void file_path_and_guard_expander::
expand(const formatters::repository& frp, const locator& l, model& fm) const {
const auto safba(frp.stock_artefact_formatters_by_archetype());
for (auto& pair : fm.formattables()) {
const auto id(pair.first);
auto& formattable(pair.second);
/*
* It doesn't really matter which segment we choose here since
* they are both mapped to the same name.
*/
const auto& e(*formattable.master_segment());
const auto n(e.name());
auto& eprops(formattable.element_properties());
/*
* Go thorough all the artefact properties and, for each, find
* the associated formatter.
*/
for (auto& pair : eprops.artefact_properties()) {
const auto arch(pair.first);
auto& art_props(pair.second);
const auto i(safba.find(arch));
if (i == safba.end()) {
BOOST_LOG_SEV(lg, error) << missing_archetype << arch;
BOOST_THROW_EXCEPTION(
expansion_error(missing_archetype + arch));
}
/*
* Ask the formatter to generate the full path for the
* artefact.
*/
const auto& fmt(i->second);
art_props.file_path(fmt->full_path(l, n));
/*
* If the formatter supports inclusion, we need to compute
* the header guard as well.
*/
const auto ns(formatters::inclusion_support_types::not_supported);
if (fmt->inclusion_support_type() != ns) {
const auto ip(fmt->inclusion_path(l, n));
art_props.header_guard(to_header_guard(ip));
}
}
}
}
Scalar calculateGradientFirst(Geometry1& point, Geometry2& line, Derivative1& dpoint) {
if(dist.norm() == 0)
return 1.;
const Vector3 d_dist = -dpoint.point() + dpoint.point().dot(line.direction())*line.direction();
const Scalar res = dist.dot(d_dist)/dist.norm();
#ifdef DCM_USE_LOGGING
if(!boost::math::isfinite(res))
BOOST_LOG_SEV(log, details::error) << "Unnormal first cluster gradient detected: "<<res
<<" with point: "<<point.point().transpose()<<", line: "<<line.point().transpose()
<< line.direction().transpose() <<" and dpoint: "<<dpoint.point().transpose();
#endif
return res;
};
std::unordered_map<std::string, annotation_group> annotation_groups_factory::
make(const std::unordered_map<std::string, scribble_group>&
scribble_groups) const {
std::unordered_map<std::string, annotation_group> r;
for (const auto& pair : scribble_groups) {
const auto id(pair.first);
BOOST_LOG_SEV(lg, debug) << "Processing scribble group: " << id;
const auto& sgrp(pair.second);
const auto ag(make(sgrp));
r[id] = ag;
}
return r;
}
void annotation_groups_factory::validate_scope(const type& t,
const scope_types current_scope) const {
if (t.scope() != scope_types::any &&
t.scope() != scope_types::not_applicable &&
t.scope() != current_scope) {
std::stringstream s;
s << field_used_in_invalid_scope << t.name().qualified()
<< expected_scope << t.scope()
<< actual_scope << current_scope;
BOOST_LOG_SEV(lg, error) << s.str();
BOOST_THROW_EXCEPTION(building_error(s.str()));
}
}
void merger::add_target(const model& target) {
require_not_has_target(target.name().simple_name());
has_target_ = true;
merged_model_.name(target.name());
merged_model_.documentation(target.documentation());
merged_model_.leaves(target.leaves());
merged_model_.modules(target.modules());
merged_model_.references(target.references());
add(target);
BOOST_LOG_SEV(lg, debug) << "added target model: "
<< target.name().simple_name();
}
bool generalization_indexer::is_leaf(const object& o) const {
// FIXME: massive hack. must not add leafs for services.
const auto uds(object_types::user_defined_service);
const bool is_service(o.object_type() == uds);
if (o.is_parent() || !o.is_child() || is_service) {
BOOST_LOG_SEV(lg, debug)
<< "Type is not in a generalization relationship."
