gcc-4.3.1/libgcc/config/libbid/bid64_mul.c - toolchain/gcc - Git at Google

 /* Copyright (C) 2007  Free Software Foundation, Inc.

 This file is part of GCC.

 GCC is free software; you can redistribute it and/or modify it under
 the terms of the GNU General Public License as published by the Free
 Software Foundation; either version 2, or (at your option) any later
 version.

 In addition to the permissions in the GNU General Public License, the
 Free Software Foundation gives you unlimited permission to link the
 compiled version of this file into combinations with other programs,
 and to distribute those combinations without any restriction coming
 from the use of this file.  (The General Public License restrictions
 do apply in other respects; for example, they cover modification of
 the file, and distribution when not linked into a combine
 executable.)

 GCC 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 General Public License
 for more details.

 You should have received a copy of the GNU General Public License
 along with GCC; see the file COPYING.  If not, write to the Free
 Software Foundation, 51 Franklin Street, Fifth Floor, Boston, MA
 02110-1301, USA.  */

 /*****************************************************************************
  *    BID64 multiply
  *****************************************************************************
  *
  *  Algorithm description:
  *
  *  if(number_digits(coefficient_x)+number_digits(coefficient_y) guaranteed
  *       below 16)
  *      return get_BID64(sign_x^sign_y, exponent_x + exponent_y - dec_bias,
  *                     coefficient_x*coefficient_y)
  *  else
  *      get long product: coefficient_x*coefficient_y
  *      determine number of digits to round off (extra_digits)
  *      rounding is performed as a 128x128-bit multiplication by
  *         2^M[extra_digits]/10^extra_digits, followed by a shift
  *         M[extra_digits] is sufficiently large for required accuracy
  *
  ****************************************************************************/

 #include "bid_internal.h"

 #if DECIMAL_CALL_BY_REFERENCE

 void
 bid64_mul (UINT64 * pres, UINT64 * px,
 	   UINT64 *
 	   py _RND_MODE_PARAM _EXC_FLAGS_PARAM _EXC_MASKS_PARAM
 	   _EXC_INFO_PARAM) {
   UINT64 x, y;
 #else

 UINT64
 bid64_mul (UINT64 x,
 	   UINT64 y _RND_MODE_PARAM _EXC_FLAGS_PARAM
 	   _EXC_MASKS_PARAM _EXC_INFO_PARAM) {
 #endif
   UINT128 P, PU, C128, Q_high, Q_low, Stemp;
   UINT64 sign_x, sign_y, coefficient_x, coefficient_y;
   UINT64 C64, remainder_h, carry, CY, res;
   UINT64 valid_x, valid_y;
   int_double tempx, tempy;
   int extra_digits, exponent_x, exponent_y, bin_expon_cx, bin_expon_cy,
     bin_expon_product;
   int rmode, digits_p, bp, amount, amount2, final_exponent, round_up;
   unsigned status, uf_status;

 #if DECIMAL_CALL_BY_REFERENCE
 #if !DECIMAL_GLOBAL_ROUNDING
   _IDEC_round rnd_mode = *prnd_mode;
 #endif
   x = *px;
   y = *py;
 #endif

   valid_x = unpack_BID64 (&sign_x, &exponent_x, &coefficient_x, x);
   valid_y = unpack_BID64 (&sign_y, &exponent_y, &coefficient_y, y);

   // unpack arguments, check for NaN or Infinity
   if (!valid_x) {

 #ifdef SET_STATUS_FLAGS
     if ((y & SNAN_MASK64) == SNAN_MASK64)	// y is sNaN
       __set_status_flags (pfpsf, INVALID_EXCEPTION);
 #endif
     // x is Inf. or NaN

