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I have the following nested loop:

for (x in xs) {
    for (y in ys) {
        # Do something with x and y

Which I’d like to flatten so I thought of building a Cartesian product of the two vectors xs and ys and iterating over the result. In Python, this would be trivial:

for xy in product(xs, ys):
    # x, y = xy[0], xy[1]

But in R, the simplest equivalent I’ve found looks daunting:

xys <- expand.grid(xs, ys)
for (i in 1 : nrow(xys)) {
    xy <- as.vector(xys[i, ])
    # x <- xy[1], y <- xy[2]

Surely there must be a better way, no? (To clarify, I don’t want to iterate over an index … I think there must be a way to directly iterate over the tuples in the product.)

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2 Answers 2

up vote 5 down vote accepted

You could use the apply function to apply a function to each row of your data frame. Just replace "your function" with your actual function.

# example data
xs <- rnorm(10)
ys <- rnorm(10)    

apply(expand.grid(xs, ys), 1, FUN = function(x) {"your function"})

This is a very basic example. Here the sum of both values in a row is calculated:

apply(expand.grid(xs, ys), 1, FUN = function(x) {x[1] + x[2]})

Here is a variant that uses named arguments (xs, ys) instead of indices (x[1], x[2]):

myfun <- function(xs, ys) xs + ys
arguments <- expand.grid(xs = rnorm(10), ys = rnorm(10))
apply(arguments, 1, function(x)do.call(myfun, as.list(x)))
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@Konrad Rudolph: I undeleted my answer. There was nothing wrong with it. I wasn't sure whether it was exactly the solution you looked for. @flodel is right about the problems using apply with mixed input types. In this case, you could use as.numeric to transform a string into a numeric value. But there is no problem as long as you use numeric vectors only. –  Sven Hohenstein Sep 9 '12 at 12:14

R has a different paradigm than Python, so don't expect it to have generators or tuples -- we have vectors and indices for that.

This way, to map a function on a Cartesian product simply call

outer(xs,ys,function(x,y) ...)

and undim the result if you wish.

EDIT: In case xs or ys are something more complex than base vectors, one option is to use indices, i.e.

outer(seq(a=xs),seq(a=ys),function(xi,yi) ... xs[[xi]]/ys[xi,]/etc. ...)

or map a function on a bit hand-crafted product using mapply

mapply(function(x,y) ...,xs,rep(ys,each=length(xs)))
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I’m not concerned with different paradigms. I am concerned about the pervasiveness of index variables in my code. As far as I understand R, most/all of them should be unnecessary. Your example code looks like what I’ve searched by it behaves in the wrong way: outer(1:2, 3:4, function(x, y) { print(sprintf('%d,%d', x, y)) } – this prints an array and a matrix with the results – so I don’t know how to rewrite my loop to work here … (I don’t know what you mean by “undim”, maybe this would explain it.) –  Konrad Rudolph Sep 9 '12 at 10:30
Uuh, the previous comment is stupid. The matrix is just the return value of outer. Nevertheless, I’m still not sure how to adapt this to work as a replacement of my nested loop, since x and y are vectors, not scalars. Unfortunately, I really do need scalars. –  Konrad Rudolph Sep 9 '12 at 10:34
@KonradRudolph Ok, extended. –  mbq Sep 9 '12 at 11:23
Cheers. This was indeed helpful but I think Sven has posted an even simpler / more directly applicable answer below … and deleted it. Is there anything wrong with his answer which I’m too inexperienced to see? It seems to work perfectly for my problem. –  Konrad Rudolph Sep 9 '12 at 11:26
Nah, it was ok; only that expand.grid won't work on any more complex structures than outer... It is only superior in case of more dimensions. –  mbq Sep 9 '12 at 11:35

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