<< " is parent: " << o.is_parent()
<< " is child: " << o.is_child()
<< " is service: " << is_service;
return false;
}
return true;
}
void utility_formatter::insert_quote(const quote_types qt) const {
switch(qt) {
case quote_types::single_quote:
stream_ << single_quote;
return;
case quote_types::double_quote:
stream_ << double_quote;
return;
default:
BOOST_LOG_SEV(lg, error) << unsupported_quote_type << qt;
BOOST_THROW_EXCEPTION(formatting_error(
unsupported_quote_type + boost::lexical_cast<std::string>(qt)));
}
}
int main(int, char*[])
{
#if defined(BOOST_LOG_USE_NATIVE_SYSLOG)
init_native_syslog();
#elif !defined(BOOST_LOG_NO_ASIO)
init_builtin_syslog();
#endif
BOOST_LOG_SCOPED_THREAD_TAG("MyLevel", std::string, "warning");
src::severity_logger< > lg;
BOOST_LOG_SEV(lg, 3) << "Hello world!";
return 0;
}
std::list<field_definition>
instantiator::instantiate(const field_definition& fd) const {
validate(fd);
BOOST_LOG_SEV(lg, debug) << "Instantiating template: " << fd;
std::list<field_definition> r;
const auto dt(fd.definition_type());
if (dt == field_definition_types::global_template)
r = instantiate_global_template(fd);
else if (dt == field_definition_types::facet_template)
r = instantiate_facet_template(fd);
else if (dt == field_definition_types::formatter_template)
r = instantiate_formatter_template(fd);
else {
BOOST_LOG_SEV(lg, error) << unsupported_definition_type << dt;
BOOST_THROW_EXCEPTION(instantiation_error(unsupported_definition_type +
boost::lexical_cast<std::string>(dt)));
}
BOOST_LOG_SEV(lg, debug) << "Instantiation result: " << r;
return r;
}
void validator::validate_yarn(const processed_object& po) const {
if (po.yarn_object_type() == yarn_object_types::object)
return; // nothing to validate for yarn objects.
/*
* Non-yarn objects are not allowed to have stereotypes.
*/
if (!po.stereotypes().empty()) {
BOOST_LOG_SEV(lg, error) << stereotypes_require_yarn_object << ": "
<< po.stereotypes();
BOOST_THROW_EXCEPTION(
validation_error(stereotypes_require_yarn_object));
}
}
helper_configuration helper_expander::
make_configuration(const feature_group& fg, const model& fm) const {
BOOST_LOG_SEV(lg, debug) << "Started making the configuration.";
helper_configuration r;
r.streaming_properties(fm.streaming_properties());
for (auto& pair : fm.formattables()) {
const auto id(pair.first);
BOOST_LOG_SEV(lg, debug) << "Procesing element: " << id;
auto& formattable(pair.second);
auto& segment(*formattable.master_segment());
const auto& cfg(*segment.configuration());
const variability::helpers::configuration_selector s(cfg);
const auto fam(s.get_text_content_or_default(fg.family));
r.helper_families()[id] = fam;
}
BOOST_LOG_SEV(lg, debug) << "Finished making the configuration. Result:"
<< r;
return r;
}
void comment_formatter::validate() const {
bool is_syle_supported(
style_ == comment_styles::c_style ||
style_ == comment_styles::shell_style ||
style_ == comment_styles::sql_style ||
style_ == comment_styles::csharp_style ||
style_ == comment_styles::cpp_style);
if (!is_syle_supported) {
const auto s(boost::lexical_cast<std::string>(style_));
BOOST_LOG_SEV(lg, error) << unsupported_style << s;
BOOST_THROW_EXCEPTION(formatting_error(unsupported_style + s));
}
}
