# Numerical issue with `foldl` and `foldr` in Haskell

I have the following Haskell script which computes the function `f(x) = (2- x) - (2^3 - x^3/12)`

``````calc x = (x - (x ^ 3) / 12)
calc2 x = (calc 2) - (calc x)

calcList1 :: [Float] -> Float
calcList1 l = foldl (+) 0.0 (map calc2 l)

calcList2 :: [Float] -> Float
calcList2 l = foldr (+) 0.0 (map calc2 l)

test1 :: Float -> Float
test1 step = (calcList1 l) - (calcList2 l)
where
l = [0.0,step..2.0]
``````

Function `calcList1` and `calcList2` run `calc2` function on each of list and then uses `foldl` and `foldr` respectively to sum the list. I was expecting both function to return the same answer but it does not.

``````*Main> test1 0.1
9.536743e-7
*Main> test1 0.01
2.2888184e-5
*Main> test1 0.001
2.4414063e-4
*Main> test1 0.0001
-3.7109375e-2
*Main>
``````

Now I am confused. I can't see why numerical issues has to be involved here. Fold are essentially how ones collect each element which should be same in both cases, right?

-
–  leftaroundabout Jan 30 '14 at 11:20
Keep in mind that for many applications, you don't actually need to use `Float`, but will be ok (or even better off) using `Rational` instead. –  kosmikus Jan 30 '14 at 11:28
@kosmikus: yes, but for many applications, you don't actually need to use `Rational`, but will be ok (and better off, provided you know the quirks) using `Double` instead. –  leftaroundabout Jan 30 '14 at 11:44
@leftaroundabout Of course there are use cases for `Float` and `Double`, but `Rational` is in my experience much less widely known, and I've seen many times that people unnecessarily jump to `Double` simply because a number has a dot in it. –  kosmikus Jan 30 '14 at 12:31

In general, the order in which floating point values are added is important. An entry point for own research could be http://en.wikipedia.org/wiki/Loss_of_significance . To summarize the basic caveat, in an oversimplified form:

Due to the limited number of significant bits, you have to assume something like

`````` 100000000000000000.0 + 1.0 = 100000000000000000.0
``````

in floating-point computations. Consequently, when computing

``````  100000000000000000.0
+                  1.0
- 100000000000000000.0
``````

the result will be `0.0` - and thus, be different from

``````  100000000000000000.0
- 100000000000000000.0
+                  1.0
``````

where the result will be `1.0`.

-
More specifically in this case, `100000.0 + 0.1 + 0.1 + ... + 0.1` is different from `0.1 + 0.1 + ... + 0.1 + 100000.0` in LTR evaluation if the repeated additions of the low numbers yield something that is significant enough to show up when added to the large number. –  Sebastian Redl Jan 30 '14 at 11:44