Both Eigen and Boost.uBLAS define expression hierarchies and abstract matrix data structures that can use any storage class that satisfies certain constraints. These libraries are written so that linear algebra operations can be clearly expressed and efficiently evaluated at a very high level. Both libraries use expression templates heavily, and are capable of doing pretty complicated compile-time expression transformations. In particular, Eigen can also use SIMD instructions, and is very competitive on several benchmarks.
For dense matrices, a common approach is to use a single pointer and keep track of additional row, column, and stride variables (the reason that you may need the third is because you may have allocated more memory than you really need to store
x * y * sizeof(value_type) elements because of alignment). However, you have no mechanisms in place to check for out-of-range accessing, and nothing in the code to help you debug. You would only want to use this sort of approach if, for example, you need to implement some linear algebra operations for educational purposes. (Even if this is the case, I advise that you first consider which algorithms you would like to implement, and then take a look at
std::allocator, and operator overloading).