Drop unused boost-thread dependency.

[pulseview.git] / pv / session.cpp

/*
 * This file is part of the PulseView project.
 *
 * Copyright (C) 2012-14 Joel Holdsworth <joel@airwebreathe.org.uk>
 *
 * 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 2 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 <http://www.gnu.org/licenses/>.
 */

#include <QFileInfo>

#include <cassert>
#include <mutex>
#include <stdexcept>

#include <sys/stat.h>

#include "devicemanager.hpp"
#include "session.hpp"

#include "data/analog.hpp"
#include "data/analogsegment.hpp"
#include "data/decode/decoder.hpp"
#include "data/decoderstack.hpp"
#include "data/logic.hpp"
#include "data/logicsegment.hpp"
#include "data/signalbase.hpp"

#include "devices/hardwaredevice.hpp"
#include "devices/inputfile.hpp"
#include "devices/sessionfile.hpp"

#include "toolbars/mainbar.hpp"

#include "view/analogsignal.hpp"
#include "view/decodetrace.hpp"
#include "view/logicsignal.hpp"
#include "view/signal.hpp"
#include "view/view.hpp"

#include <libsigrokcxx/libsigrokcxx.hpp>

#ifdef ENABLE_DECODE
#include <libsigrokdecode/libsigrokdecode.h>
#endif

using std::bad_alloc;
using std::dynamic_pointer_cast;
using std::find_if;
using std::function;
using std::lock_guard;
using std::list;
using std::make_pair;
using std::make_shared;
using std::map;
using std::max;
using std::move;
using std::mutex;
using std::pair;
using std::recursive_mutex;
using std::runtime_error;
using std::shared_ptr;
using std::string;
using std::unordered_set;
using std::vector;

using sigrok::Analog;
using sigrok::Channel;
using sigrok::ConfigKey;
using sigrok::DatafeedCallbackFunction;
using sigrok::Error;
using sigrok::InputFormat;
using sigrok::Logic;
using sigrok::Meta;
using sigrok::Packet;
using sigrok::Session;

using Glib::VariantBase;

namespace pv {
Session::Session(DeviceManager &device_manager, QString name) :
        device_manager_(device_manager),
        default_name_(name),
        name_(name),
        capture_state_(Stopped),
        cur_samplerate_(0),
        data_saved_(true)
{
}

Session::~Session()
{
        // Stop and join to the thread
        stop_capture();
}

DeviceManager& Session::device_manager()
{
        return device_manager_;
}

const DeviceManager& Session::device_manager() const
{
        return device_manager_;
}

shared_ptr<sigrok::Session> Session::session() const
{
        if (!device_)
                return shared_ptr<sigrok::Session>();
        return device_->session();
}

shared_ptr<devices::Device> Session::device() const
{
        return device_;
}

QString Session::name() const
{
        return name_;
}

void Session::set_name(QString name)
{
        if (default_name_.isEmpty())
                default_name_ = name;

        name_ = name;

        name_changed();
}

const list< shared_ptr<views::ViewBase> > Session::views() const
{
        return views_;
}

shared_ptr<views::ViewBase> Session::main_view() const
{
        return main_view_;
}

void Session::set_main_bar(shared_ptr<pv::toolbars::MainBar> main_bar)
{
        main_bar_ = main_bar;
}

shared_ptr<pv::toolbars::MainBar> Session::main_bar() const
{
        return main_bar_;
}

bool Session::data_saved() const
{
        return data_saved_;
}

void Session::save_settings(QSettings &settings) const
{
        map<string, string> dev_info;
        list<string> key_list;
        int stacks = 0, views = 0;

        if (device_) {
                shared_ptr<devices::HardwareDevice> hw_device =
                        dynamic_pointer_cast< devices::HardwareDevice >(device_);

                if (hw_device) {
                        settings.setValue("device_type", "hardware");
                        settings.beginGroup("device");

                        key_list.emplace_back("vendor");
                        key_list.emplace_back("model");
                        key_list.emplace_back("version");
                        key_list.emplace_back("serial_num");
                        key_list.emplace_back("connection_id");

                        dev_info = device_manager_.get_device_info(device_);

