# Matrix operation: indexing asymmetric vectors of logical to numerical comparisons

I am using a logical matrix to select and order the indices of corresponding elements in a numerical matrix (both have identical dimensions). For example,

`````` x <- c(FALSE, TRUE, TRUE, FALSE, TRUE, TRUE, FALSE, TRUE, TRUE, FALSE)
y <- c(7, 10, 3, 1, 6, 8, 2, 11, 1, 5)

order(y[x],decreasing=TRUE)
[1] 5 1 4 3 2 6

# NOTE: these are the **indices** of the ordered vector y[x] now containing
# only six elements (10,3,6,8,11,1)
``````

Great. Works as it should. However, when I perform the operation on a matrix, I obtained an unexpected result:

`````` x <- matrix(rep(c(F,T,T),10), nrow=10)

[,1]  [,2]  [,3]
[1,] FALSE  TRUE  TRUE
[2,]  TRUE  TRUE FALSE
[3,]  TRUE FALSE  TRUE
[4,] FALSE  TRUE  TRUE
[5,]  TRUE  TRUE FALSE
[6,]  TRUE FALSE  TRUE
[7,] FALSE  TRUE  TRUE
[8,]  TRUE  TRUE FALSE
[9,]  TRUE FALSE  TRUE
[10,] FALSE  TRUE  TRUE

y <- matrix( round(rnorm(30,sample(10))), ncol=3)

[,1] [,2] [,3]
[1,]    7    7    6
[2,]   10   12    8
[3,]    3    5    6
[4,]    1    1    0
[5,]    6    5    6
[6,]    8    7    7
[7,]    2    3    4
[8,]   11    8    9
[9,]    1    2    1
[10,]    5    5    5

y<-structure(c(7, 10, 3, 1, 6, 8, 2, 11, 1, 5, 7, 12, 5, 1, 5, 7,
3, 8, 2, 5, 6, 8, 6, 0, 6, 7, 4, 9, 1, 5), .Dim = c(10L, 3L))

order(y[x], decreasing=TRUE)
[1]  8  5  1  4 12  7 17  3 14 15 10 13 20 18  2 11  6  9 19 16
``````

It seems that as the comparison returns vectors of unequal length (depends on logical TRUE in x) I am breaking the intended behavior of the operation. However,

`````` y[x]
[1] 10  3  6  8 11  1  7 12  1  5  3  8  5  6  6  0  7  4  1  5
``````

yields what I expect with no ordering; order(y[x]) is performed on all TRUE elements. Is this a bug? I would (naively) expect that it would perform the operation on each column separately and concatenate the result like above.

In any case, is there a reasonable way to partition asymmetric results into a matrix? I considered padding each vector with NAs to max dim(x) and then cbind into a matrix (see below). Seems like a mess as I would lose vectorization. Any more elegant ideas/hints?

Thanks.

``````#Desired result
[,1] [,2] [,3]
[1,]    5    2    4
[2,]    1    6    1
[3,]    4    1    2
[4,]    3    4    7
[5,]    2    7    5
[6,]    6    5    6
[7,]   NA    3    3
``````
-

I am not sure why you want to keep a matrix structure with NAs. Couldn't you use a list of lists? In that case you could transform your matrices into data frames and use mapply. That's how you execute a function on each column independently in R.

``````my.order <- function(x, y) order(y[x],decreasing=TRUE)
mapply(my.order, as.data.frame(x), as.data.frame(y))

\$V1
[1] 5 1 4 3 2 6

\$V2
[1] 2 6 1 4 7 5 3

\$V3
[1] 4 1 2 7 5 6 3
``````

You can always pad each element and coerce the list to a data frame if you really need to.

-
Thank you for the suggestion about using lists. I'll give it a go on some real data sets - sizes in the tens of millions - and report on execution speed. –  user1789784 Dec 21 '12 at 14:27
Okay, let us know. I am not aware that there is a vectorized version of order, and if you worry about performance, you might have to write the code and the loop in a compiled language. You might want to look at the package Rcpp, which allows to write and compile C++ code in R scripts. –  Arnaud Amzallag Dec 21 '12 at 18:22

`y[x]` returns

``````[1]  8  5  1  4 12  7 17  3 14 15 10 13 20 18  2 11  6  9 19 16
``````

This is a numeric vector.

`order(y[x])` is therefore working on a numeric vector. It has no memory that `y` and `x` were matrices and no ability to read your mind that it should be applied columnwise and to a matrix that was once 3 columns and that you want to pad it with `NA` values.

You could use `is.na<-` and return a list (similar to the answer posted while I was writing this)

``````newy <- y

is.na(newy) <- !x
``````

apply(newy, 2,function(x) order(na.omit(x), decreasing = TRUE))

``````[[1]]
[1] 5 1 4 3 2 6

[[2]]
[1] 2 6 1 4 7 5 3

[[3]]
[1] 4 1 2 7 5 6 3
``````
-
Thank you for the suggestion above. I'll give it a go on some real data sets - sizes in the tens of millions - and report execution speed for both approaches. –  user1789784 Dec 21 '12 at 14:28