# Optimizing Array Compaction

Let's say I have an array `k = [1 2 0 0 5 4 0]`

I can compute a mask as follows `m = k > 0 = [1 1 0 0 1 1 0]`

Using only the mask m and the following operations

1. Shift left / right
2. And/Or

I can compact k into the following `[1 2 5 4]`

Here's how I currently do it (MATLAB pseudocode):

``````function out = compact( in )
d = in
for i = 1:size(in, 2) %do (# of items in in) passes
m = d > 0
%shift left, pad w/ 0 on right
ml = [m(2:end) 0] % shift
dl = [d(2:end) 0] % shift

%if the data originally has a gap, fill it in w/ the
%left shifted one
use = (m == 0) & (ml == 1) %2 comparison

d = use .* dl + ~use .* d

%zero out elements that have been moved to the left
use_r = [0 use(1:end-1)]
d = d .* ~use_r
end

out = d(1 : size(find(in > 0), 2)) %truncate the end
end
``````

Intuition

Each iteration, we shift the mask left and compare the mask. We set a index to have the left shifted data if we find that after this shift, an index that was originally void(mask[i] = 0) is now valid(mask[i] = 1).

Question

The above algorithm has O(N * (3 shift + 2 comparison + AND + add + 3 multiplies)). Is there a way to improve its efficiency?

-
How is this a C++ question? –  Kerrek SB Oct 25 '11 at 8:51
It's SSE / C+ related :) Array = __m256 –  jameszhao00 Oct 25 '11 at 8:52
Getting the mask is trivial in SSE. Packing it isn't... –  Mysticial Oct 25 '11 at 9:07
Yea the the algorithm above compacts in 8 passes of expensive computations :( It doesn't branch or index into the __m256 though. –  jameszhao00 Oct 25 '11 at 9:10
Which versions of SSE are we allowed to use? What type is the array? (I hope it's bytes) –  harold Oct 25 '11 at 9:21
show 5 more comments

There is no much to optimize in the original pseudo-code. I see several small improvements here:

• loop may perform one iteration less (i.e. size-1),
• if 'use' is zero, you may break the loop early,
• `use = (m == 0) & (ml == 1)` probably may be simplified to `use = ~m & ml`,
• if `~` is counted as separate operation, it would be better to use the inverted form : `use = m | ~ml`, `d = ~use .* dl + use .* d`, `use_r = [1 use(1:end-1)]`, `d = d .*use_r`

But it is possible to invent better algorithms. And the choice of algorithm depends on CPU resources used:

• Load-Store Unit, i.e. apply algorithm directly to memory words. Nothing can be done here until chipmakers add highly parallel SCATTER instruction to their instruction sets.
• SSE registers, i.e. algorithms working on entire 16 bytes of the registers. Algorithms like the proposed pseudo-code cannot help here because we already have various shuffle/permute instructions which make the work better. Using various compare instructions with PMOVMSKB, grouping the result by 4 bits and applying various shuffle instructions under switch/case (as described by LastCoder) is the best we can do.
• SSE/AVX registers with latest instruction sets allow a better approach. We can use the result of PMOVMSKB directly, transforming it to the control register for something like PSHUFB.
• Integer registers, i.e. GPR registers or working simultaneously on several DWORD/QWORD parts of SSE/AVX registers (which allows to perform several independent compactions). The proposed pseudo-code applied to integer registers allows to compact binary subsets of any length (from 2 to 20 bits). Here is my algorithm, which is likely to perform better.

C++, 64 bit, subset width = 8:

``````typedef unsigned long long ull;
const ull h = 0x8080808080808080;
const ull l = 0x0101010101010101;
const ull end = 0xffffffffffffffff;

// uncompacted bytes
ull x = 0x0100802300887700;

// set hi bit for zero bytes (see D.Knuth, volume 4)
ull m = h & ~(x | ((x|h) - l));

// bitmask for nonzero bytes
m = ~(m | (m - (m>>7)));

// tail zero bytes need no special treatment
m |= (m - 1);

while (m != end)
{
ull tailm = m ^ (m + 1); // bytes to be processed
ull tailx = x & tailm; // get the bytes
tailm |= (tailm << 8); // shift 1 byte at a time
m |= tailm; // all processed bytes are masked
x = (x ^ tailx) | (tailx << 8); // actual byte shift
}
``````
-

