Feature #15811
openPropsing new method for comparing equality of 2 (float) numbers relatively
Added by yennguyenh (yen nguyen) over 5 years ago. Updated over 5 years ago.
Description
Background¶
Equal comparison method between 2 float numbers returns unexpected results sometimes. Therefore, a relative comparison method is needed!
Proposal¶
A relative equal comparison method has been written based on a Python project! This method gives the approximation for the equal comparison based on two values: realative tolerance and absolute tolerance. Near zero value will also be considered carefully!
Implementation¶
The function for that would be called close?
close?(a, b, rel_tol, abs_tol)
a
and b
: are the two values to be tested to relative closeness
rel_tol
: is the relative tolerance -- it is the amount of error allowed, relative to the larger absolute value of a or b. For example, to set a tolerance of 5%, pass tol=0.05. The default tolerance is 1E-9, which assures that the two values are the same within about 9 decimal digits. rel_tol must be greater than 0.0
abs_tol
: is a minimum absolute tolerance level -- useful for comparisons near zero.
Evaluation of your implementation¶
By default, relative tolerance is 1E-9 which is relatively precise enough to compare two float numbers. However it can also be adjusted in case higher accuracy is requested. The absolute tolerance is by default 0.0 and need to be set in case of near-zero numbers.
Discussion¶
There are some test cases available for the method which has approved the accuracy of the method. BigNumbers and integers are also tested. However, more test cases are still needed to assure even better the accuracy of the method.
Gist¶
Relative equal comparison
https://gist.github.com/yennguyenh/63d5e7a11f354f796b43ada037c4b2c5
Test cases
https://gist.github.com/yennguyenh/2e81dc72b310cb9d886a82faf3d536ef
Updated by yennguyenh (yen nguyen) over 5 years ago
I don't know how to add the new method correctly. Please have a look at those gist and tell me what to do! Thank you :)
Updated by osyo (manga osyo) over 5 years ago
hi.
Here are the guidelines.
https://github.com/ko1/rubyhackchallenge
Updated by shevegen (Robert A. Heiler) over 5 years ago
Not sure if the name .close?
is a good name to indicate a relative comparison. Note that
I have no real pro or con opinion, just pointing out that the name may not be ideal. I
don't have a good alternative proposal either; perhaps something a bit longer, two words?
Perhaps you could add a more specific example - might be useful. Will this method reside
on Math
, for example? E. g.:
Math.close?(a, b, rel_tol, abs_tol)
Again, not having any preference myself here, just asking to see more details added to
the suggestion. The ruby team is open to adding/discussing changes/modifications based
on use cases; in my opinion, the more details can be added (when they are important),
the better.
To make it easier for others, I copy/pasted a part of your gist sample (excluding the
documents), just to make it simpler for people to read the code here; you can indent
via 4 ' '
and then the bugtracker here will correctly highlight the ruby code:
def self.close?(a, b, rel_tol: RELATIVE_TOLERANCE, abs_tol: ABSOLUTE_TOLERANCE)
raise ArgumentError.new('Arguments must be numeric') unless (a.is_a?(Numeric) && b.is_a?(Numeric))
raise ArgumentError.new('Error tolerance must positive') if (rel_tol < 0.0 || abs_tol < 0.0)
# short-cut exact equality
return true if a == b
# check if any attribute is Infinite
return false if a.infinite? || b.infinite?
# weak comparition - the tolerance is scaled by the larger of 2 values
abs_diff = (a - b).abs
((abs_diff <= (rel_tol * b).abs) ||
(abs_diff <= (rel_tol * a).abs) ||
(abs_diff <= abs_tol))
end
Updated by wishdev (John Higgins) over 5 years ago
The tests for this are incorrect and show why this does not work.
From the test gist
context 'Numbers between 1 and 0' do
let (:absolute_tolerance) { 1.0E-14 }
it 'returns true for same positive numbers' do
expect(Math.close?(1000001.0E-15, 1000002.0E-15, abs_tol: absolute_tolerance)).to be_truthy
expect(Math.close?(1000002.0E-15, 1000001.0E-15, abs_tol: absolute_tolerance)).to be_truthy
end
it 'returns true for same negative numbers' do
expect(Math.close?(-1000001.0E-15, -1000002.0E-15, abs_tol: absolute_tolerance)).to be_truthy
expect(Math.close?(-1000002.0E-15, -1000001.0E-15, abs_tol: absolute_tolerance)).to be_truthy
end
it 'returns false for different positive numbers' do
expect(Math.close?(1000010.0E-15, 1000020.0E-15, abs_tol: absolute_tolerance)).to be_falsey
expect(Math.close?(1000020.0E-15, 1000010.0E-15, abs_tol: absolute_tolerance)).to be_falsey
end
it 'returns false for different negative numbers' do
expect(Math.close?(-1000010.0E-15, -1000020.0E-15, abs_tol: absolute_tolerance)).to be_falsey
expect(Math.close?(-1000020.0E-15, -1000010.0E-15, abs_tol: absolute_tolerance)).to be_falsey
end
end
10E-15 == 1E-14 therefore since the absolute tolerance is equal to the difference of the bottom two "return false" specs - they must be true - they are not true because subtracting those floats ends up with garbage.
