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#ifndef _mpipyp_hh
#define _mpipyp_hh
#include <math.h>
#include <map>
#include <tr1/unordered_map>
//#include <google/sparse_hash_map>
#include <boost/random/uniform_real.hpp>
#include <boost/random/variate_generator.hpp>
#include <boost/random/mersenne_twister.hpp>
#include <boost/tuple/tuple.hpp>
#include <boost/serialization/map.hpp>
#include <boost/mpi.hpp>
#include <boost/mpi/environment.hpp>
#include <boost/mpi/communicator.hpp>
#include <boost/mpi/operations.hpp>
#include "pyp.hh"
//
// Pitman-Yor process with customer and table tracking
//
template <typename Dish, typename Hash=std::tr1::hash<Dish> >
class MPIPYP : public PYP<Dish, Hash> {
public:
MPIPYP(double a, double b, Hash hash=Hash());
virtual int increment(Dish d, double p0);
virtual int decrement(Dish d);
void clear();
void reset_deltas();
void synchronise();
private:
typedef std::map<Dish, int> dish_delta_type;
typedef std::map<Dish, typename PYP<Dish,Hash>::TableCounter> table_delta_type;
dish_delta_type m_count_delta;
table_delta_type m_table_delta;
};
template <typename Dish, typename Hash>
MPIPYP<Dish,Hash>::MPIPYP(double a, double b, Hash h)
: PYP<Dish,Hash>(a, b, 0, h) {}
template <typename Dish, typename Hash>
int
MPIPYP<Dish,Hash>::increment(Dish dish, double p0) {
int delta = 0;
int table_joined=-1;
typename PYP<Dish,Hash>::TableCounter &tc = PYP<Dish,Hash>::_dish_tables[dish];
// seated on a new or existing table?
int c = PYP<Dish,Hash>::count(dish);
int t = PYP<Dish,Hash>::num_tables(dish);
int T = PYP<Dish,Hash>::num_tables();
double& a = PYP<Dish,Hash>::_a;
double& b = PYP<Dish,Hash>::_b;
double pshare = (c > 0) ? (c - a*t) : 0.0;
double pnew = (b + a*T) * p0;
assert (pshare >= 0.0);
if (mt_genrand_res53() < pnew / (pshare + pnew)) {
// assign to a new table
tc.tables += 1;
tc.table_histogram[1] += 1;
PYP<Dish,Hash>::_total_tables += 1;
delta = 1;
}
else {
// randomly assign to an existing table
// remove constant denominator from inner loop
double r = mt_genrand_res53() * (c - a*t);
for (std::map<int,int>::iterator
hit = tc.table_histogram.begin();
hit != tc.table_histogram.end(); ++hit) {
r -= ((hit->first - a) * hit->second);
if (r <= 0) {
tc.table_histogram[hit->first+1] += 1;
hit->second -= 1;
if (hit->second == 0)
tc.table_histogram.erase(hit);
table_joined = hit->first+1;
break;
}
}
if (r > 0) {
std::cerr << r << " " << c << " " << a << " " << t << std::endl;
assert(false);
}
delta = 0;
}
std::tr1::unordered_map<Dish,int,Hash>::operator[](dish) += 1;
//google::sparse_hash_map<Dish,int,Hash>::operator[](dish) += 1;
PYP<Dish,Hash>::_total_customers += 1;
// MPI Delta handling
// track the customer entering
typename dish_delta_type::iterator customer_it;
bool customer_insert_result;
boost::tie(customer_it, customer_insert_result)
= m_count_delta.insert(std::make_pair(dish,0));
customer_it->second += 1;
if (customer_it->second == 0)
m_count_delta.erase(customer_it);
// increment the histogram bar for the table joined
if (!delta) {
assert (table_joined >= 0);
std::map<int,int> &histogram = m_table_delta[dish].table_histogram;
typename std::map<int,int>::iterator table_it; bool table_insert_result;
boost::tie(table_it, table_insert_result) = histogram.insert(std::make_pair(table_joined,0));
table_it->second += 1;
if (table_it->second == 0) histogram.erase(table_it);
// decrement the histogram bar for the table left
boost::tie(table_it, table_insert_result) = histogram.insert(std::make_pair(table_joined-1,0));
table_it->second -= 1;
if (table_it->second == 0) histogram.erase(table_it);
}
else {
typename PYP<Dish,Hash>::TableCounter &delta_tc = m_table_delta[dish];
delta_tc.tables += 1;
delta_tc.table_histogram[1] += 1;
}
return delta;
}
template <typename Dish, typename Hash>
int
MPIPYP<Dish,Hash>::decrement(Dish dish)
{
typename std::tr1::unordered_map<Dish, int>::iterator dcit = find(dish);
//typename google::sparse_hash_map<Dish, int>::iterator dcit = find(dish);
if (dcit == PYP<Dish,Hash>::end()) {
std::cerr << dish << std::endl;
assert(false);
}
int delta = 0, table_left=-1;
typename std::tr1::unordered_map<Dish, typename PYP<Dish,Hash>::TableCounter>::iterator dtit
= PYP<Dish,Hash>::_dish_tables.find(dish);
//typename google::sparse_hash_map<Dish, TableCounter>::iterator dtit = _dish_tables.find(dish);
if (dtit == PYP<Dish,Hash>::_dish_tables.end()) {
std::cerr << dish << std::endl;
assert(false);
}
typename PYP<Dish,Hash>::TableCounter &tc = dtit->second;
