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I'm looking for a faster and trickier way to multiply two 4x4 matrices in C. My current research is focused on x86-64 assembly with SIMD extensions. So far, I've created a function witch is about 6x faster than a naive C implementation, which has exceeded my expectations for the performance improvement. Unfortunately, this stays true only when no optimization flags are used for compilation (GCC 4.7). With -O2, C becomes faster and my effort becomes meaningless.

I know that modern compilers make use of complex optimization techniques to achieve an almost perfect code, usually faster than an ingenious piece of hand-crafed assembly. But in a minority of performance-critical cases, a human may try to fight for clock cycles with the compiler. Especially, when some mathematics backed with a modern ISA can be explored (as it is in my case).

My function looks as follows (AT&T syntax, GNU Assembler):

    .text
    .globl matrixMultiplyASM
    .type matrixMultiplyASM, @function
matrixMultiplyASM:
    movaps   (%rdi), %xmm0    # fetch the first matrix (use four registers)
    movaps 16(%rdi), %xmm1
    movaps 32(%rdi), %xmm2
    movaps 48(%rdi), %xmm3
    xorq %rcx, %rcx           # reset (forward) loop iterator
.ROW:
    movss (%rsi), %xmm4       # Compute four values (one row) in parallel:
    shufps $0x0, %xmm4, %xmm4 # 4x 4FP mul's, 3x 4FP add's 6x mov's per row,
    mulps %xmm0, %xmm4        # expressed in four sequences of 5 instructions,
    movaps %xmm4, %xmm5       # executed 4 times for 1 matrix multiplication.
    addq $0x4, %rsi

    movss (%rsi), %xmm4       # movss + shufps comprise _mm_set1_ps intrinsic
    shufps $0x0, %xmm4, %xmm4 #
    mulps %xmm1, %xmm4
    addps %xmm4, %xmm5
    addq $0x4, %rsi           # manual pointer arithmetic simplifies addressing

    movss (%rsi), %xmm4
    shufps $0x0, %xmm4, %xmm4
    mulps %xmm2, %xmm4        # actual computation happens here
    addps %xmm4, %xmm5        #
    addq $0x4, %rsi

    movss (%rsi), %xmm4       # one mulps operand fetched per sequence
    shufps $0x0, %xmm4, %xmm4 #  |
    mulps %xmm3, %xmm4        # the other is already waiting in %xmm[0-3]
    addps %xmm4, %xmm5
    addq $0x4, %rsi           # 5 preceding comments stride among the 4 blocks

    movaps %xmm5, (%rdx,%rcx) # store the resulting row, actually, a column
    addq $0x10, %rcx          # (matrices are stored in column-major order)
    cmpq $0x40, %rcx
    jne .ROW
    ret
.size matrixMultiplyASM, .-matrixMultiplyASM

It calculates a whole column of the resultant matrix per iteration, by processing four floats packed in 128-bit SSE registers. The full vectorisation is possible with a bit of math (operation reordering and aggregation) and mullps/addps instructions for parallel multiplication/addition of 4xfloat packages. The code reuses registers meant for passing parameters (%rdi, %rsi, %rdx : GNU/Linux ABI), benefits from (inner) loop unrolling and holds one matrix entirely in XMM registers to reduce memory reads. A you can see, I have researched the topic and took my time to implement it the best I can.

The naive C calculation conquering my code looks like this:

void matrixMultiplyNormal(mat4_t *mat_a, mat4_t *mat_b, mat4_t *mat_r) {
    for (unsigned int i = 0; i < 16; i += 4)
        for (unsigned int j = 0; j < 4; ++j)
            mat_r->m[i + j] = (mat_b->m[i + 0] * mat_a->m[j +  0])
                            + (mat_b->m[i + 1] * mat_a->m[j +  4])
                            + (mat_b->m[i + 2] * mat_a->m[j +  8])
                            + (mat_b->m[i + 3] * mat_a->m[j + 12]);
}

I have investigated the optimised assembly output of the above's C code which, while storing floats in XMM registers, does not involve any parallel operations – just scalar calculations, pointer arithmetic and conditional jumps. The compiler's code seems to be less deliberate, but it is still slightly more effective than my vectorised version expected to be about 4x faster. I'm sure that the general idea is correct – programmers do similar things with rewarding results. But what is wrong here? Are there any register allocation or instruction scheduling issues I am not aware of? Do you know any x86-64 assembly tools or tricks to support my battle against the machine?

share|improve this question
    
Recent compilers can micro-optimize better than humans. Focus on algorithmic optimization! – Basile Starynkevitch Aug 28 '13 at 23:33
    
