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https://github.com/AuxXxilium/linux_dsm_epyc7002.git
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7022672e40
Spelling fixes in arch/parisc/. Signed-off-by: Simon Arlott <simon@fire.lp0.eu> Acked-by: Grant Grundler <grundler@parisc-linux.org> Signed-off-by: Kyle McMartin <kyle@parisc-linux.org>
848 lines
36 KiB
C
848 lines
36 KiB
C
/*
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* Linux/PA-RISC Project (http://www.parisc-linux.org/)
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*
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* Floating-point emulation code
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* Copyright (C) 2001 Hewlett-Packard (Paul Bame) <bame@debian.org>
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2, or (at your option)
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* any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, write to the Free Software
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* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
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*/
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#ifdef __NO_PA_HDRS
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PA header file -- do not include this header file for non-PA builds.
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#endif
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/* 32-bit word grabbing functions */
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#define Dbl_firstword(value) Dallp1(value)
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#define Dbl_secondword(value) Dallp2(value)
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#define Dbl_thirdword(value) dummy_location
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#define Dbl_fourthword(value) dummy_location
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#define Dbl_sign(object) Dsign(object)
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#define Dbl_exponent(object) Dexponent(object)
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#define Dbl_signexponent(object) Dsignexponent(object)
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#define Dbl_mantissap1(object) Dmantissap1(object)
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#define Dbl_mantissap2(object) Dmantissap2(object)
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#define Dbl_exponentmantissap1(object) Dexponentmantissap1(object)
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#define Dbl_allp1(object) Dallp1(object)
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#define Dbl_allp2(object) Dallp2(object)
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/* dbl_and_signs ANDs the sign bits of each argument and puts the result
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* into the first argument. dbl_or_signs ors those same sign bits */
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#define Dbl_and_signs( src1dst, src2) \
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Dallp1(src1dst) = (Dallp1(src2)|~((unsigned int)1<<31)) & Dallp1(src1dst)
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#define Dbl_or_signs( src1dst, src2) \
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Dallp1(src1dst) = (Dallp1(src2)&((unsigned int)1<<31)) | Dallp1(src1dst)
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/* The hidden bit is always the low bit of the exponent */
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#define Dbl_clear_exponent_set_hidden(srcdst) Deposit_dexponent(srcdst,1)
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#define Dbl_clear_signexponent_set_hidden(srcdst) \
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Deposit_dsignexponent(srcdst,1)
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#define Dbl_clear_sign(srcdst) Dallp1(srcdst) &= ~((unsigned int)1<<31)
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#define Dbl_clear_signexponent(srcdst) \
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Dallp1(srcdst) &= Dmantissap1((unsigned int)-1)
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/* Exponent field for doubles has already been cleared and may be
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* included in the shift. Here we need to generate two double width
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* variable shifts. The insignificant bits can be ignored.
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* MTSAR f(varamount)
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* VSHD srcdst.high,srcdst.low => srcdst.low
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* VSHD 0,srcdst.high => srcdst.high
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* This is very difficult to model with C expressions since the shift amount
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* could exceed 32. */
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/* varamount must be less than 64 */
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#define Dbl_rightshift(srcdstA, srcdstB, varamount) \
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{if((varamount) >= 32) { \
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Dallp2(srcdstB) = Dallp1(srcdstA) >> (varamount-32); \
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Dallp1(srcdstA)=0; \
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} \
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else if(varamount > 0) { \
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Variable_shift_double(Dallp1(srcdstA), Dallp2(srcdstB), \
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(varamount), Dallp2(srcdstB)); \
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Dallp1(srcdstA) >>= varamount; \
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} }
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/* varamount must be less than 64 */
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#define Dbl_rightshift_exponentmantissa(srcdstA, srcdstB, varamount) \
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{if((varamount) >= 32) { \
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Dallp2(srcdstB) = Dexponentmantissap1(srcdstA) >> (varamount-32); \
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Dallp1(srcdstA) &= ((unsigned int)1<<31); /* clear expmant field */ \
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} \
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else if(varamount > 0) { \
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Variable_shift_double(Dexponentmantissap1(srcdstA), Dallp2(srcdstB), \
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(varamount), Dallp2(srcdstB)); \
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Deposit_dexponentmantissap1(srcdstA, \
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(Dexponentmantissap1(srcdstA)>>varamount)); \
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} }
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/* varamount must be less than 64 */
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#define Dbl_leftshift(srcdstA, srcdstB, varamount) \
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{if((varamount) >= 32) { \
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Dallp1(srcdstA) = Dallp2(srcdstB) << (varamount-32); \
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Dallp2(srcdstB)=0; \
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} \
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else { \
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if ((varamount) > 0) { \
