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I wrote this R function that, given any number of vectors (...) combines them by summing the respective element values ​​based on their names.

add_vectors <- function(...) {
  a <- list(...)
  nms <- sort(unique(unlist(lapply(a, names))))
  out <- numeric(length(nms))
  names(out) <- nms
  for (v in a) out[names(v)] <- out[names(v)] + v

  out
}

Example:

v1 <- c(a=2,b=3,e=4)
v2 <- c(b=1,c=6,d=0,a=4)
add_vectors(v1, v2)
#
a b c d e 
6 4 6 0 4

I'm trying to write an equivalent function which is much faster.

Unfortunately at the moment I have no idea how to achieve this in R so I thought to Rcpp. But, in order to convert in Rcpp this function I miss some concepts:

  1. How to manage the ... parameter. With a parameter of List type in Rcpp ?
  2. How to iterate the vectors in the ... parameter.
  3. How to access (and then sum) the elements of the vectors by their name (this is very trivial in R, but I cannot figure how to do in Rcpp).

So I'm looking for someone that can help me to improve the performances of this function (in R or Rcpp, or both).

Any help is appreciated, thanks.

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How big are your vectors? Isn't this fast enough? tapply(c(v1, v2), factor(c(names(v1), names(v2)), levels=union(names(v1), names(v2))), sum) –  Arun Apr 2 '13 at 13:50
    
Or this: unlist(lapply(split(c(v1,v2), names(c(v1,v2))), sum)). Although I suspect the first one will be faster on huge vectors than using split. –  Arun Apr 2 '13 at 13:52
    
@Arun: thanks for your solutions, I've done a benchmark on short vectors and your solutions are about 2-3 time slower (probably the result of huge vectors would reverse). –  leodido Apr 2 '13 at 13:58
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5 Answers

up vote 5 down vote accepted

I would use something like this:

#include <Rcpp.h>
using namespace Rcpp; 

// [[Rcpp::export]]
NumericVector add_all(List vectors){
    RCPP_UNORDERED_MAP<std::string,double> out ; 
    int n = vectors.size() ;
    for( int i=0; i<n; i++){
        NumericVector x = vectors[i] ;
        CharacterVector names = x.attr("names") ;
        int m = x.size() ;

        for( int j=0; j<m; j++){
            String name = names[j] ;
            out[ name ] += x[j] ;   
        }
    }
    return wrap(out) ;
}

with the following wrapper:

add_vectors_cpp <- function(...){
    add_all( list(...) )
}

RCPP_UNORDERED_MAP being just a typedef to unordered_map, either in std:: or in std::tr1:: depending on your compiler, etc ...

The trick here is to create a regular list out of the ... using the classic list(...).

If you really wanted to pass down directly ... in C++ and deal with it internally, you would have to use the .External interface. This is very rarely use, so Rcpp attributes don't support the .External interface.

With .External, it would look like this (untested):

SEXP add_vectors(SEXP args){
    RCPP_UNORDERED_MAP<std::string,double> out ; 
    args = CDR(args) ;
    while( args != R_NilValue ){
        NumericVector x = CAR(args) ;

        CharacterVector names = x.attr("names") ;
        int m = x.size() ;

        for( int j=0; j<m; j++){
            String name = names[j] ;
            out[ name ] += x[j] ;   
        }        
        args = CDR(args) ;
    }   
    return wrap(out) ;
}
share|improve this answer
    
Thanks a lot for a cleaner (and more complete) solution @Romain Francois. Thanks also for the clarification about ... parameter and CDR function. –  leodido Apr 2 '13 at 18:39
2  
Using list(...) will create a copy of all the inputs, which might be a heavy performance price to pay. A more complicated approach (but doesn't need .External) is to pass the function environment and the unevaluated argument names. –  hadley Apr 4 '13 at 12:51
    
Good catch. Maybe it would be worth to support the .External interface in the Rcpp::export attribute –  Romain Francois Apr 4 '13 at 14:17
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Compiling to bytecode using the compiler package gives you some improvement. This package ships with R.

library(compiler)
library(microbenchmark)

add_vectors_cmp <- cmpfun(add_vectors)

set.seed(1)
v <- rpois(length(letters), 10)
names(v) <- letters
vs <- replicate(150, v, simplify=FALSE)

not_compiled <- function(l) do.call(add_vectors, l)
compiled <- function(l) do.call(add_vectors_cmp, l)

plot(microbenchmark(not_compiled(vs), compiled(vs)))

enter image description here

share|improve this answer
    
I know compiler package and related but this is not what I'm looking for. Anyway, thanks! =) –  leodido Apr 2 '13 at 17:01
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I just wrote a binary version (2 input) of this function in Rcpp.

I don't know how to use the ... parameter (and how to iterate on it) in Rcpp so I've encapsulated this function in a simple R function.

