ListUserConfigParam<T, U>::ListUserConfigParam(const char* param_name,
const char* comment)
{
m_param_name = param_name;
all_params.push_back(this);
if(comment != NULL) m_comment = comment;
} // ListUserConfigParam
// ============================================================================
GroupUserConfigParam::GroupUserConfigParam(const char* group_name,
const char* comment)
{
m_param_name = group_name;
all_params.push_back(this);
if(comment != NULL) m_comment = comment;
} // GroupUserConfigParam
int main(int argc, const char *argv[])
{
PtrVector<Test> vec; //vector<Test*>
for (int i = 0; i < 5; i++) {
vec.push_back(new Test);
}
return 0;
}
/** Rebuild the list of tracks and GPs. This need to be recomputed e.g. to
* take unlocked tracks into account.
*/
void TracksScreen::buildTrackList()
{
DynamicRibbonWidget* tracks_widget = this->getWidget<DynamicRibbonWidget>("tracks");
RibbonWidget* tabs = this->getWidget<RibbonWidget>("trackgroups");
// Reset track list everytime (accounts for locking changes, etc.)
tracks_widget->clearItems();
m_random_track_list.clear();
const std::string& curr_group_name = tabs->getSelectionIDString(0);
const int track_amount = (int)track_manager->getNumberOfTracks();
// First build a list of all tracks to be displayed
// (e.g. exclude arenas, ...)
PtrVector<Track, REF> tracks;
for (int n = 0; n < track_amount; n++)
{
Track* curr = track_manager->getTrack(n);
if (race_manager->getMinorMode() == RaceManager::MINOR_MODE_EASTER_EGG
&& !curr->hasEasterEggs())
continue;
if (curr->isArena() || curr->isSoccer()||curr->isInternal()) continue;
if (curr_group_name != ALL_TRACK_GROUPS_ID &&
!curr->isInGroup(curr_group_name)) continue;
tracks.push_back(curr);
} // for n<track_amount
tracks.insertionSort();
for (unsigned int i = 0; i < tracks.size(); i++)
{
Track *curr = tracks.get(i);
if (PlayerManager::getCurrentPlayer()->isLocked(curr->getIdent()))
{
tracks_widget->addItem(
_("Locked : solve active challenges to gain access to more!"),
"locked", curr->getScreenshotFile(), LOCKED_BADGE,
IconButtonWidget::ICON_PATH_TYPE_ABSOLUTE);
}
else
{
tracks_widget->addItem(translations->fribidize(curr->getName()),
curr->getIdent(),
curr->getScreenshotFile(), 0,
IconButtonWidget::ICON_PATH_TYPE_ABSOLUTE);
m_random_track_list.push_back(curr->getIdent());
}
}
tracks_widget->addItem(_("Random Track"), "random_track",
"/gui/track_random.png", 0 /* no badge */,
IconButtonWidget::ICON_PATH_TYPE_RELATIVE);
tracks_widget->updateItemDisplay();
std::random_shuffle( m_random_track_list.begin(), m_random_track_list.end() );
} // buildTrackList
// ============================================================================
StringUserConfigParam::StringUserConfigParam(const char* default_value,
const char* param_name,
const char* comment)
{
m_value = default_value;
m_default_value = default_value;
m_param_name = param_name;
all_params.push_back(this);
if(comment != NULL) m_comment = comment;
} // StringUserConfigParam
// ============================================================================
TimeUserConfigParam::TimeUserConfigParam(StkTime::TimeType default_value,
const char* param_name,
const char* comment)
{
m_value = default_value;
m_default_value = default_value;
m_param_name = param_name;
all_params.push_back(this);
if(comment != NULL) m_comment = comment;
} // TimeUserConfigParam
ListUserConfigParam<T,U>::ListUserConfigParam(const char* param_name,
const char* comment,
int nb_elements,
...)
{
m_param_name = param_name;
all_params.push_back(this);
if(comment != NULL) m_comment = comment;
// add the default list
va_list arguments;
va_start ( arguments, nb_elements );
for ( int i = 0; i < nb_elements; i++ )
m_elements.push_back(T(va_arg ( arguments, U )));
va_end ( arguments ); // Cleans up the list
} // ListUserConfigParam
int main(int argc, char* argv[]) {
google::InitGoogleLogging(argv[0]);
gflags::ParseCommandLineFlags(&argc, &argv, true);
// Detect the hardware concurrency level.
const std::size_t num_hw_threads =
DefaultsConfigurator::GetNumHardwareThreads();
// Use the command-line value if that was supplied, else use the value
// that we computed above, provided it did return a valid value.
