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openmonero/src/CurrentBlockchainStatus.cpp

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//
// Created by mwo on 7/01/17.
//
#include "CurrentBlockchainStatus.h"
#include "tools.h"
#include "mylmdb.h"
#include "rpccalls.h"
#include "MySqlAccounts.h"
#include "ssqlses.h"
namespace xmreg
{
// initialize static variables
atomic<uint64_t> CurrentBlockchainStatus::current_height{0};
string CurrentBlockchainStatus::blockchain_path{"/home/mwo/.blockchain/lmdb"};
string CurrentBlockchainStatus::deamon_url{"http:://127.0.0.1:18081"};
bool CurrentBlockchainStatus::testnet{false};
bool CurrentBlockchainStatus::is_running{false};
std::thread CurrentBlockchainStatus::m_thread;
uint64_t CurrentBlockchainStatus::refresh_block_status_every_seconds{60};
xmreg::MicroCore CurrentBlockchainStatus::mcore;
cryptonote::Blockchain *CurrentBlockchainStatus::core_storage;
vector<transaction> CurrentBlockchainStatus::mempool_txs;
string CurrentBlockchainStatus::import_payment_address;
string CurrentBlockchainStatus::import_payment_viewkey;
uint64_t CurrentBlockchainStatus::import_fee {10000000000}; // 0.01 xmr
account_public_address CurrentBlockchainStatus::address;
secret_key CurrentBlockchainStatus::viewkey;
map<string, shared_ptr<TxSearch>> CurrentBlockchainStatus::searching_threads;
void
CurrentBlockchainStatus::start_monitor_blockchain_thread()
{
bool testnet = CurrentBlockchainStatus::testnet;
if (!import_payment_address.empty() && !import_payment_viewkey.empty())
{
if (!xmreg::parse_str_address(
import_payment_address,
address,
testnet))
{
cerr << "Cant parse address_str: "
<< import_payment_address
<< endl;
return;
}
if (!xmreg::parse_str_secret_key(
import_payment_viewkey,
viewkey))
{
cerr << "Cant parse the viewkey_str: "
<< import_payment_viewkey
<< endl;
return;
}
}
if (!is_running)
{
m_thread = std::thread{[]()
{
while (true)
{
current_height = get_current_blockchain_height();
read_mempool();
cout << "Check block height: " << current_height;
cout << " no of mempool txs: " << mempool_txs.size();
cout << endl;
clean_search_thread_map();
std::this_thread::sleep_for(std::chrono::seconds(refresh_block_status_every_seconds));
}
}};
is_running = true;
}
}
uint64_t
CurrentBlockchainStatus::get_current_blockchain_height()
{
return xmreg::MyLMDB::get_blockchain_height(blockchain_path) - 1;
}
void
CurrentBlockchainStatus::set_blockchain_path(const string &path)
{
blockchain_path = path;
}
void
CurrentBlockchainStatus::set_testnet(bool is_testnet)
{
testnet = is_testnet;
}
bool
CurrentBlockchainStatus::init_monero_blockchain()
{
// enable basic monero log output
xmreg::enable_monero_log();
// initialize mcore and core_storage
if (!xmreg::init_blockchain(blockchain_path,
mcore, core_storage))
{
cerr << "Error accessing blockchain." << endl;
return false;
}
return true;
}
bool
CurrentBlockchainStatus::get_block(uint64_t height, block &blk)
{
return mcore.get_block_from_height(height, blk);
}
bool
CurrentBlockchainStatus::get_block_txs(const block &blk, list <transaction> &blk_txs)
{
// get all transactions in the block found
// initialize the first list with transaction for solving
// the block i.e. coinbase tx.
