Beispiel #1
0
float
sinhf(float x)		/* wrapper sinhf */
{
#ifdef _IEEE_LIBM
	return __ieee754_sinhf(x);
#else
	float z;
	z = __ieee754_sinhf(x);
	if(_LIB_VERSION == _IEEE_) return z;
	if(!finitef(z)&&finitef(x)) {
	    /* sinhf overflow */
	    return (float)__kernel_standard((double)x,(double)x,125);
	} else
	    return z;
#endif
}
Beispiel #2
0
__complex__ float
__ctanf (__complex__ float x)
{
  __complex__ float res;

  if (!isfinite (__real__ x) || !isfinite (__imag__ x))
    {
      if (__isinff (__imag__ x))
	{
	  __real__ res = __copysignf (0.0, __real__ x);
	  __imag__ res = __copysignf (1.0, __imag__ x);
	}
      else if (__real__ x == 0.0)
	{
	  res = x;
	}
      else
	{
	  __real__ res = __nanf ("");
	  __imag__ res = __nanf ("");

#ifdef FE_INVALID
	  if (__isinff (__real__ x))
	    feraiseexcept (FE_INVALID);
#endif
	}
    }
  else
    {
      float sin2rx, cos2rx;
      float den;

      __sincosf (2.0 * __real__ x, &sin2rx, &cos2rx);

      den = cos2rx + __ieee754_coshf (2.0 * __imag__ x);

      __real__ res = sin2rx / den;
      __imag__ res = __ieee754_sinhf (2.0 * __imag__ x) / den;
    }

  return res;
}
Beispiel #3
0
__complex__ float
__csinhf (__complex__ float x)
{
  __complex__ float retval;
  int negate = signbit (__real__ x);
  int rcls = fpclassify (__real__ x);
  int icls = fpclassify (__imag__ x);

  __real__ x = fabsf (__real__ x);

  if (rcls >= FP_ZERO)
    {
      /* Real part is finite.  */
      if (icls >= FP_ZERO)
	{
	  /* Imaginary part is finite.  */
	  float sinh_val = __ieee754_sinhf (__real__ x);
	  float cosh_val = __ieee754_coshf (__real__ x);
	  float sinix, cosix;

	  __sincosf (__imag__ x, &sinix, &cosix);

	  __real__ retval = sinh_val * cosix;
	  __imag__ retval = cosh_val * sinix;

	  if (negate)
	    __real__ retval = -__real__ retval;
	}
      else
	{
	  if (rcls == FP_ZERO)
	    {
	      /* Real part is 0.0.  */
	      __real__ retval = __copysignf (0.0, negate ? -1.0 : 1.0);
	      __imag__ retval = __nanf ("") + __nanf ("");

#ifdef FE_INVALID
	      if (icls == FP_INFINITE)
		feraiseexcept (FE_INVALID);
#endif
	    }
	  else
	    {
	      __real__ retval = __nanf ("");
	      __imag__ retval = __nanf ("");

#ifdef FE_INVALID
	      feraiseexcept (FE_INVALID);
#endif
	    }
	}
    }
  else if (rcls == FP_INFINITE)
    {
      /* Real part is infinite.  */
      if (icls == FP_ZERO)
	{
	  /* Imaginary part is 0.0.  */
	  __real__ retval = negate ? -HUGE_VALF : HUGE_VALF;
	  __imag__ retval = __imag__ x;
	}
      else if (icls > FP_ZERO)
	{
	  /* Imaginary part is finite.  */
	  float sinix, cosix;

	  __sincosf (__imag__ x, &sinix, &cosix);

	  __real__ retval = __copysignf (HUGE_VALF, cosix);
	  __imag__ retval = __copysignf (HUGE_VALF, sinix);

	  if (negate)
	    __real__ retval = -__real__ retval;
	}
      else
	{
	  /* The addition raises the invalid exception.  */
	  __real__ retval = HUGE_VALF;
	  __imag__ retval = __nanf ("") + __nanf ("");

#ifdef FE_INVALID
	  if (icls == FP_INFINITE)
	    feraiseexcept (FE_INVALID);
#endif
	}
    }
  else
    {
      __real__ retval = __nanf ("");
      __imag__ retval = __imag__ x == 0.0 ? __imag__ x : __nanf ("");
    }

  return retval;
}
Beispiel #4
0
__complex__ float
__csinhf (__complex__ float x)
{
  __complex__ float retval;
  int negate = signbit (__real__ x);
  int rcls = fpclassify (__real__ x);
  int icls = fpclassify (__imag__ x);

  __real__ x = fabsf (__real__ x);

  if (__builtin_expect (rcls >= FP_ZERO, 1))
    {
      /* Real part is finite.  */
      if (__builtin_expect (icls >= FP_ZERO, 1))
	{
	  /* Imaginary part is finite.  */
	  const int t = (int) ((FLT_MAX_EXP - 1) * M_LN2);
	  float sinix, cosix;

	  if (__builtin_expect (icls != FP_SUBNORMAL, 1))
	    {
	      __sincosf (__imag__ x, &sinix, &cosix);
	    }
	  else
	    {
	      sinix = __imag__ x;
	      cosix = 1.0f;
	    }

	  if (fabsf (__real__ x) > t)
	    {
	      float exp_t = __ieee754_expf (t);
	      float rx = fabsf (__real__ x);
	      if (signbit (__real__ x))
		cosix = -cosix;
	      rx -= t;
	      sinix *= exp_t / 2.0f;
	      cosix *= exp_t / 2.0f;
	      if (rx > t)
		{
		  rx -= t;
		  sinix *= exp_t;
		  cosix *= exp_t;
		}
	      if (rx > t)
		{
		  /* Overflow (original real part of x > 3t).  */
		  __real__ retval = FLT_MAX * cosix;
		  __imag__ retval = FLT_MAX * sinix;
		}
	      else
		{
		  float exp_val = __ieee754_expf (rx);
		  __real__ retval = exp_val * cosix;
		  __imag__ retval = exp_val * sinix;
		}
	    }
	  else
	    {
	      __real__ retval = __ieee754_sinhf (__real__ x) * cosix;
	      __imag__ retval = __ieee754_coshf (__real__ x) * sinix;
	    }

	  if (negate)
	    __real__ retval = -__real__ retval;

	  if (fabsf (__real__ retval) < FLT_MIN)
	    {
	      volatile float force_underflow
		= __real__ retval * __real__ retval;
	      (void) force_underflow;
	    }
	  if (fabsf (__imag__ retval) < FLT_MIN)
	    {
	      volatile float force_underflow
		= __imag__ retval * __imag__ retval;
	      (void) force_underflow;
	    }
	}
      else
	{
	  if (rcls == FP_ZERO)
	    {
	      /* Real part is 0.0.  */
	      __real__ retval = __copysignf (0.0, negate ? -1.0 : 1.0);
	      __imag__ retval = __nanf ("") + __nanf ("");

	      if (icls == FP_INFINITE)
		feraiseexcept (FE_INVALID);
	    }
	  else
	    {
	      __real__ retval = __nanf ("");
	      __imag__ retval = __nanf ("");

	      feraiseexcept (FE_INVALID);
	    }
	}
    }
  else if (__builtin_expect (rcls == FP_INFINITE, 1))
    {
      /* Real part is infinite.  */
      if (__builtin_expect (icls > FP_ZERO, 1))
	{
	  /* Imaginary part is finite.  */
	  float sinix, cosix;

	  if (__builtin_expect (icls != FP_SUBNORMAL, 1))
	    {
	      __sincosf (__imag__ x, &sinix, &cosix);
	    }
	  else
	    {
	      sinix = __imag__ x;
	      cosix = 1.0f;
	    }

	  __real__ retval = __copysignf (HUGE_VALF, cosix);
	  __imag__ retval = __copysignf (HUGE_VALF, sinix);

	  if (negate)
	    __real__ retval = -__real__ retval;
	}
      else if (icls == FP_ZERO)
	{
	  /* Imaginary part is 0.0.  */
	  __real__ retval = negate ? -HUGE_VALF : HUGE_VALF;
	  __imag__ retval = __imag__ x;
	}
      else
	{
	  /* The addition raises the invalid exception.  */
	  __real__ retval = HUGE_VALF;
	  __imag__ retval = __nanf ("") + __nanf ("");

#ifdef FE_INVALID
	  if (icls == FP_INFINITE)
	    feraiseexcept (FE_INVALID);
#endif
	}
    }
  else
    {
      __real__ retval = __nanf ("");
      __imag__ retval = __imag__ x == 0.0 ? __imag__ x : __nanf ("");
    }

  return retval;
}
Beispiel #5
0
__complex__ float
__ctanf (__complex__ float x)
{
  __complex__ float res;

  if (__glibc_unlikely (!isfinite (__real__ x) || !isfinite (__imag__ x)))
    {
      if (isinf (__imag__ x))
	{
	  if (isfinite (__real__ x) && fabsf (__real__ x) > 1.0f)
	    {
	      float sinrx, cosrx;
	      __sincosf (__real__ x, &sinrx, &cosrx);
	      __real__ res = __copysignf (0.0f, sinrx * cosrx);
	    }
	  else
	    __real__ res = __copysignf (0.0, __real__ x);
	  __imag__ res = __copysignf (1.0, __imag__ x);
	}
      else if (__real__ x == 0.0)
	{
	  res = x;
	}
      else
	{
	  __real__ res = __nanf ("");
	  __imag__ res = __nanf ("");

	  if (isinf (__real__ x))
	    feraiseexcept (FE_INVALID);
	}
    }
  else
    {
      float sinrx, cosrx;
      float den;
      const int t = (int) ((FLT_MAX_EXP - 1) * M_LN2 / 2);

