I am working on a project that requires large matrices with a larger number of zeros. Unfortunately, as some of these matrices can have more than 1e10 elements, working with the "standard" R matrices is not an option, due to RAM constraints. Also, I need to work on multiple cores, as the computation can take quite a long time and really shouldn't.

So far, I have been working with the `foreach`

package, and converted the results (which come in standard matrices) to sparse matrices afterwards. I can't help but think that there must be a smarter way.

Here is a minimal example of what I have been doing so far:

```
cl <- makeSOCKcluster(8)
registerDoSNOW(cl)
Mat <- foreach(j=1:length(lambda), .combine='cbind') %dopar% {
replicate(iter, rpois(n=1, lambda[j]))
}
Mat <- Matrix(Mat, sparse=TRUE)
stopCluster(cl)
```

The lambdas are all quite small, so that only every 5th element or so is different from zero, making it sensible to store the results in a sparse matrix.

Unfortunately, it has now become necessary to increase the number of iterations from 1e6 to at least 1e7, so that the matrix that is produced by the `foreach`

loop is too large to be stored on 8GB of RAM. What I now want to do is split up the tasks into steps that each have 1e6 iterations, and combine these into a single, sparse matrix.

I now have the following as an idea:

```
library(Matrix)
library(snow)
cl <- makeSOCKcluster(8)
iter <- 1e6
steps <- 1e5
numsteps <- iter / steps
draws <- function(x, lambda, steps){
replicate(n=steps, rpois(n=1, lambda=lambda))
}
for(i in 1:numsteps){
Mat <- Matrix(0, nrow=steps, ncol=96, sparse=TRUE)
Mat <- Matrix(
parApply(cl=cl, X=Mat, MARGIN=2, FUN=draws, lambda=0.2, steps=steps)
, sparse = TRUE)
if(!exists("fullmat")) fullmat <- Mat else fullmat <- rBind(fullmat, Mat)
rm(Mat)
}
stopCluster(cl)
```

It works fine, but I had to fix lambda to some value. For my application, I need the values in the ith row to come from a poisson distribution with mean equal to the ith element of the lambda vector. This obviously worked fine in the `foreach`

loop., but I have yet to find a way to make it work in an apply loop.

My questions are:

- Is it possible to have the apply function "know" on which row it is operating and pass a corresponding argument to a function?
- Is there a way to work with foreach and sparse matrices without the need of creating a standard matrix and converting it into a sparse one in the next step?
- If none of the above, is there a way for me to manually assign tasks to slave processes of R - that is, could I specifically tell a process to work on column 1, another to work on column 2 and so on, each creating a sparse vector and only combining these in the last step.