config/rs6000/ibm-ldouble.c

1.1  mrg /* 128-bit long double support routines for Darwin.
1.1  mrg    Copyright (C) 1993-2013 Free Software Foundation, Inc.
1.1  mrg
1.1  mrg This file is part of GCC.
1.1  mrg
1.1  mrg GCC is free software; you can redistribute it and/or modify it under
1.1  mrg the terms of the GNU General Public License as published by the Free
1.1  mrg Software Foundation; either version 3, or (at your option) any later
1.1  mrg version.
1.1  mrg
1.1  mrg GCC is distributed in the hope that it will be useful, but WITHOUT ANY
1.1  mrg WARRANTY; without even the implied warranty of MERCHANTABILITY or
1.1  mrg FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
1.1  mrg for more details.
1.1  mrg
1.1  mrg Under Section 7 of GPL version 3, you are granted additional
1.1  mrg permissions described in the GCC Runtime Library Exception, version
1.1  mrg 3.1, as published by the Free Software Foundation.
1.1  mrg
1.1  mrg You should have received a copy of the GNU General Public License and
1.1  mrg a copy of the GCC Runtime Library Exception along with this program;
1.1  mrg see the files COPYING3 and COPYING.RUNTIME respectively.  If not, see
1.1  mrg <http://www.gnu.org/licenses/>.  */
1.1  mrg
1.1  mrg
1.1  mrg /* Implementations of floating-point long double basic arithmetic
1.1  mrg    functions called by the IBM C compiler when generating code for
1.1  mrg    PowerPC platforms.  In particular, the following functions are
1.1  mrg    implemented: __gcc_qadd, __gcc_qsub, __gcc_qmul, and __gcc_qdiv.
1.1  mrg    Double-double algorithms are based on the paper "Doubled-Precision
1.1  mrg    IEEE Standard 754 Floating-Point Arithmetic" by W. Kahan, February 26,
1.1  mrg    1987.  An alternative published reference is "Software for
1.1  mrg    Doubled-Precision Floating-Point Computations", by Seppo Linnainmaa,
1.1  mrg    ACM TOMS vol 7 no 3, September 1981, pages 272-283.  */
1.1  mrg
1.1  mrg /* Each long double is made up of two IEEE doubles.  The value of the
1.1  mrg    long double is the sum of the values of the two parts.  The most
1.1  mrg    significant part is required to be the value of the long double
1.1  mrg    rounded to the nearest double, as specified by IEEE.  For Inf
1.1  mrg    values, the least significant part is required to be one of +0.0 or
1.1  mrg    -0.0.  No other requirements are made; so, for example, 1.0 may be
1.1  mrg    represented as (1.0, +0.0) or (1.0, -0.0), and the low part of a
1.1  mrg    NaN is don't-care.
1.1  mrg
1.1  mrg    This code currently assumes the most significant double is in
1.1  mrg    the lower numbered register or lower addressed memory.  */
1.1  mrg
1.1  mrg #if defined (__MACH__) || defined (__powerpc__) || defined (_AIX)
1.1  mrg
1.1  mrg #define fabs(x) __builtin_fabs(x)
1.1  mrg #define isless(x, y) __builtin_isless (x, y)
1.1  mrg #define inf() __builtin_inf()
1.1  mrg
1.1  mrg #define unlikely(x) __builtin_expect ((x), 0)
1.1  mrg
1.1  mrg #define nonfinite(a) unlikely (! isless (fabs (a), inf ()))
1.1  mrg
1.1  mrg /* Define ALIASNAME as a strong alias for NAME.  */
1.1  mrg # define strong_alias(name, aliasname) _strong_alias(name, aliasname)
1.1  mrg # define _strong_alias(name, aliasname) \
1.1  mrg   extern __typeof (name) aliasname __attribute__ ((alias (#name)));
1.1  mrg
1.1  mrg /* All these routines actually take two long doubles as parameters,
1.1  mrg    but GCC currently generates poor code when a union is used to turn
1.1  mrg    a long double into a pair of doubles.  */
1.1  mrg
1.1  mrg long double __gcc_qadd (double, double, double, double);
1.1  mrg long double __gcc_qsub (double, double, double, double);
1.1  mrg long double __gcc_qmul (double, double, double, double);
1.1  mrg long double __gcc_qdiv (double, double, double, double);
1.1  mrg
1.1  mrg #if defined __ELF__ && defined SHARED \
1.1  mrg     && (defined __powerpc64__ || !(defined __linux__ || defined __gnu_hurd__))
1.1  mrg /* Provide definitions of the old symbol names to satisfy apps and
1.1  mrg    shared libs built against an older libgcc.  To access the _xlq
1.1  mrg    symbols an explicit version reference is needed, so these won't
1.1  mrg    satisfy an unadorned reference like _xlqadd.  If dot symbols are
1.1  mrg    not needed, the assembler will remove the aliases from the symbol
1.1  mrg    table.  */
1.1  mrg __asm__ (".symver __gcc_qadd,_xlqadd (at) GCC_3.4\n\t"
1.1  mrg 	 ".symver __gcc_qsub,_xlqsub (at) GCC_3.4\n\t"
1.1  mrg 	 ".symver __gcc_qmul,_xlqmul (at) GCC_3.4\n\t"
1.1  mrg 	 ".symver __gcc_qdiv,_xlqdiv (at) GCC_3.4\n\t"
1.1  mrg 	 ".symver .__gcc_qadd,._xlqadd (at) GCC_3.4\n\t"
1.1  mrg 	 ".symver .__gcc_qsub,._xlqsub (at) GCC_3.4\n\t"
1.1  mrg 	 ".symver .__gcc_qmul,._xlqmul (at) GCC_3.4\n\t"
1.1  mrg 	 ".symver .__gcc_qdiv,._xlqdiv (at) GCC_3.4");
1.1  mrg #endif
1.1  mrg
1.1  mrg typedef union
1.1  mrg {
1.1  mrg   long double ldval;
1.1  mrg   double dval[2];
1.1  mrg } longDblUnion;
1.1  mrg
1.1  mrg /* Add two 'long double' values and return the result.	*/
1.1  mrg long double
1.1  mrg __gcc_qadd (double a, double aa, double c, double cc)
1.1  mrg {
1.1  mrg   longDblUnion x;
1.1  mrg   double z, q, zz, xh;
1.1  mrg
1.1  mrg   z = a + c;
1.1  mrg
1.1  mrg   if (nonfinite (z))
1.1  mrg     {
1.1  mrg       z = cc + aa + c + a;
1.1  mrg       if (nonfinite (z))
1.1  mrg 	return z;
1.1  mrg       x.dval[0] = z;  /* Will always be DBL_MAX.  */
1.1  mrg       zz = aa + cc;
1.1  mrg       if (fabs(a) > fabs(c))
1.1  mrg 	x.dval[1] = a - z + c + zz;
1.1  mrg       else
1.1  mrg 	x.dval[1] = c - z + a + zz;
1.1  mrg     }
1.1  mrg   else
1.1  mrg     {
1.1  mrg       q = a - z;
1.1  mrg       zz = q + c + (a - (q + z)) + aa + cc;
1.1  mrg
1.1  mrg       /* Keep -0 result.  */
1.1  mrg       if (zz == 0.0)
1.1  mrg 	return z;
1.1  mrg
1.1  mrg       xh = z + zz;
1.1  mrg       if (nonfinite (xh))
1.1  mrg 	return xh;
1.1  mrg
1.1  mrg       x.dval[0] = xh;
1.1  mrg       x.dval[1] = z - xh + zz;
1.1  mrg     }
1.1  mrg   return x.ldval;
1.1  mrg }
1.1  mrg
1.1  mrg long double
1.1  mrg __gcc_qsub (double a, double b, double c, double d)
