libgcc/config/libbid/bid128_quantize.c - gcc - Git at Google

 /* Copyright (C) 2007-2021 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 3, or (at your option) any later
 version.

 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.

 Under Section 7 of GPL version 3, you are granted additional
 permissions described in the GCC Runtime Library Exception, version
 3.1, as published by the Free Software Foundation.

 You should have received a copy of the GNU General Public License and
 a copy of the GCC Runtime Library Exception along with this program;
 see the files COPYING3 and COPYING.RUNTIME respectively.  If not, see
 <http://www.gnu.org/licenses/>.  */

 #define BID_128RES
 #include "bid_internal.h"

 BID128_FUNCTION_ARG2 (bid128_quantize, x, y)

      UINT256 CT;
      UINT128 CX, CY, T, CX2, CR, Stemp, res, REM_H, C2N;
      UINT64 sign_x, sign_y, remainder_h, carry, CY64, valid_x;
      int_float tempx;
      int exponent_x, exponent_y, digits_x, extra_digits, amount;
      int expon_diff, total_digits, bin_expon_cx, rmode, status;

 valid_x = unpack_BID128_value (&sign_x, &exponent_x, &CX, x);

   // unpack arguments, check for NaN or Infinity
 if (!unpack_BID128_value (&sign_y, &exponent_y, &CY, y)) {
     // y is Inf. or NaN
 #ifdef SET_STATUS_FLAGS
 if ((x.w[1] & SNAN_MASK64) == SNAN_MASK64)	// y is sNaN
   __set_status_flags (pfpsf, INVALID_EXCEPTION);
 #endif

     // test if y is NaN
 if ((y.w[1] & 0x7c00000000000000ull) == 0x7c00000000000000ull) {
 #ifdef SET_STATUS_FLAGS
   if ((y.w[1] & 0x7e00000000000000ull) == 0x7e00000000000000ull) {
     // set status flags
     __set_status_flags (pfpsf, INVALID_EXCEPTION);
   }
 #endif
   if ((x.w[1] & 0x7c00000000000000ull) != 0x7c00000000000000ull) {
     res.w[1] = CY.w[1] & QUIET_MASK64;
     res.w[0] = CY.w[0];
   } else {
     res.w[1] = CX.w[1] & QUIET_MASK64;
     res.w[0] = CX.w[0];
   }
   BID_RETURN (res);
 }
     // y is Infinity?
 if ((y.w[1] & 0x7800000000000000ull) == 0x7800000000000000ull) {
   // check if x is not Inf.
   if (((x.w[1] & 0x7c00000000000000ull) < 0x7800000000000000ull)) {
     // return NaN
 #ifdef SET_STATUS_FLAGS
     // set status flags
     __set_status_flags (pfpsf, INVALID_EXCEPTION);
 #endif
     res.w[1] = 0x7c00000000000000ull;
     res.w[0] = 0;
     BID_RETURN (res);
   } else
     if (((x.w[1] & 0x7c00000000000000ull) <= 0x7800000000000000ull)) {
     res.w[1] = CX.w[1] & QUIET_MASK64;
     res.w[0] = CX.w[0];
     BID_RETURN (res);
   }
 }

 }

 if (!valid_x) {
   // test if x is NaN or Inf
   if ((x.w[1] & 0x7c00000000000000ull) == 0x7800000000000000ull) {
 #ifdef SET_STATUS_FLAGS
     // set status flags
     __set_status_flags (pfpsf, INVALID_EXCEPTION);
 #endif
     res.w[1] = 0x7c00000000000000ull;
     res.w[0] = 0;
     BID_RETURN (res);
   } else if ((x.w[1] & 0x7c00000000000000ull) == 0x7c00000000000000ull) {
     if ((x.w[1] & 0x7e00000000000000ull) == 0x7e00000000000000ull) {
 #ifdef SET_STATUS_FLAGS
       // set status flags
       __set_status_flags (pfpsf, INVALID_EXCEPTION);
 #endif
     }
     res.w[1] = CX.w[1] & QUIET_MASK64;
     res.w[0] = CX.w[0];
     BID_RETURN (res);
   }
   if (!CX.w[1] && !CX.w[0]) {
     get_BID128_very_fast (&res, sign_x, exponent_y, CX);
     BID_RETURN (res);
   }
 }
   // get number of decimal digits in coefficient_x
 if (CX.w[1]) {
   tempx.d = (float) CX.w[1];
   bin_expon_cx = ((tempx.i >> 23) & 0xff) - 0x7f + 64;
 } else {
   tempx.d = (float) CX.w[0];
   bin_expon_cx = ((tempx.i >> 23) & 0xff) - 0x7f;
 }

