=================================================================== RCS file: /home/cvs/OpenXM_contrib2/asir2000/builtin/math.c,v retrieving revision 1.2 retrieving revision 1.13 diff -u -p -r1.2 -r1.13 --- OpenXM_contrib2/asir2000/builtin/math.c 2000/08/21 08:31:20 1.2 +++ OpenXM_contrib2/asir2000/builtin/math.c 2018/03/29 01:32:50 1.13 @@ -23,7 +23,7 @@ * shall be made on your publication or presentation in any form of the * results obtained by use of the SOFTWARE. * (4) In the event that you modify the SOFTWARE, you shall notify FLL by - * e-mail at risa-admin@flab.fujitsu.co.jp of the detailed specification + * e-mail at risa-admin@sec.flab.fujitsu.co.jp of the detailed specification * for such modification or the source code of the modified part of the * SOFTWARE. * @@ -45,253 +45,347 @@ * DEVELOPER SHALL HAVE NO LIABILITY IN CONNECTION WITH THE USE, * PERFORMANCE OR NON-PERFORMANCE OF THE SOFTWARE. * - * $OpenXM: OpenXM_contrib2/asir2000/builtin/math.c,v 1.1.1.1 1999/12/03 07:39:07 noro Exp $ + * $OpenXM: OpenXM_contrib2/asir2000/builtin/math.c,v 1.12 2015/08/14 13:51:54 fujimoto Exp $ */ #include "ca.h" #include #include "parse.h" +#if defined(VISUAL) || defined(__MINGW32__) +#include +#endif void Pdsqrt(),Pdsin(),Pdcos(),Pdtan(),Pdasin(),Pdacos(),Pdatan(),Pdlog(),Pdexp(); -void Pabs(),Pdfloor(),Pdceil(),Pdrint(); +void Pabs(),Pdfloor(),Pdceil(),Pdrint(),Pdisnan(); struct ftab math_tab[] = { - {"dsqrt",Pdsqrt,1}, - {"dabs",Pabs,1}, - {"dsin",Pdsin,1}, - {"dcos",Pdcos,1}, - {"dtan",Pdtan,1}, - {"dlog",Pdlog,1}, - {"dexp",Pdexp,1}, - {"dasin",Pdasin,1}, - {"dacos",Pdacos,1}, - {"datan",Pdatan,1}, - {"dfloor",Pdfloor,1}, - {"dceil",Pdceil,1}, - {"drint",Pdrint,1}, - {0,0,0}, + {"dsqrt",Pdsqrt,1}, + {"dabs",Pabs,1}, + {"dsin",Pdsin,1}, + {"dcos",Pdcos,1}, + {"dtan",Pdtan,1}, + {"dlog",Pdlog,1}, + {"dexp",Pdexp,1}, + {"dasin",Pdasin,1}, + {"dacos",Pdacos,1}, + {"datan",Pdatan,1}, + {"floor",Pdfloor,1}, + {"dfloor",Pdfloor,1}, + {"ceil",Pdceil,1}, + {"dceil",Pdceil,1}, + {"rint",Pdrint,1}, + {"drint",Pdrint,1}, + {"disnan",Pdisnan,1}, + {0,0,0}, }; +void get_ri(Num z,double *r,double *i) +{ + if ( !z ) { + *r = 0; *i = 0; return; + } + if ( OID(z) != O_N ) + error("get_ri : invalid argument"); + switch ( NID(z) ) { + case N_Q: case N_R: case N_B: + *r = ToReal(z); *i = 0; + break; + case N_C: + *r = ToReal(((C)z)->r); + *i = ToReal(((C)z)->i); + break; + default: + error("get_ri : invalid argument"); + break; + } +} + void Pabs(arg,rp) NODE arg; Real *rp; { - double s; + double s,r,i; - s = fabs(ToReal(ARG0(arg))); - MKReal(s,*rp); + if ( !ARG0(arg) ) { + *rp = 0; return; + } + get_ri((Num)ARG0(arg),&r,&i); + if ( i == 0 ) + s = fabs(r); + else if ( r == 0 ) + s = fabs(i); + else + s = sqrt(r*r+i*i); + MKReal(s,*rp); } void Pdsqrt(arg,rp) NODE arg; -Real *rp; +Num *rp; { - double s; + double s,r,i,a; + C z; + Real real; - s = sqrt(ToReal(ARG0(arg))); - MKReal(s,*rp); + if ( !ARG0(arg) ) { + *rp = 0; return; + } + get_ri((Num)ARG0(arg),&r,&i); + if ( i == 0 ) + if ( r > 0 ) { + s = sqrt(r); + MKReal(s,real); + *rp = (Num)real; + } else { + NEWC(z); + z->r = 0; + s = sqrt(-r); MKReal(s,real); z->i = (Num)real; + *rp = (Num)z; + } + else { + a = sqrt(r*r+i*i); + NEWC(z); + s = sqrt((r+a)/2); MKReal(s,real); z->r = (Num)real; + s = i>0?sqrt((-r+a)/2):-sqrt((-r+a)/2); + MKReal(s,real); z->i = (Num)real; + *rp = (Num)z; + } } void Pdsin(arg,rp) NODE arg; Real *rp; { - double s; + double s; - s = sin(ToReal(ARG0(arg))); - MKReal(s,*rp); + s = sin(ToReal(ARG0(arg))); + MKReal(s,*rp); } void Pdcos(arg,rp) NODE arg; Real *rp; { - double s; + double s; - s = cos(ToReal(ARG0(arg))); - MKReal(s,*rp); + s = cos(ToReal(ARG0(arg))); + MKReal(s,*rp); } void Pdtan(arg,rp) NODE arg; Real *rp; { - double s; + double s; - s = tan(ToReal(ARG0(arg))); - MKReal(s,*rp); + s = tan(ToReal(ARG0(arg))); + MKReal(s,*rp); } void Pdasin(arg,rp) NODE arg; Real *rp; { - double s; + double s; - s = asin(ToReal(ARG0(arg))); - MKReal(s,*rp); + s = asin(ToReal(ARG0(arg))); + MKReal(s,*rp); } void Pdacos(arg,rp) NODE arg; Real *rp; { - double s; + double s; - s = acos(ToReal(ARG0(arg))); - MKReal(s,*rp); + s = acos(ToReal(ARG0(arg))); + MKReal(s,*rp); } void Pdatan(arg,rp) NODE arg; Real *rp; { - double s; + double s; - s = atan(ToReal(ARG0(arg))); - MKReal(s,*rp); + s = atan(ToReal(ARG0(arg))); + MKReal(s,*rp); } void Pdlog(arg,rp) NODE arg; Real *rp; { - double s; + double s; - s = log(ToReal(ARG0(arg))); - MKReal(s,*rp); + s = log(ToReal(ARG0(arg))); + MKReal(s,*rp); } void Pdexp(arg,rp) NODE arg; Real *rp; { - double s; + double s; - s = exp(ToReal(ARG0(arg))); - MKReal(s,*rp); + s = exp(ToReal(ARG0(arg))); + MKReal(s,*rp); } void Pdfloor(arg,rp) NODE arg; Q *rp; { - L a; - unsigned int au,al; - int sgn; - Q q; - double d; + L a; + unsigned int au,al; + int sgn; + Q q; + double d; - if ( !ARG0(arg) ) { - *rp = 0; - return; - } - d = floor(ToReal(ARG0(arg))); - if ( d < -9.223372036854775808e18 || d >= 9.223372036854775808e18 ) - error("dfloor : OverFlow"); - a = (L)d; - if ( a < 0 ) { - sgn = -1; - a = -a; - } else - sgn = 1; -#if defined(i386) || defined(__alpha) || defined(VISUAL) - au = ((unsigned int *)&a)[1]; - al = ((unsigned int *)&a)[0]; + if ( !ARG0(arg) ) { + *rp = 0; + return; + } + d = floor(ToReal(ARG0(arg))); + if ( d < -9.223372036854775808e18 || d >= 9.223372036854775808e18 ) + error("dfloor : OverFlow"); + if ( !d ) { + *rp = 0; + return; + } + a = (L)d; + if ( a < 0 ) { + sgn = -1; + a = -a; + } else + sgn = 1; +#if defined(i386) || defined(__alpha) || defined(VISUAL) || defined(__MINGW32__) || defined(__x86_64) + au = ((unsigned int *)&a)[1]; + al = ((unsigned int *)&a)[0]; #else - al = ((unsigned int *)&a)[1]; - au = ((unsigned int *)&a)[0]; + al = ((unsigned int *)&a)[1]; + au = ((unsigned int *)&a)[0]; #endif - if ( au ) { - NEWQ(q); SGN(q) = sgn; NM(q)=NALLOC(2); DN(q)=0; - PL(NM(q))=2; BD(NM(q))[0]=al; BD(NM(q))[1] = au; - } else { - UTOQ(al,q); SGN(q) = sgn; - } - *rp = q; + if ( au ) { + NEWQ(q); SGN(q) = sgn; NM(q)=NALLOC(2); DN(q)=0; + PL(NM(q))=2; BD(NM(q))[0]=al; BD(NM(q))[1] = au; + } else { + UTOQ(al,q); SGN(q) = sgn; + } + *rp = q; } void Pdceil(arg,rp) NODE arg; Q *rp; { - L a; - unsigned int au,al; - int sgn; - Q q; - double d; + L a; + unsigned int au,al; + int sgn; + Q q; + double d; - if ( !ARG0(arg) ) { - *rp = 0; - return; - } - d = ceil(ToReal(ARG0(arg))); - if ( d < -9.223372036854775808e18 || d >= 9.223372036854775808e18 ) - error("dceil : OverFlow"); - a = (L)d; - if ( a < 0 ) { - sgn = -1; - a = -a; - } else - sgn = 