bool ltr_int_broadcast_pose(linuxtrack_full_pose_t &pose)
{
pthread_mutex_lock(&send_mx);
std::multimap<std::string, int>::iterator i;
int res;
bool checkSlaves = false;
//Send updated pose to all clients
//printf("Master: %g %g %g\n", pose.pose.raw_pitch, pose.pose.raw_yaw, pose.pose.raw_roll);
for(i = slaves.begin(); i != slaves.end();) {
res = ltr_int_send_data(i->second, &pose);
if(res == -EPIPE) {
ltr_int_log_message("Slave @socket %d left!\n", i->second);
close(i->second);
i->second = -1;
slaves.erase(i++);
checkSlaves = true;
} else {
++i;
}
}
if(checkSlaves && (slaves.size() == 0)) {
no_slaves = true;
}
pthread_mutex_unlock(&send_mx);
return true;
}
void AMQPAbstractPublishNotifier::Shutdown()
{
LogPrint("amqp", "amqp: Shutdown notifier %s at %s\n", GetType(), GetAddress());
int count = mapPublishNotifiers.count(address);
// remove this notifier from the list of publishers using this address
typedef std::multimap<std::string, AMQPAbstractPublishNotifier*>::iterator iterator;
std::pair<iterator, iterator> iterpair = mapPublishNotifiers.equal_range(address);
for (iterator it = iterpair.first; it != iterpair.second; ++it) {
if (it->second == this) {
mapPublishNotifiers.erase(it);
break;
}
}
// terminate the connection if this is the last publisher using this address
if (count == 1) {
handler_->terminate();
if (thread_.get() != nullptr) {
if (thread_->joinable()) {
thread_->join();
}
}
}
}
void flush_immediate_sync() {
auto seq_no = processor_.max_finished_seq_no();
for (auto it = immediate_sync_promises_.begin(), end = immediate_sync_promises_.end();
it != end && it->first <= seq_no; it = immediate_sync_promises_.erase(it)) {
do_immediate_sync(std::move(it->second));
}
}
void updateEvent(int id, int idx, float val, int activate_cmd)
{
idmap_t id_iter = idmap.find(id);
if (id_iter != idmap.end())
{
//this is a new id
iter_t e_iter = id_iter->second;
Event * e = e_iter->second;
int onset = e->onset;
e->update(idx, val);
e->activate_cmd(activate_cmd);
if (onset != e->onset)
{
ev.erase(e_iter);
e_iter = ev.insert(pair_t(e->onset, e));
//TODO: optimize by thinking about whether to do ev_pos = e_iter
ev_pos = ev.upper_bound( tick_prev );
idmap[id] = e_iter;
}
}
else
{
g_log->printf(1, "%s unknown note %i\n", __FUNCTION__, id);
}
}
void query_recommender::merge_recommended_queries(std::multimap<double,std::string,std::less<double> > &related_queries,
hash_map<const char*,double,hash<const char*>,eqstr> &update)
{
hash_map<const char*,double,hash<const char*>,eqstr>::iterator hit;
std::multimap<double,std::string,std::less<double> >::iterator mit
= related_queries.begin();
while(mit!=related_queries.end())
{
std::string rquery = (*mit).second;
if ((hit = update.find(rquery.c_str()))!=update.end())
{
(*hit).second = std::min((*mit).first,(*hit).second);
std::multimap<double,std::string,std::less<double> >::iterator mit2 = mit;
++mit;
related_queries.erase(mit2);
}
else ++mit;
}
hit = update.begin();
hash_map<const char*,double,hash<const char*>,eqstr>::iterator chit;
while(hit!=update.end())
{
related_queries.insert(std::pair<double,std::string>((*hit).second,std::string((*hit).first)));
chit = hit;
++hit;
free_const((*chit).first);
}
}
bool World::DeletePersistentData(const PersistentDataItem &item)
{
int id = item.raw_id();
if (id > -100)
return false;
if (!BuildPersistentCache())
return false;
stl::vector<df::historical_figure*> &hfvec = df::historical_figure::get_vector();
auto eqrange = persistent_index.equal_range(item.key());
for (auto it2 = eqrange.first; it2 != eqrange.second; )
{
auto it = it2; ++it2;
if (it->second != -id)