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Dallp1(srcdstA) = (Dallp1(srcdstA) << (varamount)) | \
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(Dallp2(srcdstB) >> (32-(varamount))); \
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Dallp2(srcdstB) <<= varamount; \
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} \
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} }
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#define Dbl_leftshiftby1_withextent(lefta,leftb,right,resulta,resultb) \
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Shiftdouble(Dallp1(lefta), Dallp2(leftb), 31, Dallp1(resulta)); \
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Shiftdouble(Dallp2(leftb), Extall(right), 31, Dallp2(resultb))
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#define Dbl_rightshiftby1_withextent(leftb,right,dst) \
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Extall(dst) = (Dallp2(leftb) << 31) | ((unsigned int)Extall(right) >> 1) | \
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Extlow(right)
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#define Dbl_arithrightshiftby1(srcdstA,srcdstB) \
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Shiftdouble(Dallp1(srcdstA),Dallp2(srcdstB),1,Dallp2(srcdstB));\
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Dallp1(srcdstA) = (int)Dallp1(srcdstA) >> 1
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/* Sign extend the sign bit with an integer destination */
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#define Dbl_signextendedsign(value) Dsignedsign(value)
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#define Dbl_isone_hidden(dbl_value) (Is_dhidden(dbl_value)!=0)
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/* Singles and doubles may include the sign and exponent fields. The
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* hidden bit and the hidden overflow must be included. */
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#define Dbl_increment(dbl_valueA,dbl_valueB) \
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if( (Dallp2(dbl_valueB) += 1) == 0 ) Dallp1(dbl_valueA) += 1
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#define Dbl_increment_mantissa(dbl_valueA,dbl_valueB) \
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if( (Dmantissap2(dbl_valueB) += 1) == 0 ) \
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Deposit_dmantissap1(dbl_valueA,dbl_valueA+1)
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#define Dbl_decrement(dbl_valueA,dbl_valueB) \
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if( Dallp2(dbl_valueB) == 0 ) Dallp1(dbl_valueA) -= 1; \
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Dallp2(dbl_valueB) -= 1
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#define Dbl_isone_sign(dbl_value) (Is_dsign(dbl_value)!=0)
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#define Dbl_isone_hiddenoverflow(dbl_value) (Is_dhiddenoverflow(dbl_value)!=0)
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#define Dbl_isone_lowmantissap1(dbl_valueA) (Is_dlowp1(dbl_valueA)!=0)
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#define Dbl_isone_lowmantissap2(dbl_valueB) (Is_dlowp2(dbl_valueB)!=0)
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#define Dbl_isone_signaling(dbl_value) (Is_dsignaling(dbl_value)!=0)
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#define Dbl_is_signalingnan(dbl_value) (Dsignalingnan(dbl_value)==0xfff)
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#define Dbl_isnotzero(dbl_valueA,dbl_valueB) \
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(Dallp1(dbl_valueA) || Dallp2(dbl_valueB))
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#define Dbl_isnotzero_hiddenhigh7mantissa(dbl_value) \
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(Dhiddenhigh7mantissa(dbl_value)!=0)
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#define Dbl_isnotzero_exponent(dbl_value) (Dexponent(dbl_value)!=0)
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#define Dbl_isnotzero_mantissa(dbl_valueA,dbl_valueB) \
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(Dmantissap1(dbl_valueA) || Dmantissap2(dbl_valueB))
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#define Dbl_isnotzero_mantissap1(dbl_valueA) (Dmantissap1(dbl_valueA)!=0)
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#define Dbl_isnotzero_mantissap2(dbl_valueB) (Dmantissap2(dbl_valueB)!=0)
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#define Dbl_isnotzero_exponentmantissa(dbl_valueA,dbl_valueB) \
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(Dexponentmantissap1(dbl_valueA) || Dmantissap2(dbl_valueB))
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#define Dbl_isnotzero_low4p2(dbl_value) (Dlow4p2(dbl_value)!=0)
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#define Dbl_iszero(dbl_valueA,dbl_valueB) (Dallp1(dbl_valueA)==0 && \
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Dallp2(dbl_valueB)==0)
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#define Dbl_iszero_allp1(dbl_value) (Dallp1(dbl_value)==0)
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#define Dbl_iszero_allp2(dbl_value) (Dallp2(dbl_value)==0)
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#define Dbl_iszero_hidden(dbl_value) (Is_dhidden(dbl_value)==0)
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#define Dbl_iszero_hiddenoverflow(dbl_value) (Is_dhiddenoverflow(dbl_value)==0)
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#define Dbl_iszero_hiddenhigh3mantissa(dbl_value) \
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(Dhiddenhigh3mantissa(dbl_value)==0)
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#define Dbl_iszero_hiddenhigh7mantissa(dbl_value) \
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(Dhiddenhigh7mantissa(dbl_value)==0)
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#define Dbl_iszero_sign(dbl_value) (Is_dsign(dbl_value)==0)
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#define Dbl_iszero_exponent(dbl_value) (Dexponent(dbl_value)==0)
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#define Dbl_iszero_mantissa(dbl_valueA,dbl_valueB) \
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(Dmantissap1(dbl_valueA)==0 && Dmantissap2(dbl_valueB)==0)
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#define Dbl_iszero_exponentmantissa(dbl_valueA,dbl_valueB) \
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(Dexponentmantissap1(dbl_valueA)==0 && Dmantissap2(dbl_valueB)==0)
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#define Dbl_isinfinity_exponent(dbl_value) \
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(Dexponent(dbl_value)==DBL_INFINITY_EXPONENT)
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#define Dbl_isnotinfinity_exponent(dbl_value) \
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(Dexponent(dbl_value)!=DBL_INFINITY_EXPONENT)
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#define Dbl_isinfinity(dbl_valueA,dbl_valueB) \
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(Dexponent(dbl_valueA)==DBL_INFINITY_EXPONENT && \
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Dmantissap1(dbl_valueA)==0 && Dmantissap2(dbl_valueB)==0)
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#define Dbl_isnan(dbl_valueA,dbl_valueB) \
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(Dexponent(dbl_valueA)==DBL_INFINITY_EXPONENT && \
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(Dmantissap1(dbl_valueA)!=0 || Dmantissap2(dbl_valueB)!=0))
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#define Dbl_isnotnan(dbl_valueA,dbl_valueB) \
