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peerplays_migrated/libraries/app/api.cpp

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/*
* Copyright (c) 2015, Cryptonomex, Inc.
* All rights reserved.
*
* This source code is provided for evaluation in private test networks only, until September 8, 2015. After this date, this license expires and
* the code may not be used, modified or distributed for any purpose. Redistribution and use in source and binary forms, with or without modification,
* are permitted until September 8, 2015, provided that the following conditions are met:
*
* 1. The code and/or derivative works are used only for private test networks consisting of no more than 10 P2P nodes.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
* THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR
* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
* WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF
* ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include <graphene/app/api.hpp>
#include <graphene/app/api_access.hpp>
#include <graphene/app/application.hpp>
#include <graphene/chain/database.hpp>
#include <graphene/utilities/key_conversion.hpp>
#include <graphene/chain/protocol/fee_schedule.hpp>
#include <graphene/chain/withdraw_permission_object.hpp>
#include <graphene/chain/worker_evaluator.hpp>
#include <graphene/chain/transaction_object.hpp>
#include <graphene/chain/confidential_evaluator.hpp>
#include <fc/crypto/hex.hpp>
#include <fc/smart_ref_impl.hpp>
namespace graphene { namespace app {
database_api::database_api(graphene::chain::database& db):_db(db)
{
_change_connection = _db.changed_objects.connect([this](const vector<object_id_type>& ids) {
on_objects_changed(ids);
});
_removed_connection = _db.removed_objects.connect([this](const vector<const object*>& objs) {
on_objects_removed(objs);
});
_applied_block_connection = _db.applied_block.connect([this](const signed_block&){ on_applied_block(); });
}
fc::variants database_api::get_objects(const vector<object_id_type>& ids)const
{
fc::variants result;
result.reserve(ids.size());
std::transform(ids.begin(), ids.end(), std::back_inserter(result),
[this](object_id_type id) -> fc::variant {
if(auto obj = _db.find_object(id))
return obj->to_variant();
return {};
});
return result;
}
optional<block_header> database_api::get_block_header(uint32_t block_num) const
{
auto result = _db.fetch_block_by_number(block_num);
if(result)
return *result;
return {};
}
optional<signed_block> database_api::get_block(uint32_t block_num)const
{
return _db.fetch_block_by_number(block_num);
}
processed_transaction database_api::get_transaction(uint32_t block_num, uint32_t trx_num)const
{
auto opt_block = _db.fetch_block_by_number(block_num);
FC_ASSERT( opt_block );
FC_ASSERT( opt_block->transactions.size() > trx_num );
return opt_block->transactions[trx_num];
}
vector<optional<account_object>> database_api::lookup_account_names(const vector<string>& account_names)const
{
const auto& accounts_by_name = _db.get_index_type<account_index>().indices().get<by_name>();
vector<optional<account_object> > result;
result.reserve(account_names.size());
std::transform(account_names.begin(), account_names.end(), std::back_inserter(result),
[&accounts_by_name](const string& name) -> optional<account_object> {
auto itr = accounts_by_name.find(name);
return itr == accounts_by_name.end()? optional<account_object>() : *itr;
});
return result;
}
vector<optional<asset_object>> database_api::lookup_asset_symbols(const vector<string>& symbols_or_ids)const
{
const auto& assets_by_symbol = _db.get_index_type<asset_index>().indices().get<by_symbol>();
vector<optional<asset_object> > result;
result.reserve(symbols_or_ids.size());
std::transform(symbols_or_ids.begin(), symbols_or_ids.end(), std::back_inserter(result),
[this, &assets_by_symbol](const string& symbol_or_id) -> optional<asset_object> {
if( !symbol_or_id.empty() && std::isdigit(symbol_or_id[0]) )
{
auto ptr = _db.find(variant(symbol_or_id).as<asset_id_type>());
return ptr == nullptr? optional<asset_object>() : *ptr;
}
auto itr = assets_by_symbol.find(symbol_or_id);
return itr == assets_by_symbol.end()? optional<asset_object>() : *itr;
});
return result;
}
global_property_object database_api::get_global_properties()const
{
return _db.get(global_property_id_type());
}
dynamic_global_property_object database_api::get_dynamic_global_properties()const
{
return _db.get(dynamic_global_property_id_type());
}
vector<optional<account_object>> database_api::get_accounts(const vector<account_id_type>& account_ids)const
{
vector<optional<account_object>> result; result.reserve(account_ids.size());
std::transform(account_ids.begin(), account_ids.end(), std::back_inserter(result),
[this](account_id_type id) -> optional<account_object> {
if(auto o = _db.find(id))
return *o;
return {};
});
return result;
}
vector<optional<asset_object>> database_api::get_assets(const vector<asset_id_type>& asset_ids)const
{
vector<optional<asset_object>> result; result.reserve(asset_ids.size());
std::transform(asset_ids.begin(), asset_ids.end(), std::back_inserter(result),
[this](asset_id_type id) -> optional<asset_object> {
