Dispatch::Handler Dispatch::code2handler( Message::type_t type )
{
typedef std::map<Message::type_t, Handler> map_type;
static map_type handlers;
if ( handlers.empty() ) {
using namespace MessageTypes;
handlers[ NameQuery ] = &Dispatch::namequery_handler;
handlers[ NameReply ] = &Dispatch::namereply_handler;
handlers[ Opponentname ] = &Dispatch::opponentname_handler;
handlers[ Receive ] = &Dispatch::receive_handler;
handlers[ Invalidmove ] = &Dispatch::invalidmove_handler;
handlers[ Inform ] = &Dispatch::inform_handler;
handlers[ Status ] = &Dispatch::status_handler;
handlers[ Points ] = &Dispatch::points_handler;
handlers[ PlayQuery ] = &Dispatch::playquery_handler;
handlers[ PlayReply ] = &Dispatch::playreply_handler;
handlers[ Give3Query ] = &Dispatch::give3query_handler;
handlers[ Terminate ] = &Dispatch::terminate_handler;
// handlers[Reset] = &Dispatch::reset_handler;
handlers[ Give3Reply ] = &Dispatch::give3reply_handler;
handlers[ PlayReply ] = &Dispatch::playreply_handler;
}
map_type::iterator resp = handlers.find( type );
if ( resp == handlers.end() ) {
LOG_PLACE() << "No handler for " << type << ".\n";
return &Dispatch::error_handler;
}
return resp->second;
}
void probe (map_type& testMap, std::string name, auto keys, auto values, size_t toFind)
{
// map_type
const int width (15);
const int precision (6);
std::cout << std::setw (width) << keys.size () << " : " << std::setw (width) << name << " : " << std::flush;
high_resolution_clock::time_point startTime = high_resolution_clock::now ();
auto itValues = begin (values);
for_each (begin (keys), end (keys), [&testMap, &itValues](size_t key)
{
testMap.insert (std::make_pair (key, (*itValues++)));
});
high_resolution_clock::time_point findTime = high_resolution_clock::now ();
size_t currFind = 0;
for (auto k : keys)
{
if (currFind >= toFind)
break;
bool exists = testMap.find (k) != testMap.end ();
if (exists)
++currFind;
}
high_resolution_clock::time_point endTime = high_resolution_clock::now ();
duration<double> time_span_insert = duration_cast<duration<double>> (findTime-startTime);
duration<double> time_span_find = duration_cast<duration<double>> (endTime-findTime);
std::cout << "time insert = " << std::fixed << std::setprecision (precision) << time_span_insert.count () << " time find = " << std::setprecision (precision) << time_span_find.count () << std::setw (width) << " found = " << std::setw (width) << currFind << std::endl;
}
void *runner(void *f)
{
string tmp = "", content = *(string *)f; //將傳過來的指標轉成string
for (int i = 0; i < content.length()+1; ++i) {
if(content[i]=='\'' && tmp!="" &&((content[i+1]>='a' && content[i+1]<='z') || (content[i+1]>='A' && content[i+1]<='Z')) ) // 單引號的前後為英文單字的
{
tmp += content[i];
continue;
}
if(content[i]>='a' && content[i] <='z')
tmp += content[i];
else if(content[i] >='A' && content[i] <= 'Z')
tmp += tolower(content[i]);
else if(tmp != "")
{
pthread_mutex_lock(&mutex); //鎖
/* critical section */
iter = m.find(tmp); //搜尋
if(iter != m.end())
iter->second++; //資料重複,所以將次數+1
else
m.insert(map_type::value_type(tmp,1)); //插入資料
pthread_mutex_unlock(&mutex); //解鎖
tmp = "";
}
}
pthread_exit(0); //結束thread
}
//! conversion to clause
clause_type clause() const {
clause_type C;
const iterator pa_end = pa.end();
for (iterator i = pa.begin(); i != pa_end; ++i)
C.ls.insert(literal_type(i->first, i->second));
return C;
}
/** Compute the sum of all the elements
* Implements compensated summation
*/
double sum() {
double s=0.;
for (map_type::iterator it=map.begin(),itend=map.end();it!=itend;++it) {
s += it->second;
}
return s;
}
inline std::error_category const & to_std_category( boost::system::error_category const & cat )
{
if( cat == boost::system::system_category() )
{
static const std_category system_instance( &cat, 0x1F4D7 );
return system_instance;
}
else if( cat == boost::system::generic_category() )
{
static const std_category generic_instance( &cat, 0x1F4D3 );
return generic_instance;
}
else
{
typedef std::map< boost::system::error_category const *, std::unique_ptr<std_category>, cat_ptr_less > map_type;
static map_type map_;
static std::mutex map_mx_;
std::lock_guard<std::mutex> guard( map_mx_ );
map_type::iterator i = map_.find( &cat );
if( i == map_.end() )
{
std::unique_ptr<std_category> p( new std_category( &cat, 0 ) );
std::pair<map_type::iterator, bool> r = map_.insert( map_type::value_type( &cat, std::move( p ) ) );
i = r.first;
}
return *i->second;
}
}
inline const message::factory *get_factory(message_type type) const
{
lock guard(m);
auto it = factories.find(type);
return (it == factories.end()) ? nullptr : it->value;
}
inline class_id class_id_map::get(type_id const& type) const
{
map_type::const_iterator i = m_classes.find(type);
if (i == m_classes.end() || i->second >= local_id_base)
return unknown_class;
return i->second;
}
void print() const{
enterExclusive();
map_type::const_iterator iter = _item_map.begin();
for(; iter != _item_map.end(); ++iter){
iter->second->print();
}
leaveExclusive();
}
/** Get an element and provide a default value when it doesn't exist
* This command does not insert the element into the vector
*/
double get(mwIndex index, double default_value=0.0) {
map_type::iterator it = map.find(index);
if (it == map.end()) {
return default_value;
} else {
return it->second;
}
}
void flush(){
enterExclusive();
map_type::iterator iter = _item_map.begin();
for(; iter != _item_map.end(); ++iter){
iter->second->flush();
}
leaveExclusive();
}
/** Compute the max of the element values
* This operation returns the first element if the vector is empty.