     // test if x is NaN
     if ((x & NAN_MASK64) == NAN_MASK64) {
 #ifdef SET_STATUS_FLAGS
       if ((x & SNAN_MASK64) == SNAN_MASK64)	// sNaN
 	__set_status_flags (pfpsf, INVALID_EXCEPTION);
 #endif
       BID_RETURN (coefficient_x & QUIET_MASK64);
     }
     // x is Infinity?
     if ((x & INFINITY_MASK64) == INFINITY_MASK64) {
       // check if y is 0
       if (((y & INFINITY_MASK64) != INFINITY_MASK64)
 	  && !coefficient_y) {
 #ifdef SET_STATUS_FLAGS
 	__set_status_flags (pfpsf, INVALID_EXCEPTION);
 #endif
 	// y==0 , return NaN
 	BID_RETURN (NAN_MASK64);
       }
       // check if y is NaN
       if ((y & NAN_MASK64) == NAN_MASK64)
 	// y==NaN , return NaN
 	BID_RETURN (coefficient_y & QUIET_MASK64);
       // otherwise return +/-Inf
       BID_RETURN (((x ^ y) & 0x8000000000000000ull) | INFINITY_MASK64);
     }
     // x is 0
     if (((y & INFINITY_MASK64) != INFINITY_MASK64)) {
       if ((y & SPECIAL_ENCODING_MASK64) == SPECIAL_ENCODING_MASK64)
 	exponent_y = ((UINT32) (y >> 51)) & 0x3ff;
       else
 	exponent_y = ((UINT32) (y >> 53)) & 0x3ff;
       sign_y = y & 0x8000000000000000ull;

       exponent_x += exponent_y - DECIMAL_EXPONENT_BIAS;
       if (exponent_x > DECIMAL_MAX_EXPON_64)
 	exponent_x = DECIMAL_MAX_EXPON_64;
       else if (exponent_x < 0)
 	exponent_x = 0;
       BID_RETURN ((sign_x ^ sign_y) | (((UINT64) exponent_x) << 53));
     }
   }
   if (!valid_y) {
     // y is Inf. or NaN

     // test if y is NaN
     if ((y & NAN_MASK64) == NAN_MASK64) {
 #ifdef SET_STATUS_FLAGS
       if ((y & SNAN_MASK64) == SNAN_MASK64)	// sNaN
 	__set_status_flags (pfpsf, INVALID_EXCEPTION);
 #endif
       BID_RETURN (coefficient_y & QUIET_MASK64);
     }
     // y is Infinity?
     if ((y & INFINITY_MASK64) == INFINITY_MASK64) {
       // check if x is 0
       if (!coefficient_x) {
 	__set_status_flags (pfpsf, INVALID_EXCEPTION);
 	// x==0, return NaN
 	BID_RETURN (NAN_MASK64);
       }
       // otherwise return +/-Inf
       BID_RETURN (((x ^ y) & 0x8000000000000000ull) | INFINITY_MASK64);
     }
     // y is 0
     exponent_x += exponent_y - DECIMAL_EXPONENT_BIAS;
     if (exponent_x > DECIMAL_MAX_EXPON_64)
       exponent_x = DECIMAL_MAX_EXPON_64;
     else if (exponent_x < 0)
       exponent_x = 0;
     BID_RETURN ((sign_x ^ sign_y) | (((UINT64) exponent_x) << 53));
   }
   //--- get number of bits in the coefficients of x and y ---
   // version 2 (original)
   tempx.d = (double) coefficient_x;
   bin_expon_cx = ((tempx.i & MASK_BINARY_EXPONENT) >> 52);
   tempy.d = (double) coefficient_y;
   bin_expon_cy = ((tempy.i & MASK_BINARY_EXPONENT) >> 52);

   // magnitude estimate for coefficient_x*coefficient_y is
   //        2^(unbiased_bin_expon_cx + unbiased_bin_expon_cx)
   bin_expon_product = bin_expon_cx + bin_expon_cy;

   // check if coefficient_x*coefficient_y<2^(10*k+3)
   // equivalent to unbiased_bin_expon_cx + unbiased_bin_expon_cx < 10*k+1
   if (bin_expon_product < UPPER_EXPON_LIMIT + 2 * BINARY_EXPONENT_BIAS) {
     //  easy multiply
     C64 = coefficient_x * coefficient_y;

     res =
       get_BID64_small_mantissa (sign_x ^ sign_y,
 				exponent_x + exponent_y -
 				DECIMAL_EXPONENT_BIAS, C64, rnd_mode,
 				pfpsf);
     BID_RETURN (res);
   } else {
     uf_status = 0;
     // get 128-bit product: coefficient_x*coefficient_y
     __mul_64x64_to_128 (P, coefficient_x, coefficient_y);

     // tighten binary range of P:  leading bit is 2^bp
     // unbiased_bin_expon_product <= bp <= unbiased_bin_expon_product+1
     bin_expon_product -= 2 * BINARY_EXPONENT_BIAS;