if(auto o = _db.find(id))
return *o;
return {};
});
return result;
}
uint64_t database_api::get_account_count()const
{
return _db.get_index_type<account_index>().indices().size();
}
map<string,account_id_type> database_api::lookup_accounts(const string& lower_bound_name, uint32_t limit)const
{
FC_ASSERT( limit <= 1000 );
const auto& accounts_by_name = _db.get_index_type<account_index>().indices().get<by_name>();
map<string,account_id_type> result;
for( auto itr = accounts_by_name.lower_bound(lower_bound_name);
limit-- && itr != accounts_by_name.end();
++itr )
result.insert(make_pair(itr->name, itr->get_id()));
return result;
}
void database_api::unsubscribe_from_accounts( const vector<std::string>& names_or_ids )
{
for (const std::string& account_name_or_id : names_or_ids)
{
const account_object* account = nullptr;
if (std::isdigit(account_name_or_id[0]))
account = _db.find(fc::variant(account_name_or_id).as<account_id_type>());
else
{
const auto& idx = _db.get_index_type<account_index>().indices().get<by_name>();
auto itr = idx.find(account_name_or_id);
if (itr != idx.end())
account = &*itr;
}
if (account == nullptr)
continue;
_account_subscriptions.erase(account->id);
}
}
std::map<std::string, full_account> database_api::get_full_accounts(std::function<void(const variant&)> callback,
const vector<std::string>& names_or_ids)
{
FC_ASSERT( _account_subscriptions.size() < 1024 );
std::map<std::string, full_account> results;
for (const std::string& account_name_or_id : names_or_ids)
{
const account_object* account = nullptr;
if (std::isdigit(account_name_or_id[0]))
account = _db.find(fc::variant(account_name_or_id).as<account_id_type>());
else
{
const auto& idx = _db.get_index_type<account_index>().indices().get<by_name>();
auto itr = idx.find(account_name_or_id);
if (itr != idx.end())
account = &*itr;
}
if (account == nullptr)
continue;
_account_subscriptions[account->id] = callback;
// fc::mutable_variant_object full_account;
full_account acnt;
acnt.account = *account;
acnt.statistics = account->statistics(_db);
acnt.registrar_name = account->registrar(_db).name;
acnt.referrer_name = account->referrer(_db).name;
acnt.lifetime_referrer_name = account->lifetime_referrer(_db).name;
// Add the account itself, its statistics object, cashback balance, and referral account names
/*
full_account("account", *account)("statistics", account->statistics(_db))
("registrar_name", account->registrar(_db).name)("referrer_name", account->referrer(_db).name)
("lifetime_referrer_name", account->lifetime_referrer(_db).name);
*/
if (account->cashback_vb)
{
acnt.cashback_balance = account->cashback_balance(_db);
}
// Add the account's balances
auto balance_range = _db.get_index_type<account_balance_index>().indices().get<by_account>().equal_range(account->id);
//vector<account_balance_object> balances;
std::for_each(balance_range.first, balance_range.second,
[&acnt](const account_balance_object& balance) {
acnt.balances.emplace_back(balance);
});
// Add the account's vesting balances
auto vesting_range = _db.get_index_type<vesting_balance_index>().indices().get<by_account>().equal_range(account->id);
std::for_each(vesting_range.first, vesting_range.second,
[&acnt](const vesting_balance_object& balance) {
acnt.vesting_balances.emplace_back(balance);
});
// Add the account's orders
auto order_range = _db.get_index_type<limit_order_index>().indices().get<by_account>().equal_range(account->id);
std::for_each(order_range.first, order_range.second,
[&acnt] (const limit_order_object& order) {
acnt.limit_orders.emplace_back(order);
});
auto call_range = _db.get_index_type<call_order_index>().indices().get<by_account>().equal_range(account->id);
std::for_each(call_range.first, call_range.second,
[&acnt] (const call_order_object& call) {
acnt.call_orders.emplace_back(call);
});
results[account_name_or_id] = acnt;
}
wdump((results));
return results;
}
vector<asset> database_api::get_account_balances(account_id_type acnt, const flat_set<asset_id_type>& assets)const
{
vector<asset> result;
if (assets.empty())
{
// if the caller passes in an empty list of assets, return balances for all assets the account owns
const account_balance_index& balance_index = _db.get_index_type<account_balance_index>();
auto range = balance_index.indices().get<by_account>().equal_range(acnt);
for (const account_balance_object& balance : boost::make_iterator_range(range.first, range.second))
result.push_back(asset(balance.get_balance()));
}
else
{
result.reserve(assets.size());
std::transform(assets.begin(), assets.end(), std::back_inserter(result),
[this, acnt](asset_id_type id) { return _db.get_balance(acnt, id); });
}
return result;
}
vector<asset> database_api::get_named_account_balances(const std::string& name, const flat_set<asset_id_type>& assets) const
{
const auto& accounts_by_name = _db.get_index_type<account_index>().indices().get<by_name>();
auto itr = accounts_by_name.find(name);
FC_ASSERT( itr != accounts_by_name.end() );
return get_account_balances(itr->get_id(), assets);
}
/**
* @return the limit orders for both sides of the book for the two assets specified up to limit number on each side.