Master::Master(const std::shared_ptr<Library>& library, const MasterParameters& parameters):
_library(library),
_parameters(parameters),
nodeAcceptor(library->ioService(), parseTcpEndpoint(parameters.nodeEndpoint)),
clientAcceptor(library->ioService(), parseTcpEndpoint(parameters.clientEndpoint)),
heartbeatTimer(library->ioService()),
heartbeatRunning(true),
_sslContext(ssl::context::tlsv1),
disposed(false),
nodeAcceptorRunning(true),
clientAcceptorRunning(true)
{
// Setup SSL
std::string pw = parameters.sslPassword;
sslContext().set_password_callback([pw](std::size_t, ssl::context::password_purpose) { return pw; });
try {
BOOST_LOG_SEV(log, LogLevel::Info) <<
format("Using %s as the certificate chain file.") % parameters.sslCertificateFile;
sslContext().use_certificate_chain_file(parameters.sslCertificateFile);
} catch (const std::exception& ex) {
MSCThrow(InvalidDataException
(str(format("Error occured while attempting to use '%s' as the "
"certificate chain file: %s") %
parameters.sslCertificateFile % ex.what())));
}
try {
BOOST_LOG_SEV(log, LogLevel::Info) <<
format("Using %s as the private key file.") % parameters.sslPrivateKeyFile;
sslContext().use_private_key_file(parameters.sslPrivateKeyFile, boost::asio::ssl::context::pem);
} catch (const std::exception& ex) {
MSCThrow(InvalidDataException
(str(format("Error occured while attempting to use '%s' as the "
"private key file: %s") %
parameters.sslPrivateKeyFile % ex.what())));
}
BOOST_LOG_SEV(log, LogLevel::Debug) << "SSL is ready.";
// Prepare to accept the first client and node
BOOST_LOG_SEV(log, LogLevel::Debug) << "Preparing to accept clients and nodes.";
waitingNodeConnection = std::make_shared<MasterNodeConnection>(*this);
waitingClient = std::make_shared<MasterClient>(*this, 1,
_parameters.allowVersionSpecification);
acceptNodeConnectionAsync(true);
acceptClientAsync(true);
// Start heartbeat
BOOST_LOG_SEV(log, LogLevel::Debug) << "Starting heartbeat.";
doHeartbeat(boost::system::error_code());
BOOST_LOG_SEV(log, LogLevel::Info) <<
format("Merlion Master Server Core (%s) running.") % MSC_VERSION_STRING;
}
void voice_card_control::cti_callout(boost::shared_ptr<cti_call_out_param> cti_call_out_param_)
{
std::size_t chID;
try
{
chID = m_channel_queue.take();
}
catch (std::out_of_range)
{
BOOST_LOG_SEV(cia_g_logger, RuntimeInfo) << "业务流水:" << cti_call_out_param_->m_transId << " 获取通道失败, 通道全部繁忙";
//继续下一次呼叫
cti_callout_again(cti_call_out_param_);
return;
}
BOOST_LOG_SEV(cia_g_logger, RuntimeInfo) << "业务流水:" << cti_call_out_param_->m_transId << " 获取到得通道状态为:" << SsmChkAutoDial(chID) << ", 通道号码:" << chID;
SsmSetTxCallerId(chID, cti_call_out_param_->m_authCode.c_str());
if (SsmAutoDial(chID, cti_call_out_param_->m_pn.c_str()) == 0){
BOOST_LOG_SEV(cia_g_logger, RuntimeInfo) << "业务流水:" << cti_call_out_param_->m_transId << " 已发送请求, 已将此通道对应状态清空, 通道号码:" << chID;
boost::shared_ptr<trunk> t = m_trunk_vector.at(chID);
boost::unique_lock<boost::mutex> unique_lock_(t->m_trunk_mutex, boost::defer_lock);
if (unique_lock_.try_lock())
{
t->m_client_socket = cti_call_out_param_->m_base_client;
t->m_transId = cti_call_out_param_->m_transId;
t->m_caller_id = cti_call_out_param_->m_authCode;
t->m_called_id = cti_call_out_param_->m_pn;