So you need to figure out if the extra parallelism, shifting/shuffling overhead is worth it for such a simple task.

``````for(int inIdx = 0, outIdx = 0; inIdx < inLength; inIdx++) {
if(mask[inIdx] == 1) {
out[outIdx] = in[inIdx];
outIdx++;
}
}
``````

If you want to go the parallel SIMD route your best bet is a SWITCH CASE with all of the possible permutations of the next 4 bits of the mask. Why not 8? because the PSHUFD instruction can only shuffle on XMMX m128 not YMMX m256.

So you make 16 Cases:

• [1 1 1 1], [1 1 1 0], [1 1 0 0], [1 0 0 0], [0 0 0 0] don't need any special shift/shuffle you just copy the input to the output MOVDQU and increment the output pointer by 4, 3, 2, 1, 0 respectively.
• [0 1 1 1], [0 0 1 1], [0 1 1 0], [0 0 0 1], [0 1 0 0], [0 0 1 0] you just need to use PSRLx (shift right logical) and increment the output pointer by 3, 2, 2, 1, 1, 1 respectively
• [1 0 0 1], [1 0 1 0], [0 1 0 1], [1 0 1 1], [1 1 0 1] you use the PSHUFD to pack your input then increment your output pointer by 2, 2, 2, 3, 3 respectively.

So every case would be a minimal amount of processing (1 to 2 SIMD instructions and 1 output pointer addition). The surrounding loop of the case statements would handle the constant input pointer addition (by 4) and the MOVDQA to load the input.

-
Thanks for the answer. I should've clarified that directly indexing into the array is not an option :) –  jameszhao00 Oct 25 '11 at 14:41
The lookup table option was brought up in another stackoverflow question. (Linked in my comments on the question) –  jameszhao00 Oct 25 '11 at 14:41
Does MOVDQU work when input or output are not aligned? –  Mike DeSimone Oct 28 '11 at 13:45
@Mike DeSimone - the U in DQU stands for unaligned. LDDQU is a functionally similar SSE instruction. –  LastCoder Oct 31 '11 at 13:42

Assuming what you want is to store only positive integers from an array with minimum steps in C++ this is a sample code:

``````int j = 0;
int arraysize = (sizeof k)/4;
int store[arraysize];
for(int i = 0; i<arraysize; i++)
{
if(k[i] > 0)
{
store[j] = k[i];
j++;
}
}
``````

Or you can directly use elements of k[ ] if you don't want to use `for` loop.

-

Original code moves array element only one step at a time. This may be improved. It is possible to group array elements and shift them 2^k steps at once.

First part of this algorithm computes how many steps should each element be shifted. Second part moves elements - first by one step, then by 2, then 4, etc. This works correctly and elements are not intermixed because after each shift there is enough space to perform 2 times larger shift.

Matlab, code not tested:

``````function out = compact( in )
m = in <= 0
for i = 1:size(in, 2)-1
m = [0 m(1:end-1)]
s = s + m
end

d = in
shift = 1
for j = 1:ceil(log2(size(in, 2)))
s1 = rem(s, 2)
s = (s - s1) / 2
d = (d .* ~s1) + ([d(1+shift:end) zeros(1,shift)] .* [s1(1+shift:end) zeros(1,shift)])
shift = shift*2
end
out = d
end
``````

The above algorithm's complexity is O(N * (1 shift + 1 add) + log(N) * (1 rem + 2 add + 3 mul + 2 shift)).

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Matlab was mentioned in the Question when my first answer was ready. With it came better understanding of the problem. So I decided to add this algorithm as separate answer. The code is not tested and may contain some errors because I have no Matlab experience. –  Evgeny Kluev Oct 30 '11 at 21:04

Reading the comments below the original question, in the actual problem the array contains 32-bit floating point numbers, and the mask is (one?) 32-bit integer, so I don't get it why shifts etc. should be used for compacting the array. The simple compacting algorithm (in C) would be something like this:

``````float array[8];
unsigned int mask = ...;
int a = 0, b = 0;