bullet3/Extras/simdmathlibrary/spu/simdmath/frexpd2.h

/* frexpd2 - for each element of vector x, return the normalized fraction and store the exponent of x'
   Copyright (C) 2006, 2007 Sony Computer Entertainment Inc.
   All rights reserved.

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      notice, this list of conditions and the following disclaimer in the
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    * Neither the name of the Sony Computer Entertainment Inc nor the names
      of its contributors may be used to endorse or promote products derived
      from this software without specific prior written permission.

   THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
   AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
   IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
   ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
   LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
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 */

#ifndef ___SIMD_MATH_FREXPD2_H___
#define ___SIMD_MATH_FREXPD2_H___

#include <simdmath.h>
#include <spu_intrinsics.h>
#include <math.h>

#define __FREXPD_DBL_NAN 0x7FF8000000000000ull

static inline vector double
_frexpd2 (vector double x, vector signed long long *pexp)
{
  vec_uchar16 even = (vec_uchar16)(vec_uint4){ 0x00010203, 0x00010203, 0x08090a0b, 0x08090a0b };
  vec_uchar16 swapEvenOdd = (vec_uchar16)(vec_uint4){ 0x04050607, 0x00010203, 0x0c0d0e0f, 0x08090a0b };

  vec_ullong2 maskdw = (vec_ullong2){0xffffffffffffffffull, 0ull};

  vec_ullong2 sign = spu_splats(0x8000000000000000ull);
  vec_ullong2 expn = spu_splats(0x7ff0000000000000ull);
  vec_ullong2 zero = spu_splats(0x0000000000000000ull);

  vec_ullong2 isnan, isinf, iszero;
  vec_ullong2 e0, x0, x1;
  vec_uint4 cmpgt, cmpeq, cmpzr;
  vec_int4 lz, lz0, sh, ex;
  vec_double2 fr, frac = (vec_double2)zero;

  //NAN: x is NaN (all-ones exponent and non-zero mantissa)
  cmpgt = spu_cmpgt( (vec_uint4)spu_or( (vec_ullong2)x, sign ), (vec_uint4)spu_or(sign, expn) );
  cmpeq = spu_cmpeq( (vec_uint4)spu_or( (vec_ullong2)x, sign ), (vec_uint4)spu_or(sign, expn) );
  isnan = (vec_ullong2)spu_or( cmpgt, spu_and( cmpeq, spu_rlqwbyte( cmpgt, -4 ) ) );
  isnan = (vec_ullong2)spu_shuffle( isnan, isnan, even );
  frac = spu_sel( frac, (vec_double2)spu_splats(__FREXPD_DBL_NAN), isnan );

  //INF: x is infinite (all-ones exponent and zero mantissa)
  isinf = (vec_ullong2)spu_and( cmpeq, spu_shuffle( cmpeq, cmpeq, swapEvenOdd ) );
  frac = spu_sel( frac, x , isinf );

  //x is zero (zero exponent and zero mantissa)
  cmpzr = spu_cmpeq( (vec_uint4)spu_andc( (vec_ullong2)x, sign ), (vec_uint4)zero );
  iszero = (vec_ullong2)spu_and( cmpzr, spu_shuffle( cmpzr, cmpzr, swapEvenOdd ) );

  frac = spu_sel( frac, (vec_double2)zero , iszero );
  *pexp = spu_sel( *pexp, (vec_llong2)zero , iszero );

  //Integer Exponent: if x is normal or subnormal

  //...shift left to normalize fraction, zero shift if normal
  lz = (vec_int4)spu_cntlz( (vec_uint4)spu_andc( (vec_ullong2)x, sign) );
  lz0 = (vec_int4)spu_shuffle( lz, lz, even );
  sh = spu_sel( (vec_int4)zero, spu_sub( lz0, spu_splats((int)11) ), spu_cmpgt( lz0, (int)11 ) );
  sh = spu_sel( sh, spu_add( sh, lz ), spu_cmpeq( lz0, (int)32 ) );

  x0 = spu_slqw( spu_slqwbytebc( spu_and( (vec_ullong2)x, maskdw ), spu_extract(sh, 1) ), spu_extract(sh, 1) );
  x1 = spu_slqw( spu_slqwbytebc( (vec_ullong2)x, spu_extract(sh, 3) ), spu_extract(sh, 3) );
  fr = (vec_double2)spu_sel( x1, x0, maskdw );
  fr = spu_sel( fr, (vec_double2)spu_splats(0x3FE0000000000000ull), expn );
  fr = spu_sel( fr, x, sign );

  e0 = spu_rlmaskqw( spu_rlmaskqwbyte(spu_and( (vec_ullong2)x, expn ),-6), -4 );
  ex = spu_sel( spu_sub( (vec_int4)e0, spu_splats((int)1022) ), spu_sub( spu_splats((int)-1021), sh ), spu_cmpgt( sh, (int)0 ) );

  frac = spu_sel( frac, fr, spu_nor( isnan, spu_or( isinf, iszero ) ) );
  *pexp = spu_sel( *pexp, spu_extend( ex ), spu_nor( isnan, spu_or( isinf, iszero ) ) );

  return frac;
}

#endif