      /* tan(x+iy) = (sin(2x) + i*sinh(2y))/(cos(2x) + cosh(2y))
	 = (sin(x)*cos(x) + i*sinh(y)*cosh(y)/(cos(x)^2 + sinh(y)^2). */

      if (__glibc_likely (fabsf (__real__ x) > FLT_MIN))
	{
	  __sincosf (__real__ x, &sinrx, &cosrx);
	}
      else
	{
	  sinrx = __real__ x;
	  cosrx = 1.0f;
	}

      if (fabsf (__imag__ x) > t)
	{
	  /* Avoid intermediate overflow when the real part of the
	     result may be subnormal.  Ignoring negligible terms, the
	     imaginary part is +/- 1, the real part is
	     sin(x)*cos(x)/sinh(y)^2 = 4*sin(x)*cos(x)/exp(2y).  */
	  float exp_2t = __ieee754_expf (2 * t);

	  __imag__ res = __copysignf (1.0, __imag__ x);
	  __real__ res = 4 * sinrx * cosrx;
	  __imag__ x = fabsf (__imag__ x);
	  __imag__ x -= t;
	  __real__ res /= exp_2t;
	  if (__imag__ x > t)
	    {
	      /* Underflow (original imaginary part of x has absolute
		 value > 2t).  */
	      __real__ res /= exp_2t;
	    }
	  else
	    __real__ res /= __ieee754_expf (2 * __imag__ x);
	}
      else
	{
	  float sinhix, coshix;
	  if (fabsf (__imag__ x) > FLT_MIN)
	    {
	      sinhix = __ieee754_sinhf (__imag__ x);
	      coshix = __ieee754_coshf (__imag__ x);
	    }
	  else
	    {
	      sinhix = __imag__ x;
	      coshix = 1.0f;
	    }

	  if (fabsf (sinhix) > fabsf (cosrx) * FLT_EPSILON)
	    den = cosrx * cosrx + sinhix * sinhix;
	  else
	    den = cosrx * cosrx;
	  __real__ res = sinrx * cosrx / den;
	  __imag__ res = sinhix * coshix / den;
	}
      math_check_force_underflow_complex (res);
    }

  return res;
}
Beispiel #6
0
__complex__ float
__ccoshf (__complex__ float x)
{
  __complex__ float retval;
  int rcls = fpclassify (__real__ x);
  int icls = fpclassify (__imag__ x);

  if (__glibc_likely (rcls >= FP_ZERO))
    {
      /* Real part is finite.  */
      if (__glibc_likely (icls >= FP_ZERO))
	{
	  /* Imaginary part is finite.  */
	  const int t = (int) ((FLT_MAX_EXP - 1) * M_LN2);
	  float sinix, cosix;

	  if (__glibc_likely (fabsf (__imag__ x) > FLT_MIN))
	    {
	      __sincosf (__imag__ x, &sinix, &cosix);
	    }
	  else
	    {
	      sinix = __imag__ x;
	      cosix = 1.0f;
	    }

	  if (fabsf (__real__ x) > t)
	    {
	      float exp_t = __ieee754_expf (t);
	      float rx = fabsf (__real__ x);
	      if (signbit (__real__ x))
		sinix = -sinix;
	      rx -= t;
	      sinix *= exp_t / 2.0f;
	      cosix *= exp_t / 2.0f;
	      if (rx > t)
		{
		  rx -= t;
		  sinix *= exp_t;
		  cosix *= exp_t;
		}
	      if (rx > t)
		{
		  /* Overflow (original real part of x > 3t).  */
		  __real__ retval = FLT_MAX * cosix;
		  __imag__ retval = FLT_MAX * sinix;
		}
	      else
		{
		  float exp_val = __ieee754_expf (rx);
		  __real__ retval = exp_val * cosix;
		  __imag__ retval = exp_val * sinix;
		}
	    }
	  else
	    {
	      __real__ retval = __ieee754_coshf (__real__ x) * cosix;
	      __imag__ retval = __ieee754_sinhf (__real__ x) * sinix;
	    }