continue;
persistent_index.erase(it);
int idx = binsearch_index(hfvec, id);
if (idx >= 0) {
delete hfvec[idx];
hfvec.erase(hfvec.begin()+idx);
}
return true;
}
return false;
}
virtual void Run()
{
now = v8::base::OS::TimeCurrentMillis();
while (1)
{
AsyncEvent *p;
std::multimap<double, AsyncEvent *>::iterator e;
wait();
now = v8::base::OS::TimeCurrentMillis();
while (1)
{
p = s_acSleep.get();
if (p == NULL)
break;
s_tms.insert(std::make_pair(now + p->result(), p));
}
while (1)
{
e = s_tms.begin();
if (e == s_tms.end())
break;
if (e->first > now)
break;
e->second->apost(0);
s_tms.erase(e);
}
}
}
static void PASCAL Timer(unsigned int uTimerID, unsigned int uMsg,
DWORD_PTR dwUser, DWORD_PTR dw1, DWORD_PTR dw2)
{
AsyncEvent *p;
double tm;
std::multimap<double, AsyncEvent *>::iterator e;
while (1)
{
p = s_acSleep.get();
if (p == NULL)
break;
tm = s_time + s_now + p->result();
s_tms.insert(std::make_pair(tm, p));
}
atom_xchg(&s_now, (int)(v8::internal::OS::TimeCurrentMillis() - s_time));
while (1)
{
e = s_tms.begin();
if (e == s_tms.end())
break;
if (e->first > s_time + s_now)
break;
e->second->apost(0);
s_tms.erase(e);
}
}
void *MemoryPool::pop(size_t s, int loc) {
void *addr = nullptr;
if ((s > MIN_BLOCK_SIZE) && (s < MAX_BLOCK_SIZE)) {
locker_.lock();
// find MemoryPool block which is not smaller than demand size
auto pt = pool_.lower_bound(s);
if (pt != pool_.end()) {
size_t ts = 0;
std::tie(ts, addr) = *pt;
if (ts < s * 2) {
s = ts;
pool_.erase(pt);
pool_depth_ -= s;
} else {
addr = nullptr;
}
}
locker_.unlock();
}
if (addr == nullptr) {
try {
#ifdef __CUDA__
SP_DEVICE_CALL(cudaMallocManaged(&addr, s));
#else
addr = malloc(s);
#endif
} catch (std::bad_alloc const &error) { THROW_EXCEPTION_BAD_ALLOC(s); }
}
return addr;
}
void CZMQAbstractPublishNotifier::Shutdown()
{
assert(psocket);
int count = mapPublishNotifiers.count(address);
// remove this notifier from the list of publishers using this address
typedef std::multimap<std::string, CZMQAbstractPublishNotifier*>::iterator iterator;
std::pair<iterator, iterator> iterpair = mapPublishNotifiers.equal_range(address);
for (iterator it = iterpair.first; it != iterpair.second; ++it)
{
if (it->second==this)
{
mapPublishNotifiers.erase(it);
break;
}
}
if (count == 1)
{
LogPrint("zmq", "Close socket at address %s\n", address);
int linger = 0;
zmq_setsockopt(psocket, ZMQ_LINGER, &linger, sizeof(linger));
zmq_close(psocket);
}
psocket = 0;
}
/**
* @param name A string containing the algorithm name
* @param version The version to remove. -1 indicates all instances
* @param typedLoaders A map of names to version numbers
**/
void FileLoaderRegistryImpl::removeAlgorithm(
const std::string &name, const int version,
std::multimap<std::string, int> &typedLoaders) {
if (version == -1) // remove all
{
typedLoaders.erase(name);
} else // find the right version
{
auto range = typedLoaders.equal_range(name);
for (auto ritr = range.first; ritr != range.second; ++ritr) {
if (ritr->second == version) {
typedLoaders.erase(ritr);
break;
}
}
}
}
void GameDB::deleteGame(std::multimap<Reference<Team>, Reference<Game>>& map, Reference<Team> team, Reference<Game> game) {
auto range = map.equal_range(team);
for (auto i = range.first; i != range.second; ++i) {
if (i->second == game) {
map.erase(i);
return;
}
}
}
bool removeExampleHandler (T eventName, Handle handler) {
auto ret = map.equal_range(eventName);
for(auto it = ret.first;it != ret.second;++it) {
if(it->second == handler) {
it = map.erase(it);
return true;
}
}
return false;
}
// msgpack::type::MAP is converted to std::multimap, not std::map.
