# How to test if a function grows logarithmically?

I have function in my model that counts user's score:

``````def score
(MULTIPLER * Math::log10(bets.count * summary_value ** accuracy + 1)).floor
end
``````

My point is to test that it grows logarithmically?

-
just to clarify the question: Do you want to test if the function score is O(log(n)) in the variable bets.count ? Not sure I understand. –  Massagran Jun 7 at 15:26
I want to check that function return value grow logarithmic in variable of `bets.count`. –  Łukasz Niemier Jun 7 at 15:28
if you want to prove analytic, this is a math question and is off topic. If you want to prove numerically, you can use a graph plot gem, like rplot, and is not constructive - you can save this question editing it and prove me wrong. –  fotanus Jun 7 at 15:32
Seconding the need to clarify if you want to "test" or "prove". Also, what have you tried, or what ideas have you rejected? I mean, you know how to test things in general, yes? Why can't you apply that to this? –  bmm6o Jun 7 at 15:38
I know how to test, but I don't have idea how to generallly test that function grow logaritmically. I don't want to test against exact value, but against it growth. –  Łukasz Niemier Jun 7 at 15:51
show 1 more comment

The point of a test isn't to prove it always works (this is the area for static typing/proofs), but to check that it is probably working. This is normally good enough. I'm guessing you are doing it for a game, and what to ensure the function doesn't "grow" too quickly.

A way we could do that is to try a number of values, and check whether they are following a general logarithmic pattern.

For example, consider a pure logarithmic function `f(x) = log(x)` (any base):

If `f(x) = y`, then `f(x^n)` = `f(x) * n`.

So, if `f(x^n) == (f(x) * n)`, then the function is logarithmic.

Compare that to a linear function, eg `f(x) == x * 2`. `f(x^n) = x^n * 2`, ie `x^(n - 1)` times bigger (a lot bigger).

You may have a more complex logarithmic function, eg `f(x) = log(x + 7) + 3456`. The pattern still holds though, just less accurately. So what I did was:

1. Attempt to calculate the constant value, by using `x = 1`
2. Find the difference `f(x^n) - f(x) * n`.
3. Find the absolute difference of `f((x*100)^n) - f(100x) * n`

If (3)/(2) is less than 10, it is almost certainly not linear, and probably logarithmic. The 10 is just an arbitrary number. Most linear functions will be different by a factor of more than a billion. Even functions like `sqrt(x)` will have a bigger difference than 10.

My example code will just have the `score` method take a parameter, and test against that (to keep it simple + I don't have your supporting code).

``````require 'rspec'
require 'rspec/mocks/standalone'

def score(input)
Math.log2(input * 3 + 1000 * 3) * 3 + 100 + Math.sin(input)
end

describe "score" do
it "grows logarithmacally based on input" do
x = 50
n = 8
c = score(1)

result1 = (score(x ** n) - c) / ((score(x) -c) * n)
x *= 100
result2 = (score(x ** n) - c) / ((score(x) -c) * n)
(result2 / result1).abs.should be < 10

end
end
``````
-

Though I almost forget complex math knowledge, it seems the fact can't stop me answering the question.

My suggestion as follows

``````describe "#score" do
it "grows logarithmically" do
round_1 = FactoryGirl.create_list(:bet, 10, value: 5).score
round_2 = FactoryGirl.create_list(:bet, 11, value: 5).score
# Then expect some math relation between round_1 and round_2,
# calculated by you manually.
end
end
``````
-

Generally speaking, the best way to see if a function grows is to plot some data on a graph. Just use some graph plotting gem and evaluate the result.

A logarithmic function will always look like this:

You can then adjust how fast it grows through your parameters, and replot the graph, until you found yourself happy with the result.

-
I know how to choose constants that will fit for me, but I need to test that no one ever change this to one that isn't logarithmic. –  Łukasz Niemier Jun 7 at 16:05
If you need to treat this function like a black box, the only true solution is to get a bunch of values and see if their curve is well-approximated by a logarithmic curve, focusing on large `n`. If you could put reasonable bounds on it, like `a log(n) < score(n) < b log(n)` for some values `a` and `b` then you could just check that.