	  math_check_force_underflow_complex (retval);
	}
      else
	{
	  __imag__ retval = __real__ x == 0.0 ? 0.0 : __nanf ("");
	  __real__ retval = __nanf ("");

	  if (icls == FP_INFINITE)
	    feraiseexcept (FE_INVALID);
	}
    }
  else if (rcls == FP_INFINITE)
    {
      /* Real part is infinite.  */
      if (__glibc_likely (icls > FP_ZERO))
	{
	  /* Imaginary part is finite.  */
	  float sinix, cosix;

	  if (__glibc_likely (fabsf (__imag__ x) > FLT_MIN))
	    {
	      __sincosf (__imag__ x, &sinix, &cosix);
	    }
	  else
	    {
	      sinix = __imag__ x;
	      cosix = 1.0f;
	    }

	  __real__ retval = __copysignf (HUGE_VALF, cosix);
	  __imag__ retval = (__copysignf (HUGE_VALF, sinix)
			     * __copysignf (1.0, __real__ x));
	}
      else if (icls == FP_ZERO)
	{
	  /* Imaginary part is 0.0.  */
	  __real__ retval = HUGE_VALF;
	  __imag__ retval = __imag__ x * __copysignf (1.0, __real__ x);
	}
      else
	{
	  /* The addition raises the invalid exception.  */
	  __real__ retval = HUGE_VALF;
	  __imag__ retval = __nanf ("") + __nanf ("");

	  if (icls == FP_INFINITE)
	    feraiseexcept (FE_INVALID);
	}
    }
  else
    {
      __real__ retval = __nanf ("");
      __imag__ retval = __imag__ x == 0.0 ? __imag__ x : __nanf ("");
    }

  return retval;
}
Beispiel #7
0
__complex__ float
__ctanhf (__complex__ float x)
{
  __complex__ float res;

  if (__builtin_expect (!isfinite (__real__ x) || !isfinite (__imag__ x), 0))
    {
      if (__isinf_nsf (__real__ x))
	{
	  __real__ res = __copysignf (1.0, __real__ x);
	  __imag__ res = __copysignf (0.0, __imag__ x);
	}
      else if (__imag__ x == 0.0)
	{
	  res = x;
	}
      else
	{
	  __real__ res = __nanf ("");
	  __imag__ res = __nanf ("");

	  if (__isinf_nsf (__imag__ x))
	    feraiseexcept (FE_INVALID);
	}
    }
  else
    {
      float sinix, cosix;
      float den;
      const int t = (int) ((FLT_MAX_EXP - 1) * M_LN2 / 2);

      /* tanh(x+iy) = (sinh(2x) + i*sin(2y))/(cosh(2x) + cos(2y))
	 = (sinh(x)*cosh(x) + i*sin(y)*cos(y))/(sinh(x)^2 + cos(y)^2).  */

      if (__builtin_expect (fpclassify(__imag__ x) != FP_SUBNORMAL, 1))
	{
	  __sincosf (__imag__ x, &sinix, &cosix);
	}
      else
	{
	  sinix = __imag__ x;
	  cosix = 1.0f;
	}

      if (fabsf (__real__ x) > t)
	{
	  /* Avoid intermediate overflow when the imaginary part of
	     the result may be subnormal.  Ignoring negligible terms,
	     the real part is +/- 1, the imaginary part is
	     sin(y)*cos(y)/sinh(x)^2 = 4*sin(y)*cos(y)/exp(2x).  */
	  float exp_2t = __ieee754_expf (2 * t);

	  __real__ res = __copysignf (1.0, __real__ x);
	  __imag__ res = 4 * sinix * cosix;
	  __real__ x = fabsf (__real__ x);
	  __real__ x -= t;
	  __imag__ res /= exp_2t;
	  if (__real__ x > t)
	    {
	      /* Underflow (original real part of x has absolute value
		 > 2t).  */
	      __imag__ res /= exp_2t;
	    }
	  else
	    __imag__ res /= __ieee754_expf (2 * __real__ x);
	}
      else
	{
	  float sinhrx, coshrx;
	  if (fabsf (__real__ x) > FLT_MIN)
	    {
	      sinhrx = __ieee754_sinhf (__real__ x);
	      coshrx = __ieee754_coshf (__real__ x);
	    }
	  else
	    {
	      sinhrx = __real__ x;
	      coshrx = 1.0f;
	    }

	  if (fabsf (sinhrx) > fabsf (cosix) * FLT_EPSILON)
	    den = sinhrx * sinhrx + cosix * cosix;
	  else
	    den = cosix * cosix;
	  __real__ res = sinhrx * coshrx / den;
	  __imag__ res = sinix * cosix / den;
	}
    }

  return res;
}