I've been playing with Python's hash function. For small integers, it appears `hash(n) == n`

always. However this does not extend to large numbers:

```
>>> hash(2**100) == 2**100
False
```

I'm not surprised, I understand hash takes a finite range of values. What is that range?

I tried using binary search to find the smallest number `hash(n) != n`

```
>>> import codejamhelpers # pip install codejamhelpers
>>> help(codejamhelpers.binary_search)
Help on function binary_search in module codejamhelpers.binary_search:
binary_search(f, t)
Given an increasing function :math:`f`, find the greatest non-negative integer :math:`n` such that :math:`f(n) \le t`. If :math:`f(n) > t` for all :math:`n \ge 0`, return None.
>>> f = lambda n: int(hash(n) != n)
>>> n = codejamhelpers.binary_search(f, 0)
>>> hash(n)
2305843009213693950
>>> hash(n+1)
0
```

What's special about 2305843009213693951? I note it's less than `sys.maxsize == 9223372036854775807`

Edit: I'm using Python 3. I ran the same binary search on Python 2 and got a different result 2147483648, which I note is `sys.maxint+1`

I also played with `[hash(random.random()) for i in range(10**6)]`

to estimate the range of hash function. The max is consistently below n above. Comparing the min, it seems Python 3's hash is always positively valued, whereas Python 2's hash can take negative values.

`n+1 == 2**61-1`

– Colonel Panic Jun 3 '16 at 10:58`n`

for the whole 64bit int range. – Daniel Jun 3 '16 at 11:00They are used to quickly compare dictionary keys during a dictionary lookup.In other words, implementation-defined, and by virtue of being shorter than many values that can have hash values, may very well have collisions even in reasonable input spaces. – a CVn Jun 3 '16 at 13:48`2147483647`

equal to`sys.maxint`

(not`sys.maxint+1`

), and if 'n = 0b1111111111111111111111111111111111111111111111111111111111111' then isn't`n+1 == 2**61`

or`n == 2**61-1`

(not`n+1 == 2**61-1`

)? – phoog Jun 3 '16 at 19:35