boost/mpi/collectives/scatterv.hpp
// Copyright (C) 2011 Júlio Hoffimann. // Use, modification and distribution is subject to 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) // Message Passing Interface 1.1 -- Section 4.6. Scatterv #ifndef BOOST_MPI_SCATTERV_HPP #define BOOST_MPI_SCATTERV_HPP #include <boost/scoped_array.hpp> #include <boost/mpi/collectives/scatter.hpp> #include <boost/mpi/detail/offsets.hpp> #include <boost/mpi/detail/antiques.hpp> namespace boost { namespace mpi { namespace detail { ////////////////////////////////////////////// /// Implementation for MPI primitive types /// ////////////////////////////////////////////// // We're scattering from the root for a type that has an associated MPI // datatype, so we'll use MPI_Scatterv to do all of the work. template<typename T> void scatterv_impl(const communicator& comm, const T* in_values, T* out_values, int out_size, const int* sizes, const int* displs, int root, mpl::true_) { assert(!sizes || out_size == sizes[comm.rank()]); assert(!bool(in_values) || bool(sizes)); scoped_array<int> new_offsets_mem(make_offsets(comm, sizes, displs, root)); if (new_offsets_mem) displs = new_offsets_mem.get(); MPI_Datatype type = get_mpi_datatype<T>(*in_values); BOOST_MPI_CHECK_RESULT(MPI_Scatterv, (const_cast<T*>(in_values), const_cast<int*>(sizes), const_cast<int*>(displs), type, out_values, out_size, type, root, comm)); } // We're scattering from a non-root for a type that has an associated MPI // datatype, so we'll use MPI_Scatterv to do all of the work. template<typename T> void scatterv_impl(const communicator& comm, T* out_values, int out_size, int root, mpl::true_ is_mpi_type) { scatterv_impl(comm, (T const*)0, out_values, out_size, (const int*)0, (const int*)0, root, is_mpi_type); } ////////////////////////////////////////////////// /// Implementation for non MPI primitive types /// ////////////////////////////////////////////////// // We're scattering from the root for a type that does not have an // associated MPI datatype, so we'll need to serialize it. template<typename T> void scatterv_impl(const communicator& comm, const T* in_values, T* out_values, int out_size, int const* sizes, int const* displs, int root, mpl::false_) { packed_oarchive::buffer_type sendbuf; bool is_root = comm.rank() == root; int nproc = comm.size(); std::vector<int> archsizes; if (is_root) { assert(out_size == sizes[comm.rank()]); archsizes.resize(nproc); std::vector<int> skipped; if (displs) { skipped.resize(nproc); offsets2skipped(sizes, displs, c_data(skipped), nproc); displs = c_data(skipped); } fill_scatter_sendbuf(comm, in_values, sizes, (int const*)0, sendbuf, archsizes); } dispatch_scatter_sendbuf(comm, sendbuf, archsizes, (T const*)0, out_values, out_size, root); } // We're scattering to a non-root for a type that does not have an // associated MPI datatype. input data not needed. // it. template<typename T> void scatterv_impl(const communicator& comm, T* out_values, int n, int root, mpl::false_ isnt_mpi_type) { assert(root != comm.rank()); scatterv_impl(comm, (T const*)0, out_values, n, (int const*)0, (int const*)0, root, isnt_mpi_type); } } // end namespace detail template<typename T> void scatterv(const communicator& comm, const T* in_values, const std::vector<int>& sizes, const std::vector<int>& displs, T* out_values, int out_size, int root) { using detail::c_data; detail::scatterv_impl(comm, in_values, out_values, out_size, c_data(sizes), c_data(displs), root, is_mpi_datatype<T>()); } template<typename T> void scatterv(const communicator& comm, const std::vector<T>& in_values, const std::vector<int>& sizes, const std::vector<int>& displs, T* out_values, int out_size, int root) { using detail::c_data; ::boost::mpi::scatterv(comm, c_data(in_values), sizes, displs, out_values, out_size, root); } template<typename T> void scatterv(const communicator& comm, T* out_values, int out_size, int root) { BOOST_ASSERT(comm.rank() != root); detail::scatterv_impl(comm, out_values, out_size, root, is_mpi_datatype<T>()); } /////////////////////// // common use versions /////////////////////// template<typename T> void scatterv(const communicator& comm, const T* in_values, const std::vector<int>& sizes, T* out_values, int root) { using detail::c_data; detail::scatterv_impl(comm, in_values, out_values, sizes[comm.rank()], c_data(sizes), (int const*)0, root, is_mpi_datatype<T>()); } template<typename T> void scatterv(const communicator& comm, const std::vector<T>& in_values, const std::vector<int>& sizes, T* out_values, int root) { ::boost::mpi::scatterv(comm, detail::c_data(in_values), sizes, out_values, root); } template<typename T> void scatterv(const communicator& comm, const T* in_values, T* out_values, int n, int root) { detail::scatterv_impl(comm, in_values, out_values, n, (int const*)0, (int const*)0, root, is_mpi_datatype<T>()); } template<typename T> void scatterv(const communicator& comm, const std::vector<T>& in_values, T* out_values, int out_size, int root) { ::boost::mpi::scatterv(comm, detail::c_data(in_values), out_values, out_size, root); } } } // end namespace boost::mpi #endif // BOOST_MPI_SCATTERV_HPP