Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

How can you compute a shortest addition chain (sac) for an arbitrary n <= 600 within one second?


This is the programming competition on codility for this month.

Addition chains are numerically very important, since they are the most economical way to compute x^n (by consecutive multiplications).

Knuth's Art of Computer Programming, Volume 2, Seminumerical Algorithms has a nice introduction to addition chains and some interesting properties, but I didn't find anything that enabled me to fulfill the strict performance requirements.

What I've tried (spoiler alert)

Firstly, I constructed a (highly branching) tree (with the start 1-> 2 -> ( 3 -> ..., 4 -> ...)) such that for each node n, the path from the root to n is a sac for n. But for values >400, the runtime is about the same as for making a coffee.

Then I used that program to find some useful properties for reducing the search space. With that, I'm able to build all solutions up to 600 while making a coffee. But for n, I need to compute all solutions up to n. Unfortunately, codility measures the class initialization's runtime, too...

Since the problem is probably NP-hard, I ended up hard-coding a lookup table. But since codility asked to construct the sac, I don't know if they had a lookup table in mind, so I feel dirty and like a cheater. Hence this question.


If you think a hard-coded, full lookup table is the way to go, can you give an argument why you think a full computation/partly computed solutions/heuristics won't work?

share|improve this question
Are you explicitly asked not to build a lookup table ? It is a valid solution to a problem. – ScarletAmaranth Apr 13 '12 at 11:41
I would also opt for a lookup. More like ruse de guerre than a dirty cheater... – Anonymous Apr 13 '12 at 11:42
Ok, then problem's solved ;) Although I find codility's wording misleading - I'm not constructing a sac, I'm merely looking it up... – DaveFar Apr 13 '12 at 11:46
The one-second limit is absurdly high just to look up into a table with 600 entries. Either you're missing something, or they are ;-) – Steve Jessop Apr 13 '12 at 12:57
A hard-coded lookup table seems a bit .. cheap. – harold Apr 13 '12 at 13:01
up vote 4 down vote accepted

I have just got my Golden Certificate for this problem. I will not provide a full solution because the problem is still available on the site.I will instead give you some hints:

  1. You might consider doing a deep-first search.
  2. There exists a minimal star-chain for each n < 12509
  3. You need to know how prune your search space.
  4. You need a good lower bound for the length of the chain you are looking for.
  5. Remember that you need just one solution, not all.

Good luck.

share|improve this answer
Thanks for the advice, slvr (+1). I used much stronger properties than star-chain - did you follow my link to math.stackexchange? I did use dynamic programming, though, and thought a DFS would not be able to find a solution quickly because there are relatively few SHORTEST addition chains. So now I know I did cheat for my Golden Certificate and have a nice task for my Sunday morning :) – DaveFar Apr 21 '12 at 21:08
I did read what you wrote on Dynamic-programming, uh? Interesting. With DFS the upper bound for the running time was 80ms on a i5-2400. – slvr Apr 21 '12 at 22:36

Addition chains are numerically very important, since they are the most economical way to compute x^n (by consecutive multiplications).

This is not true. They are not always the most economical way to compute x^n. Graham et. all proved that:

If each step in addition chain is assigned a cost equal to the product of the numbers at that step, "binary" addition chains are shown to minimize the cost.

Situation changes dramatically when we compute x^n (mod m), which is a common case, for example in cryptography.

Now, to answer your question. Apart from hard-coding a table with answers, you could try a Brauer chain.

A Brauer chain (aka star-chain) is an addition chain where each new element is formed as the sum of the previous element and some element (possibly the same). Brauer chain is a sac for n < 12509. Quoting Daniel. J. Bernstein:

Brauer's algorithm is often called "the left-to-right 2^k-ary method", or simply "2^k-ary method". It is extremely popular. It is easy to implement; constructing the chain for n is a simple matter of inspecting the bits of n. It does not require much storage.

BTW. Does anybody know a decent C/C++ implementation of Brauer's chain computation? I'm working partially on a comparison of exponentiation times using binary and Brauer's chains for both cases: x^n and x^n (mod m).

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

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