*/
vector<limit_order_object> database_api::get_limit_orders(asset_id_type a, asset_id_type b, uint32_t limit)const
{
const auto& limit_order_idx = _db.get_index_type<limit_order_index>();
const auto& limit_price_idx = limit_order_idx.indices().get<by_price>();
vector<limit_order_object> result;
uint32_t count = 0;
auto limit_itr = limit_price_idx.lower_bound(price::max(a,b));
auto limit_end = limit_price_idx.upper_bound(price::min(a,b));
while(limit_itr != limit_end && count < limit)
{
result.push_back(*limit_itr);
++limit_itr;
++count;
}
count = 0;
limit_itr = limit_price_idx.lower_bound(price::max(b,a));
limit_end = limit_price_idx.upper_bound(price::min(b,a));
while(limit_itr != limit_end && count < limit)
{
result.push_back(*limit_itr);
++limit_itr;
++count;
}
return result;
}
vector<call_order_object> database_api::get_call_orders(asset_id_type a, uint32_t limit)const
{
const auto& call_index = _db.get_index_type<call_order_index>().indices().get<by_price>();
const asset_object& mia = _db.get(a);
price index_price = price::min(mia.bitasset_data(_db).options.short_backing_asset, mia.get_id());
return vector<call_order_object>(call_index.lower_bound(index_price.min()),
call_index.lower_bound(index_price.max()));
}
vector<force_settlement_object> database_api::get_settle_orders(asset_id_type a, uint32_t limit)const
{
const auto& settle_index = _db.get_index_type<force_settlement_index>().indices().get<by_expiration>();
const asset_object& mia = _db.get(a);
return vector<force_settlement_object>(settle_index.lower_bound(mia.get_id()),
settle_index.upper_bound(mia.get_id()));
}
vector<asset_object> database_api::list_assets(const string& lower_bound_symbol, uint32_t limit)const
{
FC_ASSERT( limit <= 100 );
const auto& assets_by_symbol = _db.get_index_type<asset_index>().indices().get<by_symbol>();
vector<asset_object> result;
result.reserve(limit);
auto itr = assets_by_symbol.lower_bound(lower_bound_symbol);
if( lower_bound_symbol == "" )
itr = assets_by_symbol.begin();
while(limit-- && itr != assets_by_symbol.end())
result.emplace_back(*itr++);
return result;
}
fc::optional<committee_member_object> database_api::get_committee_member_by_account(account_id_type account) const
{
const auto& idx = _db.get_index_type<committee_member_index>().indices().get<by_account>();
auto itr = idx.find(account);
if( itr != idx.end() )
return *itr;
return {};
}
fc::optional<witness_object> database_api::get_witness_by_account(account_id_type account) const
{
const auto& idx = _db.get_index_type<witness_index>().indices().get<by_account>();
auto itr = idx.find(account);
if( itr != idx.end() )
return *itr;
return {};
}
uint64_t database_api::get_witness_count()const
{
return _db.get_index_type<witness_index>().indices().size();
}
map<string, witness_id_type> database_api::lookup_witness_accounts(const string& lower_bound_name, uint32_t limit)const
{
FC_ASSERT( limit <= 1000 );
const auto& witnesses_by_id = _db.get_index_type<witness_index>().indices().get<by_id>();
// we want to order witnesses by account name, but that name is in the account object
// so the witness_index doesn't have a quick way to access it.