blk_txs.push_back(blk.miner_tx);
list <crypto::hash> missed_txs;
if (!core_storage->get_transactions(blk.tx_hashes, blk_txs, missed_txs)) {
cerr << "Cant get transactions in block: " << get_block_hash(blk) << endl;
return false;
}
return true;
}
bool
CurrentBlockchainStatus::get_output_keys(const uint64_t& amount,
const vector<uint64_t>& absolute_offsets,
vector<cryptonote::output_data_t>& outputs)
{
try
{
core_storage->get_db().get_output_key(amount,
absolute_offsets,
outputs);
}
catch (const OUTPUT_DNE& e)
{
cerr << "get_output_keys: " << e.what() << endl;
return false;
}
return true;
}
bool
CurrentBlockchainStatus::get_amount_specific_indices(const crypto::hash& tx_hash,
vector<uint64_t>& out_indices)
{
try
{
// this index is lmdb index of a tx, not tx hash
uint64_t tx_index;
if (core_storage->get_db().tx_exists(tx_hash, tx_index))
{
out_indices = core_storage->get_db()
.get_tx_amount_output_indices(tx_index);
return true;
}
}
catch(const exception& e)
{
cerr << e.what() << endl;
}
return false;
}
bool
CurrentBlockchainStatus::get_random_outputs(const vector<uint64_t>& amounts,
const uint64_t& outs_count,
vector<COMMAND_RPC_GET_RANDOM_OUTPUTS_FOR_AMOUNTS::outs_for_amount>& found_outputs)
{
rpccalls rpc {deamon_url};
string error_msg;
if (!rpc.get_random_outs_for_amounts(amounts, outs_count, found_outputs, error_msg))
{
cerr << "rpc.get_random_outs_for_amounts failed" << endl;
return false;
}
return true;
}
bool
CurrentBlockchainStatus::commit_tx(const string& tx_blob)
{
rpccalls rpc {deamon_url};
string error_msg;
if (!rpc.commit_tx(tx_blob, error_msg))
{
cerr << "commit_tx failed" << endl;
return false;
}
return true;
}
bool
CurrentBlockchainStatus::read_mempool()
{
rpccalls rpc {deamon_url};
string error_msg;
std::lock_guard<std::mutex> lck (getting_mempool_txs);
// clear current mempool txs vector
// repopulate it with each execution of read_mempool()
// not very efficient but good enough for now.
mempool_txs.clear();
// get txs in the mempool
std::vector<tx_info> mempool_tx_info;
if (!rpc.get_mempool(mempool_tx_info))
{
cerr << "Getting mempool failed " << endl;
return false;
}
// if dont have tx_blob member, construct tx
// from json obtained from the rpc call
for (size_t i = 0; i < mempool_tx_info.size(); ++i)
{
// get transaction info of the tx in the mempool
tx_info _tx_info = mempool_tx_info.at(i);
crypto::hash mem_tx_hash = null_hash;
if (hex_to_pod(_tx_info.id_hash, mem_tx_hash))
{
transaction tx;
if (!xmreg::make_tx_from_json(_tx_info.tx_json, tx))
{
cerr << "Cant make tx from _tx_info.tx_json" << endl;
return false;
}
if (_tx_info.id_hash != pod_to_hex(get_transaction_hash(tx)))
{
cerr << "Hash of reconstructed tx from json does not match "
"what we should get!"
