[Rd] Floating point maths in R

Duncan Murdoch murdoch at stats.uwo.ca
Sat Dec 9 14:49:40 CET 2006


On 12/9/2006 8:29 AM, Tom McCallum wrote:
> Hi,
> 
> I am not sure if this is just me using R (R-2.3.1 and R-2.4.0) in the  
> wrong way or if there is a more serious bug.  I was having problems  
> getting some calculations to add up so I ran the following tests:

You should read the FAQ item "Why doesn't R think these numbers are 
equal?" at


http://cran.r-project.org/doc/FAQ/R-FAQ.html#Why-doesn_0027t-R-think-these-numbers-are-equal_003f

Duncan Murdoch

> 
>> (2.34567 - 2.00000) == 0.34567 <------- should be true
> [1] FALSE
>> (2.23-2.00) == 0.23 <------- should be true
> [1] FALSE
>> 4-2==2
> [1] TRUE
>> (4-2)==2
> [1] TRUE
>> (4.0-2)==2
> [1] TRUE
>> (4.0-2.0)==2
> [1] TRUE
>> (4.0-2.0)==2.0
> [1] TRUE
>> (4.2-2.2)==2.0
> [1] TRUE
>> (4.20-2.20)==2.00
> [1] TRUE
>> (4.23-2.23)==2.00  <------- should be true
> [1] FALSE
>> (4.230-2.230)==2.000 <------- should be true
> [1] FALSE
>> (4.230-2.230)==2.00 <------- should be true
> [1] FALSE
>> (4.230-2.23)==2.00 <------- should be true
> [1] FALSE
> 
> I have tried these on both 64 and 32-bit machines.  Surely R should be  
> able to do maths to 2 decimal places and be able to test these simple  
> expressions?  The problem occurs as in the 16th decimal place junk is  
> being placed by the FPU it seems.  I have also tried:
> 
>> (4.2300000000000000-2.230000000000000) == 2
> [1] FALSE
>> a <- (4.2300000000000000-2.230000000000000)
>> a == 2
> [1] FALSE
>> (4.2300000000000000-2.230000000000000) == 2.0000000000000000
> [1] FALSE
>> (4.2300000000000000-2.230000000000000) == 2.0000000000000004 <-- correct  
>> when add 16th decimal place to 4
> [1] TRUE
>> (4.2300000000000000-2.230000000000000) == 2.00000000000000043  <-- any  
>> values after the 16th decimal place mean that the expression is true
> [1] TRUE
>> (4.2300000000000000-2.230000000000000) == 2.000000000000000435
> [1] TRUE
> 
> Also :
> 
>> (4.2300000000000000-2.230000000000000) == 2.0000000000000001
> [1] FALSE
>> (4.2300000000000000-2.230000000000000) == 2.0000000000000003
> [1] TRUE
>> (4.2300000000000000-2.230000000000000) == 2.0000000000000004
> [1] TRUE
>> (4.2300000000000000-2.230000000000000) == 2.0000000000000005
> [1] TRUE
>> (4.2300000000000000-2.230000000000000) == 2.0000000000000006 <-- 3,5 I  
>> can understand being true if rounding occurring, but 6?
> [1] TRUE
>> (4.2300000000000000-2.230000000000000) == 2.0000000000000007
> [1] FALSE
>> (4.2300000000000000-2.230000000000000) == 2.0000000000000008
> [1] FALSE
>> (4.2300000000000000-2.230000000000000) == 2.0000000000000009
> [1] FALSE
>> (4.2300000000000000-2.230000000000000) == 2.0000000000000010
> 
> 
> This is an example of junk being added in the FPU
>> formatC(a, digits=20)
> [1] "2.0000000000000004441"
> 
> I don't know if this is just a formatC error when using more than 16  
> decimal places or if this junk is what is stopping the equality from being  
> true:
> 
>> formatC(a, digits=16)
> [1] "                2"
>> formatC(a, digits=17)  <-- 16 decimal places, 17 significant figures  
>> shown
> [1] "2.0000000000000004" <-- the problem is the 4 at the end
> 
> Obviously the bytes are divided between the exponent and mantissa in  
> 16-16bit share it seems, but this doesn't account for the 16th decimal  
> place behaviour does it?
> 
> If any one has a work around or reason why this should occur it would be  
> useful to know.
> 
> what I would like is to be able to do sums such as (2.3456 - 2 ) == 0.3456  
> and get a sensible answer - any suggestions?  Currently the only way is  
> for formatC the expression to a known number of decimal places - is there  
> a better way?
> 
> Many thanks
> 
> Tom
> 
>



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