 digits_x = estimate_decimal_digits[bin_expon_cx];
 if (CX.w[1] > power10_table_128[digits_x].w[1]
     || (CX.w[1] == power10_table_128[digits_x].w[1]
 	&& CX.w[0] >= power10_table_128[digits_x].w[0]))
   digits_x++;

 expon_diff = exponent_x - exponent_y;
 total_digits = digits_x + expon_diff;

 if ((UINT32) total_digits <= 34) {
   if (expon_diff >= 0) {
     T = power10_table_128[expon_diff];
     __mul_128x128_low (CX2, T, CX);
     get_BID128_very_fast (&res, sign_x, exponent_y, CX2);
     BID_RETURN (res);
   }
 #ifndef IEEE_ROUND_NEAREST_TIES_AWAY
 #ifndef IEEE_ROUND_NEAREST
   rmode = rnd_mode;
   if (sign_x && (unsigned) (rmode - 1) < 2)
     rmode = 3 - rmode;
 #else
   rmode = 0;
 #endif
 #else
   rmode = 0;
 #endif
   // must round off -expon_diff digits
   extra_digits = -expon_diff;
   __add_128_128 (CX, CX, round_const_table_128[rmode][extra_digits]);

   // get P*(2^M[extra_digits])/10^extra_digits
   __mul_128x128_to_256 (CT, CX, reciprocals10_128[extra_digits]);

   // now get P/10^extra_digits: shift C64 right by M[extra_digits]-128
   amount = recip_scale[extra_digits];
   CX2.w[0] = CT.w[2];
   CX2.w[1] = CT.w[3];
   if (amount >= 64) {
     CR.w[1] = 0;
     CR.w[0] = CX2.w[1] >> (amount - 64);
   } else {
     __shr_128 (CR, CX2, amount);
   }

 #ifndef IEEE_ROUND_NEAREST_TIES_AWAY
 #ifndef IEEE_ROUND_NEAREST
   if (rnd_mode == 0)
 #endif
     if (CR.w[0] & 1) {
       // 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
       if (amount >= 64) {
 	remainder_h = CX2.w[0] | (CX2.w[1] << (128 - amount));
       } else
 	remainder_h = CX2.w[0] << (64 - amount);

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

 #ifdef SET_STATUS_FLAGS
   status = INEXACT_EXCEPTION;

   // get remainder
   if (amount >= 64) {
     REM_H.w[1] = (CX2.w[1] << (128 - amount));
     REM_H.w[0] = CX2.w[0];
   } else {
     REM_H.w[1] = CX2.w[0] << (64 - amount);
     REM_H.w[0] = 0;
   }

   switch (rmode) {
   case ROUNDING_TO_NEAREST:
   case ROUNDING_TIES_AWAY:
     // test whether fractional part is 0
     if (REM_H.w[1] == 0x8000000000000000ull && !REM_H.w[0]
 	&& (CT.w[1] < reciprocals10_128[extra_digits].w[1]
 	    || (CT.w[1] == reciprocals10_128[extra_digits].w[1]
 		&& CT.w[0] < reciprocals10_128[extra_digits].w[0])))
       status = EXACT_STATUS;
     break;
   case ROUNDING_DOWN:
   case ROUNDING_TO_ZERO:
     if (!(REM_H.w[1] | REM_H.w[0])
 	&& (CT.w[1] < reciprocals10_128[extra_digits].w[1]
 	    || (CT.w[1] == reciprocals10_128[extra_digits].w[1]
 		&& CT.w[0] < reciprocals10_128[extra_digits].w[0])))
       status = EXACT_STATUS;
     break;
   default:
     // round up
     __add_carry_out (Stemp.w[0], CY64, CT.w[0],
 		     reciprocals10_128[extra_digits].w[0]);
     __add_carry_in_out (Stemp.w[1], carry, CT.w[1],
 			reciprocals10_128[extra_digits].w[1], CY64);
     if (amount < 64) {
       C2N.w[1] = 0;
       C2N.w[0] = ((UINT64) 1) << amount;
       REM_H.w[0] = REM_H.w[1] >> (64 - amount);
       REM_H.w[1] = 0;
     } else {
       C2N.w[1] = ((UINT64) 1) << (amount - 64);
       C2N.w[0] = 0;
       REM_H.w[1] >>= (128 - amount);
     }
     REM_H.w[0] += carry;
     if (REM_H.w[0] < carry)
       REM_H.w[1]++;
     if (__unsigned_compare_ge_128 (REM_H, C2N))
       status = EXACT_STATUS;
   }

