/* * This file is part of the libsigrok project. * * Copyright (C) 2013-2014 Martin Ling * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . */ /* Needed for isascii(), as used in the GNU libstdc++ headers */ #ifndef _XOPEN_SOURCE #define _XOPEN_SOURCE 600 #endif #include #include #include #include namespace sigrok { /** Helper function to translate C errors to C++ exceptions. */ static void check(int result) { if (result != SR_OK) throw Error(result); } /** Helper function to obtain valid strings from possibly null input. */ static const char *valid_string(const char *input) { if (input != NULL) return input; else return ""; } /** Helper function to convert between map and GHashTable */ static GHashTable *map_to_hash_variant(map input) { auto output = g_hash_table_new_full( g_str_hash, g_str_equal, g_free, (GDestroyNotify) g_variant_unref); for (auto entry : input) g_hash_table_insert(output, g_strdup(entry.first.c_str()), entry.second.gobj_copy()); return output; } Error::Error(int result) : result(result) { } const char *Error::what() const throw() { return sr_strerror(result); } Error::~Error() throw() { } ResourceReader::~ResourceReader() { } SR_PRIV int ResourceReader::open_callback(struct sr_resource *res, const char *name, void *cb_data) { try { auto *const reader = static_cast(cb_data); reader->open(res, name); } catch (const Error &err) { return err.result; } catch (...) { return SR_ERR; } return SR_OK; } SR_PRIV int ResourceReader::close_callback(struct sr_resource *res, void *cb_data) { try { auto *const reader = static_cast(cb_data); reader->close(res); } catch (const Error &err) { return err.result; } catch (...) { return SR_ERR; } return SR_OK; } SR_PRIV ssize_t ResourceReader::read_callback(const struct sr_resource *res, void *buf, size_t count, void *cb_data) { try { auto *const reader = static_cast(cb_data); return reader->read(res, buf, count); } catch (const Error &err) { return err.result; } catch (...) { return SR_ERR; } } shared_ptr Context::create() { return shared_ptr(new Context(), Context::Deleter()); } Context::Context() : UserOwned(_structure), _session(NULL) { check(sr_init(&_structure)); struct sr_dev_driver **driver_list = sr_driver_list(_structure); if (driver_list) for (int i = 0; driver_list[i]; i++) _drivers[driver_list[i]->name] = new Driver(driver_list[i]); const struct sr_input_module **input_list = sr_input_list(); if (input_list) for (int i = 0; input_list[i]; i++) _input_formats[sr_input_id_get(input_list[i])] = new InputFormat(input_list[i]); const struct sr_output_module **output_list = sr_output_list(); if (output_list) for (int i = 0; output_list[i]; i++) _output_formats[sr_output_id_get(output_list[i])] = new OutputFormat(output_list[i]); } string Context::package_version() { return sr_package_version_string_get(); } string Context::lib_version() { return sr_lib_version_string_get(); } map> Context::drivers() { map> result; for (auto entry: _drivers) { auto name = entry.first; auto driver = entry.second; result[name] = driver->get_shared_pointer(this); } return result; } map> Context::input_formats() { map> result; for (auto entry: _input_formats) { auto name = entry.first; auto input_format = entry.second; result[name] = input_format->get_shared_pointer(this); } return result; } map> Context::output_formats() { map> result; for (auto entry: _output_formats) { auto name = entry.first; auto output_format = entry.second; result[name] = output_format->get_shared_pointer(this); } return result; } Context::~Context() { for (auto entry : _drivers) delete entry.second; for (auto entry : _input_formats) delete entry.second; for (auto entry : _output_formats) delete entry.second; check(sr_exit(_structure)); } const LogLevel *Context::log_level() { return LogLevel::get(sr_log_loglevel_get()); } void Context::set_log_level(const LogLevel *level) { check(sr_log_loglevel_set(level->id())); } static int call_log_callback(void *cb_data, int loglevel, const char *format, va_list args) { va_list args_copy; va_copy(args_copy, args); int length = vsnprintf(NULL, 0, format, args_copy); va_end(args_copy); char *buf = (char *) g_malloc(length + 1); vsprintf(buf, format, args); string message(buf, length); g_free(buf); LogCallbackFunction callback = *((LogCallbackFunction *) cb_data); try { callback(LogLevel::get(loglevel), message); } catch (Error e) { return e.result; } return SR_OK; } void Context::set_log_callback(LogCallbackFunction callback) { _log_callback = callback; check(sr_log_callback_set(call_log_callback, &_log_callback)); } void Context::set_log_callback_default() { check(sr_log_callback_set_default()); _log_callback = nullptr; } void Context::set_resource_reader(ResourceReader *reader) { if (reader) { check(sr_resource_set_hooks(_structure, &ResourceReader::open_callback, &ResourceReader::close_callback, &ResourceReader::read_callback, reader)); } else { check(sr_resource_set_hooks(_structure, nullptr, nullptr, nullptr, nullptr)); } } shared_ptr Context::create_session() { return shared_ptr( new Session(shared_from_this()), Session::Deleter()); } shared_ptr Context::create_user_device( string vendor, string model, string version) { return shared_ptr( new UserDevice(vendor, model, version), UserDevice::Deleter()); } shared_ptr Context::create_header_packet(Glib::TimeVal start_time) { auto header = g_new(struct sr_datafeed_header, 1); header->feed_version = 1; header->starttime.tv_sec = start_time.tv_sec; header->starttime.tv_usec = start_time.tv_usec; auto packet = g_new(struct sr_datafeed_packet, 1); packet->type = SR_DF_HEADER; packet->payload = header; return shared_ptr(new Packet(nullptr, packet), Packet::Deleter()); } shared_ptr Context::create_meta_packet( map config) { auto meta = g_new0(struct sr_datafeed_meta, 1); for (auto input : config) { auto key = input.first; auto value = input.second; auto output = g_new(struct sr_config, 1); output->key = key->id(); output->data = value.gobj(); g_variant_ref(output->data); meta->config = g_slist_append(meta->config, output); } auto packet = g_new(struct sr_datafeed_packet, 1); packet->type = SR_DF_META; packet->payload = meta; return shared_ptr(new Packet(nullptr, packet), Packet::Deleter()); } shared_ptr Context::create_logic_packet( void *data_pointer, size_t data_length, unsigned int unit_size) { auto logic = g_new(struct sr_datafeed_logic, 1); logic->length = data_length; logic->unitsize = unit_size; logic->data = data_pointer; auto packet = g_new(struct sr_datafeed_packet, 1); packet->type = SR_DF_LOGIC; packet->payload = logic; return shared_ptr(new Packet(nullptr, packet), Packet::Deleter()); } shared_ptr Context::create_analog_packet( vector > channels, float *data_pointer, unsigned int num_samples, const Quantity *mq, const Unit *unit, vector mqflags) { auto analog = g_new0(struct sr_datafeed_analog, 1); for (auto channel : channels) analog->channels = g_slist_append(analog->channels, channel->_structure); analog->num_samples = num_samples; analog->mq = mq->id(); analog->unit = unit->id(); analog->mqflags = QuantityFlag::mask_from_flags(mqflags); analog->data = data_pointer; auto packet = g_new(struct sr_datafeed_packet, 1); packet->type = SR_DF_ANALOG; packet->payload = analog; return shared_ptr(new Packet(nullptr, packet), Packet::Deleter()); } shared_ptr Context::load_session(string filename) { return shared_ptr( new Session(shared_from_this(), filename), Session::Deleter()); } shared_ptr Context::create_trigger(string name) { return shared_ptr( new Trigger(shared_from_this(), name), Trigger::Deleter()); } shared_ptr Context::open_file(string filename) { const struct sr_input *input; check(sr_input_scan_file(filename.c_str(), &input)); return shared_ptr( new Input(shared_from_this(), input), Input::Deleter()); } shared_ptr Context::open_stream(string header) { const struct sr_input *input; auto gstr = g_string_new(header.c_str()); auto