                        for (string key : key_list) {
                                if (dev_info.count(key))
                                        settings.setValue(QString::fromUtf8(key.c_str()),
                                                        QString::fromUtf8(dev_info.at(key).c_str()));
                                else
                                        settings.remove(QString::fromUtf8(key.c_str()));
                        }

                        settings.endGroup();
                }

                shared_ptr<devices::SessionFile> sessionfile_device =
                        dynamic_pointer_cast< devices::SessionFile >(device_);

                if (sessionfile_device) {
                        settings.setValue("device_type", "sessionfile");
                        settings.beginGroup("device");
                        settings.setValue("filename", QString::fromStdString(
                                sessionfile_device->full_name()));
                        settings.endGroup();
                }

                // Save channels and decoders
                for (shared_ptr<data::SignalBase> base : signalbases_) {
#ifdef ENABLE_DECODE
                        if (base->is_decode_signal()) {
                                shared_ptr<pv::data::DecoderStack> decoder_stack =
                                                base->decoder_stack();
                                shared_ptr<data::decode::Decoder> top_decoder =
                                                decoder_stack->stack().front();

                                settings.beginGroup("decoder_stack" + QString::number(stacks++));
                                settings.setValue("id", top_decoder->decoder()->id);
                                settings.setValue("name", top_decoder->decoder()->name);
                                settings.endGroup();
                        } else
#endif
                        {
                                settings.beginGroup(base->internal_name());
                                base->save_settings(settings);
                                settings.endGroup();
                        }
                }

                settings.setValue("decoder_stacks", stacks);

                // Save view states and their signal settings
                // Note: main_view must be saved as view0
                settings.beginGroup("view" + QString::number(views++));
                main_view_->save_settings(settings);
                settings.endGroup();

                for (shared_ptr<views::ViewBase> view : views_) {
                        if (view != main_view_) {
                                settings.beginGroup("view" + QString::number(views++));
                                view->save_settings(settings);
                                settings.endGroup();
                        }
                }

                settings.setValue("views", views);
        }
}

void Session::restore_settings(QSettings &settings)
{
        shared_ptr<devices::Device> device;

        QString device_type = settings.value("device_type").toString();

        if (device_type == "hardware") {
                map<string, string> dev_info;
                list<string> key_list;

                // Re-select last used device if possible but only if it's not demo
                settings.beginGroup("device");
                key_list.emplace_back("vendor");
                key_list.emplace_back("model");
                key_list.emplace_back("version");
                key_list.emplace_back("serial_num");
                key_list.emplace_back("connection_id");

                for (string key : key_list) {
                        const QString k = QString::fromStdString(key);
                        if (!settings.contains(k))
                                continue;

                        const string value = settings.value(k).toString().toStdString();
                        if (!value.empty())
                                dev_info.insert(make_pair(key, value));
                }

                if (dev_info.count("model") > 0)
                        device = device_manager_.find_device_from_info(dev_info);

                if (device)
                        set_device(device);

                settings.endGroup();
        }

        if (device_type == "sessionfile") {
                settings.beginGroup("device");
                QString filename = settings.value("filename").toString();
                settings.endGroup();

                if (QFileInfo(filename).isReadable()) {
                        device = make_shared<devices::SessionFile>(device_manager_.context(),
                                filename.toStdString());
                        set_device(device);

                        // TODO Perform error handling
                        start_capture([](QString infoMessage) { (void)infoMessage; });

                        set_name(QFileInfo(filename).fileName());
                }
        }

        if (device) {
                // Restore channels
                for (shared_ptr<data::SignalBase> base : signalbases_) {
                        settings.beginGroup(base->internal_name());
                        base->restore_settings(settings);
                        settings.endGroup();
                }

                // Restore decoders
#ifdef ENABLE_DECODE
                int stacks = settings.value("decoder_stacks").toInt();

                for (int i = 0; i < stacks; i++) {
                        settings.beginGroup("decoder_stack" + QString::number(i++));

                        QString id = settings.value("id").toString();
                        add_decoder(srd_decoder_get_by_id(id.toStdString().c_str()));

                        settings.endGroup();
                }
#endif

                // Restore views
                int views = settings.value("views").toInt();

                for (int i = 0; i < views; i++) {
                        settings.beginGroup("view" + QString::number(i));

