boost_1_45_0/libs/mpi/example/parallel_example.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 // Copyright (C) 2005-2006 Matthias Troyer

 // 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)

 // An example of a parallel Monte Carlo simulation using some nodes to produce
 // data and others to aggregate the data
 #include <iostream>

 #include <boost/mpi.hpp>
 #include <boost/random/parallel.hpp>
 #include <boost/random.hpp>
 #include <boost/foreach.hpp>
 #include <iostream>
 #include <cstdlib>

 namespace mpi = boost::mpi;

 enum {sample_tag, sample_skeleton_tag, sample_broadcast_tag, quit_tag};


 void calculate_samples(int sample_length)
 {
   int num_samples = 100;
   std::vector<double> sample(sample_length);

   // setup communicator by splitting

   mpi::communicator world;
   mpi::communicator calculate_communicator = world.split(0);

   unsigned int num_calculate_ranks = calculate_communicator.size();

   // the master of the accumulaion ranks is the first of them, hence
   // with a rank just one after the last calculation rank
   int master_accumulate_rank = num_calculate_ranks;

   // the master of the calculation ranks sends the skeleton of the sample
   // to the master of the accumulation ranks

   if (world.rank()==0)
     world.send(master_accumulate_rank,sample_skeleton_tag,mpi::skeleton(sample));

   // next we extract the content of the sample vector, to be used in sending
   // the content later on

   mpi::content sample_content = mpi::get_content(sample);

   // now intialize the parallel random number generator

   boost::lcg64 engine(
         boost::random::stream_number = calculate_communicator.rank(),
         boost::random::total_streams = calculate_communicator.size()
       );

   boost::variate_generator<boost::lcg64&,boost::uniform_real<> >
     rng(engine,boost::uniform_real<>());

   for (unsigned int i=0; i<num_samples/num_calculate_ranks+1;++i) {

     // calculate sample by filling the vector with random numbers
     // note that std::generate will not work since it takes the generator
     // by value, and boost::ref cannot be used as a generator.
     // boost::ref should be fixed so that it can be used as generator

     BOOST_FOREACH(double& x, sample)
       x = rng();

     // send sample to accumulation ranks
     // Ideally we want to do this as a broadcast with an inter-communicator
     // between the calculation and accumulation ranks. MPI2 should support
     // this, but here we present an MPI1 compatible solution.

     // send content of sample to first (master) accumulation process

     world.send(master_accumulate_rank,sample_tag,sample_content);

     // gather some results from all calculation ranks

     double local_result = sample[0];
     std::vector<double> gathered_results(calculate_communicator.size());
     mpi::all_gather(calculate_communicator,local_result,gathered_results);
   }

   // we are done: the master tells the accumulation ranks to quit
   if (world.rank()==0)
     world.send(master_accumulate_rank,quit_tag);
 }


 void accumulate_samples()
 {
   std::vector<double> sample;

   // setup the communicator for all accumulation ranks by splitting

   mpi::communicator world;
   mpi::communicator accumulate_communicator = world.split(1);

   bool is_master_accumulate_rank = accumulate_communicator.rank()==0;

   // the master receives the sample skeleton

   if (is_master_accumulate_rank)
     world.recv(0,sample_skeleton_tag,mpi::skeleton(sample));

   // and broadcasts it to all accumulation ranks
   mpi::broadcast(accumulate_communicator,mpi::skeleton(sample),0);

   // next we extract the content of the sample vector, to be used in receiving
   // the content later on

   mpi::content sample_content = mpi::get_content(sample);

   // accumulate until quit is called
   double sum=0.;
   while (true) {


     // the accumulation master checks whether we should quit
     if (world.iprobe(0,quit_tag)) {
       world.recv(0,quit_tag);
       for (int i=1; i<accumulate_communicator.size();++i)
         accumulate_communicator.send(i,quit_tag);
       std::cout << sum << "\n";
       break; // We're done
     }