   __set_status_flags (pfpsf, status);

 #endif
   get_BID128_very_fast (&res, sign_x, exponent_y, CR);
   BID_RETURN (res);
 }
 if (total_digits < 0) {
   CR.w[1] = CR.w[0] = 0;
 #ifndef IEEE_ROUND_NEAREST_TIES_AWAY
 #ifndef IEEE_ROUND_NEAREST
   rmode = rnd_mode;
   if (sign_x && (unsigned) (rmode - 1) < 2)
     rmode = 3 - rmode;
   if (rmode == ROUNDING_UP)
     CR.w[0] = 1;
 #endif
 #endif
 #ifdef SET_STATUS_FLAGS
   __set_status_flags (pfpsf, INEXACT_EXCEPTION);
 #endif
   get_BID128_very_fast (&res, sign_x, exponent_y, CR);
   BID_RETURN (res);
 }
   // else  more than 34 digits in coefficient
 #ifdef SET_STATUS_FLAGS
 __set_status_flags (pfpsf, INVALID_EXCEPTION);
 #endif
 res.w[1] = 0x7c00000000000000ull;
 res.w[0] = 0;
 BID_RETURN (res);

 }
	/* Copyright (C) 2007-2021 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 3, or (at your option) any later
	version.

	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.

	Under Section 7 of GPL version 3, you are granted additional
	permissions described in the GCC Runtime Library Exception, version
	3.1, as published by the Free Software Foundation.

	You should have received a copy of the GNU General Public License and
	a copy of the GCC Runtime Library Exception along with this program;
	see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
	<http://www.gnu.org/licenses/>. */

	#define BID_128RES
	#include "bid_internal.h"

	BID128_FUNCTION_ARG2 (bid128_quantize, x, y)

	UINT256 CT;
	UINT128 CX, CY, T, CX2, CR, Stemp, res, REM_H, C2N;
	UINT64 sign_x, sign_y, remainder_h, carry, CY64, valid_x;
	int_float tempx;
	int exponent_x, exponent_y, digits_x, extra_digits, amount;
	int expon_diff, total_digits, bin_expon_cx, rmode, status;

	valid_x = unpack_BID128_value (&sign_x, &exponent_x, &CX, x);

	// unpack arguments, check for NaN or Infinity
	if (!unpack_BID128_value (&sign_y, &exponent_y, &CY, y)) {
	// y is Inf. or NaN
	#ifdef SET_STATUS_FLAGS
	if ((x.w[1] & SNAN_MASK64) == SNAN_MASK64) // y is sNaN
	__set_status_flags (pfpsf, INVALID_EXCEPTION);
	#endif

