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Let x be an 8 bit integer. I will number bits from left to right because that's how we read. If I want to get the third and fifth bits and put them in the first and second bits, with everything else as zero, I can have f(x) = (5*x) & 0b11000000. More concisely:

00a0b000 -> ab000000 | f_0b00101000(x) = (5*x) & 0b11000000

However if I want the fifth, sixth and eighth bits to be in the first three bits, f(x) is different:

000ab0cd -> abcd0000 | f_0b00011011(x) = ((x << 3) & 0b11000000) | (x << 4)

Note that the n in f_n(x) indicates which bits I care about. n could have any 8 bit value. Is there some common function of x (and a few arguments) that will push all the required bits to the left? Also, this is supposed to be fast so I would prefer to only use bitwise operations.


Let's say instead I'm dealing with 3 bit integers.

000 -> 000 | f_0(x) = (1*x) & 0
00a -> a00 | f_1(x) = (4*x) & 4
0a0 -> a00 | f_2(x) = (2*x) & 4
0ab -> ab0 | f_3(x) = (2*x) & 6
a00 -> a00 | f_4(x) = (1*x) & 4
a0b -> ab0 | f_5(x) = (3*x) & 6
ab0 -> ab0 | f_6(x) = (1*x) & 6
abc -> abc | f_7(x) = (1*x) & 7

These functions can all be combined into f(x, m, a) = (m*x) & a, and I could create a lookup table which I could index to get the values of m and a from n:

t = [(1, 0), (4, 4), (2, 4), (2, 6), (1, 4), (3, 6), (1, 6), (1, 7)]

So f_n(x) becomes f(x, *t[n]). I think f(x, m, a) = (m*x) & a is optimal for 3 bits. The naive version for 3 bits is:

f(x, a, b, c, d, e, f) = ((x & a) << b) |
                         ((x & c) << d) |
                         ((x & e) << f)

The operation count is 8 for the naive function, and 2 for the optimal (?) one. Now the naive function for 8 bits is:

f(x, a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p) = ((x & a) << b) |
                                                       ((x & c) << d) |
                                                       ((x & e) << f) |
                                                       ((x & g) << h) |
                                                       ((x & i) << j) |
                                                       ((x & k) << l) |
                                                       ((x & m) << n) |
                                                       ((x & o) << p)

There are 25 operations in this instruction. Is it possible to get that down to around 7 or 8, or even lower?

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It is definitively unclear what you're asking here. Could you edit to simplify somehow? And I think the title does not really match your description? –  Sylvain Leroux Aug 29 '14 at 9:01
    
BTW, I doesn't help to anything to complain in a comment about "blind down-votes". The downvoter is gone long ago and will not see your comment. Other peoples will. –  Sylvain Leroux Aug 29 '14 at 9:02
1  
Typiaclly, bits are counted from the other end. Or am I stuck in Gulliver's travels world? –  qarma Aug 29 '14 at 9:43
    
Is this some kind of "left shift with a mask" ? With arguments in that order masked_shift_left(mask, shift) ? –  Sylvain Leroux Aug 29 '14 at 9:50
    
@SylvainLeroux You can or lots of those masked_shift_left()s together. But I don't think that is optimal. –  Scorpion_God Aug 30 '14 at 13:31

2 Answers 2

You could store functions in your lookup table:

table = [
    lambda x:x,
    lambda x:x,
    lambda x:x | ((x & 0b0001) << 1),
    ...
    ]

I would question why you are doing this by bit-shifting integers in Python. If it's for performance, I think doing this via a series of bit-shift operations is a bad idea. The interpreter overhead is going to utterly swamp any speed benefit that the bit-shifting could achieve. If it's for memory usage, because you need to fit millions of these in memory, you would probably do well to look at numpy, which can create memory-efficient arrays and apply operations simultaneously across the whole array.

One good reason I could think of for doing this in Python is because you want to experiment with the algorithm before implementing it in a low level language like C. Even then, I suspect the performance benefit would only be noticeable if you're working on very constrained hardware or doing some very intensive calculations - perhaps you are simulating tens of thousands of games of Bejeweled. If you are just doing this to calculate the logic for a single instance of the game played by a human in real-time, I doubt the bit-shifting optimization is going to be meaningful.

If you're intent on doing this with bit-shifting, could you perhaps do something like this? Rather than do it in a single step, loop until there are no more bits that can "fall". You should only need to loop at most as many times as you have bits in your integer.

Suppose you have this pattern:

        PATTERN : ab--c--d
          HOLES : 00110110

Find the highest set bit: the leftmost hole. (You can do something quite similar to this: https://graphics.stanford.edu/~seander/bithacks.html#RoundUpPowerOf2 )

  LEFTMOST HOLE : 00100000

Now eliminate just that hole. Everything on the left won't change. Everything on the right will shift left by one. Create masks for these areas.

       CAN FALL : 00011111  ( == LEFTMOST HOLE - 1)
   WON'T CHANGE : 11000000  ( == invert CAN FALL and shift left )

Use those masks to chop up, shift and reassemble all your other bitfields.

      KEEP THIS : ab
     SHIFT THIS :    -c--d
         RESULT : ab-c--d-

Finally, repeat the process until the CAN FALL mask selects only holes. It won't perform your operation in the strict minimum number of operations, but it should be relatively understandable and not require the complexity of large lookup tables.

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There would only be 256 entries in the lookup table. Is it possible to do what I want, and have that be more efficient than the method you have described? Also, for your method, I would do pattern = (pattern & ~leftmost_hole) << 1, right? –  Scorpion_God Aug 29 '14 at 10:46
    
Well I timed each solution with timeit and I got some interesting results. The other solution using string manipulation: 43.593s. Your solution: 17.549s. Using a lookup table with non-optimal functions: 5.742s. That's a very noticeable 7.6x improvement from worst to best there, even with the interpreter 'utterly swamping' any speed benefits. The timing was based on evaluating every possible combination of n and x 100 times (a total of 6,553,600 calls). –  Scorpion_God Aug 29 '14 at 16:20
    
I added a bit to the end of my question. Using the naive function for 8 bits: 9.714s. If that function could be reduced to 7 operations, I'm sure it will be faster than even a lookup table with optimal functions. –  Scorpion_God Aug 29 '14 at 16:22
    
I really think you need to give us more information about what this is for. We can try lots of crazy stuff to optimize the Python, but there's not even a full order of magnitude between your timing results. Is this a bottleneck for your program, or is this just for fun? I'm concerned you're putting in all this effort to get x5 speedups when a) it might not matter at all, and b) if it does matter, there are very possibly ways to get x100 speedups. –  Weeble Aug 29 '14 at 16:58
    
It's a bottleneck in my 'just for fun' and 'educational-ish' program. So to answer your question: both. –  Scorpion_God Aug 29 '14 at 17:02
def f(t, x):  # template, number to convert
    t = bin(t).replace("0b", "").rjust(8, "0")
    x = bin(x).replace("0b", "").rjust(8, "0")
    return int("".join([x[i] for i, b in enumerate(t) if int(b)]).ljust(8, "0"), 2)
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