     __tight_bin_range_128 (bp, P, bin_expon_product);

     // get number of decimal digits in the product
     digits_p = estimate_decimal_digits[bp];
     if (!(__unsigned_compare_gt_128 (power10_table_128[digits_p], P)))
       digits_p++;	// if power10_table_128[digits_p] <= P

     // determine number of decimal digits to be rounded out
     extra_digits = digits_p - MAX_FORMAT_DIGITS;
     final_exponent =
       exponent_x + exponent_y + extra_digits - DECIMAL_EXPONENT_BIAS;

 #ifndef IEEE_ROUND_NEAREST_TIES_AWAY
 #ifndef IEEE_ROUND_NEAREST
     rmode = rnd_mode;
     if (sign_x ^ sign_y && (unsigned) (rmode - 1) < 2)
       rmode = 3 - rmode;
 #else
     rmode = 0;
 #endif
 #else
     rmode = 0;
 #endif

     round_up = 0;
     if (((unsigned) final_exponent) >= 3 * 256) {
       if (final_exponent < 0) {
 	// underflow
 	if (final_exponent + 16 < 0) {
 	  res = sign_x ^ sign_y;
 	  __set_status_flags (pfpsf,
 			      UNDERFLOW_EXCEPTION | INEXACT_EXCEPTION);
 	  if (rmode == ROUNDING_UP)
 	    res |= 1;
 	  BID_RETURN (res);
 	}

 	uf_status = UNDERFLOW_EXCEPTION;
 	if (final_exponent == -1) {
 	  __add_128_64 (PU, P, round_const_table[rmode][extra_digits]);
 	  if (__unsigned_compare_ge_128
 	      (PU, power10_table_128[extra_digits + 16]))
 	    uf_status = 0;
 	}
 	extra_digits -= final_exponent;
 	final_exponent = 0;

 	if (extra_digits > 17) {
 	  __mul_128x128_full (Q_high, Q_low, P, reciprocals10_128[16]);

 	  amount = recip_scale[16];
 	  __shr_128 (P, Q_high, amount);

 	  // get sticky bits
 	  amount2 = 64 - amount;
 	  remainder_h = 0;
 	  remainder_h--;
 	  remainder_h >>= amount2;
 	  remainder_h = remainder_h & Q_high.w[0];

 	  extra_digits -= 16;
 	  if (remainder_h || (Q_low.w[1] > reciprocals10_128[16].w[1]
 			      || (Q_low.w[1] ==
 				  reciprocals10_128[16].w[1]
 				  && Q_low.w[0] >=
 				  reciprocals10_128[16].w[0]))) {
 	    round_up = 1;
 	    __set_status_flags (pfpsf,
 				UNDERFLOW_EXCEPTION |
 				INEXACT_EXCEPTION);
 	    P.w[0] = (P.w[0] << 3) + (P.w[0] << 1);
 	    P.w[0] |= 1;
 	    extra_digits++;
 	  }
 	}
       } else {
 	res =
 	  fast_get_BID64_check_OF (sign_x ^ sign_y, final_exponent,
 				   1000000000000000ull, rnd_mode,
 				   pfpsf);
 	BID_RETURN (res);
       }
     }


     if (extra_digits > 0) {
       // will divide by 10^(digits_p - 16)

       // add a constant to P, depending on rounding mode
       // 0.5*10^(digits_p - 16) for round-to-nearest
       __add_128_64 (P, P, round_const_table[rmode][extra_digits]);

       // get P*(2^M[extra_digits])/10^extra_digits
       __mul_128x128_full (Q_high, Q_low, P,
 			  reciprocals10_128[extra_digits]);

       // now get P/10^extra_digits: shift Q_high right by M[extra_digits]-128
       amount = recip_scale[extra_digits];
       __shr_128 (C128, Q_high, amount);

       C64 = __low_64 (C128);

 #ifndef IEEE_ROUND_NEAREST_TIES_AWAY
 #ifndef IEEE_ROUND_NEAREST
       if (rmode == 0)	//ROUNDING_TO_NEAREST
 #endif
 	if ((C64 & 1) && !round_up) {
 	  // check whether fractional part of initial_P/10^extra_digits
 	  // is exactly .5
 	  // this is the same as fractional part of
 	  // (initial_P + 0.5*10^extra_digits)/10^extra_digits is exactly zero

 	  // get remainder
 	  remainder_h = Q_high.w[0] << (64 - amount);

