# Check if the number is integer

I was surprised to learn that R doesn't come with a handy function to check if the number is integer.

``````is.integer(66) # FALSE
``````

The help files warns:

`is.integer(x)` does not test if `x` contains integer numbers! For that, use `round`, as in the function `is.wholenumber(x)` in the examples.

The example has this custom function as a "workaround"

``````is.wholenumber <- function(x, tol = .Machine\$double.eps^0.5)  abs(x - round(x)) < tol
is.wholenumber(1) # is TRUE
``````

If I would have to write a function to check for integers, assuming I hadn't read the above comments, I would write a function that would go something along the lines of

``````check.integer <- function(x) {
x == round(x)
}
``````

Where would my approach fail? What would be your work around if you were in my hypothetical shoes?

• I would hope that if `round(x)` is implemented properly, the result of applying it to an integer would always be that integer... Aug 13, 2010 at 12:39
• Take a look at the FAQ on R cran.r-project.org/doc/FAQ/… Aug 13, 2010 at 16:27
• > check.integer(9.0) [1] TRUE it's not. Jul 26, 2012 at 1:58
• @PengPeng, VitoshKa fixed this in the accepted answer. Jul 26, 2012 at 6:53
• I think there is a confusion about mathematical and computational concepts of integer. The function `is.integer` checks the computational concept, the `check.integer` user function checks the mathematical point of view. Nov 20, 2014 at 14:08

Another alternative is to check the fractional part:

``````x%%1==0
``````

or, if you want to check within a certain tolerance:

``````min(abs(c(x%%1, x%%1-1))) < tol
``````
• does the tolerance-checking suggestion really work?? `x <- 5-1e-8; x%%1` gives 0.9999999 (which would imply if `tol==1e-5` for example) that `x` is not an integer. Jan 24, 2014 at 15:34
• @BenBolker Good catch, it works for positive perturbations I think. I've changed it to an alternative solution should work. Jan 24, 2014 at 16:23
• @James, I think it should be `min(abs(c(x%%1, x%%1-1))) < tol` instead of `abs(min(x%%1, x%%1-1)) < tol` otherwise, you'll get `FALSE` for any integer...
– Cath
May 27, 2015 at 9:37
• What's wrong with `as.integer(x) == x`? It will not reject 3 or 3.0 like `is.integer(x)` would, and it will catch 3.1.
– Gabi
Oct 1, 2015 at 19:04

Here's a solution using simpler functions and no hacks:

``````all.equal(a, as.integer(a))
``````

What's more, you can test a whole vector at once, if you wish. Here's a function:

``````testInteger <- function(x){
test <- all.equal(x, as.integer(x), check.attributes = FALSE)
if(test == TRUE){ return(TRUE) }
else { return(FALSE) }
}
``````

You can change it to use `*apply` in the case of vectors, matrices, etc.

• The last `if` `else` could be done with simply `isTRUE(test)`. Indeed that is all you need to replace the `if` `else` clause and the `return` statements as R automatically returns the result of the last evaluation. Mar 5, 2013 at 16:00
• `testInteger(1.0000001)` [1] FALSE `testInteger(1.00000001)` [1] TRUE May 25, 2015 at 18:38
• `all(a == as.integer(a))` gets around this problem!'
– Alex
Mar 4, 2017 at 5:04
• This is not working properly! Check out the following counter-example: frac_test <- 1/(1-0.98), all.equal(frac_test, as.integer(frac_test)), isTRUE(all.equal(frac_test, as.integer(frac_test))) May 6, 2018 at 8:03

Here is one, apparently reliable way:

``````check.integer <- function(N){
!grepl("[^[:digit:]]", format(N,  digits = 20, scientific = FALSE))
}

check.integer(3243)
#TRUE
check.integer(3243.34)
#FALSE
check.integer("sdfds")
#FALSE
``````

This solution also allows for integers in scientific notation:

``````> check.integer(222e3)
[1] TRUE
``````
• This doesn't look very reliable to me: `check.integer(1e4)` is TRUE, while `check.integer(1e5)` is FALSE.
– wch
Feb 14, 2012 at 18:02
• -1 This is worse than `is.wholenumber`, or any of the other solutions provided in other answers. These shouldn't be different: `check.integer(1e22); check.integer(1e23)`. You can obviously change the regex to fix this, but this approach is dreadful. (Comment comes from attribution in the installr package.) Mar 5, 2013 at 15:30
• @PatrickT, I see. It's the default digit's argument. use `format(40, scientific = FALSE, digits = 20)` instead. I have updated the answer. Thanks for spotting it. May 28, 2015 at 16:38
• @PatrickT You are in the realm of machine dependent rounding errors. In that respect my solution is the same as the accepted one `1.0000000000000001 == 1L [1] TRUE`. But my solution is better if you already get a number in string form `check.integer("1000000000000000000000000000000000001") [1] TRUE` Jun 1, 2015 at 19:42
• @VitoshKa loved your answer! Although there is one point that you missed, negative numbers without decimal points are also integer ;) I modified your code accordingly. Dec 4, 2015 at 23:33