ret = sr_input_scan_buffer(gstr, &input); g_string_free(gstr, true); check(ret); return shared_ptr( new Input(shared_from_this(), input), Input::Deleter()); } map Context::serials(shared_ptr driver) { GSList *serial_list = sr_serial_list(driver ? driver->_structure : NULL); map serials; for (GSList *serial = serial_list; serial; serial = serial->next) { struct sr_serial_port *port = (sr_serial_port *) serial->data; serials[string(port->name)] = string(port->description); } g_slist_free_full(serial_list, (GDestroyNotify)sr_serial_free); return serials; } Driver::Driver(struct sr_dev_driver *structure) : ParentOwned(structure), Configurable(structure, NULL, NULL), _initialized(false) { } Driver::~Driver() { } string Driver::name() { return valid_string(_structure->name); } string Driver::long_name() { return valid_string(_structure->longname); } vector> Driver::scan( map options) { /* Initialise the driver if not yet done. */ if (!_initialized) { check(sr_driver_init(_parent->_structure, _structure)); _initialized = true; } /* Translate scan options to GSList of struct sr_config pointers. */ GSList *option_list = NULL; for (auto entry : options) { auto key = entry.first; auto value = entry.second; auto config = g_new(struct sr_config, 1); config->key = key->id(); config->data = value.gobj(); option_list = g_slist_append(option_list, config); } /* Run scan. */ GSList *device_list = sr_driver_scan(_structure, option_list); /* Free option list. */ g_slist_free_full(option_list, g_free); /* Create device objects. */ vector> result; for (GSList *device = device_list; device; device = device->next) { auto sdi = (struct sr_dev_inst *) device->data; result.push_back(shared_ptr( new HardwareDevice(shared_from_this(), sdi), HardwareDevice::Deleter())); } /* Free GSList returned from scan. */ g_slist_free(device_list); return result; } Configurable::Configurable( struct sr_dev_driver *driver, struct sr_dev_inst *sdi, struct sr_channel_group *cg) : config_driver(driver), config_sdi(sdi), config_channel_group(cg) { } Configurable::~Configurable() { } Glib::VariantBase Configurable::config_get(const ConfigKey *key) { GVariant *data; check(sr_config_get( config_driver, config_sdi, config_channel_group, key->id(), &data)); return Glib::VariantBase(data); } void Configurable::config_set(const ConfigKey *key, Glib::VariantBase value) { check(sr_config_set( config_sdi, config_channel_group, key->id(), value.gobj())); } Glib::VariantContainerBase Configurable::config_list(const ConfigKey *key) { GVariant *data; check(sr_config_list( config_driver, config_sdi, config_channel_group, key->id(), &data)); return Glib::VariantContainerBase(data); } map> Configurable::config_keys(const ConfigKey *key) { GVariant *gvar_opts; gsize num_opts; const uint32_t *opts; map> result; check(sr_config_list( config_driver, config_sdi, config_channel_group, key->id(), &gvar_opts)); opts = (const uint32_t *) g_variant_get_fixed_array( gvar_opts, &num_opts, sizeof(uint32_t)); for (gsize i = 0; i < num_opts; i++) { auto key = ConfigKey::get(opts[i] & SR_CONF_MASK); set capabilities; if (opts[i] & SR_CONF_GET) capabilities.insert(GET); if (opts[i] & SR_CONF_SET) capabilities.insert(SET); if (opts[i] & SR_CONF_LIST) capabilities.insert(LIST); result[key] = capabilities; } g_variant_unref(gvar_opts); return result; } bool Configurable::config_check(const ConfigKey *key, const ConfigKey *index_key) { GVariant *gvar_opts; gsize num_opts; const uint32_t *opts; if (sr_config_list(config_driver, config_sdi, config_channel_group, index_key->id(), &gvar_opts) != SR_OK) return false; opts = (const uint32_t *) g_variant_get_fixed_array( gvar_opts, &num_opts, sizeof(uint32_t)); for (gsize i = 0; i < num_opts; i++) { if ((opts[i] & SR_CONF_MASK) == (uint32_t) key->id()) { g_variant_unref(gvar_opts); return true; } } g_variant_unref(gvar_opts); return false; } Device::Device(struct sr_dev_inst *structure) : Configurable(sr_dev_inst_driver_get(structure), structure, NULL), _structure(structure) { for (GSList *entry = sr_dev_inst_channels_get(structure); entry; entry = entry->next) { auto channel = (struct sr_channel *) entry->data; _channels[channel] = new Channel(channel); } for (GSList *entry = sr_dev_inst_channel_groups_get(structure); entry; entry = entry->next) { auto group = (struct sr_channel_group *) entry->data; _channel_groups[group->name] = new ChannelGroup(this, group); } } Device::~Device() { for (auto entry : _channels) delete entry.second; for (auto entry : _channel_groups) delete entry.second; } string Device::vendor() { return valid_string(sr_dev_inst_vendor_get(_structure)); } string Device::model() { return valid_string(sr_dev_inst_model_get(_structure)); } string Device::version() { return valid_string(sr_dev_inst_version_get(_structure)); } string Device::serial_number() { return valid_string(sr_dev_inst_sernum_get(_structure)); } string Device::connection_id() { return valid_string(sr_dev_inst_connid_get(_structure)); } vector> Device::channels() { vector> result; for (auto channel = sr_dev_inst_channels_get(_structure); channel; channel = channel->next) result.push_back( _channels[(struct sr_channel *) channel->data]->get_shared_pointer( get_shared_from_this())); return result; } shared_ptr Device::get_channel(struct sr_channel *ptr) { return _channels[ptr]->get_shared_pointer(get_shared_from_this()); } map> Device::channel_groups() { map> result; for (auto entry: _channel_groups) { auto name = entry.first; auto channel_group = entry.second; result[name] = channel_group->get_shared_pointer(get_shared_from_this()); } return result; } void Device::open() { check(sr_dev_open(_structure)); } void Device::close() { check(sr_dev_close(_structure)); } HardwareDevice::HardwareDevice(shared_ptr driver, struct sr_dev_inst *structure) : UserOwned(structure), Device(structure), _driver(driver) { } HardwareDevice::~HardwareDevice() { } shared_ptr HardwareDevice::get_shared_from_this() { return static_pointer_cast(shared_from_this()); } shared_ptr HardwareDevice::driver() { return _driver; } UserDevice::UserDevice(string vendor, string model, string version) : UserOwned(sr_dev_inst_user_new( vendor.c_str(), model.c_str(), version.c_str())), Device(UserOwned::_structure) { } UserDevice::~UserDevice() { } shared_ptr UserDevice::get_shared_from_this() { return static_pointer_cast(shared_from_this()); } shared_ptr UserDevice::add_channel(unsigned int index, const ChannelType *type, string name) { check(sr_dev_inst_channel_add(Device::_structure, index, type->id(), name.c_str())); struct sr_channel *structure = (struct sr_channel *) g_slist_last(sr_dev_inst_channels_get(Device::_structure))->data; Channel *channel = new Channel(structure); _channels[structure] = channel; return get_channel(structure); } Channel::Channel(struct sr_channel *structure) : ParentOwned(structure), _type(ChannelType::get(_structure->type)) { } Channel::~Channel() { } string Channel::name() { return valid_string(_structure->name); } void Channel::set_name(string name) { check(sr_dev_channel_name_set(_structure, name.c_str())); } const ChannelType *Channel::type() { return ChannelType::get(_structure->type); } bool Channel::enabled() { return _structure->enabled; } void Channel::set_enabled(bool value) { check(sr_dev_channel_enable(_structure, value)); } unsigned int Channel::index() { return _structure->index; } ChannelGroup::ChannelGroup(Device *device, struct sr_channel_group *structure) : ParentOwned(structure), Configurable(sr_dev_inst_driver_get(device->_structure), device->_structure, structure) { for (GSList *entry = structure->channels; entry; entry = entry->next) _channels.push_back(device->_channels[(struct sr_channel *)entry->data]); } ChannelGroup::~ChannelGroup() { } string ChannelGroup::name() { return valid_string(_structure->name); } vector> ChannelGroup::channels() { vector> result; for (auto channel : _channels) result.push_back(channel->get_shared_pointer(_parent)); return result; } Trigger::Trigger(shared_ptr context, string name) : UserOwned(sr_trigger_new(name.c_str())), _context(context) { for (auto stage = _structure->stages; stage; stage = stage->next) _stages.push_back( new TriggerStage((struct sr_trigger_stage *) stage->data)); } Trigger::~Trigger() { for (auto stage: _stages) delete stage; sr_trigger_free(_structure); } string Trigger::name() { return _structure->name; } vector> Trigger::stages() { vector> result; for (auto stage : _stages) result.push_back(stage->get_shared_pointer(this)); return result; } shared_ptr Trigger::add_stage() { auto stage = new TriggerStage(sr_trigger_stage_add(_structure)); _stages.push_back(stage); return stage->get_shared_pointer(this); } TriggerStage::TriggerStage(struct sr_trigger_stage *structure) : ParentOwned(structure) { } TriggerStage::~TriggerStage() { for (auto match : _matches) delete match; } int TriggerStage::number() { return _structure->stage; } vector> TriggerStage::matches() { vector> result; for (auto match : _matches) result.push_back(match->get_shared_pointer(this)); return result; } void TriggerStage::add_match(shared_ptr channel, const TriggerMatchType *type, float value) { check(sr_trigger_match_add(_structure, channel->_structure, type->id(), value)); _matches.push_back(new TriggerMatch( (struct sr_trigger_match *) g_slist_last( _structure->matches)->data, channel)); } void TriggerStage::add_match(shared_ptr channel, const TriggerMatchType *type) { add_match(channel, type, NAN); } TriggerMatch::TriggerMatch(struct sr_trigger_match *structure, shared_ptr channel) : ParentOwned(structure), _channel(channel) { } TriggerMatch::~TriggerMatch() { } shared_ptr TriggerMatch::channel() { return _channel; } const TriggerMatchType *TriggerMatch::type() { return TriggerMatchType::get(_structure->match); } float TriggerMatch::value() { return _structure->value; } DatafeedCallbackData::DatafeedCallbackData(Session *session, DatafeedCallbackFunction callback) : _callback(callback), _session(session) { } void DatafeedCallbackData::run(const struct sr_dev_inst *sdi, const struct sr_datafeed_packet *pkt) { auto device = _session->get_device(sdi); auto packet = shared_ptr(new Packet(device, pkt), Packet::Deleter()); _callback(device, packet); } SourceCallbackData::SourceCallbackData(shared_ptr source) : _source(source) { } bool SourceCallbackData::run(int revents) { return _source->_callback((Glib::IOCondition) revents); } shared_ptr EventSource::create(int fd, Glib::IOCondition events, int timeout, SourceCallbackFunction callback) { auto result = new EventSource(timeout, callback); result->_type = EventSource::SOURCE_FD; result->_fd = fd; result->_events = events; return shared_ptr(result, EventSource::Deleter()); } shared_ptr EventSource::create(Glib::PollFD pollfd, int timeout, SourceCallbackFunction callback) { auto result = new EventSource(timeout, callback); result->_type = EventSource::SOURCE_POLLFD; result->_pollfd = pollfd; return shared_ptr(result, EventSource::Deleter()); } shared_ptr EventSource::create(Glib::RefPtr channel, Glib::IOCondition events, int timeout, SourceCallbackFunction callback) { auto result = new EventSource(timeout, callback); result->_type = EventSource::SOURCE_IOCHANNEL; result->_channel = channel; result->_events = events; return shared_ptr(result, EventSource::Deleter()); } EventSource::EventSource(int timeout, SourceCallbackFunction callback) : _timeout(timeout), _callback(callback) { } EventSource::~EventSource() { } SessionDevice::SessionDevice(struct sr_dev_inst *structure) : ParentOwned(structure), Device(structure) { } SessionDevice::~SessionDevice() { } shared_ptr SessionDevice::get_shared_from_this() { return static_pointer_cast(shared_from_this()); } Session::Session(shared_ptr context) : UserOwned(_structure), _context(context) { check(sr_session_new(context->_structure, &_structure)); _context->_session = this; } Session::Session(shared_ptr context, string filename) : UserOwned(_structure), _context(context), _filename(filename) { check(sr_session_load(context->_structure, filename.c_str(), &_structure)); GSList *dev_list; check(sr_session_dev_list(_structure, &dev_list)); for (GSList *dev = dev_list; dev; dev = dev->next) { auto sdi = (struct sr_dev_inst *) dev->data; _owned_devices[sdi] = new SessionDevice(sdi); } _context->_session = this; } Session::~Session() { check(sr_session_destroy(_structure)); for (auto callback : _datafeed_callbacks) delete callback; for (auto entry : _source_callbacks) delete entry.second; for (auto entry : _owned_devices) delete entry.second; } shared_ptr Session::get_device(const struct sr_dev_inst *sdi) { if (_owned_devices.count(sdi)) return static_pointer_cast( _owned_devices[sdi]->get_shared_pointer(this)); else if (_other_devices.count(sdi)) return _other_devices[sdi]; else throw Error(SR_ERR_BUG); } void Session::add_device(shared_ptr device) { check(sr_session_dev_add(_structure, device->_structure)); _other_devices[device->_structure] = device; } vector> Session::devices() { GSList *dev_list; check(sr_session_dev_list(_structure, &dev_list)); vector> result; for (GSList *dev = dev_list; dev; dev = dev->next) { auto sdi = (struct sr_dev_inst *) dev->data; result.push_back(get_device(sdi)); } return result; } void Session::remove_devices() { _other_devices.clear(); check(sr_session_dev_remove_all(_structure)); } void Session::start() { check(sr_session_start(_structure)); } void Session::run() { check(sr_session_run(_structure)); } void Session::stop() { check(sr_session_stop(_structure)); } static void datafeed_callback(const struct sr_dev_inst *sdi, const struct sr_datafeed_packet *pkt, void *cb_data) { auto callback = static_cast(cb_data); callback->run(sdi, pkt); } void Session::add_datafeed_callback(DatafeedCallbackFunction callback) { auto cb_data = new DatafeedCallbackData(this, callback); check(sr_session_datafeed_callback_add(_structure, datafeed_callback, cb_data)); _datafeed_callbacks.push_back(cb_data); } void Session::remove_datafeed_callbacks(void) { check(sr_session_datafeed_callback_remove_all(_structure)); for (auto callback : _datafeed_callbacks) delete callback; _datafeed_callbacks.clear(); } static int source_callback(int fd, int revents, void *cb_data) { (void) fd; auto callback = (SourceCallbackData *) cb_data; return callback->run(revents); } void Session::add_source(shared_ptr source) { if (_source_callbacks.count(source) == 1) throw Error(SR_ERR_ARG); auto cb_data = new SourceCallbackData(source); switch (source->_type) { case EventSource::SOURCE_FD: check(sr_session_source_add(_structure, source->_fd, source->_events, source->_timeout, source_callback, cb_data)); break; case EventSource::SOURCE_POLLFD: check(sr_session_source_add_pollfd(_structure, source->_pollfd.gobj(), source->_timeout, source_callback, cb_data)); break; case EventSource::SOURCE_IOCHANNEL: check(sr_session_source_add_channel(_structure, source->_channel->gobj(), source->_events, source->_timeout, source_callback, cb_data)); break; } _source_callbacks[source] = cb_data; } void Session::remove_source(shared_ptr source) { if (_source_callbacks.count(source) == 0) throw Error(SR_ERR_ARG); switch (source->_type) { case EventSource::SOURCE_FD: check(sr_session_source_remove(_structure, source->_fd)); break; case EventSource::SOURCE_POLLFD: check(sr_session_source_remove_pollfd(_structure, source->_pollfd.gobj())); break; case EventSource::SOURCE_IOCHANNEL: check(sr_session_source_remove_channel(_structure, source->_channel->gobj())); break; } delete _source_callbacks[source]; _source_callbacks.erase(source); } shared_ptr Session::trigger() { return _trigger; } void Session::set_trigger(shared_ptr trigger) { if (!trigger) // Set NULL trigger, i.e. remove any trigger from the