void operator()(std::multimap<msgpack::type::variant_ref, msgpack::type::variant_ref>& v) const {
std::cout << "match map" << std::endl;
std::multimap<msgpack::type::variant_ref, msgpack::type::variant_ref>::iterator it = v.begin();
std::multimap<msgpack::type::variant_ref, msgpack::type::variant_ref>::iterator end = v.end();
while(it != end) {
boost::string_ref const& key = it->first.as_boost_string_ref();
if (key == "name") {
boost::string_ref const& value = it->second.as_boost_string_ref();
if (value == "Takatoshi Kondo") {
// You can add values to msgpack::type::variant_ref.
v.insert(
std::multimap<msgpack::type::variant_ref, msgpack::type::variant_ref>::value_type(
"role",
"msgpack-c committer"
)
);
}
++it;
}
else if (key == "age") {
// You can remove key-value pair from msgpack::type::variant_ref
#if defined(MSGPACK_USE_CPP03)
v.erase(it++);
#else // defined(MSGPACK_USE_CPP03)
# if MSGPACK_LIB_STD_CXX
it = v.erase(std::multimap<msgpack::type::variant_ref, msgpack::type::variant_ref>::const_iterator(it));
# else // MSGPACK_LIB_STD_CXX
it = v.erase(it);
# endif // MSGPACK_LIB_STD_CXX
#endif // defined(MSGPACK_USE_CPP03)
}
else if (key == "address") {
// When you want to append string
// "Tokyo" -> "Tokyo, JAPAN"
// Use msgpack::type::variant instead of msgpack::type::variant_ref
// or do as follows:
boost::string_ref const& value = it->second.as_boost_string_ref();
it->second = std::string(&value.front(), value.size()) + ", JAPAN";
++it;
}
}
}
static void sort_by_location(std::multimap<std::string, Species> location_map,
std::vector<Species>& species, const std::string location="")
{
std::multimap<std::string, Species>::iterator itr;
while ((itr = location_map.find(location)) != location_map.end())
{
const Species sp((*itr).second);
species.push_back(sp);
sort_by_location(location_map, species, sp.serial());
location_map.erase(itr);
}
}
void intersect(int a, int b, const Point & I, std::vector<Segment> & segments, std::multimap<Point, int> & sweep, std::multimap<std::pair<double,int>, int,event_less> & events, bool print)
{
//remove event of ending of old segment
{
int rem_end_events[2];
rem_end_events[0] = a;
rem_end_events[1] = b;
for (int k = 0; k < 2; ++k)
{
std::pair< std::multimap<std::pair<double,int>, int,event_less>::iterator, std::multimap<std::pair<double,int>,int,event_less>::iterator > del = events.equal_range(std::make_pair(segments[rem_end_events[k]].end.x,SEG_END)); //get all events at position of the end
bool flag = false;
for (std::multimap<std::pair<double,int>, int,event_less>::iterator it = del.first; it != del.second; ++it) //search over all events
{
if (it->first.second == SEG_END && it->second == rem_end_events[k]) //event is end of segment and segment matches current
{
events.erase(it); //remove that segment
flag = true;
break; //do not expect any more
}
}
if (!flag) std::cout << "Cannot find proper ending event for segment" << std::endl;
}
}
//add new segment with intersection point up to end
segments.push_back(Segment(I, segments[a].end));
//add event of starting of new segment
events.insert(std::make_pair(std::make_pair(I.x,SEG_START), (int)segments.size() - 1));
//add event of ending of new segment
events.insert(std::make_pair(std::make_pair(segments.back().end.x,SEG_END),(int)segments.size() - 1));
//change ending point for current segment
segments[a].end = I;
//add event of ending of old segment
events.insert(std::make_pair(std::make_pair(I.x,SEG_END), a));
//add new segment with intersection point up to end
segments.push_back(Segment(I, segments[b].end));
//add event of starting of new segment
events.insert(std::make_pair(std::make_pair(I.x,SEG_START), (int)segments.size() - 1));
//add event of ending of new segment
events.insert(std::make_pair(std::make_pair(segments.back().end.x,SEG_END), (int)segments.size() - 1));