Reading the R language documentation, `as.integer` has more to do with how the number is stored than if it is practically equivalent to an integer. `is.integer` tests if the number is declared as an integer. You can declare an integer by putting a `L` after it.

``````> is.integer(66L)
[1] TRUE
> is.integer(66)
[1] FALSE
``````

Also functions like `round` will return a declared integer, which is what you are doing with `x==round(x)`. The problem with this approach is what you consider to be practically an integer. The example uses less precision for testing equivalence.

``````> is.wholenumber(1+2^-50)
[1] TRUE
> check.integer(1+2^-50)
[1] FALSE
``````

So depending on your application you could get into trouble that way.

• The second line says "as.integer tests if the number is declared as an integer." but I am pretty sure you meant "is.integer". It is only a one character edit so I couldn't easily change it. Mar 18, 2017 at 1:23

It appears that you do not see the need to incorporate some error tolerance. It would not be needed if all integers came entered as integers, however sometimes they come as a result of arithmetic operations that loose some precision. For example:

``````> 2/49*49
[1] 2
> check.integer(2/49*49)
[1] FALSE
> is.wholenumber(2/49*49)
[1] TRUE
``````

Note that this is not R's weakness, all computer software have some limits of precision.

• just in case some people don't quite get what happened here... if you enter as.integer(2/49*49) you get 1 !! [BTW, it is ever so frustrating that R doesn't present the result of the initial calculation as 2.0 to represent that the value has some decimal component) see... stackoverflow.com/questions/1535021/…
– John
Aug 13, 2010 at 13:52

From `Hmisc::spss.get`:

``````all(floor(x) == x, na.rm = TRUE)
``````

much safer option, IMHO, since it "bypasses" the machine precision issue. If you try `is.integer(floor(1))`, you'll get `FALSE`. BTW, your integer will not be saved as integer if it's bigger than `.Machine\$integer.max` value, which is, by default 2147483647, so either change the `integer.max` value, or do the alternative checks...

• if `x <- sqrt(2)^2`, then `all(floor(x) == x, na.rm = TRUE)` return `FALSE` Jul 23, 2019 at 20:42

you can use simple if condition like:

``````if(round(var) != var)­­­­­­­­­­­­­­­­­­­­­­­­­­­­­­­­­
``````

In R, whether a number is numeric or integer can be determined by class function. Generally all numbers are stored as numeric and to explicitly define a number as integer we need to specify 'L' after the number.

Example:

x <- 1

class(x)

[1] "numeric"

x <- 1L

class(x)

[1] "integer"

I hope this is what was needed. Thanks :)

[UPDATE] ==============================================================

Respect to the [OLD] answer here below, I have discovered that it worked because I have put all the numbers in a single atomic vector; one of them was a character, so every one become characters.

If we use a list (hence, coercion does not happen) all the test pass correctly but one: `1/(1 - 0.98)`, which remains a `numeric`. This because the `tol` parameter is by default `100 * .Machine\$double.eps` and that number is far from `50` little less than the double of that. So, basically, for this kind of numbers, we have to decide our tolerance!

So if you want all test became `TRUE`, you can `assertive::is_whole_number(x, tol = 200 * .Machine\$double.eps)`

Anyway, I confirm that IMO assertive remains the best solution.