t->m_hungup_by_echo_tone = cti_call_out_param_->m_hungup_by_echo_tone;
t->m_step = TRK_CALLOUT_DAIL;
t->m_callTime.restart();
}
else
{
BOOST_LOG_SEV(cia_g_logger, Critical) << "业务流水:" << cti_call_out_param_->m_transId << ", 严重异常, 被分配的语音通道处于占用状态, 请程序猿通宵解决问题";
}
}
else {
m_channel_queue.put(chID);
//上一次呼叫失败,继续呼叫
if (cti_call_out_param_->m_repeat_call_out)
{
cti_call_out_param_->m_repeat_call_out = false;
BOOST_LOG_SEV(cia_g_logger, RuntimeInfo) << "业务流水:" << cti_call_out_param_->m_transId << "上一次呼叫失败,继续呼叫";
cti_callout_again(cti_call_out_param_);
}
//已经连续两次呼叫失败, 直接返回失败
else
{
BOOST_LOG_SEV(cia_g_logger, RuntimeInfo) << "业务流水:" << cti_call_out_param_->m_transId << "已经连续两次呼叫失败, 直接返回失败";
ciaMessage msg;
msg.set_type(CIA_CALL_RESPONSE);
msg.set_transid(cti_call_out_param_->m_transId);
msg.set_status(CIA_CALL_FAIL);
cti_call_out_param_->m_base_client->do_write(chat_message(msg));
return;
}
}
}
std::unordered_map<std::string, std::list<std::string> >
generate(const inclusion_dependencies_builder_factory& f,
std::forward_list<
boost::shared_ptr<
inclusion_dependencies_provider_interface<SmlEntity>
>
> providers, const SmlEntity& e) {
const auto n(sml::string_converter::convert(e.name()));
BOOST_LOG_SEV(lg, debug) << "Creating inclusion dependencies for: " << n;
std::unordered_map<std::string, std::list<std::string> > r;
for (const auto p : providers) {
BOOST_LOG_SEV(lg, debug) << "Providing for: " << p->formatter_name();
auto id(p->provide(f, e));
if (!id)
continue;
id->sort(include_directive_comparer);
id->unique();
const auto id_pair(std::make_pair(p->formatter_name(), *id));
const bool inserted(r.insert(id_pair).second);
if (!inserted) {
BOOST_LOG_SEV(lg, error) << duplicate_formatter_name
<< p->formatter_name()
<< " for type: " << n;
BOOST_THROW_EXCEPTION(building_error(duplicate_formatter_name +
p->formatter_name()));
}
}
BOOST_LOG_SEV(lg, debug) << "Finished creating inclusion dependencies for: "
<< n;
return r;
}
void workflow::initialise_context_activity(const std::string& model_name,
const std::string& external_modules, bool is_target) {
context_ = context();
auto& m(context_.model());
m.name(create_name_for_model(model_name, external_modules));
m.original_model_name(model_name);
BOOST_LOG_SEV(lg, debug) << "Model name: " << m.name().qualified();
m.origin_type(yarn::origin_types::user);
m.is_target(is_target);
const auto mm(create_module_for_model(m.name(), is_target));
m.modules().insert(std::make_pair(mm.name().qualified(), mm));
}
Scalar calculateGradientSecond(const E::MatrixBase<DerivedA>& point,
const E::MatrixBase<DerivedB>& segment,
const E::MatrixBase<DerivedC>& dsegment) {
const Vector3 d_cross = - (dsegment.template head<3>().cross(v02) + v01.cross(dsegment.template tail<3>()));
const Vector3 d_v12 = dsegment.template head<3>() - dsegment.template tail<3>();
const Scalar res = cross.dot(d_cross)/(cross_n*v12_n) - v12.dot(d_v12)*cross_v12_n;
#ifdef DCM_USE_LOGGING
if(!boost::math::isfinite(res))
BOOST_LOG_SEV(log, error) << "Unnormal second cluster gradient detected: "<<res
<<" with point: "<<point.transpose()<<", segment: "<<segment.transpose()
<< "and dsegment: "<<dsegment.transpose();
#endif
return res;
};
bool HibernationEnabled()
{
