/**
* Cartesian product
*/
std::vector<box> box_factory::cartesian_product(std::map<std::string, std::vector<capd::interval>> m)
{
// checking if the map is empty
if(m.empty())
{
return vector<box>{};
}
unsigned long size = 1;
for(auto it = m.cbegin(); it != m.cend(); it++)
{
size *= (it->second).size();
}
std::vector<box> product;
for(unsigned long i = 0; i < size; i++)
{
unsigned long index = i;
std::map<std::string, capd::interval> tmp_m;
for(auto it1 = m.cbegin(); it1 != m.cend(); it1++)
{
unsigned long mult = 1;
for(auto it2 = --m.cend(); it2 != it1; it2--)
{
mult *= (it2->second).size();
}
unsigned long tmp_index = index / mult;
tmp_m.insert(make_pair(it1->first, (it1->second).at(tmp_index)));
index -= tmp_index * mult;
}
product.push_back(box(tmp_m));
}
return product;
}
std::wstring CTestCaseData::GetErrorMessageText() const
{
static std::wstring res;
res = L"unknown message";
auto it = mapEncodingNames.find(iEncoding);
assert(it != mapEncodingNames.cend());
if (it != mapEncodingNames.cend())
{
res = it->second;
}
return res;
}
void print(const std::map<T, P>& container) {
#ifdef _DEBUG
for (auto it = container.cbegin(); it != container.cend();) {
std::cerr << it->first << ": " << it->second;
it++;
if (it != container.cend())
std::cerr << ", ";
}
#endif
}
const IdentifierInfo * Get(
const char * name
) const {
auto it = _identifiers.find(name);
if (it == _identifiers.cend()) return nullptr;
return it->second;
}
// path lookup within registry
Path path( const std::string &key )
{
std::map<std::string, Path>::const_iterator it = g_pathRegistry.find( key );
if( it != g_pathRegistry.cend() )
return it->second;
return Path();
}
void dump_as_list(const int fd) final {
using t = typename std::map<TId, TValue>::value_type;
std::vector<t> v;
v.reserve(m_elements.size());
std::copy(m_elements.cbegin(), m_elements.cend(), std::back_inserter(v));
osmium::io::detail::reliable_write(fd, reinterpret_cast<const char*>(v.data()), sizeof(t) * v.size());
}
std::vector<std::tuple<K, V>> to_vec(std::map<K, V> m)
{
std::vector<std::tuple<K, V>> vec;
for (auto it = m.cbegin(); it != m.cend(); ++it) {
vec.emplace_back(std::make_tuple(it->first, it->second));
}
return vec;
}
int main(int argc, char** argv) {
SkCommandLineFlags::SetUsage(
"Usage: get_images_from_skps -s <dir of skps> -o <dir for output images> --testDecode "
"-j <output JSON path>\n");
SkCommandLineFlags::Parse(argc, argv);
const char* inputs = FLAGS_skps[0];
gOutputDir = FLAGS_out[0];
if (!sk_isdir(inputs) || !sk_isdir(gOutputDir)) {
SkCommandLineFlags::PrintUsage();
return 1;
}
SkOSFile::Iter iter(inputs, "skp");
for (SkString file; iter.next(&file); ) {
SkAutoTDelete<SkStream> stream =
SkStream::NewFromFile(SkOSPath::Join(inputs, file.c_str()).c_str());
sk_sp<SkPicture> picture(SkPicture::MakeFromStream(stream));
SkDynamicMemoryWStream scratch;
Sniffer sniff(file.c_str());
picture->serialize(&scratch, &sniff);
}
int totalUnknowns = 0;
/**
JSON results are written out in the following format:
{
"failures": {
"skp1": 12,
"skp4": 2,
...
