# F# Floating point ranges are experimental and may be deprecated

I'm trying to make a little function to interpolate between two values with a given increment.

``````[ 1.0 .. 0.5 .. 20.0 ]
``````

The compiler tells me that this is deprecated, and suggests using ints then casting to float. But this seems a bit long-winded if I have a fractional increment - do I have to divide my start and end values by my increment, then multiple again afterwards? (yeuch!).

I saw something somewhere once about using sequence comprehensions to do this, but I can't remember how.

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You should go via ints because it is numerically robust. Otherwise, you're likely to get round-off error from accumulating floating point additions that culminates in a final value slightly bigger than it should be and than your end point so it get incorrectly dropped from the end of your sequence. –  Jon Harrop Mar 26 '11 at 12:01

TL;DR: F# PowerPack's `BigRational` type is the way to go.

## What's Wrong with Floating-point Loops

As many have pointed out, `float` values are not suitable for looping:

• They do have Round Off Error, just like with `1/3` in decimal, we inevitably lose all digits starting at a certain exponent;
• They do experience Catastrophic Cancellation (when subtracting two almost equal numbers, the result is rounded to zero);
• They always have non-zero Machine epsilon, so the error is increased with every math operation (unless we are adding different numbers many times so that errors mutually cancel out -- but this is not the case for the loops);
• They do have different accuracy across the range: the number of unique values in a range `[0.0000001 .. 0.0000002]` is equivalent to the number of unique values in `[1000000 .. 2000000]`;

## Solution

What can instantly solve the above problems, is switching back to integer logic.

With F# PowerPack, you may use `BigRational` type:

``````open Microsoft.FSharp.Math
// [1 .. 1/3 .. 20]
[1N .. 1N/3N .. 20N]
|> List.map float
|> List.iter (printf "%f; ")
``````

Note, I took my liberty to set the step to `1/3` because `0.5` from your question actually has an exact binary representation 0.1b and is represented as +1.00000000000000000000000 * 2-1; hence it does not produce any cumulative summation error.

Outputs:

1.000000; 1.333333; 1.666667; 2.000000; 2.333333; 2.666667; 3.000000; (skipped) 18.000000; 18.333333; 18.666667; 19.000000; 19.333333; 19.666667; 20.000000;

``````// [0.2 .. 0.1 .. 3]
[1N/5N .. 1N/10N .. 3N]
|> List.map float
|> List.iter (printf "%f; ")
``````

Outputs:

0.200000; 0.300000; 0.400000; 0.500000; (skipped) 2.800000; 2.900000; 3.000000;

## Conclusion

• `BigRational` uses integer computations, which are not slower than for floating-points;
• The round-off occurs only once for each value (upon conversion to a `float`, but not within the loop);
• `BigRational` acts as if the machine epsilon were zero;

There is an obvious limitation: you can't use irrational numbers like `pi` or `sqrt(2)` as they have no exact representation as a fraction. It does not seem to be a very big problem because usually, we are not looping over both rational and irrational numbers, e.g. `[1 .. pi/2 .. 42]`. If we do (like for geometry computations), there's usually a way to reduce the irrational part, e.g. switching from radians to degrees.

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Excellent answer, thank you! –  Benjol Jun 25 at 4:42

Interestingly, float ranges don't appear to be deprecated anymore. And I remember seeing a question recently (sorry, couldn't track it down) talking about the inherent issues which manifest with float ranges, e.g.

``````> let xl = [0.2 .. 0.1 .. 3.0];;

val xl : float list =
[0.2; 0.3; 0.4; 0.5; 0.6; 0.7; 0.8; 0.9; 1.0; 1.1; 1.2; 1.3; 1.4; 1.5; 1.6;
1.7; 1.8; 1.9; 2.0; 2.1; 2.2; 2.3; 2.4; 2.5; 2.6; 2.7; 2.8; 2.9]
``````

I just wanted to point out that you can use ranges on `decimal` types with a lot less of these kind of rounding issues, e.g.

``````> [0.2m .. 0.1m .. 3.0m];;
val it : decimal list =
[0.2M; 0.3M; 0.4M; 0.5M; 0.6M; 0.7M; 0.8M; 0.9M; 1.0M; 1.1M; 1.2M; 1.3M;
1.4M; 1.5M; 1.6M; 1.7M; 1.8M; 1.9M; 2.0M; 2.1M; 2.2M; 2.3M; 2.4M; 2.5M;
2.6M; 2.7M; 2.8M; 2.9M; 3.0M]
``````

