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I am using the C++ Eigen 3 library in my program. In particular, I need to multiply two Eigen sparse matrix and store the result into another Eigen sparse matrix. However, I noticed that if the some entries of the Eigen sparse matrix is smaller than 1e-13, the corresponding entry in the result will be 0 instead of a small number. Say I multiply a sparse identity matrix a and another sparse matrix b. If the topleft entry of b, i.e., b(0,0) is smaller than 1e-13, such as 9e-14, the topleft entry of of the result c=a*b, i.e., c(0,0), is 0 instead of 9e-14.

Here is a code I test,

#include <iostream>
#include <math.h>
#include <Eigen/Sparse>
#include <Eigen/Dense>
#include <Eigen/Eigen>
#include <Eigen/Dense>
#include <Eigen/LU>

using namespace std;
using namespace Eigen;

int main() {

DynamicSparseMatrix<double, RowMajor> a(2,2);
DynamicSparseMatrix<double, ColMajor> b(2,2);
DynamicSparseMatrix<double, RowMajor> c(2,2);
a.coeffRef(0,0) = 1;
a.coeffRef(1,1) = 1;
b.coeffRef(0,0) = 9e-14;
b.coeffRef(1,1) = 1;
cout << "a" << endl;
cout << a << endl;
cout << "b" << endl;
cout << b << endl;
c = a * b;
cout << "c" << endl;
cout << c << endl;
Matrix<double, Dynamic, Dynamic> a2(2,2);
Matrix<double, Dynamic, Dynamic> b2(2,2);
Matrix<double, Dynamic, Dynamic> c2(2,2);
a2(0,0) = 1;
a2(1,1) = 1;
b2(0,0) = 9e-14;
b2(1,1) = 1;
cout << "a2" << endl;
cout << a2 << endl;
cout << "b2" << endl;
cout << b2 << endl;
c2 = a2 * b2;
cout << "c2" << endl;
cout << c2 << endl;

return 1;

Here is the strange output


1 0

0 1


Nonzero entries:

(9e-14,0) (1,1)

Column pointers:

0 1 $

9e-14 0

0 1


0 0

0 1


1 0

0 1


9e-14 0

0 1


9e-14 0

0 1

You can see the multiplication of the dense matrices is fine, but the result of the sparse matrices is wrong in the top left entry, and b has a strange output format.

I debugged into the source code of Eigen, but couldn't find where the two numbers are multiplied in the matrix. Any idea?

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Have you checked that the a and b matrices look like you think? –  Martin Kristiansen Jun 18 '11 at 21:22
I just did it and edit the question. b has a very strange output format. –  Xatan Jun 18 '11 at 21:31

2 Answers 2

There are several reasons to truncate small values to zero in a linear algebra library.

As you get close to zero, the floating-point format fails to represent calculations well. For example, 9e-14 + 1.0 might equal 1.0 because there is not enough precision to represent the true result.

Getting into matrix-specific stuff, small values can make your matrix ill-conditioned and cause unreliable results. Rounding errors increase as you get close to zero, so a tiny rounding error could produce wildly varying results.

Finally, it helps maintain sparsity of the matrices. If a calculation creates very small nonzeros, you can truncate them and keep the matrix sparse. In a lot of physical applications like finite element analysis, the small values aren't physically significant and they can be removed safely.

I am not familiar with Eigen, but I glanced at their documentation and couldn't find a way to change this rounding threshold. They probably don't want users to make the wrong choice and screw up the reliability of their results. They allow you to do "pruning" manually, but not disable the automatic pruning.

The big picture is: if your calculation relies on floating-point values very close to zero, you should choose a different numerical method. The output will never be reliable. For example, you can replace 3D matrix rotations with quaternion rotations. These methods are called "Numerically stable" and they are a main focus of Numerical Analysis.

share|improve this answer
The dense matrix accepts small value while the sparse matrix does not. I hope this point were well documented so that I wouldn't have spent hours on debugging for this. –  Xatan Jul 24 '11 at 6:20
It's the third point - the library is trying to keep the matrices sparse, so it truncates very small values down to 0. I agree with you about the documentation though; I'm surprised they don't say anything about it. You'd think it would be an option under your control. –  japreiss Jul 24 '11 at 21:20
However, 9e-14 is nowhere close to "very small" for double numbers, so truncating them would certainly be a bug when not reconfigureable. –  thiton Sep 26 '11 at 16:06

I am not sure exactly where and how the truncation is done in Eigen, but the epsilon value used for the truncation is defined in NumTraits< Scalar >::dummy_precision() in Eigen/src/Core/NumTraits.h.

share|improve this answer
Yes, I see Eigen also uses this number is its LU decomposition for dense matrix. –  Xatan Aug 25 '11 at 4:37

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