},
"totalFailures": 32,
"totalSuccesses": 21,
}
*/
Json::Value fRoot;
for(auto it = gSkpToUnknownCount.cbegin(); it != gSkpToUnknownCount.cend(); ++it)
{
SkDebugf("%s %d\n", it->first.c_str(), it->second);
totalUnknowns += it->second;
fRoot["failures"][it->first.c_str()] = it->second;
}
SkDebugf("%d known, %d unknown\n", gKnown, totalUnknowns);
fRoot["totalFailures"] = totalUnknowns;
fRoot["totalSuccesses"] = gKnown;
if (totalUnknowns > 0) {
if (!FLAGS_failuresJsonPath.isEmpty()) {
SkDebugf("Writing failures to %s\n", FLAGS_failuresJsonPath[0]);
SkFILEWStream stream(FLAGS_failuresJsonPath[0]);
stream.writeText(Json::StyledWriter().write(fRoot).c_str());
stream.flush();
}
return -1;
}
return 0;
}
static inline bbb::json convert(std::map<std::string, type, comp, alloc> &table)
{
std::map<std::string, bbb::json> json_map;
for(auto it = table.cbegin(); it != table.cend(); ++it) {
json_map.emplace(it->first, std::move(convert(it->second)));
}
return json_map;
}
bool removeTexture(const sf::String & alias)
{
ConstTextureIterator texture = textures.find(alias);
if (texture != textures.cend())
{
textures.erase(texture);
return true;
}
return false;
}
bool removeFont(const sf::String & fontAlias)
{
std::map<sf::String, sf::Font>::const_iterator font = fonts.find(fontAlias);
if (font != fonts.cend())
{
fonts.erase(font);
return true;
}
return false;
}
std::vector<std::string> getScraperList()
{
std::vector<std::string> list;
for(auto it = scraper_request_funcs.cbegin(); it != scraper_request_funcs.cend(); it++)
{
list.push_back(it->first);
}
return list;
}
static names_vec get_matching_groups( nameFlags searchFlags )
{
names_vec matching_groups;
for( auto it = names.cbegin(), end = names.cend(); it != end; ++it ) {
const nameFlags type = it->first;
if( ( searchFlags & type ) == searchFlags ) {
matching_groups.push_back( it );
}
}
return matching_groups;
}
const std::string &name_by_dt( const damage_type &dt )
{
auto iter = dt_map.cbegin();
while( iter != dt_map.cend() ) {
if( iter->second == dt ) {
return iter->first;
}
iter++;
}
static const std::string err_msg( "dt_not_found" );
return err_msg;
}
std::vector<int> find_vertical_sum(Node* node) {
void vertical_sum_rec(Node* node, int index);
vertical_sum_rec(node, 0);
std::vector<int> result;
// this is still not supported
//for (auto it:vert_sum) {
for (auto it = vert_sum.cbegin(); it != vert_sum.cend(); ++it)
result.push_back(it->second);
return result;
}
static optional<std::pair<const std::string&, const variable&>> is_builtin_variable(const id& vid) {
typedef std::pair<std::string, std::reference_wrapper<const variable>> var_pair;
static const std::map<id, var_pair> names {
{ gl_NumWorkGroups.variable_id, var_pair{ "gl_NumWorkGroups", gl_NumWorkGroups } },
{ gl_WorkGroupID.variable_id, var_pair{ "gl_WorkGroupID", gl_WorkGroupID } },
{ gl_LocalInvocationID.variable_id, var_pair{ "gl_LocalInvocationID", gl_LocalInvocationID } },
{ gl_GlobalInvocationID.variable_id, var_pair{ "gl_GlobalInvocationID", gl_GlobalInvocationID } },
{ gl_LocalInvocationIndex.variable_id, var_pair{ "gl_LocalInvocationIndex", gl_LocalInvocationIndex } }
};
auto v = names.find(vid);
if (v == names.cend())
return nullopt;
return optional<std::pair<const std::string&, const variable&>>(in_place, v->second.first, v->second.second);
}
//fills lst or const_lst (depending on which is null) with all borrowers with specified name
static void findByName_helper(const std::map<unsigned int, Borrower>& borrowers, const std::string name,
