# Most efficient way to loop through an Eigen matrix

I'm creating some functions to do things like the "separated sum" of negative and positive number, kahan, pairwise and other stuff where it doesn't matter the order I take the elements from the matrix, for example:

``````template <typename T, int R, int C>
inline T sum(const Eigen::Matrix<T,R,C>& xs)
{
T sumP(0);
T sumN(0);
for (size_t i = 0, nRows = xs.rows(), nCols = xs.cols(); i < nRows; ++i)
for (size_t j = 0; j < nCols; ++j)
{
if (xs(i,j)>0)
sumP += xs(i,j);
else if (xs(i,j)<0) //ignore 0 elements: improvement for sparse matrices I think
sumN += xs(i,j);
}
return sumP+sumN;
}
``````

Now, I would like to make this as efficient as possible, so my question is, would it be better to loop through each column of each row like the above, or do the opposite like the the following:

``````for (size_t i = 0, nRows = xs.rows(), nCols = xs.cols(); i < nCols; ++i)
for (size_t j = 0; j < nRows; ++j)
``````

(I suppose this depends on the order that the matrix elements are allocated in memory, but I couldn't find this in Eigen's manual).

Also, are there other alternate ways like using iterators (do they exist in Eigen?) that might be slightly faster?

Eigen allocates matrices in column-major (Fortran) order by default (documentation).

The fastest way to iterate over a matrix is in storage order, doing it the wrong way round will increase the number of cache misses (which if your matrix doesn't fit in L1 will dominate your computation time, so read increase your computation time) by a factor of cacheline/elemsize (probably 64/8=8).

If your matrix fits into L1 cache this won't make a difference, but a good compiler should be able to vectorise the loop, which with AVX enabled (on a shiny new core i7) could give you a speedup of as much as 4 times. (256 bits / 64 bits).

Finally don't expect any of Eigen's built-in functions to give you a speed-up (I don't think there are iterators anyhow, but I may be mistaken), they're just going to give you the same (very simple) code.

TLDR: Swap your order of iteration, you need to vary the row index most quickly.

• The page in the link you sent used `PlainObjectBase::data()` like this `for (int i = 0; i < Acolmajor.size(); i++)`, I didn't new this function existed, maybe it's as fast as simple loops and I don't have to worry if it's a column and row major order matrix. I'll do some benchmarks to check this. Thanks for the answer and link! – random_user Apr 29 '13 at 19:38
• Ah, I didn't know about that function either. That's even better! – jleahy Apr 29 '13 at 20:32
• Yeah! Take a look at my answer: it's way faster than the other two other ways! – random_user Apr 29 '13 at 20:52

I did some benchmarks to checkout which way is quicker, I got the following results (in seconds):

``````12
30
3
6
23
3
``````

The first line is doing iteration as suggested by @jleahy. The second line is doing iteration as I've done in my code in the question (the inverse order of @jleahy). The third line is doing iteration using `PlainObjectBase::data()`like this `for (int i = 0; i < matrixObject.size(); i++)`. The other 3 lines repeat the same as the above, but with an temporary as suggest by @lucas92

I also did the same tests but using substituting /if else.*/ for /else/ (no special treatment for sparse matrix) and I got the following (in seconds):

``````10
27
3
6
24
2
``````

