francescalus explained that reordering of operations causes these differences. Let's try to find out how it actually happened.
A few words about matrix product
Consider matrices A(n,p), B(p,q), C(n,q) and C = A*B.
The naive approach, a variant of which you used, involves the following nested loops:
c = 0
do i = 1, n
do j = 1, p
do k = 1, q
c(i, j) = c(i, j) + a(i, k) * b(k, j)
end do
end do
end do
These loops can be executed in any of 6 orders, depending on the variable that you choose at each level. In the example above, the loop is named "ijk", and the other variants "ikj", "jik", etc. are all correct.
There is a speed difference, due to the memory cache: when the inner loop runs across contiguous memory elements, the loop is faster. That's the jki or kji cases.
Indeed, since Fortran matrices are stored in column major order, if the innermost loop runs on i, in the instruction c(i, j) = c(i, j) + a(i, k) * c(k, j), the value c(k, j) is constant, and the operation is equivalent to v(i) = v(i) + x * u(i), where the elements of vectors v and u are contiguous.
However, regarding the order of operations, there shouldn't be a difference: you can check for yourself that all elements of C are computed in the same order. At least at the "higher level": the compiler might optimize things differently, and it's where it becomes really interesting.
What about MATMUL? I believe it's usually a naive matrix product, based on the nested loops above, say a jki loop.
There are other ways to multiply matrices, that involve the Strassen algorithm to improve the algorithm complexity or blocking (i.e. computed products of submatrices) to improve cache use. Other methods that could change the result are OpenMP (i.e. multithread), or using FMA instructions. But here we are not going to delve into these methods. It's really only about the nested loops. If you are interested, there are many resources online, check this.
A few words about optimization
Three remarks first:
- On a processor without SIMD instructions, you would get the same result as MATMUL (i.e. you would print zero in the end).
- If you had implemented the loops as above, you would also get the same result. There is a tiny but significant difference in your code.
- If you had implemented the loops as a subroutine, you would also get the same result. Here I suspect the compiler optimizer is doing some reordering, as I can't reproduce your "accumulator" code with a subroutine, at least with Intel Fortran.
Here is your implementation:
do i = 1, n
do j = 1, p
s = 0
do k = 1, q
s = s + a(i, k) * b(k, j)
end do
c(i, j) = s
end do
end do
It's also correct of course. Here, you are using an accumulator, and at the end of the innermost loop, the value of the accumulator is written in the matrix C.
Optimization is typically relevant on the innermost loop mainly. For our purpose, two "basic" instructions in the innermost loop are relevant, if we get rid of all other details:
- v(i) = v(i) + x*u(i) (the jki loop)
- s = s + x(k)*y(k) (the accumulator loop where y is contiguous in memory, but not x)
The first is usually called a "daxpy" (from the name of a BLAS routine), for "A X Plus Y", the "D" meaning double precision. The second one is just an accumulator.
On an old sequential processor, there is not much to be done to optimize. On a modern processor with SIMD, registers can hold several values, and computations can be done on all of them at once, in parallel. For instance, on x86, an XMM register (from SSE instruction set) can hold two double precision floating-point numbers. A YMM register (from AVX2) can hold four numbers, and a ZMM register (AVX512, found on Xeon) can hold eight numbers.
For instance, on YMM the innermost loop will be "unrolled" to deal with four vector elements at a time (or even more if using several registers).
Here is what the basic loop block is then roughly doing:
daxpy case:
- Read 4 numbers from u into register YMM1
- Read 4 numbers from v into register YMM2
- x is constant and is kept in another register
- Multiply in parallel x with YMM1, add in parallel to YMM2, put the result in YMM2
- Write back the result to corresponding elements of v
The read/write part is faster if the elements are contiguous in memory, but if they are not it's still worth doing this in parallel.
Note that here, we haven't changed the execution order of additions of the high level Fortran loop.
accumulator case
For the parallelism to be useful, there will be a trick: accumulate four values in parallel in a YMM register, and then add the four accumulated values.
The basic loop block is thus doing this:
- The accumulator is kept in YMM3 (four numbers)
- Read 4 numbers from X into register YMM1
- Read 4 numbers from Y into register YMM2
- Multiply in parallel YMM1 with YMM2, add in parallel to YMM3
At the end of the innermost loop, add the four components of the accumulator, and write this back as the matrix element.
It's like if we had computed:
- s1 = x(1)*y(1) + x(5)*y(5) + ... + x(29)*y(29)
- s2 = x(2)*y(2) + x(6)*y(6) + ... + x(30)*y(30)
- s3 = x(3)*y(3) + x(7)*y(7) + ... + x(31)*y(31)
- s4 = x(4)*y(4) + x(8)*y(8) + ... + x(32)*y(32)
And then the matrix element written is c(i,j) = s1+s2+s3+s4.
Here the order of additions has changed! And then, since the order is different, the result is very likely different.