list<Borrower*const> *const lst, list<const Borrower*const> *const const_lst){
borrowers_citer iter = borrowers.cbegin();
while (iter != borrowers.cend())
{
if (iter->second.getName() == name)
{
const_lst == NULL ? lst->push_back(const_cast<Borrower*>(&iter->second)) : const_lst->push_back(&iter->second);
}
iter++;
}
}
// assuming the namenode id is 0
void GetServerIDsFromHostMap(std::vector<int32_t> *server_ids,
const std::map<int32_t, HostInfo>& host_map){
int32_t num_servers = host_map.size() - 1;
server_ids->resize(num_servers);
int32_t i = 0;
for (auto host_info_iter = host_map.cbegin();
host_info_iter != host_map.cend(); host_info_iter++) {
if (host_info_iter->first == 0)
continue;
(*server_ids)[i] = host_info_iter->first;
++i;
}
}
const std::string
get_mime_type(const std::string & filePath)
{
const char *defMimeType = "application/octet-stream";
size_t extPos = filePath.rfind('.');
if (extPos == std::string::npos || (extPos == filePath.length() - 1))
return defMimeType;
std::map<std::string, std::string>::const_iterator it = mimeTypes.find(filePath.substr(extPos + 1));
if (it == mimeTypes.cend())
return defMimeType;
return it->second;
}
std::string optionsToString(std::map<std::string, std::string> const &options) {
if (!options.empty()) {
std::ostringstream resultStream;
auto optionsKvpIt = options.cbegin();
auto const &firstKvp = (*optionsKvpIt);
resultStream << firstKvp.first << "='" << firstKvp.second << '\'';
for (; optionsKvpIt != options.cend(); ++optionsKvpIt) {
auto kvp = (*optionsKvpIt);
resultStream << ", " << kvp.first << "='" << kvp.second << '\'';
}
return resultStream.str();
} else {
return std::string();
}
}
int MeshInfoSet::InitializeMeshNeiboNum(const std::map<MeshPair, int>& meshPair, std::map<int, std::vector<std::pair<int, int>>>& meshNeiboNum)
{
int rtn = 0;
meshNeiboNum.clear();
for (map<MeshPair, int>::const_iterator it = meshPair.cbegin(); it != meshPair.cend(); ++it)
{
rtn = AddMeshNeiboNum(it->first.first, it->first.second, it->second, meshNeiboNum);
CHECK_RTN(rtn);
rtn = AddMeshNeiboNum(it->first.second, it->first.first, it->second, meshNeiboNum);
CHECK_RTN(rtn);
}
for (map<int, vector<pair<int, int>>>::iterator it = meshNeiboNum.begin(); it != meshNeiboNum.end(); ++it)
sort(it->second.begin(), it->second.end(), CmpPairByLagerSecond<int, int>);
return 0;
}
//Any literal that is larger than maxvar was newly introduced by the transformation, so should be mapped to nVars()+lit
Lit mapFromPBLit(MiniSatPP::Lit lit, int maxopbvar, PCSolver& pcsolver, std::map<Atom, Atom>& opbinternal2pcsolver){
auto var = MiniSatPP::var(lit);
if(var <= maxopbvar){
return mkLit(var, sign(lit));
}else{
auto it = opbinternal2pcsolver.find(var);
if(it==opbinternal2pcsolver.cend()){
auto newv = pcsolver.newAtom();
opbinternal2pcsolver[var] = newv;
var = newv;
}else{
var = it->second;
}
return mkLit(var, sign(lit));
}
}
void remove_vertex(const T x)
{
const auto iterator = vertices.find(x);
if(iterator == vertices.cend())
return;
const size_t i = iterator->second;
vertices.erase(x);
empty_spots.push(i);
edges.at(i).clear();
for(auto& e : edges)
e.erase(i);
}
void garbage_collection()
{
for (auto i = rx_pkt_queue.cbegin(); i != rx_pkt_queue.cend(); /* NO INCREMENT*/)
{
if (i->second->id <= last_fw_id)
{
#ifdef VERBOSE
printf("Erasing pkt with id=%u, last_fw_id %u\n", i->first, last_fw_id);
#endif
rx_pkt_queue.erase(i++);
}
else
{
++i;
}
}
}
/**
* Function: wakeSleepingThreads
* Iterates over all threads alive and wakes them up if needed.
* If a thread is awaken it is added to the READY list.
