If you want to make use of
core.matrix, there are only two implementations at present that are reasonably mature and performant:
Clatrix - uses calls to native BLAS
vectorz-clj - a flexible and fast pure-JVM implementation
It really comes down to your use cases. If you mostly care about big linear algebra operations and don't mind the native dependencies, then
Clatrix is your best bet at present - simply because BLAS implementations are so fast. This is particularly useful for:
- Large matrix multiplication
- Linear algebra (matrix decompositions etc.)
If you want to do general array-programming work, then
vectorz-clj has the advantage of being pure JVM code and much more flexible in terms of array/matrix formats. Examples of things that vectorz-clj supports well that you can't do in Clatrix:
- N-dimensional arrays
- Various specialised types of sparse arrays (diagonal matrices, different sparse storage formats etc.)
- Arrays with arbitrary strided access (like Numpy)
- Lightweight "views" into larger arrays
vectorz-clj won't be as fast for things like big matrix multiplication, but is probably faster than
Clatrix for many other operations and small/medium sized vector work. I'd normally choose
vectorz-clj unless I thought that linear algebra performance would be the main bottleneck.
core.matrix implementations are less mature, but may still be useful for specific use cases. A nice feature of
core.matrix is the ability to mix and match implementations while using the same common API, so it's not an "all or nothing" choice.
Disclaimer: I have created or contributed to many of the above projects. I hope I've given a fairly unbiased and objective evaluation.
If you don't need
core.matrix support, then you have many more options - you can use any of the Java matrix libraries via Clojure's Java interop. In theory, these could become
core.matrix implementations as well - the only constraint is that someone needs to do the work to extend the core.matrix protocols to support the new matrix types.