I know Haskell a little bit, and I wonder if it's possible to write something like a matrix-matrix product in Haskell that is all of the following:

**Pure-functional**: no`IO`

or`State`

monads in its type signature (I don't care what happens in the function body.*That is, I don't care if the function body uses monads, as long as the whole function is pure*). I may want to use this matrix-matrix product in a pure function.**Memory-safe: no malloc or pointers**. I know that it's possible to "write C" in Haskell, but you lose memory safety. Actually writing this code in C and interfacing it with Haskell also loses memory safety.**As efficient as, say, Java.**For concreteness, let's assume I'm talking about a simple triple loop, single precision, contiguous column-major layout (`float[]`

, not`float[][]`

) and matrices of size 1000x1000, and a single-core CPU. (If you are getting 0.5-2 floating point operations per cycle, you are probably in the ballpark.)

(I don't want this to sound like a challenge, but note that Java can satisfy **all** of the above easily.)

I already know that

**The triple loop implementation is not the most efficient one**. It's quite cache-oblivious. It's better to use a well-written BLAS implementation in this particular case. However, one can not always count on a C library being available for what one is trying to do. I wonder if reasonably efficient code can be written in normal Haskell.**Some people wrote whole research papers that demonstrate #3**. However, I'm not a computer science researcher. I wonder if it's possible to keep simple things simple in Haskell.**The Gentle Introduction to Haskell has a matrix product implementation**. It wouldn't satisfy the above requirements though.

Addressing comments:

I have three reasons: first, the "no malloc or pointers" requirement is as yet ill-defined (I challenge you to write any piece of Haskell code which uses no pointers);

I saw plenty of Haskell programs not using `Ptr`

. Perhaps it refers to the fact that at the machine instruction level, pointers will be used? That's not what I meant. I was referring to the abstraction level of the Haskell source code.

second, the attack on CS research is out of place (and furthermore I can't imagine anything simpler than using code somebody else has already written for you); third, there are many matrix packages on Hackage (and the prep work for asking this question should include reviewing and rejecting each).

It seems that your #2 and #3 are the same ("use existing libraries"). I'm interested in the matrix product as a simple test of what Haskell can do on its own, and whether it allows you to "keep simple things simple". I could have easily come up with a numerical problem that doesn't have any ready libraries, but then I'd have to explain the problem, whereas everyone already knows what a matrix product is.

How can Java possibly satisfy 1.? Any Java method is essentially

`:: IORef Arg -> ... -> IORef This -> IO Ret`

This goes to the root of my question, actually (+1). While Java does not claim to track purity, Haskell does. In Java, whether the function is pure or not is indicated in the comments. I can claim that the matrix product is pure, even though I do mutation in the function body. **The question is whether Haskell's approach (purity encoded in the type system) is compatible with efficiency, memory-safety and simplicity.**

`:: IORef Arg -> ... -> IORef This -> IO Ret`

. – leftaroundabout Aug 1 '12 at 23:33