenchmark on Neoverse V1, for exp, exp2 and cosh respectively. Reviewed-by: Wilco Dijkstra <Wilco.Dijkstra@arm.com> 2025-02-13 17:54:46 +00:00			`svfloat64_t r1 = svmul_x (svptrue_b64 (), s1, s1);`
aarch64: Add vector implementations of exp10 routines Double-precision routines either reuse the exp table (AdvSIMD) or use SVE FEXPA intruction. 2023-10-05 16:10:52 +00:00			`svfloat64_t r2 = svmla_x (pg, s2, s2, y);`
Aarch64: Improve codegen in SVE exp and users, and update expf_inline Use unpredicted muls, and improve memory access. 7%, 3% and 1% improvement in throughput microbenchmark on Neoverse V1, for exp, exp2 and cosh respectively. Reviewed-by: Wilco Dijkstra <Wilco.Dijkstra@arm.com> 2025-02-13 17:54:46 +00:00			`svfloat64_t r0 = svmul_x (svptrue_b64 (), r2, s1);`
aarch64: Add vector implementations of exp10 routines Double-precision routines either reuse the exp table (AdvSIMD) or use SVE FEXPA intruction. 2023-10-05 16:10:52 +00:00
			`return svsel (p_cmp, r1, r0);`
			`}`

			`/* Fast vector implementation of exp10 using FEXPA instruction.`
			`Maximum measured error is 1.02 ulp.`
			`SV_NAME_D1 (exp10)(-0x1.2862fec805e58p+2) got 0x1.885a89551d782p-16`
			`want 0x1.885a89551d781p-16. */`
			`svfloat64_t SV_NAME_D1 (exp10) (svfloat64_t x, svbool_t pg)`
			`{`
			`const struct data *d = ptr_barrier (&data);`
			`svbool_t no_big_scale = svacle (pg, x, d->special_bound);`
			`svbool_t special = svnot_z (pg, no_big_scale);`

			`/* n = round(x/(log10(2)/N)). */`
			`svfloat64_t shift = sv_f64 (d->shift);`
			`svfloat64_t z = svmla_x (pg, shift, x, d->log10_2);`
			`svfloat64_t n = svsub_x (pg, z, shift);`

			`/* r = x - nlog10(2)/N. /`
			`svfloat64_t log2_10 = svld1rq (svptrue_b64 (), &d->log2_10_hi);`
			`svfloat64_t r = x;`
			`r = svmls_lane (r, n, log2_10, 0);`
			`r = svmls_lane (r, n, log2_10, 1);`

			`/* scale = 2^(n/N), computed using FEXPA. FEXPA does not propagate NaNs, so`
			`for consistent NaN handling we have to manually propagate them. This`
			`comes at significant performance cost. */`
			`svuint64_t u = svreinterpret_u64 (z);`
			`svfloat64_t scale = svexpa (u);`
Aarch64: Improve codegen in SVE exp and users, and update expf_inline Use unpredicted muls, and improve memory access. 7%, 3% and 1% improvement in throughput microbenchmark on Neoverse V1, for exp, exp2 and cosh respectively. Reviewed-by: Wilco Dijkstra <Wilco.Dijkstra@arm.com> 2025-02-13 17:54:46 +00:00			`svfloat64_t c24 = svld1rq (svptrue_b64 (), &d->c2);`
aarch64: Add vector implementations of exp10 routines Double-precision routines either reuse the exp table (AdvSIMD) or use SVE FEXPA intruction. 2023-10-05 16:10:52 +00:00			`/* Approximate exp10(r) using polynomial. */`
Aarch64: Improve codegen in SVE exp and users, and update expf_inline Use unpredicted muls, and improve memory access. 7%, 3% and 1% improvement in throughput microbenchmark on Neoverse V1, for exp, exp2 and cosh respectively. Reviewed-by: Wilco Dijkstra <Wilco.Dijkstra@arm.com> 2025-02-13 17:54:46 +00:00			`svfloat64_t r2 = svmul_x (svptrue_b64 (), r, r);`
			`svfloat64_t p12 = svmla_lane (sv_f64 (d->c1), r, c24, 0);`
			`svfloat64_t p34 = svmla_lane (sv_f64 (d->c3), r, c24, 1);`
			`svfloat64_t p14 = svmla_x (pg, p12, p34, r2);`

			`svfloat64_t y = svmla_x (pg, svmul_x (svptrue_b64 (), r, d->c0), r2, p14);`
aarch64: Add vector implementations of exp10 routines Double-precision routines either reuse the exp table (AdvSIMD) or use SVE FEXPA intruction. 2023-10-05 16:10:52 +00:00
			`/* Assemble result as exp10(x) = 2^n * exp10(r). If \|x\| > SpecialBound`
			`multiplication may overflow, so use special case routine. */`
			`if (__glibc_unlikely (svptest_any (pg, special)))`
			`{`
			`/* FEXPA zeroes the sign bit, however the sign is meaningful to the`
			`special case function so needs to be copied.`
			`e = sign bit of u << 46. */`
			`svuint64_t e = svand_x (pg, svlsl_x (pg, u, 46), 0x8000000000000000);`
			`/* Copy sign to scale. */`
			`scale = svreinterpret_f64 (svadd_x (pg, e, svreinterpret_u64 (scale)));`
			`return special_case (pg, scale, y, n, d);`
			`}`

			`/* No special case. */`
			`return svmla_x (pg, scale, scale, y);`
			`}`