google3/third_party/grte/v4_src/glibc-2.19/sysdeps/powerpc/power4/fpu/mpa.c - GRTEv4 - Git at Google


 /*
  * IBM Accurate Mathematical Library
  * written by International Business Machines Corp.
  * Copyright (C) 2001-2014 Free Software Foundation, Inc.
  *
  * This program 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.
  *
  * This program 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 this program; if not, see <http://www.gnu.org/licenses/>.
  */

 /* Define __mul and __sqr and use the rest from generic code.  */
 #define NO__MUL
 #define NO__SQR

 #include <sysdeps/ieee754/dbl-64/mpa.c>

 /* Multiply *X and *Y and store result in *Z.  X and Y may overlap but not X
    and Z or Y and Z.  For P in [1, 2, 3], the exact result is truncated to P
    digits.  In case P > 3 the error is bounded by 1.001 ULP.  */
 void
 __mul (const mp_no *x, const mp_no *y, mp_no *z, int p)
 {
   long i, i1, i2, j, k, k2;
   long p2 = p;
   double u, zk, zk2;

   /* Is z=0?  */
   if (__glibc_unlikely (X[0] * Y[0] == 0))
     {
       Z[0] = 0;
       return;
     }

   /* Multiply, add and carry */
   k2 = (p2 < 3) ? p2 + p2 : p2 + 3;
   zk = Z[k2] = 0;
   for (k = k2; k > 1;)
     {
       if (k > p2)
 	{
 	  i1 = k - p2;
 	  i2 = p2 + 1;
 	}
       else
 	{
 	  i1 = 1;
 	  i2 = k;
 	}
 #if 1
       /* Rearrange this inner loop to allow the fmadd instructions to be
          independent and execute in parallel on processors that have
          dual symmetrical FP pipelines.  */
       if (i1 < (i2 - 1))
 	{
 	  /* Make sure we have at least 2 iterations.  */
 	  if (((i2 - i1) & 1L) == 1L)
 	    {
 	      /* Handle the odd iterations case.  */
 	      zk2 = x->d[i2 - 1] * y->d[i1];
 	    }
 	  else
 	    zk2 = 0.0;
 	  /* Do two multiply/adds per loop iteration, using independent
 	     accumulators; zk and zk2.  */
 	  for (i = i1, j = i2 - 1; i < i2 - 1; i += 2, j -= 2)
 	    {
 	      zk += x->d[i] * y->d[j];
 	      zk2 += x->d[i + 1] * y->d[j - 1];
 	    }
 	  zk += zk2;		/* Final sum.  */
 	}
       else
 	{
 	  /* Special case when iterations is 1.  */
 	  zk += x->d[i1] * y->d[i1];
 	}
 #else
       /* The original code.  */
       for (i = i1, j = i2 - 1; i < i2; i++, j--)
 	zk += X[i] * Y[j];
 #endif

       u = (zk + CUTTER) - CUTTER;
       if (u > zk)
 	u -= RADIX;
       Z[k] = zk - u;
       zk = u * RADIXI;
       --k;
     }
   Z[k] = zk;

   int e = EX + EY;
   /* Is there a carry beyond the most significant digit?  */
   if (Z[1] == 0)
     {
       for (i = 1; i <= p2; i++)
 	Z[i] = Z[i + 1];
       e--;
     }

   EZ = e;
   Z[0] = X[0] * Y[0];
 }

 /* Square *X and store result in *Y.  X and Y may not overlap.  For P in
    [1, 2, 3], the exact result is truncated to P digits.  In case P > 3 the
    error is bounded by 1.001 ULP.  This is a faster special case of
    multiplication.  */
 void
 __sqr (const mp_no *x, mp_no *y, int p)
 {
   long i, j, k, ip;
   double u, yk;

   /* Is z=0?  */
   if (__glibc_unlikely (X[0] == 0))
     {
       Y[0] = 0;
       return;
     }

   /* We need not iterate through all X's since it's pointless to
      multiply zeroes.  */
   for (ip = p; ip > 0; ip--)
     if (X[ip] != 0)
       break;

   k = (__glibc_unlikely (p < 3)) ? p + p : p + 3;

   while (k > 2 * ip + 1)
     Y[k--] = 0;

   yk = 0;

   while (k > p)
     {
       double yk2 = 0.0;
       long lim = k / 2;

       if (k % 2 == 0)
         {
 	  yk += X[lim] * X[lim];
 	  lim--;
 	}

       /* In __mul, this loop (and the one within the next while loop) run
          between a range to calculate the mantissa as follows:

          Z[k] = X[k] * Y[n] + X[k+1] * Y[n-1] ... + X[n-1] * Y[k+1]
 		+ X[n] * Y[k]

          For X == Y, we can get away with summing halfway and doubling the
 	 result.  For cases where the range size is even, the mid-point needs
 	 to be added separately (above).  */
       for (i = k - p, j = p; i <= lim; i++, j--)
 	yk2 += X[i] * X[j];

       yk += 2.0 * yk2;

       u = (yk + CUTTER) - CUTTER;
       if (u > yk)
 	u -= RADIX;
       Y[k--] = yk - u;
       yk = u * RADIXI;
     }

   while (k > 1)
     {
       double yk2 = 0.0;
       long lim = k / 2;

       if (k % 2 == 0)
         {
 	  yk += X[lim] * X[lim];
 	  lim--;
 	}

       /* Likewise for this loop.  */
       for (i = 1, j = k - 1; i <= lim; i++, j--)
 	yk2 += X[i] * X[j];

       yk += 2.0 * yk2;

       u = (yk + CUTTER) - CUTTER;
       if (u > yk)
 	u -= RADIX;
       Y[k--] = yk - u;
       yk = u * RADIXI;
     }
   Y[k] = yk;

   /* Squares are always positive.  */
   Y[0] = 1.0;

   int e = EX * 2;
   /* Is there a carry beyond the most significant digit?  */
   if (__glibc_unlikely (Y[1] == 0))
     {
       for (i = 1; i <= p; i++)
 	Y[i] = Y[i + 1];
       e--;
     }
   EY = e;
 }

	/*
	* IBM Accurate Mathematical Library
	* written by International Business Machines Corp.
	* Copyright (C) 2001-2014 Free Software Foundation, Inc.
	*
	* This program 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.
	*
	* This program 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 this program; if not, see <http://www.gnu.org/licenses/>.
	*/

	/* Define __mul and __sqr and use the rest from generic code. */
	#define NO__MUL
	#define NO__SQR

	#include <sysdeps/ieee754/dbl-64/mpa.c>

	/* Multiply X and Y and store result in *Z. X and Y may overlap but not X
	and Z or Y and Z. For P in [1, 2, 3], the exact result is truncated to P
	digits. In case P > 3 the error is bounded by 1.001 ULP. */
	void
	__mul (const mp_no x, const mp_no y, mp_no *z, int p)
	{
	long i, i1, i2, j, k, k2;
	long p2 = p;
	double u, zk, zk2;

	/* Is z=0? */
	if (__glibc_unlikely (X[0] * Y[0] == 0))
	{
	Z[0] = 0;
	return;
	}

