/**************************************** * Computer Algebra System SINGULAR * ****************************************/ /* * ABSTRACT - multipolynomial resultants - real floating-point numbers using gmp * and complex numbers based on pairs of real floating-point numbers * */ // WARNING! ALWAYS use omAlloc and FreeL when alloc. memory for some char* !! #include "config.h" //#ifdef HAVE_MPR #include #include #include #include #include #include #include //%s // this was copied form longrat0.cc // and will be used in numberToFloat. // Make sure that it is up to date!! #define SR_HDL(A) ((long)(A)) #define SR_TO_INT(SR) (((long)SR) >> 2) #define SIGN_PLUS 1 #define SIGN_SPACE 2 #define SIGN_EMPTY 4 #define EXTRABYTES 4 #define DEFPREC 20 // minimum number of digits (output operations) size_t gmp_output_digits= DEFPREC; static gmp_float *gmpRel=NULL; static gmp_float *diff=NULL; /** Set size of mantissa * digits - the number of output digits (basis 10) * the size of mantissa consists of two parts: * the "output" part a and the "rest" part b. * According to the GMP-precision digits is * recomputed to bits (basis 2). * Two numbers a, b are equal if * | a - b | < | a | * 0.1^digits . * In this case we have a - b = 0 . * The epsilon e is e=0.1^(digits+rest) with * 1+e != 1, but 1+0.1*e = 1. */ void setGMPFloatDigits( size_t digits, size_t rest ) { size_t bits = 1 + (size_t) ((float)digits * 3.5); size_t rb = 1 + (size_t) ((float)rest * 3.5); size_t db = bits+rb; gmp_output_digits= digits; mpf_set_default_prec( db ); if (diff!=NULL) delete diff; diff=new gmp_float(0.0); mpf_set_prec(*diff->_mpfp(),32); if (gmpRel!=NULL) delete gmpRel; gmpRel=new gmp_float(0.0); mpf_set_prec(*gmpRel->_mpfp(),32); mpf_set_d(*gmpRel->_mpfp(),0.1); mpf_pow_ui(*gmpRel->_mpfp(),*gmpRel->_mpfp(),digits); } size_t getGMPFloatDigits() { return gmp_output_digits; } #if 1 void gmp_float::setFromStr(const char * in ) { BOOLEAN neg=false; if (*in == '-') { in++; neg=TRUE; } char *s; if ((s=strchr((char *)in,'E')) !=NULL) { *s='e'; } // gmp doesn't understand number which begin with "." -- it needs 0. // so, insert the zero if (*in == '.') { int len = strlen(in)+2; char* c_in = (char*) omAlloc(len); *c_in = '0'; strcpy(&(c_in[1]), in); mpf_set_str( t, c_in, 10 ); omFreeSize((void*)c_in, len); } else { mpf_set_str( t, in, 10 ); } if (neg) mpf_neg( t, t ); } #else // problemns with solve_s.tst void gmp_float::setFromStr(const char * in ) { BOOLEAN neg=false; BOOLEAN E_found=FALSE; if (*in == '-') { in++; neg=TRUE; } char *s; if ((s=strchr(in,'E')) !=NULL) { *s='e'; E_found=TRUE; } // gmp doesn't understand number like 1e1, it need 1e+1 // so, insert the + if (E_found ||((s=strchr(in,'e')) !=NULL)) { if ((*(s+1)!='+') && (*(s+1)!