boost/libs/mpi/test/all_reduce_test.cpp - nest-cam/4320010/boost - Git at Google

 // Copyright (C) 2005, 2006 Douglas Gregor.

 // 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)

 // A test of the all_reduce() collective.
 #include <boost/mpi/collectives/all_reduce.hpp>
 #include <boost/mpi/communicator.hpp>
 #include <boost/mpi/environment.hpp>
 #include <boost/test/minimal.hpp>
 #include <vector>
 #include <algorithm>
 #include <boost/serialization/string.hpp>
 #include <boost/iterator/counting_iterator.hpp>
 #include <boost/lexical_cast.hpp>
 #include <numeric>

 using boost::mpi::communicator;

 // A simple point class that we can build, add, compare, and
 // serialize.
 struct point
 {
   point() : x(0), y(0), z(0) { }
   point(int x, int y, int z) : x(x), y(y), z(z) { }

   int x;
   int y;
   int z;

  private:
   template<typename Archiver>
   void serialize(Archiver& ar, unsigned int /*version*/)
   {
     ar & x & y & z;
   }

   friend class boost::serialization::access;
 };

 std::ostream& operator<<(std::ostream& out, const point& p)
 {
   return out << p.x << ' ' << p.y << ' ' << p.z;
 }

 bool operator==(const point& p1, const point& p2)
 {
   return p1.x == p2.x && p1.y == p2.y && p1.z == p2.z;
 }

 bool operator!=(const point& p1, const point& p2)
 {
   return !(p1 == p2);
 }

 point operator+(const point& p1, const point& p2)
 {
   return point(p1.x + p2.x, p1.y + p2.y, p1.z + p2.z);
 }

 // test lexical order
 bool operator<(const point& p1, const point& p2)
 {
   return (p1.x < p2.x
           ? true
           : (p1.x > p2.x
              ? false
              : p1.y < p2.y ));
 }

 namespace boost { namespace mpi {

   template <>
   struct is_mpi_datatype<point> : public mpl::true_ { };

 } } // end namespace boost::mpi

 template<typename Generator, typename Op>
 void
 all_reduce_one_test(const communicator& comm, Generator generator,
                     const char* type_kind, Op op, const char* op_kind,
                     typename Generator::result_type init, bool in_place)
 {
   typedef typename Generator::result_type value_type;
   value_type value = generator(comm.rank());

   using boost::mpi::all_reduce;
   using boost::mpi::inplace;

   if (comm.rank() == 0) {
     std::cout << "Reducing to " << op_kind << " of " << type_kind << "...";
     std::cout.flush();
   }

   value_type result_value;
   if (in_place) {
     all_reduce(comm, inplace(value), op);
     result_value = value;
   } else {
     result_value = all_reduce(comm, value, op);
   }

   // Compute expected result
   std::vector<value_type> generated_values;
   for (int p = 0; p < comm.size(); ++p)
     generated_values.push_back(generator(p));
   value_type expected_result = std::accumulate(generated_values.begin(),
                                                generated_values.end(),
                                                init, op);
   BOOST_CHECK(result_value == expected_result);
   if (result_value == expected_result && comm.rank() == 0)
     std::cout << "OK." << std::endl;

   (comm.barrier)();
 }

 template<typename Generator, typename Op>
 void
 all_reduce_array_test(const communicator& comm, Generator generator,
                       const char* type_kind, Op op, const char* op_kind,
                       typename Generator::result_type init, bool in_place)
 {
   typedef typename Generator::result_type value_type;
   value_type value = generator(comm.rank());
   std::vector<value_type> send(10, value);

   using boost::mpi::all_reduce;
   using boost::mpi::inplace;

   if (comm.rank() == 0) {
       char const* place = in_place ? "in place" : "out of place";
       std::cout << "Reducing (" << place << ") array to " << op_kind << " of " << type_kind << "...";
       std::cout.flush();
   }
   std::vector<value_type> result;
   if (in_place) {
     all_reduce(comm, inplace(&(send[0])), send.size(), op);
     result.swap(send);
   } else {
     std::vector<value_type> recv(10, value_type());
     all_reduce(comm, &(send[0]), send.size(), &(recv[0]), op);
     result.swap(recv);
   }