<< endl;
return false;
}
mempool_txs.push_back(tx);
} // if (hex_to_pod(_tx_info.id_hash, mem_tx_hash))
} // for (size_t i = 0; i < mempool_tx_info.size(); ++i)
return true;
}
vector<transaction>
CurrentBlockchainStatus::get_mempool_txs()
{
std::lock_guard<std::mutex> lck (getting_mempool_txs);
return mempool_txs;
}
bool
CurrentBlockchainStatus::search_if_payment_made(
const string& payment_id_str,
const uint64_t& desired_amount,
string& tx_hash_with_payment)
{
vector<transaction> txs_to_check = get_mempool_txs();
uint64_t current_blockchain_height = current_height;
// apend txs in last to blocks into the txs_to_check vector
for (uint64_t blk_i = current_blockchain_height - 10;
blk_i <= current_blockchain_height;
++blk_i)
{
// get block cointaining this tx
block blk;
if (!get_block(blk_i, blk)) {
cerr << "Cant get block of height: " + to_string(blk_i) << endl;
return false;
}
list <cryptonote::transaction> blk_txs;
if (!get_block_txs(blk, blk_txs))
{
cerr << "Cant get transactions in block: " << to_string(blk_i) << endl;
return false;
}
txs_to_check.insert(txs_to_check.end(), blk_txs.begin(), blk_txs.end());
}
for (transaction& tx: txs_to_check)
{
if (is_coinbase(tx))
{
// not interested in coinbase txs
continue;
}
string tx_payment_id_str = get_payment_id_as_string(tx);
if (payment_id_str != tx_payment_id_str)
{
// check tx having specific payment id only
continue;
}
public_key tx_pub_key = xmreg::get_tx_pub_key_from_received_outs(tx);
// <public_key , amount , out idx>
vector<tuple<txout_to_key, uint64_t, uint64_t>> outputs;
outputs = get_ouputs_tuple(tx);
// for each output, in a tx, check if it belongs
// to the given account of specific address and viewkey
// public transaction key is combined with our viewkey
// to create, so called, derived key.
key_derivation derivation;
if (!generate_key_derivation(tx_pub_key, viewkey, derivation))
{
cerr << "Cant get derived key for: " << "\n"
<< "pub_tx_key: " << tx_pub_key << " and "
<< "prv_view_key" << viewkey << endl;
return false;
}
string tx_hash_str = pod_to_hex(get_transaction_hash(tx));
uint64_t total_received {0};
for (auto& out: outputs)
{
txout_to_key txout_k = std::get<0>(out);
uint64_t amount = std::get<1>(out);
uint64_t output_idx_in_tx = std::get<2>(out);
// get the tx output public key
// that normally would be generated for us,
// if someone had sent us some xmr.
public_key generated_tx_pubkey;
derive_public_key(derivation,
output_idx_in_tx,
address.m_spend_public_key,
generated_tx_pubkey);
// check if generated public key matches the current output's key
bool mine_output = (txout_k.key == generated_tx_pubkey);
if (mine_output)
{
total_received += amount;
}
}
cout << " - payment id check in tx: "
<< tx_hash_str
<< " found: " << total_received << endl;
if (total_received >= desired_amount)
{
// the payment has been made.
tx_hash_with_payment = tx_hash_str;
return true;
}
}
return false;
}
string
CurrentBlockchainStatus::get_payment_id_as_string(const transaction& tx)
{
crypto::hash payment_id = null_hash;
crypto::hash8 payment_id8 = null_hash8;
get_payment_id(tx, payment_id, payment_id8);
string payment_id_str{""};
if (payment_id != null_hash)
{
payment_id_str = pod_to_hex(payment_id);
}
else if (payment_id8 != null_hash8)
{
payment_id_str = pod_to_hex(payment_id8);
}
return payment_id_str;
}
bool
CurrentBlockchainStatus::start_tx_search_thread(XmrAccount acc)
{
std::lock_guard<std::mutex> lck (searching_threads_map_mtx);
if (searching_threads.count(acc.address) > 0)
{
// thread for this address exist, dont make new one
cout << "Thread exisist, dont make new one" << endl;
return false;
}
// make a tx_search object for the given xmr account
searching_threads[acc.address] = make_shared<TxSearch>(acc);
// start the thread for the created object
std::thread t1 {&TxSearch::search, searching_threads[acc.address].get()};
t1.detach();
return true;
