# Bit interleaving optimized for Ruby

Granted, optimizing bit twiddling in Ruby is a bit of a mismatch to begin with. That aside, I'm looking for a snippet or a gem that can interleave two arbitrary integer coords optimized as best can be for MRI (1.9) or a native gem.

Some approaches in C are: http://graphics.stanford.edu/~seander/bithacks.html#InterleaveTableObvious

As an example or starting point, here's "Interleave bits the obvious way" in Ruby, somewhat uglified to keep it from creating temp arrays (which increase the runtime by about 2X per array) and with a binary length method inlined for a further 6% decrease (If you know neither input is ever zero, you can omit that check for a few percent more..)

``````def interleave(y)
z = 0
bl = self > 0 ? Math.log2(self) : 1
ybl = y > 0 ? Math.log2(y) : 1
((((bl <=> ybl) == -1) ? ybl : bl).floor + 1).times{|i| z |= (self & 1 << i) << i | (y & 1 << i) << (i + 1)}
return z
end
``````

Results from a 2.66Ghz i5 with 1.9.2p180:

``````x = y = 0b11111111_11111111_11111111_11111111
Benchmark.bm{|bm| bm.report{1000000.times{x.interleave(y)}}}

user     system      total        real
18.360000   0.010000  18.370000 ( 18.356196)
``````

Surely there's a better way?

### Update

I included the zero fix from @Wayne Conrad, albeit far uglier than his and only marginally faster. Also moved the floor and + 1 so as to be executed once instead of twice per.

Here is a Gist of this with matching de-interleave.

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There's a bug if either of the arguments is zero. I'll add the fix to the bottom of my answer. – Wayne Conrad Feb 27 '11 at 15:55
Thanks, corrected that in the Q and Gist. – Yuri Gadow Feb 27 '11 at 20:23

## 3 Answers

Here's a quick & cheesy implementation to get you going until a good one comes along:

``````def mortanize(x, y)
xs, ys = [x, y].map do |n|
n.to_s(2)
end
nbits = [xs, ys].map(&:size).max
xs, ys = [xs, ys].map do |n|
('0' * (nbits - n.size) + n).chars
end
ys.zip(xs).join.to_i(2)
end
``````

As you might expect, it's no speed deamon. On my box, with MRI 1.8.7, it computes about 35,000 16-bit results per second. Yours computes 68,000 16-bit results per second. Or, see the next algorithm for 256,000 16-bit results per second.

If you're willing to trade a little memory and startup time for speed, then:

``````def base_mortanize(x, y)
xs, ys = [x, y].map do |n|
n.to_s(2)
end
nbits = [xs, ys].map(&:size).max
xs, ys = [xs, ys].map do |n|
('0' * (nbits - n.size) + n).chars
end
ys.zip(xs).join.to_i(2)
end

MORTON_TABLE_X = 256.times.map do |x|
base_mortanize(x, 0)
end

MORTON_TABLE_Y = 256.times.map do |y|
base_mortanize(0, y)
end

def mortanize(x, y)
z = []
while (x > 0 || y > 0)
z << (MORTON_TABLE_X[x & 0xff] | MORTON_TABLE_Y[y & 0xff])
x >>= 8
y >>= 8
end
z.reverse.inject(0) do |result, word|
result << 16 | word
end
end
``````

This one computes 256,000 16-bit results per second.

There's a bug in your answer if either argument is zero. Here's one possible fix for it. First define this function:

``````def bit_size(x)
return 1 if x == 0
Math.log2(x).floor + 1
end
``````

And then, inside `interleave`, replace:

``````z, bl, ybl = 0, (Math.log2(self)).floor + 1, (Math.log2(y)).floor + 1
``````

with:

``````z = 0
bl = bit_size(x)
ybl = bit_size(y)
``````

Here is the rspec test case I used:

``````describe "mortanize" do
it "should interleave integers" do
mortanize(0, 0).should eql 0
mortanize(0, 1).should eql 2
mortanize(1, 0).should eql 1
mortanize(0xf, 0x3).should eql 0x5f
mortanize(0x3, 0xf).should eql 0xaf
mortanize(0xf, 0x0).should eql 0x55
mortanize(0x0, 0xf).should eql 0xaa
mortanize(0x3, 0xc).should eql 0xa5
mortanize(0xf, 0xf).should eql 0xff
mortanize(0x1234, 0x4321).should eql 0x210e0d12
end
end
``````
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Thanks Wayne, a very readable impl using a bunch of Ruby stuff; I like it. If you're curious about comparison with the sample I just added to the question, the BM for this: `user 185.240000 system 0.160000 total 185.400000 real (185.204548)` – Yuri Gadow Feb 26 '11 at 14:14
Good point on the fix for my approach—you ought to make your version of mine a separate answer that can be accepted (tip, inline the bit_size method and call floor + 1 only once after the larger size is found for another speed boost.) – Yuri Gadow Feb 27 '11 at 16:26
@Yuri, I think you ought to add it--it's your answer, after all! I don't mind losing the checkmark; besides, that degree of optimization, where the intent of the code begins to get buried, makes me queezy. It's probably time to write C (per Chuba's answer) if you need it optimized that much. – Wayne Conrad Feb 27 '11 at 16:30
@Wayne: heh heh, I wonder if Meta has answer for when everyone says "no you take the credit." Maybe I'll just update the Q. I've thought about C, unfortunately my C-chops don't extend to efficiently dealing with inputs that, coming from Ruby, may well be 7 bits or 300 bits wide. – Yuri Gadow Feb 27 '11 at 16:54
@Yuri, Answer new and improved. Please see above. – Wayne Conrad Feb 27 '11 at 18:03

Here's another solution, benchmarked about 50% faster than the accepted one, and for 16-bit integers (where the first one only does 8-bit):

``````Magic = [0x55555555, 0x33333333, 0x0F0F0F0F, 0x00FF00FF]

# Interleave lower 16 bits of x and y, so the bits of x
# are in the even positions and bits from y in the odd;
# z gets the resulting 32-bit Morton Number.
# x and y must initially be less than 65536.
# Rubyfied from http://graphics.stanford.edu/~seander/bithacks.html
def _interleave_bits_16b(x,y)
x = (x | (x << 8)) & Magic[3]
x = (x | (x << 4)) & Magic[2]
x = (x | (x << 2)) & Magic[1]
x = (x | (x << 1)) & Magic[0]
y = (y | (y << 8)) & Magic[3]
y = (y | (y << 4)) & Magic[2]
y = (y | (y << 2)) & Magic[1]
y = (y | (y << 1)) & Magic[0]
z = x | (y << 1)
end
``````
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If you have an implementation already in C, you can use FFI, otherwise you can write it directly with the help of RubyInline

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