//change ending point for current segment
segments[b].end = I;
//add event of ending of old segment
events.insert(std::make_pair(std::make_pair(I.x,SEG_END), b));
if (print)
{
std::cout << "Number of events: " << events.size() << std::endl;
for (std::multimap<std::pair<double, int>, int,event_less>::iterator it = events.begin(); it != events.end(); ++it)
std::cout << "x: " << it->first.first << " type " << (it->first.second == SEG_START ? "start" : "end") << " segment " << it->second << std::endl;
}
}
static void save_molecular_type_recursively(const Species& location,
std::multimap<Species, const MolecularTypeBase*>& location_map,
Tspace_& space, H5::Group* root)
{
std::multimap<Species, const MolecularTypeBase*>::iterator itr;
while ((itr = location_map.find(location)) != location_map.end())
{
const MolecularTypeBase* mtb((*itr).second);
const Species species(mtb->species());
save_molecular_type(mtb, space.list_voxels_exact(species), root);
save_molecular_type_recursively(species, location_map, space, root);
location_map.erase(itr);
}
}
ExampleEventDispatcherTpl() {
ExampleEventEmitter<T, Rest...>::onExample([&](T eventName, Rest... fargs) {
auto ret = map.equal_range(eventName);
for(auto it = ret.first;it != ret.second;) {
(it->second)(fargs...);
if(eraseLast) {
it = map.erase(it);
eraseLast = false;
}
else {
++it;
}
}
});
}
void splitDrumTracks(std::multimap<int, MTrack> &tracks)
{
for (auto it = tracks.begin(); it != tracks.end(); ++it) {
if (!it->second.mtrack->drumTrack())
continue;
const auto &opers = preferences.midiImportOperations.data()->trackOpers;
if (!opers.doStaffSplit.value(it->second.indexOfOperation))
continue;
const auto newTracks = splitDrumTrack(it->second);
const int trackIndex = it->first;
it = tracks.erase(it);
for (auto i = newTracks.rbegin(); i != newTracks.rend(); ++i)
it = tracks.insert({trackIndex, i->second});
}
}
void EventManager::runTimedEvents(TimePoint now) {
//run all the events ready to run
for (auto&& event : mEvents) {
if (event->isReady(now)) {
event->run();
}
}
if (mSimpleTasks.size()) {
auto top = mSimpleTasks.begin();
if (now >= top->first) {
top->second();
mSimpleTasks.erase(top);
}
}
}
void delEvent(int id)
{
idmap_t id_iter = idmap.find(id);
if (id_iter != idmap.end())
{
iter_t e_iter = id_iter->second;//idmap[id];
if (e_iter == ev_pos) ++ev_pos;
delete e_iter->second;
ev.erase(e_iter);
idmap.erase(id_iter);
}
else
{
g_log->printf( 1, "%s unknown note %i\n", __FUNCTION__, id);
}
}
static void run_timers(color_ostream &out, lua_State *L,
std::multimap<int,int> &timers, int table, int bound)
{
while (!timers.empty() && timers.begin()->first <= bound)
{
int id = timers.begin()->second;
timers.erase(timers.begin());
lua_rawgeti(L, table, id);
if (lua_isnil(L, -1))
lua_pop(L, 1);
else
{
lua_pushnil(L);
lua_rawseti(L, table, id);
Lua::SafeCall(out, L, 0, 0);
}
}
}
void process_ongoing_requests(std::multimap<addr_type, int> & ongoing_requests,
int fake_stamp,
std::vector<Tree> & Bs,
std::vector<std::map<addr_type, int>> & Ps,
std::vector<int> & set_counters,
ModelConfig & model_config) {
std::multimap<addr_type, int>::iterator it;
it = ongoing_requests.begin();
while (it != ongoing_requests.end()) {
if (it->second <= fake_stamp) {
// If the model is configed not allocate_on_miss, need to update stack tree here
if (! model_config.allocate_on_miss) {
update_stack_tree(it->first, Bs, Ps, set_counters, model_config);
}
it = ongoing_requests.erase(it);
}
else {
it ++;
}
}
}
// Only call on io_service
void ResetTimer()
{
const auto now = std::chrono::steady_clock::now();
UniqueLock unique_lock(mutex_);
while (running_ && !data_.empty())
{
auto map_front_it = data_.begin();
const auto timeout = map_front_it->first;
if ( timeout <= now )
{
// Effeciently extract the value so we can move it.