 	  // test whether fractional part is 0
 	  if (!remainder_h
 	      && (Q_low.w[1] < reciprocals10_128[extra_digits].w[1]
 		  || (Q_low.w[1] == reciprocals10_128[extra_digits].w[1]
 		      && Q_low.w[0] <
 		      reciprocals10_128[extra_digits].w[0]))) {
 	    C64--;
 	  }
 	}
 #endif

 #ifdef SET_STATUS_FLAGS
       status = INEXACT_EXCEPTION | uf_status;

       // get remainder
       remainder_h = Q_high.w[0] << (64 - amount);

       switch (rmode) {
       case ROUNDING_TO_NEAREST:
       case ROUNDING_TIES_AWAY:
 	// test whether fractional part is 0
 	if (remainder_h == 0x8000000000000000ull
 	    && (Q_low.w[1] < reciprocals10_128[extra_digits].w[1]
 		|| (Q_low.w[1] == reciprocals10_128[extra_digits].w[1]
 		    && Q_low.w[0] <
 		    reciprocals10_128[extra_digits].w[0])))
 	  status = EXACT_STATUS;
 	break;
       case ROUNDING_DOWN:
       case ROUNDING_TO_ZERO:
 	if (!remainder_h
 	    && (Q_low.w[1] < reciprocals10_128[extra_digits].w[1]
 		|| (Q_low.w[1] == reciprocals10_128[extra_digits].w[1]
 		    && Q_low.w[0] <
 		    reciprocals10_128[extra_digits].w[0])))
 	  status = EXACT_STATUS;
 	break;
       default:
 	// round up
 	__add_carry_out (Stemp.w[0], CY, Q_low.w[0],
 			 reciprocals10_128[extra_digits].w[0]);
 	__add_carry_in_out (Stemp.w[1], carry, Q_low.w[1],
 			    reciprocals10_128[extra_digits].w[1], CY);
 	if ((remainder_h >> (64 - amount)) + carry >=
 	    (((UINT64) 1) << amount))
 	  status = EXACT_STATUS;
       }

       __set_status_flags (pfpsf, status);
 #endif

       // convert to BID and return
       res =
 	fast_get_BID64_check_OF (sign_x ^ sign_y, final_exponent, C64,
 				 rmode, pfpsf);
       BID_RETURN (res);
     }
     // go to convert_format and exit
     C64 = __low_64 (P);
     res =
       get_BID64 (sign_x ^ sign_y,
 		 exponent_x + exponent_y - DECIMAL_EXPONENT_BIAS, C64,
 		 rmode, pfpsf);
     BID_RETURN (res);
   }
 }
	/* Copyright (C) 2007 Free Software Foundation, Inc.

	This file is part of GCC.

	GCC is free software; you can redistribute it and/or modify it under
	the terms of the GNU General Public License as published by the Free
	Software Foundation; either version 2, or (at your option) any later
	version.

	In addition to the permissions in the GNU General Public License, the
	Free Software Foundation gives you unlimited permission to link the
	compiled version of this file into combinations with other programs,
	and to distribute those combinations without any restriction coming
	from the use of this file. (The General Public License restrictions
	do apply in other respects; for example, they cover modification of
	the file, and distribution when not linked into a combine
	executable.)

	GCC 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 General Public License
	for more details.

	You should have received a copy of the GNU General Public License
	along with GCC; see the file COPYING. If not, write to the Free
	Software Foundation, 51 Franklin Street, Fifth Floor, Boston, MA
	02110-1301, USA. */

	/*****************************************************************************
	* BID64 multiply
	*****************************************************************************
	*
	* Algorithm description:
	*
	* if(number_digits(coefficient_x)+number_digits(coefficient_y) guaranteed
	* below 16)
	* return get_BID64(sign_x^sign_y, exponent_x + exponent_y - dec_bias,
	* coefficient_x*coefficient_y)
	* else
	* get long product: coefficient_x*coefficient_y
	* determine number of digits to round off (extra_digits)
	* rounding is performed as a 128x128-bit multiplication by
	* 2^M[extra_digits]/10^extra_digits, followed by a shift
	* M[extra_digits] is sufficiently large for required accuracy
	*
	****************************************************************************/

	#include "bid_internal.h"

	#if DECIMAL_CALL_BY_REFERENCE

	void
	bid64_mul (UINT64 * pres, UINT64 * px,
	UINT64 *
	py _RND_MODE_PARAM _EXC_FLAGS_PARAM _EXC_MASKS_PARAM
	_EXC_INFO_PARAM) {
	UINT64 x, y;
	#else

