# Eigen how to concatenate matrix along a specific dimension?

I have two eigen matrices and I would like to concatenate them, like in matlab `cat(0, A, B)`

Is there anything equivalent in eigen?

Thanks.

• That matlab code does not work. – debo Sep 14 '17 at 19:58

You can use the comma initializer syntax for that.

Horizontally:

``````MatrixXd C(A.rows(), A.cols()+B.cols());
C << A, B;
``````

Vertically:

``````// eigen uses provided dimensions in declaration to determine
// concatenation direction
MatrixXd D(A.rows()+B.rows(), A.cols()); // <-- D(A.rows() + B.rows(), ...)
D << A, B; // <-- syntax is the same for vertical and horizontal concatenation
``````

For readability, one might format vertical concatenations with whitespace:

``````D << A,
B; // <-- But this is for readability only.
``````
• How does Eigen figure out whether to concatenate the matrices vertically or horizontally? Is it based on the size of the output matrix? – Sobi Oct 23 '16 at 20:59
• yes, you guessed right. (It's not based on the code formatting!) – ggael Oct 23 '16 at 21:55
• Can this be done with the sparse matrix? – donlan Mar 6 '18 at 23:21
• Not yet for sparse matrices. – ggael Mar 8 '18 at 13:10
• @ggael I don't think this "guessing" is very intuitive. It's not very explicit and it also requires quite a lot of "trust" that it really does "the right thing". Wouldn't it be better to handle this more explicitly? (It could be like numpy's `concatenate`/`hstack`/`vstack` or with the comma-initializer, I don't mind, though the numpy-way is used in lots of matrix libraries). – Ela782 May 25 '18 at 20:46

I had a slightly different use case: To vertically stack a std::vector of Eigen matrices. Here is how I implemented a function which is more general purpose. Let me know if this can be further improved:

``````// matrix_eig = Eigen::MatrixXf in RowMajor format
matrix_eig VStack(const std::vector<matrix_eig> &mat_vec) {
assert(!mat_vec.empty());
long num_cols = mat_vec.cols();
size_t num_rows = 0;
for (size_t mat_idx = 0; mat_idx < mat_vec.size(); ++mat_idx) {
assert(mat_vec[mat_idx].cols() == num_cols);
num_rows += mat_vec[mat_idx].rows();
}
matrix_eig vstacked_mat(num_rows, num_cols);
size_t row_offset = 0;
for (size_t mat_idx = 0; mat_idx < mat_vec.size(); ++mat_idx) {
long cur_rows = mat_vec[mat_idx].rows();
vstacked_mat.middleRows(row_offset, cur_rows) = mat_vec[mat_idx];
row_offset +=  cur_rows;
}
return vstacked_mat;
}
``````

I'd use Eigen's block indexing in a way similar to this post (which concatenates to an existing matrix).

The block indexing avoids the direction ambiguity in the accepted approach, and is pretty compact syntax. The following is equivalent to `C = cat(2, A, B)` in MATLAB:

``````MatrixXd C(A.rows(), A.cols()+B.cols());
C.leftCols(A.cols()) = A;
C.rightCols(B.cols()) = B;
``````