Knuth's "The Art of Computer Programming" Vol 2. is an excellent reference for arbitrary precision arithmetic.

A simple way to get a base 10 representation is to continously divide your number by 10, each division extracts one digit (the remainder). This obviously requires being able to divide by 10 in whatever base you already have.

For example, if your number is 321 decimal or 101000001 binary, we can divide:

10100001 binary by 1010 binary

100000 with remainder 1 (so first digit is 1 decimal)

divide 100000 by 1010 binary

11 with remainder 10 (so next digit is 2 decimal)

divide 11 by 1010 binary

0 with remainder 11 (so last digit is 3 decimal)

According to: http://people.cis.ksu.edu/~rhowell/calculator/comparison.html this is the radix conversion algorithm used in Sun's Java BigInteger class and is O(n^2) complexity. The authors in this link have implemented an O(n logn) algorithm based on an algorithm described in Knuth p. 592 and credited to A. Shönhage.

first, then implement binary-to-decimal conversion on top of the fundamental arithmetic. – Steve Jessop Jan 24 '11 at 0:29`vector`

element isn't a very efficient way to implement big integers. – dan04 Jan 24 '11 at 0:31