     // the otehr accumulation ranks check whether we should quit
     if (accumulate_communicator.iprobe(0,quit_tag)) {
       accumulate_communicator.recv(0,quit_tag);
       std::cout << sum << "\n";
       break; // We're done
     }

     // check whether the master accumulation rank has received a sample
     if (world.iprobe(mpi::any_source,sample_tag)) {
       BOOST_ASSERT(is_master_accumulate_rank);

       // receive the content
       world.recv(mpi::any_source,sample_tag,sample_content);

       // now we need to braodcast
       // the problam is we do not have a non-blocking broadcast that we could
       // abort if we receive a quit message from the master. We thus need to
       // first tell all accumulation ranks to start a broadcast. If the sample
       // is small, we could just send the sample in this message, but here we
       // optimize the code for large samples, so that the overhead of these
       // sends can be ignored, and we count on an optimized broadcast
       // implementation with O(log N) complexity

       for (int i=1; i<accumulate_communicator.size();++i)
         accumulate_communicator.send(i,sample_broadcast_tag);

       // now broadcast the contents of the sample to all accumulate ranks
       mpi::broadcast(accumulate_communicator,sample_content,0);

       // and handle the sample by summing the appropriate value
       sum += sample[0];
     }

     // the other accumulation ranks wait for a mesage to start the broadcast
     if (accumulate_communicator.iprobe(0,sample_broadcast_tag)) {
       BOOST_ASSERT(!is_master_accumulate_rank);

       accumulate_communicator.recv(0,sample_broadcast_tag);

       // receive broadcast of the sample contents
       mpi::broadcast(accumulate_communicator,sample_content,0);

       // and handle the sample

       // and handle the sample by summing the appropriate value
       sum += sample[accumulate_communicator.rank()];
     }
   }
 }

 int main(int argc, char** argv)
 {
   mpi::environment env(argc, argv);
   mpi::communicator world;

   // half of the processes generate, the others accumulate
   // the sample size is just the number of accumulation ranks
   if (world.rank() < world.size()/2)
     calculate_samples(world.size()-world.size()/2);
   else
     accumulate_samples();

   return 0;
 }
	// Copyright (C) 2005-2006 Matthias Troyer

	// 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)

	// An example of a parallel Monte Carlo simulation using some nodes to produce
	// data and others to aggregate the data
	#include <iostream>

	#include <boost/mpi.hpp>
	#include <boost/random/parallel.hpp>
	#include <boost/random.hpp>
	#include <boost/foreach.hpp>
	#include <iostream>
	#include <cstdlib>

	namespace mpi = boost::mpi;

	enum {sample_tag, sample_skeleton_tag, sample_broadcast_tag, quit_tag};


	void calculate_samples(int sample_length)
	{
	int num_samples = 100;
	std::vector<double> sample(sample_length);

	// setup communicator by splitting

	mpi::communicator world;
	mpi::communicator calculate_communicator = world.split(0);

	unsigned int num_calculate_ranks = calculate_communicator.size();

	// the master of the accumulaion ranks is the first of them, hence
	// with a rank just one after the last calculation rank
	int master_accumulate_rank = num_calculate_ranks;

	// the master of the calculation ranks sends the skeleton of the sample
	// to the master of the accumulation ranks

	if (world.rank()==0)
	world.send(master_accumulate_rank,sample_skeleton_tag,mpi::skeleton(sample));

	// next we extract the content of the sample vector, to be used in sending
	// the content later on

	mpi::content sample_content = mpi::get_content(sample);

	// now intialize the parallel random number generator

	boost::lcg64 engine(
	boost::random::stream_number = calculate_communicator.rank(),
	boost::random::total_streams = calculate_communicator.size()
	);

	boost::variate_generator<boost::lcg64&,boost::uniform_real<> >
	rng(engine,boost::uniform_real<>());

	for (unsigned int i=0; i<num_samples/num_calculate_ranks+1;++i) {

	// calculate sample by filling the vector with random numbers
	// note that std::generate will not work since it takes the generator
	// by value, and boost::ref cannot be used as a generator.
	// boost::ref should be fixed so that it can be used as generator

	BOOST_FOREACH(double& x, sample)
	x = rng();

	// send sample to accumulation ranks
	// Ideally we want to do this as a broadcast with an inter-communicator
	// between the calculation and accumulation ranks. MPI2 should support
	// this, but here we present an MPI1 compatible solution.