}
bool
CurrentBlockchainStatus::ping_search_thread(const string& address)
{
std::lock_guard<std::mutex> lck (searching_threads_map_mtx);
if (searching_threads.count(address) == 0)
{
// thread does not exist
cout << "does not exist" << endl;
return false;
}
searching_threads[address].get()->ping();
return true;
}
bool
CurrentBlockchainStatus::set_new_searched_blk_no(const string& address, uint64_t new_value)
{
std::lock_guard<std::mutex> lck (searching_threads_map_mtx);
if (searching_threads.count(address) == 0)
{
// thread does not exist
cout << " thread does not exist" << endl;
return false;
}
searching_threads[address].get()->set_searched_blk_no(new_value);
return true;
}
void
CurrentBlockchainStatus::clean_search_thread_map()
{
std::lock_guard<std::mutex> lck (searching_threads_map_mtx);
for (auto st: searching_threads)
{
if (st.second->still_searching() == false)
{
cout << st.first << " still searching: " << st.second->still_searching() << endl;
searching_threads.erase(st.first);
}
}
}
TxSearch::TxSearch(XmrAccount& _acc)
{
acc = make_shared<XmrAccount>(_acc);
xmr_accounts = make_shared<MySqlAccounts>();
bool testnet = CurrentBlockchainStatus::testnet;
if (!xmreg::parse_str_address(acc->address, address, testnet))
{
cerr << "Cant parse string address: " << acc->address << endl;
throw TxSearchException("Cant parse string address: " + acc->address);
}
if (!xmreg::parse_str_secret_key(acc->viewkey, viewkey))
{
cerr << "Cant parse the private key: " << acc->viewkey << endl;
throw TxSearchException("Cant parse private key: " + acc->viewkey);
}
// start searching from last block that we searched for
// this accont
searched_blk_no = acc->scanned_block_height;
ping();
}
void
TxSearch::search()
{
if (searched_blk_no > CurrentBlockchainStatus::current_height)
{
throw TxSearchException("searched_blk_no > CurrentBlockchainStatus::current_height");
}
uint64_t current_timestamp = chrono::duration_cast<chrono::seconds>(
chrono::system_clock::now().time_since_epoch()).count();
uint64_t loop_idx {0};
while(continue_search)
{
++loop_idx;
uint64_t loop_timestamp {current_timestamp};
if (loop_idx % 2 == 0)
{
// get loop time every second iteration. no need to call it
// all the time.
loop_timestamp = chrono::duration_cast<chrono::seconds>(
chrono::system_clock::now().time_since_epoch()).count();
//cout << "loop_timestamp: " << loop_timestamp << endl;
//cout << "last_ping_timestamp: " << last_ping_timestamp << endl;
//cout << "loop_timestamp - last_ping_timestamp: " << (loop_timestamp - last_ping_timestamp) << endl;
if (loop_timestamp - last_ping_timestamp > THREAD_LIFE_DURATION)
{
// also check if we caught up with current blockchain height
if (searched_blk_no == CurrentBlockchainStatus::current_height)
{
stop();
continue;
}
}
}
if (searched_blk_no > CurrentBlockchainStatus::current_height) {
fmt::print("searched_blk_no {:d} and current_height {:d}\n",
searched_blk_no, CurrentBlockchainStatus::current_height);
std::this_thread::sleep_for(
std::chrono::seconds(
CurrentBlockchainStatus::refresh_block_status_every_seconds)
);
continue;
}
//
//cout << " - searching tx of: " << acc << endl;
// get block cointaining this tx
block blk;
if (!CurrentBlockchainStatus::get_block(searched_blk_no, blk)) {
cerr << "Cant get block of height: " + to_string(searched_blk_no) << endl;
//searched_blk_no = -2; // just go back one block, and retry
continue;
}
// for each tx in the given block look, get ouputs
list <cryptonote::transaction> blk_txs;
if (!CurrentBlockchainStatus::get_block_txs(blk, blk_txs)) {
throw TxSearchException("Cant get transactions in block: " + to_string(searched_blk_no));
}
if (searched_blk_no % 100 == 0)
{
// print status every 10th block
fmt::print(" - searching block {:d} of hash {:s} \n",
searched_blk_no, pod_to_hex(get_block_hash(blk)));
}
// searching for our incoming and outgoing xmr has two componotes.
