/**************************************** * Computer Algebra System SINGULAR * ****************************************/ /* $Id$ */ /* * ABSTRACT: computations with GMP floating-point numbers * * ngf == number gnu floats */ #include "config.h" #include "coeffs.h" #include #include #include "numbers.h" #include "modulop.h" #include "longrat.h" #include #include extern size_t gmp_output_digits; //ring ngfMapRing; // to be used also in gnumpc.cc /// Our Type! static const n_coeffType ID = n_gnump_R; static number ngfMapP(number from, const coeffs src, const coeffs dst) { return ngfInit(npInt(from,src), dst); } number ngfMapQ(number from, const coeffs src, const coeffs dst) { gmp_float *res=new gmp_float(numberFieldToFloat(from,QTOF)); return (number)res; } union nf { float _f; number _n; nf(float f) {_f = f;} nf(number n) {_n = n;} float F() const {return _f;} number N() const {return _n;} }; static number ngfMapR(number from, const coeffs src, const coeffs dst) { gmp_float *res=new gmp_float((double)nf(from).F()); return (number)res; } static number ngfMapC(number from, const coeffs src, const coeffs dst) { gmp_float *res=new gmp_float(((gmp_complex*)from)->real()); return (number)res; } /*2 * n := i */ number ngfInit (int i, const coeffs r) { assume( getCoeffType(r) == ID ); gmp_float* n= new gmp_float( (double)i ); return (number)n; } /*2 * convert number to int */ int ngfInt(number &i, const coeffs r) { assume( getCoeffType(r) == ID ); double d=(double)*(gmp_float*)i; if (d<0.0) return (int)(d-0.5); else return (int)(d+0.5); } int ngfSize(number n, const coeffs r) { int i = ngfInt(n, r); /* basically return the largest integer in n; only if this happens to be zero although n != 0, return 1; (this code ensures that zero has the size zero) */ if ((i == 0) && (ngfIsZero(n) == FALSE)) i = 1; return i; } /*2 * delete a */ void ngfDelete (number * a, const coeffs r) { assume( getCoeffType(r) == ID ); if ( *a != NULL ) { delete *(gmp_float**)a; *a=NULL; } } /*2 * copy a to b */ number ngfCopy(number a, const coeffs r) { assume( getCoeffType(r) == ID ); gmp_float* b= new gmp_float( *(gmp_float*)a ); return (number)b; } /*2 * za:= - za */ number ngfNeg (number a, const coeffs r) { assume( getCoeffType(r) == ID ); *(gmp_float*)a= -(*(gmp_float*)a); return (number)a; } /* * 1/a */ number ngfInvers(number a, const coeffs r) { assume( getCoeffType(r) == ID ); gmp_float* f= NULL; if (((gmp_float*)a)->isZero() ) { WerrorS(nDivBy0); } else { f= new gmp_float( gmp_float(1) / (*(gmp_float*)a) ); } return (number)f; } /*2 * u:= a + b */ number ngfAdd (number a, number b, const coeffs R) { assume( getCoeffType(R) == ID ); gmp_float* r= new gmp_float( (*(gmp_float*)a) + (*(gmp_float*)b) ); return (number)r; } /*2 * u:= a - b */ number ngfSub (number a, number b, const coeffs R) { assume( getCoeffType(R) == ID ); gmp_float* r= new gmp_float( (*(gmp_float*)a) - (*(gmp_float*)b) ); return (number)r; } /*2 * u := a * b */ number ngfMult (number a, number b, const coeffs R) { assume( getCoeffType(R) == ID ); gmp_float* r= new gmp_float( (*(gmp_float*)a) * (*(gmp_float*)b) ); return (number)r; } /*2 * u := a / b */ number ngfDiv (number a, number b, const coeffs r) { assume( getCoeffType(r) == ID ); if ( ((gmp_float*)b)->isZero() ) { // a/0 = error WerrorS(nDivBy0); return NULL; } gmp_float* f= new gmp_float( (*(gmp_float*)a) / (*(gmp_float*)b) ); return (number)f; } /*2 * u:= x ^ exp */ number ngfPower (number x, int exp, const coeffs r) { assume( getCoeffType(r) == ID ); if ( exp == 0 ) { gmp_float* n = new gmp_float(1); *u=(number)n; return; } else if ( ngfIsZero(x, r) ) // 0^e, e>0 { *u=ngfInit(0, r); return; } else if ( exp == 1 ) { n_New(u, r); gmp_float* n = new gmp_float(); *n= *(gmp_float*)x; *u=(number)n; return; } return (number) ( new gmp_float( (*(gmp_float*)x)^exp ) ); } /* kept for compatibility reasons, to be deleted */ void ngfPower ( number x, int exp, number * u, const coeffs r ) { *u = ngfPower(x, exp, r); } BOOLEAN ngfIsZero (number a, const coeffs r) { assume( getCoeffType(r) == ID ); return ( ((gmp_float*)a)->isZero() ); } /*2 * za > 0 ? */ BOOLEAN ngfGreaterZero (number a, const coeffs r) { assume( getCoeffType(r) == ID ); return (((gmp_float*)a)->sign() > 0); } /*2 * a > b ? */ BOOLEAN ngfGreater (number a, number b, const coeffs r) { assume( getCoeffType(r) == ID ); return ( (*(gmp_float*)a) > (*(gmp_float*)b) ); } /*2 * a = b ? */ BOOLEAN ngfEqual (number a, number b, const coeffs r) { assume( getCoeffType(r) == ID ); return ( (*(gmp_float*)a) == (*(gmp_float*)b) ); } /*2 * a == 1 ? */ BOOLEAN ngfIsOne (number a, const coeffs r) { assume( getCoeffType(r) == ID ); return ((gmp_float*)a)->isOne(); } /*2 * a == -1 ? */ BOOLEAN ngfIsMOne (number a, const coeffs r) { assume( getCoeffType(r) == ID ); return ((gmp_float*)a)->isMOne(); } static char * ngfEatFloatNExp(char * s ) { char *start= s; // eat floats (mantissa) like: // 0.394394993, 102.203003008, .300303032, pssibly starting with - if (*s == '-') s++; while ((*s >= '0' && *s <= '9')||(*s == '.')) s++; // eat the exponent, starts with 'e' followed by '+', '-' // and digits, like: // e-202, e+393, accept also E7 if ( (s != start) && ((*s == 'e')||(*s=='E'))) { if (*s=='E') *s='e'; s++; // skip 'e'/'E' if ((*s == '+') || (*s == '-')) s++; while ((*s >= '0' && *s <= '9')) s++; } return s; } /*2 * extracts the number a from s, returns the rest */ const char * ngfRead (const char * start, number * a, const coeffs r) { assume( getCoeffType(r) == ID ); char *s= (char *)start; //Print("%s\n",s); s= ngfEatFloatNExp( s ); if (*s=='\0') // 0 { if ( *(gmp_float**)a == NULL ) (*(gmp_float**)a)= new gmp_float(); (*(gmp_float**)a)->setFromStr(start); } else if (s==start) // 1 { if ( *(gmp_float**)a != NULL ) delete (*(gmp_float**)a); (*(gmp_float**)a)= new gmp_float(1); } else { gmp_float divisor(1.0); char *start2=s; if ( *s == '/' ) { s++; s= ngfEatFloatNExp( (char *)s ); if (s!= start2+1) { char tmp_c=*s; *s='\0'; divisor.setFromStr(start2+1); *s=tmp_c; } else { Werror("wrong long real format: %s",start2); } } char c=*start2; *start2='\0'; if ( *(gmp_float**)a == NULL ) (*(gmp_float**)a)= new gmp_float(); (*(gmp_float**)a)->setFromStr(start); *start2=c; if (divisor.isZero()) { WerrorS(nDivBy0); } else (**(gmp_float**)a) /= divisor; } return s; } /*2 * write a floating point number */ void ngfWrite (number &a, const coeffs r) { assume( getCoeffType(r) == ID ); extern size_t gmp_output_digits; char *out; if ( a != NULL ) { out= floatToStr(*(gmp_float*)a, gmp_output_digits, r); StringAppendS(out); //omFreeSize((void *)out, (strlen(out)+1)* sizeof(char) ); omFree( (void *)out ); } else { StringAppendS("0"); } } static BOOLEAN ngfCoeffsEqual(const coeffs r, n_coeffType n, int) { assume( getCoeffType(r) == ID ); return (n == ID); }; void ngfInitChar(coeffs n, int) { assume( getCoeffType(n) == ID ); n->cfDelete = ngfDelete; n->nNormalize=ndNormalize; n->cfInit = ngfInit; n->n_Int = ngfInt; n->nAdd = ngfAdd; n->nSub = ngfSub; n->nMult = ngfMult; n->nDiv = ngfDiv; n->nExactDiv= ngfDiv; n->nNeg = ngfNeg; n->nInvers = ngfInvers; n->cfCopy = ngfCopy; n->nGreater = ngfGreater; n->nEqual = ngfEqual; n->nIsZero = ngfIsZero; n->nIsOne = ngfIsOne; n->nIsMOne = ngfIsMOne; n->nGreaterZero = ngfGreaterZero; n->cfWrite = ngfWrite; n->nRead = ngfRead; n->nPower = ngfPower; n->cfSetMap = ngfSetMap; #ifdef LDEBUG n->nDBTest = ndDBTest; // not yet implemented: ngfDBTest #endif number ngfMapQ(number from, const coeffs aRing, const coeffs r) { assume( getCoeffType(r) == ID ); assume( getCoeffType(aRing) == n_Q ); if ( from != NULL ) { gmp_float *res=new gmp_float(numberFieldToFloat(from,QTOF)); return (number)res; } else return NULL; } static number ngfMapR(number from, const coeffs aRing, const coeffs r) { assume( getCoeffType(r) == ID ); assume( getCoeffType(aRing) == n_R ); if ( from != NULL ) { gmp_float *res=new gmp_float((double)nrFloat(from)); return (number)res; } else return NULL; } static number ngfMapP(number from, const coeffs aRing, const coeffs r) { assume( getCoeffType(r) == ID ); assume( getCoeffType(aRing) == n_Zp ); if ( from != NULL ) return ngfInit(npInt(from,src), dst); else return NULL; } static number ngfMapC(number from, const coeffs aRing, const coeffs r) { assume( getCoeffType(r) == ID ); assume( getCoeffType(aRing) == n_long_C ); if ( (from != NULL) || ((gmp_complex*)from)->real().isZero() ) { gmp_float *res=new gmp_float(((gmp_complex*)from)->real()); return (number)res; } else return NULL; } nMapFunc ngfSetMap(const coeffs src, const coeffs dst) { assume( getCoeffType(dst) == ID ); if (nField_is_Q(src)) { return ngfMapQ; } if (nField_is_long_R(src)) { return ngfCopy; } if (nField_is_R(src)) { return ngfMapR; } if (nField_is_long_C(src)) { return ngfMapC; } if (nField_is_Zp(src)) { return ngfMapP; } return NULL; }