doc/TopicMultithreading.dox - eigen - Git at Google

 namespace Eigen {

 /** \page TopicMultiThreading Eigen and multi-threading

 \section TopicMultiThreading_MakingEigenMT Make Eigen run in parallel

 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:
  - GCC: \c -fopenmp
  - ICC: \c -openmp
  - MSVC: check the respective option in the build properties.

 You can control the number of threads that will be used using either the OpenMP API or %Eigen's API using the following priority:
 \code
  OMP_NUM_THREADS=n ./my_program
  omp_set_num_threads(n);
  Eigen::setNbThreads(n);
 \endcode
 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:
 \code
 n = Eigen::nbThreads( );
 \endcode
 You can disable %Eigen's multi threading at compile time by defining the \link TopicPreprocessorDirectivesPerformance EIGEN_DONT_PARALLELIZE \endlink preprocessor token.

 Currently, the following algorithms can make use of multi-threading:
  - general dense matrix - matrix products
  - PartialPivLU
  - row-major-sparse * dense vector/matrix products
  - ConjugateGradient with \c Lower|Upper as the \c UpLo template parameter.
  - BiCGSTAB with a row-major sparse matrix format.
  - LeastSquaresConjugateGradient

 \warning On most OS it is <strong>very important</strong> to limit the number of threads to the number of physical cores, otherwise significant slowdowns are expected, especially for operations involving dense matrices.

 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 <i>cores</i> reported by OpenMP.

 \section TopicMultiThreading_UsingEigenWithMT Using Eigen in a multi-threaded application

 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 \b before creating the threads:
 \code
 #include <Eigen/Core>

 int main(int argc, char** argv)
 {
   Eigen::initParallel();

   ...
 }
 \endcode

 \note With %Eigen 3.3, and a fully C++11 compliant compiler (i.e., <a href="http://en.cppreference.com/w/cpp/language/storage_duration#Static_local_variables">thread-safe static local variable initialization</a>), then calling \c initParallel() is optional.

 \warning Note that all functions generating random matrices are \b not re-entrant nor thread-safe. Those include DenseBase::Random(), and DenseBase::setRandom() despite a call to `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 (\link DenseBase::NullaryExpr(Index, const CustomNullaryOp&) example \endlink) 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.

 \warning Using OpenMP with custom scalar types that might throw exceptions can lead to unexpected behaviour in the event of throwing.
 */

 }
	namespace Eigen {

	/** \page TopicMultiThreading Eigen and multi-threading

	\section TopicMultiThreading_MakingEigenMT Make Eigen run in parallel

	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:
	- GCC: \c -fopenmp
	- ICC: \c -openmp
	- MSVC: check the respective option in the build properties.

	You can control the number of threads that will be used using either the OpenMP API or %Eigen's API using the following priority:
	\code
	OMP_NUM_THREADS=n ./my_program
	omp_set_num_threads(n);
	Eigen::setNbThreads(n);
	\endcode
	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:
	\code
	n = Eigen::nbThreads( );
	\endcode
	You can disable %Eigen's multi threading at compile time by defining the \link TopicPreprocessorDirectivesPerformance EIGEN_DONT_PARALLELIZE \endlink preprocessor token.

	Currently, the following algorithms can make use of multi-threading:
	- general dense matrix - matrix products
	- PartialPivLU
	- row-major-sparse * dense vector/matrix products
	- ConjugateGradient with \c Lower\|Upper as the \c UpLo template parameter.
	- BiCGSTAB with a row-major sparse matrix format.
	- LeastSquaresConjugateGradient

	\warning On most OS it is <strong>very important</strong> to limit the number of threads to the number of physical cores, otherwise significant slowdowns are expected, especially for operations involving dense matrices.

	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 <i>cores</i> reported by OpenMP.

	\section TopicMultiThreading_UsingEigenWithMT Using Eigen in a multi-threaded application

	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 \b before creating the threads:
	\code
	#include <Eigen/Core>

	int main(int argc, char** argv)
	{
	Eigen::initParallel();

	...
	}
	\endcode

	\note With %Eigen 3.3, and a fully C++11 compliant compiler (i.e., <a href="http://en.cppreference.com/w/cpp/language/storage_duration#Static_local_variables">thread-safe static local variable initialization</a>), then calling \c initParallel() is optional.

	\warning Note that all functions generating random matrices are \b not re-entrant nor thread-safe. Those include DenseBase::Random(), and DenseBase::setRandom() despite a call to `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 (\link DenseBase::NullaryExpr(Index, const CustomNullaryOp&) example \endlink) 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.

	\warning Using OpenMP with custom scalar types that might throw exceptions can lead to unexpected behaviour in the event of throwing.
	*/

	}