boost/property_map/parallel/impl/distributed_property_map.ipp
// Copyright (C) 2004-2006 The Trustees of Indiana University.
// 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)
// Authors: Douglas Gregor
// Nick Edmonds
// Andrew Lumsdaine
#include <boost/assert.hpp>
#include <boost/property_map/parallel/distributed_property_map.hpp>
#include <boost/property_map/parallel/detail/untracked_pair.hpp>
#include <boost/type_traits/is_base_and_derived.hpp>
#include <boost/bind.hpp>
#include <boost/property_map/parallel/simple_trigger.hpp>
namespace boost { namespace parallel {
template<typename ProcessGroup, typename GlobalMap, typename StorageMap>
template<typename Reduce>
PBGL_DISTRIB_PMAP
::distributed_property_map(const ProcessGroup& pg, const GlobalMap& global,
const StorageMap& pm, const Reduce& reduce)
: data(new data_t(pg, global, pm, reduce, Reduce::non_default_resolver))
{
typedef handle_message<Reduce> Handler;
data->ghost_cells.reset(new ghost_cells_type());
data->reset = &data_t::template do_reset<Reduce>;
data->process_group.replace_handler(Handler(data, reduce));
data->process_group.template get_receiver<Handler>()
->setup_triggers(data->process_group);
}
template<typename ProcessGroup, typename GlobalMap, typename StorageMap>
PBGL_DISTRIB_PMAP::~distributed_property_map() { }
template<typename ProcessGroup, typename GlobalMap, typename StorageMap>
template<typename Reduce>
void
PBGL_DISTRIB_PMAP::set_reduce(const Reduce& reduce)
{
typedef handle_message<Reduce> Handler;
data->process_group.replace_handler(Handler(data, reduce));
Handler* handler = data->process_group.template get_receiver<Handler>();
BOOST_ASSERT(handler);
handler->setup_triggers(data->process_group);
data->get_default_value = reduce;
data->has_default_resolver = Reduce::non_default_resolver;
int model = data->model;
data->reset = &data_t::template do_reset<Reduce>;
set_consistency_model(model);
}
template<typename ProcessGroup, typename GlobalMap, typename StorageMap>
void PBGL_DISTRIB_PMAP::prune_ghost_cells() const
{
if (data->max_ghost_cells == 0)
return;
while (data->ghost_cells->size() > data->max_ghost_cells) {
// Evict the last ghost cell
if (data->model & cm_flush) {
// We need to flush values when we evict them.
boost::parallel::detail::untracked_pair<key_type, value_type> const& victim
= data->ghost_cells->back();
send(data->process_group, get(data->global, victim.first).first,
property_map_put, victim);
}
// Actually remove the ghost cell
data->ghost_cells->pop_back();
}
}
template<typename ProcessGroup, typename GlobalMap, typename StorageMap>
typename PBGL_DISTRIB_PMAP::value_type&
PBGL_DISTRIB_PMAP::cell(const key_type& key, bool request_if_missing) const
{
// Index by key
ghost_cells_key_index_type const& key_index
= data->ghost_cells->template get<1>();
// Search for the ghost cell by key, and project back to the sequence
iterator ghost_cell
= data->ghost_cells->template project<0>(key_index.find(key));
if (ghost_cell == data->ghost_cells->end()) {
value_type value;
if (data->has_default_resolver)
// Since we have a default resolver, use it to create a default
// value for this ghost cell.