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(Dexponent(dbl_valueA)!=DBL_INFINITY_EXPONENT || \
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(Dmantissap1(dbl_valueA)==0 && Dmantissap2(dbl_valueB)==0))
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#define Dbl_islessthan(dbl_op1a,dbl_op1b,dbl_op2a,dbl_op2b) \
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(Dallp1(dbl_op1a) < Dallp1(dbl_op2a) || \
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(Dallp1(dbl_op1a) == Dallp1(dbl_op2a) && \
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Dallp2(dbl_op1b) < Dallp2(dbl_op2b)))
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#define Dbl_isgreaterthan(dbl_op1a,dbl_op1b,dbl_op2a,dbl_op2b) \
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(Dallp1(dbl_op1a) > Dallp1(dbl_op2a) || \
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(Dallp1(dbl_op1a) == Dallp1(dbl_op2a) && \
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Dallp2(dbl_op1b) > Dallp2(dbl_op2b)))
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#define Dbl_isnotlessthan(dbl_op1a,dbl_op1b,dbl_op2a,dbl_op2b) \
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(Dallp1(dbl_op1a) > Dallp1(dbl_op2a) || \
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(Dallp1(dbl_op1a) == Dallp1(dbl_op2a) && \
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Dallp2(dbl_op1b) >= Dallp2(dbl_op2b)))
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#define Dbl_isnotgreaterthan(dbl_op1a,dbl_op1b,dbl_op2a,dbl_op2b) \
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(Dallp1(dbl_op1a) < Dallp1(dbl_op2a) || \
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(Dallp1(dbl_op1a) == Dallp1(dbl_op2a) && \
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Dallp2(dbl_op1b) <= Dallp2(dbl_op2b)))
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#define Dbl_isequal(dbl_op1a,dbl_op1b,dbl_op2a,dbl_op2b) \
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((Dallp1(dbl_op1a) == Dallp1(dbl_op2a)) && \
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(Dallp2(dbl_op1b) == Dallp2(dbl_op2b)))
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#define Dbl_leftshiftby8(dbl_valueA,dbl_valueB) \
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Shiftdouble(Dallp1(dbl_valueA),Dallp2(dbl_valueB),24,Dallp1(dbl_valueA)); \
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Dallp2(dbl_valueB) <<= 8
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#define Dbl_leftshiftby7(dbl_valueA,dbl_valueB) \
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Shiftdouble(Dallp1(dbl_valueA),Dallp2(dbl_valueB),25,Dallp1(dbl_valueA)); \
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Dallp2(dbl_valueB) <<= 7
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#define Dbl_leftshiftby4(dbl_valueA,dbl_valueB) \
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Shiftdouble(Dallp1(dbl_valueA),Dallp2(dbl_valueB),28,Dallp1(dbl_valueA)); \
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Dallp2(dbl_valueB) <<= 4
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#define Dbl_leftshiftby3(dbl_valueA,dbl_valueB) \
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Shiftdouble(Dallp1(dbl_valueA),Dallp2(dbl_valueB),29,Dallp1(dbl_valueA)); \
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Dallp2(dbl_valueB) <<= 3
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#define Dbl_leftshiftby2(dbl_valueA,dbl_valueB) \
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Shiftdouble(Dallp1(dbl_valueA),Dallp2(dbl_valueB),30,Dallp1(dbl_valueA)); \
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Dallp2(dbl_valueB) <<= 2
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#define Dbl_leftshiftby1(dbl_valueA,dbl_valueB) \
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Shiftdouble(Dallp1(dbl_valueA),Dallp2(dbl_valueB),31,Dallp1(dbl_valueA)); \
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Dallp2(dbl_valueB) <<= 1
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#define Dbl_rightshiftby8(dbl_valueA,dbl_valueB) \
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Shiftdouble(Dallp1(dbl_valueA),Dallp2(dbl_valueB),8,Dallp2(dbl_valueB)); \
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Dallp1(dbl_valueA) >>= 8
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#define Dbl_rightshiftby4(dbl_valueA,dbl_valueB) \
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Shiftdouble(Dallp1(dbl_valueA),Dallp2(dbl_valueB),4,Dallp2(dbl_valueB)); \
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Dallp1(dbl_valueA) >>= 4
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#define Dbl_rightshiftby2(dbl_valueA,dbl_valueB) \
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Shiftdouble(Dallp1(dbl_valueA),Dallp2(dbl_valueB),2,Dallp2(dbl_valueB)); \
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Dallp1(dbl_valueA) >>= 2
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#define Dbl_rightshiftby1(dbl_valueA,dbl_valueB) \
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Shiftdouble(Dallp1(dbl_valueA),Dallp2(dbl_valueB),1,Dallp2(dbl_valueB)); \
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Dallp1(dbl_valueA) >>= 1
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/* This magnitude comparison uses the signless first words and
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* the regular part2 words. The comparison is graphically:
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*
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* 1st greater? -------------
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* |
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* 1st less?-----------------+---------
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* | |
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* 2nd greater or equal----->| |
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* False True
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*/
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#define Dbl_ismagnitudeless(leftB,rightB,signlessleft,signlessright) \
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((signlessleft <= signlessright) && \
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( (signlessleft < signlessright) || (Dallp2(leftB)<Dallp2(rightB)) ))
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#define Dbl_copytoint_exponentmantissap1(src,dest) \
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dest = Dexponentmantissap1(src)
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/* A quiet NaN has the high mantissa bit clear and at least on other (in this
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* case the adjacent bit) bit set. */
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#define Dbl_set_quiet(dbl_value) Deposit_dhigh2mantissa(dbl_value,1)
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#define Dbl_set_exponent(dbl_value, exp) Deposit_dexponent(dbl_value,exp)
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#define Dbl_set_mantissa(desta,destb,valuea,valueb) \
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Deposit_dmantissap1(desta,valuea); \
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Dmantissap2(destb) = Dmantissap2(valueb)
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#define Dbl_set_mantissap1(desta,valuea) \
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Deposit_dmantissap1(desta,valuea)
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#define Dbl_set_mantissap2(destb,valueb) \
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Dmantissap2(destb) = Dmantissap2(valueb)
