I am using fixed point long arithmetics and my pow is log2/exp2 based. Numbers consist of:

- int sig = { -1; +1 } signum
- DWORD a[A+B] number
- A is num of DWORDs for integer part of number
- B is num of DWORDs for fractional part

My simplified solution is this:

```
//---------------------------------------------------------------------------
longnum exp2 (const longnum &x)
{
int i,j;
longnum c,d;
c.one();
if (x.iszero()) return c;
i=x.bits()-1;
for(d=2,j=_longnum_bits_b;j<=i;j++,d*=d)
if (x.bitget(j))
c*=d;
for(i=0,j=_longnum_bits_b-1;i<_longnum_bits_b;j--,i++)
if (x.bitget(j))
c*=_longnum_log2[i];
if (x.sig<0) {d.one(); c=d/c;}
return c;
}
//---------------------------------------------------------------------------
longnum log2 (const longnum &x)
{
int i,j;
longnum c,d,dd,e,xx;
c.zero(); d.one(); e.zero(); xx=x;
if (xx.iszero()) return c; //**** error: log2(0) = infinity
if (xx.sig<0) return c; //**** error: log2(negative x) ... no result possible
if (d.geq(x,d)==0) {xx=d/xx; xx.sig=-1;}
i=xx.bits()-1;
e.bitset(i); i-=_longnum_bits_b;
for (;i>0;i--,e>>=1) // integer part
{
dd=d*e;
j=dd.geq(dd,xx);
if (j==1) continue; // dd> xx
c+=i; d=dd;
if (j==2) break; // dd==xx
}
for (i=0;i<_longnum_bits_b;i++) // fractional part
{
dd=d*_longnum_log2[i];
j=dd.geq(dd,xx);
if (j==1) continue; // dd> xx
c.bitset(_longnum_bits_b-i-1); d=dd;
if (j==2) break; // dd==xx
}
c.sig=xx.sig;
c.iszero();
return c;
}
//---------------------------------------------------------------------------
longnum pow (const longnum &x,const longnum &y)
{
//x^y = exp2(y*log2(x))
int ssig=+1; longnum c; c=x;
if (y.iszero()) {c.one(); return c;} // ?^0=1
if (c.iszero()) return c; // 0^?=0
if (c.sig<0)
{
c.overflow(); c.sig=+1;
if (y.isreal()) {c.zero(); return c;} //**** error: negative x ^ noninteger y
if (y.bitget(_longnum_bits_b)) ssig=-1;
}
c=exp2(log2(c)*y); c.sig=ssig; c.iszero();
return c;
}
//---------------------------------------------------------------------------
```

where:

_longnum_bits_a = A*32

_longnum_bits_b = B*32

_longnum_log2[i] = 2 ^ (1/(2^i)) ... precomputed sqrt table

- _longnum_log2[0]=sqrt(2)
- _longnum_log2[1]=sqrt[tab[0])
- _longnum_log2[i]=sqrt(tab[i-1])

longnum::zero() sets *this=0

longnum::one() sets *this=+1

bool longnum::iszero() returns (*this==0)

bool longnum::isnonzero() returns (*this!=0)

bool longnum::isreal() returns (true if fractional part !=0)

bool longnum::isinteger() returns (true if fractional part ==0)

int longnum::bits() return num of used bits in number counted from LSB

longnum::bitget()/bitset()/bitres()/bitxor() are bit access

longnum.overflow() rounds number if there was a overflow

- X.FFFFFFFFFF...FFFFFFFFF??h -> (X+1).0000000000000...000000000h

int longnum::geq(x,y) is comparition |x|,|y| returns 0,1,2 for (<,>,==)

All you need to understand this code is that numbers in binary form consists of sum of powers of 2, when you need to compute 2^num then it can be rewritten as this

2^(b(-n)*2^(-n) + ... + b(+m)*2^(+m)) where n are fractional bits and m are integer bits
multiplication/division by 2 in binary form is simple bit shifting so if you put it all together you get code for exp2 similar to my. log2 is based on changing the result bits from MSB to LSB until it matches searched value (very similar algorithm as for fast sqrt computation). hope this helps clarify things...