# Why are these numbers not equal?

The following code is obviously wrong. What's the problem?

``````i <- 0.1
i <- i + 0.05
i
##  0.15
if(i==0.15) cat("i equals 0.15") else cat("i does not equal 0.15")
## i does not equal 0.15
``````

# General (language agnostic) reason

Since not all numbers can be represented exactly in IEEE floating point arithmetic (the standard that almost all computers use to represent decimal numbers and do math with them), you will not always get what you expected. This is especially true because some values which are simple, finite decimals (such as 0.1 and 0.05) are not represented exactly in the computer and so the results of arithmetic on them may not give a result that is identical to a direct representation of the "known" answer.

This is a well known limitation of computer arithmetic and is discussed in several places:

# Comparing scalars

The standard solution to this in `R` is not to use `==`, but rather the `all.equal` function. Or rather, since `all.equal` gives lots of detail about the differences if there are any, `isTRUE(all.equal(...))`.

``````if(isTRUE(all.equal(i,0.15))) cat("i equals 0.15") else cat("i does not equal 0.15")
``````

yields

``````i equals 0.15
``````

Some more examples of using `all.equal` instead of `==` (the last example is supposed to show that this will correctly show differences).

``````0.1+0.05==0.15
# FALSE
isTRUE(all.equal(0.1+0.05, 0.15))
# TRUE
1-0.1-0.1-0.1==0.7
# FALSE
isTRUE(all.equal(1-0.1-0.1-0.1, 0.7))
# TRUE
0.3/0.1 == 3
# FALSE
isTRUE(all.equal(0.3/0.1, 3))
# TRUE
0.1+0.1==0.15
# FALSE
isTRUE(all.equal(0.1+0.1, 0.15))
# FALSE
``````

Some more detail, directly copied from an answer to a similar question:

The problem you have encountered is that floating point cannot represent decimal fractions exactly in most cases, which means you will frequently find that exact matches fail.

while R lies slightly when you say:

``````1.1-0.2
# 0.9
0.9
# 0.9
``````

You can find out what it really thinks in decimal:

``````sprintf("%.54f",1.1-0.2)
# "0.900000000000000133226762955018784850835800170898437500"
sprintf("%.54f",0.9)
# "0.900000000000000022204460492503130808472633361816406250"
``````

You can see these numbers are different, but the representation is a bit unwieldy. If we look at them in binary (well, hex, which is equivalent) we get a clearer picture:

``````sprintf("%a",0.9)
# "0x1.ccccccccccccdp-1"
sprintf("%a",1.1-0.2)
# "0x1.ccccccccccccep-1"
sprintf("%a",1.1-0.2-0.9)
# "0x1p-53"
``````

You can see that they differ by `2^-53`, which is important because this number is the smallest representable difference between two numbers whose value is close to 1, as this is.

We can find out for any given computer what this smallest representable number is by looking in R's machine field:

`````` ?.Machine
#....
#double.eps     the smallest positive floating-point number x
#such that 1 + x != 1. It equals base^ulp.digits if either
#base is 2 or rounding is 0; otherwise, it is
#(base^ulp.digits) / 2. Normally 2.220446e-16.
#....
.Machine\$double.eps
# 2.220446e-16
sprintf("%a",.Machine\$double.eps)
# "0x1p-52"
``````

You can use this fact to create a 'nearly equals' function which checks that the difference is close to the smallest representable number in floating point. In fact this already exists: `all.equal`.

``````?all.equal
#....
#all.equal(x,y) is a utility to compare R objects x and y testing ‘near equality’.
#....
#all.equal(target, current,
#      tolerance = .Machine\$double.eps ^ 0.5,
#      scale = NULL, check.attributes = TRUE, ...)
#....
``````

So the all.equal function is actually checking that the difference between the numbers is the square root of the smallest difference between two mantissas.

This algorithm goes a bit funny near extremely small numbers called denormals, but you don't need to worry about that.