// TODO(jmp): May need to change this at some point to keep one thread
// available for the OS if the hardware concurrency level is high.
const unsigned int real_num_workers = quickstep::FLAGS_num_workers != 0
? quickstep::FLAGS_num_workers
: (num_hw_threads != 0 ?
num_hw_threads
: 1);
if (real_num_workers > 0) {
printf("Starting Quickstep with %d worker thread(s) and a %.2f GB buffer pool\n",
real_num_workers,
(static_cast<double>(quickstep::FLAGS_buffer_pool_slots) * quickstep::kSlotSizeBytes)/quickstep::kAGigaByte);
} else {
LOG(FATAL) << "Quickstep needs at least one worker thread to run";
}
#ifdef QUICKSTEP_HAVE_FILE_MANAGER_HDFS
if (quickstep::FLAGS_use_hdfs) {
LOG(INFO) << "Using HDFS as the default persistent storage, with namenode at "
<< quickstep::FLAGS_hdfs_namenode_host << ":"
<< quickstep::FLAGS_hdfs_namenode_port << " and block replication factor "
<< quickstep::FLAGS_hdfs_num_replications << "\n";
}
#endif
// Initialize the thread ID based map here before the Foreman and workers are
// constructed because the initialization isn't thread safe.
quickstep::ClientIDMap::Instance();
MessageBusImpl bus;
bus.Initialize();
// The TMB client id for the main thread, used to kill workers at the end.
const client_id main_thread_client_id = bus.Connect();
bus.RegisterClientAsSender(main_thread_client_id, kPoisonMessage);
// Setup the paths used by StorageManager.
string fixed_storage_path(quickstep::FLAGS_storage_path);
if (!fixed_storage_path.empty()
&& (fixed_storage_path.back() != quickstep::kPathSeparator)) {
fixed_storage_path.push_back(quickstep::kPathSeparator);
}
string catalog_path(fixed_storage_path);
catalog_path.append("catalog.pb.bin");
if (quickstep::FLAGS_initialize_db) { // Initialize the database
// TODO(jmp): Refactor the code in this file!
LOG(INFO) << "Initializing the database, creating a new catalog file and storage directory\n";
// Create the directory
// TODO(jmp): At some point, likely in C++-17, we will just have the
// filesystem path, and we can clean this up
#ifdef QUICKSTEP_OS_WINDOWS
std::filesystem::create_directories(fixed_storage_path);
LOG(FATAL) << "Failed when attempting to create the directory: " << fixed_storage_path << "\n";
LOG(FATAL) << "Check if the directory already exists. If so, delete it or move it before initializing \n";
#else
{
string path_name = "mkdir " + fixed_storage_path;
if (std::system(path_name.c_str())) {
LOG(FATAL) << "Failed when attempting to create the directory: " << fixed_storage_path << "\n";
}
}
#endif
// Create the default catalog file.
std::ofstream catalog_file(catalog_path);
if (!catalog_file.good()) {
LOG(FATAL) << "ERROR: Unable to open catalog.pb.bin for writing.\n";
}
quickstep::Catalog catalog;
catalog.addDatabase(new quickstep::CatalogDatabase(nullptr, "default"));
if (!catalog.getProto().SerializeToOstream(&catalog_file)) {
LOG(FATAL) << "ERROR: Unable to serialize catalog proto to file catalog.pb.bin\n";
return 1;
}
// Close the catalog file - it will be reopened below by the QueryProcessor.
catalog_file.close();
}
// Setup QueryProcessor, including CatalogDatabase and StorageManager.
std::unique_ptr<QueryProcessor> query_processor;
try {
query_processor.reset(new QueryProcessor(catalog_path, fixed_storage_path));
} catch (const std::exception &e) {
LOG(FATAL) << "FATAL ERROR DURING STARTUP: "
<< e.what()
<< "\nIf you intended to create a new database, "
<< "please use the \"-initialize_db=true\" command line option.";
} catch (...) {
LOG(FATAL) << "NON-STANDARD EXCEPTION DURING STARTUP";
}
// Parse the CPU affinities for workers and the preloader thread, if enabled
// to warm up the buffer pool.