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#define Dbl_set_exponentmantissa(desta,destb,valuea,valueb) \
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Deposit_dexponentmantissap1(desta,valuea); \
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Dmantissap2(destb) = Dmantissap2(valueb)
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#define Dbl_set_exponentmantissap1(dest,value) \
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Deposit_dexponentmantissap1(dest,value)
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#define Dbl_copyfromptr(src,desta,destb) \
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Dallp1(desta) = src->wd0; \
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Dallp2(destb) = src->wd1
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#define Dbl_copytoptr(srca,srcb,dest) \
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dest->wd0 = Dallp1(srca); \
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dest->wd1 = Dallp2(srcb)
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/* An infinity is represented with the max exponent and a zero mantissa */
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#define Dbl_setinfinity_exponent(dbl_value) \
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Deposit_dexponent(dbl_value,DBL_INFINITY_EXPONENT)
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#define Dbl_setinfinity_exponentmantissa(dbl_valueA,dbl_valueB) \
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Deposit_dexponentmantissap1(dbl_valueA, \
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(DBL_INFINITY_EXPONENT << (32-(1+DBL_EXP_LENGTH)))); \
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Dmantissap2(dbl_valueB) = 0
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#define Dbl_setinfinitypositive(dbl_valueA,dbl_valueB) \
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Dallp1(dbl_valueA) \
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= (DBL_INFINITY_EXPONENT << (32-(1+DBL_EXP_LENGTH))); \
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Dmantissap2(dbl_valueB) = 0
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#define Dbl_setinfinitynegative(dbl_valueA,dbl_valueB) \
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Dallp1(dbl_valueA) = ((unsigned int)1<<31) | \
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(DBL_INFINITY_EXPONENT << (32-(1+DBL_EXP_LENGTH))); \
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Dmantissap2(dbl_valueB) = 0
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#define Dbl_setinfinity(dbl_valueA,dbl_valueB,sign) \
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Dallp1(dbl_valueA) = ((unsigned int)sign << 31) | \
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(DBL_INFINITY_EXPONENT << (32-(1+DBL_EXP_LENGTH))); \
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Dmantissap2(dbl_valueB) = 0
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#define Dbl_sethigh4bits(dbl_value, extsign) Deposit_dhigh4p1(dbl_value,extsign)
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#define Dbl_set_sign(dbl_value,sign) Deposit_dsign(dbl_value,sign)
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#define Dbl_invert_sign(dbl_value) Deposit_dsign(dbl_value,~Dsign(dbl_value))
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#define Dbl_setone_sign(dbl_value) Deposit_dsign(dbl_value,1)
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#define Dbl_setone_lowmantissap2(dbl_value) Deposit_dlowp2(dbl_value,1)
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#define Dbl_setzero_sign(dbl_value) Dallp1(dbl_value) &= 0x7fffffff
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#define Dbl_setzero_exponent(dbl_value) \
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Dallp1(dbl_value) &= 0x800fffff
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#define Dbl_setzero_mantissa(dbl_valueA,dbl_valueB) \
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Dallp1(dbl_valueA) &= 0xfff00000; \
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Dallp2(dbl_valueB) = 0
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#define Dbl_setzero_mantissap1(dbl_value) Dallp1(dbl_value) &= 0xfff00000
|
|
#define Dbl_setzero_mantissap2(dbl_value) Dallp2(dbl_value) = 0
|
|
#define Dbl_setzero_exponentmantissa(dbl_valueA,dbl_valueB) \
|
|
Dallp1(dbl_valueA) &= 0x80000000; \
|
|
Dallp2(dbl_valueB) = 0
|
|
#define Dbl_setzero_exponentmantissap1(dbl_valueA) \
|
|
Dallp1(dbl_valueA) &= 0x80000000
|
|
#define Dbl_setzero(dbl_valueA,dbl_valueB) \
|
|
Dallp1(dbl_valueA) = 0; Dallp2(dbl_valueB) = 0
|
|
#define Dbl_setzerop1(dbl_value) Dallp1(dbl_value) = 0
|
|
#define Dbl_setzerop2(dbl_value) Dallp2(dbl_value) = 0
|
|
#define Dbl_setnegativezero(dbl_value) \
|
|
Dallp1(dbl_value) = (unsigned int)1 << 31; Dallp2(dbl_value) = 0
|
|
#define Dbl_setnegativezerop1(dbl_value) Dallp1(dbl_value) = (unsigned int)1<<31
|
|
|
|
/* Use the following macro for both overflow & underflow conditions */
|
|
#define ovfl -
|
|
#define unfl +
|
|
#define Dbl_setwrapped_exponent(dbl_value,exponent,op) \
|
|
Deposit_dexponent(dbl_value,(exponent op DBL_WRAP))
|
|
|
|
#define Dbl_setlargestpositive(dbl_valueA,dbl_valueB) \
|
|
Dallp1(dbl_valueA) = ((DBL_EMAX+DBL_BIAS) << (32-(1+DBL_EXP_LENGTH))) \
|
|
| ((1<<(32-(1+DBL_EXP_LENGTH))) - 1 ); \
|
|
Dallp2(dbl_valueB) = 0xFFFFFFFF
|
|
#define Dbl_setlargestnegative(dbl_valueA,dbl_valueB) \
|
|
Dallp1(dbl_valueA) = ((DBL_EMAX+DBL_BIAS) << (32-(1+DBL_EXP_LENGTH))) \
|
|
| ((1<<(32-(1+DBL_EXP_LENGTH))) - 1 ) \
|
|
| ((unsigned int)1<<31); \
|
|
Dallp2(dbl_valueB) = 0xFFFFFFFF
|
|
#define Dbl_setlargest_exponentmantissa(dbl_valueA,dbl_valueB) \
|
|
Deposit_dexponentmantissap1(dbl_valueA, \
|
|
(((DBL_EMAX+DBL_BIAS) << (32-(1+DBL_EXP_LENGTH))) \
|
|
| ((1<<(32-(1+DBL_EXP_LENGTH))) - 1 ))); \
|
|
Dallp2(dbl_valueB) = 0xFFFFFFFF
|
|
|
|
#define Dbl_setnegativeinfinity(dbl_valueA,dbl_valueB) \
|
|
Dallp1(dbl_valueA) = ((1<<DBL_EXP_LENGTH) | DBL_INFINITY_EXPONENT) \
|
|
<< (32-(1+DBL_EXP_LENGTH)) ; \
|
|
Dallp2(dbl_valueB) = 0
|
|
#define Dbl_setlargest(dbl_valueA,dbl_valueB,sign) \
|
|
Dallp1(dbl_valueA) = ((unsigned int)sign << 31) | \
|
|
((DBL_EMAX+DBL_BIAS) << (32-(1+DBL_EXP_LENGTH))) | \
|
|
((1 << (32-(1+DBL_EXP_LENGTH))) - 1 ); \
|
|
Dallp2(dbl_valueB) = 0xFFFFFFFF
|
|
|
|
|
|
/* The high bit is always zero so arithmetic or logical shifts will work. */
|
|
#define Dbl_right_align(srcdstA,srcdstB,shift,extent) \
|
|
if( shift >= 32 ) \
|
|
{ \
|
|
/* Big shift requires examining the portion shift off \
|
|
the end to properly set inexact. */ \
|
|
if(shift < 64) \
|
|
{ \
|
|
if(shift > 32) \
|
|
{ \
|
|
Variable_shift_double(Dallp1(srcdstA),Dallp2(srcdstB), \
|
|
shift-32, Extall(extent)); \
|
|
if(Dallp2(srcdstB) << 64 - (shift)) Ext_setone_low(extent); \
|
|
} \
|
|
else Extall(extent) = Dallp2(srcdstB); \
|
|
Dallp2(srcdstB) = Dallp1(srcdstA) >> (shift - 32); \
|
|
} \
|
|
else \
|
|
{ \
|
|
Extall(extent) = Dallp1(srcdstA); \
|
|
if(Dallp2(srcdstB)) Ext_setone_low(extent); \
|
|
Dallp2(srcdstB) = 0; \
|
|
} \
|
|
Dallp1(srcdstA) = 0; \
|
|
} \
|
|
else \
|
|
{ \
|
|
/* Small alignment is simpler. Extension is easily set. */ \
|
|
if (shift > 0) \
|
|
{ \
|
|
Extall(extent) = Dallp2(srcdstB) << 32 - (shift); \
|
|
Variable_shift_double(Dallp1(srcdstA),Dallp2(srcdstB),shift, \
|
|
Dallp2(srcdstB)); \
|
|
Dallp1(srcdstA) >>= shift; \
|
|
} \
|
|
else Extall(extent) = 0; \
|
|
}
|
|
|
|
/*
|
|
* Here we need to shift the result right to correct for an overshift
|
|
* (due to the exponent becoming negative) during normalization.