# Comparing vectors

The above discussion assumed a comparison of two single values. In R, there are no scalars, just vectors and implicit vectorization is a strength of the language. For comparing the value of vectors element-wise, the previous principles hold, but the implementation is slightly different. `==` is vectorized (does an element-wise comparison) while `all.equal` compares the whole vectors as a single entity.

Using the previous examples

``````a <- c(0.1+0.05, 1-0.1-0.1-0.1, 0.3/0.1, 0.1+0.1)
b <- c(0.15,     0.7,           3,       0.15)
``````

`==` does not give the "expected" result and `all.equal` does not perform element-wise

``````a==b
# FALSE FALSE FALSE FALSE
all.equal(a,b)
# "Mean relative difference: 0.01234568"
isTRUE(all.equal(a,b))
# FALSE
``````

Rather, a version which loops over the two vectors must be used

``````mapply(function(x, y) {isTRUE(all.equal(x, y))}, a, b)
#  TRUE  TRUE  TRUE FALSE
``````

If a functional version of this is desired, it can be written

``````elementwise.all.equal <- Vectorize(function(x, y) {isTRUE(all.equal(x, y))})
``````

which can be called as just

``````elementwise.all.equal(a, b)
#  TRUE  TRUE  TRUE FALSE
``````

Alternatively, instead of wrapping `all.equal` in even more function calls, you can just replicate the relevant internals of `all.equal.numeric` and use implicit vectorization:

``````tolerance = .Machine\$double.eps^0.5
# this is the default tolerance used in all.equal,
# but you can pick a different tolerance to match your needs

abs(a - b) < tolerance
#  TRUE  TRUE  TRUE FALSE
``````

This is the approach taken by `dplyr::near`, which documents itself as

This is a safe way of comparing if two vectors of floating point numbers are (pairwise) equal. This is safer than using `==`, because it has a built in tolerance

``````dplyr::near(a, b)
#  TRUE  TRUE  TRUE FALSE
``````
• R is a free software environment for statistical computing?? – kittygirl Jun 17 at 17:05

Adding to Brian's comment (which is the reason) you can over come this by using `all.equal` instead:

``````# i <- 0.1
# i <- i + 0.05
# i
#if(all.equal(i, .15)) cat("i equals 0.15\n") else cat("i does not equal 0.15\n")
#i equals 0.15
``````

Per Joshua's warning here is the updated code (Thanks Joshua):

`````` i <- 0.1
i <- i + 0.05
i
if(isTRUE(all.equal(i, .15))) { #code was getting sloppy &went to multiple lines
cat("i equals 0.15\n")
} else {
cat("i does not equal 0.15\n")
}
#i equals 0.15
``````
• `all.equal` doesn't return `FALSE` when there are differences, so you need to wrap it with `isTRUE` when using it in an `if` statement. – Joshua Ulrich Mar 1 '12 at 0:49

This is hackish, but quick:

``````if(round(i, 10)==0.15) cat("i equals 0.15") else cat("i does not equal 0.15")
``````
• But you can use the `all.equal(... tolerance)` parameter. `all.equal(0.147, 0.15, tolerance=0.05)` is TRUE. – smci May 28 '18 at 11:25

`dplyr::near()` is an option for testing if two vectors of floating point numbers are equal. This is the example from the docs:

``````sqrt(2) ^ 2 == 2
#>  FALSE
library(dplyr)
near(sqrt(2) ^ 2, 2)
#>  TRUE
``````

The function has a built in tolerance parameter: `tol = .Machine\$double.eps^0.5` that can be adjusted. The default parameter is the same as the default for `all.equal()`.

I had a similar problem. I used the following solution.

