If this is a genuine problem, there are plenty of BigNum libraries out there to assist, such as the MPIR library.

If it's something where you *can't* use a third-party library, it's still relatively easy. You don't actually *need* a complex BigNum library for this, you only need one operation: divide by two.

Here's how you do it. Start with an empty stack of binary digits. Then loop until the number is "0" (yes, that's still a string). If the last digit of the number is odd, push 1 on to the stack, otherwise push 0. Then divide the number by two and restart the loop.

Once the loop is finished (number is "0"), pop the digits off the stack one at a time and print them. There you go.

Oh, yeah, the divide-by-two, that *is* a rather important piece of the puzzle :-)

Let's start with "12345". Here's the process you follow, in pseudo-code.

```
Set next_additive to 0.
For every digit in number (starting at the left):
Set additive to next_additive.
If the digit is odd, set next_additive to 5, else set it to 0.
Divide the digit by two (and truncate if necessary).
Remove leading zero if necessary (if it starts with 0 but is not just 0).
```

This can be done by processing the actual string one character at a time.

Starting with `1`

(from `12345`

), additive is `0`

, number is odd, so next_additive is `5`

. Divide `1`

by `2`

and add additive of `0`

, you get `0`

: `02345`

.

Next digit `2`

, additive is `5`

, number is even, so next_additive is `0`

. Divide `2`

by `2`

and add additive of `5`

, you get `6`

: `06345`

.

Next digit `3`

, additive is `0`

, number is odd, so next_additive is `5`

. Divide `3`

by `2`

and add additive of `0`

, you get `1`

: `06145`

.

Next digit `4`

, additive is `5`

, number is even, so next_additive is `0`

. Divide `4`

by `2`

and add additive of `5`

, you get `7`

: `06175`

.

Next digit `5`

, additive is `0`

, number is odd, so next_additive is `5`

. Divide `5`

by `2`

and add additive of `0`

, you get `2`

: `06172`

.

Strip off leading zeros: `6172`

. Ignore the next additive since you're truncating the result.

And there you have it: `12345 / 2 = 6172`

.

By way of example, here's a Python approach to implementing this algorithm as follows. First the support routines for checking if a number is odd and for dividing it by two:

```
def isOdd (s):
if s.endswith("1"): return True
if s.endswith("3"): return True
if s.endswith("5"): return True
if s.endswith("7"): return True
if s.endswith("9"): return True
return False
def divByTwo (s):
new_s = ""
next_add = 0
for ch in s:
add = next_add
if isOdd (ch):
next_add = 5
else:
next_add = 0
new_ch = chr ((ord (ch) - ord ('0')) / 2 + add + ord ('0'))
new_s = "%s%s"%(new_s,new_ch)
if new_s != "0":
if new_s[:1] == "0":
new_s = new_s[1:]
return new_s
```

Then the actual code to make a binary string from the decimal string:

```
num = "12345"
stack = ""
print num
while num != "0":
if isOdd (num):
stack = "1%s"%(stack)
else:
stack = "0%s"%(stack)
num = divByTwo (num)
print stack
```

Note that if you wanted to actually use this to populate real bits (rather than make a string of bits), it's a simple matter to change what happens in the `if`

statement.

It's probably not the most efficient Python code you could come up with but it's simply meant to show the process, not be some well-engineered production-ready piece of code. The output is (with some added stuff below to show what's going on):

```
12345
11000000111001
|| ||| |
|| ||| +- 1
|| ||+---- 8
|| |+----- 16
|| +------ 32
|+------------- 4096
+-------------- 8192
=====
12345
```

that you stated. For a start, it returns an`int`

... and the there's no way that`10^1000`

fits in an`int`

. – Stephen C Jun 13 '12 at 7:44