Add ipmitool (#2087)

git-svn-id: svn://svn.openwrt.org/openwrt/packages@13147 3c298f89-4303-0410-b956-a3cf2f4a3e73

utils/ipmitool/patches/100-cubic_root.patch

@@ -0,0 +1,147 @@
+--- ipmitool-1.8.9/lib/ipmi_sdr.c.orig	2007-07-16 13:09:13.000000000 +0200
++++ ipmitool-1.8.9/lib/ipmi_sdr.c	2007-07-16 13:09:20.000000000 +0200
+@@ -4264,3 +4264,144 @@
+ 
+ 	return rc;
+ }
++
++/*							cbrt.c
++ *
++ *	Cube root
++ *
++ *
++ *
++ * SYNOPSIS:
++ *
++ * double x, y, cbrt();
++ *
++ * y = cbrt( x );
++ *
++ *
++ *
++ * DESCRIPTION:
++ *
++ * Returns the cube root of the argument, which may be negative.
++ *
++ * Range reduction involves determining the power of 2 of
++ * the argument.  A polynomial of degree 2 applied to the
++ * mantissa, and multiplication by the cube root of 1, 2, or 4
++ * approximates the root to within about 0.1%.  Then Newton's
++ * iteration is used three times to converge to an accurate
++ * result.
++ *
++ *
++ *
++ * ACCURACY:
++ *
++ *                      Relative error:
++ * arithmetic   domain     # trials      peak         rms
++ *    DEC        -10,10     200000      1.8e-17     6.2e-18
++ *    IEEE       0,1e308     30000      1.5e-16     5.0e-17
++ *
++ */
++/*							cbrt.c  */
++
++/*
++Cephes Math Library Release 2.8:  June, 2000
++Copyright 1984, 1991, 2000 by Stephen L. Moshier
++*/
++
++
++static double CBRT2  = 1.2599210498948731647672;
++static double CBRT4  = 1.5874010519681994747517;
++static double CBRT2I = 0.79370052598409973737585;
++static double CBRT4I = 0.62996052494743658238361;
++
++#ifdef ANSIPROT
++extern double frexp ( double, int * );
++extern double ldexp ( double, int );
++extern int isnan ( double );
++extern int isfinite ( double );
++#else
++double frexp(), ldexp();
++int isnan(), isfinite();
++#endif
++
++double cbrt(x)
++double x;
++{
++int e, rem, sign;
++double z;
++
++#ifdef NANS
++if( isnan(x) )
++  return x;
++#endif
++#ifdef INFINITIES
++if( !isfinite(x) )
++  return x;
++#endif
++if( x == 0 )
++	return( x );
++if( x > 0 )
++	sign = 1;
++else
++	{
++	sign = -1;
++	x = -x;
++	}
++
++z = x;
++/* extract power of 2, leaving
++ * mantissa between 0.5 and 1
++ */
++x = frexp( x, &e );
++
++/* Approximate cube root of number between .5 and 1,
++ * peak relative error = 9.2e-6
++ */
++x = (((-1.3466110473359520655053e-1  * x
++      + 5.4664601366395524503440e-1) * x
++      - 9.5438224771509446525043e-1) * x
++      + 1.1399983354717293273738e0 ) * x
++      + 4.0238979564544752126924e-1;
++
++/* exponent divided by 3 */
++if( e >= 0 )
++	{
++	rem = e;
++	e /= 3;
++	rem -= 3*e;
++	if( rem == 1 )
++		x *= CBRT2;
++	else if( rem == 2 )
++		x *= CBRT4;
++	}
++
++
++/* argument less than 1 */
++
++else
++	{
++	e = -e;
++	rem = e;
++	e /= 3;
++	rem -= 3*e;
++	if( rem == 1 )
++		x *= CBRT2I;
++	else if( rem == 2 )
++		x *= CBRT4I;
++	e = -e;
++	}
++
++/* multiply by power of 2 */
++x = ldexp( x, e );
++
++/* Newton iteration */
++x -= ( x - (z/(x*x)) )*0.33333333333333333333;
++#ifdef DEC
++x -= ( x - (z/(x*x)) )/3.0;
++#else
++x -= ( x - (z/(x*x)) )*0.33333333333333333333;
++#endif
++
++if( sign < 0 )
++	x = -x;
++return(x);
++}