='-')) { int len = strlen(in)+3; char* c_in = (char*) omAlloc(len); if (*in == '.') { *c_in = '0'; strcpy(&(c_in[1]), in); } else { strcpy(c_in, in); } char * ss=strchr(c_in,'e'); memmove(ss+2,s+1,strlen(s+1)); *(ss+1)+'+'; mpf_set_str( t, c_in, 10 ); omFreeSize((void*)c_in, len); } } // gmp doesn't understand number which begin with "." -- it needs 0. // so, insert the zero else if (*in == '.') { int len = strlen(in)+2; char* c_in = (char*) omAlloc(len); *c_in = '0'; strcpy(&(c_in[1]), in); mpf_set_str( t, c_in, 10 ); omFreeSize((void*)c_in, len); } else { mpf_set_str( t, in, 10 ); } if (neg) mpf_neg( t, t ); } #endif // = operator gmp_float operator + ( const gmp_float & a, const gmp_float & b ) { gmp_float tmp( a ); tmp += b; return tmp; } gmp_float operator - ( const gmp_float & a, const gmp_float & b ) { gmp_float tmp( a ); tmp -= b; return tmp; } gmp_float operator * ( const gmp_float & a, const gmp_float & b ) { gmp_float tmp( a ); tmp *= b; return tmp; } gmp_float operator / ( const gmp_float & a, const gmp_float & b ) { gmp_float tmp( a ); tmp /= b; return tmp; } // operator gmp_float & gmp_float::operator += ( const gmp_float & a ) { if (mpf_sgn(t) != -(mpf_sgn(a.t))) { mpf_add( t, t, a.t); return *this; } if((mpf_sgn(a.t)==0) && (mpf_sgn(t)==0)) { mpf_set_d( t, 0.0); return *this; } mpf_add( t, t, a.t ); mpf_set(diff->t, t); mpf_set_prec(diff->t, 32); mpf_div(diff->t, diff->t, a.t); mpf_abs(diff->t, diff->t); if(mpf_cmp(diff->t, gmpRel->t) < 0) mpf_set_d( t, 0.0); return *this; } gmp_float & gmp_float::operator -= ( const gmp_float & a ) { if (mpf_sgn(t) != mpf_sgn(a.t)) { mpf_sub( t, t, a.t); return *this; } if((mpf_sgn(a.t)==0) && (mpf_sgn(t)==0)) { mpf_set_d( t, 0.0); return *this; } mpf_sub( t, t, a.t ); mpf_set(diff->t, t); mpf_set_prec(diff->t, 32); mpf_div(diff->t, diff->t, a.t); mpf_abs(diff->t, diff->t); if(mpf_cmp(diff->t, gmpRel->t) < 0) mpf_set_d( t, 0.0); return *this; } // == ?? bool operator == ( const gmp_float & a, const gmp_float & b ) { if(mpf_sgn(a.t) != mpf_sgn(b.t)) return false; if((mpf_sgn(a.t)==0) && (mpf_sgn(b.t)==0)) return true; mpf_sub(diff->t, a.t, b.t); mpf_div(diff->t, diff->t, a.t); mpf_abs(diff->t, diff->t); if(mpf_cmp(diff->t, gmpRel->t) < 0) return true; else return false; } // t == 0 ? bool gmp_float::isZero() const { return (mpf_sgn( t ) == 0); } // t == 1 ? bool gmp_float::isOne() const { #ifdef VARIANTE_1 return (mpf_cmp_ui( t , 1 ) == 0); #else if (mpf_sgn(t) <= 0) return false; mpf_sub_ui(diff->t, t, 1); mpf_abs(diff->t, diff->t); if(mpf_cmp(diff->t, gmpRel->t) < 0) return true; else return false; #endif } // t == -1 ? bool gmp_float::isMOne() const { #ifdef VARIANTE_1 return (mpf_cmp_si( t , -1 ) == 0); #else if (mpf_sgn(t) >= 0) return false; mpf_add_ui(diff->t, t, 1); mpf_abs(diff->t, diff->t); if(mpf_cmp(diff->t, gmpRel->t) < 0) return true; else return false; #endif } bool operator > ( const gmp_float & a, const gmp_float & b ) { if (a.t == b.t) return false; return mpf_cmp( a.t, b.t ) > 0; } bool operator < ( const gmp_float & a, const gmp_float & b ) { if (a.t == b.t) return false; return mpf_cmp( a.t, b.t ) < 0; } bool operator >= ( const gmp_float & a, const gmp_float & b ) { if (a.t == b.t) return true; return mpf_cmp( a.t, b.t ) >= 0; } bool operator <= ( const gmp_float & a, const gmp_float & b ) { if (a.t == b.t) return true; return mpf_cmp( a.t, b.t ) <= 0; } // unary - gmp_float operator - ( const