This is exactly what I've done -- I used an alternative calculation to adapt the problem for SSE. It is actually a different algorithm. The problem is, probably, that now I also have to optimize it at the instruction level because, while focusing on the algorithm, I might have introduced data dependency problems, ineffective memory access patterns or some other black magic. – Krzysztof Abramowicz Aug 29 '13 at 0:05
    
You might be better off using SSE intrinsics available through <immintrin.h> - you can try other things like _mm_dp_ps with _MM_TRANSPOSE4_PS, without maintaining assembly. – Brett Hale Aug 29 '13 at 6:31
    
If you add the restrict qualifier to the pointer arguments to the C function and compile with -O3, GCC will vectorise it. Without the restrict qualifiers, the compiler has to assume that the output matrix could be the same as one of the input matrices. – caf Aug 29 '13 at 6:38
    
@BrettHale, I agree intrinsics are the way to do this but _mm_dp_ps or _MM_TRANSPOSE4_PS will be inefficient. See my answer and stackoverflow.com/questions/14967969/… – Z boson Aug 29 '13 at 10:32

4x4 matrix multiplication is 64 multiplications and 48 additions. Using SSE this can be reduced to 16 multiplications and 12 additions (and 16 broadcasts). The following code will do this for you. It only requires SSE (#include <xmmintrin.h>). The arrays A, B, and C need to be 16 byte aligned. Using horizontal instructions such as hadd (SSE3) and dpps (SSE4.1) will be less efficient (especially dpps). I don't know if loop unrolling will help.

void M4x4_SSE(float *A, float *B, float *C) {
    __m128 row1 = _mm_load_ps(&B[0]);
    __m128 row2 = _mm_load_ps(&B[4]);
    __m128 row3 = _mm_load_ps(&B[8]);
    __m128 row4 = _mm_load_ps(&B[12]);
    for(int i=0; i<4; i++) {
        __m128 brod1 = _mm_set1_ps(A[4*i + 0]);
        __m128 brod2 = _mm_set1_ps(A[4*i + 1]);
        __m128 brod3 = _mm_set1_ps(A[4*i + 2]);
        __m128 brod4 = _mm_set1_ps(A[4*i + 3]);
        __m128 row = _mm_add_ps(
                    _mm_add_ps(
                        _mm_mul_ps(brod1, row1),
                        _mm_mul_ps(brod2, row2)),
                    _mm_add_ps(
                        _mm_mul_ps(brod3, row3),
                        _mm_mul_ps(brod4, row4)));
        _mm_store_ps(&C[4*i], row);
    }
}
share|improve this answer
    
Many thanks for your answer. The code looks better than my previous experiment with SSE intrinsics for matrix multiplication. It also gives a better-looking assembly with -O2 and runs a bit faster than mine. But I am still wondering why I cannot achieve at least same results with pure assembly. – Krzysztof Abramowicz Aug 31 '13 at 14:06
    
If you're using GCC why are you not compiling with -O3? – Z boson Sep 1 '13 at 19:19
    
Maybe because I've always been told that -O3 introduces aggressive optimisation techniques which may not boost performance, but may introduce additional cost, e.g. by increasing code size when unrolling loops or inlining functions. But you're right – first -O3, then low-level optimisation! :-) Fortunately, in my example it doesn't make much difference. – Krzysztof Abramowicz Sep 14 '13 at 21:13
up vote 8 down vote accepted

There is a way to accelerate the code and outplay the compiler. It does not involve any sophisticated pipeline analysis or deep code micro-optimisation (which doesn't mean that it couldn't further benefit from these). The optimisation uses three simple tricks:

  1. The function is now 32-byte aligned (which significantly boosted performance),

  2. Main loop goes inversely, which reduces comparison to a zero test (based on EFLAGS),

  3. Instruction-level address arithmetic proved to be faster than the "external" pointer calculation (even though it requires twice as much additions «in 3/4 cases»). It shortened the loop body by four instructions and reduced data dependencies within its execution path. See related question.

Additionally, the code uses a relative jump syntax which suppresses symbol redefinition error, which occurs when GCC tries to inline it (after being placed within asm statement and compiled with -O3).