	/* Multiply, add and carry */
	k2 = (p2 < 3) ? p2 + p2 : p2 + 3;
	zk = Z[k2] = 0;
	for (k = k2; k > 1;)
	{
	if (k > p2)
	{
	i1 = k - p2;
	i2 = p2 + 1;
	}
	else
	{
	i1 = 1;
	i2 = k;
	}
	#if 1
	/* Rearrange this inner loop to allow the fmadd instructions to be
	independent and execute in parallel on processors that have
	dual symmetrical FP pipelines. */
	if (i1 < (i2 - 1))
	{
	/* Make sure we have at least 2 iterations. */
	if (((i2 - i1) & 1L) == 1L)
	{
	/* Handle the odd iterations case. */
	zk2 = x->d[i2 - 1] * y->d[i1];
	}
	else
	zk2 = 0.0;
	/* Do two multiply/adds per loop iteration, using independent
	accumulators; zk and zk2. */
	for (i = i1, j = i2 - 1; i < i2 - 1; i += 2, j -= 2)
	{
	zk += x->d[i] * y->d[j];
	zk2 += x->d[i + 1] * y->d[j - 1];
	}
	zk += zk2; /* Final sum. */
	}
	else
	{
	/* Special case when iterations is 1. */
	zk += x->d[i1] * y->d[i1];
	}
	#else
	/* The original code. */
	for (i = i1, j = i2 - 1; i < i2; i++, j--)
	zk += X[i] * Y[j];
	#endif

	u = (zk + CUTTER) - CUTTER;
	if (u > zk)
	u -= RADIX;
	Z[k] = zk - u;
	zk = u * RADIXI;
	--k;
	}
	Z[k] = zk;

	int e = EX + EY;
	/* Is there a carry beyond the most significant digit? */
	if (Z[1] == 0)
	{
	for (i = 1; i <= p2; i++)
	Z[i] = Z[i + 1];
	e--;
	}

	EZ = e;
	Z[0] = X[0] * Y[0];
	}

	/* Square X and store result in Y. X and Y may not overlap. For P in
	[1, 2, 3], the exact result is truncated to P digits. In case P > 3 the
	error is bounded by 1.001 ULP. This is a faster special case of
	multiplication. */
	void
	__sqr (const mp_no x, mp_no y, int p)
	{
	long i, j, k, ip;
	double u, yk;

	/* Is z=0? */
	if (__glibc_unlikely (X[0] == 0))
	{
	Y[0] = 0;
	return;
	}

	/* We need not iterate through all X's since it's pointless to
	multiply zeroes. */
	for (ip = p; ip > 0; ip--)
	if (X[ip] != 0)
	break;

	k = (__glibc_unlikely (p < 3)) ? p + p : p + 3;

	while (k > 2 * ip + 1)
	Y[k--] = 0;

	yk = 0;

	while (k > p)
	{
	double yk2 = 0.0;
	long lim = k / 2;

	if (k % 2 == 0)
	{
	yk += X[lim] * X[lim];
	lim--;
	}

	/* In __mul, this loop (and the one within the next while loop) run
	between a range to calculate the mantissa as follows:

	Z[k] = X[k] * Y[n] + X[k+1] * Y[n-1] ... + X[n-1] * Y[k+1]
	+ X[n] * Y[k]

	For X == Y, we can get away with summing halfway and doubling the
	result. For cases where the range size is even, the mid-point needs
	to be added separately (above). */
	for (i = k - p, j = p; i <= lim; i++, j--)
	yk2 += X[i] * X[j];

	yk += 2.0 * yk2;

	u = (yk + CUTTER) - CUTTER;
	if (u > yk)
	u -= RADIX;
	Y[k--] = yk - u;
	yk = u * RADIXI;
	}

	while (k > 1)
	{
	double yk2 = 0.0;
	long lim = k / 2;

	if (k % 2 == 0)
	{
	yk += X[lim] * X[lim];
	lim--;
	}

	/* Likewise for this loop. */
	for (i = 1, j = k - 1; i <= lim; i++, j--)
	yk2 += X[i] * X[j];

	yk += 2.0 * yk2;

	u = (yk + CUTTER) - CUTTER;
	if (u > yk)
	u -= RADIX;
	Y[k--] = yk - u;
	yk = u * RADIXI;
	}
	Y[k] = yk;

	/* Squares are always positive. */
	Y[0] = 1.0;

	int e = EX * 2;
	/* Is there a carry beyond the most significant digit? */
	if (__glibc_unlikely (Y[1] == 0))
	{
	for (i = 1; i <= p; i++)
	Y[i] = Y[i + 1];
	e--;
	}
	EY = e;
	}