# Why is vectorization faster

I've been learning R for a while now, and have come across a lot of advice to programming types like myself to vectorize operations. Being a programmer, I'm interested as to why / how it's faster. An example:

``````n = 10^7
# populate with random nos
v=runif(n)
system.time({vv<-v*v; m<-mean(vv)}); m
system.time({for(i in 1:length(v)) { vv[i]<-v[i]*v[i] }; m<-mean(vv)}); m
``````

This gave

``````   user  system elapsed
0.04    0.01    0.07
[1] 0.3332091

user  system elapsed
36.68    0.02   36.69
[1] 0.3332091
``````

The most obvious thing to consider is that we're running native code, i.e. machine code compiled from C or C++, rather than interpreted code, as shown by the massive difference in user time between the two examples (circa 3 orders of magnitude). But is there anything else going on? For example, does R do:

• Cunning native data structures, e.g. clever ways of storing sparse vectors or matrices so that we only do multiplications when we need to?

• Lazy evaluation, e.g. on a matrix multiply, don't evaluate cells until as and when you need to.

• Parallel processing.

• Something else.

To test whether there might be some sparse vector optimization I tried doing dot products with difference vector contents

``````# populate with random nos
v<-runif(n)
system.time({m<-v%*%v/n}); m
# populate with runs of 1 followed by 99 0s
v <-rep(rep(c(1,rep(0,99)),n/100))
system.time({m<-v%*%v/n}); m
# populate with 0s
v <-rep(0,n)
system.time({m<-v%*%v/n}); m
``````

However there was no significant difference in time (circa 0.09 elapsed)

(Similar question for Matlab: Why does vectorized code run faster than for loops in MATLAB?)

The most obvious thing to consider is that we're running native code, i.e. machine code compiled from C or C++, rather than interpreted code

That's most of it. The other big-ish component is that since R code is functional in its design paradigm, functions (attempt to) have no side effects, which means that in some (but perhaps not all; R does try to be efficient about this) instances calling `[<-` in side a for loop results in having to copy the entire object. That can get slow.

A small side note: R does have rather extensive functionality for handling sparse matrix structures efficiently, but they aren't the "default".

• Thanks, I didn't quite follow what you meant by functions in a loop, would you be able to provide a simple example or a reference (I'm interested generally in how the functional side of R affects things from a user's point of view -- so far everything I've done has been pretty procedural in style). – TooTone Jun 3 '13 at 19:07
• @TooTone `x <- 1:10; tracemem(x); x[5] <- 1` would be the simplest example, probably. – joran Jun 3 '13 at 19:20
• That's subtle. I had no idea that was happening (there is a discussion thread, which notes that R mostly optimizes these copies away, in case anyone else wants to look into this further). I've done some testing, and in my code with the `for` loop, `vv` is copied once, when `i==1`, but this has no impact on performance. – TooTone Jun 3 '13 at 20:18
• @TooTone Yes, as I mentioned, R does try hard (and often succeeds) in minimizing this copying, but you can easily imagine more complex situations in writing a long code block in a for loop where R can't know ahead of time whether an object is going to need to be modified or not, or referenced in the future, and so copying becomes inevitable. – joran Jun 3 '13 at 20:23
• @TooTone In you case, `vv` exists before the loop version, and hence storage is already allocated. You still incur a large overhead of all the function calls to `*` and `[<-` and 3 `[` per iteration. – Gavin Simpson Jun 3 '13 at 20:23

You are running both interpreted code and native code in both examples. The difference is that in the second you are doing the loop at the R level resulting in many more function calls that all need to be interpreted, and then the C code called. In your first example, the loop happens within the compiled code and hence R has far less to interpret, far fewer R code calls and far fewer calls to compiled code.

In regard to parallel processing, out-of-the-box R does not do any parallel processing. Of course there is the built-in `parallel` package, but you have to adapt your code to using e.g. `mclapply` to use parallel processing. There are options to let your linear algebra be calculated in parallel using a special version of `blas`, but this is not standardly using in R, although getting it to work does not seems that hard.

• Thanks I guess parallel processing is one way in which Revolution Analytics R (love them or hate them) try to make a business. – TooTone Jun 3 '13 at 19:09