pl/math/atan2_2u5.c

*412f47f9SXin Li/*
*412f47f9SXin Li * Double-precision scalar atan2(x) function.
*412f47f9SXin Li *
*412f47f9SXin Li * Copyright (c) 2021-2023, Arm Limited.
*412f47f9SXin Li * SPDX-License-Identifier: MIT OR Apache-2.0 WITH LLVM-exception
*412f47f9SXin Li */
*412f47f9SXin Li
*412f47f9SXin Li#include <stdbool.h>
*412f47f9SXin Li
*412f47f9SXin Li#include "atan_common.h"
*412f47f9SXin Li#include "math_config.h"
*412f47f9SXin Li#include "pl_sig.h"
*412f47f9SXin Li#include "pl_test.h"
*412f47f9SXin Li
*412f47f9SXin Li#define Pi (0x1.921fb54442d18p+1)
*412f47f9SXin Li#define PiOver2 (0x1.921fb54442d18p+0)
*412f47f9SXin Li#define PiOver4 (0x1.921fb54442d18p-1)
*412f47f9SXin Li#define SignMask (0x8000000000000000)
*412f47f9SXin Li#define ExpMask (0x7ff0000000000000)
*412f47f9SXin Li
*412f47f9SXin Li/* We calculate atan2 by P(n/d), where n and d are similar to the input
*412f47f9SXin Li   arguments, and P is a polynomial. Evaluating P(x) requires calculating x^8,
*412f47f9SXin Li   which may underflow if n and d have very different magnitude.
*412f47f9SXin Li   POW8_EXP_UFLOW_BOUND is the lower bound of the difference in exponents of n
*412f47f9SXin Li   and d for which P underflows, and is used to special-case such inputs.  */
*412f47f9SXin Li#define POW8_EXP_UFLOW_BOUND 62
*412f47f9SXin Li
*412f47f9SXin Listatic inline int64_t
*412f47f9SXin Libiased_exponent (double f)
*412f47f9SXin Li{
*412f47f9SXin Li  uint64_t fi = asuint64 (f);
*412f47f9SXin Li  return (fi & ExpMask) >> 52;
*412f47f9SXin Li}
*412f47f9SXin Li
*412f47f9SXin Li/* Fast implementation of scalar atan2. Largest errors are when y and x are
*412f47f9SXin Li   close together. The greatest observed error is 2.28 ULP:
*412f47f9SXin Li   atan2(-0x1.5915b1498e82fp+732, 0x1.54d11ef838826p+732)
*412f47f9SXin Li   got -0x1.954f42f1fa841p-1 want -0x1.954f42f1fa843p-1.  */
*412f47f9SXin Lidouble
*412f47f9SXin Liatan2 (double y, double x)
*412f47f9SXin Li{
*412f47f9SXin Li  uint64_t ix = asuint64 (x);
*412f47f9SXin Li  uint64_t iy = asuint64 (y);
*412f47f9SXin Li
*412f47f9SXin Li  uint64_t sign_x = ix & SignMask;
*412f47f9SXin Li  uint64_t sign_y = iy & SignMask;
*412f47f9SXin Li
*412f47f9SXin Li  uint64_t iax = ix & ~SignMask;
*412f47f9SXin Li  uint64_t iay = iy & ~SignMask;
*412f47f9SXin Li
*412f47f9SXin Li  bool xisnan = isnan (x);
*412f47f9SXin Li  if (unlikely (isnan (y) && !xisnan))
*412f47f9SXin Li    return __math_invalid (y);
*412f47f9SXin Li  if (unlikely (xisnan))
*412f47f9SXin Li    return __math_invalid (x);
*412f47f9SXin Li
*412f47f9SXin Li  /* m = 2 * sign(x) + sign(y).  */
*412f47f9SXin Li  uint32_t m = ((iy >> 63) & 1) | ((ix >> 62) & 2);
*412f47f9SXin Li
*412f47f9SXin Li  int64_t exp_diff = biased_exponent (x) - biased_exponent (y);
*412f47f9SXin Li
*412f47f9SXin Li  /* y = 0.  */
*412f47f9SXin Li  if (iay == 0)
*412f47f9SXin Li    {
*412f47f9SXin Li      switch (m)
*412f47f9SXin Li	{
*412f47f9SXin Li	case 0:
*412f47f9SXin Li	case 1:
*412f47f9SXin Li	  return y; /* atan(+-0,+anything)=+-0.  */
*412f47f9SXin Li	case 2:
*412f47f9SXin Li	  return Pi; /* atan(+0,-anything) = pi.  */
*412f47f9SXin Li	case 3:
*412f47f9SXin Li	  return -Pi; /* atan(-0,-anything) =-pi.  */
*412f47f9SXin Li	}
*412f47f9SXin Li    }
*412f47f9SXin Li  /* Special case for (x, y) either on or very close to the y axis. Either x =
*412f47f9SXin Li     0, or y is much larger than x (difference in exponents >=
*412f47f9SXin Li     POW8_EXP_UFLOW_BOUND).  */