For example
1000020.0E-15 - 1000010.0E-15
equals
1.0000000000085785e-14
Which places it outside of 1E14 but common sense (and looking at the numbers in front of us) obviously the correct answer is 1E14.
Floating numbers cannot be acted upon and then the result used to prove something.
This does not provide what it claims to provide - it is not possible to provide what you wish to provide here when dealing with floats.
Sorry
John
Updated by nobu (Nobuyoshi Nakada) over 5 years ago
- Description updated (diff)
I think it should be under Math
or Float
, and a independent gem could be a good first step.
Updated by duerst (Martin Dürst) over 5 years ago
Ruby is an object-oriented language. So I think this should be something like:
a.close_to?(b, abs_tolerance: t)
or so, not a function with two main numbers.
Updated by sawa (Tsuyoshi Sawada) over 5 years ago
Related to https://bugs.ruby-lang.org/issues/10425
Updated by mame (Yusuke Endoh) over 5 years ago
- Related to Feature #10425: A predicate method to tell if a number is near another added
Updated by nobu (Nobuyoshi Nakada) over 5 years ago
duerst (Martin Dürst) wrote:
Ruby is an object-oriented language. So I think this should be something like:
a.close_to?(b, abs_tolerance: t)
or so, not a function with two main numbers.
If it is an instance method, the relative tolerance feels relative to the absolute value of the receiver, not the larger one.
Updated by yennguyenh (yen nguyen) over 5 years ago
nobu (Nobuyoshi Nakada) wrote:
I think it should be under
Math
orFloat
, and a independent gem could be a good first step.
I have updated the first gist. It is under Math! I just forgot putting it in gist . Thank you for reminding anyway :D
Updated by yennguyenh (yen nguyen) over 5 years ago
wishdev (John Higgins) wrote:
The tests for this are incorrect and show why this does not work.
From the test gist
context 'Numbers between 1 and 0' do let (:absolute_tolerance) { 1.0E-14 } it 'returns true for same positive numbers' do expect(Math.close?(1000001.0E-15, 1000002.0E-15, abs_tol: absolute_tolerance)).to be_truthy expect(Math.close?(1000002.0E-15, 1000001.0E-15, abs_tol: absolute_tolerance)).to be_truthy end it 'returns true for same negative numbers' do expect(Math.close?(-1000001.0E-15, -1000002.0E-15, abs_tol: absolute_tolerance)).to be_truthy expect(Math.close?(-1000002.0E-15, -1000001.0E-15, abs_tol: absolute_tolerance)).to be_truthy end it 'returns false for different positive numbers' do expect(Math.close?(1000010.0E-15, 1000020.0E-15, abs_tol: absolute_tolerance)).to be_falsey expect(Math.close?(1000020.0E-15, 1000010.0E-15, abs_tol: absolute_tolerance)).to be_falsey end it 'returns false for different negative numbers' do expect(Math.close?(-1000010.0E-15, -1000020.0E-15, abs_tol: absolute_tolerance)).to be_falsey expect(Math.close?(-1000020.0E-15, -1000010.0E-15, abs_tol: absolute_tolerance)).to be_falsey end end
10E-15 == 1E-14 therefore since the absolute tolerance is equal to the difference of the bottom two "return false" specs - they must be true - they are not true because subtracting those floats ends up with garbage.
For example
1000020.0E-15 - 1000010.0E-15
equals
1.0000000000085785e-14
Which places it outside of 1E14 but common sense (and looking at the numbers in front of us) obviously the correct answer is 1E14.
Floating numbers cannot be acted upon and then the result used to prove something.
This does not provide what it claims to provide - it is not possible to provide what you wish to provide here when dealing with floats.
Sorry
John
Sorry but I do not really understand what you meant. What I get so far is that you mean the difference of that pair of number (1000020.0E-15 - 1000010.0E-15) results not as expected, 1.0000000000085785e-14 instead of 1.0e-14. I have taken a look on that and realize one mistake on the algorithm. The absolute tolerance is set to check the accuracy to a certain decimal place and so at that place the difference should be less than 1 which is 0. Therefore the equal case should not be considered as the case for equal numbers. It should be fixed like below ( I have also updated the code!)
current method:
abs_diff = (a - b).abs
((abs_diff <= (rel_tol * b).abs) ||
(abs_diff <= (rel_tol * a).abs) ||
(abs_diff <= abs_tol))
fixed method:
abs_diff = (a - b).abs
((abs_diff <= (rel_tol * b).abs) ||
(abs_diff <= (rel_tol * a).abs) ||
(abs_diff < abs_tol))
For ex:
absolute tolerance: 1e-2
a: 0.01
b: 0.02
(a-b).abs: 0.001 == 1e-2
At the second decimal place, there is the difference of '1' which should return false for the equal comparison, so it return false in case absolute tolerance == (a-b).abs
If it is not what you meant, please explain me more! Anyway thank you for the feedback, that I could find out that mistake!
