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I have a matrix M and a matrix L that contains 'pair of rows indexes' that i need to select in M, in order to apply a function. The function returns a matrix with 2 rows and the same number of columns of M:

# M has even number of rows
M = matrix(runif(24), ncol = 3)
# each row of L is a pair of row indexes that will be selected in M
# so the first 'pair' is M[1,] M[3,], the second is M[2,] M[4,] and so on
L = matrix(c(1,3,2,4,6,7), ncol = 2, byrow = T)

The function f is:

f = function(r1, r2)
 matrix(c(r1+r2, r1-r2), nrow = 2, byrow = T)

The thing is that a need to loop over L, apply f for each 'pair' and append the results to another matrix. So, for the code above the final result would be:

#first row of L
res1 = f(M[1,], M[3,])
#second row of L
res2 = f(M[2,], M[4,])
#third row of L
res3 = f(M[6,], M[7,])

#append everything
RES = rbind(res1, res2, res3)

How can i vectorize this operation? The rows indexes in L are random, and the row order of the final result didn't matter.

Thanks for any help!

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1 Answer 1

up vote 2 down vote accepted

What if you wrap your f function in something that takes the matrix M as an additional argument:

fm <- function(rowVector, mat) {
  f(mat[rowVector[1],], mat[rowVector[2],])

then call it with apply:

apply(L, 1, fm, mat=M)

           [,1]       [,2]        [,3]
[1,]  0.8383620  1.2803317  1.84306495
[2,] -0.3073447 -0.5360839 -0.04628558
[3,]  0.8350886  0.2383430  1.15394514
[4,]  0.4231395 -0.1147705 -0.38573770
[5,]  1.0976537  1.7693513  0.86381629
[6,]  0.3375833  0.2144609 -0.43953124
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You solution looks great, but i'm getting different results! By the way, the row order of the final result didn't matter. –  Fernando Sep 14 '12 at 20:47
I just add matrix(t(apply(L,1,fm,mat = M)), byrow = F, ncol = 3), i think it does the trick! –  Fernando Sep 14 '12 at 20:51

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