Sign up ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

For my algorithms class we are required to write a bottoms-up minimal-change algorithm.

As an example output our professor provided us with

1234     2314     3124
1243     2341     3142
1423     2431     3412
4123     4231     4312
4132     4213     4321
1432     2413     3421
1342     2143     3241
1324     2134     3214

Notice that it generates 24 permutations (6 for each digit). The permutations for 4 (as in, 4 being the first number in a permutation) are a byproduct from the other calls in that algorithm. You can also see that at most only 2 numbers every switch positions.

I've been struggling to find a good pattern within those numbers to base my code on. So I was thinking of taking a slightly different approach to the problem.

If I take the factorial of n I can calculate the number of permutations. By dividing the number of permutations by n I get the number of times each digit is in each respective position (i.e. how many permutations start with each number). Dividing the subsequent result by n-1 I get the number of times each second digit will occur, given the first digit remains the same. So on and so forth (with n being decreased by one every time) until all digits have been exhausted.

As an example, assume that n=4

4! = 24
24/4 = 6
6/3 = 2
2/2 = 1

Using these results I can generate permutations vertically, not horizontally.

Instead taking a number and sliding it back and forth over the other numbers and doing swaps every so often I would instead generate a table that is nxn! in dimension. Then, going down the columns fill in the first column with 6 ones, 6 twos, 6 threes, 6 fours, and 6 fives.

When I get to second column each number would be put in twp times, and then repeated until the end of the array is reached. Subsequently, each column would follow a similar pattern. This pattern would work with any sized n input.

My output would be this:

1234    2134    3124    4123
1243    2143    3142    4132
1324    2314    3214    4213
1342    2341    3241    4231
1423    2413    3421    4312
1432    2431    3412    4321

Now my question is... is this still considered a minimal-change algorithm?

My algorithm works more in lexicographical order, and that worries me that it may not be considered a minimal-change algorithm (because during certain steps more than one number seems 'swapped', though in reality no swapping is being done).

share|improve this question
I encountered something like this in a project euler problem. I had to use factoradics to give a proper ordering to the permutations. With that, you could arrange them however you want. –  Caleb Jares Dec 6 '11 at 2:07
Are you saying that I could use my technique, and reorder my output to match his? –  Johannes Dec 6 '11 at 2:11
No, it's not a minimum-change algorithm. –  Per Dec 6 '11 at 3:12
The only thing I can find on minimal change algorithms is the Johnson-Trotter algorithm on the Permutations Wikipedia page. Now I know I'm not the right person to answer this question, but I'm kind of interested. Can you point me towards some more info on this type of algorithm? –  Caleb Jares Dec 6 '11 at 15:48
It's funny that you mention it because I also had to create a Johnson-Trotter algorithm in C#. The best information I've gotten is from a a book called "Introduction to the Design and Analysis of Algoirthms" by Anany Levitin. It's a college-level textbook. If you look hard enough you can find it for real cheap (I bought an international edition for $25). And honestly some stuff in that book doesn't even seem to appear on google, so they have some real specialized stuff. Personally, I find algorithms to be tough and challenging, but a lot of fun! –  Johannes Dec 7 '11 at 18:31

1 Answer 1

up vote 0 down vote accepted

No, it's not a minimum-change algorithm—the requirement is that each adjacent pair of permutations in the output differ by one swap.

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.