gmp_float & a ) { gmp_float tmp; mpf_neg( *(tmp._mpfp()), *(a.mpfp()) ); return tmp; } gmp_float abs( const gmp_float & a ) { gmp_float tmp; mpf_abs( *(tmp._mpfp()), *a.mpfp() ); return tmp; } gmp_float sqrt( const gmp_float & a ) { gmp_float tmp; mpf_sqrt( *(tmp._mpfp()), *a.mpfp() ); return tmp; } gmp_float sin( const gmp_float & a ) { gmp_float tmp( sin((double)a) ); return tmp; } gmp_float cos( const gmp_float & a ) { gmp_float tmp( cos((double)a) ); return tmp; } gmp_float log( const gmp_float & a ) { gmp_float tmp( log((double)a) ); return tmp; } gmp_float hypot( const gmp_float & a, const gmp_float & b ) { #if 1 return ( sqrt( (a*a) + (b*b) ) ); #else gmp_float tmp( hypot( (double)a, (double)b ) ); return tmp; #endif } gmp_float exp( const gmp_float & a ) { gmp_float tmp( exp((double)a) ); return tmp; } gmp_float max( const gmp_float & a, const gmp_float & b ) { gmp_float tmp; a > b ? tmp= a : tmp= b; return tmp; } // // number to float, number = Q, R, C // makes a COPY of num! (Ist das gut?) // gmp_float numberToFloat( number num, const coeffs src) { gmp_float r; if ( nCoeff_is_Q(src) ) { if ( num != NULL ) { if (SR_HDL(num) & SR_INT) { r= SR_TO_INT(num); } else { if ( num->s == 0 ) { nlNormalize( num, src ); } if (SR_HDL(num) & SR_INT) { r= SR_TO_INT(num); } else { if ( num->s != 3 ) { r= num->z; r/= (gmp_float)num->n; } else { r= num->z; } } } } else { r= 0.0; } } else if (nCoeff_is_long_R(src) || nCoeff_is_long_C(src)) { r= *(gmp_float*)num; } else if ( nCoeff_is_R(src) ) { // Add some code here :-) WerrorS("Ground field not implemented!"); } else { WerrorS("Ground field not implemented!"); } return r; } gmp_float numberFieldToFloat( number num, int k, const coeffs src) { gmp_float r; switch (k) { case QTOF: if ( num != NULL ) { if (SR_HDL(num) & SR_INT) { r= SR_TO_INT(num); } else { if ( num->s == 0 ) { nlNormalize( num, src ); } if (SR_HDL(num) & SR_INT) { r= SR_TO_INT(num); } else { if ( num->s != 3 ) { r= num->z; r/= (gmp_float)num->n; } else { r= num->z; } } } } else { r= 0.0; } break; case RTOF: r= *(gmp_float*)num; break; case CTOF: WerrorS("Can not map from field C to field R!"); break; case ZTOF: default: WerrorS("Ground field not implemented!"); } // switch return r; } // Do some strange things with the mantissa string and the exponent // to get some nice output string. char *nicifyFloatStr( char * in, mp_exp_t exponent, size_t oprec, int *size, int thesign ) { char *out; int sign= (in[0] == '-') ? 1 : 0; char csign[2]; switch (thesign) { case SIGN_PLUS: sign ? strcpy(csign,"-") : strcpy(csign,"+"); //+123, -123 break; case SIGN_SPACE: sign ? strcpy(csign,"-") : strcpy(csign," "); // 123, -123 break; case SIGN_EMPTY: default: sign ? strcpy(csign,"-") : strcpy(csign,""); //123, -123 break; } if ( strlen(in) == 0 ) { *size= 2*sizeof(char); return omStrDup("0"); } if ( ((unsigned int)ABS(exponent) <= oprec) /*|| (exponent+sign >= (int)strlen(in))*/ ) { if ( exponent+sign < (int)strlen(in) ) { int eexponent= (exponent >= 0) ? 