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I'm using the Eigen library in a computer graphics project with meshes that will change often.

What are the performance implications of using a dynamic Eigen Matrix for all the vertex positions, normals, etc?

Should I use:

Eigen::Matrix<float, Eigen::Dynamic, 3, Eigen::RowMajor> vertices;


std::vector<Eigen::Vector3f> vertices;

I will have to copy the mesh data to GPU after every change, but as I understand it, I can do this with memcpy efficiently with both representations.

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3 Answers 3

up vote 1 down vote accepted

The memory layout of both representation are exactly the same. The main differences are that a std::vector<> is more flexible if you need to insert vectors or stuff like that. On the other hand a Matrix<.,3,Dynamic> is an Eigen object, so it is easier to perform some operations on it, e.g.:

Matrix<.,3,Dynamic> data;
data = Affine3f(...) * data; // apply an affine transformation
data.colwise().norm(); // get the norm of each vectors
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Vector will probably consume more memory, because it usually allocates more space than required to store data and vector will call default constructor and destructor for Eigen::Vector3f every time you resize it. AFAIK, default Eigen::Vector3f constructor is empty, so it will cost you zero in release build (but you may experience performance problems in debug build, due to this and debug iterators). On the other side, Eigen::Matrix will reallocate memory each time you resize it (it will also copy the content just as std::vector if you use conservativeResize), this is slow.

Howewer, I still recommend you to use vector, because it is more convenient. You can dynamically add elements, resize it without reallocation, it is simpler to use standart algorithms on vector. If you want to be sure, that your vector don't consume more memory than required, you can use this trick to resize it:

std::vector<Eigen::Vector3f> vertices;
vertices.swap( std::vector<Eigen::Vector3f>(size, Eigen::Vector3f()) );

Or see shrink_to_fit

And yes you can use memcpy to copy data efficently using both representation. But using std::copy will do the same job with same performance in release build (sometimes it is even replaced by compiler with memcpy).

Howewer, if you are still not satisfied with performance, here are tips I've made for myself to make a decision in such cases:

  • If you are going to frequently resize vertices array (add or remove elements) -> go with std::vector to avoid frequent reallocations.
  • If you store huge chunks of data in vertices array -> go with Eigen::Matrix to avoid excessive memory consumption.
  • If you are not satisfied with performance in debug mode (this will luckily be true if you frequently process data in your vertices array) -> go with Eigen::Matrix, stl debug iterators can ruin the performance (only true for MSVC)

Also consider boost::shared_array(scoped_array), these are especially designed to store large chunks of data without consuming extra memory. Using them makes more sense in your scenario.

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This answer contains good tips; unfortunately I can only accept one answer. –  Wilbert Dec 10 '12 at 9:35

Two issues in general with arrays of dynamically allocated matrices :

  • you won't be able to use a global memcpy to copy your whole structure : in the case of dynamically allocated matrices (for example, you have an std::vector<float*> instead of an std::vector<Eigen::Vector3f>), your array only contains a serie of pointers, and all these pointers can point to very different locations in memory. So, performing a memcpy will only copy the pointers, not the data, and there is no way to change that since your elements are not consecutive in memory (only their pointers are). Instead, you would need to go through each element of your std::vector, access it with operator[] and memcpy the element separately. For instance, when doing your memcpy, you will have sizeof(Eigen::Matrix<float, Eigen::Dynamic, 3, Eigen::RowMajor>) = sizeof(void*) + 2*sizeof(int) (or something similar : it stores a pointer and a number of rows and columns), while sizeof(Eigen::Vector3f) = 3*sizeof(float) since it really stores data and not pointers.

  • if you need to frequently create and destroy matrices, doing that with dynamically allocated matrices will be much slower. Having fixed-size matrices allows for the allocation to be made on the stack, which makes it much faster.

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