    .text
    .align 32                           # 1. function entry alignment
    .globl matrixMultiplyASM            #    (for a faster call)
    .type matrixMultiplyASM, @function
matrixMultiplyASM:
    movaps   (%rdi), %xmm0
    movaps 16(%rdi), %xmm1
    movaps 32(%rdi), %xmm2
    movaps 48(%rdi), %xmm3
    movq $48, %rcx                      # 2. loop reversal
1:                                      #    (for simpler exit condition)
    movss (%rsi, %rcx), %xmm4           # 3. extended address operands
    shufps $0, %xmm4, %xmm4             #    (faster than pointer calculation)
    mulps %xmm0, %xmm4
    movaps %xmm4, %xmm5
    movss 4(%rsi, %rcx), %xmm4
    shufps $0, %xmm4, %xmm4
    mulps %xmm1, %xmm4
    addps %xmm4, %xmm5
    movss 8(%rsi, %rcx), %xmm4
    shufps $0, %xmm4, %xmm4
    mulps %xmm2, %xmm4
    addps %xmm4, %xmm5
    movss 12(%rsi, %rcx), %xmm4
    shufps $0, %xmm4, %xmm4
    mulps %xmm3, %xmm4
    addps %xmm4, %xmm5
    movaps %xmm5, (%rdx, %rcx)
    subq $16, %rcx                      # one 'sub' (vs 'add' & 'cmp')
    jge 1b                              # SF=OF, idiom: jump if positive
    ret

This is the fastest x86-64 implementation I have seen so far. I will appreciate, vote up and accept any answer providing a faster piece of assembly for that purpose!

share|improve this answer
    
I'm having trouble getting this to work. I'm calling it from C with this signature: void abramowicz_MM4x4(float *A, float *B, float *C); And then I have the assembly in another file named to match gcc name mangling: .globl _Z16abramowicz_MM4x4PfS_S _Z16abramowicz_MM4x4PfS_S: The call gives incorrect values. What might be going wrong? – Praxeolitic Mar 22 '14 at 21:34
    
The issue was that the order of the arguments are flipped. For anyone who is going to try this either flip A and B in the function signature in C or flip rdi and rsi in the asm. – Praxeolitic Mar 23 '14 at 0:47
    
anyone have an intel ASM translation of above? – Jason Nelson Dec 17 '15 at 3:42

I wonder if transposing one of the matrices may be beneficial.

Consider how we multiply the following two matrices ...

A1 A2 A3 A4        W1 W2 W3 W4
B1 B2 B3 B4        X1 X2 X3 X4
C1 C2 C3 C4    *   Y1 Y2 Y3 Y4
D1 D2 D3 D4        Z1 Z2 Z3 Z4

This would result in ...

dot(A,?1) dot(A,?2) dot(A,?3) dot(A,?4)
dot(B,?1) dot(B,?2) dot(B,?3) dot(B,?4)
dot(C,?1) dot(C,?2) dot(C,?3) dot(C,?4)
dot(D,?1) dot(D,?2) dot(D,?3) dot(D,?4)

Doing the dot product of a row and a column is a pain.

What if we transposed the second matrix before we multiplied?

A1 A2 A3 A4        W1 X1 Y1 Z1
B1 B2 B3 B4        W2 X2 Y2 Z2
C1 C2 C3 C4    *   W3 X3 Y3 Z3
D1 D2 D3 D4        W4 X4 Y4 Z4

Now instead doing the dot product of a row and column, we are doing the dot product of two rows. This could lend itself to better use of the SIMD instructions.

Hope this helps.

share|improve this answer
4  
You almost never want to do a dot product of two vectors with SSE. Instead you do do four dot products at once. You do the same thing you do with scalar code but instead you use SIMD registers. E.g. for four components vectors this means you do 4 _mm_mul_ps and 3 _mm_add_ps and this gives you four dot products. – Z boson Aug 29 '13 at 8:52
1  
@redrum: I see. Until now, I've been using combinations of "mulps" and "haddps" for dot products and matrix,vector multiplication. Looks like I have some more tweaking to do. – Sparky Aug 29 '13 at 12:10
1  
hadd has its use sometimes but not in this case. I have never found dpps to be useful. – Z boson Aug 30 '13 at 7:18
    
@Zboson Would you mind explaining your statement a bit further please? Why would you do 4 _mm_mul_pss instead of _mm_mul_sss, if everything is the same as in the scalar case? – user1095108 Sep 11 '14 at 7:48
    
@user1095108, I mean the SIMD code if used efficiently looks almost the same as the scalar case. Consider the 3D dot product w = x1x2 + y1y2 +z1z1. The variables here can be scalars or SIMD vectors and the results w is either a single number or the result of multiple dot products at once. Each case uses the same number of instructions: 3 mults and 2 adds. But the scalar case uses scalar instructions and the SIMD case the SIMD instructions. – Z boson Sep 11 '14 at 8:00

Obviously you can fetch terms from four matrices at a time and multiply four matrices simultaneously using the same algorithm.

share|improve this answer
    
Elaborate... does it really answer the question? – peterh Nov 20 '15 at 22:36

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