Doing the tests again gave me results pretty similar. I used `g++ 4.7.3` with `-O3`. The code:

``````#include <ctime>
#include <iostream>
#include <Eigen/Dense>

using namespace std;

template <typename T, int R, int C>
inline T sum_kahan1(const Eigen::Matrix<T,R,C>& xs) {
if (xs.size() == 0) return 0;
T sumP(0);
T sumN(0);
T tP(0);
T tN(0);
T cP(0);
T cN(0);
T yP(0);
T yN(0);
for (size_t i = 0, nRows = xs.rows(), nCols = xs.cols(); i < nCols; ++i)
for (size_t j = 0; j < nRows; ++j)
{
if (xs(j,i)>0)
{
yP = xs(j,i) - cP;
tP = sumP + yP;
cP = (tP - sumP) - yP;
sumP = tP;
}
else if (xs(j,i)<0)
{
yN = xs(j,i) - cN;
tN = sumN + yN;
cN = (tN - sumN) - yN;
sumN = tN;
}
}
return sumP+sumN;
}

template <typename T, int R, int C>
inline T sum_kahan2(const Eigen::Matrix<T,R,C>& xs) {
if (xs.size() == 0) return 0;
T sumP(0);
T sumN(0);
T tP(0);
T tN(0);
T cP(0);
T cN(0);
T yP(0);
T yN(0);
for (size_t i = 0, nRows = xs.rows(), nCols = xs.cols(); i < nRows; ++i)
for (size_t j = 0; j < nCols; ++j)
{
if (xs(i,j)>0)
{
yP = xs(i,j) - cP;
tP = sumP + yP;
cP = (tP - sumP) - yP;
sumP = tP;
}
else if (xs(i,j)<0)
{
yN = xs(i,j) - cN;
tN = sumN + yN;
cN = (tN - sumN) - yN;
sumN = tN;
}
}
return sumP+sumN;
}

template <typename T, int R, int C>
inline T sum_kahan3(const Eigen::Matrix<T,R,C>& xs) {
if (xs.size() == 0) return 0;
T sumP(0);
T sumN(0);
T tP(0);
T tN(0);
T cP(0);
T cN(0);
T yP(0);
T yN(0);
for (size_t i = 0, size = xs.size(); i < size; i++)
{
if ((*(xs.data() + i))>0)
{
yP = (*(xs.data() + i)) - cP;
tP = sumP + yP;
cP = (tP - sumP) - yP;
sumP = tP;
}
else if ((*(xs.data() + i))<0)
{
yN = (*(xs.data() + i)) - cN;
tN = sumN + yN;
cN = (tN - sumN) - yN;
sumN = tN;
}
}
return sumP+sumN;
}

template <typename T, int R, int C>
inline T sum_kahan1t(const Eigen::Matrix<T,R,C>& xs) {
if (xs.size() == 0) return 0;
T sumP(0);
T sumN(0);
T tP(0);
T tN(0);
T cP(0);
T cN(0);
T yP(0);
T yN(0);
for (size_t i = 0, nRows = xs.rows(), nCols = xs.cols(); i < nCols; ++i)
for (size_t j = 0; j < nRows; ++j)
{
T temporary = xs(j,i);
if (temporary>0)
{
yP = temporary - cP;
tP = sumP + yP;
cP = (tP - sumP) - yP;
sumP = tP;
}
else if (temporary<0)
{
yN = temporary - cN;
tN = sumN + yN;
cN = (tN - sumN) - yN;
sumN = tN;
}
}
return sumP+sumN;
}

template <typename T, int R, int C>
inline T sum_kahan2t(const Eigen::Matrix<T,R,C>& xs) {
if (xs.size() == 0) return 0;
T sumP(0);
T sumN(0);
T tP(0);
T tN(0);
T cP(0);
T cN(0);
T yP(0);
T yN(0);
for (size_t i = 0, nRows = xs.rows(), nCols = xs.cols(); i < nRows; ++i)
for (size_t j = 0; j < nCols; ++j)
{
T temporary = xs(i,j);
if (temporary>0)
{
yP = temporary - cP;
tP = sumP + yP;
cP = (tP - sumP) - yP;
sumP = tP;
}
else if (temporary<0)
{
yN = temporary - cN;
tN = sumN + yN;
cN = (tN - sumN) - yN;
sumN = tN;
}
}
return sumP+sumN;
}

template <typename T, int R, int C>
inline T sum_kahan3t(const Eigen::Matrix<T,R,C>& xs) {
if (xs.size() == 0) return 0;
T sumP(0);
T sumN(0);
T tP(0);
T tN(0);
T cP(0);
T cN(0);
T yP(0);
T yN(0);
for (size_t i = 0, size = xs.size(); i < size; i++)
{
T temporary = (*(xs.data() + i));
if (temporary>0)
{
yP = temporary - cP;
tP = sumP + yP;
cP = (tP - sumP) - yP;
sumP = tP;
}
else if (temporary<0)
