There is a family of combinatorial algorithms, based on following technique - we observe some property of the structure and, using that property, traversing then all possible/accessible variants in linear (or closed to, whatever, doesn't really matters) time, without recursion.
lexicographic permutation a1 .. a[n]
- find last a[k] such that a[k] < a[k + 1] > ...
- find the minimal a[m] in a[k + 1] .. a[n] such that a[k] < a[m]
- swap a[m] and a[k]
- revert a[k + 1] .. a[n]
k-subsets of n
- iterate from the end, find first zero, preceded by 1 (first a[k]==0 such that a[k + 1] == 1)
- assign a[k] = 1
- count 1's in a[k] .. a[n]
- rebalance - assign as much 1's at the end as it possible, the rest set to zero
partitions of n (in descending order)
- find first k such that a[k] > a[k + 1] (k = 1 also is ok)
- increase a[k] = a[k] + 1
- find sum of elements from k to the last one
- increase left neighbors by 1 as long as sum allows.
I guess, this is enough to illustrate the nature of such algorithms. These, and some other examples can be found in excellent, superb book "Algorithms and Programming: Problems and Solutions".
My question is following. Can you, please, describe me more examples, in any area, of such algorithms. It would bee great if you also provide the algorithm itself (in words, like above, is preferable). References to the books, articles are also welcome. References to related theoretical issues are also welcome (for example, I just don't have a feeling when such algorithms can be builded and when - not).
Thanks in advance.