*/
mwIndex max_index() {
mwIndex index=0;
double maxval=std::numeric_limits<double>::min();
for (map_type::iterator it=map.begin(),itend=map.end();it!=itend;++it) {
if (it->second>maxval) { maxval = it->second; index = it->first; }
}
return index;
}
void
mapper::_free_map(map_type &m) {
map_type::iterator i = m.begin();
for (; i != m.end(); i++) {
if (i->first) free((void *)i->first);
if (i->second) free((void *)i->second);
}
m.clear();
}
static void del(map_type& cont, const key_type& key)
{
if ( cont.find(key) != cont.end() ) {
cont.erase(key);
}
else {
KeyError();
}
}
inline void operation_sequence::remove_operation(int id)
{
using namespace std;
map_type::iterator it = operations_.find(id);
if (it == operations_.end())
throw runtime_error( string("No such operation: ") +
lexical_cast<string>(id) );
operations_.erase(it);
}
std::unique_ptr<osmium::io::detail::InputFormat> create_input(const osmium::io::File& file, osmium::osm_entity_bits::type read_which_entities, osmium::thread::Queue<std::string>& input_queue) {
file.check();
auto it = m_callbacks.find(file.format());
if (it != m_callbacks.end()) {
return std::unique_ptr<osmium::io::detail::InputFormat>((it->second)(file, read_which_entities, input_queue));
}
throw std::runtime_error(std::string("Support for input format '") + as_string(file.format()) + "' not compiled into this binary.");
}
std::unique_ptr<osmium::io::detail::OutputFormat> create_output(const osmium::io::File& file, data_queue_type& output_queue) {
file.check();
auto it = m_callbacks.find(file.format());
if (it != m_callbacks.end()) {
return std::unique_ptr<osmium::io::detail::OutputFormat>((it->second)(file, output_queue));
}
throw std::runtime_error(std::string("Support for output format '") + as_string(file.format()) + "' not compiled into this binary.");
}
KOKKOS_INLINE_FUNCTION
void operator()( size_type i ) const
{
const size_type invalid_index = map_type::invalid_index;
uint32_t list = m_map.m_hash_lists(i);
for (size_type curr = list, ii=0; curr != invalid_index; curr = m_map.m_next_index[curr], ++ii) {
printf("%d[%d]: %d->%d\n", list, ii, m_map.key_at(curr), m_map.value_at(curr));
}
}
void print(std::ostream & metrics_out, std::ostream & length_out, std::ostream & distance_out, std::ostream & block_distance_out)
{
metrics_out << map.capacity() << " , ";
metrics_out << inserts/collisions << " , ";
metrics_out << (100.0 * inserts/collisions) / map.capacity() << " , ";
metrics_out << inserts << " , ";
metrics_out << (map.failed_insert() ? "true" : "false") << " , ";
metrics_out << collisions << " , ";
metrics_out << 1e9*(seconds/inserts) << " , ";
metrics_out << seconds << std::endl;
length_out << map.capacity() << " , ";
length_out << ((100.0 *inserts/collisions) / map.capacity()) << " , ";
length_out << collisions << " , ";
histogram.print_length(length_out);
distance_out << map.capacity() << " , ";
distance_out << ((100.0 *inserts/collisions) / map.capacity()) << " , ";
distance_out << collisions << " , ";
histogram.print_distance(distance_out);
block_distance_out << map.capacity() << " , ";
block_distance_out << ((100.0 *inserts/collisions) / map.capacity()) << " , ";
block_distance_out << collisions << " , ";
histogram.print_block_distance(block_distance_out);
}
void remove(hash_type hash, wchar_t c)
{
auto it = map.find(c);
if(it == map.end())
return;
auto &container = it->second;
auto iter = std::find_if(container.begin(), container.end(), [&hash](container_type::value_type &v){return std::get<0>(v) == hash;});
if(iter != container.end())
container.erase(iter);
}
KOKKOS_INLINE_FUNCTION
void operator()(typename execution_space::size_type i) const
{
if (Near) {
m_map.erase(i/m_num_duplicates);
}
else {
m_map.erase(i%(m_num_erase/m_num_duplicates));
}
}
static mapped_type get(map_type & x, const key_type & v)