	// test if y is NaN
	if ((y.w[1] & 0x7c00000000000000ull) == 0x7c00000000000000ull) {
	#ifdef SET_STATUS_FLAGS
	if ((y.w[1] & 0x7e00000000000000ull) == 0x7e00000000000000ull) {
	// set status flags
	__set_status_flags (pfpsf, INVALID_EXCEPTION);
	}
	#endif
	if ((x.w[1] & 0x7c00000000000000ull) != 0x7c00000000000000ull) {
	res.w[1] = CY.w[1] & QUIET_MASK64;
	res.w[0] = CY.w[0];
	} else {
	res.w[1] = CX.w[1] & QUIET_MASK64;
	res.w[0] = CX.w[0];
	}
	BID_RETURN (res);
	}
	// y is Infinity?
	if ((y.w[1] & 0x7800000000000000ull) == 0x7800000000000000ull) {
	// check if x is not Inf.
	if (((x.w[1] & 0x7c00000000000000ull) < 0x7800000000000000ull)) {
	// return NaN
	#ifdef SET_STATUS_FLAGS
	// set status flags
	__set_status_flags (pfpsf, INVALID_EXCEPTION);
	#endif
	res.w[1] = 0x7c00000000000000ull;
	res.w[0] = 0;
	BID_RETURN (res);
	} else
	if (((x.w[1] & 0x7c00000000000000ull) <= 0x7800000000000000ull)) {
	res.w[1] = CX.w[1] & QUIET_MASK64;
	res.w[0] = CX.w[0];
	BID_RETURN (res);
	}
	}

	}

	if (!valid_x) {
	// test if x is NaN or Inf
	if ((x.w[1] & 0x7c00000000000000ull) == 0x7800000000000000ull) {
	#ifdef SET_STATUS_FLAGS
	// set status flags
	__set_status_flags (pfpsf, INVALID_EXCEPTION);
	#endif
	res.w[1] = 0x7c00000000000000ull;
	res.w[0] = 0;
	BID_RETURN (res);
	} else if ((x.w[1] & 0x7c00000000000000ull) == 0x7c00000000000000ull) {
	if ((x.w[1] & 0x7e00000000000000ull) == 0x7e00000000000000ull) {
	#ifdef SET_STATUS_FLAGS
	// set status flags
	__set_status_flags (pfpsf, INVALID_EXCEPTION);
	#endif
	}
	res.w[1] = CX.w[1] & QUIET_MASK64;
	res.w[0] = CX.w[0];
	BID_RETURN (res);
	}
	if (!CX.w[1] && !CX.w[0]) {
	get_BID128_very_fast (&res, sign_x, exponent_y, CX);
	BID_RETURN (res);
	}
	}
	// get number of decimal digits in coefficient_x
	if (CX.w[1]) {
	tempx.d = (float) CX.w[1];
	bin_expon_cx = ((tempx.i >> 23) & 0xff) - 0x7f + 64;
	} else {
	tempx.d = (float) CX.w[0];
	bin_expon_cx = ((tempx.i >> 23) & 0xff) - 0x7f;
	}

	digits_x = estimate_decimal_digits[bin_expon_cx];
	if (CX.w[1] > power10_table_128[digits_x].w[1]
	\|\| (CX.w[1] == power10_table_128[digits_x].w[1]
	&& CX.w[0] >= power10_table_128[digits_x].w[0]))
	digits_x++;

	expon_diff = exponent_x - exponent_y;
	total_digits = digits_x + expon_diff;

	if ((UINT32) total_digits <= 34) {
	if (expon_diff >= 0) {
	T = power10_table_128[expon_diff];
	__mul_128x128_low (CX2, T, CX);
	get_BID128_very_fast (&res, sign_x, exponent_y, CX2);
	BID_RETURN (res);
	}
	#ifndef IEEE_ROUND_NEAREST_TIES_AWAY
	#ifndef IEEE_ROUND_NEAREST
	rmode = rnd_mode;
	if (sign_x && (unsigned) (rmode - 1) < 2)
	rmode = 3 - rmode;
	#else
	rmode = 0;
	#endif
	#else
	rmode = 0;
	#endif
	// must round off -expon_diff digits
	extra_digits = -expon_diff;
	__add_128_128 (CX, CX, round_const_table_128[rmode][extra_digits]);

	// get P*(2^M[extra_digits])/10^extra_digits
	__mul_128x128_to_256 (CT, CX, reciprocals10_128[extra_digits]);

