# What's the difference between as.integer() and +0L used on booleans?

I saw `+0L` used in an answer to a question and found out that it works well with matrices / data frames / data tables where `as.integer()` would be unable to preserve the initial data classes.

``````> a <- matrix(TRUE, nrow=3, ncol=3)
> a
[,1] [,2] [,3]
[1,] TRUE TRUE TRUE
[2,] TRUE TRUE TRUE
[3,] TRUE TRUE TRUE
> as.integer(a)
 1 1 1 1 1 1 1 1 1
> a+0L
[,1] [,2] [,3]
[1,]    1    1    1
[2,]    1    1    1
[3,]    1    1    1
``````
• Is there other differences between these approaches?
• What are the pros and cons and caveats when using one or the other?

[edit:] lots of wisdom in comments! Apparently there is many different ways to achieve the same result, some of which I had no idea about, so:

• What are the other ways to achieve what `a+0L` does?
• To get the original dimensions, `'dim<-'(as.integer(a), dim(a))`. If there is `Inf` as one of the elements, `as.integer` coerces it to `NA`, while the `+0L` gives `Inf` value for that element – akrun Feb 9 '15 at 14:31
• Or just `a[] <- as.integer(a)`. Though it doesn't answer the question. – David Arenburg Feb 9 '15 at 14:32
• Or, `storage.mode(a) <- "integer"` – James Feb 9 '15 at 14:39
• Another way to achieve what `a+0L` does is: `apply(a, MARGIN = 1, FUN = as.integer)` – Francesco Palmiotto Feb 9 '15 at 15:00

`x + 0L` is an element wise operation on `x`; as such, it often preserves the shape of the data. `as.integer` isn’t: it takes the whole structure – here, a matrix – and converts it into a one-dimensional integer vector.

That said, in the general case I’d strongly suggest using `as.integer` and discourage `+ 0L` as a clever hack (remember: often, clever ≠ good). If you want to preserve the shape of data I suggest using David’s method from the comments, rather than the `+ 0L` hack:

``````a[] = as.integer(a)
``````

This uses the normal meaning of `as.integer`, but the result is assigned to the individual elements of `a`, rather than `a` itself. In other words, `a`’s shape remains untouched.

• strongly agree. I wonder how `storage.mode(a) <- "integer"` (as commented above by @James) compares in terms of transparency and efficiency – Ben Bolker Feb 9 '15 at 15:05
• I guess `"storage.mode<-"` should be the more formal way to do this since it justs coerces and keeps attributes. `"[<-"`, on the other hand, needs coercions in `as.integer(a)` and when subassigning an "integer" to a, still, "logical" `a`. A benchmark: `m1 = m2 = matrix(TRUE, 1e4, 1e3); system.time({ m1[] = as.integer(m1) }); system.time({ storage.mode(m2) = "integer" })` – alexis_laz Feb 9 '15 at 15:16
• @alexis_laz I have to admit that I find the `storage.mode<-` method terribly obscure. It essentially does very much the same (`mode<-` would in fact call `as.xyz` on the members, `storage.mode<-` does conceptually the same, but more optimised) as `as.integer`, but in a much less clear way. – Konrad Rudolph Feb 9 '15 at 15:29
• I agree that `"storage.mode<-"` and `as.integer` operate the same on the object (both call `coerceVector`), but, I guess, `"storage.mode<-"` has a more flexible functionality in modifying an existing object: it preserves attributes and does not do the extra coercions that `"[<-"` does in the present case. – alexis_laz Feb 9 '15 at 15:47
• @JoshO'Brien : Yes, it concerns `"[<-"`. As a reference, see, also, `do_storage_mode` which seems to just coerce "a" to the wanted `typeof`, while `a[] <- as.integer(a)` coerces "a" in both separate calls (`as.integer` and `"[<-"`). (Sorry for my overloading this answer with comments) – alexis_laz Feb 9 '15 at 20:44

Adding `0L` promotes `a` to integer as described in `?Arithmetic`:

Logical vectors will be coerced to integer or numeric vectors, FALSE having value zero and TRUE having value one.

