# how do I convert fractional decimal numbers to fractional binary numbers using dc

So dc is a great tool for converting between bases - handy for those bit twiddling coding jobs. e.g to convert 1078 into binary I can do this:

``````bash> echo "2o1078p" | dc
10000110110
``````

However I can't get it to print fractions between 0 and 1 correctly. Trying to convert 0.3 into binary:

``````bash> echo "2o10k 0.3p" | dc
.0100
``````

But 0.0100(bin) = 0.25 not 0.3.

However if I construct the value manually I get the right answer

``````bash> echo "2o10k 3 10 / p" | dc
.0100110011001100110011001100110011
``````

Well it looks like its giving me more than the 10 significant figures I ask for but thats OK

Am I doing something wrong? Or am I trying to make dc do something that its not able to do?

``````bash> dc --version
dc (GNU bc 1.06) 1.3
...
``````
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A quick look at the source shows that there are no radix tests as part of 1.06 and that it attempts to meet the POSIX dc definition which is likely pessimistic. Given how wrong 1t gets `3/10` I wouldn't trust it at all for these computations. – msw Aug 28 '10 at 4:57
Instead of echoing the expression into a pipe, the preferred way is to just use the expression parameter of dc, e.g. `dc -e "2o10k 3 10 / p"` – FloHimself Sep 30 '14 at 7:17

Strange. My first thought was that maybe precision only applies to calculations, not conversions. But then it only works for division, not addition, subtraction, or multiplication:

echo "2o10k 0.3 1 / p" | dc

.0100110011001100110011001100110011

echo "2o10k 0.3 0 + p" | dc

.0100

echo "2o10k 0.3 0 - p" | dc

.0100

echo "2o10k 0.3 1 * p" | dc

.0100

As for precision, the man page says "The precision is always measured in decimal digits, regardless of the current input or output radix." That explains why the output (when you get it) is 33 significant bits.

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Interestingly "2o10k 0.3000 p" works OK too .. so something funny is going on with number of s.f. when in a base other than 10. – Michael Anderson Aug 29 '10 at 1:06

It seems that dc is getting the number of significant figures from the input.

Now `1/log10(2)=3.32` so each decimal significant digit is 3.3 binary digits. Looking at the output of dc for varying input SF lengths shows:

```````dc -e "2o10k 0.3 p"` => .0100
`dc -e "2o10k 0.30 p"` => .0100110
`dc -e "2o10k 0.300 p"` => .0100110011
`dc -e "2o10k 0.3000 p"` => .01001100110011
``````

A table of these values and expected value, `ceil(log10(2)*SFinput)` is as follows:

``````input : output : expected output
1     : 4      : 4
2     : 7      : 7
3     : 10     : 10
4     : 14     : 14
``````

And dc is behaving exactly as expected.

So the solution is to either use the right number of significant figures in the input, or the division form `dc -e "2o10k 3 10 / p"`

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