1.1  mrg {
1.1  mrg   return __gcc_qadd (a, b, -c, -d);
1.1  mrg }
1.1  mrg
1.1  mrg #ifdef __NO_FPRS__
1.1  mrg static double fmsub (double, double, double);
1.1  mrg #endif
1.1  mrg
1.1  mrg long double
1.1  mrg __gcc_qmul (double a, double b, double c, double d)
1.1  mrg {
1.1  mrg   longDblUnion z;
1.1  mrg   double t, tau, u, v, w;
1.1  mrg
1.1  mrg   t = a * c;			/* Highest order double term.  */
1.1  mrg
1.1  mrg   if (unlikely (t == 0)		/* Preserve -0.  */
1.1  mrg       || nonfinite (t))
1.1  mrg     return t;
1.1  mrg
1.1  mrg   /* Sum terms of two highest orders. */
1.1  mrg
1.1  mrg   /* Use fused multiply-add to get low part of a * c.  */
1.1  mrg #ifndef __NO_FPRS__
1.1  mrg   asm ("fmsub %0,%1,%2,%3" : "=f"(tau) : "f"(a), "f"(c), "f"(t));
1.1  mrg #else
1.1  mrg   tau = fmsub (a, c, t);
1.1  mrg #endif
1.1  mrg   v = a*d;
1.1  mrg   w = b*c;
1.1  mrg   tau += v + w;	    /* Add in other second-order terms.	 */
1.1  mrg   u = t + tau;
1.1  mrg
1.1  mrg   /* Construct long double result.  */
1.1  mrg   if (nonfinite (u))
1.1  mrg     return u;
1.1  mrg   z.dval[0] = u;
1.1  mrg   z.dval[1] = (t - u) + tau;
1.1  mrg   return z.ldval;
1.1  mrg }
1.1  mrg
1.1  mrg long double
1.1  mrg __gcc_qdiv (double a, double b, double c, double d)
1.1  mrg {
1.1  mrg   longDblUnion z;
1.1  mrg   double s, sigma, t, tau, u, v, w;
1.1  mrg
1.1  mrg   t = a / c;                    /* highest order double term */
1.1  mrg
1.1  mrg   if (unlikely (t == 0)		/* Preserve -0.  */
1.1  mrg       || nonfinite (t))
1.1  mrg     return t;
1.1  mrg
1.1  mrg   /* Finite nonzero result requires corrections to the highest order
1.1  mrg      term.  These corrections require the low part of c * t to be
1.1  mrg      exactly represented in double.  */
1.1  mrg   if (fabs (a) <= 0x1p-969)
1.1  mrg     {
1.1  mrg       a *= 0x1p106;
1.1  mrg       b *= 0x1p106;
1.1  mrg       c *= 0x1p106;
1.1  mrg       d *= 0x1p106;
1.1  mrg     }
1.1  mrg
1.1  mrg   s = c * t;                    /* (s,sigma) = c*t exactly.  */
1.1  mrg   w = -(-b + d * t);	/* Written to get fnmsub for speed, but not
1.1  mrg 			   numerically necessary.  */
1.1  mrg
1.1  mrg   /* Use fused multiply-add to get low part of c * t.	 */
1.1  mrg #ifndef __NO_FPRS__
1.1  mrg   asm ("fmsub %0,%1,%2,%3" : "=f"(sigma) : "f"(c), "f"(t), "f"(s));
1.1  mrg #else
1.1  mrg   sigma = fmsub (c, t, s);
1.1  mrg #endif
1.1  mrg   v = a - s;
1.1  mrg
1.1  mrg   tau = ((v-sigma)+w)/c;   /* Correction to t.  */
1.1  mrg   u = t + tau;
1.1  mrg
1.1  mrg   /* Construct long double result.  */
1.1  mrg   if (nonfinite (u))
1.1  mrg     return u;
1.1  mrg   z.dval[0] = u;
1.1  mrg   z.dval[1] = (t - u) + tau;
1.1  mrg   return z.ldval;
1.1  mrg }
1.1  mrg
1.1  mrg #if defined (_SOFT_DOUBLE) && defined (__LONG_DOUBLE_128__)
1.1  mrg
1.1  mrg long double __gcc_qneg (double, double);
1.1  mrg int __gcc_qeq (double, double, double, double);
1.1  mrg int __gcc_qne (double, double, double, double);
1.1  mrg int __gcc_qge (double, double, double, double);
