# Unittest (sometimes) fails because floating-point imprecision

I have a class Vector that represents a point in 3-dimensional space. This vector has a method `normalize(self, length = 1)` which scales the vector down/up to be `length == vec.normalize(length).length`.

The unittest for this method sometimes fails because of the imprecision of floating-point numbers. My question is, how can I make sure this test does not fail when the methods are implemented correctly? Is it possible to do it without testing for an approximate value?

``````    def testNormalize(self):
vec = Vector(random.random(), random.random(), random.random())
self.assertEqual(vec.normalize(5).length, 5)
``````

This sometimes results in either `AssertionError: 4.999999999999999 != 5` or `AssertionError: 5.000000000000001 != 5`.

Note: I am aware that the floating-point issue may be in the `Vector.length` property or in `Vector.normalize()`.

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try rounding it to less decimal places –  JBernardo Jan 19 '12 at 15:54
@JBernardo: That's bad advice -- small differences in the original values can still result in the rounded values being different. –  Sven Marnach Jan 19 '12 at 16:05

### 1) How can I make sure the test works?

Use `assertAlmostEqual`, `assertNotAlmostEqual`.

From the official documentation:

``````assertAlmostEqual(first, second, places=7, msg=None, delta=None)
``````

Test that first and second are approximately equal by computing the difference, rounding to the given number of decimal places (default 7), and comparing to zero.

### 2) Is it possible to do it without testing for an approximate value?

Esentially No.

The floating point issue can't be bypassed, so you have either to "round" the result given by `vec.normalize` or accept an almost-equal result (each one of the two is an approximation).

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Sure, but the OP is specifically asking if it can be done "without testing for an approximate value" (emphasis theirs). –  NPE Jan 19 '12 at 16:02
@aix: But it is the nicest answer under the ones that recommend using an approximate comparison. I will just check out the approach of jcollado, but I think I will fall back to this method as the `decimal.Decimal` approach seems to be impractical. –  Niklas R Jan 19 '12 at 16:28
@aix: he asked if it's possible without an approximation, and the answer to that is no, because from one side or the other he have to deal with the representation of a floating point. –  Rik Poggi Jan 19 '12 at 16:29
(+1) Fair enough. I see that the answer has undergone significant editing since I made that remark. –  NPE Jan 19 '12 at 16:34
Perfect answer, especially after your edit. :) +1, check-marked. –  Niklas R Jan 19 '12 at 16:43

By using a floating point value, you accept a small possible imprecision. Therefore, your tests should test if your computed value falls in an acceptable range such as:

``````theoreticalValue - epsilon < normalizedValue < theoreticalValue + epsilon
``````

where `epsilon` is a very small value that you define as acceptable for a variation due to floating point imprecision.

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In general, you should not assert equality for floats. Instead, ensure that the result is within certain bounds, e.g.:

``````self.assertTrue(abs(vec.normalize(5).length - 5) < 0.001)
``````
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Warning: this can raise weird exceptions like "AssertionError: False is not true"! –  Pete Nov 19 '12 at 21:49

I suppose one possibility is to apply the function to test cases for which all inputs, the results of all intermediate calculations, and the output are exactly representable by `float`.

To illustrate:

``````In [2]: import math

In [4]: def norm(x, y):
...:     return math.sqrt(x*x + y*y)
...:

In [6]: norm(3, 4) == 5
Out[6]: True
``````

Not sure how practical this is though...

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