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Does the difficulty of a strongly NP-hard or NP-complete problem (as e.g. defined here http://en.wikipedia.org/wiki/Strongly_NP-complete) change when its input is unary instead of binary encoded?

What difference does it make if the input of a strongly NP-hard problem is unary encoded? I mean, if I take for instance the weakly NP-complete Knapsack problem, it is NP-complete when binary encoded but can be solved in polynomial time by dynamic programming when unary encoded.

Does the notion of strongly ...-hard also hold for other complexity classes, e.g. higher classes of the polynomial time hierarchy?

Thanks for any help.

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closed as off topic by templatetypedef, rici, Tuxdude, Troy Alford, barrowc Mar 17 '13 at 1:24

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Encoding doesn't change the problem itself, just the representation of the problem statement. With that said, this is more a CS question than a programming one. Check out Computer Science. –  cHao Mar 16 '13 at 20:50
@cHao, unary encoding does make a difference. However, you are right that this question would probably receive better answers on cs.stackexchange.com. –  rici Mar 16 '13 at 22:07
Thanks for pointing this out, I didn't notice that there were different forums for programming and CS. I will post it on cs.stackexchange.com then. –  user2145167 Mar 16 '13 at 22:55
Here is the question on cs.stackexchange for those who want to follow the answers: cs.stackexchange.com/q/10563/3011 –  Paresh Mar 17 '13 at 9:15
I just noticed, maybe cstheory.stackexchange.com/ would have been an even better place to ask this question? –  user2145167 Mar 17 '13 at 11:41

2 Answers 2

Complexity always depends on what you measure against, since the Landau symbol is based on some function of the input or output. (The latter turns out to be much more useful sometimes - for example, if you perform polynomial division, your runtime cannot be bound by input length, since (x^n-1)/(x-1) can become arbitrarily long if n gets large.)

By switching to unary encoding, you might argue that now your input length is much larger than in some n-ary encoding. In that sense, yes, it could happen. But that's not useful, in the same sense that, e.g., in the discussion about integer multiplication algorithms, it's not really useful to talk about complexity in the integers themselves - it is simply customary to consider the complexity in the logarithm of these integers, i.e., in the number of digits they have in some non-unary base.

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There is a qualitative difference between unary and base b>1 encodings. In unary encoding, the size of the inputs is polynomial in the size of the problem. In b>1 encoding, the size of the inputs is exponential in the size of the problem. That can and does make a difference, and, yes, it is sometimes an important difference. Read the referenced wikipedia page for more information. –  rici Mar 16 '13 at 22:06

I don't think you understand what complexity is referring to. Suppose you need to sum some elements:

(this sample is C but that doesn't matter)

int Sum( int *x, int n ) {
    int r = 0;
    for( int i = 0; i < n; ++ i ) {
        r += x[i];
    return r;

This has O(n) complexity. Nothing has been said about the encoding. It could be unary, binary, or trinary, but if we're interested in that aspect, we could say it is O(log_b(m)) where b is the base and m is the maximum number representable. Or we could combine these and say it's O(n*log_b(m))

But usually nobody cares about the complexity of adding numbers together or whatnot, so we just omit it. It's constant. It doesn't matter. The algorithm above has O(n) complexity, because n is an interesting parameter. And if something's O(n^2) or O(log(n)) or anything else, changing b (the base) won't ever change that.


To factor in some of the comments this has been getting, I think I should mention the case of m itself changing:

Suppose we have a factorial function:

int Factorial( int n ) {
    int r = 1;
    for( int i = 1; i <= n; ++ i ) {
        r *= i;
    return r;

Now we can say that m (the maximum representable number) can be equal to n. Thus the complexity, which is O(n) and O(log_b(m)) (each multiplication stage must loop through the entire represented number), so O(n*log_b(m)) can be seen as O(n*log_b(n)). HOWEVER, this relies on the idea that our input number does not have a fixed number of significant figures, but instead is the shortest representation within the current base.

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Your last statement is only true for bases b >= 2. Switching to unary notation can change the complexity class of problems because the input size is exponentially larger than in any other base. –  nwellnhof Mar 16 '13 at 21:24
@nwellnhof Actually it is correct. Besides, base 2 is exponentially larger than base 3, etc. You seem to have missed the point: changing b will never change the complexity when we're writing the complexity in terms of n. No matter what. End of story. –  Dave Mar 16 '13 at 21:39
That might be true for many practical cases. But for some problems like integer factorization we are interested in the complexity in terms of the size of n. So I wouldn't brush off the question. –  nwellnhof Mar 16 '13 at 21:54
You should read that wikipedia page. It (correctly) says that the 0-1 knapsack problem is polynomial time if the input is encoded in unary; i.e., it is only NP-complete if input values are exponential in the size of the problem. –  rici Mar 16 '13 at 22:04
@nwellnhof That's still not the point. n and b are independent. If the algorithm is O(n^2) and O(b), we can also say it's O(n^2*b). But no matter what we do to b it will never be anything other than O(n^2). It can't become O(n) or O(log(n)). Sure, you can say you care about the complexity relative to b, but that's a different complexity. –  Dave Mar 16 '13 at 22:05

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