0 : -exponent; int eeexponent= (exponent >= 0) ? exponent : 0; *size= (strlen(in)+15+eexponent) * sizeof(char); out= (char*)omAlloc(*size); memset(out,0,*size); strcpy(out,csign); strncat(out,in+sign,eeexponent); if (exponent == 0) strcat(out,"0."); else if ( exponent > 0 ) strcat(out,"."); else { strcat(out,"0."); memset(out+strlen(out),'0',eexponent); } strcat(out,in+sign+eeexponent); } else if ( exponent+sign > (int)strlen(in) ) { *size= (strlen(in)+exponent+12)*sizeof(char); out= (char*)omAlloc(*size); memset(out,0,*size); sprintf(out,"%s%s",csign,in+sign); memset(out+strlen(out),'0',exponent-strlen(in)+sign); } else { *size= (strlen(in)+2) * sizeof(char) + 10; out= (char*)omAlloc(*size); memset(out,0,*size); sprintf(out,"%s%s",csign,in+sign); } } else { // if ( exponent > 0 ) // { int c=1,d=10; while ( exponent / d > 0 ) { // count digits d*=10; c++; } *size= (strlen(in)+12+c) * sizeof(char) + 10; out= (char*)omAlloc(*size); memset(out,0,*size); sprintf(out,"%s0.%se%s%d",csign,in+sign,exponent>=0?"+":"",(int)exponent); // } // else // { // *size=2; // out= (char*)omAlloc(*size); // strcpy(out,"0"); // } } return out; } char *floatToStr( const gmp_float & r, const unsigned int oprec ) { #if 1 mp_exp_t exponent; int size,insize; char *nout,*out,*in; insize= (oprec+2) * sizeof(char) + 10; in= (char*)omAlloc( insize ); mpf_get_str(in,&exponent,10,oprec,*(r.mpfp())); if ( (exponent > 0) && (exponent < (int)oprec) && (strlen(in)-(in[0]=='-'?1:0) == oprec) ) { omFree( (void *) in ); insize= (exponent+oprec+2) * sizeof(char) + 10; in= (char*)omAlloc( insize ); int newprec= exponent+oprec; mpf_get_str(in,&exponent,10,newprec,*(r.mpfp())); } nout= nicifyFloatStr( in, exponent, oprec, &size, SIGN_EMPTY ); omFree( (void *) in ); out= (char*)omAlloc( (strlen(nout)+1) * sizeof(char) ); strcpy( out, nout ); omFree( (void *) nout ); return out; #else // for testing purpose... char *out= (char*)omAlloc( (1024) * sizeof(char) ); sprintf(out,"% .10f",(double)r); return out; #endif } //<- //-> gmp_complex::* // = operator // gmp_complex operator + ( const gmp_complex & a, const gmp_complex & b ) { return gmp_complex( a.r + b.r, a.i + b.i ); } gmp_complex operator - ( const gmp_complex & a, const gmp_complex & b ) { return gmp_complex( a.r - b.r, a.i - b.i ); } gmp_complex operator * ( const gmp_complex & a, const gmp_complex & b ) { return gmp_complex( a.r * b.r - a.i * b.i, a.r * b.i + a.i * b.r); } gmp_complex operator / ( const gmp_complex & a, const gmp_complex & b ) { gmp_float d = b.r*b.r + b.i*b.i; return gmp_complex( (a.r * b.r + a.i * b.i) / d, (a.i * b.r - a.r * b.i) / d); } // operator // gmp_complex & gmp_complex::operator += ( const gmp_complex & b ) { r+=b.r; i+=b.i; return *this; } gmp_complex & gmp_complex::operator -= ( const gmp_complex & b ) { r-=b.r; i-=b.i; return *this; } gmp_complex & gmp_complex::operator *= ( const gmp_complex & b ) { gmp_float f = r * b.r - i * b.i; i = r * b.i + i * b.r; r = f; return *this; } gmp_complex & gmp_complex::neg ( ) { i.neg(); r.neg(); return *this; } gmp_complex & gmp_complex::operator /= ( const gmp_complex & b ) { gmp_float d = b.r*b.r + b.i*b.i; r = (r * b.r + i * b.i) / d; i = (i * b.r - r * b.i) / d; return *this; } // Returns square root of gmp_complex number // gmp_complex sqrt( const gmp_complex & x ) { gmp_float r = abs(x); gmp_float nr, ni; if (r == (gmp_float) 0.0) { nr = ni = r; } else if ( x.real() > (gmp_float)0) { nr = sqrt((gmp_float)0.5 * (r + x.real())); ni = x.imag() / nr / (gmp_float)2; } else { ni = sqrt((gmp_float)0.5 * (r - x.real())); if (x.imag() < (gmp_float)0) { ni = - ni; } nr = x.imag() / ni / (gmp_float)2; } gmp_complex tmp(nr, ni); return tmp; } // converts a gmp_complex to a string ( + I * ) // char *complexToStr( gmp_complex & c, const unsigned int oprec, const coeffs src ) { const char * complex_parameter = "I"; int N = 1; // strlen(complex_parameter); if (nCoeff_is_long_C(src)) { complex_parameter = n_ParameterNames(src)[0]; N = strlen(complex_parameter); } assume( complex_parameter != NULL && N > 0); char *out,*in_imag,*in_real; c.SmallToZero(); if ( !c.imag().isZero() ) { in_real=floatToStr( c.real(), oprec ); // get real part in_imag=floatToStr( abs(c.imag()), oprec ); // get imaginary part if (nCoeff_is_long_C(src)) { int len=(strlen(in_real)+strlen(in_imag)+7+N)*sizeof(char); out=(char*)omAlloc(len); memset(out,0,len); if ( !c.real().isZero() ) // (-23-i*5.43) or (15.1+i*5.3) sprintf(out,"(%s%s%s*%s)",in_real,c.imag().sign()>=0?"+":"-",complex_parameter,in_imag); else // (-i*43) or (i*34) { if (c.imag().isOne()) sprintf(out,"%s", complex_parameter); else if (c.imag().isMOne()) sprintf(out,"-%s", complex_parameter); else sprintf(out,"(%s%s*%s)",c.imag().sign()>=0?"":"-", complex_parameter,in_imag); } } else { int len=(strlen(in_real)+strlen(in_imag)+9) * sizeof(char); out=(char*)omAlloc( len ); memset(out,0,len); if ( !c.real().isZero() ) sprintf(out,"(%s%s%s)",in_real,c.imag().sign()>=0?"+I*":"-I*",in_imag); else sprintf(out,"(%s%s)",c.imag().sign()>=0?"I*":"-I*",in_imag); } omFree( (void *) in_real ); omFree( (void *) in_imag ); } else { out= floatToStr( c.real(), oprec ); } return out; } //<- bool complexNearZero( gmp_complex * c, int digits ) { gmp_float eps,epsm; if ( digits < 1 ) return true; eps=pow(10.0,(int)digits); //Print("eps: %s\n",floatToStr(eps,gmp_output_digits)); eps=(gmp_float)1.0/eps; epsm=-eps; //Print("eps: %s\n",floatToStr(eps,gmp_output_digits)); if ( c->real().sign() > 0 ) // + return (c->real() < eps && (c->imag() < eps && c->imag() > epsm)); else // - return (c->real() > epsm && (c->imag() < eps && c->imag() > epsm)); } void gmp_complex::SmallToZero() { gmp_float ar=this->real(); gmp_float ai=this->imag(); if (ar.isZero() || ai.isZero()) return; mpf_abs(*ar._mpfp(), *ar._mpfp()); mpf_abs(*ai._mpfp(), *ai._mpfp()); mpf_set_prec(*ar._mpfp(), 32); mpf_set_prec(*ai._mpfp(), 32); if (ar > ai) { mpf_div(*ai._mpfp(), *ai._mpfp(), *ar._mpfp()); if (ai < *gmpRel) this->imag(0.0); } else { mpf_div(*ar._mpfp(), *ar._mpfp(), *ai._mpfp()); if (ar < *gmpRel) this->real(0.0); } } //%e //#endif // HAVE_MPR // local Variables: *** // folded-file: t *** // compile-command-1: "make installg" *** // compile-command-2: "make install" *** // End: ***