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I have a matrix of indices I where some of the indices are repeated. I put an example below.

I have another matrix A with dimensions compatible with the indices and initiated to 0 everywhere. I would like to do something like

A[I] += 1

I face two issues:

  1. A[I] = A[I] + 1 is too inefficient
  2. matrix I has redundant indices. For example rows 2 & 6 are identical and I would like to obtain A[1,2] = 2

A partial answer would be to create a 3 columns matrix with the two first columns being the product of unique(I) and the third column with the counts, but I don't see any solution for that either. Any pointer or help would be greatly appreciated!

> I is:
     [,1] [,2]
[1,]    1    1
[2,]    1    2
[3,]    1    3
[4,]    1    4
[5,]    1    1
[6,]    1    2
[7,]    1    3
share|improve this question
The word "index" refers to a location. You are confusing it with the value at that location. If I is a matrix, A[I] is highly unlikely to do what you think it does. Please provide a small sample of A and what you want the updated A matrix to look like. –  Carl Witthoft Nov 8 '12 at 20:36
The answers below are nice. I wonder about your "too inefficient" statement. How big are A and I ... ? –  Ben Bolker Nov 8 '12 at 20:38

2 Answers 2

Here you go:

## Reproducible versions of your A and I objects
A <- matrix(0, nrow=2, ncol=5)
## For computations that follow, you'll be better off having this as a data.frame
## (Just use `I <- as.data.frame(I)` to convert a matrix object I).
I <- read.table(text=" 1    1
1    2
1    3
1    4
1    1
1    2
1    3", header=FALSE)

## Create data.frame with number of times each matrix element should
## be incremented
I$count <- ave(I[,1], I[,1], I[,2], FUN=length)
I <- unique(I)

## Replace desired elements, using a two column matrix (the "third form of
## indexing" mentioned in "Matrices and arrays" section" of ?"[").
A[as.matrix(I[1:2])] <- I[[3]]

#      [,1] [,2] [,3] [,4] [,5]
# [1,]    2    2    2    1    0
# [2,]    0    0    0    0    0
share|improve this answer

This may be quickest using sparse matrix methods (see the Matrix package and others).

Using standard matricies you could collapse the identical rows using the xtabs function then matrix assignment (edited based on comment):

I <- cbind(1, c(1:4,1:3))

tmp <- as.data.frame(xtabs( ~I[,1]+I[,2] ))

A <- matrix(0, nrow=5, ncol=5)
tmp2 <- as.matrix(tmp[,1:2])
tmp3 <- as.numeric(tmp2)
dim(tmp3) <- dim(tmp2)
A[ tmp3 ] <- tmp[,3]

You could probably make it a little quicker by pulling the core functionality out of as.data.frame.table rather than converting to data frame and back again.

Here is another version that may be more efficient. It will overwrite some 0's with other 0's computed by xtabs:

I <- cbind(1:5,1:5)
A <- matrix(0, 5, 5)

tmp <- xtabs( ~I[,2]+I[,1] )

A[ as.numeric(rownames(tmp)), as.numeric(colnames(tmp)) ] <- c(tmp)

If the A matrix has dimnames and the I matrix has the names instead of the indexes, then this later one will also work (just remove the as.numerics.

share|improve this answer
I like the idea of using xtabs() but this doesn't do what it is meant to. (Look at A to see that). The problem is that the call to as.numeric() converts the character matrix to a numeric vector which completely changes the meaning of the indexing. –  Josh O'Brien Nov 8 '12 at 22:39
@JoshO'Brien, can you elaborate? My A matrix matches what I expect. What is the difference? –  Greg Snow Nov 9 '12 at 1:54
Sure. Try yours with I <- cbind(1:5, 1:5), for example, to see that there's a problem. Then have a look at the value of as.numeric(as.matrix(tmp[,1:2])) to see why. (I'm assuming you and I agree that the results of feeding I <- cbind(1:5, 1:5) to your code should be the 5-by-5 identity matrix.) –  Josh O'Brien Nov 9 '12 at 2:04
@JoshO'Brien, OK, I see the problem (did not read your comment closely enough) is that the dimensions of the matrix are dropped. I will edit the code above with a better solution. –  Greg Snow Nov 9 '12 at 3:41

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