                        if (i > 0) {
                                views::ViewType type = (views::ViewType)settings.value("type").toInt();
                                add_view(name_, type, this);
                                views_.back()->restore_settings(settings);
                        } else
                                main_view_->restore_settings(settings);

                        settings.endGroup();
                }
        }
}

void Session::select_device(shared_ptr<devices::Device> device)
{
        try {
                if (device)
                        set_device(device);
                else
                        set_default_device();
        } catch (const QString &e) {
                main_bar_->session_error(tr("Failed to Select Device"),
                        tr("Failed to Select Device"));
        }
}

void Session::set_device(shared_ptr<devices::Device> device)
{
        assert(device);

        // Ensure we are not capturing before setting the device
        stop_capture();

        if (device_)
                device_->close();

        device_.reset();

        // Revert name back to default name (e.g. "Session 1") as the data is gone
        name_ = default_name_;
        name_changed();

        // Remove all stored data
        for (shared_ptr<views::ViewBase> view : views_) {
                view->clear_signals();
#ifdef ENABLE_DECODE
                view->clear_decode_signals();
#endif
        }
        for (const shared_ptr<data::SignalData> d : all_signal_data_)
                d->clear();
        all_signal_data_.clear();
        signalbases_.clear();
        cur_logic_segment_.reset();

        for (auto entry : cur_analog_segments_) {
                shared_ptr<sigrok::Channel>(entry.first).reset();
                shared_ptr<data::AnalogSegment>(entry.second).reset();
        }

        logic_data_.reset();

        signals_changed();

        device_ = move(device);

        try {
                device_->open();
        } catch (const QString &e) {
                device_.reset();
        }

        if (device_) {
                device_->session()->add_datafeed_callback([=]
                        (shared_ptr<sigrok::Device> device, shared_ptr<Packet> packet) {
                                data_feed_in(device, packet);
                        });

                update_signals();
        }

        device_changed();
}

void Session::set_default_device()
{
        const list< shared_ptr<devices::HardwareDevice> > &devices =
                device_manager_.devices();

        if (devices.empty())
                return;

        // Try and find the demo device and select that by default
        const auto iter = find_if(devices.begin(), devices.end(),
                [] (const shared_ptr<devices::HardwareDevice> &d) {
                        return d->hardware_device()->driver()->name() == "demo";        });
        set_device((iter == devices.end()) ? devices.front() : *iter);
}

void Session::load_init_file(const string &file_name, const string &format)
{
        shared_ptr<InputFormat> input_format;

        if (!format.empty()) {
                const map<string, shared_ptr<InputFormat> > formats =
                        device_manager_.context()->input_formats();
                const auto iter = find_if(formats.begin(), formats.end(),
                        [&](const pair<string, shared_ptr<InputFormat> > f) {
                                return f.first == format; });
                if (iter == formats.end()) {
                        main_bar_->session_error(tr("Error"),
                                tr("Unexpected input format: %s").arg(QString::fromStdString(format)));
                        return;
                }

                input_format = (*iter).second;
        }

        load_file(QString::fromStdString(file_name), input_format);
}

void Session::load_file(QString file_name,
        shared_ptr<sigrok::InputFormat> format,
        const map<string, Glib::VariantBase> &options)
{
        const QString errorMessage(
                QString("Failed to load file %1").arg(file_name));

        try {
                if (format)
                        set_device(shared_ptr<devices::Device>(
                                new devices::InputFile(
                                        device_manager_.context(),
                                        file_name.toStdString(),
                                        format, options)));
                else
                        set_device(shared_ptr<devices::Device>(
                                new devices::SessionFile(
                                        device_manager_.context(),
                                        file_name.toStdString())));
        } catch (Error e) {
                main_bar_->session_error(tr("Failed to load ") + file_name, e.what());
                set_default_device();
                main_bar_->update_device_list();
                return;
        }

        main_bar_->update_device_list();

        start_capture([&, errorMessage](QString infoMessage) {
                main_bar_->session_error(errorMessage, infoMessage); });

        set_name(QFileInfo(file_name).fileName());
}

Session::capture_state Session::get_capture_state() const
{
        lock_guard<mutex> lock(sampling_mutex_);
        return capture_state_;
}

void Session::start_capture(function<void (const QString)> error_handler)
{
        if (!device_) {
                error_handler(tr("No active device set, can't start acquisition."));
                return;
        }

        stop_capture();