//
// FIRST. to search for the incoming xmr, we use address, viewkey and
// outputs public key. Its stright forward.
// second. searching four our spendings is trickier, as we dont have
//
// SECOND. But what we can do, we can look for condidate spend keys.
// and this can be achieved by checking if any mixin in associated with
// the given image, is our output. If it is our output, than we assume
// its our key image (i.e. we spend this output). Off course this is only
// assumption as our outputs can be used in key images of others for their
// mixin purposes. Thus, we sent to the front end, the list of key images
// that we think are yours, and the frontend, because it has spend key,
// can filter out false positives.
for (transaction& tx: blk_txs)
{
crypto::hash tx_hash = get_transaction_hash(tx);
crypto::hash tx_prefix_hash = get_transaction_prefix_hash(tx);
string tx_hash_str = pod_to_hex(tx_hash);
string tx_prefix_hash_str = pod_to_hex(tx_prefix_hash);
bool is_coinbase_tx = is_coinbase(tx);
vector<uint64_t> amount_specific_indices;
// cout << pod_to_hex(tx_hash) << endl;
public_key tx_pub_key = xmreg::get_tx_pub_key_from_received_outs(tx);
// <public_key , amount , out idx>
vector<tuple<txout_to_key, uint64_t, uint64_t>> outputs;
outputs = get_ouputs_tuple(tx);
// for each output, in a tx, check if it belongs
// to the given account of specific address and viewkey
// public transaction key is combined with our viewkey
// to create, so called, derived key.
key_derivation derivation;
if (!generate_key_derivation(tx_pub_key, viewkey, derivation))
{
cerr << "Cant get derived key for: " << "\n"
<< "pub_tx_key: " << tx_pub_key << " and "
<< "prv_view_key" << viewkey << endl;
throw TxSearchException("");
}
uint64_t total_received {0};
// FIRST component: Checking for our outputs.
// <out_pub_key, amount , index in tx>
vector<tuple<string, uint64_t, uint64_t>> found_mine_outputs;
for (auto& out: outputs)
{
txout_to_key txout_k = std::get<0>(out);
uint64_t amount = std::get<1>(out);
uint64_t output_idx_in_tx = std::get<2>(out);
// get the tx output public key
// that normally would be generated for us,
// if someone had sent us some xmr.
public_key generated_tx_pubkey;
derive_public_key(derivation,
output_idx_in_tx,
address.m_spend_public_key,
generated_tx_pubkey);
// check if generated public key matches the current output's key
bool mine_output = (txout_k.key == generated_tx_pubkey);
//cout << "Chekcing output: " << pod_to_hex(txout_k.key) << " "
// << "mine_output: " << mine_output << endl;
// if mine output has RingCT, i.e., tx version is 2
// need to decode its amount. otherwise its zero.
if (mine_output && tx.version == 2)
{
// initialize with regular amount
uint64_t rct_amount = amount;
// cointbase txs have amounts in plain sight.
// so use amount from ringct, only for non-coinbase txs
if (!is_coinbase_tx)
{
bool r;
r = decode_ringct(tx.rct_signatures,
tx_pub_key,
viewkey,
output_idx_in_tx,
tx.rct_signatures.ecdhInfo[output_idx_in_tx].mask,
rct_amount);
if (!r)
{
cerr << "Cant decode ringCT!" << endl;
throw TxSearchException("Cant decode ringCT!");
}
rct_amount = amount;
}
amount = rct_amount;
} // if (mine_output && tx.version == 2)
if (mine_output)
{
string out_key_str = pod_to_hex(txout_k.key);
// found an output associated with the given address and viewkey
string msg = fmt::format("block: {:d}, tx_hash: {:s}, output_pub_key: {:s}\n",
searched_blk_no,
pod_to_hex(tx_hash),
out_key_str);
cout << msg << endl;
total_received += amount;
found_mine_outputs.emplace_back(out_key_str,
amount,
output_idx_in_tx);
}
} // for (const auto& out: outputs)
DateTime blk_timestamp_mysql_format
= XmrTransaction::timestamp_to_DateTime(blk.timestamp);
uint64_t tx_mysql_id {0};
if (!found_mine_outputs.empty())
{
// before adding this tx and its outputs to mysql
// check if it already exists. So that we dont
// do it twice.
XmrTransaction tx_data;
if (xmr_accounts->tx_exists(acc->id, tx_hash_str, tx_data))
{
cout << "\nTransaction " << tx_hash_str
<< " already present in mysql"
<< endl;
continue;
}
tx_data.hash = tx_hash_str;
tx_data.prefix_hash = tx_prefix_hash_str;
tx_data.account_id = acc->id;
tx_data.total_received = total_received;
tx_data.total_sent = 0; // at this stage we don't have any
// info about spendings
tx_data.unlock_time = 0;
tx_data.height = searched_blk_no;
tx_data.coinbase = is_coinbase_tx;
tx_data.payment_id = CurrentBlockchainStatus::get_payment_id_as_string(tx);
tx_data.mixin = get_mixin_no(tx) - 1;
tx_data.timestamp = blk_timestamp_mysql_format;
// insert tx_data into mysql's Transactions table
tx_mysql_id = xmr_accounts->insert_tx(tx_data);
// get amount specific (i.e., global) indices of outputs
if (!CurrentBlockchainStatus::get_amount_specific_indices(tx_hash,
amount_specific_indices))
{
cerr << "cant get_amount_specific_indices!" << endl;
throw TxSearchException("cant get_amount_specific_indices!");
}
if (tx_mysql_id == 0)
{
//cerr << "tx_mysql_id is zero!" << endl;
//throw TxSearchException("tx_mysql_id is zero!");
}
// now add the found outputs into Outputs tables
for (auto &out_k_idx: found_mine_outputs)
{
XmrOutput out_data;
out_data.account_id = acc->id;
out_data.tx_id = tx_mysql_id;
out_data.out_pub_key = std::get<0>(out_k_idx);
out_data.tx_pub_key = pod_to_hex(tx_pub_key);
out_data.amount = std::get<1>(out_k_idx);
out_data.out_index = std::get<2>(out_k_idx);
out_data.global_index = amount_specific_indices.at(out_data.out_index);
out_data.mixin = tx_data.mixin;
out_data.timestamp = tx_data.timestamp;
// insert output into mysql's outputs table
uint64_t out_mysql_id = xmr_accounts->insert_output(out_data);
if (out_mysql_id == 0)
{
//cerr << "out_mysql_id is zero!" << endl;
//throw TxSearchException("out_mysql_id is zero!");
}
} // for (auto &out_k_idx: found_mine_outputs)
// once tx and outputs were added, update Accounts table
XmrAccount updated_acc = *acc;
updated_acc.total_received = acc->total_received + tx_data.total_received;
if (xmr_accounts->update(*acc, updated_acc))
{
// if success, set acc to updated_acc;
*acc = updated_acc;
}
} // if (!found_mine_outputs.empty())
// SECOND component: Checking for our key images, i.e., inputs.
vector<txin_to_key> input_key_imgs = xmreg::get_key_images(tx);
// here we will keep what we find.
vector<XmrInput> inputs_found;
// make timescale maps for mixins in input
for (const txin_to_key& in_key: input_key_imgs)
{
// get absolute offsets of mixins
std::vector<uint64_t> absolute_offsets
= cryptonote::relative_output_offsets_to_absolute(
in_key.key_offsets);
// get public keys of outputs used in the mixins that match to the offests
std::vector<cryptonote::output_data_t> mixin_outputs;
if (!CurrentBlockchainStatus::get_output_keys(in_key.amount,
absolute_offsets,
mixin_outputs))
{
cerr << "Mixins key images not found" << endl;
continue;
}
// for each found output public key find check if its ours or not
for (const cryptonote::output_data_t& output_data: mixin_outputs)
{
string output_public_key_str = pod_to_hex(output_data.pubkey);
XmrOutput out;
if (xmr_accounts->output_exists(output_public_key_str, out))
{
cout << "input uses some mixins which are our outputs"
<< out << endl;
// seems that this key image is ours.