	// now get P/10^extra_digits: shift C64 right by M[extra_digits]-128
	amount = recip_scale[extra_digits];
	CX2.w[0] = CT.w[2];
	CX2.w[1] = CT.w[3];
	if (amount >= 64) {
	CR.w[1] = 0;
	CR.w[0] = CX2.w[1] >> (amount - 64);
	} else {
	__shr_128 (CR, CX2, amount);
	}

	#ifndef IEEE_ROUND_NEAREST_TIES_AWAY
	#ifndef IEEE_ROUND_NEAREST
	if (rnd_mode == 0)
	#endif
	if (CR.w[0] & 1) {
	// 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
	if (amount >= 64) {
	remainder_h = CX2.w[0] \| (CX2.w[1] << (128 - amount));
	} else
	remainder_h = CX2.w[0] << (64 - amount);

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

	#ifdef SET_STATUS_FLAGS
	status = INEXACT_EXCEPTION;

	// get remainder
	if (amount >= 64) {
	REM_H.w[1] = (CX2.w[1] << (128 - amount));
	REM_H.w[0] = CX2.w[0];
	} else {
	REM_H.w[1] = CX2.w[0] << (64 - amount);
	REM_H.w[0] = 0;
	}

	switch (rmode) {
	case ROUNDING_TO_NEAREST:
	case ROUNDING_TIES_AWAY:
	// test whether fractional part is 0
	if (REM_H.w[1] == 0x8000000000000000ull && !REM_H.w[0]
	&& (CT.w[1] < reciprocals10_128[extra_digits].w[1]
	\|\| (CT.w[1] == reciprocals10_128[extra_digits].w[1]
	&& CT.w[0] < reciprocals10_128[extra_digits].w[0])))
	status = EXACT_STATUS;
	break;
	case ROUNDING_DOWN:
	case ROUNDING_TO_ZERO:
	if (!(REM_H.w[1] \| REM_H.w[0])
	&& (CT.w[1] < reciprocals10_128[extra_digits].w[1]
	\|\| (CT.w[1] == reciprocals10_128[extra_digits].w[1]
	&& CT.w[0] < reciprocals10_128[extra_digits].w[0])))
	status = EXACT_STATUS;
	break;
	default:
	// round up
	__add_carry_out (Stemp.w[0], CY64, CT.w[0],
	reciprocals10_128[extra_digits].w[0]);
	__add_carry_in_out (Stemp.w[1], carry, CT.w[1],
	reciprocals10_128[extra_digits].w[1], CY64);
	if (amount < 64) {
	C2N.w[1] = 0;
	C2N.w[0] = ((UINT64) 1) << amount;
	REM_H.w[0] = REM_H.w[1] >> (64 - amount);
	REM_H.w[1] = 0;
	} else {
	C2N.w[1] = ((UINT64) 1) << (amount - 64);
	C2N.w[0] = 0;
	REM_H.w[1] >>= (128 - amount);
	}
	REM_H.w[0] += carry;
	if (REM_H.w[0] < carry)
	REM_H.w[1]++;
	if (__unsigned_compare_ge_128 (REM_H, C2N))
	status = EXACT_STATUS;
	}

	__set_status_flags (pfpsf, status);

	#endif
	get_BID128_very_fast (&res, sign_x, exponent_y, CR);
	BID_RETURN (res);
	}
	if (total_digits < 0) {
	CR.w[1] = CR.w[0] = 0;
	#ifndef IEEE_ROUND_NEAREST_TIES_AWAY
	#ifndef IEEE_ROUND_NEAREST
	rmode = rnd_mode;
	if (sign_x && (unsigned) (rmode - 1) < 2)
	rmode = 3 - rmode;
	if (rmode == ROUNDING_UP)
	CR.w[0] = 1;
	#endif
	#endif
	#ifdef SET_STATUS_FLAGS
	__set_status_flags (pfpsf, INEXACT_EXCEPTION);
	#endif
	get_BID128_very_fast (&res, sign_x, exponent_y, CR);
	BID_RETURN (res);
	}
	// else more than 34 digits in coefficient
	#ifdef SET_STATUS_FLAGS
	__set_status_flags (pfpsf, INVALID_EXCEPTION);
	#endif
	res.w[1] = 0x7c00000000000000ull;
	res.w[0] = 0;
	BID_RETURN (res);

	}