        // Check that at least one channel is enabled
        const shared_ptr<sigrok::Device> sr_dev = device_->device();
        if (sr_dev) {
                const auto channels = sr_dev->channels();
                if (!any_of(channels.begin(), channels.end(),
                        [](shared_ptr<Channel> channel) {
                                return channel->enabled(); })) {
                        error_handler(tr("No channels enabled."));
                        return;
                }
        }

        // Clear signal data
        for (const shared_ptr<data::SignalData> d : all_signal_data_)
                d->clear();

        // Revert name back to default name (e.g. "Session 1") for real devices
        // as the (possibly saved) data is gone. File devices keep their name.
        shared_ptr<devices::HardwareDevice> hw_device =
                dynamic_pointer_cast< devices::HardwareDevice >(device_);

        if (hw_device) {
                name_ = default_name_;
                name_changed();
        }

        // Begin the session
        sampling_thread_ = std::thread(
                &Session::sample_thread_proc, this, error_handler);
}

void Session::stop_capture()
{
        if (get_capture_state() != Stopped)
                device_->stop();

        // Check that sampling stopped
        if (sampling_thread_.joinable())
                sampling_thread_.join();
}

void Session::register_view(shared_ptr<views::ViewBase> view)
{
        if (views_.empty()) {
                main_view_ = view;
        }

        views_.push_back(view);

        update_signals();
}

void Session::deregister_view(shared_ptr<views::ViewBase> view)
{
        views_.remove_if([&](shared_ptr<views::ViewBase> v) { return v == view; });

        if (views_.empty()) {
                main_view_.reset();

                // Without a view there can be no main bar
                main_bar_.reset();
        }
}

bool Session::has_view(shared_ptr<views::ViewBase> view)
{
        for (shared_ptr<views::ViewBase> v : views_)
                if (v == view)
                        return true;

        return false;
}

double Session::get_samplerate() const
{
        double samplerate = 0.0;

        for (const shared_ptr<pv::data::SignalData> d : all_signal_data_) {
                assert(d);
                const vector< shared_ptr<pv::data::Segment> > segments =
                        d->segments();
                for (const shared_ptr<pv::data::Segment> &s : segments)
                        samplerate = max(samplerate, s->samplerate());
        }
        // If there is no sample rate given we use samples as unit
        if (samplerate == 0.0)
                samplerate = 1.0;

        return samplerate;
}

const unordered_set< shared_ptr<data::SignalBase> > Session::signalbases() const
{
        return signalbases_;
}

#ifdef ENABLE_DECODE
bool Session::add_decoder(srd_decoder *const dec)
{
        if (!dec)
                return false;

        map<const srd_channel*, shared_ptr<data::SignalBase> > channels;
        shared_ptr<data::DecoderStack> decoder_stack;

        try {
                // Create the decoder
                decoder_stack = make_shared<data::DecoderStack>(*this, dec);

                // Make a list of all the channels
                vector<const srd_channel*> all_channels;
                for (const GSList *i = dec->channels; i; i = i->next)
                        all_channels.push_back((const srd_channel*)i->data);
                for (const GSList *i = dec->opt_channels; i; i = i->next)
                        all_channels.push_back((const srd_channel*)i->data);

                // Auto select the initial channels
                for (const srd_channel *pdch : all_channels)
                        for (shared_ptr<data::SignalBase> b : signalbases_) {
                                if (b->logic_data()) {
                                        if (QString::fromUtf8(pdch->name).toLower().
                                                contains(b->name().toLower()))
                                                channels[pdch] = b;
                                }
                        }

                assert(decoder_stack);
                assert(!decoder_stack->stack().empty());
                assert(decoder_stack->stack().front());
                decoder_stack->stack().front()->set_channels(channels);

                // Create the decode signal
                shared_ptr<data::SignalBase> signalbase =
                        make_shared<data::SignalBase>(nullptr, data::SignalBase::DecodeChannel);

                signalbase->set_decoder_stack(decoder_stack);
                signalbases_.insert(signalbase);

                for (shared_ptr<views::ViewBase> view : views_)
                        view->add_decode_signal(signalbase);
        } catch (runtime_error e) {
                return false;
        }

        signals_changed();