const vector<int> worker_cpu_affinities =
InputParserUtil::ParseWorkerAffinities(real_num_workers,
quickstep::FLAGS_worker_affinities);
const std::size_t num_numa_nodes_covered =
DefaultsConfigurator::GetNumNUMANodesCoveredByWorkers(worker_cpu_affinities);
if (quickstep::FLAGS_preload_buffer_pool) {
std::chrono::time_point<std::chrono::steady_clock> preload_start, preload_end;
preload_start = std::chrono::steady_clock::now();
printf("Preloading the buffer pool ... ");
fflush(stdout);
quickstep::PreloaderThread preloader(*query_processor->getDefaultDatabase(),
query_processor->getStorageManager(),
worker_cpu_affinities.front());
preloader.start();
preloader.join();
preload_end = std::chrono::steady_clock::now();
printf("in %g seconds\n",
std::chrono::duration<double>(preload_end - preload_start).count());
}
Foreman foreman(&bus,
query_processor->getDefaultDatabase(),
query_processor->getStorageManager(),
num_numa_nodes_covered);
// Get the NUMA affinities for workers.
vector<int> cpu_numa_nodes = InputParserUtil::GetNUMANodesForCPUs();
if (cpu_numa_nodes.empty()) {
// libnuma is not present. Assign -1 as the NUMA node for every worker.
cpu_numa_nodes.assign(worker_cpu_affinities.size(), -1);
}
vector<int> worker_numa_nodes;
PtrVector<Worker> workers;
vector<client_id> worker_client_ids;
// Initialize the worker threads.
DCHECK_EQ(static_cast<std::size_t>(real_num_workers),
worker_cpu_affinities.size());
for (std::size_t worker_thread_index = 0;
worker_thread_index < worker_cpu_affinities.size();
++worker_thread_index) {
int numa_node_id = -1;
if (worker_cpu_affinities[worker_thread_index] >= 0) {
// This worker can be NUMA affinitized.
numa_node_id = cpu_numa_nodes[worker_cpu_affinities[worker_thread_index]];
}
worker_numa_nodes.push_back(numa_node_id);
workers.push_back(
new Worker(worker_thread_index, &bus, worker_cpu_affinities[worker_thread_index]));
worker_client_ids.push_back(workers.back().getBusClientID());
}
// TODO(zuyu): Move WorkerDirectory within Shiftboss once the latter is added.
WorkerDirectory worker_directory(worker_cpu_affinities.size(),
worker_client_ids,
worker_numa_nodes);
foreman.setWorkerDirectory(&worker_directory);
// Start the worker threads.
for (Worker &worker : workers) {
worker.start();
}
LineReaderImpl line_reader("quickstep> ",
" ...> ");
std::unique_ptr<SqlParserWrapper> parser_wrapper(new SqlParserWrapper());
std::chrono::time_point<std::chrono::steady_clock> start, end;
for (;;) {
string *command_string = new string();
*command_string = line_reader.getNextCommand();
if (command_string->size() == 0) {
delete command_string;
break;
}
parser_wrapper->feedNextBuffer(command_string);
bool quitting = false;
// A parse error should reset the parser. This is because the thrown quickstep
// SqlError does not do the proper reset work of the YYABORT macro.
bool reset_parser = false;
for (;;) {
ParseResult result = parser_wrapper->getNextStatement();
if (result.condition == ParseResult::kSuccess) {
if (result.parsed_statement->getStatementType() == ParseStatement::kQuit) {
quitting = true;
break;
}
if (result.parsed_statement->getStatementType() == ParseStatement::kCommand) {
try {
quickstep::cli::executeCommand(
*result.parsed_statement,
*(query_processor->getDefaultDatabase()), stdout);
} catch (const quickstep::SqlError &sql_error) {
fprintf(stderr, "%s",
sql_error.formatMessage(*command_string).c_str());
reset_parser = true;
break;
}
continue;
}
std::unique_ptr<QueryHandle> query_handle;
try {
query_handle.reset(query_processor->generateQueryHandle(*result.parsed_statement));
} catch (const quickstep::SqlError &sql_error) {
fprintf(stderr, "%s", sql_error.formatMessage(*command_string).c_str());
reset_parser = true;
break;
}
DCHECK(query_handle->getQueryPlanMutable() != nullptr);
foreman.setQueryPlan(query_handle->getQueryPlanMutable()->getQueryPlanDAGMutable());
foreman.reconstructQueryContextFromProto(query_handle->getQueryContextProto());
try {
start = std::chrono::steady_clock::now();
foreman.start();
foreman.join();
end = std::chrono::steady_clock::now();
const CatalogRelation *query_result_relation = query_handle->getQueryResultRelation();
if (query_result_relation) {
PrintToScreen::PrintRelation(*query_result_relation,
query_processor->getStorageManager(),
stdout);
DropRelation::Drop(*query_result_relation,
query_processor->getDefaultDatabase(),
query_processor->getStorageManager());
}
query_processor->saveCatalog();
printf("Execution time: %g seconds\n",
std::chrono::duration<double>(end - start).count());
} catch (const std::exception &e) {
fprintf(stderr, "QUERY EXECUTION ERROR: %s\n", e.what());
break;
}
printf("Query Complete\n");
} else {
if (result.condition == ParseResult::kError) {
fprintf(stderr, "%s", result.error_message.c_str());
}
reset_parser = true;
break;
}
}
if (quitting) {
break;
} else if (reset_parser) {
parser_wrapper.reset(new SqlParserWrapper());
reset_parser = false;
}
}
// Terminate all workers before exiting.
// The main thread broadcasts poison message to the workers. Each worker dies
// after receiving poison message. The order of workers' death is irrelavant.
MessageStyle style;
style.Broadcast(true);
Address address;
address.All(true);
std::unique_ptr<WorkerMessage> poison_message(WorkerMessage::PoisonMessage());
TaggedMessage poison_tagged_message(poison_message.get(),
sizeof(*poison_message),
kPoisonMessage);
const tmb::MessageBus::SendStatus send_status =
bus.Send(main_thread_client_id,
address,
style,
std::move(poison_tagged_message));
CHECK(send_status == tmb::MessageBus::SendStatus::kOK) <<
"Broadcast message from Foreman to workers failed";
for (Worker &worker : workers) {
worker.join();
}
return 0;
}
void addListener(GUIEngine::ITextBoxWidgetListener* listener)
{
m_listeners.push_back(listener);
}
void KartSelectionScreen::setKartsFromCurrentGroup()
{
RibbonWidget* tabs = getWidget<RibbonWidget>("kartgroups");
assert(tabs != NULL);
std::string selected_kart_group =
tabs->getSelectionIDString(PLAYER_ID_GAME_MASTER);
UserConfigParams::m_last_used_kart_group = selected_kart_group;
// This can happen if addons are removed so that also the previously
// selected kart group is removed. In this case, select the
// 'standard' group
if (selected_kart_group != ALL_KART_GROUPS_ID &&
!kart_properties_manager->getKartsInGroup(selected_kart_group).size())
{
selected_kart_group = DEFAULT_GROUP_NAME;
}
DynamicRibbonWidget* w = getWidget<DynamicRibbonWidget>("karts");
w->clearItems();
int usable_kart_count = 0;
PtrVector<const KartProperties, REF> karts;
for(unsigned int i=0; i<kart_properties_manager->getNumberOfKarts(); i++)
{
const KartProperties* prop = kart_properties_manager->getKartById(i);
// Ignore karts that are not in the selected group
if(selected_kart_group != ALL_KART_GROUPS_ID &&
!prop->isInGroup(selected_kart_group))
continue;
karts.push_back(prop);
}
karts.insertionSort();
for(unsigned int i=0; i<karts.size(); i++)
{
const KartProperties* prop = karts.get(i);
if (PlayerManager::getCurrentPlayer()->isLocked(prop->getIdent()) &&
!m_multiplayer)
{
w->addItem(_("Locked : solve active challenges to gain access to more!"),
ID_LOCKED + prop->getIdent(),
prop->getAbsoluteIconFile(), LOCKED_BADGE,
IconButtonWidget::ICON_PATH_TYPE_ABSOLUTE);
}
else
{
w->addItem(translations->fribidize(prop->getName()),
prop->getIdent(),
prop->getAbsoluteIconFile(), 0,
IconButtonWidget::ICON_PATH_TYPE_ABSOLUTE);
usable_kart_count++;
}
}
// add random
if (usable_kart_count > 1)
{
w->addItem(_("Random Kart"), RANDOM_KART_ID, "/gui/random_kart.png");
}
w->updateItemDisplay();
}
void manualInsertObject(TrackObject* obj)
{
m_all_objects.push_back(obj);
}
void Screen::parseScreenFileDiv(irr::io::IXMLReader* xml, PtrVector<Widget>& append_to,
irr::gui::IGUIElement* parent)
{
// parse XML file
while (xml && xml->read())
{
switch (xml->getNodeType())
{
case irr::io::EXN_TEXT:
{
break;
}
case irr::io::EXN_ELEMENT:
{
/* find which type of widget is specified by the current tag, and instanciate it */
if (wcscmp(L"div", xml->getNodeName()) == 0)
{
Widget* w = new Widget(WTYPE_DIV);
append_to.push_back(w);
}
else if (wcscmp(L"stkgui", xml->getNodeName()) == 0)
{
// outer node that's there only to comply with XML standard (and expat)
continue;
}
else if (wcscmp(L"placeholder", xml->getNodeName()) == 0)
{
Widget* w = new Widget(WTYPE_DIV, true);
append_to.push_back(w);
}
else if (wcscmp(L"box", xml->getNodeName()) == 0)
{
Widget* w = new Widget(WTYPE_DIV);
w->m_show_bounding_box = true;
append_to.push_back(w);
}
else if (wcscmp(L"bottombar", xml->getNodeName()) == 0)
{
Widget* w = new Widget(WTYPE_DIV);
w->m_bottom_bar = true;
append_to.push_back(w);
}
else if (wcscmp(L"topbar", xml->getNodeName()) == 0)
{
Widget* w = new Widget(WTYPE_DIV);
w->m_top_bar = true;
append_to.push_back(w);
}
else if (wcscmp(L"roundedbox", xml->getNodeName()) == 0)
{
Widget* w = new Widget(WTYPE_DIV);
w->m_show_bounding_box = true;
w->m_is_bounding_box_round = true;
append_to.push_back(w);
}
else if (wcscmp(L"ribbon", xml->getNodeName()) == 0)
{
append_to.push_back(new RibbonWidget());
}
else if (wcscmp(L"buttonbar", xml->getNodeName()) == 0)
{
append_to.push_back(new RibbonWidget(RIBBON_TOOLBAR));
}
else if (wcscmp(L"tabs", xml->getNodeName()) == 0)
{
append_to.push_back(new RibbonWidget(RIBBON_TABS));
}
else if (wcscmp(L"spinner", xml->getNodeName()) == 0)
{
append_to.push_back(new SpinnerWidget());
}
else if (wcscmp(L"button", xml->getNodeName()) == 0)
{
append_to.push_back(new ButtonWidget());
}
else if (wcscmp(L"gauge", xml->getNodeName()) == 0)
{
append_to.push_back(new SpinnerWidget(true));
}
else if (wcscmp(L"progressbar", xml->getNodeName()) == 0)
{
append_to.push_back(new ProgressBarWidget());
}
else if (wcscmp(L"icon-button", xml->getNodeName()) == 0)
{
append_to.push_back(new IconButtonWidget());
}
else if (wcscmp(L"icon", xml->getNodeName()) == 0)
{
append_to.push_back(new IconButtonWidget(IconButtonWidget::SCALE_MODE_KEEP_TEXTURE_ASPECT_RATIO,
false, false));
}
else if (wcscmp(L"checkbox", xml->getNodeName()) == 0)
{
append_to.push_back(new CheckBoxWidget());
}
else if (wcscmp(L"label", xml->getNodeName()) == 0)
{
append_to.push_back(new LabelWidget());
}
else if (wcscmp(L"bright", xml->getNodeName()) == 0)
{
append_to.push_back(new LabelWidget(false, true));
}
else if (wcscmp(L"bubble", xml->getNodeName()) == 0)
{
append_to.push_back(new BubbleWidget());
}
else if (wcscmp(L"header", xml->getNodeName()) == 0)
{
append_to.push_back(new LabelWidget(true));
}
else if (wcscmp(L"spacer", xml->getNodeName()) == 0)
{
append_to.push_back(new Widget(WTYPE_SPACER));
}
else if (wcscmp(L"ribbon_grid", xml->getNodeName()) == 0)
{
append_to.push_back(new DynamicRibbonWidget(false /* combo */, true /* multi-row */));
}
else if (wcscmp(L"scrollable_ribbon", xml->getNodeName()) == 0)
{
append_to.push_back(new DynamicRibbonWidget(true /* combo */, false /* multi-row */));
}
else if (wcscmp(L"scrollable_toolbar", xml->getNodeName()) == 0)
{
append_to.push_back(new DynamicRibbonWidget(false /* combo */, false /* multi-row */));
}
