# Tag Info

## Hot answers tagged eigen

6

Eigen is mostly header-only library. All that you need is to add Eigen path to (MSVC2010): Project Properties -> C/C++ -> General -> Additional Include Directories Let's say you have header Core in folder C:/folder1/folder2/Eigen/, i.e.: C:/folder1/folder2/Eigen/Core So you should add path C:/folder1/folder2 to Additional Include Directories.

6

Perhaps I am not understanding the question correctly, but within Rcpp, I don't see how you could possibly do this more efficiently than a for loop. for loops are generally inefficient in R only because iterating through a loop in R requires a lot of heavy interpreted machinery. But this is not the case once you are down at the C++ level. Even natively ...

6

The best way to solve A system of linear equations of the Form Ax = b is to do the following. decompose A into the format A = M1 * M2 Solve M1 * y = b for y Solve M2 * x = y for x For square matrices, step 1 would use LU Decomposition. For non square matrices, step 1 would use QR Decomposition. Edit: matrix A is positive definite and not sparse. ...

5

Your compiler should be able to do this for you, using the common Return Value Optimization method. Basically what this does, is that the compiler rewrites load_from_gpu to take a pointer to an Eigen::MatrixXf as a parameter, and fill that matrix directly. Note that it can only do this because it can see that mat will always be the return value, if there ...

5

Not an answer, but maybe helpful for framing the issue. Seems like worst-case performance is to sum many short groups, and this seems to scale linearly with the size of the vector > n = 100000; x = runif(n); f = sample(n/2, n, TRUE) > system.time(rowsum(x, f)) user system elapsed 0.228 0.000 0.229 > n = 1000000; x = runif(n); f = ...

5

According to Eigen Doc: Vector(const T * array) Constructor reading the coords from an array. And vector reference: std::vector::data T* data(); const T* data() const; Returns pointer to the underlying array serving as element storage. The pointer is such that range [data(); data() + size()) is always a valid range, even if the container is ...

5

You are not allocating nothing in there. The line double y_OUT[nrow] = {}; contains two errors. As described by the error messages. nrow is not constexpr. It cannot be evaluated at compile time. by the braces initializer you suggest the vector has 0 elements, it does not make sense either. The proper syntax for dynamic allocation is: double* y_OUT = new ...

4

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 ...

4

I believe what you need to use is zip_view. Your for_each invocation would be: typedef demo::data_eigen<REALTYPE>& vector_ref; typedef boost::fusion::vector<vector_ref,vector_ref,vector_ref> my_zip; boost::fusion::for_each(boost::fusion::zip_view<my_zip>(my_zip(eig_d1, ...

4

You're trying to allocate 100000*100000 elements of 8 bytes each, or 80,000,000,000 bytes (74.5GB), which is failing as you only have 16GB of memory. This causes the memory allocation to fail, as it can't find a single continuous block of memory that large. There is no fixed limit in Eigen, but the array does need to be allocatable on your system.

4

You can also use void eigen2cv(const Eigen::Matrix<_Tp, _rows, _cols, _options, _maxRows, _maxCols>& src, Mat& dst) and void cv2eigen(const Mat& src, Eigen::Matrix<_Tp, _rows, _cols, _options, _maxRows, _maxCols>& dst) from #include <opencv2/core/eigen.hpp>.

4

libigl has many wrappers for Eigen to make it feel more like MATLAB. In particular, there is a slice function so that you can call: igl::slice(A,indices,B); which is equivalent to MATLAB's B = A(indices)

4

Yes, that's exactly what it means. You need to tell the compiler that head is a template and not a data member: return v6.template head<3>(); The reason that the compiler can't tell is because it doesn't know what the instantiated type of v6 is (since it depends on the template parameter Scalar). We had a question with the same answer earlier ...

3

Switching to R 3.0.0 should not per see have an impact on how a package such as RcppEigen performs. If you saw a regression in performance, something else may be going on. You can also try to ballpark things by compiling an SVD directly in C++ using Armadillo and / or Eigen (if you have them installed outside of R, and/or you may get the headers from the R ...

3

This operator is not available because we would have to disallow calling it with (i,j) with i!=j and therefore such a function would make little sense. You have to use a more verbose approach that consists in taking the diagonal: diag_mat.diagonal()[i] = ...; Here, the .diagonal() member returns an expression of the diagonal as a 1D vector. You can also ...