{
if (x.count(v) != 0)
{
return x.at(v);
}
else
{
PyErr_SetString(PyExc_IndexError, "Index out of range");
boost::python::throw_error_already_set();
}
}
inline OccupationInfo& find_or_insert(Point const& point, Point& mapped_point)
{
typename map_type::iterator it = map.find(point);
if (it == boost::end(map))
{
std::pair<typename map_type::iterator, bool> pair
= map.insert(std::make_pair(point, OccupationInfo()));
it = pair.first;
}
mapped_point = it->first;
return it->second;
}
static void find_unreachable_objects_impl(map_type const & m, map2_type & m2)
{
// scan objects for shared_ptr members, compute internal counts
{
std::cout << "... " << m.size() << " objects in m.\n";
for(map_type::const_iterator i = m.begin(); i != m.end(); ++i)
{
abt_boost::detail::sp_counted_base const * p = static_cast<abt_boost::detail::sp_counted_base const *>(i->first);
BOOST_ASSERT(p->use_count() != 0); // there should be no inactive counts in the map
m2[ i->first ];
scan_and_count(i->second.first, i->second.second, m, m2);
}
std::cout << "... " << m2.size() << " objects in m2.\n";
}
// mark reachable objects
{
open_type open;
for(map2_type::iterator i = m2.begin(); i != m2.end(); ++i)
{
abt_boost::detail::sp_counted_base const * p = static_cast<abt_boost::detail::sp_counted_base const *>(i->first);
if(p->use_count() != i->second) open.push_back(p);
}
std::cout << "... " << open.size() << " objects in open.\n";
for(open_type::iterator j = open.begin(); j != open.end(); ++j)
{
m2.erase(*j);
}
while(!open.empty())
{
void const * p = open.front();
open.pop_front();
map_type::const_iterator i = m.find(p);
BOOST_ASSERT(i != m.end());
scan_and_mark(i->second.first, i->second.second, m2, open);
}
}
// m2 now contains the unreachable objects
}
static void del(map_type & x, const key_type & v)
{
if (x.count(v) != 0)
{
x.erase(v);
}
else
{
PyErr_SetString(PyExc_IndexError, "Index out of range");
boost::python::throw_error_already_set();
}
}
static void set(map_type & x, const key_type & v, mapped_type & m)
{
if (x.count(v) == 0)
{
x.insert(std::make_pair(v, m));
}
else
{
PyErr_SetString(PyExc_IndexError, "Value already set");
boost::python::throw_error_already_set();
}
}
create_parser_type get_creator_function(const osmium::io::File& file) {
auto it = m_callbacks.find(file.format());
if (it == m_callbacks.end()) {
throw unsupported_file_format_error(
std::string("Can not open file '") +
file.filename() +
"' with type '" +
as_string(file.format()) +
"'. No support for reading this format in this program.");
}
return it->second;
}
void remove_handler_helper(hash_type hash, unsigned id, Integers... ids)
{
auto it = map.find(id);
if(it == map.end())
return;
auto &container = it->second;
auto iter = std::find_if(container.begin(), container.end(), [&hash](container_type::value_type &v){return std::get<0>(v) == hash;});
if(iter != container.end())
container.erase(iter);
remove_handler_helper(hash, ids...);
}
std::unique_ptr<osmium::io::detail::OutputFormat> create_output(const osmium::io::File& file, future_string_queue_type& output_queue) {
auto it = m_callbacks.find(file.format());
if (it != m_callbacks.end()) {
return std::unique_ptr<osmium::io::detail::OutputFormat>((it->second)(file, output_queue));
}
throw unsupported_file_format_error(
std::string("Can not open file '") +
file.filename() +
"' with type '" +
as_string(file.format()) +
"'. No support for writing this format in this program.");
}
inline void dictionary::replace(std::string& key)
{
using namespace std;
string copy(key);
tolower(copy);
map_type::iterator it = map_.find(key);
if (it == map_.end())
return;
string& value = it->second;
if (!value.empty() && !key.empty() && std::isupper((unsigned char) key[0]))
value[0] = std::toupper((unsigned char) value[0]);
key = value;
return;
}
