1 /* 2 * Copyright (c) 1985 Regents of the University of California. 3 * 4 * Use and reproduction of this software are granted in accordance with 5 * the terms and conditions specified in the Berkeley Software License 6 * Agreement (in particular, this entails acknowledgement of the programs' 7 * source, and inclusion of this notice) with the additional understanding 8 * that all recipients should regard themselves as participants in an 9 * ongoing research project and hence should feel obligated to report 10 * their experiences (good or bad) with these elementary function codes, 11 * using "sendbug 4bsd-bugs@BERKELEY", to the authors. 12 */ 13 14 #ifndef lint 15 static char sccsid[] = "@(#)cabs.c 1.2 (Berkeley) 08/21/85"; 16 #endif not lint 17 18 /* CABS(Z) 19 * RETURN THE ABSOLUTE VALUE OF THE COMPLEX NUMBER Z = X + iY 20 * DOUBLE PRECISION (VAX D format 56 bits, IEEE DOUBLE 53 BITS) 21 * CODED IN C BY K.C. NG, 11/28/84. 22 * REVISED BY K.C. NG, 7/12/85. 23 * 24 * Required kernel function : 25 * hypot(x,y) 26 * 27 * Method : 28 * cabs(z) = hypot(x,y) . 29 */ 30 31 double cabs(z) 32 struct { double x, y;} z; 33 { 34 double hypot(); 35 return(hypot(z.x,z.y)); 36 } 37 38 39 /* HYPOT(X,Y) 40 * RETURN THE SQUARE ROOT OF X^2 + Y^2 WHERE Z=X+iY 41 * DOUBLE PRECISION (VAX D format 56 bits, IEEE DOUBLE 53 BITS) 42 * CODED IN C BY K.C. NG, 11/28/84; 43 * REVISED BY K.C. NG, 7/12/85. 44 * 45 * Required system supported functions : 46 * copysign(x,y) 47 * finite(x) 48 * scalb(x,N) 49 * sqrt(x) 50 * 51 * Method : 52 * 1. replace x by |x| and y by |y|, and swap x and 53 * y if y > x (hence x is never smaller than y). 54 * 2. Hypot(x,y) is computed by: 55 * Case I, x/y > 2 56 * 57 * y 58 * hypot = x + ----------------------------- 59 * 2 60 * sqrt ( 1 + [x/y] ) + x/y 61 * 62 * Case II, x/y <= 2 63 * y 64 * hypot = x + -------------------------------------------------- 65 * 2 66 * [x/y] - 2 67 * (sqrt(2)+1) + (x-y)/y + ----------------------------- 68 * 2 69 * sqrt ( 1 + [x/y] ) + sqrt(2) 70 * 71 * 72 * 73 * Special cases: 74 * hypot(x,y) is INF if x or y is +INF or -INF; else 75 * hypot(x,y) is NAN if x or y is NAN. 76 * 77 * Accuracy: 78 * hypot(x,y) returns the sqrt(x^2+y^2) with error less than 1 ulps (units 79 * in the last place). See Kahan's "Interval Arithmetic Options in the 80 * Proposed IEEE Floating Point Arithmetic Standard", Interval Mathematics 81 * 1980, Edited by Karl L.E. Nickel, pp 99-128. (A faster but less accurate 82 * code follows in comments.) In a test run with 500,000 random arguments 83 * on a VAX, the maximum observed error was .959 ulps. 84 * 85 * Constants: 86 * The hexadecimal values are the intended ones for the following constants. 87 * The decimal values may be used, provided that the compiler will convert 88 * from decimal to binary accurately enough to produce the hexadecimal values 89 * shown. 