Many people doing "serious" matrix stuff, rely on BLAS, adding LAPACK / ATLAS (normal matrices) or UMFPACK (sparse matrices) for more advanced math. The reason is that this code is well-tested, stable, reliable, and quite fast. Furthermore, you can buy them directly from a vendor (e.g. Intel MKL) tuned towards your architecture, but also get them for free. uBLAS mentioned in Manuel's answer is probably the standard C++ BLAS implementation. And if you need something like LAPACK later on, there are bindings to do so.

However, none of these standard libraries (BLAS / LAPACK / ATLAS or uBLAS + bindings + LAPACK / ATLAS) ticks your box for being templated and easy to use (unless uBLAS is all you'll ever need). Actually, I must admit, that I tend to call the C / Fortran interface directly when I use a BLAS / LAPACK implementation, since I often don't see much additional advantage in the uBLAS + bindings combination.

If I a need a simple-to-use, general-purpose C++ matrix library, I tend to use Eigen (I used to use NewMat in the past). Advantages:

- quite fast on Intel architecture, probably the fastest for smaller matrices
- nice interface
- almost everything you expect from a matrix library
- you can easily add new types

Disadvantages (IMO):

- single-processor [
**Edit:** partly fixed in Eigen 3.0]
- slower for larger matrices and some advanced math than ATLAS or Intel MKL (e.g. LU decomposition) [
**Edit:** also improved in Eigen 3.0]
- only experimental support for sparse matrices [
**Edit:** improved in upcoming version 3.1].

**Edit:** The upcoming Eigen 3.1 allows some functions to use the Intel MKL (or any other BLAS / LAPACK implementation).