        // Do an initial decode
        decoder_stack->begin_decode();

        return true;
}

void Session::remove_decode_signal(shared_ptr<data::SignalBase> signalbase)
{
        signalbases_.erase(signalbase);

        for (shared_ptr<views::ViewBase> view : views_)
                view->remove_decode_signal(signalbase);

        signals_changed();
}
#endif

void Session::set_capture_state(capture_state state)
{
        bool changed;

        {
                lock_guard<mutex> lock(sampling_mutex_);
                changed = capture_state_ != state;
                capture_state_ = state;
        }

        if (changed)
                capture_state_changed(state);
}

void Session::update_signals()
{
        if (!device_) {
                signalbases_.clear();
                logic_data_.reset();
                for (shared_ptr<views::ViewBase> view : views_) {
                        view->clear_signals();
#ifdef ENABLE_DECODE
                        view->clear_decode_signals();
#endif
                }
                return;
        }

        lock_guard<recursive_mutex> lock(data_mutex_);

        const shared_ptr<sigrok::Device> sr_dev = device_->device();
        if (!sr_dev) {
                signalbases_.clear();
                logic_data_.reset();
                for (shared_ptr<views::ViewBase> view : views_) {
                        view->clear_signals();
#ifdef ENABLE_DECODE
                        view->clear_decode_signals();
#endif
                }
                return;
        }

        // Detect what data types we will receive
        auto channels = sr_dev->channels();
        unsigned int logic_channel_count = count_if(
                channels.begin(), channels.end(),
                [] (shared_ptr<Channel> channel) {
                        return channel->type() == sigrok::ChannelType::LOGIC; });

        // Create data containers for the logic data segments
        {
                lock_guard<recursive_mutex> data_lock(data_mutex_);

                if (logic_channel_count == 0) {
                        logic_data_.reset();
                } else if (!logic_data_ ||
                        logic_data_->num_channels() != logic_channel_count) {
                        logic_data_.reset(new data::Logic(
                                logic_channel_count));
                        assert(logic_data_);
                }
        }

        // Make the signals list
        for (shared_ptr<views::ViewBase> viewbase : views_) {
                views::TraceView::View *trace_view =
                        qobject_cast<views::TraceView::View*>(viewbase.get());

                if (trace_view) {
                        unordered_set< shared_ptr<views::TraceView::Signal> >
                                prev_sigs(trace_view->signals());
                        trace_view->clear_signals();

                        for (auto channel : sr_dev->channels()) {
                                shared_ptr<data::SignalBase> signalbase;
                                shared_ptr<views::TraceView::Signal> signal;

                                // Find the channel in the old signals
                                const auto iter = find_if(
                                        prev_sigs.cbegin(), prev_sigs.cend(),
                                        [&](const shared_ptr<views::TraceView::Signal> &s) {
                                                return s->base()->channel() == channel;
                                        });
                                if (iter != prev_sigs.end()) {
                                        // Copy the signal from the old set to the new
                                        signal = *iter;
                                        trace_view->add_signal(signal);
                                } else {
                                        // Find the signalbase for this channel if possible
                                        signalbase.reset();
                                        for (const shared_ptr<data::SignalBase> b : signalbases_)
                                                if (b->channel() == channel)
                                                        signalbase = b;

                                        switch(channel->type()->id()) {
                                        case SR_CHANNEL_LOGIC:
                                                if (!signalbase) {
                                                        signalbase = make_shared<data::SignalBase>(channel,
                                                                data::SignalBase::LogicChannel);
                                                        signalbases_.insert(signalbase);

                                                        all_signal_data_.insert(logic_data_);
                                                        signalbase->set_data(logic_data_);

                                                        connect(this, SIGNAL(capture_state_changed(int)),
                                                                signalbase.get(), SLOT(on_capture_state_changed(int)));
                                                }

                                                signal = shared_ptr<views::TraceView::Signal>(
                                                        new views::TraceView::LogicSignal(*this,
                                                                device_, signalbase));
                                                trace_view->add_signal(signal);
                                                break;

