On a system with 64-bit longs, `sys.maxint`

is:

```
// decimal hexadecimal
9223372036854775807 0x7fffffffffffffff
```

So `sys.maxint - 100`

is:

```
9223372036854775707 0x7fffffffffffff9b
```

Adding `0.01`

forces this value to be rounded to double-precision floating point before the addition. The two closest values that are representable in double-precision are:

```
9223372036854774784 0x7ffffffffffffc00
9223372036854775808 0x8000000000000000
```

Because `sys.maxint - 100`

is closer to the second (larger) value, it rounds up. Adding `0.01`

gives:

```
9223372036854775808.01 0x8000000000000000.028f5c28f5c...
```

which is not representable in double-precision, so it is rounded again, to:

```
9223372036854775808 0x8000000000000000
```

So the value of `sys.maxint - 100 + 0.01`

**is** actually larger than the value of `sys.maxint`

. However, in many modern languages, comparison between an integer and a float forces the integer value to be converted to floating point before the comparison takes place; if this were the case in python, `sys.maxint`

would be rounded up to the same value, and they would compare equal. It seems that this is not the case in Python. I'm not familiar with the details of python numerics, but this is an interesting curiosity of the language.