   // Compute expected result
   std::vector<value_type> generated_values;
   for (int p = 0; p < comm.size(); ++p)
     generated_values.push_back(generator(p));
   value_type expected_result = std::accumulate(generated_values.begin(),
                                                generated_values.end(),
                                                init, op);

   bool got_expected_result = (std::equal_range(result.begin(), result.end(),
                                                expected_result)
                               == std::make_pair(result.begin(), result.end()));
   BOOST_CHECK(got_expected_result);
   if (got_expected_result && comm.rank() == 0)
       std::cout << "OK." << std::endl;

   (comm.barrier)();
 }

 // Test the 4 families of all reduce: (value, array) X (in place, out of place)
 template<typename Generator, typename Op>
 void
 all_reduce_test(const communicator& comm, Generator generator,
                 const char* type_kind, Op op, const char* op_kind,
                 typename Generator::result_type init)
 {
   const bool in_place = true;
   const bool out_of_place = false;
   all_reduce_one_test(comm, generator, type_kind, op, op_kind,  init, in_place);
   all_reduce_one_test(comm, generator, type_kind, op, op_kind,  init, out_of_place);
   all_reduce_array_test(comm, generator, type_kind, op, op_kind,
                         init, in_place);
   all_reduce_array_test(comm, generator, type_kind, op, op_kind,
                         init, out_of_place);
 }

 // Generates integers to test with all_reduce()
 struct int_generator
 {
   typedef int result_type;

   int_generator(int base = 1) : base(base) { }

   int operator()(int p) const { return base + p; }

  private:
   int base;
 };

 // Generate points to test with all_reduce()
 struct point_generator
 {
   typedef point result_type;

   point_generator(point origin) : origin(origin) { }

   point operator()(int p) const
   {
     return point(origin.x + 1, origin.y + 1, origin.z + 1);
   }

  private:
   point origin;
 };

 struct string_generator
 {
   typedef std::string result_type;

   std::string operator()(int p) const
   {
     std::string result = boost::lexical_cast<std::string>(p);
     result += " rosebud";
     if (p != 1) result += 's';
     return result;
   }
 };

 struct secret_int_bit_and
 {
   int operator()(int x, int y) const { return x & y; }
 };

 struct wrapped_int
 {
   wrapped_int() : value(0) { }
   explicit wrapped_int(int value) : value(value) { }

   template<typename Archive>
   void serialize(Archive& ar, unsigned int /* version */)
   {
     ar & value;
   }

   int value;
 };

 wrapped_int operator+(const wrapped_int& x, const wrapped_int& y)
 {
   return wrapped_int(x.value + y.value);
 }

 bool operator==(const wrapped_int& x, const wrapped_int& y)
 {
   return x.value == y.value;
 }

 bool operator<(const wrapped_int& x, const wrapped_int& y)
 {
   return x.value < y.value;
 }

 // Generates wrapped_its to test with all_reduce()
 struct wrapped_int_generator
 {
   typedef wrapped_int result_type;

   wrapped_int_generator(int base = 1) : base(base) { }

   wrapped_int operator()(int p) const { return wrapped_int(base + p); }

  private:
   int base;
 };

 namespace boost { namespace mpi {

 // Make std::plus<wrapped_int> commutative.
 template<>
 struct is_commutative<std::plus<wrapped_int>, wrapped_int>
   : mpl::true_ { };

 } } // end namespace boost::mpi

 int test_main(int argc, char* argv[])
 {
   using namespace boost::mpi;
   environment env(argc, argv);

   communicator comm;
   const bool in_place = true;
   const bool out_of_place = false;

   // Built-in MPI datatypes with built-in MPI operations
   all_reduce_test(comm, int_generator(), "integers", std::plus<int>(), "sum",
                   0);
   all_reduce_test(comm, int_generator(), "integers", std::multiplies<int>(),
                   "product", 1);
   all_reduce_test(comm, int_generator(), "integers", maximum<int>(),
                   "maximum", 0);
   all_reduce_test(comm, int_generator(), "integers", minimum<int>(),
                   "minimum", 2);

   // User-defined MPI datatypes with operations that have the
   // same name as built-in operations.
   all_reduce_test(comm, point_generator(point(0,0,0)), "points",
                   std::plus<point>(), "sum", point());

   // Built-in MPI datatypes with user-defined operations
   all_reduce_test(comm, int_generator(17), "integers", secret_int_bit_and(),
                   "bitwise and", -1);

   // Arbitrary types with user-defined, commutative operations.
   all_reduce_test(comm, wrapped_int_generator(17), "wrapped integers",
                   std::plus<wrapped_int>(), "sum", wrapped_int(0));

   // Arbitrary types with (non-commutative) user-defined operations
   all_reduce_test(comm, string_generator(), "strings",
                   std::plus<std::string>(), "concatenation", std::string());

   return 0;
 }
	// Copyright (C) 2005, 2006 Douglas Gregor.