// so save it to database for later use.
XmrInput in_data;
in_data.account_id = acc->id;
in_data.tx_id = 0; // for now zero, later we set it
in_data.output_id = out.id;
in_data.key_image = pod_to_hex(in_key.k_image);
in_data.amount = in_key.amount;
in_data.timestamp = blk_timestamp_mysql_format;
inputs_found.push_back(in_data);
// a key image has only one real mixin. Rest is fake.
// so if we find a candidate, break the search.
// break;
} // if (xmr_accounts->output_exists(output_public_key_str, out))
} // for (const cryptonote::output_data_t& output_data: outputs)
} // for (const txin_to_key& in_key: input_key_imgs)
if (!inputs_found.empty())
{
// seems we have some inputs found. time
// to write it to mysql. But first,
// check if this tx is written in mysql.
// calculate how much we preasumply spent.
uint64_t total_sent {0};
for (const XmrInput& in_data: inputs_found)
{
total_sent += in_data.amount;
}
if (tx_mysql_id == 0)
{
// this txs hasnt been seen in step first.
// it means that it only contains potentially our
// key images. It does not have our outputs.
// so write it to mysql as ours, with
// total received of 0.
XmrTransaction tx_data;
tx_data.hash = tx_hash_str;
tx_data.prefix_hash = tx_prefix_hash_str;
tx_data.account_id = acc->id;
tx_data.total_received = 0;
tx_data.total_sent = total_sent;
tx_data.unlock_time = 0;
tx_data.height = searched_blk_no;
tx_data.coinbase = is_coinbase(tx);
tx_data.payment_id = CurrentBlockchainStatus::get_payment_id_as_string(tx);
tx_data.mixin = get_mixin_no(tx) - 1;
tx_data.timestamp = blk_timestamp_mysql_format;
// insert tx_data into mysql's Transactions table
tx_mysql_id = xmr_accounts->insert_tx(tx_data);
if (tx_mysql_id == 0)
{
//cerr << "tx_mysql_id is zero!" << endl;
//throw TxSearchException("tx_mysql_id is zero!");
}
}
} // if (!inputs_found.empty())
// save all input found into database
for (XmrInput& in_data: inputs_found)
{
in_data.tx_id = tx_mysql_id;
uint64_t in_mysql_id = xmr_accounts->insert_input(in_data);
}
} // for (const transaction& tx: blk_txs)
if ((loop_timestamp - current_timestamp > UPDATE_SCANNED_HEIGHT_INTERVAL)
|| searched_blk_no == CurrentBlockchainStatus::current_height)
{
// update scanned_block_height every given interval
// or when we reached top of the blockchain
XmrAccount updated_acc = *acc;
updated_acc.scanned_block_height = searched_blk_no;
if (xmr_accounts->update(*acc, updated_acc))
{
// iff success, set acc to updated_acc;
cout << "scanned_block_height updated" << endl;
*acc = updated_acc;
}
current_timestamp = loop_timestamp;
}
++searched_blk_no;
} // while(continue_search)
}
void
TxSearch::stop()
{
cout << "Stoping the thread by setting continue_search=false" << endl;
continue_search = false;
}
TxSearch::~TxSearch()
{
cout << "TxSearch destroyed" << endl;
}
void
TxSearch::set_searched_blk_no(uint64_t new_value)
{
searched_blk_no = new_value;
}
void
TxSearch::ping()
{
cout << "new last_ping_timestamp: " << last_ping_timestamp << endl;
last_ping_timestamp = chrono::duration_cast<chrono::seconds>(
chrono::system_clock::now().time_since_epoch()).count();
}
bool
TxSearch::still_searching()
{
return continue_search;
}
}
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