// get all the names and look them all up, sort them, then figure out what
// records to return. This could be optimized, but we expect the
// number of witnesses to be few and the frequency of calls to be rare
std::map<std::string, witness_id_type> witnesses_by_account_name;
for (const witness_object& witness : witnesses_by_id)
if (auto account_iter = _db.find(witness.witness_account))
if (account_iter->name >= lower_bound_name) // we can ignore anything below lower_bound_name
witnesses_by_account_name.insert(std::make_pair(account_iter->name, witness.id));
auto end_iter = witnesses_by_account_name.begin();
while (end_iter != witnesses_by_account_name.end() && limit--)
++end_iter;
witnesses_by_account_name.erase(end_iter, witnesses_by_account_name.end());
return witnesses_by_account_name;
}
map<string, committee_member_id_type> database_api::lookup_committee_member_accounts(const string& lower_bound_name, uint32_t limit)const
{
FC_ASSERT( limit <= 1000 );
const auto& committee_members_by_id = _db.get_index_type<committee_member_index>().indices().get<by_id>();
// we want to order committee_members by account name, but that name is in the account object
// so the committee_member_index doesn't have a quick way to access it.
// get all the names and look them all up, sort them, then figure out what
// records to return. This could be optimized, but we expect the
// number of committee_members to be few and the frequency of calls to be rare
std::map<std::string, committee_member_id_type> committee_members_by_account_name;
for (const committee_member_object& committee_member : committee_members_by_id)
if (auto account_iter = _db.find(committee_member.committee_member_account))
if (account_iter->name >= lower_bound_name) // we can ignore anything below lower_bound_name
committee_members_by_account_name.insert(std::make_pair(account_iter->name, committee_member.id));
auto end_iter = committee_members_by_account_name.begin();
while (end_iter != committee_members_by_account_name.end() && limit--)
++end_iter;
committee_members_by_account_name.erase(end_iter, committee_members_by_account_name.end());
return committee_members_by_account_name;
}
vector<optional<witness_object>> database_api::get_witnesses(const vector<witness_id_type>& witness_ids)const
{
vector<optional<witness_object>> result; result.reserve(witness_ids.size());
std::transform(witness_ids.begin(), witness_ids.end(), std::back_inserter(result),
[this](witness_id_type id) -> optional<witness_object> {
if(auto o = _db.find(id))
return *o;
return {};
});
return result;
}
vector<optional<committee_member_object>> database_api::get_committee_members(const vector<committee_member_id_type>& committee_member_ids)const
{
vector<optional<committee_member_object>> result; result.reserve(committee_member_ids.size());
std::transform(committee_member_ids.begin(), committee_member_ids.end(), std::back_inserter(result),
[this](committee_member_id_type id) -> optional<committee_member_object> {
if(auto o = _db.find(id))
return *o;
return {};
});
return result;
}
login_api::login_api(application& a)
:_app(a)
{
}
login_api::~login_api()
{
}
bool login_api::login(const string& user, const string& password)
{
optional< api_access_info > acc = _app.get_api_access_info( user );
if( !acc.valid() )
return false;
if( acc->password_hash_b64 != "*" )
{
std::string password_salt = fc::base64_decode( acc->password_salt_b64 );
std::string acc_password_hash = fc::base64_decode( acc->password_hash_b64 );
fc::sha256 hash_obj = fc::sha256::hash( password + password_salt );
if( hash_obj.data_size() != acc_password_hash.length() )
return false;
if( memcmp( hash_obj.data(), acc_password_hash.c_str(), hash_obj.data_size() ) != 0 )
return false;
}
for( const std::string& api_name : acc->allowed_apis )
enable_api( api_name );
return true;
}
void login_api::enable_api( const std::string& api_name )
{
if( api_name == "database_api" )
{
_database_api = std::make_shared< database_api >( std::ref( *_app.chain_database() ) );
}
else if( api_name == "network_broadcast_api" )
{
_network_broadcast_api = std::make_shared< network_broadcast_api >( std::ref( _app ) );
}
else if( api_name == "history_api" )
{
_history_api = std::make_shared< history_api >( _app );
}
else if( api_name == "network_node_api" )
{
_network_node_api = std::make_shared< network_node_api >( std::ref(_app) );
}
return;
}
network_broadcast_api::network_broadcast_api(application& a):_app(a)
{
_applied_block_connection = _app.chain_database()->applied_block.connect([this](const signed_block& b){ on_applied_block(b); });
}
void network_broadcast_api::on_applied_block( const signed_block& b )