	UINT64
	bid64_mul (UINT64 x,
	UINT64 y _RND_MODE_PARAM _EXC_FLAGS_PARAM
	_EXC_MASKS_PARAM _EXC_INFO_PARAM) {
	#endif
	UINT128 P, PU, C128, Q_high, Q_low, Stemp;
	UINT64 sign_x, sign_y, coefficient_x, coefficient_y;
	UINT64 C64, remainder_h, carry, CY, res;
	UINT64 valid_x, valid_y;
	int_double tempx, tempy;
	int extra_digits, exponent_x, exponent_y, bin_expon_cx, bin_expon_cy,
	bin_expon_product;
	int rmode, digits_p, bp, amount, amount2, final_exponent, round_up;
	unsigned status, uf_status;

	#if DECIMAL_CALL_BY_REFERENCE
	#if !DECIMAL_GLOBAL_ROUNDING
	_IDEC_round rnd_mode = *prnd_mode;
	#endif
	x = *px;
	y = *py;
	#endif

	valid_x = unpack_BID64 (&sign_x, &exponent_x, &coefficient_x, x);
	valid_y = unpack_BID64 (&sign_y, &exponent_y, &coefficient_y, y);

	// unpack arguments, check for NaN or Infinity
	if (!valid_x) {

	#ifdef SET_STATUS_FLAGS
	if ((y & SNAN_MASK64) == SNAN_MASK64) // y is sNaN
	__set_status_flags (pfpsf, INVALID_EXCEPTION);
	#endif
	// x is Inf. or NaN

	// test if x is NaN
	if ((x & NAN_MASK64) == NAN_MASK64) {
	#ifdef SET_STATUS_FLAGS
	if ((x & SNAN_MASK64) == SNAN_MASK64) // sNaN
	__set_status_flags (pfpsf, INVALID_EXCEPTION);
	#endif
	BID_RETURN (coefficient_x & QUIET_MASK64);
	}
	// x is Infinity?
	if ((x & INFINITY_MASK64) == INFINITY_MASK64) {
	// check if y is 0
	if (((y & INFINITY_MASK64) != INFINITY_MASK64)
	&& !coefficient_y) {
	#ifdef SET_STATUS_FLAGS
	__set_status_flags (pfpsf, INVALID_EXCEPTION);
	#endif
	// y==0 , return NaN
	BID_RETURN (NAN_MASK64);
	}
	// check if y is NaN
	if ((y & NAN_MASK64) == NAN_MASK64)
	// y==NaN , return NaN
	BID_RETURN (coefficient_y & QUIET_MASK64);
	// otherwise return +/-Inf
	BID_RETURN (((x ^ y) & 0x8000000000000000ull) \| INFINITY_MASK64);
	}
	// x is 0
	if (((y & INFINITY_MASK64) != INFINITY_MASK64)) {
	if ((y & SPECIAL_ENCODING_MASK64) == SPECIAL_ENCODING_MASK64)
	exponent_y = ((UINT32) (y >> 51)) & 0x3ff;
	else
	exponent_y = ((UINT32) (y >> 53)) & 0x3ff;
	sign_y = y & 0x8000000000000000ull;

	exponent_x += exponent_y - DECIMAL_EXPONENT_BIAS;
	if (exponent_x > DECIMAL_MAX_EXPON_64)
	exponent_x = DECIMAL_MAX_EXPON_64;
	else if (exponent_x < 0)
	exponent_x = 0;
	BID_RETURN ((sign_x ^ sign_y) \| (((UINT64) exponent_x) << 53));
	}
	}
	if (!valid_y) {
	// y is Inf. or NaN

