5

I need to implement RSA algorithm in Java. I've found the best solution using BigIntegers, problem is that I need to work only with ints or longs. The encrypting is done like this: M[i]^e mod n where M[i] is an input char and e is a key value. I tried using the ASCII codes of chars, and with codes such as 115 and 116 I quickly get out of range. How can I solve the problem? Thanks in advance.

9
  • 4
    "I need to work only with ints or longs" why this restriction?
    – Howard
    May 21, 2011 at 7:21
  • Similar question: stackoverflow.com/questions/5433992/… May 21, 2011 at 7:23
  • 1
    If n<2^32 using longs is easy(i^2 won't overflow since i<n and n^n<2^64). Else you probably need to use int/long arrays. You just need to implement one operation: ModPow. For example using the square-and-multiply algorithm. May 21, 2011 at 7:26
  • 1
    @Egor then please add the homework tag.
    – Howard
    May 21, 2011 at 7:30
  • 2
    @Egor: Yes reimplementing the wheel is painful, and basically pointless (in and of itself)... but I'm one of the "old school" who believes that ALL professional programmers need a grounding in "the low-level stuff". Quite often it is low-level considerations which determine the high level posibilities, regardless of whether or not you're using a "high level" language. For an illuminating (and ammusing) essay on this topic see Back To Basics (Schlemiel the Painter's algorithm). Cheers. Keith.
    – corlettk
    May 21, 2011 at 8:22

2 Answers 2

4

You may have a look at modular exponentiation. This way you overcome most of the overflows in your calculations.

0
1

To clarify a bit...

(a * b) mod m == ((a mod m) * (b mod m)) mod m

If you recall from basic math,

a ^ 10 = (a ^ 5) * (a ^ 5)

So, you can split your crazy high powers into lower powers and then take the modulo of their value (thereby keeping the value small), and then recombine them afterwards:

Too Big!         = Just Right!
(2 ^ 20) mod 113 = (((2 ^ 10) mod 113) * ((2 ^ 10) mod 113)) mod 113

I don't know if this counts as "giving it away" but my students had trouble with this once and I had no problem showing them this trick. Besides, I presume this is more of an exercise in recursion than anything else.

0

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.