3

The solution is now online in the Rcpp Gallery


I re-implemented dmvnorm from the mvtnorm package in RcppArmadillo. I somehow like Armadillo, but I guess it would also work in plain Rcpp. The approach from dmvnorm is based on the mahalanobis distance, so I have a function for that and then the multivariate normal density function.

Let me show you my code:

#include <RcppArmadillo.h>
#include <Rcpp.h>

// [[Rcpp::depends("RcppArmadillo")]]

// [[Rcpp::export]]
arma::vec mahalanobis_arma( arma::mat x ,  arma::mat mu, arma::mat sigma ){

  int n = x.n_rows;
  arma::vec md(n);
    for (int i=0; i<n; i++){
        arma::mat x_i = x.row(i) - mu;
        arma::mat Y = arma::solve( sigma, arma::trans(x_i) );
        md(i) = arma::as_scalar(x_i * Y);
    }
    return md;

    }



// [[Rcpp::export]]
arma::vec dmvnorm ( arma::mat x,  arma::mat mean,  arma::mat sigma, bool log){ 

arma::vec distval = mahalanobis_arma(x,  mean, sigma);

    double logdet = sum(arma::log(arma::eig_sym(sigma)));
    double log2pi = 1.8378770664093454835606594728112352797227949472755668;
    arma::vec logretval = -( (x.n_cols * log2pi + logdet + distval)/2  ) ;

       if(log){ 
         return(logretval);

       }else { 
       return(exp(logretval));
         }
}

So, and not to my big disappointment:

simulate some data

sigma <- matrix(c(4,2,2,3), ncol=2)
x <- rmvnorm(n=5000000, mean=c(1,2), sigma=sigma, method="chol")

and benchmark

system.time(mvtnorm::dmvnorm(x,t(1:2),.2+diag(2),F))
   user  system elapsed 
   0.05    0.02    0.06 

system.time(dmvnorm(x,t(1:2),.2+diag(2),F))
   user  system elapsed 
   0.12    0.02    0.14 

No!!!!!! :-(

[EDIT]

The questions are: 1) Why is the RcppArmadillo implementation slower than a plain R implementation? 2) How do I create an Rcpp/RcppArmadillo implementation that beats the R implementation?

[EDIT 2]

I put in the mahalanobis_arma into the mvtnorm::dmvnorm function and it also slows down.

  • 1
    I don't understand what your question is – David Marx Jul 12 '13 at 14:50
  • 2
    If the bulk of the calculations are going to be performed by the same linear algebra library between the two implementaions, why do you expect to see a significant improvement? – David Marx Jul 12 '13 at 15:05
  • 3
    This just shows you can write slow code in any language. :) Why not simply call mvtnorm::dmvnorm from C++? – Joshua Ulrich Jul 12 '13 at 15:22
  • 1
    Your question title is misleading. RCppArmadillo is not slower than R; it's slower than R plus Fortran. The Fortran bit happens to be more important than the R bit here. – Hong Ooi Jul 12 '13 at 15:37
  • 2
    the bottom line of this is that re-coding in lower-level languages generally only helps if the relevant operations are not already dropping through to compiled binary code in the original R functions ... – Ben Bolker Jul 12 '13 at 15:59
8

If you want a faster implementation of the mahalanobis distance, you just have to re-write your algorithm and mimic the one used by R. It's pretty straightforward

I modified a little bit your function mahalanobis_arma to turn mu to a rowvec.

Basically I just translated the R code to RcppArmadillo

mahalanobis
function (x, center, cov, inverted = FALSE, ...) 
{
    x <- if (is.vector(x)) 
        matrix(x, ncol = length(x))
    else as.matrix(x)
    x <- sweep(x, 2, center)
    if (!inverted) 
        cov <- solve(cov, ...)
    setNames(rowSums((x %*% cov) * x), rownames(x))
}
<bytecode: 0x6e5b408>
<environment: namespace:stats>

Here it is

#include <RcppArmadillo.h>
#include <Rcpp.h>

// [[Rcpp::depends("RcppArmadillo")]]
// [[Rcpp::export]]
arma::vec Mahalanobis(arma::mat x, arma::rowvec center, arma::mat cov){
    int n = x.n_rows;
    arma::mat x_cen;
    x_cen.copy_size(x);
    for (int i=0; i < n; i++) {
        x_cen.row(i) = x.row(i) - center;
    }
    return sum((x_cen * cov.i()) % x_cen, 1);    
}