#pragma warning (push, 4)
#pragma warning( disable : 4800 )
BOOST_LOG_SEV(logger(), debug) << "IsPwrHibernateAllowed(): " << (bool)IsPwrHibernateAllowed();
BOOST_LOG_SEV(logger(), debug) << "IsPwrShutdownAllowed(): " << (bool)IsPwrShutdownAllowed();
BOOST_LOG_SEV(logger(), debug) << "IsPwrSuspendAllowed(): " << (bool)IsPwrSuspendAllowed();
#pragma warning (pop)
SYSTEM_POWER_CAPABILITIES systemPowerCapabilities = {0};
if (!GetPwrCapabilities(&systemPowerCapabilities)) {
DWORD last_error = GetLastError();
std::string msg = Utilities::MakeString() << "GetPwrCapabilities() failed. Reason: " << last_error;
BOOST_LOG_SEV(logger(), error) << msg;
return false;
}
#pragma warning (push, 4)
#pragma warning( disable : 4800 )
BOOST_LOG_SEV(logger(), debug) << "systemPowerCapabilities.Hiberboot: " << (bool)systemPowerCapabilities.Hiberboot;
#pragma warning (pop)
return !!systemPowerCapabilities.Hiberboot;
}
void Module3D<Typelist, ID>::type<Sys>::Geometry3D_base<Derived>::set(const T& geometry) {
m_geometry = geometry;
//first init, so that the geometry internal vector has the right size
Base::template init< typename geometry_traits<T>::tag >();
//now write the value;
(typename geometry_traits<T>::modell()).template extract<Scalar,
typename geometry_traits<T>::accessor >(geometry, Base::getValue());
#ifdef DCM_USE_LOGGING
BOOST_LOG_SEV(Base::log, information) << "Set global Value: " << Base::getValue().transpose();
#endif
reset();
};
void merger::add_target(const model& target) {
const auto qn(target.name().qualified());
require_not_has_target(qn);
has_target_ = true;
merged_model_.name(target.name());
merged_model_.documentation(target.documentation());
merged_model_.leaves(target.leaves());
merged_model_.modules(target.modules());
merged_model_.references(target.references());
merged_model_.extensions(target.extensions());
merged_model_.is_target(true);
BOOST_LOG_SEV(lg, debug) << "added target model: " << qn;
}
void voice_card_control::init_cti()
{
BOOST_LOG_SEV(cia_g_logger, RuntimeInfo) << "读取语音卡配置文件";
if (SsmStartCti("ShConfig.ini", "ShIndex.ini") != 0)
{
show_error();
BOOST_LOG_SEV(cia_g_logger, Critical) << "读取语音卡配置文件失败";
throw std::runtime_error("读取语音卡配置文件失败");
}
else{
BOOST_LOG_SEV(cia_g_logger, RuntimeInfo) << "语音卡配置文件读取成功";
}
//设置驱动程序抛出事件的模式
EVENT_SET_INFO EventMode;
EventMode.dwWorkMode = EVENT_CALLBACK; // 事件回调模式
EventMode.lpHandlerParam = (LPVOID)voice_card_control::cti_callback; // 注册回调函数
SsmSetEvent(0xffff, -1, true, &EventMode); // 启动事件触发模式
//如果要在程序中获取SS7消息, 则需要同时注意以下两点
//配置文件 ShConfig.ini 中, GetMsuOnAutoHandle = 1
//程序中: SsmSetEvent(E_RCV_Ss7Msu, -1, true, &EventMode);
SsmSetEvent(E_RCV_Ss7Msu, -1, true, &EventMode);
BOOST_LOG_SEV(cia_g_logger, RuntimeInfo) << "正在初始化语音卡通道, 预期耗时15秒";
// 为了兼容1号信令,注释以下代码,改为sleep 15秒
//while (SsmSearchIdleCallOutCh(160, 0x1E0000) < 0){ // 循环等待, 直到能够获取语音卡空闲通道号, 语音卡初始化完毕
// boost::this_thread::sleep_for(boost::chrono::milliseconds(500));
//}
boost::this_thread::sleep_for(boost::chrono::seconds(15));
BOOST_LOG_SEV(cia_g_logger, RuntimeInfo) << "语音卡通道初始化完毕";
for (std::size_t i = 0; i < m_numChannelCount; i++){
m_channel_queue.put(i);
}
}
void grapher::
process_child_node(const vertex_descriptor_type& v, const processed_object& o) {