90 */ 91 92 #ifdef VAX /* VAX D format */ 93 /* static double */ 94 /* r2p1hi = 2.4142135623730950345E0 , Hex 2^ 2 * .9A827999FCEF32 */ 95 /* r2p1lo = 1.4349369327986523769E-17 , Hex 2^-55 * .84597D89B3754B */ 96 /* sqrt2 = 1.4142135623730950622E0 ; Hex 2^ 1 * .B504F333F9DE65 */ 97 static long r2p1hix[] = { 0x8279411a, 0xef3299fc}; 98 static long r2p1lox[] = { 0x597d2484, 0x754b89b3}; 99 static long sqrt2x[] = { 0x04f340b5, 0xde6533f9}; 100 #define r2p1hi (*(double*)r2p1hix) 101 #define r2p1lo (*(double*)r2p1lox) 102 #define sqrt2 (*(double*)sqrt2x) 103 #else /* IEEE double format */ 104 static double 105 r2p1hi = 2.4142135623730949234E0 , /*Hex 2^1 * 1.3504F333F9DE6 */ 106 r2p1lo = 1.2537167179050217666E-16 , /*Hex 2^-53 * 1.21165F626CDD5 */ 107 sqrt2 = 1.4142135623730951455E0 ; /*Hex 2^ 0 * 1.6A09E667F3BCD */ 108 #endif 109 110 double hypot(x,y) 111 double x, y; 112 { 113 static double zero=0, one=1, 114 small=1.0E-18; /* fl(1+small)==1 */ 115 static ibig=30; /* fl(1+2**(2*ibig))==1 */ 116 double copysign(),scalb(),logb(),sqrt(),t,r; 117 int finite(), exp; 118 119 if(finite(x)) 120 if(finite(y)) 121 { 122 x=copysign(x,one); 123 y=copysign(y,one); 124 if(y > x) 125 { t=x; x=y; y=t; } 126 if(x == zero) return(zero); 127 if(y == zero) return(x); 128 exp= logb(x); 129 if(exp-(int)logb(y) > ibig ) 130 /* raise inexact flag and return |x| */ 131 { one+small; return(x); } 132 133 /* start computing sqrt(x^2 + y^2) */ 134 r=x-y; 135 if(r>y) { /* x/y > 2 */ 136 r=x/y; 137 r=r+sqrt(one+r*r); } 138 else { /* 1 <= x/y <= 2 */ 139 r/=y; t=r*(r+2.0); 140 r+=t/(sqrt2+sqrt(2.0+t)); 141 r+=r2p1lo; r+=r2p1hi; } 142 143 r=y/r; 144 return(x+r); 145 146 } 147 148 else if(y==y) /* y is +-INF */ 149 return(copysign(y,one)); 150 else 151 return(y); /* y is NaN and x is finite */ 152 153 else if(x==x) /* x is +-INF */ 154 return (copysign(x,one)); 155 else if(finite(y)) 156 return(x); /* x is NaN, y is finite */ 157 else if(y!=y) return(y); /* x and y is NaN */ 158 else return(copysign(y,one)); /* y is INF */ 159 } 160 161 /* A faster but less accurate version of cabs(x,y) */ 162 #if 0 163 double hypot(x,y) 164 double x, y; 165 { 166 static double zero=0, one=1; 167 small=1.0E-18; /* fl(1+small)==1 */ 168 static ibig=30; /* fl(1+2**(2*ibig))==1 */ 169 double copysign(),scalb(),logb(),sqrt(),temp; 170 int finite(), exp; 171 172 if(finite(x)) 173 if(finite(y)) 174 { 175 x=copysign(x,one); 176 y=copysign(y,one); 177 if(y > x) 178 { temp=x; x=y; y=temp; } 179 if(x == zero) return(zero); 180 if(y == zero) return(x); 181 exp= logb(x); 182 x=scalb(x,-exp); 183 if(exp-(int)logb(y) > ibig ) 184 /* raise inexact flag and return |x| */ 185 { one+small; return(scalb(x,exp)); } 186 else y=scalb(y,-exp); 187 return(scalb(sqrt(x*x+y*y),exp)); 188 } 189 190 else if(y==y) /* y is +-INF */ 191 return(copysign(y,one)); 192 else 193 return(y); /* y is NaN and x is finite */ 194 195 else if(x==x) /* x is +-INF */ 196 return (copysign(x,one)); 197 else if(finite(y)) 198 return(x); /* x is NaN, y is finite */ 199 else if(y!=y) return(y); /* x and y is NaN */ 200 else return(copysign(y,one)); /* y is INF */ 201 } 202 #endif 203