lokinet/llarp/dht/txholder.hpp

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#ifndef LLARP_DHT_TXHOLDER
#define LLARP_DHT_TXHOLDER
#include <dht/tx.hpp>
#include <dht/txowner.hpp>
#include <util/time.hpp>
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#include <util/status.hpp>
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#include <memory>
#include <unordered_map>
namespace llarp
{
namespace dht
{
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template < typename K, typename V, typename K_Hash >
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struct TXHolder
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{
using TXPtr = std::unique_ptr< TX< K, V > >;
// tx who are waiting for a reply for each key
std::unordered_multimap< K, TXOwner, K_Hash > waiting;
// tx timesouts by key
std::unordered_map< K, llarp_time_t, K_Hash > timeouts;
// maps remote peer with tx to handle reply from them
std::unordered_map< TXOwner, TXPtr, TXOwner::Hash > tx;
const TX< K, V >*
GetPendingLookupFrom(const TXOwner& owner) const;
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util::StatusObject
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ExtractStatus() const
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{
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util::StatusObject obj{};
std::vector< util::StatusObject > txObjs, timeoutsObjs, waitingObjs;
std::transform(tx.begin(), tx.end(), std::back_inserter(txObjs),
[](const auto& item) -> util::StatusObject {
return util::StatusObject{
{"owner", item.first.ExtractStatus()},
{"tx", item.second->ExtractStatus()}};
});
obj["tx"] = txObjs;
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std::transform(
timeouts.begin(), timeouts.end(), std::back_inserter(timeoutsObjs),
[](const auto& item) -> util::StatusObject {
return util::StatusObject{{"time", item.second},
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{"target", item.first.ToString()}};
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});
obj["timeouts"] = timeoutsObjs;
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std::transform(waiting.begin(), waiting.end(),
std::back_inserter(waitingObjs),
[](const auto& item) -> util::StatusObject {
return util::StatusObject{
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{"target", item.first.ToString()},
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{"whoasked", item.second.ExtractStatus()}};
});
obj["waiting"] = waitingObjs;
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return obj;
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}
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bool
HasLookupFor(const K& target) const
{
return timeouts.find(target) != timeouts.end();
}
bool
HasPendingLookupFrom(const TXOwner& owner) const
{
return GetPendingLookupFrom(owner) != nullptr;
}
void
NewTX(const TXOwner& askpeer, const TXOwner& whoasked, const K& k,
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TX< K, V >* t, llarp_time_t requestTimeoutMS = 15000);
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/// mark tx as not fond
void
NotFound(const TXOwner& from, const std::unique_ptr< Key_t >& next);
void
Found(const TXOwner& from, const K& k, const std::vector< V >& values)
{
Inform(from, k, values, true);
}
/// inform all watches for key of values found
void
Inform(TXOwner from, K key, std::vector< V > values,
bool sendreply = false, bool removeTimeouts = true);
void
Expire(llarp_time_t now);
};
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template < typename K, typename V, typename K_Hash >
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const TX< K, V >*
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TXHolder< K, V, K_Hash >::GetPendingLookupFrom(const TXOwner& owner) const
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{
auto itr = tx.find(owner);
if(itr == tx.end())
{
return nullptr;
}
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return itr->second.get();
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}
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template < typename K, typename V, typename K_Hash >
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void
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TXHolder< K, V, K_Hash >::NewTX(const TXOwner& askpeer,
const TXOwner& whoasked, const K& k,
TX< K, V >* t,
llarp_time_t requestTimeoutMS)
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{
(void)whoasked;
tx.emplace(askpeer, std::unique_ptr< TX< K, V > >(t));
auto count = waiting.count(k);
waiting.emplace(k, askpeer);
auto itr = timeouts.find(k);
if(itr == timeouts.end())
{
timeouts.emplace(k, time_now_ms() + requestTimeoutMS);
}
if(count == 0)
{
t->Start(askpeer);
}
}
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template < typename K, typename V, typename K_Hash >
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void
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TXHolder< K, V, K_Hash >::NotFound(const TXOwner& from,
const std::unique_ptr< Key_t >& next)
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{
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auto txitr = tx.find(from);
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if(txitr == tx.end())
{
return;
}
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Inform(from, txitr->second->target, {}, true, true);
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}
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template < typename K, typename V, typename K_Hash >
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void
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TXHolder< K, V, K_Hash >::Inform(TXOwner from, K key,
std::vector< V > values, bool sendreply,
bool removeTimeouts)
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{
auto range = waiting.equal_range(key);
auto itr = range.first;
while(itr != range.second)
{
auto txitr = tx.find(itr->second);
if(txitr != tx.end())
{
for(const auto& value : values)
{
txitr->second->OnFound(from.node, value);
}
if(sendreply)
{
txitr->second->SendReply();
tx.erase(txitr);
}
}
++itr;
}
if(sendreply)
{
waiting.erase(key);
}
if(removeTimeouts)
{
timeouts.erase(key);
}
}
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template < typename K, typename V, typename K_Hash >
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void
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TXHolder< K, V, K_Hash >::Expire(llarp_time_t now)
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{
auto itr = timeouts.begin();
while(itr != timeouts.end())
{
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if(now >= itr->second)
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{
Inform(TXOwner{}, itr->first, {}, true, false);
itr = timeouts.erase(itr);
}
else
{
++itr;
}
}
}
} // namespace dht
} // namespace llarp
#endif