3

With thanks to ChriSopht_ from the #eigen IRC channel: VectorXd compareMat = ...; double cutoff = 3; Matrix<bool, Dynamic, 1> result = compareMat.array() <= cutoff; So, the trick is using .array() to get at coefficient-wise operators, and of course then getting the return type rightâ€¦

3

Using std::random_shuffle is perfectly fine, then you have to use a PermutationMatrix: PermutationMatrix<Dynamic,Dynamic> perm(size); perm.setIdentity(); std::random_shuffle(perm.indices().data(), perm.indices().data()+perm.indices().size()); A_perm = A * perm; // permute columns A_perm = perm * A; // permute rows

3

Firstly, Eigen's resize method reallocates memory if the new number of elements is not the same as the old, both when growing and when shrinking, so you would lose data in this case The following method uses .head<int>(), which is Eigen3's version of .start<int>(), plus some template programming so you don't have to check whether you're ...

3

No need for the row(0), you can either use ->coeff(i) (not recommended because it skips the assertions, even in debug mode), or use operator* to dereference your shared_pointer: for(int i=0; i<vec->size(); ++i) cout << (*vec)[i]; You can also use an InnerIterator, but you have to dereference your shared_pointer: RowVectorXf::InnerIterator ...

3

To complement Martin's code, here is some Rcpp based version. int increment_maybe(int value, double vec_i){ return vec_i == 0 ? value : ( value +1 ) ; } // [[Rcpp::export]] NumericVector cpprowsum2(NumericVector x, IntegerVector f){ std::vector<double> vec(10) ; vec.reserve(1000); int n=x.size(); for( int i=0; i<n; i++){ ...

3

You do not need to do any reverse operation. When using Eigen::Map you are mapping a raw array to an Eigen class. This means that you can now read or write it using Eighen functions. In case that you modify the mapped array the changes are already there. You can simply access the original array. float buffer[16]; //a raw array of float //let's map the ...

3

The DenseBase<> class is an empty base class, so it does not make sense to create an object of that type. So if you really want to pass input by value, then its type must be DERIVED not DenseBase. Nevertheless, it still sounds weird to pass it by value while the only purpose of your function to make another copy.

3

If you use a RowMajor matrix for A, then the copies will be much faster thanks to better cache coherence and vectorization: Matrix<double,10,Dynamic,RowMajor> A(10,n); However, this might also slow down other operations. Finally, make sure you compiled with optimizations on (e.g., -O2 with gcc), and it might be slightly faster to avoid the comma ...

3

Matlab uses MKL as its BLAS and LAPACK backend. And MKL is the fastest (in almost all the cases) library for BLAS and LAPACK on Intel CPUs. You could use these command to check the version of MKL used by Matlab >> version -blas >> version -lapack See this link for some benchmark results done by Intel himself. ...

3

.unaryExpr returns "view" to original data transformed by given function. It doesn't do transformation of original data. You cannot change argument passed to transformation function. Your code is compiled only because you have not triggered template instantiation of appropriate code. If assign result to value then it fails to compile: #include ...

3

Simply call the .data() function: glUniformMatrix4fv(render_projection_matrix_loc, 1, GL_FALSE, projection_matrix.data()); You might also be interested by the <unsupported/Eigen/OpenGLSupport> module which allows you to write: glUniform(render_projection_matrix_loc, projection_matrix); while taking care of the dimensions, scalar type, storage ...

3

There are 2 main options that come to my mind: The product of eigenvalues of square matrix is the determinant of this matrix, therefore a sum of logarithms of each eigenvalue is a logarithm of the determinant of this matrix. Assume det(A) = a and det(B) = b for compact notation. After applying aforementioned for 2 matrices A and B, we end up with log(a) ...

3

This is a bug in /usr/lib/debug/usr/lib/i386-linux-gnu/libstdc++.so.6.0.18-gdb.py. Make sure you have the lastest version of the gcc4.8 packages, it might be that this issue is already fixed in unbuntu (it is fixed in debian). See this bug entry. In the last ressort you can patch this file so that it searches in the right location.

3

This is not a full answer (yet - and I'm not sure it will become one). Let's think of the math first a little. Since matrix multiplication is associative we can either do (A*A')Y or A(A'*Y). Floating point operations for (A*A')*Y 2*m*n*m + 2*m*m*k //the twos come from addition and multiplication Floating point operations for A*(A'*Y) 2*m*n*k + 2*m*n*k ...

2

Try to use transposeInPlace() function Here is the documentation: http://eigen.tuxfamily.org/dox/TutorialMatrixArithmetic.html For in-place transposition, as for instance in a = a.transpose(), simply use the transposeInPlace() function: MatrixXf a(2,3); a << 1, 2, 3, 4, 5, 6; cout << "Here is the initial matrix a:\n" << a << ...

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