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
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:
The standard solution to this in
Some more examples of using
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:
You can find out what it really thinks in decimal:
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:
You can see that they differ by
We can find out for any given computer what this smallest representable number is by looking in R's machine field:
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:
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.
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.
Using the previous examples
Rather, a version which loops over the two vectors must be used
If a functional version of this is desired, it can be written
which can be called as just
Adding to Brian's comment (which is the reason) you can over come this by using
Per Joshua's warning here is the updated code (Thanks Joshua):
Some interesting example - even the order of numbers can make a difference!
This is hackish, but quick: