# What's the difference between `1L` and `1`?

I often seen the symbol `1L` (or `2L`, `3L`, etc) appear in R code. Whats the difference between `1L` and `1`? `1==1L` evaluates to `TRUE`. Why is `1L` used in R code?

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So, @James and @Brian explained what 3L means. But why would you use it?

Most of the time it makes no difference - but sometimes you can use it to get your code to run faster and consume less memory. A double ("numeric") vector uses 8 bytes per element. An integer vector uses only 4 bytes per element. For large vectors, that's less wasted memory and less to wade through for the CPU (so it's typically faster).

Mostly this applies when working with indices. Here's an example where adding 1 to an integer vector turns it into a double vector:

``````x <- 1:100
typeof(x) # integer

y <- x+1
typeof(y) # double, twice the memory size
object.size(y) # 840 bytes (on win64)

z <- x+1L
typeof(z) # still integer
object.size(z) # 440 bytes (on win64)
``````

...but also note that working excessively with integers can be dangerous:

``````1e9L * 2L # Works fine; fast lean and mean!
1e9L * 4L # Ooops, overflow!
``````

...and as @Gavin pointed out, the range for integers is roughly -2e9 to 2e9.

A caveat though is that this applies to the current R version (2.13). R might change this at some point (64-bit integers would be sweet, which could enable vectors of length > 2e9). To be safe, you should use `.Machine\$integer.max` whenever you need the maximum integer value (and negate that for the minimum).

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I think the memory requirements by R are the same regardless of type, at least according to `object.size`. What it is useful for is passing to Fortran or C code which may require data of a particular type. –  James Aug 10 '11 at 17:04
Nope, try `object.size(1:100)` vs. `object.size(1:100+0)` it's 400 bytes + some overhead vs. 800 bytes + some overhead. I updated the example above. –  Tommy Aug 10 '11 at 17:14
Ah, yes you are right, although objects of length 1 are both 32 bytes. –  James Aug 10 '11 at 17:20
Worth mentioning that the integer overflow is due to use of 32-bit signed integers, hence restricted to about +/-2*10^9, even on 64-bit R... –  Gavin Simpson Aug 10 '11 at 17:47
Why use 1L over as.integer(1)? I guess the second statement creates a double and then converts to int? –  Zach Aug 10 '11 at 18:39

From the Constants Section of the R Language Definition:

We can use the ‘L’ suffix to qualify any number with the intent of making it an explicit integer. So ‘0x10L’ creates the integer value 16 from the hexadecimal representation. The constant 1e3L gives 1000 as an integer rather than a numeric value and is equivalent to 1000L. (Note that the ‘L’ is treated as qualifying the term 1e3 and not the 3.) If we qualify a value with ‘L’ that is not an integer value, e.g. 1e-3L, we get a warning and the numeric value is created. A warning is also created if there is an unnecessary decimal point in the number, e.g. 1.L.

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So I should use 1L when I want to explicitly create an integer? –  Zach Aug 10 '11 at 16:35
Nice answer, but could you provide the link or command you used to find it? –  Joshua Ulrich Aug 10 '11 at 16:35
@Joshua Here you go: cran.r-project.org/doc/manuals/R-lang.pdf –  Brian Gordon Aug 10 '11 at 16:36
@Brian: thanks, but I wasn't asking for me. ;-) –  Joshua Ulrich Aug 10 '11 at 16:41

L specifies an integer type, rather than a double that the standard numeric class is.

``````> str(1)
num 1
> str(1L)
int 1
``````
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In some situations the type of literal value is vital. As you can see in this sample calling m() with 1 or 1L will call two different methods.

``````public static void main(String[] args) {
m(1);
m(1L);
}

static void m(int n) {
System.out.println("Running int version...");
}

static void m(long n) {
System.out.println("Running long version...");
}
``````
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