{
yN = temporary - cN;
tN = sumN + yN;
cN = (tN - sumN) - yN;
sumN = tN;
}
}
return sumP+sumN;
}

template <typename T, int R, int C>
inline T sum_kahan1e(const Eigen::Matrix<T,R,C>& xs) {
if (xs.size() == 0) return 0;
T sumP(0);
T sumN(0);
T tP(0);
T tN(0);
T cP(0);
T cN(0);
T yP(0);
T yN(0);
for (size_t i = 0, nRows = xs.rows(), nCols = xs.cols(); i < nCols; ++i)
for (size_t j = 0; j < nRows; ++j)
{
if (xs(j,i)>0)
{
yP = xs(j,i) - cP;
tP = sumP + yP;
cP = (tP - sumP) - yP;
sumP = tP;
}
else
{
yN = xs(j,i) - cN;
tN = sumN + yN;
cN = (tN - sumN) - yN;
sumN = tN;
}
}
return sumP+sumN;
}

template <typename T, int R, int C>
inline T sum_kahan2e(const Eigen::Matrix<T,R,C>& xs) {
if (xs.size() == 0) return 0;
T sumP(0);
T sumN(0);
T tP(0);
T tN(0);
T cP(0);
T cN(0);
T yP(0);
T yN(0);
for (size_t i = 0, nRows = xs.rows(), nCols = xs.cols(); i < nRows; ++i)
for (size_t j = 0; j < nCols; ++j)
{
if (xs(i,j)>0)
{
yP = xs(i,j) - cP;
tP = sumP + yP;
cP = (tP - sumP) - yP;
sumP = tP;
}
else
{
yN = xs(i,j) - cN;
tN = sumN + yN;
cN = (tN - sumN) - yN;
sumN = tN;
}
}
return sumP+sumN;
}

template <typename T, int R, int C>
inline T sum_kahan3e(const Eigen::Matrix<T,R,C>& xs) {
if (xs.size() == 0) return 0;
T sumP(0);
T sumN(0);
T tP(0);
T tN(0);
T cP(0);
T cN(0);
T yP(0);
T yN(0);
for (size_t i = 0, size = xs.size(); i < size; i++)
{
if ((*(xs.data() + i))>0)
{
yP = (*(xs.data() + i)) - cP;
tP = sumP + yP;
cP = (tP - sumP) - yP;
sumP = tP;
}
else
{
yN = (*(xs.data() + i)) - cN;
tN = sumN + yN;
cN = (tN - sumN) - yN;
sumN = tN;
}
}
return sumP+sumN;
}

template <typename T, int R, int C>
inline T sum_kahan1te(const Eigen::Matrix<T,R,C>& xs) {
if (xs.size() == 0) return 0;
T sumP(0);
T sumN(0);
T tP(0);
T tN(0);
T cP(0);
T cN(0);
T yP(0);
T yN(0);
for (size_t i = 0, nRows = xs.rows(), nCols = xs.cols(); i < nCols; ++i)
for (size_t j = 0; j < nRows; ++j)
{
T temporary = xs(j,i);
if (temporary>0)
{
yP = temporary - cP;
tP = sumP + yP;
cP = (tP - sumP) - yP;
sumP = tP;
}
else
{
yN = temporary - cN;
tN = sumN + yN;
cN = (tN - sumN) - yN;
sumN = tN;
}
}
return sumP+sumN;
}

template <typename T, int R, int C>
inline T sum_kahan2te(const Eigen::Matrix<T,R,C>& xs) {
if (xs.size() == 0) return 0;
T sumP(0);
T sumN(0);
T tP(0);
T tN(0);
T cP(0);
T cN(0);
T yP(0);
T yN(0);
for (size_t i = 0, nRows = xs.rows(), nCols = xs.cols(); i < nRows; ++i)
for (size_t j = 0; j < nCols; ++j)
{
T temporary = xs(i,j);
if (temporary>0)
{
yP = temporary - cP;
tP = sumP + yP;
cP = (tP - sumP) - yP;
sumP = tP;
}
else
{
yN = temporary - cN;
tN = sumN + yN;
cN = (tN - sumN) - yN;
sumN = tN;
}
}
return sumP+sumN;
}

template <typename T, int R, int C>
inline T sum_kahan3te(const Eigen::Matrix<T,R,C>& xs) {
if (xs.size() == 0) return 0;
T sumP(0);
T sumN(0);
T tP(0);
T tN(0);
T cP(0);
T cN(0);
T yP(0);
T yN(0);
for (size_t i = 0, size = xs.size(); i < size; i++)
{
T temporary = (*(xs.data() + i));
if (temporary>0)
{
yP = temporary - cP;
tP = sumP + yP;
cP = (tP - sumP) - yP;
sumP = tP;
}
else
{
yN = temporary - cN;
tN = sumN + yN;
cN = (tN - sumN) - yN;
sumN = tN;
}
}
return sumP+sumN;
}

int main() {

