5
u <- rnorm(10000)
v <- rnorm(10000)

# `outer`
system.time(mat1 <- outer(u, v , `<`))
#    user  system elapsed 
#    1.80    1.34    3.32 

# `for` loop
system.time({
  mat2 <- matrix(NA, nrow = length(u), ncol = length(v))
  for(i in seq_along(v)) {
    mat2[, i] <- u < v[i]
  }
})
#    user  system elapsed 
#    0.97    0.02    1.01 

identical(mat1, mat2)
# [1] TRUE
11
  • 1
    I get (almost) exactly the same system.time for both (0.45/0.17/0.62 Vs 0.45/0.18/0.63)
    – Sotos
    Dec 15, 2022 at 10:01
  • 1
    I also tried this a few times (with a few different sizes of matrix) and outer was always slightly faster. What speed difference do you get if you run mat3 <- `<`(rep(u, times = ceiling(length(v)/length(u))), rep(v, rep.int(length(u), length(v)))) ? That's essentially what `outer is doing.
    – SamR
    Dec 15, 2022 at 10:08
  • 6
    Probably because of memory allocation. outer does the whole operation at once, hence needs to allocate a lot of memory, while the for loop does many simple operations. If you'll test it on u <- rnorm(100) ; v <- rnorm(100), you'll see outer is faster. Usually, this is the tradeoff between loop and vectorized functions- if the operation is simple but needs a lot of memory- loop is better, but if the operation is complicated, then doing it per iteration is costly, while a compiled code will much preferable Dec 15, 2022 at 10:08
  • 1
    Also, why would you expect outer to be faster than for loops?
    – Maël
    Dec 15, 2022 at 10:12
  • 3
    Best of both worlds: vapply(seq_along(v), \(i) u < v[i], logical(length(u)))
    – s_baldur
    Dec 15, 2022 at 10:15

1 Answer 1

8

Allocating and destroying memory takes time

If you use bench::press() with the four options set out you can get the sense that the method with the most memory allocations takes longest, as suggested by David Arenburg in the comments.

The four options are:

  1. outer().
  2. A for loop.
  3. vapply() (from comment by sindri_baldur).
  4. `<`(rep(x), rep(y)) (exactly what outer() is doing under the hood).

I like bench because it shows memory usage. Each facet in this plot shows the speed of these four approaches with an n*n matrix, and levels of garbage collection.

enter image description here

With 100 rows, vapply is slower than the other methods, and there's no difference in gc (garbage collection).

However, once the data is larger than that, we can see that vapply() does a lot less garbage collection and is a lot faster.

Similarly, in the final facet (1e4 rows and columns), we can see that the for loop has less garbage collection and tends to be faster than outer().

vapply() uses the least RAM

You might suspect that vapply() has less garbage collection because it leaves more garbage uncollected. However, if we look at the total RAM usage, we can see that actually it uses about a third of the RAM of outer():

enter image description here

Note: I don't know how it could actually use 0 bytes in creating a 1x1 matrix - but if you're really comparing two scalars you would probably not use a matrix at all.

What do the garbage collection levels mean?

See the R Internals chapter, The write barrier and the garbage collector:

There are three levels of collections. Level 0 collects only the youngest generation, level 1 collects the two youngest generations and level 2 collects all generations. After 20 level-0 collections the next collection is at level 1, and after 5 level-1 collections at level 2. Further, if a level-n collection fails to provide 20% free space (for each of nodes and the vector heap), the next collection will be at level n+1. (The R-level function gc() performs a level-2 collection.)

The way to understand this is that if a function is creating more temporary objects, and then destroying them, it will do more allocations and have more garbage collection.

Code to run the simulation and generate the first plot

sizes <- c(1, 1e2, 1e3, 1e4)

results <- bench::press(
    size = sizes,
    {
        set.seed(1)
        u <- rnorm(size)
        v <- rnorm(size)

        bench::mark(
            min_iterations = 10,
            check = FALSE,
            outer = {
                mat <- outer(u, v, `<`)
            },
            loop = {
                mat <- matrix(NA, nrow = length(u), ncol = length(v))
                for (i in seq_along(v)) {
                    mat[, i] <- u < v[i]
                }
                mat
            },
            vapply = {
                mat <- vapply(seq_along(v), \(i) u < v[i], logical(length(u)))
            },
            seq = {
                mat <- as.matrix(
                    `<`(
                        rep(u, times = ceiling(length(v) / length(u))),
                        rep(v, rep.int(length(u), length(v)))
                    ),
                    nrow = length(u)
                )
            }
        )
    }
)

ggplot2::autoplot(results) +
    ggplot2::facet_wrap(ggplot2::vars(size),scales="free_x")

Code for the second plot

library(ggplot2)
p  <- results  |>
    dplyr::mutate(
        expr = attr(expression, "description"),
        size = as.factor(size))  |>
    ggplot() +
        geom_col(aes(
            x = reorder(expr, mem_alloc),
            y = mem_alloc,
            fill = size
        ), color= "black") +
        facet_wrap(vars(size), scales="free_y") +
    labs(
        title = "Total RAM usage", 
        y = "Bytes", 
        x = "Expression"
    )

Disclaimer: These are the results on one machine (an unremarkable fairly old laptop). I didn't get the same magnitude of discrepancy between outer() and the for loop as you did so your results may differ.

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