|
|
*/
|
|
#define Dbl_fix_overshift(srcdstA,srcdstB,shift,extent) \
|
|
Extall(extent) = Dallp2(srcdstB) << 32 - (shift); \
|
|
Dallp2(srcdstB) = (Dallp1(srcdstA) << 32 - (shift)) | \
|
|
(Dallp2(srcdstB) >> (shift)); \
|
|
Dallp1(srcdstA) = Dallp1(srcdstA) >> shift
|
|
|
|
#define Dbl_hiddenhigh3mantissa(dbl_value) Dhiddenhigh3mantissa(dbl_value)
|
|
#define Dbl_hidden(dbl_value) Dhidden(dbl_value)
|
|
#define Dbl_lowmantissap2(dbl_value) Dlowp2(dbl_value)
|
|
|
|
/* The left argument is never smaller than the right argument */
|
|
#define Dbl_subtract(lefta,leftb,righta,rightb,resulta,resultb) \
|
|
if( Dallp2(rightb) > Dallp2(leftb) ) Dallp1(lefta)--; \
|
|
Dallp2(resultb) = Dallp2(leftb) - Dallp2(rightb); \
|
|
Dallp1(resulta) = Dallp1(lefta) - Dallp1(righta)
|
|
|
|
/* Subtract right augmented with extension from left augmented with zeros and
|
|
* store into result and extension. */
|
|
#define Dbl_subtract_withextension(lefta,leftb,righta,rightb,extent,resulta,resultb) \
|
|
Dbl_subtract(lefta,leftb,righta,rightb,resulta,resultb); \
|
|
if( (Extall(extent) = 0-Extall(extent)) ) \
|
|
{ \
|
|
if((Dallp2(resultb)--) == 0) Dallp1(resulta)--; \
|
|
}
|
|
|
|
#define Dbl_addition(lefta,leftb,righta,rightb,resulta,resultb) \
|
|
/* If the sum of the low words is less than either source, then \
|
|
* an overflow into the next word occurred. */ \
|
|
Dallp1(resulta) = Dallp1(lefta) + Dallp1(righta); \
|
|
if((Dallp2(resultb) = Dallp2(leftb) + Dallp2(rightb)) < Dallp2(rightb)) \
|
|
Dallp1(resulta)++
|
|
|
|
#define Dbl_xortointp1(left,right,result) \
|
|
result = Dallp1(left) XOR Dallp1(right)
|
|
|
|
#define Dbl_xorfromintp1(left,right,result) \
|
|
Dallp1(result) = left XOR Dallp1(right)
|
|
|
|
#define Dbl_swap_lower(left,right) \
|
|
Dallp2(left) = Dallp2(left) XOR Dallp2(right); \
|
|
Dallp2(right) = Dallp2(left) XOR Dallp2(right); \
|
|
Dallp2(left) = Dallp2(left) XOR Dallp2(right)
|
|
|
|
/* Need to Initialize */
|
|
#define Dbl_makequietnan(desta,destb) \
|
|
Dallp1(desta) = ((DBL_EMAX+DBL_BIAS)+1)<< (32-(1+DBL_EXP_LENGTH)) \
|
|
| (1<<(32-(1+DBL_EXP_LENGTH+2))); \
|
|
Dallp2(destb) = 0
|
|
#define Dbl_makesignalingnan(desta,destb) \
|
|
Dallp1(desta) = ((DBL_EMAX+DBL_BIAS)+1)<< (32-(1+DBL_EXP_LENGTH)) \
|
|
| (1<<(32-(1+DBL_EXP_LENGTH+1))); \
|
|
Dallp2(destb) = 0
|
|
|
|
#define Dbl_normalize(dbl_opndA,dbl_opndB,exponent) \
|
|
while(Dbl_iszero_hiddenhigh7mantissa(dbl_opndA)) { \
|
|
Dbl_leftshiftby8(dbl_opndA,dbl_opndB); \
|
|
exponent -= 8; \
|
|
} \
|
|
if(Dbl_iszero_hiddenhigh3mantissa(dbl_opndA)) { \
|
|
Dbl_leftshiftby4(dbl_opndA,dbl_opndB); \
|
|
exponent -= 4; \
|
|
} \
|
|
while(Dbl_iszero_hidden(dbl_opndA)) { \
|
|
Dbl_leftshiftby1(dbl_opndA,dbl_opndB); \
|
|
exponent -= 1; \
|
|
}
|
|
|
|
#define Twoword_add(src1dstA,src1dstB,src2A,src2B) \
|
|
/* \
|
|
* want this macro to generate: \
|
|
* ADD src1dstB,src2B,src1dstB; \
|
|
* ADDC src1dstA,src2A,src1dstA; \
|
|
*/ \
|
|
if ((src1dstB) + (src2B) < (src1dstB)) Dallp1(src1dstA)++; \
|
|
Dallp1(src1dstA) += (src2A); \
|
|
Dallp2(src1dstB) += (src2B)
|
|
|
|
#define Twoword_subtract(src1dstA,src1dstB,src2A,src2B) \
|
|
/* \
|
|
* want this macro to generate: \
|
|
* SUB src1dstB,src2B,src1dstB; \
|
|
* SUBB src1dstA,src2A,src1dstA; \
|
|
*/ \
|
|
if ((src1dstB) < (src2B)) Dallp1(src1dstA)--; \
|
|
Dallp1(src1dstA) -= (src2A); \
|
|
Dallp2(src1dstB) -= (src2B)
|
|
|
|
#define Dbl_setoverflow(resultA,resultB) \
|
|
/* set result to infinity or largest number */ \
|
|
switch (Rounding_mode()) { \
|
|
case ROUNDPLUS: \
|
|
if (Dbl_isone_sign(resultA)) { \
|
|
Dbl_setlargestnegative(resultA,resultB); \
|
|
} \
|
|
else { \
|
|
Dbl_setinfinitypositive(resultA,resultB); \
|
|
} \
|
|
break; \
|
|
case ROUNDMINUS: \
|
|
if (Dbl_iszero_sign(resultA)) { \
|
|
Dbl_setlargestpositive(resultA,resultB); \
|
|
} \
|
|
else { \
|
|
Dbl_setinfinitynegative(resultA,resultB); \
|
|
} \
|
|
break; \
|
|
case ROUNDNEAREST: \
|
|
Dbl_setinfinity_exponentmantissa(resultA,resultB); \
|
|
break; \
|
|
case ROUNDZERO: \
|
|
Dbl_setlargest_exponentmantissa(resultA,resultB); \
|
|
}
|
|
|
|
#define Dbl_denormalize(opndp1,opndp2,exponent,guard,sticky,inexact) \
|
|
Dbl_clear_signexponent_set_hidden(opndp1); \
|
|
if (exponent >= (1-DBL_P)) { \
|
|
if (exponent >= -31) { \
|
|
guard = (Dallp2(opndp2) >> -exponent) & 1; \
|
|
if (exponent < 0) sticky |= Dallp2(opndp2) << (32+exponent); \
|
|
if (exponent > -31) { \
|
|
Variable_shift_double(opndp1,opndp2,1-exponent,opndp2); \
|
|
Dallp1(opndp1) >>= 1-exponent; \
|
|
} \
|
|
else { \
|
|
Dallp2(opndp2) = Dallp1(opndp1); \
|
|
Dbl_setzerop1(opndp1); \
|
|
} \
|
|
} \
|
|
else { \
|
|
guard = (Dallp1(opndp1) >> -32-exponent) & 1; \
|
|
if (exponent == -32) sticky |= Dallp2(opndp2); \
|
|
else sticky |= (Dallp2(opndp2) | Dallp1(opndp1) << 64+exponent); \
|
|
Dallp2(opndp2) = Dallp1(opndp1) >> -31-exponent; \
|
|
Dbl_setzerop1(opndp1); \
|
|
} \
|
|
inexact = guard | sticky; \
|
|
} \
|
|
else { \
|
|
guard = 0; \
|
|
sticky |= (Dallp1(opndp1) | Dallp2(opndp2)); \
|
|
Dbl_setzero(opndp1,opndp2); \
|
|
inexact = sticky; \
|
|
}
|
|
|
|
/*
|
|
* The fused multiply add instructions requires a double extended format,
|
|
* with 106 bits of mantissa.
