Some Eigen's algorithms can exploit the multiple cores present in your hardware. To this end, it is enough to enable OpenMP on your compiler, for instance:
-fopenmp -openmp You can control the number of threads that will be used using either the OpenMP API or Eigen's API using the following priority:
Unless setNbThreads has been called, Eigen uses the number of threads specified by OpenMP. You can restore this behavior by calling setNbThreads(0);. You can query the number of threads that will be used with:
You can disable Eigen's multi threading at compile time by defining the EIGEN_DONT_PARALLELIZE preprocessor token.
Currently, the following algorithms can make use of multi-threading:
Lower|Upper as the UpLo template parameter.Indeed, the principle of hyper-threading is to run multiple threads (in most cases 2) on a single core in an interleaved manner. However, Eigen's matrix-matrix product kernel is fully optimized and already exploits nearly 100% of the CPU capacity. Consequently, there is no room for running multiple such threads on a single core, and the performance would drops significantly because of cache pollution and other sources of overheads. At this stage of reading you're probably wondering why Eigen does not limit itself to the number of physical cores? This is simply because OpenMP does not allow to know the number of physical cores, and thus Eigen will launch as many threads as cores reported by OpenMP.
In the case your own application is multithreaded, and multiple threads make calls to Eigen, then you have to initialize Eigen by calling the following routine before creating the threads:
initParallel() is optional.Eigen::initParallel(). This is because these functions are based on std::rand which is not re-entrant. For thread-safe random generator, we recommend the use of c++11 random generators (example ) or boost::random.In the case your application is parallelized with OpenMP, you might want to disable Eigen's own parallelization as detailed in the previous section.