value = data->get_default_value(key);
else if (request_if_missing)
// Request the actual value of this key from its owner
send_oob_with_reply(data->process_group, get(data->global, key).first,
property_map_get, key, value);
else
value = value_type();
// Create a ghost cell containing the new value
ghost_cell
= data->ghost_cells->push_front(std::make_pair(key, value)).first;
// If we need to, prune the ghost cells
if (data->max_ghost_cells > 0)
prune_ghost_cells();
} else if (data->max_ghost_cells > 0)
// Put this cell at the beginning of the MRU list
data->ghost_cells->relocate(data->ghost_cells->begin(), ghost_cell);
return const_cast<value_type&>(ghost_cell->second);
}
template<typename ProcessGroup, typename GlobalMap, typename StorageMap>
template<typename Reduce>
void
PBGL_DISTRIB_PMAP
::handle_message<Reduce>::operator()(process_id_type source, int tag)
{
BOOST_ASSERT(false);
}
template<typename ProcessGroup, typename GlobalMap, typename StorageMap>
template<typename Reduce>
void
PBGL_DISTRIB_PMAP::handle_message<Reduce>::
handle_put(int /*source*/, int /*tag*/,
const boost::parallel::detail::untracked_pair<key_type, value_type>& req, trigger_receive_context)
{
using boost::get;
shared_ptr<data_t> data(data_ptr);
owner_local_pair p = get(data->global, req.first);
BOOST_ASSERT(p.first == process_id(data->process_group));
detail::maybe_put(data->storage, p.second,
reduce(req.first,
get(data->storage, p.second),
req.second));
}
template<typename ProcessGroup, typename GlobalMap, typename StorageMap>
template<typename Reduce>
typename PBGL_DISTRIB_PMAP::value_type
PBGL_DISTRIB_PMAP::handle_message<Reduce>::
handle_get(int source, int /*tag*/, const key_type& key,
trigger_receive_context)
{
using boost::get;
shared_ptr<data_t> data(data_ptr);
BOOST_ASSERT(data);
owner_local_pair p = get(data->global, key);
return get(data->storage, p.second);
}
template<typename ProcessGroup, typename GlobalMap, typename StorageMap>
template<typename Reduce>
void
PBGL_DISTRIB_PMAP::handle_message<Reduce>::
handle_multiget(int source, int tag, const std::vector<key_type>& keys,
trigger_receive_context)
{
shared_ptr<data_t> data(data_ptr);
BOOST_ASSERT(data);
typedef boost::parallel::detail::untracked_pair<key_type, value_type> key_value;
std::vector<key_value> results;
std::size_t n = keys.size();
results.reserve(n);
using boost::get;
for (std::size_t i = 0; i < n; ++i) {
local_key_type local_key = get(data->global, keys[i]).second;
results.push_back(key_value(keys[i], get(data->storage, local_key)));
}
send(data->process_group, source, property_map_multiget_reply, results);
}
template<typename ProcessGroup, typename GlobalMap, typename StorageMap>
template<typename Reduce>
void
PBGL_DISTRIB_PMAP::handle_message<Reduce>::
handle_multiget_reply
(int source, int tag,
const std::vector<boost::parallel::detail::untracked_pair<key_type, value_type> >& msg,
trigger_receive_context)
{
shared_ptr<data_t> data(data_ptr);
BOOST_ASSERT(data);
// Index by key
ghost_cells_key_index_type const& key_index
= data->ghost_cells->template get<1>();
std::size_t n = msg.size();
for (std::size_t i = 0; i < n; ++i) {
// Search for the ghost cell by key, and project back to the sequence
iterator position
= data->ghost_cells->template project<0>(key_index.find(msg[i].first));
if (position != data->ghost_cells->end())
const_cast<value_type&>(position->second) = msg[i].second;
}
}
template<typename ProcessGroup, typename GlobalMap, typename StorageMap>
template<typename Reduce>
void
PBGL_DISTRIB_PMAP::handle_message<Reduce>::
handle_multiput
(int source, int tag,
const std::vector<unsafe_pair<local_key_type, value_type> >& values,
trigger_receive_context)
{
using boost::get;
shared_ptr<data_t> data(data_ptr);
BOOST_ASSERT(data);
std::size_t n = values.size();
for (std::size_t i = 0; i < n; ++i) {
local_key_type local_key = values[i].first;
value_type local_value = get(data->storage, local_key);
detail::maybe_put(data->storage, values[i].first,
reduce(values[i].first,
local_value,
values[i].second));
}
}
template<typename ProcessGroup, typename GlobalMap, typename StorageMap>
template<typename Reduce>
void
PBGL_DISTRIB_PMAP::handle_message<Reduce>::
setup_triggers(process_group_type& pg)
{
using boost::parallel::simple_trigger;
simple_trigger(pg, property_map_put, this, &handle_message::handle_put);
simple_trigger(pg, property_map_get, this, &handle_message::handle_get);
simple_trigger(pg, property_map_multiget, this,
&handle_message::handle_multiget);
simple_trigger(pg, property_map_multiget_reply, this,
&handle_message::handle_multiget_reply);
simple_trigger(pg, property_map_multiput, this,
&handle_message::handle_multiput);
}
template<typename ProcessGroup, typename GlobalMap, typename StorageMap>
void
PBGL_DISTRIB_PMAP
::on_synchronize::operator()()
{
int stage=0; // we only get called at the start now
shared_ptr<data_t> data(data_ptr);
BOOST_ASSERT(data);
// Determine in which stage backward consistency messages should be sent.
