# C++ Big Integer

I'm trying to implement a BigInteger Class in C++. But, first of all, I've a base question, how the "base data" can be represented? For example, the most stupid way is to have a fixed (or dynamic) array of char and store each single number of an integer in a char. But, ok, this is a very stupid way, and I'm here for your suggestions.

Thanks.

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possible duplicate of How to implement big int in C++ – darioo Dec 22 '10 at 7:45

There are a bunch of suggestions here for existing implementations: C++ handling very large integers

If you have to implement your own (e.g. for homework), then you have to decide the best way, and how "big" you need to handle. You could use an array of DWORDs, and handle overflowing from one to the next.

Although, for some of the Project Euler stuff, I actually implemented a BigNumber class built on a string. It turned out to be the simplest to implement for +-*/, and scaled to significantly longer numbers than I could get with a few unsigned long longs. And the performance was perfectly adequate for solving those puzzles.

So, you face a tradeoff between ease of implementation and optimal performance. Have fun ;-)

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You can create a big integer in exactly the way you describe. In fact, the first time I implemented such a class, that's exactly the way I did it. It helped me implement the arithmetic operations (+, -, etc) since it was in the base (10) that I was used to.

A natural enhancement to your "array of chars" is to keep it in base 10, but use 4 bits for the digit, instead of the whole byte. Thus, the number 123,456 might be represented by the bytes 12 34 56 instead of the string 123456. (Three bytes as opposed to six.)

From there, you could make the storage for the number in base two. The basic arithmetic operations such as addition work exactly the same in base 2 as they do in base 10. Thus, the number 65565 could be stored using the bytes FF FF. (In a vector of unsigned chars, for example.) Some implementations of BigInts use larger chunks, such as short or long, for efficiency.

Base-10 big ints can be useful if you're doing a lot of displaying and/or serializing to base-10, and want to avoid the conversion to base-2.

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