                                        case SR_CHANNEL_ANALOG:
                                        {
                                                if (!signalbase) {
                                                        signalbase = make_shared<data::SignalBase>(channel,
                                                                data::SignalBase::AnalogChannel);
                                                        signalbases_.insert(signalbase);

                                                        shared_ptr<data::Analog> data(new data::Analog());
                                                        all_signal_data_.insert(data);
                                                        signalbase->set_data(data);

                                                        connect(this, SIGNAL(capture_state_changed(int)),
                                                                signalbase.get(), SLOT(on_capture_state_changed(int)));
                                                }

                                                signal = shared_ptr<views::TraceView::Signal>(
                                                        new views::TraceView::AnalogSignal(
                                                                *this, signalbase));
                                                trace_view->add_signal(signal);
                                                break;
                                        }

                                        default:
                                                assert(false);
                                                break;
                                        }
                                }
                        }
                }
        }

        signals_changed();
}

shared_ptr<data::SignalBase> Session::signalbase_from_channel(
        shared_ptr<sigrok::Channel> channel) const
{
        for (shared_ptr<data::SignalBase> sig : signalbases_) {
                assert(sig);
                if (sig->channel() == channel)
                        return sig;
        }
        return shared_ptr<data::SignalBase>();
}

void Session::sample_thread_proc(function<void (const QString)> error_handler)
{
        assert(error_handler);

        if (!device_)
                return;

        cur_samplerate_ = device_->read_config<uint64_t>(ConfigKey::SAMPLERATE);

        out_of_memory_ = false;

        try {
                device_->start();
        } catch (Error e) {
                error_handler(e.what());
                return;
        }

        set_capture_state(device_->session()->trigger() ?
                AwaitingTrigger : Running);

        device_->run();
        set_capture_state(Stopped);

        // Confirm that SR_DF_END was received
        if (cur_logic_segment_) {
                qDebug("SR_DF_END was not received.");
                assert(false);
        }

        // Optimize memory usage
        free_unused_memory();

        // We now have unsaved data unless we just "captured" from a file
        shared_ptr<devices::File> file_device =
                dynamic_pointer_cast<devices::File>(device_);

        if (!file_device)
                data_saved_ = false;

        if (out_of_memory_)
                error_handler(tr("Out of memory, acquisition stopped."));
}

void Session::free_unused_memory()
{
        for (shared_ptr<data::SignalData> data : all_signal_data_) {
                const vector< shared_ptr<data::Segment> > segments = data->segments();

                for (shared_ptr<data::Segment> segment : segments) {
                        segment->free_unused_memory();
                }
        }
}

void Session::feed_in_header()
{
        cur_samplerate_ = device_->read_config<uint64_t>(ConfigKey::SAMPLERATE);
}

void Session::feed_in_meta(shared_ptr<Meta> meta)
{
        for (auto entry : meta->config()) {
                switch (entry.first->id()) {
                case SR_CONF_SAMPLERATE:
                        // We can't rely on the header to always contain the sample rate,
                        // so in case it's supplied via a meta packet, we use it.
                        if (!cur_samplerate_)
                                cur_samplerate_ = g_variant_get_uint64(entry.second.gobj());

                        /// @todo handle samplerate changes
                        break;
                default:
                        // Unknown metadata is not an error.
                        break;
                }
        }

        signals_changed();
}

void Session::feed_in_trigger()
{
        // The channel containing most samples should be most accurate
        uint64_t sample_count = 0;

        {
                for (const shared_ptr<pv::data::SignalData> d : all_signal_data_) {
                        assert(d);
                        uint64_t temp_count = 0;

                        const vector< shared_ptr<pv::data::Segment> > segments =
                                d->segments();
                        for (const shared_ptr<pv::data::Segment> &s : segments)
                                temp_count += s->get_sample_count();

                        if (temp_count > sample_count)
                                sample_count = temp_count;
                }
        }

        trigger_event(sample_count / get_samplerate());
}

void Session::feed_in_frame_begin()
{
        if (cur_logic_segment_ || !cur_analog_segments_.empty())
                frame_began();
}

void Session::feed_in_logic(shared_ptr<Logic> logic)
{
        lock_guard<recursive_mutex> lock(data_mutex_);

        if (!logic_data_) {
                // The only reason logic_data_ would not have been created is
                // if it was not possible to determine the signals when the
                // device was created.
                update_signals();
        }

        if (!cur_logic_segment_) {
                // This could be the first packet after a trigger
                set_capture_state(Running);

