# How to convert a double to its' binary form in Arithmetic Coding?

I am doing Arithmetic Coding now, and I have got the final start position and distance, then I add them. How can I convert the result to binary mode?

For example, how can I convert `0.125 decimal` to `0.001 binary` in C++?

``````void CArithmeticCoding::Encode()
{
if ( 0 == m_input )
return;
printf("The input is [%s].\n", this->m_input);

while (*m_input)
{
if ( *m_input == m_MPS )
{
DOMPS();
}
else
{
DOLPS();
}
++m_input;
}
double ret = m_start + m_dis;

return;
}
``````
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Converting anything to binary means finding out how many of each kind of power of 2 is involved. In the case of a decimal number, the powers involved are negative.

For `.125`, the sequence is like this:

``````.125 x 2 =  .250 (< 1)
.250 x 2 =  .500 (< 1)
.500 x 2 = 1.000 (>= 1)
.000     = 0     done
``````

So, the binary representation is `0`x`2^-1` + `0`x`2^-2` + `1`x`2^-3` = `.001` binary. As an exercise, contrast this technique with converting a normal integer into binary representation.

Just as regular decimals can have non-terminating patterns (like 1/3 or pi/4), the same can happen for the binary representations. In those cases, you have to stop the calculation when you reach your desired precision.

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As an exercise, try converting 1/3 ;) –  Mare Infinitus Jun 12 '12 at 8:45
@MareInfinitus: ;-) Thanks for the input, answer is updated. –  jxh Jun 12 '12 at 8:48
no problem. besides there are lots of example implementations of IEEE 754 around, if you just now what to search for ; –  Mare Infinitus Jun 12 '12 at 9:30

Arithmetic coding is done with integer data types for efficiency and predicability. There are no advantages and only disadvantages to using floating point types. You can simply consider the integer of n bits to be an n-bit fraction. As you take bits off the top, you renormalize the fraction to use those bits.

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You should investigate IEEE 754

This is the standard for binary representation of floating point formats, both single and double precision

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