boost/mpi/cartesian_communicator.hpp
// Copyright Alain Miniussi 2014. // Distributed under the Boost Software License, Version 1.0. // (See accompanying file LICENSE_1_0.txt or copy at // http://www.boost.org/LICENSE_1_0.txt) // Authors: Alain Miniussi /** @file cartesian_communicator.hpp * * This header defines facilities to support MPI communicators with * cartesian topologies. * If known at compiled time, the dimension of the implied grid * can be statically enforced, through the templatized communicator * class. Otherwise, a non template, dynamic, base class is provided. * */ #ifndef BOOST_MPI_CARTESIAN_COMMUNICATOR_HPP #define BOOST_MPI_CARTESIAN_COMMUNICATOR_HPP #include <boost/mpi/communicator.hpp> #include <vector> #include <utility> #include <iostream> #include <utility> #if !defined(BOOST_NO_CXX11_HDR_INITIALIZER_LIST) #include <initializer_list> #endif // BOOST_NO_CXX11_HDR_INITIALIZER_LIST // Headers required to implement cartesian topologies #include <boost/shared_array.hpp> #include <boost/assert.hpp> #include <boost/foreach.hpp> namespace boost { namespace mpi { /** * @brief Specify the size and periodicity of the grid in a single dimension. * * POD lightweight object. */ struct cartesian_dimension { /** The size of the grid n this dimension. */ int size; /** Is the grid periodic in this dimension. */ bool periodic; cartesian_dimension(int sz = 0, bool p = false) : size(sz), periodic(p) {} private: friend class boost::serialization::access; template<class Archive> void serialize(Archive & ar, const unsigned int version) { ar & size & periodic; } }; template <> struct is_mpi_datatype<cartesian_dimension> : mpl::true_ { }; /** * @brief Test if the dimensions values are identical. */ inline bool operator==(cartesian_dimension const& d1, cartesian_dimension const& d2) { return &d1 == &d2 || (d1.size == d2.size && d1.periodic == d2.periodic); } /** * @brief Test if the dimension values are different. */ inline bool operator!=(cartesian_dimension const& d1, cartesian_dimension const& d2) { return !(d1 == d2); } /** * @brief Pretty printing of a cartesian dimension (size, periodic) */ std::ostream& operator<<(std::ostream& out, cartesian_dimension const& d); /** * @brief Describe the topology of a cartesian grid. * * Behave mostly like a sequence of @c cartesian_dimension with the notable * exception that its size is fixed. * This is a lightweight object, so that any constructor that could be considered * missing could be replaced with a function (move constructor provided when supported). */ class BOOST_MPI_DECL cartesian_topology : private std::vector<cartesian_dimension> { friend class cartesian_communicator; typedef std::vector<cartesian_dimension> super; public: /** * Retrieve a specific dimension. */ using super::operator[]; /** * @brief Topology dimentionality. */ using super::size; using super::begin; using super::end; using super::swap; #if !defined(BOOST_NO_CXX11_DELETED_FUNCTIONS) cartesian_topology() = delete; #endif #if !defined(BOOST_NO_CXX11_DEFAULTED_FUNCTIONS) cartesian_topology(cartesian_topology const&) = default; cartesian_topology& operator=(cartesian_topology const&) = default; // There is apparently no macro for checking the support of move constructor. // Assume that defaulted function is close enough. #if !defined(BOOST_NO_CXX11_DEFAULTED_MOVES) cartesian_topology(cartesian_topology&& other) : super(other) {} cartesian_topology& operator=(cartesian_topology&& other) { stl().swap(other.stl()); return *this; } #endif ~cartesian_topology() = default; #endif /** * @brief Create a N dimension space. * Each dimension is initialized as non periodic of size 0. */ cartesian_topology(int ndim) : super(ndim) {} /** * @brief Use the provided dimensions specification as initial values. */ cartesian_topology(std::vector<cartesian_dimension> const& dims) : super(dims) {} /** * @brief Use dimensions specification provided in the sequence container as initial values. * #param dims must be a sequence container. */ template<class InitArr> explicit cartesian_topology(InitArr dims) : super(0) { BOOST_FOREACH(cartesian_dimension const& d, dims) { push_back(d); } } #if !defined(BOOST_NO_CXX11_HDR_INITIALIZER_LIST) /** * @brief Use dimensions specification provided in the initialization list as initial values. * #param dims can be of the form { dim_1, false}, .... {dim_n, true} */ explicit cartesian_topology(std::initializer_list<cartesian_dimension> dims) : super(dims) {} #endif /** * @brief Use dimensions specification provided in the array. * #param dims can be of the form { dim_1, false}, .... {dim_n, true} */ template<int NDIM> explicit cartesian_topology(cartesian_dimension (&dims)[NDIM]) : super(dims, dims+NDIM) {} /** * @brief Use dimensions specification provided in the input ranges * The ranges do not need to be the same size. If the sizes are different, * the missing values will be complete with zeros of the dim and assumed non periodic. * @param dim_rg the dimensions, values must convert to integers. * @param period_rg the periodicities, values must convert to booleans. * #param dims can be of the form { dim_1, false}, .... {dim_n, true} */ template<class DimRg, class PerRg> cartesian_topology(DimRg const& dim_rg, PerRg const& period_rg) : super(0) { BOOST_FOREACH(int d, dim_rg) { super::push_back(cartesian_dimension(d)); } super::iterator it = begin(); BOOST_FOREACH(bool p, period_rg) { if (it < end()) { it->periodic = p; } else { push_back(cartesian_dimension(0,p)); } ++it; } } /** * @brief Iterator based initializer. * Will use the first n iterated values. * Both iterators can be single pass. * @param dit dimension iterator, value must convert to integer type. * @param pit periodicity iterator, value must convert to booleans.. */ template<class DimIter, class PerIter> cartesian_topology(DimIter dit, PerIter pit, int n) : super(n) { for(int i = 0; i < n; ++i) { (*this)[i] = cartesian_dimension(*dit++, *pit++); } } /** * Export as an stl sequence. */ std::vector<cartesian_dimension>& stl() { return *this; } /** * Export as an stl sequence. */ std::vector<cartesian_dimension> const& stl() const{ return *this; } /** * Split the topology in two sequences of sizes and periodicities. */ void split(std::vector<int>& dims, std::vector<bool>& periodics) const; }; inline bool operator==(cartesian_topology const& t1, cartesian_topology const& t2) { return t1.stl() == t2.stl(); } inline bool operator!