I'm writing a matrix library (part of SciRuby) with multiple storage types ('stypes') and multiple data types ('dtypes'). For example, a matrix's `stype`

may currently be dense, yale (AKA 'csr'), or list-of-lists; and its `dtype`

may be `int8`

, `int16`

, `int32`

, `int64`

, `float32`

, `float64`

, `complex64`

, etc.

It's super easy to write a template processor in Ruby or sed which takes a basic function (like sparse matrix multiplication) and creates a custom version for each possible `dtype`

. I could even write such a template to handle two different dtypes, say if we wanted to multiply an `int32`

by a `float64`

.

The same can be done in certain cases for different stypes. Eventually, though, you could end up with a very large set of functions, many of which never even get used in the course of most people's use.

It's also easy to use function pointer arrays to enable access to these functions -- and imagining even a 3-dimensional function pointer array is not too hard:

```
MultFuncs[lhs->stype][lhs->dtype][rhs->dtype](lhs->shape[0], rhs->shape[1], lhs->data, rhs->data, result->data);
// This might point to some function like this:
// i32_f64_dense_mult(size_t, size_t, int32_t*, float64*, float64*);
```

The extreme alternative to function pointer arrays, of course, which would be incredibly complicated to code and maintain, is hierarchical `switch`

or `if`

/`else`

statements:

```
switch(lhs->stype) {
case STYPE_SPARSE:
switch(lhs->dtype) {
case DTYPE_INT32:
switch(rhs->dtype) {
case DTYPE_FLOAT64:
i32_f64_mult(lhs->shape[0], rhs->shape[1], lhs->ija, rhs->ija, lhs->a, rhs->a, result->data);
break;
// ... and so on ...
```

It also seems that this would be O(*sd*^{2}), where *s*=number of stypes, *d*=number of dtypes for every operation, whereas the function pointer array would be O(*r*), where *r*=number of dimensions in the array.

But there's also a third option.

The third option is to use function pointer arrays for common operations (e.g., copying from one unknown type to another):

```
SetFuncs[lhs->dtype][rhs->dtype](5, // copy five consecutive items
&to, // destination
dtype_sizeof[lhs->dtype], // dtype_sizeof is a const size_t array giving sizeof(int8_t), sizeof(int16_t), etc.
&from, // source
dtype_sizeof[rhs->dtype]);
```

And then to call that from a generic sparse matrix multiplication function, which might be declared like this:

```
void generic_sparse_multiply(size_t* ija, size_t* ijb, void* a, void* b, int dtype_a, int dtype_b);
```

And that would use `SetFuncs[dtype_a][dtype_b]`

to reference the correct assignment function, for example. The downside, then, is that you might have to implement a whole bunch of these -- IncrementFuncs, DecrementFuncs, MultFuncs, AddFuncs, SubFuncs, etc. -- because you'd never know what types to expect.

So, finally, my questions:

- What is the cost, if any, of having enormous multi-dimensional const arrays of function pointers? Large library or executable? Slow load time? etc.
- Does use of generics like
`IncrementFuncs`

,`SetFuncs`

, etc. (which all probably depend on`memcpy`

or typecasts) present barriers to compile-time optimization? - If one were to use switch statements as described above, would these be optimized out by modern compilers? Or would they be evaluated every single time?

I realize this is an incredibly complicated array of questions.

If you can simply refer me to a good resource and prefer not to answer directly, that's perfectly fine. I used the Google extensively before posting this, but wasn't quite sure what search terms to use.

`int64`

,`float64`

and`complex64`

, and then writing transformers that will convert, say,`int8`

to`int64`

(and, if need so be, convert back from`int64`

to`int8`

)? – Jonathan Leffler Feb 15 '12 at 7:14