if (!o.child_node_id().empty()) {
const std::string id(o.child_node_id());
const vertex_descriptor_type cv(vertex_for_id(id));
boost::add_edge(v, cv, graph_);
BOOST_LOG_SEV(lg, debug) << "Creating edge between '"
<< o.id() << "' and '" << id << "'";
const auto k(orphanage_.find(id));
if (k != orphanage_.end()) {
BOOST_LOG_SEV(lg, debug) << "Object is no longer orphan: "
<< id << "'";
orphanage_.erase(k);
}
connected_ids_.insert(id);
}
if (connected_ids_.find(o.id()) == connected_ids_.end()) {
orphanage_.insert(std::make_pair(o.id(), v));
BOOST_LOG_SEV(lg, debug) << "Vertex for object joined orphanage: "
<< o.id();
}
}
bool CameraGigeAravis::setSize(int width, int height, bool customSize) {
if(customSize) {
arv_camera_set_region(camera, 0, 0,width,height);
arv_camera_get_region (camera, NULL, NULL, &mWidth, &mHeight);
BOOST_LOG_SEV(logger, notification) << "Camera region size : " << mWidth << "x" << mHeight;
// Default is maximum size
}else {
int sensor_width, sensor_height;
arv_camera_get_sensor_size(camera, &sensor_width, &sensor_height);
BOOST_LOG_SEV(logger, notification) << "Camera sensor size : " << sensor_width << "x" << sensor_height;
arv_camera_set_region(camera, 0, 0,sensor_width,sensor_height);
arv_camera_get_region (camera, NULL, NULL, &mWidth, &mHeight);
}
return true;
}
void injector::inject_visitors(intermediate_model& m) {
BOOST_LOG_SEV(lg, debug) << "Injecting visitors.";
std::list<visitor> visitors;
for (auto& pair : m.objects()) {
auto& o(pair.second);
if (!o.is_visitable())
continue;
if (o.leaves().empty()) {
const auto qn(o.name().qualified());
BOOST_LOG_SEV(lg, error) << zero_leaves << qn;
BOOST_THROW_EXCEPTION(injection_error(zero_leaves + qn));
}
const auto v(create_visitor(o, o.leaves()));
inject_visitable_by(o, o.leaves(), v.name(), m);
visitors.push_back(v);
}
for (const auto v : visitors) {
BOOST_LOG_SEV(lg, debug) << "Adding visitor: "
<< v.name().qualified();
const auto pair(std::make_pair(v.name().qualified(), v));
const auto i(m.visitors().insert(pair));
if (!i.second) {
const auto qn(v.name().qualified());
BOOST_LOG_SEV(lg, error) << duplicate_name << qn;
BOOST_THROW_EXCEPTION(injection_error(duplicate_name + qn));
}
}
BOOST_LOG_SEV(lg, debug) << "Done injecting visitors.";
}
layer hydrator::read_layer() {
validate_current_element(dia_layer);
layer layer;
layer.name(read_xml_string_attribute(dia_name));
layer.visible(try_read_xml_bool_attribute(dia_layer_visible));
layer.active(try_read_xml_bool_attribute(dia_layer_active));
BOOST_LOG_SEV(lg, debug) << "Reading layer: " << layer.name();
std::vector<object> objects;
const bool is_self_closing(reader_.is_empty());
reader_.read();
if (!is_self_closing) {
do {
objects.push_back(read_object());
} while (!is_end_element(dia_layer));
reader_.read();
}
layer.objects(objects);
BOOST_LOG_SEV(lg, debug) << "Read layer: " << layer.name();
return layer;
}
Scalar calculateGradientFirst(const E::MatrixBase<DerivedA>& point,
const E::MatrixBase<DerivedB>& segment,
const E::MatrixBase<DerivedC>& dpoint) {
const Vector3 d_point = dpoint; //eigen only acceppts vector3 for cross product
const Vector3 d_cross = d_point.cross(v02) + v01.cross(d_point);
const Scalar res = cross.dot(d_cross)/(cross_n*v12_n);
