I am using a VPTree to optimize some K-Nearest neighbors algorithms.

A VPTree requires that a distance function satisfy the triangle inequality.

The triangle inequality states that the following must be true:

```
distance(x,z) <= distance(x,y) + distance(y,z)
```

One of the features used in our distance function is geographic distance, in meters, which is calculated with floating point arithmetic. I found that this feature has been violating the triangle inequality due to inexact floating point calculations.

For Example:

```
x = -90,-180
y = -90,-162
z = -81,-144
distance(x,z) = 1005162.6564502382
distance(x,y) = 1.2219041408558764E-10
distance(y,z) = 1005162.656450238
distance(x,y) + distance(y,z) = 1005162.6564502381
```

Obviously the triangle inequality has failed in this case.

I was messing around and found that if I round the distance in meters DOWN to the next integer, ie Math.floor() in java, and then add 5, the result seems to all of a sudden satisfy the triangle inequality in all cases I have tested.

I have tested every lat/long combination that is a multiple of 10, ie 20^6 combinations.

After this change we get the following results for the example above:

```
x = -90,-180
y = -90,-162
z = -81,-144
distance(x,z) = 1005167
distance(x,y) = 5
distance(y,z) = 1005167
distance(x,y) + distance(y,z) = 1005172
```

Obviously the triangle inequality no longer fails in this case.

This seems perfect since 5 meters really isn't significant in our use case.

**Am I just "forcing" this to work and am still violating some requirement of the triangle inequality or some requirement of VPTrees? Is this something that is known property of floats?**

Note that simply rounding DOWN without adding 5 does not work.

For Example:

```
x = -90,-180
y = -81,-180
z = -72,-180
distance(x,z) = 2009836.0
distance(x,y) = 1005162.0
distance(y,z) = 1004673.0
distance(x,y) + distance(y,z) = 2009835.0
```

And adding 5:

```
x = -90,-180
y = -81,-180
z = -72,-180
distance(x,z) = 2009841.0
distance(x,y) = 1005167.0
distance(y,z) = 1004678.0
distance(x,y) + distance(y,z) = 2009845.0
```

Also note that I have found that this works for any kind of floating point arithmetic, not just geo distance. For example a distance function that calculates a percentage of some maximum value with a single division operation, as long as you always round to a specific number of digits and add 5 to the last digit.