# element wise matrix multiplication in Rcpp

I am trying to speed up some R code with Rcpp that takes a vector of length L (psi) and a matrix of dimensions (L,L) and does some element-wise operations. Is there a more efficient way to be doing these element-wise operations with Rcpp?

r:

 UpdateLambda <- function(psi,phi){
# updated full-day infection probabilites
psi.times.phi <- apply(phi,1,function(x) x*psi)
## return Lambda_{i,j} = 1 - \prod_{j} (1 - \psi_{i,j,t} \phi_{i,j})
apply(psi.times.phi,2,function(x) 1-prod(1-x))
}


cpp:

#include <Rcpp.h>
#include <algorithm>
using namespace Rcpp;

// [[Rcpp::export]]
NumericVector UpdateLambdaC(NumericVector psi,
NumericMatrix phi
){

int n = psi.size();
NumericMatrix psi_times_phi(n,n);
NumericVector tmp(n,1.0);
NumericVector lambda(n);

for(int i=0; i<n;i++){
psi_times_phi(i,_) = psi*phi(i,_);
}

for(int i=0; i<n;i++){
// \pi_{j} (1- \lambda_{i,j,t})
for(int j=0; j<n;j++){
tmp[i] *= 1-psi_times_phi(i,j);
}
lambda[i] = 1-tmp[i];
}

return lambda;
}

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It looks like you can avoid the use of apply in your R code, and use colSums with loged variables to get the products. – James Feb 14 '13 at 8:39
The first apply is equivalent to t(phi)*psi, which should be faster – James Feb 14 '13 at 8:46
you think log and then exp'ing and summing will be that much faster than prods? – scottyaz Feb 14 '13 at 9:10
@scottyaz colSums is vectorized and very efficient. Unfortunately, there is no colProds in base R. Thats why @James suggested summing the logs. There is a function colProds in package matrixStats, which apparently uses this algorithm. The message is, that you probably don't need Rcpp if you optimize your R code. – Roland Feb 14 '13 at 10:54
@scottyaz I'll put the method down as an answer and you can see if it works for you – James Feb 14 '13 at 13:11

You can replace you apply loops with vectorised alternatives.

The first one is equivalent to:

t(phi)*psi


And the second:

1-exp(colSums(log(1-psi.times.phi)))

#test data
phi <- matrix(runif(1e6),1e3)
psi <- runif(1e3)

#new function
UpdateLambda2 <- function(psi,phi) 1-exp(colSums(log(1-t(phi)*psi)))

#sanity check
identical(UpdateLambda(psi,phi),UpdateLambda2(psi,phi))
[1] TRUE

#timings
library(rbenchmark)
benchmark(UpdateLambda(psi,phi),UpdateLambda2(psi,phi))
test replications elapsed relative user.self sys.self
1  UpdateLambda(psi, phi)          100   16.05    1.041     15.06     0.93
2 UpdateLambda2(psi, phi)          100   15.42    1.000     14.19     1.19


Well, it appears that it does not make much of a difference, which is very surprising as colSums is typically much faster than apply. I'm not sure if the test data I've used is relevant as the output is all 1's due number of multiplications of number less than 1 in the second part. You may be better off working in a log scale anyway if you want to note the detail of such small numbers.

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