	// 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)

	// A test of the all_reduce() collective.
	#include <boost/mpi/collectives/all_reduce.hpp>
	#include <boost/mpi/communicator.hpp>
	#include <boost/mpi/environment.hpp>
	#include <boost/test/minimal.hpp>
	#include <vector>
	#include <algorithm>
	#include <boost/serialization/string.hpp>
	#include <boost/iterator/counting_iterator.hpp>
	#include <boost/lexical_cast.hpp>
	#include <numeric>

	using boost::mpi::communicator;

	// A simple point class that we can build, add, compare, and
	// serialize.
	struct point
	{
	point() : x(0), y(0), z(0) { }
	point(int x, int y, int z) : x(x), y(y), z(z) { }

	int x;
	int y;
	int z;

	private:
	template<typename Archiver>
	void serialize(Archiver& ar, unsigned int /version/)
	{
	ar & x & y & z;
	}

	friend class boost::serialization::access;
	};

	std::ostream& operator<<(std::ostream& out, const point& p)
	{
	return out << p.x << ' ' << p.y << ' ' << p.z;
	}

	bool operator==(const point& p1, const point& p2)
	{
	return p1.x == p2.x && p1.y == p2.y && p1.z == p2.z;
	}

	bool operator!=(const point& p1, const point& p2)
	{
	return !(p1 == p2);
	}

	point operator+(const point& p1, const point& p2)
	{
	return point(p1.x + p2.x, p1.y + p2.y, p1.z + p2.z);
	}

	// test lexical order
	bool operator<(const point& p1, const point& p2)
	{
	return (p1.x < p2.x
	? true
	: (p1.x > p2.x
	? false
	: p1.y < p2.y ));
	}

	namespace boost { namespace mpi {

	template <>
	struct is_mpi_datatype<point> : public mpl::true_ { };

	} } // end namespace boost::mpi

	template<typename Generator, typename Op>
	void
	all_reduce_one_test(const communicator& comm, Generator generator,
	const char* type_kind, Op op, const char* op_kind,
	typename Generator::result_type init, bool in_place)
	{
	typedef typename Generator::result_type value_type;
	value_type value = generator(comm.rank());

	using boost::mpi::all_reduce;
	using boost::mpi::inplace;

	if (comm.rank() == 0) {
	std::cout << "Reducing to " << op_kind << " of " << type_kind << "...";
	std::cout.flush();
	}

	value_type result_value;
	if (in_place) {
	all_reduce(comm, inplace(value), op);
	result_value = value;
	} else {
	result_value = all_reduce(comm, value, op);
	}

	// Compute expected result
	std::vector<value_type> generated_values;
	for (int p = 0; p < comm.size(); ++p)
	generated_values.push_back(generator(p));
	value_type expected_result = std::accumulate(generated_values.begin(),
	generated_values.end(),
	init, op);
	BOOST_CHECK(result_value == expected_result);
	if (result_value == expected_result && comm.rank() == 0)
	std::cout << "OK." << std::endl;

	(comm.barrier)();
	}

	template<typename Generator, typename Op>
	void
	all_reduce_array_test(const communicator& comm, Generator generator,
	const char* type_kind, Op op, const char* op_kind,
	typename Generator::result_type init, bool in_place)
	{
	typedef typename Generator::result_type value_type;
	value_type value = generator(comm.rank());
	std::vector<value_type> send(10, value);

	using boost::mpi::all_reduce;
	using boost::mpi::inplace;

	if (comm.rank() == 0) {
	char const* place = in_place ? "in place" : "out of place";
	std::cout << "Reducing (" << place << ") array to " << op_kind << " of " << type_kind << "...";
	std::cout.flush();
	}
	std::vector<value_type> result;
	if (in_place) {
	all_reduce(comm, inplace(&(send[0])), send.size(), op);
	result.swap(send);
	} else {
	std::vector<value_type> recv(10, value_type());
	all_reduce(comm, &(send[0]), send.size(), &(recv[0]), op);
	result.swap(recv);
	}

	// Compute expected result
	std::vector<value_type> generated_values;
	for (int p = 0; p < comm.size(); ++p)
	generated_values.push_back(generator(p));
	value_type expected_result = std::accumulate(generated_values.begin(),
	generated_values.end(),
	init, op);

	bool got_expected_result = (std::equal_range(result.begin(), result.end(),
	expected_result)
	== std::make_pair(result.begin(), result.end()));
	BOOST_CHECK(got_expected_result);
	if (got_expected_result && comm.rank() == 0)
	std::cout << "OK." << std::endl;