1.1  mrg int __gcc_qle (double, double, double, double);
1.1  mrg long double __gcc_stoq (float);
1.1  mrg long double __gcc_dtoq (double);
1.1  mrg float __gcc_qtos (double, double);
1.1  mrg double __gcc_qtod (double, double);
1.1  mrg int __gcc_qtoi (double, double);
1.1  mrg unsigned int __gcc_qtou (double, double);
1.1  mrg long double __gcc_itoq (int);
1.1  mrg long double __gcc_utoq (unsigned int);
1.1  mrg
1.1  mrg extern int __eqdf2 (double, double);
1.1  mrg extern int __ledf2 (double, double);
1.1  mrg extern int __gedf2 (double, double);
1.1  mrg
1.1  mrg /* Negate 'long double' value and return the result.	*/
1.1  mrg long double
1.1  mrg __gcc_qneg (double a, double aa)
1.1  mrg {
1.1  mrg   longDblUnion x;
1.1  mrg
1.1  mrg   x.dval[0] = -a;
1.1  mrg   x.dval[1] = -aa;
1.1  mrg   return x.ldval;
1.1  mrg }
1.1  mrg
1.1  mrg /* Compare two 'long double' values for equality.  */
1.1  mrg int
1.1  mrg __gcc_qeq (double a, double aa, double c, double cc)
1.1  mrg {
1.1  mrg   if (__eqdf2 (a, c) == 0)
1.1  mrg     return __eqdf2 (aa, cc);
1.1  mrg   return 1;
1.1  mrg }
1.1  mrg
1.1  mrg strong_alias (__gcc_qeq, __gcc_qne);
1.1  mrg
1.1  mrg /* Compare two 'long double' values for less than or equal.  */
1.1  mrg int
1.1  mrg __gcc_qle (double a, double aa, double c, double cc)
1.1  mrg {
1.1  mrg   if (__eqdf2 (a, c) == 0)
1.1  mrg     return __ledf2 (aa, cc);
1.1  mrg   return __ledf2 (a, c);
1.1  mrg }
1.1  mrg
1.1  mrg strong_alias (__gcc_qle, __gcc_qlt);
1.1  mrg
1.1  mrg /* Compare two 'long double' values for greater than or equal.  */
1.1  mrg int
1.1  mrg __gcc_qge (double a, double aa, double c, double cc)
1.1  mrg {
1.1  mrg   if (__eqdf2 (a, c) == 0)
1.1  mrg     return __gedf2 (aa, cc);
1.1  mrg   return __gedf2 (a, c);
1.1  mrg }
1.1  mrg
1.1  mrg strong_alias (__gcc_qge, __gcc_qgt);
1.1  mrg
1.1  mrg /* Convert single to long double.  */
1.1  mrg long double
1.1  mrg __gcc_stoq (float a)
1.1  mrg {
1.1  mrg   longDblUnion x;
1.1  mrg
1.1  mrg   x.dval[0] = (double) a;
1.1  mrg   x.dval[1] = 0.0;
1.1  mrg
1.1  mrg   return x.ldval;
1.1  mrg }
1.1  mrg
1.1  mrg /* Convert double to long double.  */
1.1  mrg long double
1.1  mrg __gcc_dtoq (double a)
1.1  mrg {
1.1  mrg   longDblUnion x;
1.1  mrg
1.1  mrg   x.dval[0] = a;
1.1  mrg   x.dval[1] = 0.0;
1.1  mrg
1.1  mrg   return x.ldval;
1.1  mrg }
1.1  mrg
1.1  mrg /* Convert long double to single.  */
1.1  mrg float
1.1  mrg __gcc_qtos (double a, double aa __attribute__ ((__unused__)))
1.1  mrg {
1.1  mrg   return (float) a;
1.1  mrg }
1.1  mrg
1.1  mrg /* Convert long double to double.  */
1.1  mrg double
1.1  mrg __gcc_qtod (double a, double aa __attribute__ ((__unused__)))
1.1  mrg {
1.1  mrg   return a;
1.1  mrg }
1.1  mrg
1.1  mrg /* Convert long double to int.  */
1.1  mrg int
1.1  mrg __gcc_qtoi (double a, double aa)
1.1  mrg {
1.1  mrg   double z = a + aa;
1.1  mrg   return (int) z;
1.1  mrg }
1.1  mrg
1.1  mrg /* Convert long double to unsigned int.  */
1.1  mrg unsigned int
1.1  mrg __gcc_qtou (double a, double aa)
1.1  mrg {