As a consequence any arithmetic operation using `a` and the identity element for that operation (but doesn't have to go to numeric at some point, eg `/` and `^`) will work:

``````a+0L
a-0L
a*1L
a%/%1
``````

Unary operations will also work, so perhaps the "best" code golf version is:

``````--a
``````

This has a parallel with the common trick of using `!!a` to convert a numeric object to logical.

``````identical(a+0L, a-0L, a*1L, a%/%1L, --a)
 TRUE
``````

Converting back to logical:

``````identical(a, !!--a)
 TRUE
``````

An alternative, and perhaps clearer, approach is to change the `storage.mode` of `a` directly:

``````storage.mode(a) <- "integer"
a
[,1] [,2] [,3]
[1,]    1    1    1
[2,]    1    1    1
[3,]    1    1    1
``````
• Ah, the good old systematic approach to knowledge - reveal the underlying principles! – LauriK Feb 9 '15 at 15:44

`as.integer`, by definition, behaves like `as.vector`, i.e. it strips all attributes ("dim" included) to create an R vector. It won't, just, return the same object with a changed `typeof`. To restore attributes after the coercion, `"dim<-"`, `"names<-"`, `"class<-"` etc. need to be called explicitly or via a function that stores attributes of its arguments (e.g. `"[<-"`). E.g. `"dim<-"(as.integer(a), dim(a))` or `array(as.integer(a), dim(a))` or `a[] <- as.integer(a)`. A benchmark:

``````x = matrix(T, 1e3, 1e3)
microbenchmark::microbenchmark("dim<-"(as.integer(x), dim(x)),
array(as.integer(x), dim(x)),
{ x[] = as.integer(x) }, times = 25)
#Unit: milliseconds
#                           expr      min       lq   median        uq      max neval
# `dim<-`(as.integer(x), dim(x)) 1.650232 1.691296 2.492748  4.237985  5.67872    25
#   array(as.integer(x), dim(x)) 6.226130 6.638513 8.526779  8.973268 47.50351    25
#    {     x[] = as.integer(x) } 7.822421 8.071243 9.658487 10.408435 11.90798    25
``````

In the above, `"dim<-"` justs adds an attribute to the created `as.integer(x)`, `array` allocates a new vector to store the created `as.integer(x)`, and `"[<-"` changes "x" so that it can accept the values of the created `as.integer(x)` and, then, iterates through "x" to insert its new values.

The `"[<-"` method, though, has a disadvantage:

``````x = as.character(1:5)
x
# "1" "2" "3" "4" "5"
x[] = as.integer(x)
x
# "1" "2" "3" "4" "5"
``````

Or:

``````x = 1:5
x
# 1 2 3 4 5
x[] = as.logical(x)
x
# 1 1 1 1 1
``````

But:

``````x = round(runif(5), 2)
x
# 0.68 0.54 0.02 0.14 0.08
x[] = as.character(x)
x
# "0.68" "0.54" "0.02" "0.14" "0.08"
``````

I.e. `"[<-"` won't change the `typeof` of the replaceable object if the `typeof` of replacement object is higher. Subassignment (i.e. `"[<-"`) coerces either the object to be replaced or the replacing object or none depending on their `typeof`s (this is done by `SubassignTypeFix`). @Josh O'Brien notes the possibility for a difference to exist in the behaviour of `"[<-"` if the indices are missing. To be honest, I could not find a specific treatment in such case, as in, for example `do_subset_dflt` (`"["`) that indirectly handles missingness.

As already mentioned, there is, also, `"storage.mode<-"` to change the `typeof` of an object:

``````"storage.mode<-"(as.character(1:5), "integer")
# 1 2 3 4 5
"storage.mode<-"(1:5, "logical")
# TRUE TRUE TRUE TRUE TRUE
"storage.mode<-"(round(runif(5), 2), "character")
# "0.09" "0.38" "0.98" "0.73" "0.81"

x = matrix(T, 1e3, 1e3)
microbenchmark::microbenchmark("storage.mode<-"(x, "integer"),
"dim<-"(as.integer(x), dim(x)), times = 25)
#Unit: milliseconds
#                           expr      min      lq   median       uq      max neval
# `storage.mode<-`(x, "integer") 1.986055 2.01842 2.147181 2.406096 6.019415    25
# `dim<-`(as.integer(x), dim(x)) 1.984664 2.02016 2.111684 2.613854 6.174973    25
``````

Similar in efficiency to `"dim<-"` since they both coerce once and store an attribute.

Binary operations (as mentioned by James and Konrad Rudolph) coerce their arguments to suitable `typeof` and keep attributes ("dim", "names", "class" etc.) depending on rules regarding the two arguments. (Section "Value" in `?Arithmetic`)