*/
void wakeSleepingThreads()
{
uthread *curr;
// Add waking threads to READY list
for (auto th=livingThreads.cbegin(); th != livingThreads.cend(); ++th)
{
// curr is the current thread in the for loop
curr = th->second;
// If the thread is sleeping and it should wake up, wake it up
if (curr->get_state() == uthread::state::SLEEPING &&
uthread_get_time_until_wakeup(curr->get_id())==SHOULD_WAKE)
{
curr->set_state(uthread::state::READY);
readyThreads.push_back(curr->get_id());
}
}
}
bool getTokenKeyword(const std::string& token, const std::string& name, const std::map<std::string, int>& map, int& value)
{
if (token.size() < name.size() + 2 ||
token.substr(0, name.size()) != name ||
token[name.size()] != '=')
return false;
std::string t = token.substr(name.size()+1);
if (t[0] == '\'' && t[t.size()-1] == '\'')
t = t.substr(1, t.size()-2);
auto p = map.find(t);
if (p == map.cend())
return false;
value = p->second;
return true;
}
bool check_types(const std::map<std::string, uint16_t>& expected) {
// holds the type names we see at runtime
std::map<std::string, uint16_t> found;
// fetch all available type names
auto types = uniform_type_info::instances();
for (auto tinfo : types) {
found.insert(std::make_pair(tinfo->name(), tinfo->type_nr()));
}
// compare the two maps
if (expected == found) {
CAF_CHECKPOINT();
return true;
}
CAF_CHECK(false);
using const_iterator = std::map<std::string, uint16_t>::const_iterator;
using std::setw;
using std::left;
std::ostringstream oss;
oss << left << setw(20) << ("found (" + tostr(found.size(), 1) + ")")
<< " | expected (" << expected.size() << ")";
CAF_PRINT(oss.str());
oss.seekp(0);
oss << std::setfill('-') << setw(22) << "" << "|" << setw(22) << "";
CAF_PRINT(oss.str());
auto fi = found.cbegin();
auto fe = found.cend();
auto ei = expected.cbegin();
auto ee = expected.cend();
std::string dummy(20, ' ');
auto out = [&](const_iterator& i, const_iterator last) -> std::string {
if (i == last) {
return dummy;
}
std::ostringstream tmp;
tmp << left << setw(16) << i->first << "[" << tostr(i->second) << "]";
++i;
return tmp.str();
};
while (fi != fe || ei != ee) {
CAF_PRINT(out(fi, fe) << " | " << out(ei, ee));
}
return false;
}
void check_martialarts()
{
for( auto style = martialarts.cbegin(); style != martialarts.cend(); ++style ) {
for( auto technique = style->second.techniques.cbegin();
technique != style->second.techniques.cend(); ++technique ) {
if( ma_techniques.find( *technique ) == ma_techniques.end() ) {
debugmsg( "Technique with id %s in style %s doesn't exist.",
technique->c_str(), style->second.name.c_str() );
}
}
for( auto weapon = style->second.weapons.cbegin();
weapon != style->second.weapons.cend(); ++weapon ) {
if( !item::type_is_defined( *weapon ) ) {
debugmsg( "Weapon %s in style %s doesn't exist.",
weapon->c_str(), style->second.name.c_str() );
}
}
}
}
int main()
{
const std::map< int, std::vector<double> > map =
{
{ 247, { 1.2, 2.3, 3.4, 4.5 } },
{ 106, { 5.6, 6.7, 7.8, 8.9, 9.1, 1.2, 2.3 } },
{ 184, { 3.4, 4.5 } }
};
{
// option 1: range-based loops
for( const auto& pair : map )
{
std::cout << "key: " << pair.first << " value: [ " ;
for( double d : pair.second ) std::cout << d << " " ;
std::cout << "]\n" ;
}
}
std::cout << "----------------\n" ;
{
// option 2: iterators
for( auto map_iter = map.cbegin() ; map_iter != map.cend() ; ++map_iter )
{
std::cout << "key: " << map_iter->first << " value: [ " ;
for( auto vec_iter = map_iter->second.cbegin() ; vec_iter != map_iter->second.cend() ; ++vec_iter )
std::cout << *vec_iter << " " ;
std::cout << "]\n" ;
}
}
std::cout << "----------------\n" ;
{
// option 3: range-based loop for map, subscript operator for vector
for( const auto& pair : map )
{
std::cout << "key: " << pair.first << " value: [ " ;
for( std::size_t i = 0 ; i < pair.second.size() ; ++i ) std::cout << pair.second[i] << " " ;
std::cout << "]\n" ;
}
}
// options 4, 5 ...
}
DRAWABLE_PTR_CONTAINER_TEMPLATE_CPP
const model_map ModelData::readModelList(GLFWwindow* window, const std::map<std::string, std::string>& fileNamesAndPaths, const DescriptorType descType){
model_map models;
std::map<std::string, std::string>::const_iterator it;
// Start to asynchronously load models
for (it = fileNamesAndPaths.cbegin(); it != fileNamesAndPaths.cend(); ++it){
models.emplace(it->first, new ModelData(it->second, false, descType)); // Do not create voxel space, also
}
// Wait for individual models to load
std::map<std::string, ModelData*>::const_iterator m_i;
for (m_i = models.cbegin(); m_i != models.cend(); ++m_i){
Framework::GL::initObjectToDraw(m_i->second, window);
}
Framework::ModelUtils::updateModelTransforms(models);
return models;
}
