# Slow performance of sparse matrix using std::vector

I'm trying to implement the functionality of MATLAB function `sparse`.

Insert a value in sparse matrix at a specific index such that:

If a value with same index is already present in the matrix, then the new and old values are added.

Else the new value is appended to the matrix.

The function `addNode` performs correctly but the problem is that it is extremely slow. I call this function in a loop about 100000 times and the program takes more than 3 minutes to run. While MATLAB accomplishes this task in a matter of seconds. Is there any way to optimize the code or use stl algorithms instead of my own function to achieve what I want?

# Code:

``````struct SparseMatNode
{
int x;
int y;
float value;
};

std::vector<SparseMatNode> SparseMatrix;

void addNode(int x, int y, float val)
{
SparseMatNode n;
n.x = x;
n.y = y;
n.value = val;

int i = 0;
for(i=0; i<SparseMatrix.size(); i++)
{
if((SparseMatrix[i].x == x) && (SparseMatrix[i].y == y))
{
break;
}
}

{
SparseMatrix[i].value += val;
if(SparseMatrix[i].value == 0.0f)
SparseMatrix.erase(SparseMatrix.begin + i);
}
else
SparseMatrix.push_back(n);
}
``````
-

The first thinks that stands out is that you are implementing your own functionality for finding an element: that's what `std::find` is for. So, instead of:

``````bool alreadyPresent = false;

int i = 0;
for(i=0; i<SparseMatrix.size(); i++)
{
if((SparseMatrix[i].x == x) && (SparseMatrix[i].y == y))
{
break;
}
}
``````

You should write:

``````auto it = std::find(SparseMatrix.begin(), SparseMatrix().end(), Comparer);
``````

where `Comparer` is a function that compares two `SparseMatNode` objects.

But the main improvement will come from using the appropriate container. Instead of `std::vector`, you will be much better off using an associative container. This way, finding an element will have just a `O(logN)` complexity instead of `O(N)`. You may slighly modify your `SparseMatNode` class as follows:

``````typedef std::pair<int, int> Coords;
typedef std::pair<const Coords, float> SparseMatNode;
``````

You may cover this typedefs inside a class to provide a better interface, of course.

And then:

``````std::unordered_map<Coords, float> SparseMatrix;
``````

This way you can use:

``````auto it = SparseMatrix.find(std::make_pair(x, y));
``````

to find elements much more efficiently.

-
I cant't use `auto`. I'm using VS2008. –  sgarizvi Nov 19 '12 at 8:02
@sgar91 I used `auto` for simplicity, but you can use the right type quite easily (`std::unordered_map<Coords, float>::iterator`). In the same way you can use your available hash map type instead of `std::unordered_map`. –  Gorpik Nov 19 '12 at 8:08

Sparse matrices aren't typically stored as a vector of triplets as you are attempting.

MATLAB (as well as many other libraries) uses a Compressed Sparse Column (CSC) data structure, which is very efficient for static matrices. The MATLAB function `sparse` also does not build the matrix one entry at a time (as you are attempting) - it takes an array of triplet entries and packs the whole sequence into a CSC matrix. If you are attempting to build a static sparse matrix this is the way to go.

If you want a dynamic sparse matrix object, that supports efficient insertion and deletion of entries, you could look at different structures - possibly a `std::map` of triplets, or an array of column lists - see here for more information on data formats.

Also, there are many good libraries. If you're wanting to do sparse matrix operations/factorisations etc - SuiteSparse is a good option, otherwise Eigen also has good sparse support.

-

Sparse matrices are usually stored in compressed sparse row (CSR) or compressed sparse column (CSC, also called Harwell-Boeing) format. MATLAB by default uses CSC, IIRC, while most sparse matrix packages tend to use CSR.

Anyway, if this is for production usage rather than a learning exercise, I'd recommend using a matrix package with support for sparse matrices. In the C++ world, my favourite is Eigen.

-

Have you tried sorting your vector of sparse nodes? Performing a linear search becomes costly every time you add a node. You could Insert In Place and always perform Binary Search.

-
All answers are informative, but in the end, your suggestion worked best. Sorting the vector leaded me to forming a better algo for the above mentioned process, and processing time was reduced by magnitudes. :) –  sgarizvi Nov 19 '12 at 16:51

Because sparse matrix may be huge and need to be compressed, you may use `std::unordered_map`. I assume matrix indexes (`x` and `y`) are always positive.

``````#include <unordered_map>

const size_t MAX_X =  1000*1000*1000;
std::unordered_map <size_t, float> matrix;

void addNode (size_t x, size_t y, float val)
{
size_t index = x + y*MAX_X;
matrix[index] += val;      //this function can be still faster
if (matrix[index] == 0)    //using find() / insert() methods
matrix.erase(index);
}
``````

If `std::unordered_map` is not available on your system, you may try `std::tr1::unordered_map` or `stdext::hash_map`...

If you can use more memory, then use `double` instead of `float`, this will improve a bit your processing speed.

-
-1: This is just a dense matrix - which is never going to work for general sparse problems (i.e. can easily have 100,000's rows/cols...) –  Darren Engwirda Nov 19 '12 at 7:45
Hi @DarrenEngwirda I have just finished to write my answer. You did not specified your MIN/MAX for `x` and `y` in your question. I know that my fastest version consumes lots of memory, but please test it, you may have enough memory on your computer. –  olibre Nov 19 '12 at 7:52
For general sparse problems it's not reasonable to use dense representations. It's not just about the memory, it's also the asymptotic performance of algorithms (i.e. sparse matrix multiplication/factorisation etc are much better than the `O(n^3)` performance of dense algorithms...). Also, it's @sgar91's question... –  Darren Engwirda Nov 19 '12 at 8:00
Ok @DarrenEngwirda, I read what 'sparse' matrix and 'dense' matrix are. Therefore I removed the fastest version as you suggested that was not relevant. I hope my current answer meets the requirements now. Cheers. –  olibre Nov 19 '12 at 8:35