1; -#if defined(i386) || defined(__alpha) || defined(VISUAL) - au = ((unsigned int *)&a)[1]; - al = ((unsigned int *)&a)[0]; + if ( !ARG0(arg) ) { + *rp = 0; + return; + } + d = ceil(ToReal(ARG0(arg))); + if ( d < -9.223372036854775808e18 || d >= 9.223372036854775808e18 ) + error("dceil : OverFlow"); + if ( !d ) { + *rp = 0; + return; + } + a = (L)d; + if ( a < 0 ) { + sgn = -1; + a = -a; + } else + sgn = 1; +#if defined(i386) || defined(__alpha) || defined(VISUAL) || defined(__MINGW32__) || defined(__x86_64) + au = ((unsigned int *)&a)[1]; + al = ((unsigned int *)&a)[0]; #else - al = ((unsigned int *)&a)[1]; - au = ((unsigned int *)&a)[0]; + al = ((unsigned int *)&a)[1]; + au = ((unsigned int *)&a)[0]; #endif - if ( au ) { - NEWQ(q); SGN(q) = sgn; NM(q)=NALLOC(2); DN(q)=0; - PL(NM(q))=2; BD(NM(q))[0]=al; BD(NM(q))[1] = au; - } else { - UTOQ(al,q); SGN(q) = sgn; - } - *rp = q; + if ( au ) { + NEWQ(q); SGN(q) = sgn; NM(q)=NALLOC(2); DN(q)=0; + PL(NM(q))=2; BD(NM(q))[0]=al; BD(NM(q))[1] = au; + } else { + UTOQ(al,q); SGN(q) = sgn; + } + *rp = q; } void Pdrint(arg,rp) NODE arg; Q *rp; { - L a; - unsigned int au,al; - int sgn; - Q q; - double d; + L a; + unsigned int au,al; + int sgn; + Q q; + double d; - if ( !ARG0(arg) ) { - *rp = 0; - return; - } -#if defined(VISUAL) - d = ToReal(ARG0(arg)); - if ( d > 0 ) - d = floor(d+0.5); - else - d = ceil(d-0.5); + if ( !ARG0(arg) ) { + *rp = 0; + return; + } +#if defined(VISUAL) || defined(__MINGW32__) + d = ToReal(ARG0(arg)); + if ( d > 0 ) + d = floor(d+0.5); + else + d = ceil(d-0.5); #else - d = rint(ToReal(ARG0(arg))); + d = rint(ToReal(ARG0(arg))); #endif - if ( d < -9.223372036854775808e18 || d >= 9.223372036854775808e18 ) - error("drint : OverFlow"); - a = (L)d; - if ( a < 0 ) { - sgn = -1; - a = -a; - } else - sgn = 1; -#if defined(i386) || defined(__alpha) || defined(VISUAL) - au = ((unsigned int *)&a)[1]; - al = ((unsigned int *)&a)[0]; + if ( d < -9.223372036854775808e18 || d >= 9.223372036854775808e18 ) + error("drint : OverFlow"); + a = (L)d; + if ( a < 0 ) { + sgn = -1; + a = -a; + } else + sgn = 1; +#if defined(i386) || defined(__alpha) || defined(VISUAL) || defined(__MINGW32__) || defined(__x86_64) + au = ((unsigned int *)&a)[1]; + al = ((unsigned int *)&a)[0]; #else - al = ((unsigned int *)&a)[1]; - au = ((unsigned int *)&a)[0]; + al = ((unsigned int *)&a)[1]; + au = ((unsigned int *)&a)[0]; #endif - if ( au ) { - NEWQ(q); SGN(q) = sgn; NM(q)=NALLOC(2); DN(q)=0; - PL(NM(q))=2; BD(NM(q))[0]=al; BD(NM(q))[1] = au; - } else { - UTOQ(al,q); SGN(q) = sgn; - } - *rp = q; + if ( au ) { + NEWQ(q); SGN(q) = sgn; NM(q)=NALLOC(2); DN(q)=0; + PL(NM(q))=2; BD(NM(q))[0]=al; BD(NM(q))[1] = au; + } else if ( al ) { + UTOQ(al,q); SGN(q) = sgn; + } else + q = 0; + *rp = q; +} + +void Pdisnan(NODE arg,Q *rp) +{ + Real r; + double d; +#if defined(VISUAL) || defined(__MINGW32__) + int c; +#endif + + r = (Real)ARG0(arg); + if ( !r || !NUM(r) || !REAL(r) ) { + *rp = 0; + return; + } + d = ToReal(r); +#if defined(VISUAL) || defined(__MINGW32__) + c = _fpclass(d); + if ( c == _FPCLASS_SNAN || c == _FPCLASS_QNAN ) *rp = ONE; + else if ( c == _FPCLASS_PINF || c == _FPCLASS_NINF ) STOQ(2,*rp); +#else + if ( isnan(d) ) *rp = ONE; + else if ( isinf(d) ) STOQ(2,*rp); +#endif + else *rp = 0; }