I am trying to write an efficient ranking algorithm in C++ but I will present my case in R as it is far easier to understand this way.

```
> samples_x <- c(4, 10, 9, 2, NA, 3, 7, 1, NA, 8)
> samples_y <- c(5, 7, 9, NA, 1, 4, NA, 8, 2, 10)
> orders_x <- order(samples_x)
> orders_y <- order(samples_y)
> cbind(samples_x, orders_x, samples_y, orders_y)
samples_x orders_x samples_y orders_y
[1,] 4 8 5 5
[2,] 10 4 7 9
[3,] 9 6 9 6
[4,] 2 1 NA 1
[5,] NA 7 1 2
[6,] 3 10 4 8
[7,] 7 3 NA 3
[8,] 1 2 8 10
[9,] NA 5 2 4
[10,] 8 9 10 7
```

Suppose the above is already precomputed. Performing a simple ranking on each of the sample sets takes linear time complexity (the result is much like the `rank`

function):

```
> ranks_x <- rep(0, length(samples_x))
> for (i in 1:length(samples_x)) ranks_x[orders_x[i]] <- i
```

For a work project I am working on, it would be useful for me to emulate the following behaviour in linear time complexity:

```
> cc <- complete.cases(samples_x, samples_y)
> ranks_x <- rank(samples_x[cc])
> ranks_y <- rank(samples_y[cc])
```

The `complete.cases`

function, when given n sets of the same length, returns the indices for which none of the sets contain NAs. The `order`

function returns the permutation of indices corresponding to the sorted sample set. The `rank`

function returns the ranks of the sample set.

How to do this? Let me know if I have provided sufficient information as to the problem in question.

More specifically, I am trying to build a correlation matrix based on Spearman's rank sum correlation coefficient test in a way such that NAs are handled properly. The presence of NAs requires that the rankings be calculated for every pairwise sample set (`s n^2 log n`

); I am trying to avoid that by calculating the orders once for every sample set (`s n log n`

) and use a linear complexity for every pairwise comparison. Is this even doable?

Thanks in advance.

youto understand, but makes it completely opaque to anybody who doesn't know R. – Jerry Coffin Aug 22 '12 at 16:46