session. check(sr_session_trigger_set(_structure, NULL)); else check(sr_session_trigger_set(_structure, trigger->_structure)); _trigger = trigger; } string Session::filename() { return _filename; } shared_ptr Session::context() { return _context; } Packet::Packet(shared_ptr device, const struct sr_datafeed_packet *structure) : UserOwned(structure), _device(device) { switch (structure->type) { case SR_DF_HEADER: _payload = new Header( static_cast( structure->payload)); break; case SR_DF_META: _payload = new Meta( static_cast( structure->payload)); break; case SR_DF_LOGIC: _payload = new Logic( static_cast( structure->payload)); break; case SR_DF_ANALOG: _payload = new Analog( static_cast( structure->payload)); break; default: _payload = nullptr; break; } } Packet::~Packet() { if (_payload) delete _payload; } const PacketType *Packet::type() { return PacketType::get(_structure->type); } shared_ptr Packet::payload() { if (_payload) return _payload->get_shared_pointer(this); else throw Error(SR_ERR_NA); } PacketPayload::PacketPayload() { } PacketPayload::~PacketPayload() { } Header::Header(const struct sr_datafeed_header *structure) : ParentOwned(structure), PacketPayload() { } Header::~Header() { } shared_ptr Header::get_shared_pointer(Packet *_parent) { return static_pointer_cast( ParentOwned::get_shared_pointer(_parent)); } int Header::feed_version() { return _structure->feed_version; } Glib::TimeVal Header::start_time() { return Glib::TimeVal( _structure->starttime.tv_sec, _structure->starttime.tv_usec); } Meta::Meta(const struct sr_datafeed_meta *structure) : ParentOwned(structure), PacketPayload() { } Meta::~Meta() { } shared_ptr Meta::get_shared_pointer(Packet *_parent) { return static_pointer_cast( ParentOwned::get_shared_pointer(_parent)); } map Meta::config() { map result; for (auto l = _structure->config; l; l = l->next) { auto config = (struct sr_config *) l->data; result[ConfigKey::get(config->key)] = Glib::VariantBase(config->data); } return result; } Logic::Logic(const struct sr_datafeed_logic *structure) : ParentOwned(structure), PacketPayload() { } Logic::~Logic() { } shared_ptr Logic::get_shared_pointer(Packet *_parent) { return static_pointer_cast( ParentOwned::get_shared_pointer(_parent)); } void *Logic::data_pointer() { return _structure->data; } size_t Logic::data_length() { return _structure->length; } unsigned int Logic::unit_size() { return _structure->unitsize; } Analog::Analog(const struct sr_datafeed_analog *structure) : ParentOwned(structure), PacketPayload() { } Analog::~Analog() { } shared_ptr Analog::get_shared_pointer(Packet *_parent) { return static_pointer_cast( ParentOwned::get_shared_pointer(_parent)); } float *Analog::data_pointer() { return _structure->data; } unsigned int Analog::num_samples() { return _structure->num_samples; } vector> Analog::channels() { vector> result; for (auto l = _structure->channels; l; l = l->next) result.push_back(_parent->_device->get_channel( (struct sr_channel *)l->data)); return result; } const Quantity *Analog::mq() { return Quantity::get(_structure->mq); } const Unit *Analog::unit() { return Unit::get(_structure->unit); } vector Analog::mq_flags() { return QuantityFlag::flags_from_mask(_structure->mqflags); } InputFormat::InputFormat(const struct sr_input_module *structure) : ParentOwned(structure) { } InputFormat::~InputFormat() { } string InputFormat::name() { return valid_string(sr_input_id_get(_structure)); } string InputFormat::description() { return valid_string(sr_input_description_get(_structure)); } vector InputFormat::extensions() { vector exts; for (const char *const *e = sr_input_extensions_get(_structure); e && *e; e++) exts.push_back(*e); return exts; } map> InputFormat::options() { const struct sr_option **options = sr_input_options_get(_structure); map> result; if (options) { auto option_array = shared_ptr( options, sr_input_options_free); for (int i = 0; options[i]; i++) result[options[i]->id] = shared_ptr