And if you really do need floats in the end, then you can do something like

``````> {0.2m .. 0.1m .. 3.0m} |> Seq.map float |> Seq.toList;;
val it : float list =
[0.2; 0.3; 0.4; 0.5; 0.6; 0.7; 0.8; 0.9; 1.0; 1.1; 1.2; 1.3; 1.4; 1.5; 1.6;
1.7; 1.8; 1.9; 2.0; 2.1; 2.2; 2.3; 2.4; 2.5; 2.6; 2.7; 2.8; 2.9; 3.0]
``````
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Thanks, that sounds like good stuff. I believe the comment your referring to was by Jon (as on my question here), and that it was on one of my answers elsewhere, also because I'd re-discovered float ranges (but I'd forgotten about this question!). Just out of curiosity, is the a reason you use seq in your last code block, when you're going to convert it to a list anyway at the end? –  Benjol Apr 17 '11 at 8:24
Yes, same concern as expressed in Jon's comments, but actually did find the recent related question I was talking about: stackoverflow.com/questions/5429501/… –  Stephen Swensen Apr 17 '11 at 13:31
The reason I used a seq first in my last code block is because it uses about half as much memory as `[0.2m .. 0.1m .. 3.0m] |> List.map float` since sequences are lazy. It probably only makes a difference with huge lists, since the first list would be short-lived. –  Stephen Swensen Apr 17 '11 at 13:35

As Jon and others pointed out, floating point range expressions are not numerically robust. For example `[0.0 .. 0.1 .. 0.3]` equals `[0.0 .. 0.1 .. 0.2]`. Using Decimal or Int Types in the range expression is probably better.

For floats I use this function, it first increases the total range 3 times by the smallest float step. I am not sure if this algorithm is very robust now. But it is good enough for me to insure that the stop value is included in the Seq:

``````let floatrange start step stop =
if step = 0.0 then  failwith "stepsize cannot be zero"
let range = stop - start
|> BitConverter.DoubleToInt64Bits
|> (+) 3L
|> BitConverter.Int64BitsToDouble
let steps = range/step
if steps < 0.0 then failwith "stop value cannot be reached"
let rec frange (start, i, steps) =
seq { if i <= steps then
yield start + i*step
yield! frange (start, (i + 1.0), steps) }
frange (start, 0.0, steps)
``````
-

Try the following sequence expression

``````seq { 2 .. 40 } |> Seq.map (fun x -> (float x) / 2.0)
``````
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Yes, but how do I generalise that with to a function with arbitrary start, end, increment? –  Benjol Dec 18 '08 at 9:04

You can also write a relatively simple function to generate the range:

``````let rec frange(from:float, by:float, tof:float) =
seq { if (from < tof) then
yield from
yield! frange(from + by, tof) }
``````

Using this you can just write:

``````frange(1.0, 0.5, 20.0)
``````
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It would be the answer, if I could get it to compile! –  Benjol Dec 18 '08 at 13:27
and it won't work for ranges from positive to negative numbers ;) –  Benjol Dec 18 '08 at 15:03
and it only happens to work when the floating point representations of all the numbers involved (including those generated in the range) happens to be exact. –  Jon Harrop Mar 26 '11 at 11:45

Updated version of Tomas Petricek's answer, which compiles, and works for decreasing ranges (and works with units of measure): (but it doesn't look as pretty)

``````let rec frange(from:float<'a>, by:float<'a>, tof:float<'a>) =
// (extra ' here for formatting)
seq {
yield from
if (float by > 0.) then
if (from + by <= tof) then yield! frange(from + by, by, tof)
else
if (from + by >= tof) then yield! frange(from + by, by, tof)
}

#r "FSharp.Powerpack"
open Math.SI
frange(1.0<m>, -0.5<m>, -2.1<m>)
``````

UPDATE I don't know if this is new, or if it was always possible, but I just discovered (here), that this - simpler - syntax is also possible:

``````let dl = 9.5 / 11.
let min = 21.5 + dl
let max = 40.5 - dl

let a = [ for z in min .. dl .. max -> z ]
let b = a.Length
``````

(Watch out, there's a gotcha in this particular example :)

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Still not numerically robust. –  Jon Harrop Mar 26 '11 at 11:47