The `crc32`

function outputs an unsigned 32-bit number, and the code tests if the CRC value is lower than the test_ratio times the maximum 32-bit number.

The `& 0xffffffff`

mask is there only to ensure compatibility with Python 2 and 3. In Python 2 the same function could return a *signed* integer, in a range from -(2^31) to (2^31) - 1, masking this with the `0xffffffff`

mask normalises the value to a signed.

So basically, either version turns the identifier into an integer, and the hash is used to make that integer reasonably uniformly distributed in a range; for the MD5 hash that's the last byte making the value fall between 0 and 255, for the CRC32 checksum the value lies between 0 and (2^32)-1. This integer is then compared to the full range; if it falls below the `test_ratio * maximum`

cut-off point it is considered selected.

You could also use a random function, but then you'd get a different subset of your input each time you picked a sample; by hashing the identifier you get to produce a *consistent* subset. The difference between the two methods is that they'll produce a different subset, so you could use both together to pick multiple, independent subsets from the same input.

Compare:

```
>>> import numpy as np
>>> from zlib import crc32
>>> from hashlib import md5
>>> import random
>>> identifier = np.int64(random.randrange(2**63))
>>> md5(identifier).digest()[-1]
243
>>> md5(identifier).digest()[-1] / 256 # as a ratio of the full range
0.94921875
>>> crc32(identifier)
4276259108
>>> crc32(identifier) / (2 ** 32) # ratio again
0.9956441605463624
>>> identifier = np.int64(random.randrange(2**63)) # different id to compare
>>> md5(identifier).digest()[-1] / 256 # as a ratio of the full range
0.83203125
>>> crc32(identifier) / (2 ** 32) # ratio again
0.10733163682743907
```

So the two different methods produce different outputs, but as long as the CRC32 and MD5 hashes produce reasonably *uniformly distributed* hash values, then either will give you a fair 20% sampling rate.