=(cartesian_topology const& t1, cartesian_topology const& t2) { return t1.stl() != t2.stl(); } /** * @brief Pretty printing of a cartesian topology */ std::ostream& operator<<(std::ostream& out, cartesian_topology const& t); /** * @brief An MPI communicator with a cartesian topology. * * A @c cartesian_communicator is a communicator whose topology is * expressed as a grid. Cartesian communicators have the same * functionality as (intra)communicators, but also allow one to query * the relationships among processes and the properties of the grid. */ class BOOST_MPI_DECL cartesian_communicator : public communicator { friend class communicator; /** * INTERNAL ONLY * * Construct a cartesian communicator given a shared pointer to the * underlying MPI_Comm (which must have a cartesian topology). * This operation is used for "casting" from a communicator to * a cartesian communicator. */ explicit cartesian_communicator(const shared_ptr<MPI_Comm>& comm_ptr) : communicator() { this->comm_ptr = comm_ptr; BOOST_ASSERT(has_cartesian_topology()); } public: /** * Build a new Boost.MPI cartesian communicator based on the MPI * communicator @p comm with cartesian topology. * * @p comm may be any valid MPI communicator. If @p comm is * MPI_COMM_NULL, an empty communicator (that cannot be used for * communication) is created and the @p kind parameter is * ignored. Otherwise, the @p kind parameter determines how the * Boost.MPI communicator will be related to @p comm: * * - If @p kind is @c comm_duplicate, duplicate @c comm to create * a new communicator. This new communicator will be freed when * the Boost.MPI communicator (and all copies of it) is * destroyed. This option is only permitted if the underlying MPI * implementation supports MPI 2.0; duplication of * intercommunicators is not available in MPI 1.x. * * - If @p kind is @c comm_take_ownership, take ownership of @c * comm. It will be freed automatically when all of the Boost.MPI * communicators go out of scope. * * - If @p kind is @c comm_attach, this Boost.MPI communicator * will reference the existing MPI communicator @p comm but will * not free @p comm when the Boost.MPI communicator goes out of * scope. This option should only be used when the communicator is * managed by the user. */ cartesian_communicator(const MPI_Comm& comm, comm_create_kind kind) : communicator(comm, kind) { BOOST_ASSERT(has_cartesian_topology()); } /** * Create a new communicator whose topology is described by the * given cartesian. The indices of the vertices in the cartesian will be * assumed to be the ranks of the processes within the * communicator. There may be fewer vertices in the cartesian than * there are processes in the communicator; in this case, the * resulting communicator will be a NULL communicator. * * @param comm The communicator that the new, cartesian communicator * will be based on. * * @param dims the cartesian dimension of the new communicator. The size indicate * the number of dimension. Some dimensions be set to zero, in which case * the corresponding dimension value is left to the system. * * @param reorder Whether MPI is permitted to re-order the process * ranks within the returned communicator, to better optimize * communication. If false, the ranks of each process in the * returned process will match precisely the rank of that process * within the original communicator. */ cartesian_communicator(const communicator& comm, const cartesian_topology& dims, bool reorder = false); /** * Create a new cartesian communicator whose topology is a subset of * an existing cartesian cimmunicator. * @param comm the original communicator. * @param keep and array containiing the dimension to keep from the existing * communicator. */ cartesian_communicator(const cartesian_communicator& comm, const std::vector<int>& keep ); using communicator::rank; /** * Retrive the number of dimension of the underlying toppology. */ int ndims() const; /** * Return the rank of the process at the given coordinates. * @param coords the coordinates. the size must match the communicator's topology. */ int rank(const std::vector<int>& coords) const; /** * Return the rank of the source and target destination process through a shift. * @param dim the dimension in which the shift takes place. 0 <= dim <= ndim(). * @param disp the shift displacement, can be positive (upward) or negative (downward). */ std::pair<int, int> shifted_ranks(int dim, int disp) const; /** * Provides the coordinates of the process with the given rank. * @param rk the ranks in this communicator. * @returns the coordinates. */ std::vector<int> coordinates(int rk) const; /** * Retrieve the topology and coordinates of this process in the grid. * */ void topology( cartesian_topology& dims, std::vector<int>& coords ) const; /** * Retrieve the topology of the grid. * */ cartesian_topology topology() const; }; /** * Given en number of processes, and a partially filled sequence * of dimension, try to complete the dimension sequence. * @param nb_proc the numer of mpi processes.fill a sequence of dimension. * @param dims a sequence of positive or null dimensions. Non zero dimension * will be left untouched. */ std::vector<int>& cartesian_dimensions(int nb_proc, std::vector<int>& dims); } } // end namespace boost::mpi #endif // BOOST_MPI_CARTESIAN_COMMUNICATOR_HPP