What you copied is a template for generating code. It's not a good idea to transliterate that template into another language and expect it to run fast. Let's expand the template.

(T)~(T)0 means "as many 1-bits as fit in type T". The algorithm needs 4 masks which we will compute for the various T-sizes we might be interested in.

```
>>> for N in (8, 16, 32, 64, 128):
... all_ones = (1 << N) - 1
... constants = ' '.join([hex(x) for x in [
... all_ones // 3,
... all_ones // 15 * 3,
... all_ones // 255 * 15,
... all_ones // 255,
... ]])
... print N, constants
...
8 0x55 0x33 0xf 0x1
16 0x5555 0x3333 0xf0f 0x101
32 0x55555555L 0x33333333L 0xf0f0f0fL 0x1010101L
64 0x5555555555555555L 0x3333333333333333L 0xf0f0f0f0f0f0f0fL 0x101010101010101L
128 0x55555555555555555555555555555555L 0x33333333333333333333333333333333L 0xf0f0f0f0f0f0f0f0f0f0f0f0f0f0f0fL 0x1010101010101010101010101010101L
>>>
```

You'll notice that the masks generated for the 32-bit case match those in the hardcoded 32-bit C code. Implementation detail: lose the `L`

suffix from the 32-bit masks (Python 2.x) and lose all `L`

suffixes for Python 3.x.

As you can see the whole template and (T)~(T)0 caper is merely obfuscatory sophistry. Put quite simply, for a k-byte type, you need 4 masks:

```
k bytes each 0x55
k bytes each 0x33
k bytes each 0x0f
k bytes each 0x01
```

and the final shift is merely N-8 (i.e. 8*(k-1)) bits. Aside: I doubt if the template code would actually work on a machine whose CHAR_BIT was not 8, but there aren't very many of those around these days.

Update: There is another point that affects the correctness and the speed when transliterating such algorithms from C to Python. The C algorithms often assume unsigned integers. In C, operations on unsigned integers work silently modulo 2**N. In other words, only the least significant N bits are retained. No overflow exceptions. Many bit twiddling algorithms rely on this. However (a) Python's `int`

and `long`

are signed (b) old Python 2.X will raise an exception, recent Python 2.Xs will silently promote `int`

to `long`

and Python 3.x `int`

== Python 2.x `long`

.

The correctness problem usually requires `register &= all_ones`

at least once in the Python code. Careful analysis is often required to determine the minimal correct masking.

Working in `long`

instead of `int`

doesn't do much for efficiency. You'll notice that the algorithm for 32 bits will return a `long`

answer even from input of `0`

, because the 32-bits all_ones is `long`

.