	// send content of sample to first (master) accumulation process

	world.send(master_accumulate_rank,sample_tag,sample_content);

	// gather some results from all calculation ranks

	double local_result = sample[0];
	std::vector<double> gathered_results(calculate_communicator.size());
	mpi::all_gather(calculate_communicator,local_result,gathered_results);
	}

	// we are done: the master tells the accumulation ranks to quit
	if (world.rank()==0)
	world.send(master_accumulate_rank,quit_tag);
	}



	void accumulate_samples()
	{
	std::vector<double> sample;

	// setup the communicator for all accumulation ranks by splitting

	mpi::communicator world;
	mpi::communicator accumulate_communicator = world.split(1);

	bool is_master_accumulate_rank = accumulate_communicator.rank()==0;

	// the master receives the sample skeleton

	if (is_master_accumulate_rank)
	world.recv(0,sample_skeleton_tag,mpi::skeleton(sample));

	// and broadcasts it to all accumulation ranks
	mpi::broadcast(accumulate_communicator,mpi::skeleton(sample),0);

	// next we extract the content of the sample vector, to be used in receiving
	// the content later on

	mpi::content sample_content = mpi::get_content(sample);

	// accumulate until quit is called
	double sum=0.;
	while (true) {


	// the accumulation master checks whether we should quit
	if (world.iprobe(0,quit_tag)) {
	world.recv(0,quit_tag);
	for (int i=1; i<accumulate_communicator.size();++i)
	accumulate_communicator.send(i,quit_tag);
	std::cout << sum << "\n";
	break; // We're done
	}

	// the otehr accumulation ranks check whether we should quit
	if (accumulate_communicator.iprobe(0,quit_tag)) {
	accumulate_communicator.recv(0,quit_tag);
	std::cout << sum << "\n";
	break; // We're done
	}

	// check whether the master accumulation rank has received a sample
	if (world.iprobe(mpi::any_source,sample_tag)) {
	BOOST_ASSERT(is_master_accumulate_rank);

	// receive the content
	world.recv(mpi::any_source,sample_tag,sample_content);

	// now we need to braodcast
	// the problam is we do not have a non-blocking broadcast that we could
	// abort if we receive a quit message from the master. We thus need to
	// first tell all accumulation ranks to start a broadcast. If the sample
	// is small, we could just send the sample in this message, but here we
	// optimize the code for large samples, so that the overhead of these
	// sends can be ignored, and we count on an optimized broadcast
	// implementation with O(log N) complexity

	for (int i=1; i<accumulate_communicator.size();++i)
	accumulate_communicator.send(i,sample_broadcast_tag);

	// now broadcast the contents of the sample to all accumulate ranks
	mpi::broadcast(accumulate_communicator,sample_content,0);

	// and handle the sample by summing the appropriate value
	sum += sample[0];
	}

	// the other accumulation ranks wait for a mesage to start the broadcast
	if (accumulate_communicator.iprobe(0,sample_broadcast_tag)) {
	BOOST_ASSERT(!is_master_accumulate_rank);

	accumulate_communicator.recv(0,sample_broadcast_tag);

	// receive broadcast of the sample contents
	mpi::broadcast(accumulate_communicator,sample_content,0);

	// and handle the sample

	// and handle the sample by summing the appropriate value
	sum += sample[accumulate_communicator.rank()];
	}
	}
	}

	int main(int argc, char** argv)
	{
	mpi::environment env(argc, argv);
	mpi::communicator world;

	// half of the processes generate, the others accumulate
	// the sample size is just the number of accumulation ranks
	if (world.rank() < world.size()/2)
	calculate_samples(world.size()-world.size()/2);
	else
	accumulate_samples();

	return 0;
	}