// [[Rcpp::export]]
arma::vec mahalanobis_arma( arma::mat x ,  arma::rowvec mu, arma::mat sigma ){

  int n = x.n_rows;
  arma::vec md(n);
    for (int i=0; i<n; i++){
        arma::mat x_i = x.row(i) - mu;
        arma::mat Y = arma::solve( sigma, arma::trans(x_i) );
        md(i) = arma::as_scalar(x_i * Y);
    }
    return md;

    }

Now, let's compare this new armadillo version (Mahalanobis), your first version (mahalanobis_arma) and the R implementation (mahalanobis).

I save this Cpp code as mahalanobis.cpp

require(RcppArmadillo)
sourceCpp("mahalanobis.cpp")

set.seed(1)
x <- matrix(rnorm(10000 * 10), ncol = 10)
Sx <- cov(x)


all.equal(c(Mahalanobis(x, colMeans(x), Sx))
          ,mahalanobis(x, colMeans(x), Sx))
## [1] TRUE

all.equal(mahalanobis_arma(x, colMeans(x), Sx)
          ,Mahalanobis(x, colMeans(x), Sx))
## [1] TRUE


require(rbenchmark)
benchmark(Mahalanobis(x, colMeans(x), Sx),
          mahalanobis(x, colMeans(x), Sx),
          mahalanobis_arma(x, colMeans(x), Sx),
          order = "elapsed")


##                                   test replications elapsed
## 1      Mahalanobis(x, colMeans(x), Sx)          100   0.124
## 2      mahalanobis(x, colMeans(x), Sx)          100   0.741
## 3 mahalanobis_arma(x, colMeans(x), Sx)          100   4.509
##   relative user.self sys.self user.child sys.child
## 1    1.000     0.173    0.077          0         0
## 2    5.976     0.804    0.670          0         0
## 3   36.363     4.386    4.626          0         0

As you can see the new implementation is faster than the R one. I'm pretty sure that we can do better here by using cholesky decomposition to solve the covariance matrix or by using other matrix decomposition.

Finally, we can just plug this Mahalanobis function into your dmvnorm and test it :

require(mvtnorm)
set.seed(1)
sigma <- matrix(c(4, 2, 2, 3), ncol = 2)
x <- rmvnorm(n = 5000000, mean = c(1, 2), sigma = sigma, method = "chol")


all.equal(mvtnorm::dmvnorm(x, t(1:2), .2 + diag(2), FALSE),
          c(dmvnorm(x, t(1:2), .2+diag(2), FALSE)))
## [1] TRUE

benchmark(mvtnorm::dmvnorm(x, t(1:2), .2 + diag(2), FALSE),
          dmvnorm(x, t(1:2), .2+diag(2), FALSE),
          order = "elapsed")

##                                                test replications
## 2          dmvnorm(x, t(1:2), 0.2 + diag(2), FALSE)          100
## 1 mvtnorm::dmvnorm(x, t(1:2), 0.2 + diag(2), FALSE)          100
##   elapsed relative user.self sys.self user.child sys.child
## 2  35.366    1.000    31.117    4.193          0         0
## 1  60.770    1.718    56.666   13.236          0         0

It almost twice as fast now.

| improve this answer | |
  • Just one more thing: I might have different means. So I have to subtract them in advance, and then run this with mean 0. – Inferrator Jul 12 '13 at 20:53
  • @Inferrator You can turn mu to mat again by making sure that you substract it carefully to x (row wise) and the dimension are adequate. – dickoa Jul 12 '13 at 21:00
  • Right. Great, thanks much! Simple but smart solution. Wouldn't this be nice for the Rcpp gallery? – Inferrator Jul 12 '13 at 21:12
  • I put everything together in a gist and added openMP: gist.github.com/anonymous/5987975 - Just run Sys.setenv("PKG_CXXFLAGS"="-fopenmp") Sys.setenv("PKG_LIBS"="-fopenmp") in R and then use sourceCpp – Inferrator Jul 12 '13 at 21:24
  • @Inferrator Well I think it could be a nice addition to Rcpp gallery, I think they accept gist if you want to add an entry. – dickoa Jul 12 '13 at 21:35

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.