SOLUTION

library(Rcpp)
cppFunction(
  code = '
  NumericVector add_vectors_cpp(NumericVector v1, NumericVector v2) {
    // merging names, sorting them and removing duplicates
    std::vector<std::string> nms1 = v1.names();
    std::vector<std::string> nms2 = v2.names();
    std::vector<std::string> nms;
    nms.resize(nms1.size() + nms2.size());
    std::merge(nms1.begin(), nms1.end(), nms2.begin(), nms2.end(), nms.begin());
    std::sort(nms.begin(), nms.end());
    nms.erase(std::unique(nms.begin(), nms.end()), nms.end());
    // summing vector elements by their names and storing them in an associative data structure
    int num_names = nms.size();
    std::tr1::unordered_map<std::string, double> map(num_names);
    for (std::vector<int>::size_type i1 = 0; i1 != nms1.size(); i1++) {
        map[nms1[i1]] += v1[i1];
    }
    for (std::vector<int>::size_type i2 = 0; i2 != nms2.size(); i2++) {
        map[nms2[i2]] += v2[i2];
    }
    // extracting map values (to use as result vector) and keys (to use as result vector names)
    NumericVector vals(map.size());
    for (unsigned r = 0; r < num_names; ++r) {
        vals[r] = map[nms[r]];
    }
    vals.names() = nms;
    return vals;
  }',
  includes = '
  #include <vector>
  #include <tr1/unordered_map>
  #include <algorithm>'
)

Then the encapsulation in a R function:

add_vectors_2 <- function(...) {
  Reduce(function(x, y) add_vectors_cpp(x, y), list(...))
}

Note that this solution uses the STL libs. I don't know if this is a well written c++ solution or if a more efficient solution can be written (probably), but for sure it is a good (and working) starting point.

EXAMPLES OF USE

v1 <- c(b = 1, d = 2, c = 3, a = 4, e = 6, f = 5)
v2 <- c(d = 2, c = 3, a = 4, e = 6, f = 5)
add_vectors(v1, v2, v1, v2)
#  a  b  c  d  e  f 
# 16  2 12  8 24 20
add_vectors_2(v1, v2, v1, v2)
#  a  b  c  d  e  f 
# 16  2 12  8 24 20 

NOTE: this function works also for vector which names are not uniques.

v1 <- c(b = 1, d = 2, c = 3, a = 4, e = 6, f = 5)
v2 <- c(d = 2, c = 3, a = 4, e = 6, f = 5, f = 10, a = 12)
add_vectors(v1, v2)
#  a  b  c  d  e  f 
# 16  1  6  4 12 15 
add_vectors_2(v1, v2)
#  a  b  c  d  e  f 
# 20  1  6  4 12 20

As showed by the last example this solution works even when the input vectors have non-unique names, summing the elements of the same vector with the same name.

BENCHMARKS

My solution is about 3 times faster than R solution in the simplest case (two vectors). It is good imporvement, but probably there is scope for further small improvements with a better C++ solution.

Unit: microseconds
                 expr    min     lq median      uq     max neval
  add_vectors(v1, v2) 65.460 68.569 70.913 73.5205 614.274   100
add_vectors_2(v1, v2) 20.743 23.389 25.142 26.9920 337.544   100

enter image description here

When applying this function to more vectors the performances degrade a bit (only 2 time faster).

Unit: microseconds
                                 expr     min       lq  median       uq     max neval
  add_vectors(v1, v2, v1, v2, v1, v1) 105.994 195.7565 205.174 212.5745 993.756   100
add_vectors_2(v1, v2, v1, v2, v1, v1)  66.168 125.2110 135.060 139.7725 666.975   100

So the last goal now is to remove the R wrapping function managing the ... (or similar, e.g. List?) parameter directly with Rcpp.

I think that this is possible because Rcpp sugar have features similar to it (e.g. the porting of the sapply function). Anyone can suggest or help me? Thanks in advance

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The data.table package is excellent at performing aggregation and other operations. I'm not really an expert, but

library(data.table)
add_vectors5 <- function(...)
{
    vals <- do.call(c, list(...))
    dt <- data.table(nm=names(vals), v=vals, key="nm")
    dt <- dt[,sum(v), by=nm]
    setNames(dt[[2]], dt[[1]])
}

seems to be about 2x faster than other pure R implementations. A more cryptic implementation is

add_vectors6 <- function(..., method="radix")
{
    vals <- do.call(c, list(...))
    ## order by name, but use integers for faster order algo
    idx <- match(names(vals), unique(names(vals)))
    o <- sort.list(idx, method=method, na.last=NA)

    ## cummulative sum of ordered values
    csum <- cumsum(vals[o])

    ## subset where ordering factor changes, and then diff
    idxo <- idx[o]
    diff(c(0, csum[idxo != c(idxo[-1], TRUE)]))
}

which is prone to numeric overflow; use method="radix" if there are less than 100,000 names, as implied on ?sort.list, otherwise method="quick".

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I don't think that you'll get much speedup. I took an alternate approach in R code, combining all inputs into a single vector, then resplitting by name, and aggregating with vapply. More or less all the functions there call internal C code, and the speed is comparable to your function for large vectors (tested on vectors of length 1e5 and 1e6). It's a little slower for the toy examples of 3 or 4 elements.

add_vectors2 <- function(...) {
  y <- do.call(c, unname(list(...)))
  vapply(split(y, names(y)), sum, numeric(1))
}

#Longer sample vectors
m <- 1e3
n <- 1e6
v1 <- sample(m, n, replace = TRUE)
names(v1) <- sample(n)
v2 <- sample(m, n, replace = TRUE)
names(v2) <- sample(seq_len(n) + n / 2)  

#Timings
k <- 20
system.time(for(i in 1:k) add_vectors(v1, v2))   #5 or 6 seconds
system.time(for(i in 1:k) add_vectors2(v1, v2))  #same

EDIT: Vector names fixed to be unique, reflecting Roland's comment. My solution is now a little slower than OP's.

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1  
The OP's function makes the assumption that names are unique for each vector, yours doesn't. Thus, results differ for your large vectors. –  Roland Apr 2 '13 at 15:43
    
@Roland: the fact that the names must be unique is not a primary requirement, instead the speed it's. ;) –  leodido Apr 2 '13 at 17:01
    
@Richie Cotton: thanks for your solution, however! –  leodido Apr 2 '13 at 17:04
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