auto event = std::move( map_front_it->second );
data_.erase(map_front_it);
// Unlock incase callback calls a TimedActions method.
unique_lock.unlock();
event_processor_(std::move(event), std::error_code());
unique_lock.lock();
}
else
{
timeout_timer_.expires_at(timeout);
timeout_timer_.async_wait(
boost::bind(
&TimedEvents<Event>::HandleTimeout,
this->shared_from_this(),
boost::asio::placeholders::error
)
);
break;
}
}
}
void disconnect(Class& obj, void (Class::*func)(Params...)) {
m_functions.erase(Key { &obj, getHash(func) });
}
int main(int argc, char **argv)
{
long int i, N;
bool already_invaded;
short int L, j, k, l;
double pc = 0.49;
L = atoi(argv[1]);
N = L*L;
for(j=-L/2; j < L/2; j++)
{
for(k=-L/2+1; k < L/2+1; k++)
{
Site loc = std::make_pair(j, k);
unitCell_Square cell;
lattice.insert(std::make_pair(loc, cell));
}
}
Site start = std::make_pair(0,0);
lattice[start].is_invaded = true;
add_new_Bonds(start);
try
{
for (i=0; i<N;)
{
std::multimap<double, Bond>::iterator weakest;
weakest = accessible_Bonds.begin();
already_invaded = invade_bond(weakest->second);
if(!already_invaded)
{
i++;
}
accessible_Bonds.erase(weakest);
}
std::multimap<double, Bond>::iterator weakest = accessible_Bonds.begin();
cluster.push_back(weakest->second);
}
catch (std::exception& e) {}
std::ofstream toFile1("fractures.txt", std::ios::trunc);
std::ofstream toFile2("trapped.txt", std::ios::trunc);
toFile1 << cluster.size() << "\n";
toFile2 << trappedBonds.size() << "\n";
toFile1 << "Invasion for: temp" << "\n";
toFile2 << "Trapping for: temp" << "\n";
toFile1.precision(17);
toFile2.precision(17);
Bond current_Line;
while (!cluster.empty())
{
current_Line = cluster.front();
cluster.pop_front();
toFile1 << get_strength(current_Line) << "\t";
toFile1 << current_Line.first.first << "\t";
toFile1 << current_Line.first.second << "\t";
Site other_end = get_end(current_Line);
toFile1 << other_end.first << "\t";
toFile1 << other_end.second << "\n";
}
while (!trappedBonds.empty())
{
current_Line = trappedBonds.front();
trappedBonds.pop_front();
toFile2 << get_strength(current_Line) << "\t";
toFile2 << current_Line.first.first << "\t";
toFile2 << current_Line.first.second << "\t";
Site other_end = get_end(current_Line);
toFile2 << other_end.first << "\t";
toFile2 << other_end.second << "\n";
}
toFile1.close();
toFile2.close();
accessible_Bonds.clear();
for(j=-L/2; j < L/2; j++)
{
for(k=-L/2+1; k < L/2+1; k++)
{
for(l=0; l<2; l++)
{
Site loc = std::make_pair(j, k);
Bond bond = std::make_pair(loc, l);
accessible_Bonds.insert(std::make_pair(lattice[loc].bonds[l], bond));
}
}
}
std::multimap<double, Bond>::iterator weakest = accessible_Bonds.begin();
while(weakest->first < pc)
{
lattice[weakest->second.first].is_open[weakest->second.second] = grow_clusters(weakest->second);
accessible_Bonds.erase(weakest);
weakest = accessible_Bonds.begin();
}
unitCell_Square * current_cell;
for(j=-L/2; j < L/2; j++)
{
for(k=-L/2+1; k < L/2+1; k++)
{
current_cell = &lattice[std::make_pair(j,k)];
current_cell->clusterN = find(current_cell->clusterN);
}
}
long int bond_count = 0;
for(lattice_iterator iter = lattice.begin(); iter != lattice.end(); iter++)
{
current_cell = &iter->second;
if(current_cell->is_open[0])
{
bond_count++;
}
if(current_cell->is_open[1])
{
bond_count++;
}
}
std::ofstream toFile3("clusters.txt", std::ios::trunc);
toFile3 << bond_count << "\n";
unitCell_Square Line;
Site begin;