{
if( _callbacks.size() )
{
for( uint32_t trx_num = 0; trx_num < b.transactions.size(); ++trx_num )
{
const auto& trx = b.transactions[trx_num];
auto id = trx.id();
auto itr = _callbacks.find(id);
auto block_num = b.block_num();
if( itr != _callbacks.end() )
{
fc::async( [=](){ itr->second( fc::variant(transaction_confirmation{ id, block_num, trx_num, trx}) ); } );
}
}
}
}
void network_broadcast_api::broadcast_transaction(const signed_transaction& trx)
{
trx.validate();
_app.chain_database()->push_transaction(trx);
_app.p2p_node()->broadcast_transaction(trx);
}
void network_broadcast_api::broadcast_transaction_with_callback( confirmation_callback cb, const signed_transaction& trx)
{
trx.validate();
_callbacks[trx.id()] = cb;
_app.chain_database()->push_transaction(trx);
_app.p2p_node()->broadcast_transaction(trx);
}
network_node_api::network_node_api( application& a ) : _app( a )
{
}
void network_node_api::add_node(const fc::ip::endpoint& ep)
{
_app.p2p_node()->add_node(ep);
}
std::vector<net::peer_status> network_node_api::get_connected_peers() const
{
return _app.p2p_node()->get_connected_peers();
}
fc::api<network_broadcast_api> login_api::network_broadcast()const
{
FC_ASSERT(_network_broadcast_api);
return *_network_broadcast_api;
}
fc::api<network_node_api> login_api::network_node()const
{
FC_ASSERT(_network_node_api);
return *_network_node_api;
}
fc::api<database_api> login_api::database()const
{
FC_ASSERT(_database_api);
return *_database_api;
}
fc::api<history_api> login_api::history() const
{
FC_ASSERT(_history_api);
return *_history_api;
}
vector<account_id_type> get_relevant_accounts( const object* obj )
{
vector<account_id_type> result;
if( obj->id.space() == protocol_ids )
{
switch( (object_type)obj->id.type() )
{
case null_object_type:
case base_object_type:
case OBJECT_TYPE_COUNT:
return result;
case account_object_type:{
result.push_back( obj->id );
break;
} case asset_object_type:{
const auto& aobj = dynamic_cast<const asset_object*>(obj);
assert( aobj != nullptr );
result.push_back( aobj->issuer );
break;
} case force_settlement_object_type:{
const auto& aobj = dynamic_cast<const force_settlement_object*>(obj);
assert( aobj != nullptr );
result.push_back( aobj->owner );
break;
} case committee_member_object_type:{
const auto& aobj = dynamic_cast<const committee_member_object*>(obj);
assert( aobj != nullptr );
result.push_back( aobj->committee_member_account );
break;
} case witness_object_type:{
const auto& aobj = dynamic_cast<const witness_object*>(obj);
assert( aobj != nullptr );
result.push_back( aobj->witness_account );
break;
} case limit_order_object_type:{
const auto& aobj = dynamic_cast<const limit_order_object*>(obj);
assert( aobj != nullptr );
result.push_back( aobj->seller );
break;
} case call_order_object_type:{
const auto& aobj = dynamic_cast<const call_order_object*>(obj);
assert( aobj != nullptr );
result.push_back( aobj->borrower );
break;
} case custom_object_type:{
} case proposal_object_type:{
const auto& aobj = dynamic_cast<const proposal_object*>(obj);
assert( aobj != nullptr );
flat_set<account_id_type> impacted;
aobj->proposed_transaction.get_impacted_accounts( impacted );
result.reserve( impacted.size() );
for( auto& item : impacted ) result.emplace_back(item);
break;
} case operation_history_object_type:{
const auto& aobj = dynamic_cast<const operation_history_object*>(obj);
assert( aobj != nullptr );
flat_set<account_id_type> impacted;
operation_get_impacted_accounts( aobj->op, impacted );
result.reserve( impacted.size() );
for( auto& item : impacted ) result.emplace_back(item);
break;
} case withdraw_permission_object_type:{
const auto& aobj = dynamic_cast<const withdraw_permission_object*>(obj);
assert( aobj != nullptr );
result.push_back( aobj->withdraw_from_account );
result.push_back( aobj->authorized_account );
break;
} case vesting_balance_object_type:{
const auto& aobj = dynamic_cast<const vesting_balance_object*>(obj);
assert( aobj != nullptr );
result.push_back( aobj->owner );
break;
} case worker_object_type:{
const auto& aobj = dynamic_cast<const worker_object*>(obj);
assert( aobj != nullptr );
result.push_back( aobj->worker_account );
break;
} case balance_object_type:{
/** these are free from any accounts */
}
}
}
else if( obj->id.space() == implementation_ids )
{
switch( (impl_object_type)obj->id.type() )
{
case impl_global_property_object_type:{
} case impl_dynamic_global_property_object_type:{
} case impl_index_meta_object_type:{
} case impl_asset_dynamic_data_type:{
} case impl_asset_bitasset_data_type:{
break;
} case impl_account_balance_object_type:{
