Vendor-provided LAPACK / BLAS libraries (Intel's IPP/MKL have been mentioned, but there's also AMD's ACML, and other CPU vendors like IBM/Power or Oracle/SPARC provide equivalents as well) are often highly optimized for specific CPU abilities that'll significantly boost performance on *large* datasets.

Often, though, you've got very *specific* small data to operate on (say, 4x4 matrices or 4D dot products, i.e. operations used in 3D geometry processing) and for those sort of things, BLAS/LAPACK are overkill, because of initial tests done by these subroutines which codepaths to choose, depending on properties of the data set. In those situations, simple C/C++ sourcecode, maybe using SSE2...4 intrinsics and/or compiler-generated vectorization, may beat BLAS/LAPACK.

That's why, for example, Intel has two libraries - MKL for *large* linear algebra datasets, and IPP for *small* (graphics vectors) data sets.

In that sense,

- what exactly is your data set ?
- What matrix/vector sizes ?
- What linear algebra operations ?

Also, regarding "simple for loops": Give the compiler the chance to vectorize for you. I.e. something like:

```
for (i = 0; i < DIM_OF_MY_VECTOR; i += 4) {
vecmul[i] = src1[i] * src2[i];
vecmul[i+1] = src1[i+1] * src2[i+1];
vecmul[i+2] = src1[i+2] * src2[i+2];
vecmul[i+3] = src1[i+3] * src2[i+3];
}
for (i = 0; i < DIM_OF_MY_VECTOR; i += 4)
dotprod += vecmul[i] + vecmul[i+1] + vecmul[i+2] + vecmul[i+3];
```

might be a better feed to a vectorizing compiler than the plain

```
for (i = 0; i < DIM_OF_MY_VECTOR; i++) dotprod += src1[i]*src2[i];
```

expression. In some ways, what you mean by *calculations with for loops* will have a significant impact.

If your vector dimensions are large enough though, the BLAS version,

```
dotprod = CBLAS.ddot(DIM_OF_MY_VECTOR, src1, 1, src2, 1);
```

will be cleaner code and likely faster.

On the reference side, these might be of interest: