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In the previous post on RcppEigen I described an example of sampling from collection of multinomial distributions represented by a matrix of probabilities. In the timing example the matrix was 100000 by 5 with each of the 100000 rows summing to 1. The objective is to create a vector of 100000 1-based indices representing a sample from the probabilities in each row. Want to share your content on R-bloggers? click here if you have a blog, or here if you don't.
For each row we take the cumulative sums and, for safety, normalize by dividing by the last element then compare these values to a random draw from a standard uniform distribution. The number of elements in the cumulative sums that are less than the uniform draw is the 0-based index of the result. We add 1 to convert to a 1-based index.
I have been experimenting a bit with a very interesting new language called Julia and decided to write a similar function in it. The version shown here has been updated according to suggestions from Jeff Bezanson, Stefan Karpinski and Viral Shah on the julia-dev list at Google Groups
function samp1(x::Array{Float64, 2},) cs = cumsum(reshape(x, length(x))) sum(cs/cs[end] < rand()) + 1 end function samp(X::Array{Float64, 2},) if any(X < 0) error("Negative probabilities not allowed") end [samp1(X[i,:]) | i = 1:size(X,1)] endThis version is about 10 times as fast as the pure R version but about 9 times slower than the RcppEigenversion.
Update:
In the thread on the julia-dev list about this example Stefan Karpinski showed that in Julia you can enhance performance by de-vectorizing your code and came up with the following version which is much faster than the RcppEigenversion
function SKsamp(X::Matrix{Float64}) if any(X < 0) error("Negative probabilities not allowed") end s = Array(Int, size(X,1)) for i = 1:size(X,1) r = rand() for j = 1:size(X,2) r -= X[i,j] if r <= 0.0 s[i] = j break end end end return s endTo a longtime R/S programmer the concept of de-vectorizing your code seems heretical but I can understand that code created by a JITwill be happier with the looping and break style.
In any case, I think this example shows that R programmers should take a look at Julia. Two immediate applications I can imagine are McMC methods and large scale iterative fits such as Generalized linear models
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