|
|
*/
|
|
#define DBLEXT_THRESHOLD 106
|
|
|
|
#define Dblext_setzero(valA,valB,valC,valD) \
|
|
Dextallp1(valA) = 0; Dextallp2(valB) = 0; \
|
|
Dextallp3(valC) = 0; Dextallp4(valD) = 0
|
|
|
|
|
|
#define Dblext_isnotzero_mantissap3(valC) (Dextallp3(valC)!=0)
|
|
#define Dblext_isnotzero_mantissap4(valD) (Dextallp3(valD)!=0)
|
|
#define Dblext_isone_lowp2(val) (Dextlowp2(val)!=0)
|
|
#define Dblext_isone_highp3(val) (Dexthighp3(val)!=0)
|
|
#define Dblext_isnotzero_low31p3(val) (Dextlow31p3(val)!=0)
|
|
#define Dblext_iszero(valA,valB,valC,valD) (Dextallp1(valA)==0 && \
|
|
Dextallp2(valB)==0 && Dextallp3(valC)==0 && Dextallp4(valD)==0)
|
|
|
|
#define Dblext_copy(srca,srcb,srcc,srcd,desta,destb,destc,destd) \
|
|
Dextallp1(desta) = Dextallp4(srca); \
|
|
Dextallp2(destb) = Dextallp4(srcb); \
|
|
Dextallp3(destc) = Dextallp4(srcc); \
|
|
Dextallp4(destd) = Dextallp4(srcd)
|
|
|
|
#define Dblext_swap_lower(leftp2,leftp3,leftp4,rightp2,rightp3,rightp4) \
|
|
Dextallp2(leftp2) = Dextallp2(leftp2) XOR Dextallp2(rightp2); \
|
|
Dextallp2(rightp2) = Dextallp2(leftp2) XOR Dextallp2(rightp2); \
|
|
Dextallp2(leftp2) = Dextallp2(leftp2) XOR Dextallp2(rightp2); \
|
|
Dextallp3(leftp3) = Dextallp3(leftp3) XOR Dextallp3(rightp3); \
|
|
Dextallp3(rightp3) = Dextallp3(leftp3) XOR Dextallp3(rightp3); \
|
|
Dextallp3(leftp3) = Dextallp3(leftp3) XOR Dextallp3(rightp3); \
|
|
Dextallp4(leftp4) = Dextallp4(leftp4) XOR Dextallp4(rightp4); \
|
|
Dextallp4(rightp4) = Dextallp4(leftp4) XOR Dextallp4(rightp4); \
|
|
Dextallp4(leftp4) = Dextallp4(leftp4) XOR Dextallp4(rightp4)
|
|
|
|
#define Dblext_setone_lowmantissap4(dbl_value) Deposit_dextlowp4(dbl_value,1)
|
|
|
|
/* The high bit is always zero so arithmetic or logical shifts will work. */
|
|
#define Dblext_right_align(srcdstA,srcdstB,srcdstC,srcdstD,shift) \
|
|
{int shiftamt, sticky; \
|
|
shiftamt = shift % 32; \
|
|
sticky = 0; \
|
|
switch (shift/32) { \
|
|
case 0: if (shiftamt > 0) { \
|
|
sticky = Dextallp4(srcdstD) << 32 - (shiftamt); \
|
|
Variable_shift_double(Dextallp3(srcdstC), \
|
|
Dextallp4(srcdstD),shiftamt,Dextallp4(srcdstD)); \
|
|
Variable_shift_double(Dextallp2(srcdstB), \
|
|
Dextallp3(srcdstC),shiftamt,Dextallp3(srcdstC)); \
|
|
Variable_shift_double(Dextallp1(srcdstA), \
|
|
Dextallp2(srcdstB),shiftamt,Dextallp2(srcdstB)); \
|
|
Dextallp1(srcdstA) >>= shiftamt; \
|
|
} \
|
|
break; \
|
|
case 1: if (shiftamt > 0) { \
|
|
sticky = (Dextallp3(srcdstC) << 31 - shiftamt) | \
|
|
Dextallp4(srcdstD); \
|
|
Variable_shift_double(Dextallp2(srcdstB), \
|
|
Dextallp3(srcdstC),shiftamt,Dextallp4(srcdstD)); \
|
|
Variable_shift_double(Dextallp1(srcdstA), \
|
|
Dextallp2(srcdstB),shiftamt,Dextallp3(srcdstC)); \
|
|
} \
|
|
else { \
|
|
sticky = Dextallp4(srcdstD); \
|
|
Dextallp4(srcdstD) = Dextallp3(srcdstC); \
|
|
Dextallp3(srcdstC) = Dextallp2(srcdstB); \
|
|
} \
|
|
Dextallp2(srcdstB) = Dextallp1(srcdstA) >> shiftamt; \
|
|
Dextallp1(srcdstA) = 0; \
|
|
break; \
|
|
case 2: if (shiftamt > 0) { \
|
|
sticky = (Dextallp2(srcdstB) << 31 - shiftamt) | \
|
|
Dextallp3(srcdstC) | Dextallp4(srcdstD); \
|
|
Variable_shift_double(Dextallp1(srcdstA), \
|
|
Dextallp2(srcdstB),shiftamt,Dextallp4(srcdstD)); \
|
|
} \
|
|
else { \
|
|
sticky = Dextallp3(srcdstC) | Dextallp4(srcdstD); \
|
|
Dextallp4(srcdstD) = Dextallp2(srcdstB); \
|
|
} \
|
|
Dextallp3(srcdstC) = Dextallp1(srcdstA) >> shiftamt; \
|
|
Dextallp1(srcdstA) = Dextallp2(srcdstB) = 0; \
|
|
break; \
|
|
case 3: if (shiftamt > 0) { \
|
|
sticky = (Dextallp1(srcdstA) << 31 - shiftamt) | \
|
|
Dextallp2(srcdstB) | Dextallp3(srcdstC) | \
|
|
Dextallp4(srcdstD); \
|
|
} \
|
|
else { \
|
|
sticky = Dextallp2(srcdstB) | Dextallp3(srcdstC) | \
|
|
Dextallp4(srcdstD); \
|
|
} \
|
|
Dextallp4(srcdstD) = Dextallp1(srcdstA) >> shiftamt; \
|
|
Dextallp1(srcdstA) = Dextallp2(srcdstB) = 0; \
|
|
Dextallp3(srcdstC) = 0; \
|
|
break; \
|
|
} \
|
|
if (sticky) Dblext_setone_lowmantissap4(srcdstD); \
|
|
}
|
|
|
|
/* The left argument is never smaller than the right argument */
|
|
#define Dblext_subtract(lefta,leftb,leftc,leftd,righta,rightb,rightc,rightd,resulta,resultb,resultc,resultd) \
|
|
if( Dextallp4(rightd) > Dextallp4(leftd) ) \
|
|
if( (Dextallp3(leftc)--) == 0) \
|
|
if( (Dextallp2(leftb)--) == 0) Dextallp1(lefta)--; \
|
|
Dextallp4(resultd) = Dextallp4(leftd) - Dextallp4(rightd); \
|
|
if( Dextallp3(rightc) > Dextallp3(leftc) ) \
|
|
if( (Dextallp2(leftb)--) == 0) Dextallp1(lefta)--; \
|
|
Dextallp3(resultc) = Dextallp3(leftc) - Dextallp3(rightc); \
|
|
if( Dextallp2(rightb) > Dextallp2(leftb) ) Dextallp1(lefta)--; \
|
|
Dextallp2(resultb) = Dextallp2(leftb) - Dextallp2(rightb); \
|
|
Dextallp1(resulta) = Dextallp1(lefta) - Dextallp1(righta)
|
|
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#define Dblext_addition(lefta,leftb,leftc,leftd,righta,rightb,rightc,rightd,resulta,resultb,resultc,resultd) \
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/* If the sum of the low words is less than either source, then \
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* an overflow into the next word occurred. */ \
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if ((Dextallp4(resultd) = Dextallp4(leftd)+Dextallp4(rightd)) < \
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Dextallp4(rightd)) \
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if((Dextallp3(resultc) = Dextallp3(leftc)+Dextallp3(rightc)+1) <= \
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Dextallp3(rightc)) \
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if((Dextallp2(resultb) = Dextallp2(leftb)+Dextallp2(rightb)+1) \
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<= Dextallp2(rightb)) \
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Dextallp1(resulta) = Dextallp1(lefta)+Dextallp1(righta)+1; \
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else Dextallp1(resulta) = Dextallp1(lefta)+Dextallp1(righta); \
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else \
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if ((Dextallp2(resultb) = Dextallp2(leftb)+Dextallp2(rightb)) < \
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Dextallp2(rightb)) \
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Dextallp1(resulta) = Dextallp1(lefta)+Dextallp1(righta)+1; \
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else Dextallp1(resulta) = Dextallp1(lefta)+Dextallp1(righta); \
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else \
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if ((Dextallp3(resultc) = Dextallp3(leftc)+Dextallp3(rightc)) < \
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Dextallp3(rightc)) \
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if ((Dextallp2(resultb) = Dextallp2(leftb)+Dextallp2(rightb)+1) \
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<= Dextallp2(rightb)) \
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Dextallp1(resulta) = Dextallp1(lefta)+Dextallp1(righta)+1; \
