}
eDVBService::eDVBService()
+ :m_flags(0)
{
}
res = 0;
break;
case eDVBChannelQuery::tSatellitePosition:
- res = (ref.getDVBNamespace().get() >> 16) == query.m_int;
+ res = ((unsigned int)ref.getDVBNamespace().get())>>16 == query.m_int;
break;
case eDVBChannelQuery::tChannelID:
{
case eDVBChannelQuery::tOR:
res = checkFilter(ref, *query.m_p1) || checkFilter(ref, *query.m_p2);
break;
+ case eDVBChannelQuery::tAny:
+ res = 1;
+ break;
}
if (query.m_inverse)
struct stat s;
if ( !stat("lamedb", &s) )
{
- rename("lamedb", CONFIGDIR"/enigma2/lamedb" );
- reloadServicelist();
+ if ( !stat(CONFIGDIR"/enigma2", &s) )
+ {
+ rename("lamedb", CONFIGDIR"/enigma2/lamedb" );
+ reloadServicelist();
+ }
}
return;
}
ter.guard_interval = guard_interval;
ter.hierarchy = hierarchy;
ter.inversion = inversion;
-
feparm->setDVBT(ter);
} else if (line[1]=='c')
{
- int frequency, symbol_rate, inversion=0, modulation=3;
- sscanf(line+2, "%d:%d:%d:%d", &frequency, &symbol_rate, &inversion, &modulation);
-// t.setCable(frequency, symbol_rate, inversion, modulation);
+ eDVBFrontendParametersCable cab;
+ int frequency, symbol_rate,
+ inversion=eDVBFrontendParametersCable::Inversion::Unknown,
+ modulation=eDVBFrontendParametersCable::Modulation::Auto,
+ fec_inner=eDVBFrontendParametersCable::FEC::fAuto;
+ sscanf(line+2, "%d:%d:%d:%d:%d", &frequency, &symbol_rate, &inversion, &modulation, &fec_inner);
+ cab.frequency = frequency;
+ cab.fec_inner = fec_inner;
+ cab.inversion = inversion;
+ cab.symbol_rate = symbol_rate;
+ cab.modulation = modulation;
+ feparm->setDVBC(cab);
}
}
addChannelToList(channelid, feparm);
chid.transport_stream_id.get(), chid.original_network_id.get());
eDVBFrontendParametersSatellite sat;
eDVBFrontendParametersTerrestrial ter;
+ eDVBFrontendParametersCable cab;
if (!ch.m_frontendParameters->getDVBS(sat))
{
fprintf(f, "\ts %d:%d:%d:%d:%d:%d\n",
ter.code_rate_LP, ter.modulation, ter.transmission_mode,
ter.guard_interval, ter.hierarchy, ter.inversion);
}
+ if (!ch.m_frontendParameters->getDVBC(cab))
+ {
+ fprintf(f, "\tc %d:%d:%d:%d:%d\n",
+ cab.frequency, cab.symbol_rate, cab.inversion, cab.modulation, cab.fec_inner);
+ }
fprintf(f, "/\n");
channels++;
}
0);
fprintf(f, "%s\n", i->second->m_service_name.c_str());
+
fprintf(f, "p:%s", i->second->m_provider_name.c_str());
// write cached pids
ca != i->second->m_ca.end(); ++ca)
fprintf(f, ",C:%04x", *ca);
+ if (i->second->m_flags)
+ fprintf(f, ",f:%x", i->second->m_flags);
+
fprintf(f, "\n");
services++;
}
return 0;
}
+eServiceReference eDVBDB::searchReference(int tsid, int onid, int sid)
+{
+ eServiceID Sid(sid);
+ eTransportStreamID Tsid(tsid);
+ eOriginalNetworkID Onid(onid);
+ for (std::map<eServiceReferenceDVB, ePtr<eDVBService> >::iterator sit(m_services.begin());
+ sit != m_services.end(); ++sit)
+ {
+ if (sit->first.getTransportStreamID() == Tsid &&
+ sit->first.getOriginalNetworkID() == Onid &&
+ sit->first.getServiceID() == Sid)
+ return sit->first;
+ }
+ return eServiceReference();
+}
+
DEFINE_REF(eDVBDBQueryBase);
eDVBDBQueryBase::eDVBDBQueryBase(eDVBDB *db, const eServiceReference &source, eDVBChannelQuery *query)
RESULT parseExpression(ePtr<eDVBChannelQuery> &res, std::list<std::string>::const_iterator begin, std::list<std::string>::const_iterator end)
{
std::list<std::string>::const_iterator end_of_exp;
+
+ if (begin == end)
+ {
+ eDebug("empty expression!");
+ return 0;
+ }
+
if (*begin == "(")
{
end_of_exp = begin;
/* now we recursivly parse that. */
int r = parseExpression(res, tokens.begin(), tokens.end());
+ /* we have an empty (but valid!) expression */
+ if (!r && !res)
+ {
+ res = new eDVBChannelQuery();
+ res->m_inverse = 0;
+ res->m_type = eDVBChannelQuery::tAny;
+ }
+
if (res)
{
res->m_sort = sort;