	// test if y is NaN
	if ((y & NAN_MASK64) == NAN_MASK64) {
	#ifdef SET_STATUS_FLAGS
	if ((y & SNAN_MASK64) == SNAN_MASK64) // sNaN
	__set_status_flags (pfpsf, INVALID_EXCEPTION);
	#endif
	BID_RETURN (coefficient_y & QUIET_MASK64);
	}
	// y is Infinity?
	if ((y & INFINITY_MASK64) == INFINITY_MASK64) {
	// check if x is 0
	if (!coefficient_x) {
	__set_status_flags (pfpsf, INVALID_EXCEPTION);
	// x==0, return NaN
	BID_RETURN (NAN_MASK64);
	}
	// otherwise return +/-Inf
	BID_RETURN (((x ^ y) & 0x8000000000000000ull) \| INFINITY_MASK64);
	}
	// y is 0
	exponent_x += exponent_y - DECIMAL_EXPONENT_BIAS;
	if (exponent_x > DECIMAL_MAX_EXPON_64)
	exponent_x = DECIMAL_MAX_EXPON_64;
	else if (exponent_x < 0)
	exponent_x = 0;
	BID_RETURN ((sign_x ^ sign_y) \| (((UINT64) exponent_x) << 53));
	}
	//--- get number of bits in the coefficients of x and y ---
	// version 2 (original)
	tempx.d = (double) coefficient_x;
	bin_expon_cx = ((tempx.i & MASK_BINARY_EXPONENT) >> 52);
	tempy.d = (double) coefficient_y;
	bin_expon_cy = ((tempy.i & MASK_BINARY_EXPONENT) >> 52);

	// magnitude estimate for coefficient_x*coefficient_y is
	// 2^(unbiased_bin_expon_cx + unbiased_bin_expon_cx)
	bin_expon_product = bin_expon_cx + bin_expon_cy;

	// check if coefficient_xcoefficient_y<2^(10k+3)
	// equivalent to unbiased_bin_expon_cx + unbiased_bin_expon_cx < 10*k+1
	if (bin_expon_product < UPPER_EXPON_LIMIT + 2 * BINARY_EXPONENT_BIAS) {
	// easy multiply
	C64 = coefficient_x * coefficient_y;

	res =
	get_BID64_small_mantissa (sign_x ^ sign_y,
	exponent_x + exponent_y -
	DECIMAL_EXPONENT_BIAS, C64, rnd_mode,
	pfpsf);
	BID_RETURN (res);
	} else {
	uf_status = 0;
	// get 128-bit product: coefficient_x*coefficient_y
	__mul_64x64_to_128 (P, coefficient_x, coefficient_y);

	// tighten binary range of P: leading bit is 2^bp
	// unbiased_bin_expon_product <= bp <= unbiased_bin_expon_product+1
	bin_expon_product -= 2 * BINARY_EXPONENT_BIAS;

	__tight_bin_range_128 (bp, P, bin_expon_product);

	// get number of decimal digits in the product
	digits_p = estimate_decimal_digits[bp];
	if (!(__unsigned_compare_gt_128 (power10_table_128[digits_p], P)))
	digits_p++; // if power10_table_128[digits_p] <= P

	// determine number of decimal digits to be rounded out
	extra_digits = digits_p - MAX_FORMAT_DIGITS;
	final_exponent =
	exponent_x + exponent_y + extra_digits - DECIMAL_EXPONENT_BIAS;

	#ifndef IEEE_ROUND_NEAREST_TIES_AWAY
	#ifndef IEEE_ROUND_NEAREST
	rmode = rnd_mode;
	if (sign_x ^ sign_y && (unsigned) (rmode - 1) < 2)
	rmode = 3 - rmode;
	#else
	rmode = 0;
	#endif
	#else
	rmode = 0;
	#endif

	round_up = 0;
	if (((unsigned) final_exponent) >= 3 * 256) {
	if (final_exponent < 0) {
	// underflow
	if (final_exponent + 16 < 0) {
	res = sign_x ^ sign_y;
	__set_status_flags (pfpsf,
	UNDERFLOW_EXCEPTION \| INEXACT_EXCEPTION);
	if (rmode == ROUNDING_UP)
	res \|= 1;
	BID_RETURN (res);
	}

	uf_status = UNDERFLOW_EXCEPTION;
	if (final_exponent == -1) {
	__add_128_64 (PU, P, round_const_table[rmode][extra_digits]);
	if (__unsigned_compare_ge_128
	(PU, power10_table_128[extra_digits + 16]))
	uf_status = 0;
	}
	extra_digits -= final_exponent;
	final_exponent = 0;

	if (extra_digits > 17) {
	__mul_128x128_full (Q_high, Q_low, P, reciprocals10_128[16]);

	amount = recip_scale[16];
	__shr_128 (P, Q_high, amount);