const auto& aobj = dynamic_cast<const account_balance_object*>(obj);
assert( aobj != nullptr );
result.push_back( aobj->owner );
break;
} case impl_account_statistics_object_type:{
const auto& aobj = dynamic_cast<const account_statistics_object*>(obj);
assert( aobj != nullptr );
result.push_back( aobj->owner );
break;
} case impl_transaction_object_type:{
const auto& aobj = dynamic_cast<const transaction_object*>(obj);
assert( aobj != nullptr );
flat_set<account_id_type> impacted;
aobj->trx.get_impacted_accounts( impacted );
result.reserve( impacted.size() );
for( auto& item : impacted ) result.emplace_back(item);
break;
} case impl_blinded_balance_object_type:{
const auto& aobj = dynamic_cast<const blinded_balance_object*>(obj);
assert( aobj != nullptr );
result.reserve( aobj->owner.account_auths.size() );
for( const auto& a : aobj->owner.account_auths )
result.push_back( a.first );
break;
} case impl_block_summary_object_type:{
} case impl_account_transaction_history_object_type:{
} case impl_witness_schedule_object_type: {
}
}
}
return result;
} // end get_relevant_accounts( obj )
void database_api::on_objects_removed( const vector<const object*>& objs )
{
if( _account_subscriptions.size() )
{
map<account_id_type, vector<variant> > broadcast_queue;
for( const auto& obj : objs )
{
auto relevant = get_relevant_accounts( obj );
for( const auto& r : relevant )
{
auto sub = _account_subscriptions.find(r);
if( sub != _account_subscriptions.end() )
broadcast_queue[r].emplace_back(obj->to_variant());
}
}
if( broadcast_queue.size() )
{
_broadcast_removed_complete = fc::async([=](){
for( const auto& item : broadcast_queue )
{
auto sub = _account_subscriptions.find(item.first);
if( sub != _account_subscriptions.end() )
sub->second( fc::variant(item.second ) );
}
});
}
}
if( _market_subscriptions.size() )
{
map< pair<asset_id_type, asset_id_type>, vector<variant> > broadcast_queue;
for( const auto& obj : objs )
{
const limit_order_object* order = dynamic_cast<const limit_order_object*>(obj);
if( order )
{
auto sub = _market_subscriptions.find( order->get_market() );
if( sub != _market_subscriptions.end() )
broadcast_queue[order->get_market()].emplace_back( order->id );
}
}
if( broadcast_queue.size() )
{
_broadcast_removed_complete = fc::async([=](){
for( const auto& item : broadcast_queue )
{
auto sub = _market_subscriptions.find(item.first);
if( sub != _market_subscriptions.end() )
sub->second( fc::variant(item.second ) );
}
});
}
}
}
void database_api::on_objects_changed(const vector<object_id_type>& ids)
{
vector<object_id_type> my_objects;
map<account_id_type, vector<variant> > broadcast_queue;
map< pair<asset_id_type, asset_id_type>, vector<variant> > market_broadcast_queue;
for(auto id : ids)
{
if(_subscriptions.find(id) != _subscriptions.end())
my_objects.push_back(id);
const object* obj = nullptr;
if( _account_subscriptions.size() )
{
obj = _db.find_object( id );
if( obj )
{
vector<account_id_type> relevant = get_relevant_accounts( obj );
for( const auto& r : relevant )
{
auto sub = _account_subscriptions.find(r);
if( sub != _account_subscriptions.end() )
broadcast_queue[r].emplace_back(obj->to_variant());
}
}
}
if( _market_subscriptions.size() )
{
if( !_account_subscriptions.size() ) obj = _db.find_object( id );
if( obj )
{
const limit_order_object* order = dynamic_cast<const limit_order_object*>(obj);
if( order )
{
auto sub = _market_subscriptions.find( order->get_market() );
if( sub != _market_subscriptions.end() )
market_broadcast_queue[order->get_market()].emplace_back( order->id );
}
}
}
}
/// TODO: consider making _broadcast_changes_complete a deque and
/// pushing the future back / popping the prior future if it is complete.
/// if a connection hangs then this could get backed up and result in
/// a failure to exit cleanly.
_broadcast_changes_complete = fc::async([=](){
for( const auto& item : broadcast_queue )
{
auto sub = _account_subscriptions.find(item.first);
if( sub != _account_subscriptions.end() )
sub->second( fc::variant(item.second ) );
}
for( const auto& item : market_broadcast_queue )
{
auto sub = _market_subscriptions.find(item.first);
if( sub != _market_subscriptions.end() )
sub->second( fc::variant(item.second ) );
}
for(auto id : my_objects)
{
// just incase _usbscriptions changed between filter and broadcast
auto itr = _subscriptions.find( id );
if( itr != _subscriptions.end() )
{
const object* obj = _db.find_object( id );
if( obj != nullptr )
{
itr->second(obj->to_variant());
}
else
{
itr->second(fc::variant(id));
}
}
}
});
}
/** note: this method cannot yield because it is called in the middle of
* apply a block.