#ifdef DCM_USE_LOGGING
if(!boost::math::isfinite(res))
BOOST_LOG_SEV(log, error) << "Unnormal first cluster gradient detected: "<<res
<<" with point: "<<point.transpose()<<", segment: "<<segment.transpose()
<<" and dpoint: "<<dpoint.transpose();
#endif
return res;
};
bool Linklet::messageParsed(Message &msg)
{
if (m_state == State::IntroWait) {
// We have received the hello message, extract information and detach
Protocol::Interplex::Hello hello = message_cast<Protocol::Interplex::Hello>(msg);
Contact peerContact = Contact::fromMessage(hello.local_contact());
if (peerContact.isNull()) {
BOOST_LOG_SEV(m_logger, log::error) << "Invalid peer contact in hello message!";
return false;
}
m_peerContact = peerContact;
// Perform additional verification on the peer before transitioning into
// the connected state
if (!signalVerifyPeer(shared_from_this()) || !m_manager.verifyPeer(peerContact)) {
BOOST_LOG_SEV(m_logger, log::error) << "Peer verificaton has failed!";
return false;
}
BOOST_LOG_SEV(m_logger, log::normal) << "Introductory phase with " << peerContact.nodeId().hex() << " completed.";
m_state = State::Connected;
signalConnectionSuccess(shared_from_this());
// The above signal may close this linklet, in this case we should not start reading,
// otherwise this will cause a segmentation fault
if (m_state != State::Connected)
return false;
} else {
// Payload has been read, emit message and detach
signalMessageReceived(shared_from_this(), msg);
}
msg.detach();
return true;
}
formattables::path_derivatives
inclusion_directives_factory::path_derivatives_for_formatter_name(
const std::unordered_map<std::string,
formattables::path_derivatives>& pd,
const std::string& formatter_name) const {
const auto i(pd.find(formatter_name));
if (i == pd.end()) {
BOOST_LOG_SEV(lg, error) << formatter_name_not_found
<< formatter_name;
BOOST_THROW_EXCEPTION(
building_error(formatter_name_not_found + formatter_name));
}
return i->second;
}
void NodeVersionLoader::receiveHeader()
{
auto self = shared_from_this();
checkThread();
auto& item = currentDownloadItem();
state = State::ReceivingHeader;
auto buf = std::make_shared<std::uint64_t>();
timer.expires_from_now(boost::posix_time::seconds(8));
timer.async_wait([this, self] (const error_code& error) {
if (error) {
return;
}
if (disposed) {
return;
}
if (state == State::ReceivingHeader) {
BOOST_LOG_SEV(log, LogLevel::Warn) <<
"Timed out.";
socket.cancel();
}
});
asio::async_read(socket, asio::buffer(buf.get(), 8), [this, self, &item, buf](const error_code& error, std::size_t) {
checkThread();
if (disposed) {
downloadCancelled();
return;
}
if (error) {
downloadFailed(error.message());
return;
}
timer.cancel();
auto size = *buf;
if (size == 0) {
downloadFailed("Version cannot be downloaded for some reason.");
return;
}
receiveData(size);
});
}
void workflow::report_exception_common() const {
if (can_log_) {
BOOST_LOG_SEV(lg, warn) << stitcher_product << errors_msg;
std::cerr << log_file_name_.string() << ":0: " << log_file_msg
<< std::endl;
// << log_file_msg << "'" << log_file_name_.string()
// << "' " << std::endl;
}
if (template_name_.empty())
return;
std::cerr << "Failed to generate template: '" << template_name_ << "'."
<< std::endl;
}
