# Print the integral value of a very long binary representation

Let's say you have a very long binary-word (>64bit), which represents an unsigned integral value, and you would like to print the actual number. We're talking C++, so let's assume you start off with a bool[ ] or std::vector<bool> or a std::bitset, and end up with a std::string or some kind of std::ostream - whatever your solution prefers. But please only use the core-language and STL.

Now, i suspected, you must evaluate it chunkwise, to have some intermediate results, that are small enough to store away - preferably base 10, as in x·10k. I could figure out to assemble the number from that point. But since there is no chunk-width that corresponds to the base of 10, I don't know how to do it. Of course, you can start with any other chunk-width, let's say 3, to get intermediates in the form of x·(23)k, and then convert it to base 10, but this will lead to x·103·k·lg2 which obviously has a floating-point exponent, that isn't of any help.

Anyway, I'm exhausted of this math-crap and I would appreciate a thoughtful suggestion.

Yours sincerely,
Armin

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Search Stack Overflow for "binary to decimal conversion" or similar. But note that in general, every decimal digit is dependent on every binary digit. –  Oli Charlesworth Jan 4 '13 at 20:18
This problem is so much harder than you'd think. I'd say use a bignum library for the task, or give up. Otherwise, you have to implement and do lots and lots of bidnum division and modulo to get the answer. Is rounding allowed? If rounding is allowed, then it's easy to convert it to a `double`. –  Mooing Duck Jan 4 '13 at 20:24
Another option is to forget base 10, and simply print as hex, or base64, both of which are trivial. –  Mooing Duck Jan 4 '13 at 20:27
@AK4749, MooingDuck: Conceptually, this isn't very hard (see e.g. my answer here). Once you've defined a `bignum` class and defined some arithmetic overloads for it, the code almost writes itself. Doing it efficiently, however, is more challenging... –  Oli Charlesworth Jan 4 '13 at 20:31
@AK4749: See also en.wikipedia.org/wiki/Double_dabble. –  Oli Charlesworth Jan 4 '13 at 20:35

I'm going to assume you already have some sort of bignum division/modulo function to work with, because implementing such a thing is a complete nightmare.

``````class bignum {
public:
bignum(unsigned value=0);
bignum(const bignum& rhs);
bignum(bignum&& rhs);
void divide(const bignum& denominator, bignum& out_modulo);
explicit operator bool();
explicit operator unsigned();
};

std::ostream& operator<<(std::ostream& out, bignum value) {
std::string backwards;
bignum remainder;
do {
value.divide(10, remainder);
backwards.push_back(unsigned(remainder)+'0');
}while(value);
std::copy(backwards.rbegin(), backwards.rend(), std::ostream_iterator(out));
return out;
}
``````

If rounding is an option, it should be fairly trivial to convert most bignums to `double` as well, which would be a LOT faster. Namely, copy the 64 most significant bits to an `unsigned long`, convert that to a `double`, and then multiply by 2.0 to the power of the number of significant bits minus 64. (I say significant bits, because you have to skip any leading zeros)
So if you have 150 significant bits, copy the top 64 into an `unsigned long`, convert that to a `double`, and multiply that by `std::pow(2.0, 150-64)` ~ 7.73e+25 to get the result. If you only have 40 significant bits, pad with zeros on the right it still works. copy the 40 bits to the MSB of an `unsigned long`, convert that to a `double`, and multiply that by `std::pow(2.0, 40-64)` ~ 5.96e-8 to get the result!

# Edit

Oli Charlesworth posted a link to the wikipedia page on Double Dabble which blows the first algorithm I showed out of the water. Don't I feel silly.

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+1 because you speak from experience. –  Seth Carnegie Jan 4 '13 at 20:50
-1. You don't need all this. Certainly not division. –  n.m. Jan 4 '13 at 20:58
@SethCarnegie: Though I speak from experience, that does not mean wisdon. Oli Charlesworth posted a link on how to do it in linear time rather than my crazy slow method. –  Mooing Duck Jan 4 '13 at 21:02
@MooingDuck: I basically have a bignum class and I implemented most of the arithmetic operations - except for division and modulo. If I understand your rounding-approach correctly, it's an approximation of the result, not an approximation of the intermediates that magically end up in the precise integral result, as I thought. So it's a solution to keep in mind if anything other fails. To try out your remainder-example, I will have to wait until I implemented modulo and division. But thanks for your contribution. –  armin tamzarian Jan 4 '13 at 21:10
@armintamzarian: Seriously, ignore everything I wrote here about division and look up Double Dabble. –  Mooing Duck Jan 4 '13 at 21:11