                // Create a new data segment
                cur_logic_segment_ = make_shared<data::LogicSegment>(
                        *logic_data_, logic->unit_size(), cur_samplerate_);
                logic_data_->push_segment(cur_logic_segment_);

                // @todo Putting this here means that only listeners querying
                // for logic will be notified. Currently the only user of
                // frame_began is DecoderStack, but in future we need to signal
                // this after both analog and logic sweeps have begun.
                frame_began();
        }

        cur_logic_segment_->append_payload(logic);

        data_received();
}

void Session::feed_in_analog(shared_ptr<Analog> analog)
{
        lock_guard<recursive_mutex> lock(data_mutex_);

        const vector<shared_ptr<Channel>> channels = analog->channels();
        const unsigned int channel_count = channels.size();
        const size_t sample_count = analog->num_samples() / channel_count;
        const float *data = static_cast<const float *>(analog->data_pointer());
        bool sweep_beginning = false;

        if (signalbases_.empty())
                update_signals();

        for (auto channel : channels) {
                shared_ptr<data::AnalogSegment> segment;

                // Try to get the segment of the channel
                const map< shared_ptr<Channel>, shared_ptr<data::AnalogSegment> >::
                        iterator iter = cur_analog_segments_.find(channel);
                if (iter != cur_analog_segments_.end())
                        segment = (*iter).second;
                else {
                        // If no segment was found, this means we haven't
                        // created one yet. i.e. this is the first packet
                        // in the sweep containing this segment.
                        sweep_beginning = true;

                        // Find the analog data associated with the channel
                        shared_ptr<data::SignalBase> base = signalbase_from_channel(channel);
                        assert(base);

                        shared_ptr<data::Analog> data(base->analog_data());
                        assert(data);

                        // Create a segment, keep it in the maps of channels
                        segment = make_shared<data::AnalogSegment>(
                                *data, cur_samplerate_);
                        cur_analog_segments_[channel] = segment;

                        // Push the segment into the analog data.
                        data->push_segment(segment);
                }

                assert(segment);

                // Append the samples in the segment
                segment->append_interleaved_samples(data++, sample_count,
                        channel_count);
        }

        if (sweep_beginning) {
                // This could be the first packet after a trigger
                set_capture_state(Running);
        }

        data_received();
}

void Session::data_feed_in(shared_ptr<sigrok::Device> device,
        shared_ptr<Packet> packet)
{
        static bool frame_began = false;

        (void)device;

        assert(device);
        assert(device == device_->device());
        assert(packet);

        switch (packet->type()->id()) {
        case SR_DF_HEADER:
                feed_in_header();
                break;

        case SR_DF_META:
                feed_in_meta(dynamic_pointer_cast<Meta>(packet->payload()));
                break;

        case SR_DF_TRIGGER:
                feed_in_trigger();
                break;

        case SR_DF_FRAME_BEGIN:
                feed_in_frame_begin();
                frame_began = true;
                break;

        case SR_DF_LOGIC:
                try {
                        feed_in_logic(dynamic_pointer_cast<Logic>(packet->payload()));
                } catch (bad_alloc) {
                        out_of_memory_ = true;
                        device_->stop();
                }
                break;

        case SR_DF_ANALOG:
                try {
                        feed_in_analog(dynamic_pointer_cast<Analog>(packet->payload()));
                } catch (bad_alloc) {
                        out_of_memory_ = true;
                        device_->stop();
                }
                break;

        case SR_DF_FRAME_END:
        case SR_DF_END:
        {
                {
                        lock_guard<recursive_mutex> lock(data_mutex_);
                        cur_logic_segment_.reset();
                        cur_analog_segments_.clear();
                }
                if (frame_began) {
                        frame_began = false;
                        frame_ended();
                }
                break;
        }
        default:
                break;
        }
}

void Session::on_data_saved()
{
        data_saved_ = true;
}

} // namespace pv