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I have a function that takes an input vector of length k, where each element in the vector can take up to n values.

Generally k will be in the range 6:10, and n in the range 2:(k-1).

For any given (n,k) there will be n^k-1 permutations of possible vectors.

Currently I am mapping each of the integers 0:(n^k-1) to a unique permutation and evaluating the function at that permutation to find the optimal input vector over all possible vectors.

For example, with n=3 and k=6 the mapping would be:

0:1,1,1,1,1,1
1:1,1,1,1,1,2
2:1,1,1,1,1,3 
3:1,1,1,1,2,1
...
728:3,3,3,3,3,3

However, for my purpose some of the permutations are equivalent. You can think of the vector as an allocation of k elements among n classes.

Two permutations A and B are equivalent if the following both hold:

  1. All elements in A that share a class, also share a class in B.
  2. All elements in A that do not share a class, also do not share a class in B.

For example: With n=2 and k=6, the vectors

1,2,1,1,2,1 
2,1,2,2,1,2 

are equivalent. In both vectors, elements {1,3,4,6} share a class and elements {2,5} share a class.

With n=3 and k=6, the vectors

1,2,3,1,2,3
1,3,2,1,3,2
2,3,1,2,3,1
2,1,3,2,1,3
3,2,1,3,2,1
3,1,2,3,1,2 

are all equivalent.

My aim is to find a more efficient way of finding the optimal vector than trying every input in the range 1:(n^k-1).

I can see two possible ways forward:

Option 1. Enumerate every possibility and then filter out all the equivalent vectors.

Option 2: Reduce the range I need to check in advance. For example, for n=3, k=6, I am fairly confident (but haven't proven) that I won't need to check anything above 161:1,2,3,3,3,3 and there should be some equivalent permutations within the range 1:161 as well.

I much prefer Option 2.

The ideal solution is a function of (n,k) that outputs a list of vectors representing the intervals in 1:n^k-1 that I need to check. Almost as good would be a function of (n,k) that outputs the largest integer/vector in 1:n^k-1 that I need to check.

As a starting point, here is some sample R code:

vectorFromID <- function(id, n, k) {
  if(id >= n^k) {
    stop('ID too large!')
  }
  remainder <- id
  elements <- list()
  for(i in (k-1):0) {
    elements[[k-i]] <- (remainder  %/% (n ^ i))+1
    remainder <- remainder %% (n ^ i)
  }
  return(unlist(elements))
}

vectorToID <- function(inputVector, n, k) {
  total <- 0
  for(i in 0:(k-1)) {
    total <- total + (inputVector[i+1]-1) * (n ^ ((k-1)-i))
  }
  return(total)
}

# generate all possible vectors for n=3, k=6
all_vectors <- Map(function(x) vectorFromID(x, 3, 6), 0:728)

Edited to add an R implementation of the recursive solution, and benchmarking of the two solutions.

enum <- function(v=NULL, n, k, maxv=0) {
  if (k == 0) {
    return(list(v))
  } else {
    acc <- list()
    for (i in 1:min(n, maxv+1)) {
      acc <- c(acc, enum(c(v,i), n, k-1, max(i,maxv)))
    }
    return(acc)
  }
}
res2 <- enum(NULL, 3, 6, 0)

Both solutions produce equivalent output, but for larger values of k & n the recursive solution is much faster. Below, time1 refers to the time in seconds the recursive solution takes.

n: 2 k: 6 rows1: 32 rows2: 32 match: TRUE time1: 0.02 time2: 0.05
n: 3 k: 6 rows1: 122 rows2: 122 match: TRUE time1: 0 time2: 0.51
n: 4 k: 6 rows1: 187 rows2: 187 match: TRUE time1: 0.01 time2: 3.32
n: 5 k: 6 rows1: 202 rows2: 202 match: TRUE time1: 0 time2: 16.8
n: 2 k: 7 rows1: 64 rows2: 64 match: TRUE time1: 0.02 time2: 0.11
n: 3 k: 7 rows1: 365 rows2: 365 match: TRUE time1: 0 time2: 1.83
n: 4 k: 7 rows1: 715 rows2: 715 match: TRUE time1: 0.05 time2: 19.62
n: 5 k: 7 rows1: 855 rows2: 855 match: TRUE time1: 0.04 time2: 277.81
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    I'm not sure how you have done your comparison, but I find that these two methods do not give the same results. The method that I proposed results in far more unique combinations than the other method(e.g. n=5,k=7 has 4875 unique, not 855; n=3,k=6 has 162 unique, not 122). – Marc in the box Jan 15 '15 at 12:13
  • Your solution as written produces a data frame with 122 rows, but the labels go up to 162. Try comparing rownames(res) vs nrow(res). – logworthy Jan 15 '15 at 22:06
  • You're right - my apologies. The algorithm from @deniss is quite interesting - I haven't seen a function before that uses itself in a loop. – Marc in the box Jan 16 '15 at 4:41
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Lets first choose a representative for each equivalence class. Lets say that vector p = {x_1 ... x_k} is a representative if it is lexicographical minimum from all p_i such that p_i ~ p.

Notice that x_i is in range (1..x_j + 1) forall j < i. If that doesn't hold, then we can construct equivalent p_i which is less than p lexicographically. (x_1 = 1 for the same reason)

Also, if for each i, x_i is in range (1..x_j + 1), then p is a representative. Otherwise there is some q = {y_1 ... y_n}, such that for some k, y_i = x_i for all i < k and y_k < x_k. But for that k all values from (1..max(x_i)) are in the first k-1 elements of p. So it is y_k. But that proves p is not equivalent to q.

So p is a representative iff x_i is in range (1..x_j + 1) forall j < i. Then we can derive all such representatives with a simple recursive procedure. Sorry for my code example is in C++, I don't know R:

void printResult(std::vector<int>& v){
    for (auto val : v){
        std::cout << val << ' ';
    }
    std::cout << '\n';
}

void enumerate(std::vector<int>& v, int n, int k, int max){
    if (k == 0){
        printResult(v);
    } else {
        for (int i = 1; i <= std::min(n, max + 1); i++){
            v.push_back(i);
            enumerate(v, n, k - 1, std::max(i, max));
            v.pop_back();
        }
    }
}

void solve(int n, int k){
    std::vector<int> v;
    enumerate(v, n, k, 0);
}
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I haven't tested this completely, but I think it gets you what you want. I have three main steps:

  1. Apply expand.grid to supply all possibly permutations of n and k.
  2. Turn values into factors, with levels based on the order of appearance. Then, turn these back into a numeric value (in the loop). e.g. c(1,2,3,1,2,3) and c(3,2,1,3,2,1) would be returned as c(1,2,3,1,2,3) and c(1,2,3,1,2,3) (i.e. equivalent) due to the similar order of factor levels.
  3. Return only unique combinations. With n=3 and k=6, the number of unique combinations is reduced from 729 to 162:

Function combnmix:

combnmix <- function(n,k){
  tmp <- lapply(as.list(rep(n, k)), seq)
  res1 <- expand.grid(tmp)
  res2 <- NaN*res1
  for(i in seq(nrow(res1))){
    levs <- unique(c(res1[i,]))
    res2[i,] <- as.numeric(factor(res1[i,], levels=levs))
  }
  res3 <- unique(res2)
  res3
}

res <- combnmix(3,6)
res

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