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else Dextallp1(resulta) = Dextallp1(lefta)+Dextallp1(righta); \
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else \
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if ((Dextallp2(resultb) = Dextallp2(leftb)+Dextallp2(rightb)) < \
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Dextallp2(rightb)) \
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Dextallp1(resulta) = Dextallp1(lefta)+Dextallp1(righta)+1; \
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else Dextallp1(resulta) = Dextallp1(lefta)+Dextallp1(righta)
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#define Dblext_arithrightshiftby1(srcdstA,srcdstB,srcdstC,srcdstD) \
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Shiftdouble(Dextallp3(srcdstC),Dextallp4(srcdstD),1,Dextallp4(srcdstD)); \
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Shiftdouble(Dextallp2(srcdstB),Dextallp3(srcdstC),1,Dextallp3(srcdstC)); \
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Shiftdouble(Dextallp1(srcdstA),Dextallp2(srcdstB),1,Dextallp2(srcdstB)); \
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Dextallp1(srcdstA) = (int)Dextallp1(srcdstA) >> 1
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#define Dblext_leftshiftby8(valA,valB,valC,valD) \
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Shiftdouble(Dextallp1(valA),Dextallp2(valB),24,Dextallp1(valA)); \
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Shiftdouble(Dextallp2(valB),Dextallp3(valC),24,Dextallp2(valB)); \
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Shiftdouble(Dextallp3(valC),Dextallp4(valD),24,Dextallp3(valC)); \
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Dextallp4(valD) <<= 8
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#define Dblext_leftshiftby4(valA,valB,valC,valD) \
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Shiftdouble(Dextallp1(valA),Dextallp2(valB),28,Dextallp1(valA)); \
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Shiftdouble(Dextallp2(valB),Dextallp3(valC),28,Dextallp2(valB)); \
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Shiftdouble(Dextallp3(valC),Dextallp4(valD),28,Dextallp3(valC)); \
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Dextallp4(valD) <<= 4
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#define Dblext_leftshiftby3(valA,valB,valC,valD) \
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Shiftdouble(Dextallp1(valA),Dextallp2(valB),29,Dextallp1(valA)); \
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Shiftdouble(Dextallp2(valB),Dextallp3(valC),29,Dextallp2(valB)); \
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Shiftdouble(Dextallp3(valC),Dextallp4(valD),29,Dextallp3(valC)); \
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Dextallp4(valD) <<= 3
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#define Dblext_leftshiftby2(valA,valB,valC,valD) \
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Shiftdouble(Dextallp1(valA),Dextallp2(valB),30,Dextallp1(valA)); \
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Shiftdouble(Dextallp2(valB),Dextallp3(valC),30,Dextallp2(valB)); \
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Shiftdouble(Dextallp3(valC),Dextallp4(valD),30,Dextallp3(valC)); \
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Dextallp4(valD) <<= 2
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#define Dblext_leftshiftby1(valA,valB,valC,valD) \
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Shiftdouble(Dextallp1(valA),Dextallp2(valB),31,Dextallp1(valA)); \
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Shiftdouble(Dextallp2(valB),Dextallp3(valC),31,Dextallp2(valB)); \
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Shiftdouble(Dextallp3(valC),Dextallp4(valD),31,Dextallp3(valC)); \
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Dextallp4(valD) <<= 1
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#define Dblext_rightshiftby4(valueA,valueB,valueC,valueD) \
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Shiftdouble(Dextallp3(valueC),Dextallp4(valueD),4,Dextallp4(valueD)); \
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Shiftdouble(Dextallp2(valueB),Dextallp3(valueC),4,Dextallp3(valueC)); \
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Shiftdouble(Dextallp1(valueA),Dextallp2(valueB),4,Dextallp2(valueB)); \
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Dextallp1(valueA) >>= 4
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#define Dblext_rightshiftby1(valueA,valueB,valueC,valueD) \
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Shiftdouble(Dextallp3(valueC),Dextallp4(valueD),1,Dextallp4(valueD)); \
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Shiftdouble(Dextallp2(valueB),Dextallp3(valueC),1,Dextallp3(valueC)); \
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Shiftdouble(Dextallp1(valueA),Dextallp2(valueB),1,Dextallp2(valueB)); \
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Dextallp1(valueA) >>= 1
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#define Dblext_xortointp1(left,right,result) Dbl_xortointp1(left,right,result)
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#define Dblext_xorfromintp1(left,right,result) \
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Dbl_xorfromintp1(left,right,result)
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#define Dblext_copytoint_exponentmantissap1(src,dest) \
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Dbl_copytoint_exponentmantissap1(src,dest)
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#define Dblext_ismagnitudeless(leftB,rightB,signlessleft,signlessright) \
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Dbl_ismagnitudeless(leftB,rightB,signlessleft,signlessright)
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#define Dbl_copyto_dblext(src1,src2,dest1,dest2,dest3,dest4) \
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Dextallp1(dest1) = Dallp1(src1); Dextallp2(dest2) = Dallp2(src2); \
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Dextallp3(dest3) = 0; Dextallp4(dest4) = 0
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#define Dblext_set_sign(dbl_value,sign) Dbl_set_sign(dbl_value,sign)
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#define Dblext_clear_signexponent_set_hidden(srcdst) \
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Dbl_clear_signexponent_set_hidden(srcdst)
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#define Dblext_clear_signexponent(srcdst) Dbl_clear_signexponent(srcdst)
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#define Dblext_clear_sign(srcdst) Dbl_clear_sign(srcdst)
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#define Dblext_isone_hidden(dbl_value) Dbl_isone_hidden(dbl_value)
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/*
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* The Fourword_add() macro assumes that integers are 4 bytes in size.
