I am trying to write a function in Fortran that multiplies a number of matrices with different weights and then adds them together to form a single matrix. I have identified that this process is the bottleneck in my program (this weighting will be made *many* times for a single run of the program, with different weights). Right now I'm trying to make it run faster by switching from Matlab to Fortran. I am a newbie at Fortran so I appreciate all help.

In Matlab the fastest way I have found to make such a computation looks like this:

```
function B = weight_matrices()
n = 46;
m = 1800;
A = rand(n,m,m);
w = rand(n,1);
tic;
B = squeeze(sum(bsxfun(@times,w,A),1));
toc;
```

The line where `B`

is assigned runs in about 0.9 seconds on my machine (Matlab R2012b, MacBook Pro 13" retina, 2.5 GHz Intel Core i5, 8 GB 1600 MHz DDR3). It should be noted that for my problem, the tensor `A`

will be the same (constant) for the whole run of the program (after initialization), but w can take any values. Also, typical values of `n`

and `m`

are used here, meaning that the tensor `A`

will have a size of about 1 GB in memory.

The clearest way I can think of writing this in Fortran is something like this:

```
pure function weight_matrices(w,A) result(B)
implicit none
integer, parameter :: n = 46
integer, parameter :: m = 1800
double precision, dimension(num_sizes), intent(in) :: w
double precision, dimension(num_sizes,msize,msize), intent(in) :: A
double precision, dimension(msize,msize) :: B
integer :: i
B = 0
do i = 1,n
B = B + w(i)*A(i,:,:)
end do
end function weight_matrices
```

This function runs in about 1.4 seconds when compiled with gfortran 4.7.2, using -O3 (function call timed with "call cpu_time(t)"). If I manually unwrap the loop into

```
B = w(1)*A(1,:,:)+w(2)*A(2,:,:)+ ... + w(46)*A(46,:,:)
```

the function takes about 0.11 seconds to run instead. This is great and means that I get a speedup of about 8 times compared to the Matlab version. However, I still have some questions on readability and performance.

First, I wonder if there is an even faster way to perform this weighting and summing of matrices. I have looked through BLAS and LAPACK, but can't find any function that seems to fit. I have also tried to put the dimension in `A`

that enumerates the matrices as the last dimension (i.e. switching from `(i,j,k)`

to `(k,i,j)`

for the elements), but this resulted in slower code.

Second, this fast version is not very flexible, and actually looks quite ugly, since it is so much text for such a simple computation. For the tests I am running I would like to try to use different numbers of weights, so that the length of w will vary, to see how it affects the rest of my algorithm. However, that means I quite tedious rewrite of the assignment of `B`

every time. Is there any way to make this more flexible, while keeping the performance the same (or better)?

Third, the tensor `A`

will, as mentioned before, be constant during the run of the program. I have set constant scalar values in my program using the "parameter" attribute in their own module, importing them with the "use" expression into the functions/subroutines that need them. What is the best way to do the equivalent thing for the tensor `A`

? I want to tell the compiler that this tensor will be constant, after init., so that any corresponding optimizations can be done. Note that `A`

is typically ~1 GB in size, so it is not practical to enter it directly in the source file.

Thank you in advance for any input! :)