*/
void database_api::on_applied_block()
{
if(_market_subscriptions.size() == 0)
return;
const auto& ops = _db.get_applied_operations();
map< std::pair<asset_id_type,asset_id_type>, vector<pair<operation, operation_result>> > subscribed_markets_ops;
for(const auto& op : ops)
{
std::pair<asset_id_type,asset_id_type> market;
switch(op.op.which())
{
/* This is sent via the object_changed callback
case operation::tag<limit_order_create_operation>::value:
market = op.op.get<limit_order_create_operation>().get_market();
break;
*/
case operation::tag<fill_order_operation>::value:
market = op.op.get<fill_order_operation>().get_market();
break;
/*
case operation::tag<limit_order_cancel_operation>::value:
*/
default: break;
}
if(_market_subscriptions.count(market))
subscribed_markets_ops[market].push_back(std::make_pair(op.op, op.result));
}
fc::async([=](){
for(auto item : subscribed_markets_ops)
{
auto itr = _market_subscriptions.find(item.first);
if(itr != _market_subscriptions.end())
itr->second(fc::variant(item.second));
}
});
}
database_api::~database_api()
{
try {
if(_broadcast_changes_complete.valid())
{
_broadcast_changes_complete.cancel();
_broadcast_changes_complete.wait();
}
if(_broadcast_removed_complete.valid())
{
_broadcast_removed_complete.cancel();
_broadcast_removed_complete.wait();
}
} catch (const fc::exception& e)
{
wlog("${e}", ("e",e.to_detail_string()));
}
}
bool database_api::subscribe_to_objects( const std::function<void(const fc::variant&)>& callback, const vector<object_id_type>& ids)
{
FC_ASSERT( _subscriptions.size() < 1024 );
for(auto id : ids) _subscriptions[id] = callback;
return true;
}
bool database_api::unsubscribe_from_objects(const vector<object_id_type>& ids)
{
for(auto id : ids) _subscriptions.erase(id);
return true;
}
void database_api::subscribe_to_market(std::function<void(const variant&)> callback, asset_id_type a, asset_id_type b)
{
if(a > b) std::swap(a,b);
FC_ASSERT(a != b);
_market_subscriptions[ std::make_pair(a,b) ] = callback;
}
void database_api::unsubscribe_from_market(asset_id_type a, asset_id_type b)
{
if(a > b) std::swap(a,b);
FC_ASSERT(a != b);
_market_subscriptions.erase(std::make_pair(a,b));
}
std::string database_api::get_transaction_hex(const signed_transaction& trx)const
{
return fc::to_hex(fc::raw::pack(trx));
}
vector<operation_history_object> history_api::get_account_history(account_id_type account, operation_history_id_type stop, unsigned limit, operation_history_id_type start) const
{
FC_ASSERT(_app.chain_database());
const auto& db = *_app.chain_database();
FC_ASSERT(limit <= 100);
vector<operation_history_object> result;
const auto& stats = account(db).statistics(db);
if(stats.most_recent_op == account_transaction_history_id_type()) return result;
const account_transaction_history_object* node = &stats.most_recent_op(db);
if(start == operation_history_id_type())
start = node->id;
while(node && node->operation_id.instance.value > stop.instance.value && result.size() < limit)
{
if(node->id.instance() <= start.instance.value)
result.push_back(node->operation_id(db));
if(node->next == account_transaction_history_id_type())
node = nullptr;
else node = db.find(node->next);
}
return result;
}
flat_set<uint32_t> history_api::get_market_history_buckets()const
{
auto hist = _app.get_plugin<market_history_plugin>( "market_history" );
FC_ASSERT( hist );
return hist->tracked_buckets();
}
vector<bucket_object> history_api::get_market_history( asset_id_type a, asset_id_type b,
uint32_t bucket_seconds, fc::time_point_sec start, fc::time_point_sec end )const
{ try {
FC_ASSERT(_app.chain_database());
const auto& db = *_app.chain_database();
vector<bucket_object> result;
result.reserve(100);
if( a > b ) std::swap(a,b);
const auto& bidx = db.get_index_type<bucket_index>();
const auto& by_key_idx = bidx.indices().get<by_key>();
auto itr = by_key_idx.lower_bound( bucket_key( a, b, bucket_seconds, start ) );
while( itr != by_key_idx.end() && itr->key.open <= end && result.size() < 100 )
{
if( !(itr->key.base == a && itr->key.quote == b && itr->key.seconds == bucket_seconds) )
return result;
result.push_back(*itr);
++itr;
}
return result;
} FC_CAPTURE_AND_RETHROW( (a)(b)(bucket_seconds)(start)(end) ) }
/**
* @return all accounts that referr to the key or account id in their owner or active authorities.