Here below a reprex for this [UPDATE].

``````expect_trues_c <- c(
cl = sqrt(2)^2,
pp = 9.0,
t = 1 / (1 - 0.98),
ar0 = 66L,
ar1 = 66,
ar2 = 1 + 2^-50,
v = 222e3,
w1 = 1e4,
w2 = 1e5,
v2 = "1000000000000000000000000000000000001",
an = 2 / 49 * 49,
ju1 = 1e22,
ju2 = 1e24,
al = floor(1),
v5 = 1.0000000000000001 # this is under machine precision!
)

str(expect_trues_c)
#>  Named chr [1:15] "2" "9" "50" "66" "66" "1" "222000" "10000" "1e+05" ...
#>  - attr(*, "names")= chr [1:15] "cl" "pp" "t" "ar0" ...
assertive::is_whole_number(expect_trues_c)
#> Warning: Coercing expect_trues_c to class 'numeric'.
#>                      2                      9                     50
#>                   TRUE                   TRUE                   TRUE
#>                     66                     66                      1
#>                   TRUE                   TRUE                   TRUE
#>                 222000                  10000                 100000
#>                   TRUE                   TRUE                   TRUE
#>                  1e+36                      2                  1e+22
#>                   TRUE                   TRUE                   TRUE
#> 9.9999999999999998e+23                      1                      1
#>                   TRUE                   TRUE                   TRUE

expect_trues_l <- list(
cl = sqrt(2)^2,
pp = 9.0,
t = 1 / (1 - 0.98),
ar0 = 66L,
ar1 = 66,
ar2 = 1 + 2^-50,
v = 222e3,
w1 = 1e4,
w2 = 1e5,
v2 = "1000000000000000000000000000000000001",
an = 2 / 49 * 49,
ju1 = 1e22,
ju2 = 1e24,
al = floor(1),
v5 = 1.0000000000000001 # this is under machine precision!
)

str(expect_trues_l)
#> List of 15
#>  \$ cl : num 2
#>  \$ pp : num 9
#>  \$ t  : num 50
#>  \$ ar0: int 66
#>  \$ ar1: num 66
#>  \$ ar2: num 1
#>  \$ v  : num 222000
#>  \$ w1 : num 10000
#>  \$ w2 : num 1e+05
#>  \$ v2 : chr "1000000000000000000000000000000000001"
#>  \$ an : num 2
#>  \$ ju1: num 1e+22
#>  \$ ju2: num 1e+24
#>  \$ al : num 1
#>  \$ v5 : num 1
assertive::is_whole_number(expect_trues_l)
#> Warning: Coercing expect_trues_l to class 'numeric'.
#> There was 1 failure:
#>   Position              Value      Cause
#> 1        3 49.999999999999957 fractional
assertive::is_whole_number(expect_trues_l, tol = 200 * .Machine\$double.eps)
#> Warning: Coercing expect_trues_l to class 'numeric'.
#>     2.0000000000000004                      9     49.999999999999957
#>                   TRUE                   TRUE                   TRUE
#>                     66                     66     1.0000000000000009
#>                   TRUE                   TRUE                   TRUE
#>                 222000                  10000                 100000
#>                   TRUE                   TRUE                   TRUE
#>                  1e+36     1.9999999999999998                  1e+22
#>                   TRUE                   TRUE                   TRUE
#> 9.9999999999999998e+23                      1                      1
#>                   TRUE                   TRUE                   TRUE

expect_falses <- list(
bb = 5 - 1e-8,
pt1 = 1.0000001,
pt2 = 1.00000001,
v3 = 3243.34,
v4 = "sdfds"
)

str(expect_falses)
#> List of 5
#>  \$ bb : num 5
#>  \$ pt1: num 1
#>  \$ pt2: num 1
#>  \$ v3 : num 3243
#>  \$ v4 : chr "sdfds"
assertive::is_whole_number(expect_falses)
#> Warning: Coercing expect_falses to class 'numeric'.
#> Warning in as.this_class(x): NAs introduced by coercion
#> There were 5 failures:
#>   Position              Value      Cause
#> 1        1 4.9999999900000001 fractional
#> 2        2 1.0000001000000001 fractional
#> 3        3 1.0000000099999999 fractional
#> 4        4 3243.3400000000001 fractional
#> 5        5               <NA>    missing
assertive::is_whole_number(expect_falses, tol = 200 * .Machine\$double.eps)
#> Warning: Coercing expect_falses to class 'numeric'.

#> Warning: NAs introduced by coercion
#> There were 5 failures:
#>   Position              Value      Cause
#> 1        1 4.9999999900000001 fractional
#> 2        2 1.0000001000000001 fractional
#> 3        3 1.0000000099999999 fractional
#> 4        4 3243.3400000000001 fractional
#> 5        5               <NA>    missing
``````

Created on 2019-07-23 by the reprex package (v0.3.0)

[OLD] =================================================================

IMO the best solution comes from the `assertive` package (which, for the moment, solve all positive and negative examples in this thread):

``````are_all_whole_numbers <- function(x) {
all(assertive::is_whole_number(x), na.rm = TRUE)
}

are_all_whole_numbers(c(
cl = sqrt(2)^2,
pp = 9.0,
t = 1 / (1 - 0.98),
ar0 = 66L,
ar1 = 66,
ar2 = 1 + 2^-50,
v = 222e3,
w1 = 1e4,
w2 = 1e5,
v2 = "1000000000000000000000000000000000001",
an = 2 / 49 * 49,
ju1 = 1e22,
ju2 = 1e24,
al = floor(1),
v5 = 1.0000000000000001 # difference is under machine precision!
))
#> Warning: Coercing x to class 'numeric'.
#> [1] TRUE

are_all_not_whole_numbers <- function(x) {
all(!assertive::is_whole_number(x), na.rm = TRUE)
}

are_all_not_whole_numbers(c(
bb = 5 - 1e-8,
pt1 = 1.0000001,
pt2 = 1.00000001,
v3 = 3243.34,
v4 = "sdfds"
))
#> Warning: Coercing x to class 'numeric'.
#> Warning in as.this_class(x): NAs introduced by coercion
#> [1] TRUE
``````

Created on 2019-07-23 by the reprex package (v0.3.0)

If you prefer not to write your own function, try `check.integer` from package installr. Currently it uses VitoshKa's answer.