int backward_stage = -1;
if (data->model & cm_backward) {
if (data->model & cm_flush) backward_stage = 1;
else backward_stage = 0;
}
// Flush results in first stage
if (stage == 0 && data->model & cm_flush)
data->flush();
// Backward consistency
if (stage == backward_stage && !(data->model & (cm_clear | cm_reset)))
data->refresh_ghost_cells();
// Optionally clear results
if (data->model & cm_clear)
data->clear();
// Optionally reset results
if (data->model & cm_reset) {
if (data->reset) ((*data).*data->reset)();
}
}
template<typename ProcessGroup, typename GlobalMap, typename StorageMap>
void
PBGL_DISTRIB_PMAP::set_consistency_model(int model)
{
data->model = model;
bool need_on_synchronize = (model != cm_forward);
// Backward consistency is a two-stage process.
if (model & cm_backward) {
// For backward consistency to work, we absolutely cannot throw
// away any ghost cells.
data->max_ghost_cells = 0;
}
// attach the on_synchronize handler.
if (need_on_synchronize)
data->process_group.replace_on_synchronize_handler(on_synchronize(data));
}
template<typename ProcessGroup, typename GlobalMap, typename StorageMap>
void
PBGL_DISTRIB_PMAP::set_max_ghost_cells(std::size_t max_ghost_cells)
{
if ((data->model & cm_backward) && max_ghost_cells > 0)
boost::throw_exception(std::runtime_error("distributed_property_map::set_max_ghost_cells: "
"cannot limit ghost-cell usage with a backward "
"consistency model"));
if (max_ghost_cells == 1)
// It is not safe to have only 1 ghost cell; the cell() method
// will fail.
max_ghost_cells = 2;
data->max_ghost_cells = max_ghost_cells;
prune_ghost_cells();
}
template<typename ProcessGroup, typename GlobalMap, typename StorageMap>
void PBGL_DISTRIB_PMAP::clear()
{
data->clear();
}
template<typename ProcessGroup, typename GlobalMap, typename StorageMap>
void PBGL_DISTRIB_PMAP::data_t::clear()
{
ghost_cells->clear();
}
template<typename ProcessGroup, typename GlobalMap, typename StorageMap>
void PBGL_DISTRIB_PMAP::reset()
{
if (data->reset) ((*data).*data->reset)();
}
template<typename ProcessGroup, typename GlobalMap, typename StorageMap>
void PBGL_DISTRIB_PMAP::flush()
{
data->flush();
}
template<typename ProcessGroup, typename GlobalMap, typename StorageMap>
void PBGL_DISTRIB_PMAP::data_t::refresh_ghost_cells()
{
using boost::get;
std::vector<std::vector<key_type> > keys;
keys.resize(num_processes(process_group));
// Collect the set of keys for which we will request values
for (iterator i = ghost_cells->begin(); i != ghost_cells->end(); ++i)
keys[get(global, i->first).first].push_back(i->first);
// Send multiget requests to each of the other processors
typedef typename ProcessGroup::process_size_type process_size_type;
process_size_type n = num_processes(process_group);
process_id_type id = process_id(process_group);
for (process_size_type p = (id + 1) % n ; p != id ; p = (p + 1) % n) {
if (!keys[p].empty())
send(process_group, p, property_map_multiget, keys[p]);
}
}
template<typename ProcessGroup, typename GlobalMap, typename StorageMap>
void PBGL_DISTRIB_PMAP::data_t::flush()
{
using boost::get;
int n = num_processes(process_group);
std::vector<std::vector<unsafe_pair<local_key_type, value_type> > > values;
values.resize(n);
// Collect all of the flushed values
for (iterator i = ghost_cells->begin(); i != ghost_cells->end(); ++i) {
std::pair<int, local_key_type> g = get(global, i->first);
values[g.first].push_back(std::make_pair(g.second, i->second));
}
// Transmit flushed values
for (int p = 0; p < n; ++p) {
if (!values[p].empty())
send(process_group, p, property_map_multiput, values[p]);
}
}
template<typename ProcessGroup, typename GlobalMap, typename StorageMap>
void PBGL_DISTRIB_PMAP::do_synchronize()
{
if (data->model & cm_backward) {
synchronize(data->process_group);
return;
}
// Request refreshes of the values of our ghost cells
data->refresh_ghost_cells();
// Allows all of the multigets to get to their destinations
synchronize(data->process_group);
// Allows all of the multiget responses to get to their destinations
synchronize(data->process_group);
}
template<typename ProcessGroup, typename GlobalMap, typename StorageMap>
template<typename Resolver>
void PBGL_DISTRIB_PMAP::data_t::do_reset()
{
Resolver* resolver = get_default_value.template target<Resolver>();
BOOST_ASSERT(resolver);
for (iterator i = ghost_cells->begin(); i != ghost_cells->end(); ++i)
const_cast<value_type&>(i->second) = (*resolver)(i->first);
}
} } // end namespace boost::parallel