	(comm.barrier)();
	}

	// Test the 4 families of all reduce: (value, array) X (in place, out of place)
	template<typename Generator, typename Op>
	void
	all_reduce_test(const communicator& comm, Generator generator,
	const char* type_kind, Op op, const char* op_kind,
	typename Generator::result_type init)
	{
	const bool in_place = true;
	const bool out_of_place = false;
	all_reduce_one_test(comm, generator, type_kind, op, op_kind, init, in_place);
	all_reduce_one_test(comm, generator, type_kind, op, op_kind, init, out_of_place);
	all_reduce_array_test(comm, generator, type_kind, op, op_kind,
	init, in_place);
	all_reduce_array_test(comm, generator, type_kind, op, op_kind,
	init, out_of_place);
	}

	// Generates integers to test with all_reduce()
	struct int_generator
	{
	typedef int result_type;

	int_generator(int base = 1) : base(base) { }

	int operator()(int p) const { return base + p; }

	private:
	int base;
	};

	// Generate points to test with all_reduce()
	struct point_generator
	{
	typedef point result_type;

	point_generator(point origin) : origin(origin) { }

	point operator()(int p) const
	{
	return point(origin.x + 1, origin.y + 1, origin.z + 1);
	}

	private:
	point origin;
	};

	struct string_generator
	{
	typedef std::string result_type;

	std::string operator()(int p) const
	{
	std::string result = boost::lexical_cast<std::string>(p);
	result += " rosebud";
	if (p != 1) result += 's';
	return result;
	}
	};

	struct secret_int_bit_and
	{
	int operator()(int x, int y) const { return x & y; }
	};

	struct wrapped_int
	{
	wrapped_int() : value(0) { }
	explicit wrapped_int(int value) : value(value) { }

	template<typename Archive>
	void serialize(Archive& ar, unsigned int /* version */)
	{
	ar & value;
	}

	int value;
	};

	wrapped_int operator+(const wrapped_int& x, const wrapped_int& y)
	{
	return wrapped_int(x.value + y.value);
	}

	bool operator==(const wrapped_int& x, const wrapped_int& y)
	{
	return x.value == y.value;
	}

	bool operator<(const wrapped_int& x, const wrapped_int& y)
	{
	return x.value < y.value;
	}

	// Generates wrapped_its to test with all_reduce()
	struct wrapped_int_generator
	{
	typedef wrapped_int result_type;

	wrapped_int_generator(int base = 1) : base(base) { }

	wrapped_int operator()(int p) const { return wrapped_int(base + p); }

	private:
	int base;
	};

	namespace boost { namespace mpi {

	// Make std::plus<wrapped_int> commutative.
	template<>
	struct is_commutative<std::plus<wrapped_int>, wrapped_int>
	: mpl::true_ { };

	} } // end namespace boost::mpi

	int test_main(int argc, char* argv[])
	{
	using namespace boost::mpi;
	environment env(argc, argv);

	communicator comm;
	const bool in_place = true;
	const bool out_of_place = false;

	// Built-in MPI datatypes with built-in MPI operations
	all_reduce_test(comm, int_generator(), "integers", std::plus<int>(), "sum",
	0);
	all_reduce_test(comm, int_generator(), "integers", std::multiplies<int>(),
	"product", 1);
	all_reduce_test(comm, int_generator(), "integers", maximum<int>(),
	"maximum", 0);
	all_reduce_test(comm, int_generator(), "integers", minimum<int>(),
	"minimum", 2);

	// User-defined MPI datatypes with operations that have the
	// same name as built-in operations.
	all_reduce_test(comm, point_generator(point(0,0,0)), "points",
	std::plus<point>(), "sum", point());

	// Built-in MPI datatypes with user-defined operations
	all_reduce_test(comm, int_generator(17), "integers", secret_int_bit_and(),
	"bitwise and", -1);

	// Arbitrary types with user-defined, commutative operations.
	all_reduce_test(comm, wrapped_int_generator(17), "wrapped integers",
	std::plus<wrapped_int>(), "sum", wrapped_int(0));

	// Arbitrary types with (non-commutative) user-defined operations
	all_reduce_test(comm, string_generator(), "strings",
	std::plus<std::string>(), "concatenation", std::string());

	return 0;
	}