[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, write to the Free Software
 * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA  02110-1301 USA
 */

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

#include "session.hpp"

#include "devicemanager.hpp"

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

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

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

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

#include <sys/stat.h>

#include <QDebug>

#include <libsigrokcxx/libsigrokcxx.hpp>

using boost::shared_lock;
using boost::shared_mutex;
using boost::unique_lock;

using std::dynamic_pointer_cast;
using std::function;
using std::lock_guard;
using std::list;
using std::map;
using std::mutex;
using std::recursive_mutex;
using std::set;
using std::shared_ptr;
using std::string;
using std::unordered_set;
using std::vector;

using sigrok::Analog;
using sigrok::Channel;
using sigrok::ChannelType;
using sigrok::ConfigKey;
using sigrok::DatafeedCallbackFunction;
using sigrok::Error;
using sigrok::Header;
using sigrok::Logic;
using sigrok::Meta;
using sigrok::Packet;
using sigrok::PacketPayload;
using sigrok::Session;
using sigrok::SessionDevice;

using Glib::VariantBase;
using Glib::Variant;

namespace pv {
Session::Session(DeviceManager &device_manager) :
	device_manager_(device_manager),
	capture_state_(Stopped),
	cur_samplerate_(0)
{
}

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_;
}

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

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

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

	decode_traces_.clear();

	device_selected();
}

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 = std::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);
}

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)
{
	stop_capture();

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

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

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

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

set< shared_ptr<data::SignalData> > Session::get_data() const
{
	shared_lock<shared_mutex> lock(signals_mutex_);
	set< shared_ptr<data::SignalData> > data;
	for (const shared_ptr<view::Signal> sig : signals_) {
		assert(sig);
		data.insert(sig->data());
	}

	return data;
}

boost::shared_mutex& Session::signals_mutex() const
{
	return signals_mutex_;
}

const unordered_set< shared_ptr<view::Signal> >& Session::signals() const
{
	return signals_;
}

#ifdef ENABLE_DECODE
bool Session::add_decoder(srd_decoder *const dec)
{
	map<const srd_channel*, shared_ptr<view::LogicSignal> > channels;
	shared_ptr<data::DecoderStack> decoder_stack;

	try
	{
		lock_guard<boost::shared_mutex> lock(signals_mutex_);

		// Create the decoder
		decoder_stack = shared_ptr<data::DecoderStack>(
			new data::DecoderStack(*this, dec));

		// Make a list of all the channels
		std::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<view::Signal> s : signals_)
			{
				shared_ptr<view::LogicSignal> l =
					dynamic_pointer_cast<view::LogicSignal>(s);
				if (l && QString::fromUtf8(pdch->name).
					toLower().contains(
					l->name().toLower()))
					channels[pdch] = l;
			}

		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<view::DecodeTrace> d(
			new view::DecodeTrace(*this, decoder_stack,
				decode_traces_.size()));
		decode_traces_.push_back(d);
	}
	catch(std::runtime_error e)
	{
		return false;
	}

	signals_changed();

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

	return true;
}

vector< shared_ptr<view::DecodeTrace> > Session::get_decode_signals() const
{
	shared_lock<shared_mutex> lock(signals_mutex_);
	return decode_traces_;
}

void Session::remove_decode_signal(view::DecodeTrace *signal)
{
	for (auto i = decode_traces_.begin(); i != decode_traces_.end(); i++)
		if ((*i).get() == signal)
		{
			decode_traces_.erase(i);
			signals_changed();
			return;
		}
}
#endif

void Session::set_capture_state(capture_state state)
{
	lock_guard<mutex> lock(sampling_mutex_);
	const bool changed = capture_state_ != state;
	capture_state_ = state;
	if(changed)
		capture_state_changed(state);
}

void Session::update_signals()
{
	assert(device_);

	lock_guard<recursive_mutex> lock(data_mutex_);

	const shared_ptr<sigrok::Device> sr_dev = device_->device();
	if (!sr_dev) {
		signals_.clear();
		logic_data_.reset();
		return;
	}