Updated by ko1 (Koichi Sasada) over 5 years ago
could you share how about other languages (code examples)?
anyway, if you are interest about this ticket yet, could you file on our dev-meeting agenda?
https://bugs.ruby-lang.org/issues/15996
Thanks.
Updated by wishdev (John Higgins) over 5 years ago
yennguyenh (yen nguyen) wrote:
wishdev (John Higgins) wrote:
....
Sorry but I do not really understand what you meant. What I get so far is that you mean the difference of that pair of number (1000020.0E-15 - 1000010.0E-15) results not as expected, 1.0000000000085785e-14 instead of 1.0e-14. I have taken a look on that and realize one mistake on the algorithm. The absolute tolerance is set to check the accuracy to a certain decimal place and so at that place the difference should be less than 1 which is 0. Therefore the equal case should not be considered as the case for equal numbers. It should be fixed like below ( I have also updated the code!)
First, my sincere apologies - I missed an email along the way and this just popped up on my radar this evening with the newest message.
However to be clear
Tolerance = 0.01
0.01 - 0.02 = -0.01 (False/True depending on which version of the code)
0.02 - 0.03 = -0.009999999999999998 (True always)
0.03 - 0.04 = -0.010000000000000002 (False always)
Those are not weird e-15 vs e-14 numbers - that's pennies on a dollar transaction.
Sorry
John
Updated by mrkn (Kenta Murata) over 5 years ago
Julia provides isapprox
function in Base
module. This returns true
if norm(x-y) <= max(atol, rtol*max(norm(x), norm(y)))
.
The detail documentation is here.
The definition is here:
function isapprox(x::Number, y::Number; atol::Real=0, rtol::Real=rtoldefault(x,y,atol), nans::Bool=false)
x == y || (isfinite(x) && isfinite(y) && abs(x-y) <= max(atol, rtol*max(abs(x), abs(y)))) || (nans && isnan(x) && isnan(y))
end
const ≈ = isapprox
Updated by wishdev (John Higgins) over 5 years ago
mrkn (Kenta Murata) wrote:
Julia provides
isapprox
function inBase
module. This returnstrue
ifnorm(x-y) <= max(atol, rtol*max(norm(x), norm(y)))
.
The detail documentation is here.The definition is here:
function isapprox(x::Number, y::Number; atol::Real=0, rtol::Real=rtoldefault(x,y,atol), nans::Bool=false) x == y || (isfinite(x) && isfinite(y) && abs(x-y) <= max(atol, rtol*max(abs(x), abs(y)))) || (nans && isnan(x) && isnan(y)) end const ≈ = isapprox
From https://repl.it/languages/julia (online julia repl)
isapprox(0.01-0.02, 0, atol=1e-2)
true
isapprox(0.02-0.03, 0, atol=1e-2)
true
isapprox(0.03-0.04, 0, atol=1e-2)
false
This does not work here either. Which mirrors the examples above (they take the earlier code from this ticket and treat exactly 0.01 as true for this example).
Updated by wishdev (John Higgins) over 5 years ago
So there is one path that might work here (it has limits but there are limits in general that cannot be worked around).
If one takes the following scenario
We have a set of items in a store where the base unit of price is 0.01 meaning that something may cost 1.23, or 2.45, but we would not see anything like 1.234 or 45.4555 because those are lower than the working "unit of change" (0.01).
So we could construct a method like this which would allow us to determine if two items where priced within a set of "units of change"
def within_amount(item_a, item_b, amount, unit_of_change)
(item_a - item_b).abs < ((within_amount).abs + (unit_of_change).abs /2)
end
So going back to earlier examples - if we take
0.01 vs 0.02 we would have a unit of change of no more than 0.01 because while we might have 0.015 as a valid option - we know that 0.03 is a valid option.
So taking the new method
item_a = 0.01
item_b = 0.02
amount = 0.01
unit_of_change = 0.01
(0.01 - 0.02).abs = 0.01
(0.01).abs + (0.01).abs /2 = 0.015
0.01 < 0.015 so it returns true
This works because we know that the unit of change implies the limits of the possible answers of (item_a - item_b).abs - so in this case we should have the following options
0.01, 0.02, 0.03, and so on
Since floating point subtraction is not exact we might end up with 0.0099999999994747, 0.01, or 0.010000000001 when comparing two adjacent numbers within our set
However, if we take the unit of change and halve it then we have better boundaries 0.010000000001 does not worked against a tight comparison to 0.01 but it works just fine if we compare it against 0.015 or 0.005 because those options lay well outside of the error bounds that floating point subtraction will offer us.
So the answer remains that simply comparing two numbers does not work - however, one can compare two numbers within a defined space and obtain the desired conceptual results.
The obvious rules are that within_amount must be at least equal to the unit of change. There are also issues if the within_amount is not a multiple of the unit of change. The validation check for that (checking if x is a multiple of y) starts us back down the road of inexact comparisons so it may be something that is a documented limit as opposed to a test within the method itself.
John