else if (wcscmp(L"model", xml->getNodeName()) == 0)
{
append_to.push_back(new ModelViewWidget());
}
else if (wcscmp(L"list", xml->getNodeName()) == 0)
{
append_to.push_back(new ListWidget());
}
else if (wcscmp(L"textbox", xml->getNodeName()) == 0)
{
append_to.push_back(new TextBoxWidget());
}
else
{
std::cerr << "/!\\ Warning /!\\ : unknown tag found in STK GUI file : '"
<< xml->getNodeName() << "'" << std::endl;
continue;
}
/* retrieve the created widget */
Widget& widget = append_to[append_to.size()-1];
/* read widget properties using macro magic */
#define READ_PROPERTY( prop_name, prop_flag ) const wchar_t* prop_name = xml->getAttributeValue( L###prop_name ); \
if(prop_name != NULL) widget.m_properties[prop_flag] = core::stringc(prop_name).c_str(); else widget.m_properties[prop_flag] = ""
READ_PROPERTY(id, PROP_ID);
READ_PROPERTY(proportion, PROP_PROPORTION);
READ_PROPERTY(width, PROP_WIDTH);
READ_PROPERTY(height, PROP_HEIGHT);
READ_PROPERTY(child_width, PROP_CHILD_WIDTH);
READ_PROPERTY(child_height, PROP_CHILD_HEIGHT);
READ_PROPERTY(word_wrap, PROP_WORD_WRAP);
//READ_PROPERTY(grow_with_text, PROP_GROW_WITH_TEXT);
READ_PROPERTY(x, PROP_X);
READ_PROPERTY(y, PROP_Y);
READ_PROPERTY(layout, PROP_LAYOUT);
READ_PROPERTY(align, PROP_ALIGN);
READ_PROPERTY(icon, PROP_ICON);
READ_PROPERTY(focus_icon, PROP_FOCUS_ICON);
READ_PROPERTY(text_align, PROP_TEXT_ALIGN);
READ_PROPERTY(min_value, PROP_MIN_VALUE);
READ_PROPERTY(max_value, PROP_MAX_VALUE);
READ_PROPERTY(square_items, PROP_SQUARE);
READ_PROPERTY(max_width, PROP_MAX_WIDTH);
READ_PROPERTY(max_height, PROP_MAX_HEIGHT);
READ_PROPERTY(extend_label, PROP_EXTEND_LABEL);
READ_PROPERTY(label_location, PROP_LABELS_LOCATION);
READ_PROPERTY(max_rows, PROP_MAX_ROWS);
READ_PROPERTY(wrap_around, PROP_WRAP_AROUND);
#undef READ_PROPERTY
const wchar_t* text = xml->getAttributeValue( L"text" );
if (text != NULL)
{
widget.m_text = _(text);
widget.m_is_text_rtl = (translations->isRTLLanguage() && widget.m_text != text);
}
if (parent != NULL)
{
widget.setParent(parent);
}
/* a new div starts here, continue parsing with this new div as new parent */
if (widget.getType() == WTYPE_DIV || widget.getType() == WTYPE_RIBBON)
{
parseScreenFileDiv( xml, append_to[append_to.size()-1].m_children, parent );
}
}// end case EXN_ELEMENT
break;
case irr::io::EXN_ELEMENT_END:
{
// we're done parsing this 'div', return one step back in the recursive call
if (wcscmp(L"div", xml->getNodeName()) == 0)
return;
if (wcscmp(L"box", xml->getNodeName()) == 0)
return;
if (wcscmp(L"placeholder", xml->getNodeName()) == 0)
return;
if (wcscmp(L"roundedbox", xml->getNodeName()) == 0)
return;
if (wcscmp(L"bottombar", xml->getNodeName()) == 0)
return;
if (wcscmp(L"topbar", xml->getNodeName()) == 0)
return;
// We're done parsing this 'ribbon', return one step back in
// the recursive call.
if (wcscmp(L"ribbon", xml->getNodeName()) == 0 ||
wcscmp(L"buttonbar", xml->getNodeName()) == 0 ||
wcscmp(L"tabs", xml->getNodeName()) == 0)
return;
}
break;
default: break;
}//end switch
} // end while
} // end function