@ I found this work around solution about unequal cut intervals. @ I used the round function in R. By setting the option to 2 digits, did not solved the problem.

``````options(digits = 2)
cbind(
seq(      from = 1, to = 9, by = 1 ),
cut( seq( from = 1, to = 9, by = 1),          c( 0, 3, 6, 9 ) ),
seq(      from = 0.1, to = 0.9, by = 0.1 ),
cut( seq( from = 0.1, to = 0.9, by = 0.1),    c( 0, 0.3, 0.6, 0.9 )),
seq(      from = 0.01, to = 0.09, by = 0.01 ),
cut( seq( from = 0.01, to = 0.09, by = 0.01),    c( 0, 0.03, 0.06, 0.09 ))
)
``````

output of unequal cut intervals based on options(digits = 2):

``````  [,1] [,2] [,3] [,4] [,5] [,6]
[1,]    1    1  0.1    1 0.01    1
[2,]    2    1  0.2    1 0.02    1
[3,]    3    1  0.3    2 0.03    1
[4,]    4    2  0.4    2 0.04    2
[5,]    5    2  0.5    2 0.05    2
[6,]    6    2  0.6    2 0.06    3
[7,]    7    3  0.7    3 0.07    3
[8,]    8    3  0.8    3 0.08    3
[9,]    9    3  0.9    3 0.09    3

options(digits = 200)
cbind(
seq(      from = 1, to = 9, by = 1 ),
cut( round(seq( from = 1, to = 9, by = 1), 2),          c( 0, 3, 6, 9 ) ),
seq(      from = 0.1, to = 0.9, by = 0.1 ),
cut( round(seq( from = 0.1, to = 0.9, by = 0.1), 2),    c( 0, 0.3, 0.6, 0.9 )),
seq(      from = 0.01, to = 0.09, by = 0.01 ),
cut( round(seq( from = 0.01, to = 0.09, by = 0.01), 2),    c( 0, 0.03, 0.06, 0.09 ))
)
``````

output of equal cut intervals based on round function:

``````      [,1] [,2] [,3] [,4] [,5] [,6]
[1,]    1    1  0.1    1 0.01    1
[2,]    2    1  0.2    1 0.02    1
[3,]    3    1  0.3    1 0.03    1
[4,]    4    2  0.4    2 0.04    2
[5,]    5    2  0.5    2 0.05    2
[6,]    6    2  0.6    2 0.06    2
[7,]    7    3  0.7    3 0.07    3
[8,]    8    3  0.8    3 0.08    3
[9,]    9    3  0.9    3 0.09    3
``````

Generalized comparisons ("<=", ">=", "=") in double precion arithmetic:

Comparing a <= b:

``````IsSmallerOrEqual <- function(a,b) {
# Control the existence of "Mean relative difference..." in all.equal;
# if exists, it results in character, not logical:
if (   class(all.equal(a, b)) == "logical" && (a<b | all.equal(a, b))) { return(TRUE)
} else if (a < b) { return(TRUE)
} else { return(FALSE) }
}

IsSmallerOrEqual(abs(-2-(-2.2)), 0.2) # TRUE
IsSmallerOrEqual(abs(-2-(-2.2)), 0.3) # TRUE
IsSmallerOrEqual(abs(-2-(-2.2)), 0.1) # FALSE
IsSmallerOrEqual(3,3); IsSmallerOrEqual(3,4); IsSmallerOrEqual(4,3)
# TRUE; TRUE; FALSE
``````

Comparing a >= b:

``````IsBiggerOrEqual <- function(a,b) {
# Control the existence of "Mean relative difference..." in all.equal;
# if exists, it results in character, not logical:
if (   class(all.equal(a, b)) == "logical" && (a>b | all.equal(a, b))) { return(TRUE)
} else if (a > b) { return(TRUE)
} else { return(FALSE) }
}
IsBiggerOrEqual(3,3); IsBiggerOrEqual(4,3); IsBiggerOrEqual(3,4)
# TRUE; TRUE; FALSE
``````

Comparing a = b:

``````IsEqual <- function(a,b) {
# Control the existence of "Mean relative difference..." in all.equal;
# if exists, it results in character, not logical:
if (   class(all.equal(a, b)) == "logical" ) { return(TRUE)
} else { return(FALSE) }
}

IsEqual(0.1+0.05,0.15) # TRUE
``````