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I would like to perform some complex multidimensional array multiplication where I multiply over specific margins of arrays.

Consider this example, where I have prevalence of a grouping feature (A and B) by some margins of a population:

# setup data

random=runif(4)

group.prevalence <- aperm (array(c(random,1-random),
                  dim=c(2,2,2), 
                  dimnames=list(age=c("young","old"),
                                gender=c("male","female"),
                                group=c("A","B"))) , c(3,1,2) )

group.prevalence 
# A + B = 1

Suppose now that I have a population of interest …

population <- round(array(runif(4, min=100,max=200) %o% c(1,1*(1+random[1]),1*(1+random[1])^2), 
                          dim=c(2,2,3), dimnames=list(age=c("young","old"),
                                                      gender=c("male","female"),
                                                      year=c("year1","year2","year3"))))

population

… for which I would like to calculate the prevalence of "A" and "B".

The bad solution would be to fill it all in a loop:

# bad solution
grouped.population <- array(NA, dim=c(2,2,2,3), 
                            dimnames=list(group=c("A","B"),
                                          age=c("young","old"),
                                          gender=c("male","female"),
                                          year=c("year1","year2","year3")))

for (group in c("A","B"))
  for(gender in c("male","female"))
    for (age in c("young","old")) 
      grouped.population[group,age,gender,] <- group.prevalence[group,age,gender] * population[age,gender,]

But I suppose that some sort of apply could come in handy, possibly plyr's aaply, because the result's dimensions should be retained. I have tried:

library(plyr)
aaply(population, c(1,2), function(x) x * group.prevalence)
# too many dimensions

I welcome any suggestions.

1

For your particular case, you can compute:

out <- rep(group.prevalence, times=last(dim(population))) * 
       rep(population, each=first(dim(group.prevalence)))

and then you can set the dimensions of this array:

array(out, dim=c(2,2,2,3), 
      dimnames=list(group=c("A","B"),
                    age=c("young","old"),
                    gender=c("male","female"),
                    year=c("year1","year2","year3")))

The key is to align the dimensions of the two arrays via transposition of dimensions and expansion/replication to fill the missing dimensions that are in the other array. In general, the procedure is:

  1. Identify the intersecting dimensions. Here, it is (age,gender).
  2. For the left hand side argument of the multiply, group.prevalence, permute the dimensions (using aperm) so that all the non-intersecting dimensions (i.e., group) are first. Then, replicate that array N times (using times) where N is the size of the non-intersecting dimensions (i.e., year) of the right hand side argument, population.
  3. For the right hand side argument of the multiply, population, permute the dimensions so that all the non-intersecting dimensions (i.e., year) are last. Then, replicate each element of the array M times (using each) where M is the size of the non-intersecting dimensions (i.e., group) of the left hand side argument, group.prevalence.
  4. Then just (array) multiply, which is vectorized and fast.
  5. The joint dimensions of the result is simply the non-intersecting dimensions of the left hand side argument, followed by the intersecting dimensions, followed by the non-intersecting dimensions of the right hand side (i.e., (group, age, gender, year)). You can then permute these dimensions as necessary in the output to get what you want.

As a check:

# bad solution
grouped.population <- array(NA, dim=c(2,2,2,3), 
                            dimnames=list(group=c("A","B"),
                                          age=c("young","old"),
                                          gender=c("male","female"),
                                          year=c("year1","year2","year3")))

for (group in c("A","B"))
  for(gender in c("male","female"))
    for (age in c("young","old")) 
      grouped.population[group,age,gender,] <- group.prevalence[group,age,gender] * population[age,gender,]

# another approach
grouped.population2 <- array(rep(group.prevalence, times=last(dim(population))) * 
                             rep(population, each=first(dim(group.prevalence))), 
                             dim=c(2,2,2,3), 
                             dimnames=list(group=c("A","B"),
                                           age=c("young","old"),
                                           gender=c("male","female"),
                                           year=c("year1","year2","year3")))

# check
all.equal(grouped.population,grouped.population2)
##[1] TRUE

Updated with benchmark:

library(microbenchmark)

f1 <- function(group.prevalence, population) {
  grouped.population <- array(NA, dim=c(2,2,2,3), 
                              dimnames=list(group=c("A","B"),
                                            age=c("young","old"),
                                            gender=c("male","female"),
                                            year=c("year1","year2","year3")))
  for (group in c("A","B")) {
    for(gender in c("male","female")) {
      for (age in c("young","old")) {
        grouped.population[group,age,gender,] <- group.prevalence[group,age,gender] * population[age,gender,]}}}
}

f2 <- function(group.prevalence, population) {
  grouped.population2 <- array(rep(group.prevalence, times=last(dim(population))) * 
                               rep(population, each=first(dim(group.prevalence))), 
                               dim=c(2,2,2,3), 
                               dimnames=list(group=c("A","B"),
                                             age=c("young","old"),
                                             gender=c("male","female"),
                                             year=c("year1","year2","year3")))
}

print(microbenchmark(f1(group.prevalence, population)))
##Unit: microseconds
##                             expr     min      lq     mean   median      uq     max neval
## f1(group.prevalence, population) 101.473 103.998 149.2562 106.8865 115.372 1185.32   100
print(microbenchmark(f2(group.prevalence, population)))
##Unit: microseconds
##                             expr    min     lq     mean median      uq     max neval
## f2(group.prevalence, population) 66.392 67.672 70.19873 68.454 69.4205 173.284   100

I believe the performance will diverge even more as the number of dimensions and the size in each dimension increases.

  • This isn't a bad idea but it is much slower than for() loop on my env. – cuttlefish44 Sep 1 '16 at 15:35
  • @cuttlefish44: Wow, I did not know that. Should have profiled before posting. This is how one would do it in C/C++/Fortran except that we would not actually permute the dimensions, but just keep track of them internally. I would guess that that is the bottleneck here. Do you know of a package that does this in R? – aichao Sep 1 '16 at 15:43
  • 1
    @cuttlefish44: I was actually referring to a multi-dim array manipulation package for this problem. – aichao Sep 1 '16 at 16:44

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