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1.1 ! root 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[] = "@(#)expm1.c 1.2 (Berkeley) 8/21/85"; ! 16: #endif not lint ! 17: ! 18: /* EXPM1(X) ! 19: * RETURN THE EXPONENTIAL OF X MINUS ONE ! 20: * DOUBLE PRECISION (IEEE 53 BITS, VAX D FORMAT 56 BITS) ! 21: * CODED IN C BY K.C. NG, 1/19/85; ! 22: * REVISED BY K.C. NG on 2/6/85, 3/7/85, 3/21/85, 4/16/85. ! 23: * ! 24: * Required system supported functions: ! 25: * scalb(x,n) ! 26: * copysign(x,y) ! 27: * finite(x) ! 28: * ! 29: * Kernel function: ! 30: * exp__E(x,c) ! 31: * ! 32: * Method: ! 33: * 1. Argument Reduction: given the input x, find r and integer k such ! 34: * that ! 35: * x = k*ln2 + r, |r| <= 0.5*ln2 . ! 36: * r will be represented as r := z+c for better accuracy. ! 37: * ! 38: * 2. Compute EXPM1(r)=exp(r)-1 by ! 39: * ! 40: * EXPM1(r=z+c) := z + exp__E(z,c) ! 41: * ! 42: * 3. EXPM1(x) = 2^k * ( EXPM1(r) + 1-2^-k ). ! 43: * ! 44: * Remarks: ! 45: * 1. When k=1 and z < -0.25, we use the following formula for ! 46: * better accuracy: ! 47: * EXPM1(x) = 2 * ( (z+0.5) + exp__E(z,c) ) ! 48: * 2. To avoid rounding error in 1-2^-k where k is large, we use ! 49: * EXPM1(x) = 2^k * { [z+(exp__E(z,c)-2^-k )] + 1 } ! 50: * when k>56. ! 51: * ! 52: * Special cases: ! 53: * EXPM1(INF) is INF, EXPM1(NaN) is NaN; ! 54: * EXPM1(-INF)= -1; ! 55: * for finite argument, only EXPM1(0)=0 is exact. ! 56: * ! 57: * Accuracy: ! 58: * EXPM1(x) returns the exact (exp(x)-1) nearly rounded. In a test run with ! 59: * 1,166,000 random arguments on a VAX, the maximum observed error was ! 60: * .872 ulps (units of the last place). ! 61: * ! 62: * Constants: ! 63: * The hexadecimal values are the intended ones for the following constants. ! 64: * The decimal values may be used, provided that the compiler will convert ! 65: * from decimal to binary accurately enough to produce the hexadecimal values ! 66: * shown. ! 67: */ ! 68: ! 69: #ifdef VAX /* VAX D format */ ! 70: /* double static */ ! 71: /* ln2hi = 6.9314718055829871446E-1 , Hex 2^ 0 * .B17217F7D00000 */ ! 72: /* ln2lo = 1.6465949582897081279E-12 , Hex 2^-39 * .E7BCD5E4F1D9CC */ ! 73: /* lnhuge = 9.4961163736712506989E1 , Hex 2^ 7 * .BDEC1DA73E9010 */ ! 74: /* invln2 = 1.4426950408889634148E0 ; Hex 2^ 1 * .B8AA3B295C17F1 */ ! 75: static long ln2hix[] = { 0x72174031, 0x0000f7d0}; ! 76: static long ln2lox[] = { 0xbcd52ce7, 0xd9cce4f1}; ! 77: static long lnhugex[] = { 0xec1d43bd, 0x9010a73e}; ! 78: static long invln2x[] = { 0xaa3b40b8, 0x17f1295c}; ! 79: #define ln2hi (*(double*)ln2hix) ! 80: #define ln2lo (*(double*)ln2lox) ! 81: #define lnhuge (*(double*)lnhugex) ! 82: #define invln2 (*(double*)invln2x) ! 83: #else /* IEEE double */ ! 84: double static ! 85: ln2hi = 6.9314718036912381649E-1 , /*Hex 2^ -1 * 1.62E42FEE00000 */ ! 86: ln2lo = 1.9082149292705877000E-10 , /*Hex 2^-33 * 1.A39EF35793C76 */ ! 87: lnhuge = 7.1602103751842355450E2 , /*Hex 2^ 9 * 1.6602B15B7ECF2 */ ! 88: invln2 = 1.4426950408889633870E0 ; /*Hex 2^ 0 * 1.71547652B82FE */ ! 89: #endif ! 90: ! 91: double expm1(x) ! 92: double x; ! 93: { ! 94: double static one=1.0, half=1.0/2.0; ! 95: double scalb(), copysign(), exp__E(), z,hi,lo,c; ! 96: int k,finite(); ! 97: #ifdef VAX ! 98: static prec=56; ! 99: #else /* IEEE double */ ! 100: static prec=53; ! 101: #endif ! 102: #ifndef VAX ! 103: if(x!=x) return(x); /* x is NaN */ ! 104: #endif ! 105: ! 106: if( x <= lnhuge ) { ! 107: if( x >= -40.0 ) { ! 108: ! 109: /* argument reduction : x - k*ln2 */ ! 110: k= invln2 *x+copysign(0.5,x); /* k=NINT(x/ln2) */ ! 111: hi=x-k*ln2hi ; ! 112: z=hi-(lo=k*ln2lo); ! 113: c=(hi-z)-lo; ! 114: ! 115: if(k==0) return(z+exp__E(z,c)); ! 116: if(k==1) ! 117: if(z< -0.25) ! 118: {x=z+half;x +=exp__E(z,c); return(x+x);} ! 119: else ! 120: {z+=exp__E(z,c); x=half+z; return(x+x);} ! 121: /* end of k=1 */ ! 122: ! 123: else { ! 124: if(k<=prec) ! 125: { x=one-scalb(one,-k); z += exp__E(z,c);} ! 126: else if(k<100) ! 127: { x = exp__E(z,c)-scalb(one,-k); x+=z; z=one;} ! 128: else ! 129: { x = exp__E(z,c)+z; z=one;} ! 130: ! 131: return (scalb(x+z,k)); ! 132: } ! 133: } ! 134: /* end of x > lnunfl */ ! 135: ! 136: else ! 137: /* expm1(-big#) rounded to -1 (inexact) */ ! 138: if(finite(x)) ! 139: { ln2hi+ln2lo; return(-one);} ! 140: ! 141: /* expm1(-INF) is -1 */ ! 142: else return(-one); ! 143: } ! 144: /* end of x < lnhuge */ ! 145: ! 146: else ! 147: /* expm1(INF) is INF, expm1(+big#) overflows to INF */ ! 148: return( finite(x) ? scalb(one,5000) : x); ! 149: }
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