Eigen::Matrix<double, Eigen::Dynamic, Eigen::Dynamic> test = Eigen::Matrix<double, Eigen::Dynamic, Eigen::Dynamic>::Random(10000,10000);

cout << "start" << endl;
int now;

now = time(0);
sum_kahan1(test);
cout << time(0) - now << endl;

now = time(0);
sum_kahan2(test);
cout << time(0) - now << endl;

now = time(0);
sum_kahan3(test);
cout << time(0) - now << endl;

now = time(0);
sum_kahan1t(test);
cout << time(0) - now << endl;

now = time(0);
sum_kahan2t(test);
cout << time(0) - now << endl;

now = time(0);
sum_kahan3t(test);
cout << time(0) - now << endl;

now = time(0);
sum_kahan1e(test);
cout << time(0) - now << endl;

now = time(0);
sum_kahan2e(test);
cout << time(0) - now << endl;

now = time(0);
sum_kahan3e(test);
cout << time(0) - now << endl;

now = time(0);
sum_kahan1te(test);
cout << time(0) - now << endl;

now = time(0);
sum_kahan2te(test);
cout << time(0) - now << endl;

now = time(0);
sum_kahan3te(test);
cout << time(0) - now << endl;

return 0;
}
``````
• Benchmarks! Beautiful. You'd be surprised how many people refuse to benchmark their code. I'm surprised that using .data is so much faster, that could be an indication that eigen is doing some work in the .cols, .rows and .xs functions. You could try hoisting xs.size() and xs.data() out of the loop, that might help even more if that's the case (although it's unlikely it might be worth a shot). – jleahy Apr 30 '13 at 9:27
• xs.size() is already out of the loop. I was having trouble putting xs.data() out: `T * xsBegin = xs.data();` as g++ was outputting those crazy big errors about templates and turns out I was just missing a const: `const T * xsBegin = xs.data();`. – random_user Apr 30 '13 at 15:41
• AFAIK `for (size_t i = 0, size = xs.size(); i < size; i++) { }` is similar to `{size_t i = 0, size = xs.size(); for (; i < size; i++) { } }` – random_user Apr 30 '13 at 16:22
• It is, my apologies, I wasn't looking at your code properly and I didn't notice you'd made the optimisation already. Previous comment retracted so not to confuse people. – jleahy Apr 30 '13 at 17:38

I notice that the code is equivalent to the sum of all the entries in the matrix, i.e., you could just do this:

``````return xs.sum();
``````

I would assume that would perform better since it's only a single pass, and furthermore Eigen ought to "know" how to arrange the passes for optimum performance.

If, however, you want to retain the two passes, you could express this using the coefficient-wise reduction mechanisms, like this:

``````return (xs.array() > 0).select(xs, 0).sum() +
(xs.array() < 0).select(xs, 0).sum();
``````

which uses the boolean coefficient-wise select to pick the positive and negative entries. I don't know whether it would outperform the hand-rolled loops, but in theory coding it this way allows Eigen (and the compiler) to know more about your intention, and possibly improve the results.

Try to store xs(i,j) inside a temporary variable inside the loop so you only call the function once.

• It's inside an if/else if so you only ever call it once. – jleahy Apr 29 '13 at 19:23
• I call it two or three times per iteration. I'll do some benchmarks to check if it's faster to create a temporary. – random_user Apr 29 '13 at 19:41