# Fast multiplication of k x k boolean matrices, where 8 <= k <= 16

I want to find an as fast as possible way of multiplying two small boolean matrices, where small means, 8x8, 9x9 ... 16x16. This routine will be used a lot, so it needs to be very efficient, so please don't suggest that the straightforward solution should be fast enough.

For the special cases 8x8, and 16x16 I already have fairly efficient implementations, based on the solution found here, where we treat the entire matrix as an `uint64_t` or `uint64_t[4]` respectively. On my machine this is roughly 70-80 times faster than the straightforward implementation.

However, in the case of 8 < k < 16, I don't really know how I can leverage any reasonable representation in order to enable such clever tricks as above.

So basically, I'm open for any suggestions using any kind of representation (of the matrices) and function signature. You may assume that this targets either a 32-bit or 64-bit architecture (pick what best suits your suggestion)

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How come we can choose 32-bit or 64-bit? –  Jan Dvorak Jan 29 '13 at 10:43
@Dvorak It was just to not limit any answers. If you have a very clever way of doing this, but it requires 64-bit, please just use that :) –  hakoja Jan 29 '13 at 10:46
Can you clarify what you mean by multiplying boolean matrices? Are you talking about doing modulo-2 arithmetic? –  Oliver Charlesworth Jan 29 '13 at 10:50
@Oli Yes - the matrices consists only of binary values, so for all operations you can just use bit operations. –  hakoja Jan 29 '13 at 10:54
are the matrices sparse? –  Josh Petitt Jan 29 '13 at 17:18

Given two 4x4 matrices a= 0010,0100,1111,0001, b=1100,0001,0100,0100, one could first calculate the transpose b' = 1000,1011,0000,0100.

Then the resulting matrix M(i,j)=a x b mod 2 == popcount(a[i]&b[j]) & 1; // or parity

From that one can notice that the complexity only grows in n^2, as long as the bitvector fits a computer word.

This can be speed up for 8x8 matrices at least, provided that some special permutation and bit selection operations are available. One can iterate exactly N times with NxN bits in a vector. (so 16x16 is pretty much the limit).

Each step consists of accumulating i.e. Result(n+1) = Result(n) XOR A(n) .& B(n), where Result(0) = 0, A(n) is A <<< n, and '<<<' == columnwise rotation of elements and where B(n) copies diagonal elements from the matrix B:

``````    a b c          a e i          d h c          g b f
B=  d e f  B(0) =  a e i  B(1) =  d h c   B(2) = g b f
g h i          a e i          d h c          g b f
``````

And after thinking it a bit further, a better option is to `^^^` (row wise rotate) matrix B and select A(n) == column copied diagonals from A:

``````    a b c         a a a           b b b           c c c
A=  d e f  A(0) = e e e , A(1) =  f f f,  A(2) =  d d d
g h i         i i i           g g g           h h h
``````

EDIT To benefit later readers, I'd propose the full solution for W<=16 bit matrix multiplications in portable C.

``````#include <stdint.h>
void matrix_mul_gf2(uint16_t *a, uint16_t *b, uint16_t *c)
{
// these arrays can be read in two successive xmm registers or in a single ymm
uint16_t D[16];      // Temporary
uint16_t C[16]={0};  // result
uint16_t B[16];
uint16_t A[16];
int i,j;
uint16_t top_row;
// Preprocess B (while reading from input)
// -- "un-tilt" the diagonal to bit position 0x8000
for (i=0;i<W;i++) B[i]=(b[i]<<i) | (b[i]>>(W-i));
for (i=0;i<W;i++) A[i]=a[i];  // Just read in matrix 'a'
// Loop W times
// Can be parallelized 4x with MMX, 8x with XMM and 16x with YMM instructions
for (j=0;j<W;j++) {
for (i=0;i<W;i++) D[i]=((int16_t)B[i])>>15;  // copy sign bit to rows
for (i=0;i<W;i++) B[i]<<=1;                  // Prepare B for next round
for (i=0;i<W;i++) C[i]^= A[i]&B[i];          // Add the partial product

top_row=A[0];
for (i=0;i<W-1;i++) A[i]=A[i+1];
A[W-1]=top_row;
}
for (i=0;i<W;i++) c[i]=W[i];      // return result
}
``````
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Thank you for your answer, however since Sjoerd's was first to suggest the use of transposed matrices, I'll accept his answer. –  hakoja Jan 30 '13 at 16:00
No problem with that -- although I'd consider at the moment the fully parallel version that would use ~W*16 xmm instructions outperforming the W^2*K approach suggested by me in the first revision. –  Aki Suihkonen Jan 30 '13 at 17:01
@Hakoja Feel free to move the accepted answer to this answer. It covers more ground than mine and has example code, so is much more complete. –  Sjoerd Feb 3 '13 at 11:18

How about padding it out to the next "clever" (e.g. 8 or 16) size, with all '1' on the diagonal?

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Then you'll spend a lot of time multiplying zeroes if you pad from 9x9 to 16x16. –  Jan Dvorak Jan 29 '13 at 10:48
We're multiplying bit vectors, a machine word at a time. The extra multiplications would be far outweighed by the conditional branching you'd spend handling different sizes. –  sheu Jan 29 '13 at 10:50
@sheu Do you think you could please expand a bit on your answer? How exactly should the 16x16 representation of a 9x9 (say) matrix look like? And what should the signature of this function be? Should the padding be the responsibility of the caller or the function itself? –  hakoja Jan 29 '13 at 11:19
@JanDvorak, not if you use the fact that boolean "multiplication" is just AND. Also, the processor is going to operate on the word size. So any "small" square matrix should use the native word size of the machine, and probably pad the MSBs to avoid having to shift to get your final answer. –  Josh Petitt Jan 29 '13 at 17:23

Depending on your application, storing both the matrix and its transpose together might help. You will save a lot of time that otherwise would be used to transpose during matrix multiplications, at the expense of some memory and some more operations.

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I believe you are forgetting to sum over some dimension and essentially calculate only a .* b'; –  Aki Suihkonen Jan 29 '13 at 13:42
@AkiSuihkonen Nice catch, thanks! That invalidates most of my answer, although I think there is still an advantage by storing the transpose. –  Sjoerd Jan 29 '13 at 13:50
Absolutely, just as in my answer below. –  Aki Suihkonen Jan 29 '13 at 13:58