Also try `check.numeric(v, only.integer=TRUE)` from package varhandle, which has the benefit of being vectorized.

Here's my attempt at a solution using Rcpp for the case when you want to check that all numbers are whole numbers.

Edit: Updated the C++ function.

### Rcpp function

``````library(bench)
library(Rcpp)

cppFunction('SEXP cpp_is_whole_num(SEXP x, SEXP tol, bool na_rm = true) {
R_xlen_t n = Rf_xlength(x);
int tol_len = Rf_length(tol);
if (tol_len > 1){
Rcpp::stop("tol must be of length <= 1");
}
if (tol_len == 0){
n = 0;
}
bool is_whole;
R_xlen_t n_na = 0;
bool is_na;
SEXP out = PROTECT(Rf_allocVector(LGLSXP, 1));
int *p_out = INTEGER(out);
p_out[0] = false;
switch ( TYPEOF(x) ){
case LGLSXP:
case INTSXP: {
p_out[0] = true;
break;
}
case REALSXP: {
// Re-initialise so that we can break when we find non-whole num
p_out[0] = true;
double *p_x = REAL(x);
double *p_t = REAL(tol);
for (R_xlen_t i = 0; i < n; ++i) {
is_na = !(p_x[i] == p_x[i]);
n_na += is_na;
if (!is_whole && !is_na){
p_out[0] = false;
break;
}
}
if (!na_rm && n_na > 0){
p_out[0] = NA_LOGICAL;
break;
}
break;
}
}
UNPROTECT(1);
return out;
}')
``````

### Benchmark

``````x1 <- c(1:10^7, 0.01)
x2 <- c(0.01, 1:10^7)

# Non-integers at the end of the vector

mark(james = all(x1%%1==0),
iterator = isTRUE(all.equal(x1, as.integer(x1))),
me = cpp_is_whole_num(x1, sqrt(.Machine\$double.eps)))
#> Warning: Some expressions had a GC in every iteration; so filtering is
#> disabled.
#> # A tibble: 3 × 6
#>   expression      min   median `itr/sec` mem_alloc `gc/sec`
#>   <bch:expr> <bch:tm> <bch:tm>     <dbl> <bch:byt>    <dbl>
#> 1 james       306.4ms    318ms      3.15  114.44MB     3.15
#> 2 iterator    271.2ms    273ms      3.66  305.46MB     5.50
#> 3 me           34.3ms     38ms     24.0     2.49KB     0

# Non-integers at the start of the vector

mark(james = all(x2%%1==0),
iterator = isTRUE(all.equal(x2, as.integer(x2))),
me = cpp_is_whole_num(x2, sqrt(.Machine\$double.eps)))
#> Warning: Some expressions had a GC in every iteration; so filtering is
#> disabled.
#> # A tibble: 3 × 6
#>   expression      min   median `itr/sec` mem_alloc `gc/sec`
#>   <bch:expr> <bch:tm> <bch:tm>     <dbl> <bch:byt>    <dbl>
#> 1 james       242.1ms  264.8ms      3.78  114.44MB     1.89
#> 2 iterator    215.5ms  266.4ms      3.71  305.18MB     7.42
#> 3 me            1.7µs    2.8µs 266295.      2.49KB     0

# R wrapper to account for non-numeric classes and coercion
is_whole_number <- function(x, tol = sqrt(.Machine\$double.eps), na.rm = TRUE){
is.numeric(x) && cpp_is_whole_num(x, tol = as.double(tol), na_rm = na.rm)
}

## NA handling
x <- c(1, NA)
y <- c(1.5, NA)

is_whole_number(x, na.rm = F)
#> [1] NA
is_whole_number(y, na.rm = F)
#> [1] FALSE
``````

Created on 2023-10-26 with reprex v2.0.2

Once can also use `dplyr::near`:

``````library(dplyr)

near(a, as.integer(a))
``````

It applies to any vector `a`, and has an optional tolerance parameter.

For a vector `m`, `m[round(m) != m]` will return the indices of values in the vector that are not integers.

I am not sure what you are trying to accomplish. But here are some thoughts:
1. Convert to integer:
```num = as.integer(123.2342) ```
2. Check if a variable is an integer:
``` is.integer(num) typeof(num)=="integer"```

• I'm just making sure the users enters an appropriate number - we're talking about the number of "subjects", which can be only an integer. Aug 14, 2010 at 17:46