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* It will break if this is not the case.
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*/
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#define Fourword_add(src1dstA,src1dstB,src1dstC,src1dstD,src2A,src2B,src2C,src2D) \
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/* \
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* want this macro to generate: \
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* ADD src1dstD,src2D,src1dstD; \
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* ADDC src1dstC,src2C,src1dstC; \
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* ADDC src1dstB,src2B,src1dstB; \
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* ADDC src1dstA,src2A,src1dstA; \
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*/ \
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if ((unsigned int)(src1dstD += (src2D)) < (unsigned int)(src2D)) { \
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if ((unsigned int)(src1dstC += (src2C) + 1) <= \
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(unsigned int)(src2C)) { \
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if ((unsigned int)(src1dstB += (src2B) + 1) <= \
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(unsigned int)(src2B)) src1dstA++; \
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} \
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else if ((unsigned int)(src1dstB += (src2B)) < \
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(unsigned int)(src2B)) src1dstA++; \
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} \
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else { \
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if ((unsigned int)(src1dstC += (src2C)) < \
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(unsigned int)(src2C)) { \
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if ((unsigned int)(src1dstB += (src2B) + 1) <= \
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(unsigned int)(src2B)) src1dstA++; \
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} \
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else if ((unsigned int)(src1dstB += (src2B)) < \
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(unsigned int)(src2B)) src1dstA++; \
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} \
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src1dstA += (src2A)
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#define Dblext_denormalize(opndp1,opndp2,opndp3,opndp4,exponent,is_tiny) \
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{int shiftamt, sticky; \
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is_tiny = TRUE; \
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if (exponent == 0 && (Dextallp3(opndp3) || Dextallp4(opndp4))) { \
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switch (Rounding_mode()) { \
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case ROUNDPLUS: \
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if (Dbl_iszero_sign(opndp1)) { \
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Dbl_increment(opndp1,opndp2); \
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if (Dbl_isone_hiddenoverflow(opndp1)) \
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is_tiny = FALSE; \
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Dbl_decrement(opndp1,opndp2); \
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} \
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break; \
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case ROUNDMINUS: \
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if (Dbl_isone_sign(opndp1)) { \
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Dbl_increment(opndp1,opndp2); \
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if (Dbl_isone_hiddenoverflow(opndp1)) \
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is_tiny = FALSE; \
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Dbl_decrement(opndp1,opndp2); \
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} \
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break; \
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case ROUNDNEAREST: \
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if (Dblext_isone_highp3(opndp3) && \
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(Dblext_isone_lowp2(opndp2) || \
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Dblext_isnotzero_low31p3(opndp3))) { \
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Dbl_increment(opndp1,opndp2); \
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if (Dbl_isone_hiddenoverflow(opndp1)) \
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is_tiny = FALSE; \
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Dbl_decrement(opndp1,opndp2); \
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} \
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break; \
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} \
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} \
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Dblext_clear_signexponent_set_hidden(opndp1); \
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if (exponent >= (1-QUAD_P)) { \
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shiftamt = (1-exponent) % 32; \
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switch((1-exponent)/32) { \
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case 0: sticky = Dextallp4(opndp4) << 32-(shiftamt); \
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Variableshiftdouble(opndp3,opndp4,shiftamt,opndp4); \
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Variableshiftdouble(opndp2,opndp3,shiftamt,opndp3); \
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Variableshiftdouble(opndp1,opndp2,shiftamt,opndp2); \
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Dextallp1(opndp1) >>= shiftamt; \
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break; \
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case 1: sticky = (Dextallp3(opndp3) << 32-(shiftamt)) | \
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Dextallp4(opndp4); \
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Variableshiftdouble(opndp2,opndp3,shiftamt,opndp4); \
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Variableshiftdouble(opndp1,opndp2,shiftamt,opndp3); \
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Dextallp2(opndp2) = Dextallp1(opndp1) >> shiftamt; \
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Dextallp1(opndp1) = 0; \
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break; \
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case 2: sticky = (Dextallp2(opndp2) << 32-(shiftamt)) | \
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Dextallp3(opndp3) | Dextallp4(opndp4); \
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Variableshiftdouble(opndp1,opndp2,shiftamt,opndp4); \
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Dextallp3(opndp3) = Dextallp1(opndp1) >> shiftamt; \
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Dextallp1(opndp1) = Dextallp2(opndp2) = 0; \
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break; \
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case 3: sticky = (Dextallp1(opndp1) << 32-(shiftamt)) | \
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Dextallp2(opndp2) | Dextallp3(opndp3) | \
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Dextallp4(opndp4); \
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Dextallp4(opndp4) = Dextallp1(opndp1) >> shiftamt; \
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Dextallp1(opndp1) = Dextallp2(opndp2) = 0; \
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Dextallp3(opndp3) = 0; \
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break; \
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} \
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} \
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else { \
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sticky = Dextallp1(opndp1) | Dextallp2(opndp2) | \
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Dextallp3(opndp3) | Dextallp4(opndp4); \
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Dblext_setzero(opndp1,opndp2,opndp3,opndp4); \
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} \
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if (sticky) Dblext_setone_lowmantissap4(opndp4); \
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exponent = 0; \
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}
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