void Codec20::writeExpirationParams(transport::Transport& t,uint64_t lifespan, uint64_t maxIdle) const {
uint32_t lInt= (uint32_t) lifespan;
uint32_t mInt= (uint32_t) maxIdle;
if ( lInt != lifespan)
throw HotRodClientException("lifespan exceed 32bit integer");
if ( mInt != maxIdle)
throw HotRodClientException("maxIdle exceed 32bit integer");
t.writeVInt(lInt);
t.writeVInt(mInt);
}
std::vector<char> Codec20::returnPossiblePrevValue(transport::Transport& t, uint8_t status, uint32_t /*flags*/) const{
std::vector<char> result;
if (HotRodConstants::hasPrevious(status)) {
TRACEBYTES("return value = ", result);
result = t.readArray();
} else {
TRACE("No return value");
}
return result;
}
ClientCacheEntryExpiredEvent<std::vector<char>> Codec21::readExpiredEvent(transport::Transport &transport) const
{
std::vector<char> key = transport.readArray();
return ClientCacheEntryExpiredEvent<std::vector<char>>(key);
}
void Codec21::writeClientListenerParams(transport::Transport& t, const ClientListener& clientListener,
const std::vector<std::vector<char> > &filterFactoryParams, const std::vector<std::vector<char> > &converterFactoryParams) const
{
Codec20::writeClientListenerParams(t,clientListener, filterFactoryParams, converterFactoryParams);
t.writeByte((short)(clientListener.useRawData ? 1 : 0));
}