*/
vector<account_id_type> database_api::get_account_references( account_id_type account_id )const
{
const auto& idx = _db.get_index_type<account_index>();
const auto& aidx = dynamic_cast<const primary_index<account_index>&>(idx);
const auto& refs = aidx.get_secondary_index<graphene::chain::account_member_index>();
auto itr = refs.account_to_account_memberships.find(account_id);
vector<account_id_type> result;
if( itr != refs.account_to_account_memberships.end() )
{
result.reserve( itr->second.size() );
for( auto item : itr->second ) result.push_back(item);
}
return result;
}
/**
* @return all accounts that referr to the key or account id in their owner or active authorities.
*/
vector<vector<account_id_type>> database_api::get_key_references( vector<public_key_type> keys )const
{
vector< vector<account_id_type> > final_result;
final_result.reserve(keys.size());
for( auto& key : keys )
{
const auto& idx = _db.get_index_type<account_index>();
const auto& aidx = dynamic_cast<const primary_index<account_index>&>(idx);
const auto& refs = aidx.get_secondary_index<graphene::chain::account_member_index>();
auto itr = refs.account_to_key_memberships.find(key);
vector<account_id_type> result;
if( itr != refs.account_to_key_memberships.end() )
{
result.reserve( itr->second.size() );
for( auto item : itr->second ) result.push_back(item);
}
final_result.emplace_back( std::move(result) );
}
return final_result;
}
/** TODO: add secondary index that will accelerate this process */
vector<proposal_object> database_api::get_proposed_transactions( account_id_type id )const
{
const auto& idx = _db.get_index_type<proposal_index>();
vector<proposal_object> result;
idx.inspect_all_objects( [&](const object& obj){
const proposal_object& p = static_cast<const proposal_object&>(obj);
if( p.required_active_approvals.find( id ) != p.required_active_approvals.end() )
result.push_back(p);
else if ( p.required_owner_approvals.find( id ) != p.required_owner_approvals.end() )
result.push_back(p);
else if ( p.available_active_approvals.find( id ) != p.available_active_approvals.end() )
result.push_back(p);
});
return result;
}
vector<call_order_object> database_api::get_margin_positions( const account_id_type& id )const
{ try {
const auto& idx = _db.get_index_type<call_order_index>();
const auto& aidx = idx.indices().get<by_account>();
auto start = aidx.lower_bound( boost::make_tuple( id, 0 ) );
auto end = aidx.lower_bound( boost::make_tuple( id+1, 0 ) );
vector<call_order_object> result;
while( start != end )
{
result.push_back(*start);
++start;
}
return result;
} FC_CAPTURE_AND_RETHROW( (id) ) }
vector<asset> database_api::get_vested_balances( const vector<balance_id_type>& objs )const
{ try {
vector<asset> result;
result.reserve( objs.size() );
auto now = _db.head_block_time();
for( auto obj : objs )
result.push_back( obj(_db).available( now ) );
return result;
} FC_CAPTURE_AND_RETHROW( (objs) ) }
vector<balance_object> database_api::get_balance_objects( const vector<address>& addrs )const
{ try {
const auto& bal_idx = _db.get_index_type<balance_index>();
const auto& by_owner_idx = bal_idx.indices().get<by_owner>();
vector<balance_object> result;
for( const auto& owner : addrs )
{
auto itr = by_owner_idx.lower_bound( boost::make_tuple( owner, asset_id_type(0) ) );
while( itr != by_owner_idx.end() && itr->owner == owner )
{
result.push_back( *itr );
++itr;
}
}
return result;
} FC_CAPTURE_AND_RETHROW( (addrs) ) }
set<public_key_type> database_api::get_required_signatures( const signed_transaction& trx, const flat_set<public_key_type>& available_keys )const
{
return trx.get_required_signatures( available_keys,
[&]( account_id_type id ){ return &id(_db).active; },
[&]( account_id_type id ){ return &id(_db).owner; },
_db.get_global_properties().parameters.max_authority_depth );
}
bool database_api::verify_authority( const signed_transaction& trx )const
{
trx.verify_authority( [&]( account_id_type id ){ return &id(_db).active; },
[&]( account_id_type id ){ return &id(_db).owner; },
_db.get_global_properties().parameters.max_authority_depth );
return true;
}
vector<blinded_balance_object> database_api::get_blinded_balances( const flat_set<commitment_type>& commitments )const
{
vector<blinded_balance_object> result; result.reserve(commitments.size());
const auto& bal_idx = _db.get_index_type<blinded_balance_index>();
const auto& by_commitment_idx = bal_idx.indices().get<by_commitment>();
for( const auto& c : commitments )
{
auto itr = by_commitment_idx.find( c );
if( itr != by_commitment_idx.end() )
result.push_back( *itr );
}
return result;
}
} } // graphene::app
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