	// get sticky bits
	amount2 = 64 - amount;
	remainder_h = 0;
	remainder_h--;
	remainder_h >>= amount2;
	remainder_h = remainder_h & Q_high.w[0];

	extra_digits -= 16;
	if (remainder_h \|\| (Q_low.w[1] > reciprocals10_128[16].w[1]
	\|\| (Q_low.w[1] ==
	reciprocals10_128[16].w[1]
	&& Q_low.w[0] >=
	reciprocals10_128[16].w[0]))) {
	round_up = 1;
	__set_status_flags (pfpsf,
	UNDERFLOW_EXCEPTION \|
	INEXACT_EXCEPTION);
	P.w[0] = (P.w[0] << 3) + (P.w[0] << 1);
	P.w[0] \|= 1;
	extra_digits++;
	}
	}
	} else {
	res =
	fast_get_BID64_check_OF (sign_x ^ sign_y, final_exponent,
	1000000000000000ull, rnd_mode,
	pfpsf);
	BID_RETURN (res);
	}
	}


	if (extra_digits > 0) {
	// will divide by 10^(digits_p - 16)

	// add a constant to P, depending on rounding mode
	// 0.5*10^(digits_p - 16) for round-to-nearest
	__add_128_64 (P, P, round_const_table[rmode][extra_digits]);

	// get P*(2^M[extra_digits])/10^extra_digits
	__mul_128x128_full (Q_high, Q_low, P,
	reciprocals10_128[extra_digits]);

	// now get P/10^extra_digits: shift Q_high right by M[extra_digits]-128
	amount = recip_scale[extra_digits];
	__shr_128 (C128, Q_high, amount);

	C64 = __low_64 (C128);

	#ifndef IEEE_ROUND_NEAREST_TIES_AWAY
	#ifndef IEEE_ROUND_NEAREST
	if (rmode == 0) //ROUNDING_TO_NEAREST
	#endif
	if ((C64 & 1) && !round_up) {
	// check whether fractional part of initial_P/10^extra_digits
	// is exactly .5
	// this is the same as fractional part of
	// (initial_P + 0.5*10^extra_digits)/10^extra_digits is exactly zero

	// get remainder
	remainder_h = Q_high.w[0] << (64 - amount);

	// test whether fractional part is 0
	if (!remainder_h
	&& (Q_low.w[1] < reciprocals10_128[extra_digits].w[1]
	\|\| (Q_low.w[1] == reciprocals10_128[extra_digits].w[1]
	&& Q_low.w[0] <
	reciprocals10_128[extra_digits].w[0]))) {
	C64--;
	}
	}
	#endif

	#ifdef SET_STATUS_FLAGS
	status = INEXACT_EXCEPTION \| uf_status;

	// get remainder
	remainder_h = Q_high.w[0] << (64 - amount);

	switch (rmode) {
	case ROUNDING_TO_NEAREST:
	case ROUNDING_TIES_AWAY:
	// test whether fractional part is 0
	if (remainder_h == 0x8000000000000000ull
	&& (Q_low.w[1] < reciprocals10_128[extra_digits].w[1]
	\|\| (Q_low.w[1] == reciprocals10_128[extra_digits].w[1]
	&& Q_low.w[0] <
	reciprocals10_128[extra_digits].w[0])))
	status = EXACT_STATUS;
	break;
	case ROUNDING_DOWN:
	case ROUNDING_TO_ZERO:
	if (!remainder_h
	&& (Q_low.w[1] < reciprocals10_128[extra_digits].w[1]
	\|\| (Q_low.w[1] == reciprocals10_128[extra_digits].w[1]
	&& Q_low.w[0] <
	reciprocals10_128[extra_digits].w[0])))
	status = EXACT_STATUS;
	break;
	default:
	// round up
	__add_carry_out (Stemp.w[0], CY, Q_low.w[0],
	reciprocals10_128[extra_digits].w[0]);
	__add_carry_in_out (Stemp.w[1], carry, Q_low.w[1],
	reciprocals10_128[extra_digits].w[1], CY);
	if ((remainder_h >> (64 - amount)) + carry >=
	(((UINT64) 1) << amount))
	status = EXACT_STATUS;
	}

	__set_status_flags (pfpsf, status);
	#endif

	// convert to BID and return
	res =
	fast_get_BID64_check_OF (sign_x ^ sign_y, final_exponent, C64,
	rmode, pfpsf);
	BID_RETURN (res);
	}
	// go to convert_format and exit
	C64 = __low_64 (P);
	res =
	get_BID64 (sign_x ^ sign_y,
	exponent_x + exponent_y - DECIMAL_EXPONENT_BIAS, C64,
	rmode, pfpsf);
	BID_RETURN (res);
	}
	}