I have implemented one matrix multiplication with boost::numeric::ublas::matrix (see my full, working boost code)

Result result = read ();

boost::numeric::ublas::matrix<int> C;
C = boost::numeric::ublas::prod(result.A, result.B);

and another one with the standard algorithm (see full standard code):

vector< vector<int> > ijkalgorithm(vector< vector<int> > A, 
                                    vector< vector<int> > B) {
    int n = A.size();

    // initialise C with 0s
    vector<int> tmp(n, 0);
    vector< vector<int> > C(n, tmp);

    for (int i = 0; i < n; i++) {
        for (int k = 0; k < n; k++) {
            for (int j = 0; j < n; j++) {
                C[i][j] += A[i][k] * B[k][j];
            }
        }
    }
    return C;
}

This is how I test the speed:

time boostImplementation.out > boostResult.txt
diff boostResult.txt correctResult.txt

time simpleImplementation.out > simpleResult.txt
diff simpleResult.txt correctResult.txt

Both programs read a hard-coded textfile which contains two 2000 x 2000 matrices. Both programs were compiled with these flags:

g++ -std=c++98 -Wall -O3 -g $(PROBLEM).cpp -o $(PROBLEM).out -pedantic

I got 15 seconds for my implementation and over 4 minutes for the boost-implementation!

edit: After compiling it with

g++ -std=c++98 -Wall -pedantic -O3 -D NDEBUG -DBOOST_UBLAS_NDEBUG library-boost.cpp -o library-boost.out

I got 28.19 seconds for the ikj-algorithm and 60.99 seconds for Boost. So Boost is still considerably slower.

Why is boost so much slower than my implementation?

Slower performance of the uBLAS version can be partly explained by debugging features of the latter as was pointed out by TJD.

Here's the time taken by the uBLAS version with debugging on:

real    0m19.966s
user    0m19.809s
sys     0m0.112s

Here's the time taken by the uBLAS version with debugging off (-DNDEBUG -DBOOST_UBLAS_NDEBUG compiler flags added):

real    0m7.061s
user    0m6.936s
sys     0m0.096s

So with debugging off, uBLAS version is almost 3 times faster.

Remaining performance difference can be explained by quoting the following section of uBLAS FAQ "Why is uBLAS so much slower than (atlas-)BLAS":

An important design goal of ublas is to be as general as possible.

This generality almost always comes with a cost. In particular the prod function template can handle different types of matrices, such as sparse or triangular ones. Fortunately uBLAS provides alternatives optimized for dense matrix multiplication, in particular, axpy_prod and block_prod. Here are the results of comparing different methods:

ijkalgorithm   prod   axpy_prod  block_prod
   1.335       7.061    1.330       1.278

As you can see both axpy_prod and block_prod are somewhat faster than your implementation. Measuring just the computation time without I/O, removing unnecessary copying and careful choice of the block size for block_prod (I used 64) can make the difference more profound.

See also uBLAS FAQ and Effective uBlas and general code optimization.

I believe, your compiler doesn't optimize enough. uBLAS code makes heavy use of templates and templates require heavy use of optimizations. I ran your code through MS VC 7.1 compiler in release mode for 1000x1000 matrices, it gives me

10.064s for uBLAS

7.851s for vector

The difference is still there, but by no means overwhelming. uBLAS's core concept is lazy evaluation, so prod(A, B) evaluates results only when needed, e.g. prod(A, B)(10,100) will execute in no time, since only that one element will actually be calculated. As such there's actually no dedicated algorithm for whole matrix multiplication which could be optimized (see below). But you could help the library a little, declaring

matrix<int, column_major> B;

will reduce running time to 4.426s which beats your function with one hand tied. This declaration makes access to memory more sequential when multiplying matrices, optimizing cache usage.

P.S. Having read uBLAS documentation to the end ;), you should have found out that there's actually a dedicated function to multiply whole matrices at once. 2 functions - axpy_prod and opb_prod. So

opb_prod(A, B, C, true);

even on unoptimized row_major B matrix executes in 8.091 sec and is on par with your vector algorithm

P.P.S. There's even more optimizations:

C = block_prod<matrix<int>, 1024>(A, B);

executes in 4.4s, no matter whether B is column_ or row_ major. Consider the description: "The function block_prod is designed for large dense matrices." Choose specific tools for specific tasks!

I created a little website Matrix-Matrix Product Experiments with uBLAS. It's about integrating a new implementation for the matrix-matrix product into uBLAS. If you already have the boost library it only consists of additional 4 files. So it is pretty much self-contained.

I would be interested if others could run the simple benchmarks on different machines.