*412f47f9SXin Li  if (unlikely (iax == 0 || exp_diff <= -POW8_EXP_UFLOW_BOUND))
*412f47f9SXin Li    return sign_y ? -PiOver2 : PiOver2;
*412f47f9SXin Li
*412f47f9SXin Li  /* Special case for either x is INF or (x, y) is very close to x axis and x is
*412f47f9SXin Li     negative.  */
*412f47f9SXin Li  if (unlikely (iax == 0x7ff0000000000000
*412f47f9SXin Li		|| (exp_diff >= POW8_EXP_UFLOW_BOUND && m >= 2)))
*412f47f9SXin Li    {
*412f47f9SXin Li      if (iay == 0x7ff0000000000000)
*412f47f9SXin Li	{
*412f47f9SXin Li	  switch (m)
*412f47f9SXin Li	    {
*412f47f9SXin Li	    case 0:
*412f47f9SXin Li	      return PiOver4; /* atan(+INF,+INF).  */
*412f47f9SXin Li	    case 1:
*412f47f9SXin Li	      return -PiOver4; /* atan(-INF,+INF).  */
*412f47f9SXin Li	    case 2:
*412f47f9SXin Li	      return 3.0 * PiOver4; /* atan(+INF,-INF).  */
*412f47f9SXin Li	    case 3:
*412f47f9SXin Li	      return -3.0 * PiOver4; /* atan(-INF,-INF).  */
*412f47f9SXin Li	    }
*412f47f9SXin Li	}
*412f47f9SXin Li      else
*412f47f9SXin Li	{
*412f47f9SXin Li	  switch (m)
*412f47f9SXin Li	    {
*412f47f9SXin Li	    case 0:
*412f47f9SXin Li	      return 0.0; /* atan(+...,+INF).  */
*412f47f9SXin Li	    case 1:
*412f47f9SXin Li	      return -0.0; /* atan(-...,+INF).  */
*412f47f9SXin Li	    case 2:
*412f47f9SXin Li	      return Pi; /* atan(+...,-INF).  */
*412f47f9SXin Li	    case 3:
*412f47f9SXin Li	      return -Pi; /* atan(-...,-INF).  */
*412f47f9SXin Li	    }
*412f47f9SXin Li	}
*412f47f9SXin Li    }
*412f47f9SXin Li  /* y is INF.  */
*412f47f9SXin Li  if (iay == 0x7ff0000000000000)
*412f47f9SXin Li    return sign_y ? -PiOver2 : PiOver2;
*412f47f9SXin Li
*412f47f9SXin Li  uint64_t sign_xy = sign_x ^ sign_y;
*412f47f9SXin Li
*412f47f9SXin Li  double ax = asdouble (iax);
*412f47f9SXin Li  double ay = asdouble (iay);
*412f47f9SXin Li  uint64_t pred_aygtax = (ay > ax);
*412f47f9SXin Li
*412f47f9SXin Li  /* Set up z for call to atan.  */
*412f47f9SXin Li  double n = pred_aygtax ? -ax : ay;
*412f47f9SXin Li  double d = pred_aygtax ? ay : ax;
*412f47f9SXin Li  double z = n / d;
*412f47f9SXin Li
*412f47f9SXin Li  double ret;
*412f47f9SXin Li  if (unlikely (m < 2 && exp_diff >= POW8_EXP_UFLOW_BOUND))
*412f47f9SXin Li    {
*412f47f9SXin Li      /* If (x, y) is very close to x axis and x is positive, the polynomial
*412f47f9SXin Li	 will underflow and evaluate to z.  */
*412f47f9SXin Li      ret = z;
*412f47f9SXin Li    }
*412f47f9SXin Li  else
*412f47f9SXin Li    {
*412f47f9SXin Li      /* Work out the correct shift.  */
*412f47f9SXin Li      double shift = sign_x ? -2.0 : 0.0;
*412f47f9SXin Li      shift = pred_aygtax ? shift + 1.0 : shift;
*412f47f9SXin Li      shift *= PiOver2;
*412f47f9SXin Li
*412f47f9SXin Li      ret = eval_poly (z, z, shift);
*412f47f9SXin Li    }
*412f47f9SXin Li
*412f47f9SXin Li  /* Account for the sign of x and y.  */
*412f47f9SXin Li  return asdouble (asuint64 (ret) ^ sign_xy);
*412f47f9SXin Li}
*412f47f9SXin Li
*412f47f9SXin Li/* Arity of 2 means no mathbench entry emitted. See test/mathbench_funcs.h.  */
*412f47f9SXin LiPL_SIG (S, D, 2, atan2)
*412f47f9SXin LiPL_TEST_ULP (atan2, 1.78)
*412f47f9SXin LiPL_TEST_INTERVAL (atan2, -10.0, 10.0, 50000)
*412f47f9SXin LiPL_TEST_INTERVAL (atan2, -1.0, 1.0, 40000)
*412f47f9SXin LiPL_TEST_INTERVAL (atan2, 0.0, 1.0, 40000)
*412f47f9SXin LiPL_TEST_INTERVAL (atan2, 1.0, 100.0, 40000)
*412f47f9SXin LiPL_TEST_INTERVAL (atan2, 1e6, 1e32, 40000)