Sparse matrix class with parameterizable “zero”

I am doing some computations on a sparse matrix of floats in the log domain, so the "empty" entries are actually -Inf (using -FLT_MAX). I'm using a custom sparse matrix class right now but I am eager to swap in an off-the-shelf replacement.

This is in C++. My inclinations were to look at the compressed column matrices in Eigen and Boost uBlas. However it is not clear that either supports a custom value for "zero" (perhaps provided by a template parameter). Does anyone have a suggestion?

Clarification:

What I want is this: for any cell (i,j) that has not been "set" previously, I would like mat[i,j] to return -Inf ... so this is perhaps better described as a "default" value for the "empty" entries of the sparse matrix.

I am using this to perform HMM recursions (Viterbi, sum-product) with probabilities kept in the log domain to avoid underflow.

I am not doing any matrix operations ... I am just filling in a dynamic programming tableau, essentially. I want to use a sparse matrix class because I am only filling in a band of the matrix and I would like efficient memory use. The compressed band matrices would give good performance since I am filling in the matrix "in order."

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The "zero" elements of a conventional sparse matrix are not stored, nor are they used in any numerical calculations. I understand that `log(0) = -Inf` but I don't understand what you're trying to do - if you add `-FLT_MAX` for all zero elements you'll end up with a dense matrix, and at any rate I can't see how doing numerical operations on matrices involving `-Inf` is meaningful. Maybe I've missed the point? –  Darren Engwirda Aug 31 '11 at 14:48
For example, `x * 0 == 0`, but `x * -Inf != -Inf` when `x` is negative (and likewise `x + 0 == x`, but `x + -Inf != x`). So when doing a sparse matrix multiplication you can't just ignore the so-called empty values if those values are `-Inf`, whereas you can jump straight past a bunch of zeroes. –  Steve Jessop Aug 31 '11 at 14:58
I think what the OP wants is a sparse matrix where the zero cells are in fact some other value and not zero. So instead of a matrix where most of the values are zero (so it's sparse), most of the values are some value X (but still sparse in respect to non-X values). –  Skizz Aug 31 '11 at 15:10
What kind of computations do you intend to do with your matrix? –  Nicolas Grebille Aug 31 '11 at 16:34
@David: the questioner did explain - the values in the matrix are logs of probabilities, and will be anti-logged before multiplication. `-Inf` is used as an approximation to `log(0)`. So the sparse thing presumably doesn't needn't matrix arithmetic (which is meaningless in the log domain AFAIK), just a sparse 2-dimensional array with a tunable empty value would do. –  Steve Jessop Aug 31 '11 at 17:27

``````class compressed_matrix_nonzero_default : public boost::numeric::ublas::compressed_matrix<double>
{
double def;
public:
compressed_matrix_nonzero_default( int s1, int s2 )
: boost::numeric::ublas::compressed_matrix<double>(s1,s2)
, def(0)
{

}
void setDefault( double d ) { def = d; }
double value( int i, int j )
{
typedef boost::numeric::ublas::compressed_matrix<double>::iterator1 it1_t;
typedef boost::numeric::ublas::compressed_matrix<double>::iterator2 it2_t;
for (it1_t it1 = begin1(); it1 != end1(); it1++)
{
if( it1.index1() <  i )
continue;
if( it1.index1() > i ) {
return def;
}
for (it2_t it2 = it1.begin(); it2 != it1.end(); it2++)
{
if( it2.index2() < j )
continue;
if( it2.index2() == j )
return *it2;
if( it2.index2() > j )
return def;
}

}
return def;
}

};
``````

Usage

``````compressed_matrix_nonzero_default MNZ(3,3);
MNZ.setDefault(-100);
MNZ (1,1) = 45;

for( int i = 0; i < 3; i++ ) {
for( int j = 0; j < 3; j++ ) {
std::cout << MNZ.value(i,j) << ",";
}
std::cout << "\n";
}
``````
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Thanks ravenspoint, that's definitely a viable solution. My only fault with it is that it always involves a linear scan. If the underlying boost compressed_matrix has some fast caching scheme to speed up in-order accesses, we cannot take advantage of it in this way. But I do not know whether boost or eigen actually does implement such a scheme---I will have to check. –  David Alexander Aug 31 '11 at 21:52
Boost compressed_matrix actually has a nice separation of functionality here: find_element locates the (i,j) element and returns a pointer, while operator() either dereferences that pointer or returns zero_. So I think the hook I am looking for is either to set zero_ somehow or inherit and override operator() –  David Alexander Aug 31 '11 at 22:24
You may want to test the performance - that call to sort made by find_element looks expensive! –  ravenspoint Aug 31 '11 at 22:44
According to http://www.guwi17.de/ublas/matrix_sparse_usage.html, the appropriate way to fill a sparse_matrix "in order" is using push_back(i,j, val), which is then a constant-time operation. –  David Alexander Sep 1 '11 at 15:39
Sure. But what has that got to do with extracting a value from a random location? –  ravenspoint Sep 1 '11 at 19:23
show 1 more comment

The solution I have currently cooked up is this. Define a class `lfloat`:

``````class lfloat {
float value;
public:
lfloat(float f=-FLT_MAX)
{
value = f;
}

lfloat& operator=(float f)
{
value = f;
return *this;
}

operator float()   { return value; }
};
``````

and use it like so:

``````compressed_matrix<lfloat> M1(3,3);
``````

This way we are not rewriting any of the functionality in the boost matrix classes, but we should get the desired result.

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Have you tested this? It seems to me that the compressed matrix will return a zero value for absent values, which is exactly what you do not want. –  ravenspoint Sep 1 '11 at 19:26
I tested it and it works. I returns value_type() as "zero", which in this case will be lfloat()=-FLT_MAX –  David Alexander Sep 1 '11 at 21:15
That is neat. May I suggest a small optimization. Since each return of an absent value invokes the default constructor, you can speed it up a little by writing lfoat::lfloat() : value( -FLT_MAX ) {} –  ravenspoint Sep 2 '11 at 13:16