2 Copyright © 1995-2008, The AROS Development Team. All rights reserved.
6 #include "mathieeesingtrans_intern.h"
8 /*****************************************************************************
12 AROS_LH1(float, IEEESPLog
,
15 AROS_LHA(float, y
, D0
),
18 struct Library
*, MathIeeeSingTransBase
, 14, MathIeeeSingTrans
)
21 Calculate logarithm (base e) of the given IEEE single precision number
26 IEEE single precision number
30 negative : result is negative
31 overflow : argument was negative
38 If the Argument is negative set overflow-flag and return 0.
39 If the Argument is 0 return 0xffffffff.
43 (ld is the logarithm with base 2)
44 (ln is the logarithm with base e)
47 ln y = ln ( M * 2^E ) =
54 = ----- + E * ----- = [ld 2 = 1]
61 ld e can be precalculated, of course.
62 For calculating ld M see file intern_ieeespld.c
64 *****************************************************************************/
68 LONG ld_M
, Exponent
, Mask
= 0x40, i
, Sign
;
70 /* check for negative sign */
73 SetSR(Overflow_Bit
, Zero_Bit
| Negative_Bit
| Overflow_Bit
);
77 /* check for argument == 0 or argument == +infinity */
78 if (0 == y
|| IEEESP_Pinfty
== y
) return y
;
80 /* convert the Exponent of the argument (y) to the ieeesp-format */
81 Exponent
= ((y
& IEEESPExponent_Mask
) >> 23) - 0x7e ;
86 Sign
= IEEESPSign_Mask
;
93 /* find the number of the highest set bit in the exponent */
97 while ( (Mask
& Exponent
) == 0)
103 Exponent
<<= (17 + i
);
104 Exponent
&= IEEESPMantisse_Mask
;
105 Exponent
|= ((0x85 - i
) << 23);
109 ld_M
= intern_IEEESPLd((y
& IEEESPMantisse_Mask
) | 0x3f000000);
117 return IEEESPMul( IEEESPAdd(ld_M
, Exponent
), InvLde
);