1.1  mrg   double z = a + aa;
1.1  mrg   return (unsigned int) z;
1.1  mrg }
1.1  mrg
1.1  mrg /* Convert int to long double.  */
1.1  mrg long double
1.1  mrg __gcc_itoq (int a)
1.1  mrg {
1.1  mrg   return __gcc_dtoq ((double) a);
1.1  mrg }
1.1  mrg
1.1  mrg /* Convert unsigned int to long double.  */
1.1  mrg long double
1.1  mrg __gcc_utoq (unsigned int a)
1.1  mrg {
1.1  mrg   return __gcc_dtoq ((double) a);
1.1  mrg }
1.1  mrg
1.1  mrg #endif
1.1  mrg
1.1  mrg #ifdef __NO_FPRS__
1.1  mrg
1.1  mrg int __gcc_qunord (double, double, double, double);
1.1  mrg
1.1  mrg extern int __eqdf2 (double, double);
1.1  mrg extern int __unorddf2 (double, double);
1.1  mrg
1.1  mrg /* Compare two 'long double' values for unordered.  */
1.1  mrg int
1.1  mrg __gcc_qunord (double a, double aa, double c, double cc)
1.1  mrg {
1.1  mrg   if (__eqdf2 (a, c) == 0)
1.1  mrg     return __unorddf2 (aa, cc);
1.1  mrg   return __unorddf2 (a, c);
1.1  mrg }
1.1  mrg
1.1  mrg #include "soft-fp/soft-fp.h"
1.1  mrg #include "soft-fp/double.h"
1.1  mrg #include "soft-fp/quad.h"
1.1  mrg
1.1  mrg /* Compute floating point multiply-subtract with higher (quad) precision.  */
1.1  mrg static double
1.1  mrg fmsub (double a, double b, double c)
1.1  mrg {
1.1  mrg     FP_DECL_EX;
1.1  mrg     FP_DECL_D(A);
1.1  mrg     FP_DECL_D(B);
1.1  mrg     FP_DECL_D(C);
1.1  mrg     FP_DECL_Q(X);
1.1  mrg     FP_DECL_Q(Y);
1.1  mrg     FP_DECL_Q(Z);
1.1  mrg     FP_DECL_Q(U);
1.1  mrg     FP_DECL_Q(V);
1.1  mrg     FP_DECL_D(R);
1.1  mrg     double r;
1.1  mrg     long double u, x, y, z;
1.1  mrg
1.1  mrg     FP_INIT_ROUNDMODE;
1.1  mrg     FP_UNPACK_RAW_D (A, a);
1.1  mrg     FP_UNPACK_RAW_D (B, b);
1.1  mrg     FP_UNPACK_RAW_D (C, c);
1.1  mrg
1.1  mrg     /* Extend double to quad.  */
1.1  mrg #if (2 * _FP_W_TYPE_SIZE) < _FP_FRACBITS_Q
1.1  mrg     FP_EXTEND(Q,D,4,2,X,A);
1.1  mrg     FP_EXTEND(Q,D,4,2,Y,B);
1.1  mrg     FP_EXTEND(Q,D,4,2,Z,C);
1.1  mrg #else
1.1  mrg     FP_EXTEND(Q,D,2,1,X,A);
1.1  mrg     FP_EXTEND(Q,D,2,1,Y,B);
1.1  mrg     FP_EXTEND(Q,D,2,1,Z,C);
1.1  mrg #endif
1.1  mrg     FP_PACK_RAW_Q(x,X);
1.1  mrg     FP_PACK_RAW_Q(y,Y);
1.1  mrg     FP_PACK_RAW_Q(z,Z);
1.1  mrg     FP_HANDLE_EXCEPTIONS;
1.1  mrg
1.1  mrg     /* Multiply.  */
1.1  mrg     FP_INIT_ROUNDMODE;
1.1  mrg     FP_UNPACK_Q(X,x);
1.1  mrg     FP_UNPACK_Q(Y,y);
1.1  mrg     FP_MUL_Q(U,X,Y);
1.1  mrg     FP_PACK_Q(u,U);
1.1  mrg     FP_HANDLE_EXCEPTIONS;
1.1  mrg
1.1  mrg     /* Subtract.  */
1.1  mrg     FP_INIT_ROUNDMODE;
1.1  mrg     FP_UNPACK_SEMIRAW_Q(U,u);
1.1  mrg     FP_UNPACK_SEMIRAW_Q(Z,z);
1.1  mrg     FP_SUB_Q(V,U,Z);
1.1  mrg
1.1  mrg     /* Truncate quad to double.  */
1.1  mrg #if (2 * _FP_W_TYPE_SIZE) < _FP_FRACBITS_Q
1.1  mrg     V_f[3] &= 0x0007ffff;
1.1  mrg     FP_TRUNC(D,Q,2,4,R,V);
1.1  mrg #else
1.1  mrg     V_f1 &= 0x0007ffffffffffffL;
1.1  mrg     FP_TRUNC(D,Q,1,2,R,V);
1.1  mrg #endif
1.1  mrg     FP_PACK_SEMIRAW_D(r,R);
1.1  mrg     FP_HANDLE_EXCEPTIONS;
1.1  mrg
1.1  mrg     return r;
1.1  mrg }
1.1  mrg
1.1  mrg #endif
1.1  mrg
1.1  mrg #endif