Site other_end;
std::map<unsigned int, unsigned int> cluster_sizes;
while (!lattice.empty())
{
begin = lattice.begin()->first;
Line = lattice.begin()->second;
lattice.erase(begin);
if(Line.is_open[0])
{
if(cluster_sizes.count(Line.clusterN) > 0)
{
cluster_sizes[Line.clusterN]++;
}
else
{
cluster_sizes.insert(std::make_pair(Line.clusterN,1));
}
toFile3 << Line.clusterN << "\t";
toFile3 << begin.first << "\t";
toFile3 << begin.second << "\t";
other_end = get_end(std::make_pair(begin, 0));
toFile3 << other_end.first << "\t";
toFile3 << other_end.second << "\n";
}
if(Line.is_open[1])
{
if(cluster_sizes.count(Line.clusterN) > 0)
{
cluster_sizes[Line.clusterN]++;
}
else
{
cluster_sizes.insert(std::make_pair(Line.clusterN,1));
}
toFile3 << Line.clusterN << "\t";
toFile3 << begin.first << "\t";
toFile3 << begin.second << "\t";
other_end = get_end(std::make_pair(begin, 1));
toFile3 << other_end.first << "\t";
toFile3 << other_end.second << "\n";
}
}
toFile3.close();
unsigned int largest_cluster = 0;
unsigned int largest_cluster_size = 0;
std::map<unsigned int, unsigned int>::iterator iter;
for(iter = cluster_sizes.begin(); iter != cluster_sizes.end(); iter++)
{
if(iter->second > largest_cluster_size)
{
largest_cluster = iter->first;
largest_cluster_size = iter->second;
}
}
std::map<unsigned int, unsigned int> cluster_count;
unsigned int size, begin2;
while (!cluster_sizes.empty())
{
begin2 = cluster_sizes.begin()->first;
size = cluster_sizes.begin()->second;
cluster_sizes.erase(begin2);
if(cluster_count.count(size) > 0)
{
cluster_count[size]++;
}
else
{
cluster_count.insert(std::make_pair(size, 1));
}
}
std::ofstream toFile4("cluster_distribution.txt", std::ios::trunc);
toFile4 << cluster_count.size() << "\t" << largest_cluster << "\t";
toFile4 << cluster_map[largest_cluster].second.first << "\t" << cluster_map[largest_cluster].second.second << "\n";
unsigned int count;
while (!cluster_count.empty())
{
size = cluster_count.begin()->first;
count = cluster_count.begin()->second;
cluster_count.erase(size);
toFile4 << size << "\t" << count << "\n";
}
toFile4.close();
return 0;
}
void removeAllExampleHandlers (T eventName) {
auto ret = map.equal_range(eventName);
for(auto it = ret.first;it != ret.second;) {
it = map.erase(it);
}
}
void NodeHelper::remove(Contactable& contactable) {
NodeItem item = name_cache[&contactable];
name_cache.erase(&contactable);
by_part_name.erase(item.nc.getNestedName());
by_category.erase(item.nc.getCategory());
}
bool NodeListT::FollowToNode(const std::vector<StationID>::const_iterator &itr,
std::multimap<UnitID, NodeListT::SuperInfoT> &supersets,
const std::vector<StationID>::const_iterator &itr_1,
bool neg) const
{
const auto node_itr = nodes.find(*itr);
if(node_itr == nodes.end())
return false;
const NodeInfoT* info = &node_itr->second;
auto next = supersets.begin();
for(auto sitr = supersets.begin(); sitr != supersets.end(); sitr = next)
{
++(next = sitr);
UnitID cur_line = sitr->first;
std::size_t& last_station_no = sitr->second.last_station_no;
std::size_t new_last_station_no = std::numeric_limits<std::size_t>::max();
const auto in_nodes = info->equal_range(cur_line);
std::size_t tmp = lengths.at(cur_line);
for(auto in_node = in_nodes.first;
in_node != in_nodes.second; ++in_node)
{
tmp = value_of(supersets, cur_line, in_node->second, neg);
if(tmp == 0)
tmp = lengths.at(cur_line);
if(tmp >= last_station_no && // is it a future node?
tmp < new_last_station_no /* better than previous result? */ )
{
new_last_station_no = tmp;
}
}
if(new_last_station_no == std::numeric_limits<std::size_t>::max())
supersets.erase(sitr);
else
{
// was the last node visited twice before we got here?
// if so, this train can still be a short train
const auto& last_in_nodes =
nodes.at(*itr_1).equal_range(cur_line);
bool no_express = true;
if(last_station_no < new_last_station_no - 1) // some nodes between...
{
no_express = false;
for(auto last_in_node = last_in_nodes.first;
(!no_express) && last_in_node != last_in_nodes.second;
++last_in_node)
{
std::size_t value_found_in_last = value_of(supersets, cur_line, last_in_node->second, neg);
if(last_station_no < value_found_in_last
&& value_found_in_last == (new_last_station_no-1))
{
// ok, it was just a slope we've left out
no_express = true;
}
}
}
sitr->second.can_be_short_train =
sitr->second.can_be_short_train && no_express;
// advance
last_station_no = new_last_station_no;
}
}
return true;
}
bool IndexServerConn::HandleMsg(enum IndexServerMsg msg_id)
{
switch(msg_id)
{
case TS_MSG_VERSION:
return HandShake();
break;
case TS_MSG_WIS_VERSION:
{
int version;
if (BytesReceived() < sizeof(uint32_t)) // The message is not completely received
return true;
if (!ReceiveInt(version)) // Receive the version number of the server index
return false;
if (version > VERSION)
{
DPRINT(INFO,"The server at %i have a version %i, while we are only running a %i version",
GetIP(), version, VERSION);
exit(EXIT_FAILURE);
}
else if(version < VERSION)
{
DPRINT(INFO,"This server is running an old version (v%i) !", version);
return false;
}
DPRINT(INFO,"We are running the same version..");
}
break;
case TS_MSG_JOIN_LEAVE:
{
int ip;
int port;
std::string version;
if (!ReceiveStr(version))
return false;
if (BytesReceived() < 2*sizeof(uint32_t)) // The message is not completely received
return true;
if (!ReceiveInt(ip)) // Receive the IP of the warmux server
return false;
if (!ReceiveInt(port)) // Receive the port of the warmux server
return false;
if (port < 0) // means it disconnected
{
for (std::multimap<std::string, FakeClient>::iterator serv = fake_clients.lower_bound(version);
serv != fake_clients.upper_bound(version);
serv++) {
if( serv->second.ip == ip
&& serv->second.port == -port )
{
fake_clients.erase(serv);
DPRINT(MSG, "A fake server disconnected");
break;
}
}
}
else
{
HostOptions options;
std::string game_name;
if (!ReceiveStr(game_name))
return false;
int passwd;
if (!ReceiveInt(passwd))
return false;
options.Set(game_name, passwd);
fake_clients.insert(std::make_pair(version, FakeClient(ip, port, options)));
stats.NewFakeServer(version);
}
}
break;
default:
DPRINT(INFO,"Bad message!");
return false;
}
msg_id = TS_NO_MSG;
return true;
}