double r = mt_genrand_res53() * PYP<Dish,Hash>::count(dish);
for (std::map<int,int>::iterator hit = tc.table_histogram.begin();
hit != tc.table_histogram.end(); ++hit) {
r -= (hit->first * hit->second);
if (r <= 0) {
table_left = hit->first;
if (hit->first > 1) {
tc.table_histogram[hit->first-1] += 1;
}
else {
delta = -1;
tc.tables -= 1;
PYP<Dish,Hash>::_total_tables -= 1;
}
hit->second -= 1;
if (hit->second == 0) tc.table_histogram.erase(hit);
break;
}
}
if (r > 0) {
std::cerr << r << " " << PYP<Dish,Hash>::count(dish) << " " << PYP<Dish,Hash>::_a << " "
<< PYP<Dish,Hash>::num_tables(dish) << std::endl;
assert(false);
}
// remove the customer
dcit->second -= 1;
PYP<Dish,Hash>::_total_customers -= 1;
assert(dcit->second >= 0);
if (dcit->second == 0) {
PYP<Dish,Hash>::erase(dcit);
PYP<Dish,Hash>::_dish_tables.erase(dtit);
}
typename dish_delta_type::iterator it;
bool insert_result;
boost::tie(it, insert_result) = m_count_delta.insert(std::make_pair(dish,0));
it->second -= 1;
if (it->second == 0)
m_count_delta.erase(it);
assert (table_left >= 0);
typename PYP<Dish,Hash>::TableCounter& delta_tc = m_table_delta[dish];
if (table_left > 1)
delta_tc.table_histogram[table_left-1] += 1;
else delta_tc.tables -= 1;
std::map<int,int>::iterator tit = delta_tc.table_histogram.find(table_left);
//assert (tit != delta_tc.table_histogram.end());
tit->second -= 1;
if (tit->second == 0) delta_tc.table_histogram.erase(tit);
return delta;
}
template <typename Dish, typename Hash>
void
MPIPYP<Dish,Hash>::clear() {
PYP<Dish,Hash>::clear();
reset_deltas();
}
template <typename Dish, typename Hash>
void
MPIPYP<Dish,Hash>::reset_deltas() {
m_count_delta.clear();
m_table_delta.clear();
}
template <typename Dish>
struct sum_maps {
typedef std::map<Dish,int> map_type;
map_type& operator() (map_type& l, map_type const & r) const {
for (typename map_type::const_iterator it=r.begin(); it != r.end(); it++)
l[it->first] += it->second;
return l;
}
};
// Needed Boost definitions
namespace boost {
namespace mpi {
template <>
struct is_commutative< sum_maps<int>, std::map<int,int> > : mpl::true_ {};
}
namespace serialization {
template<class Archive>
void serialize(Archive & ar, PYP<int>::TableCounter& t, const unsigned int version) {
ar & t.table_histogram;
ar & t.tables;
}
} // namespace serialization
} // namespace boost
template <typename Dish, typename Hash>
void
MPIPYP<Dish,Hash>::synchronise() {
boost::mpi::communicator world;
int rank = world.rank(), size = world.size();
// communicate the customer count deltas
dish_delta_type global_dish_delta; // the “merged” map
boost::mpi::all_reduce(world, m_count_delta, global_dish_delta, sum_maps<Dish>());
// update this restaurant
for (typename dish_delta_type::const_iterator it=global_dish_delta.begin();
it != global_dish_delta.end(); ++it) {
std::tr1::unordered_map<Dish,int,Hash>::operator[](it->first) += (it->second - m_count_delta[it->first]);
PYP<Dish,Hash>::_total_customers += (it->second - m_count_delta[it->first]);
//std::cerr << "Process " << rank << " adding " << (it->second - m_count_delta[it->first]) << " customers." << std::endl;
}
// communicate the table count deltas
// for (int process = 0; process < size; ++process) {
// if (rank == process) {
// // broadcast deltas
// std::cerr << " -- Rank " << rank << " broadcasting -- " << std::endl;
//
// boost::mpi::broadcast(world, m_table_delta, process);
//
// std::cerr << " -- Rank " << rank << " done broadcasting -- " << std::endl;
// }
// else {
// std::cerr << " -- Rank " << rank << " receiving -- " << std::endl;
// // receive deltas
// table_delta_type recv_table_delta;
//
// boost::mpi::broadcast(world, recv_table_delta, process);
//
// std::cerr << " -- Rank " << rank << " done receiving -- " << std::endl;
//
// for (typename table_delta_type::const_iterator dish_it=recv_table_delta.begin();
// dish_it != recv_table_delta.end(); ++dish_it) {
// typename PYP<Dish,Hash>::TableCounter &tc = PYP<Dish,Hash>::_dish_tables[dish_it->first];
//
// for (std::map<int,int>::const_iterator it=dish_it->second.table_histogram.begin();
// it != dish_it->second.table_histogram.end(); ++it) {
// tc.table_histogram[it->first] += it->second;
// }
// tc.tables += dish_it->second.tables;
// PYP<Dish,Hash>::_total_tables += dish_it->second.tables;
// }
// }
// }
// std::cerr << " -- Done Reducing -- " << std::endl;
reset_deltas();
}
#endif
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