Python has arbitrary-precision integers but standard limited (double) precision floats. In Python 3, the division of two integers with `/`

produces a float, which means (e.g.) that

```
>>> 10**50/10**25
1e+25
>>> int(10**50/10**25)
10000000000000000905969664
```

but if we work purely with integers using `//`

, we get:

```
>>> 10**50//10**25
10000000000000000000000000
```

In your code, both `(n-1)/3`

and `(n/2)`

will produce float output, which means that you've only got ~18 digits or so of precision. If we rework your function to work purely with integers:

```
def sumof3b(n):
n = (n-1)//3
return (6+3*(n-1))*n//2
```

Then we get agreement for the low values:

```
>>> all(sumof3(n) == sumof3b(n) for n in range(10**7))
True
```

but at high values we preserve the precision:

```
>>> n = 232471924
>>> sumof3(n) # bad
9007199280122284
>>> sumof3b(n) # good
9007199280122283
```

[Here we can reorder to make sure we're not losing any fractional data, but I sometimes find the `fractions`

module comes in handy too.]