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While there are plenty of java libraries for linear algebra, Clojure currently does not have an idiomatic computer algebra system that would include support for symbolic math. As a start I figure I can start working on something simple.

As a first step, I think getting the data structures right would be a good start.

Step 1: Implement a persistent matrix

I will be using deftype (or reify), and for now, for ease of implementation, I will use a hashmap for storage (Please suggest an alternative if think its better but state tradeoffs). (One can imagine many different implementations depending on your performance requirements, such as using arrays or delegating to an external java library and implementing some sort of transients interface.)

My question is, what interfaces/protocols should I be considering to implement? (In general, what is a good listing of all the protocols/interfaces that clojure uses?) Also is there any advice on how to implement these?

My list of things to implement:

-Assoc'ing would be useful, to modify sections of the matrix in an immutable manner

-treating the matrix as a function as an accessor of the elements, I was thinking you could pass a two-tuple to return a single element, a single value (index by width*y+x), hashmap to get columns, rows, or minor, via custom query hashmap/language.

Note, my goal at the moment is to design good abstractions that enable flexibility in choosing implementations.

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4 Answers 4

up vote 2 down vote accepted

I more or less manage the linear algebra modules in SymPy, a major Python symbolics package. I'll give you my perspective coming from a traditional computer algebra system.

We have three separate implementations for three important use cases

  1. Mutable matrices -- Despite being in Python SymPy is immutable by default. We've actually broken this rule for matrices. Matrix algorithms are the standard example of where you really need to switch to mutability for performance reasons.
  2. Immutable matrices -- But you'd like to have the option to switch back. Our intended workflow is as follows

    1. Build an immutable matrix
    2. Switch to mutability and perform some algorithm
    3. Switch back to immutability and present this to the user
  3. Matrix Symbols -- Often you don't need to deal with explicit entries in the matrix but would rather deal with the idea of a matrix. See this scicomp.stackexchange post. This is my current work and I find it to be very exciting.

There are other splits like dense representations vs sparsity. Symbolic linear algebra is a big and important field. I look forward to seeing the Clojure community's collective solution.

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I checked your links, nice work so far. One advantage of clojure is we have access to David Nolen's core.logic library so that may be quite useful in developing a CAS in clojure. I completely agree with the need to enable a "transient" like method for doing efficient work. Right now I'm simply looking for implementation details about designing good interfaces to make it easy to do any of the above you suggest (I'll update my question). Thank you for your points. –  bmillare Nov 17 '12 at 16:06
    
There are lots of advantages to doing this work in Clojure. core.logic is certainly embodies a number of them (I've had to reimplement some pieces of similar technology). Sadly my scientific user-base is much more into Python/Fortran/C than Lisp/Clojure. I look forward to seeing what the Clojure community does in this area. –  MRocklin Nov 17 '12 at 18:26

Although it is a Java library, I designed vectorz to be used from Clojure.

It offers a lot of data structures and algorithms for high performance vector and matrix maths. You might find it useful. I'm currently using it for both computer graphics and machine learning in Clojure.

The matrices and vectors are mutable, but I found that this was a necessary evil: using immutable vectors and matrices was simply too slow for many algorithms.

I'd be interested in building an idiomatic clojure wrapper (including immutable versions of vectors and matrices) if enough people would find this useful and/or want to get involved.

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Note, I'm interested in primarily symbolic manipulation, not numerical methods so performance is not on my priority. I'd rather have generic matrices that allow any types and make it simple to do any type of manipulation to its form. As an example problem, I want to do symbolic QR decomposition on a jacobian where each element was computed with a symbolic derivative, and then the expansion of all operations is emitted as code to be run directly on a GPU. –  bmillare Nov 17 '12 at 15:51

This may not be answering your question, but one thing I found while working with Incanter was I needed to be able to access elements with wraparound. Same for vectors, it's sometimes handy to be able to provide negative indices to access elements in reverse from the end, or out-of-range indices to access elements from the start. Naturally computing the offsets adds overhead but it's sometimes a feature you're willing to pay for

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MPL is a simple symbolic mathematics library written in portable R6RS Scheme. Here's a short introduction.

Since Scheme is a Lisp, MPL should be quite straightforward to port to Clojure.

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