	// Detect what data types we will receive
	auto channels = sr_dev->channels();
	unsigned int logic_channel_count = std::count_if(
		channels.begin(), channels.end(),
		[] (shared_ptr<Channel> channel) {
			return channel->type() == 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
	{
		unique_lock<shared_mutex> lock(signals_mutex_);

		unordered_set< shared_ptr<view::Signal> > prev_sigs(signals_);
		signals_.clear();

		for (auto channel : sr_dev->channels()) {
			shared_ptr<view::Signal> signal;

			// Find the channel in the old signals
			const auto iter = std::find_if(
				prev_sigs.cbegin(), prev_sigs.cend(),
				[&](const shared_ptr<view::Signal> &s) {
					return s->channel() == channel;
				});
			if (iter != prev_sigs.end()) {
				// Copy the signal from the old set to the new
				signal = *iter;
				auto logic_signal = dynamic_pointer_cast<
					view::LogicSignal>(signal);
				if (logic_signal)
					logic_signal->set_logic_data(
						logic_data_);
			} else {
				// Create a new signal
				switch(channel->type()->id()) {
				case SR_CHANNEL_LOGIC:
					signal = shared_ptr<view::Signal>(
						new view::LogicSignal(*this,
							device_, channel,
							logic_data_));
					break;

				case SR_CHANNEL_ANALOG:
				{
					shared_ptr<data::Analog> data(
						new data::Analog());
					signal = shared_ptr<view::Signal>(
						new view::AnalogSignal(
							*this, channel, data));
					break;
				}

				default:
					assert(0);
					break;
				}
			}

			assert(signal);
			signals_.insert(signal);
		}
	}

	signals_changed();
}

shared_ptr<view::Signal> Session::signal_from_channel(
	shared_ptr<Channel> channel) const
{
	lock_guard<boost::shared_mutex> lock(signals_mutex_);
	for (shared_ptr<view::Signal> sig : signals_) {
		assert(sig);
		if (sig->channel() == channel)
			return sig;
	}
	return shared_ptr<view::Signal>();
}

void Session::sample_thread_proc(shared_ptr<devices::Device> device,
	function<void (const QString)> error_handler)
{
	assert(device);
	assert(error_handler);

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

	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(0);
	}
}

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

	signals_changed();
}

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);

		// Get sample limit.
		const uint64_t sample_limit = device_->read_config<uint64_t>(
			ConfigKey::LIMIT_SAMPLES);

		// Create a new data segment
		cur_logic_segment_ = shared_ptr<data::LogicSegment>(
			new data::LogicSegment(
				logic, cur_samplerate_, sample_limit));
		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();
	}
	else
	{
		// Append to the existing data segment
		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 = analog->data_pointer();
	bool sweep_beginning = false;

	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 havn't
			// created one yet. i.e. this is the first packet
			// in the sweep containing this segment.
			sweep_beginning = true;

			// Get sample limit.
			uint64_t sample_limit;
			try {
				assert(device_);
				const std::shared_ptr<sigrok::Device> device =
					device_->device();
				assert(device);
				sample_limit = VariantBase::cast_dynamic<Variant<guint64>>(
					device->config_get(ConfigKey::LIMIT_SAMPLES)).get();
			} catch (Error) {
				sample_limit = 0;
			}

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

			// Find the annalog data associated with the channel
			shared_ptr<view::AnalogSignal> sig =
				dynamic_pointer_cast<view::AnalogSignal>(
					signal_from_channel(channel));
			assert(sig);

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

			// 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)
{
	(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_FRAME_BEGIN:
		feed_in_frame_begin();
		break;

	case SR_DF_LOGIC:
		feed_in_logic(dynamic_pointer_cast<Logic>(packet->payload()));
		break;

	case SR_DF_ANALOG:
		feed_in_analog(dynamic_pointer_cast<Analog>(packet->payload()));
		break;

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

} // namespace pv
Commit	Line	Data
	1	/*
	2	* This file is part of the PulseView project.
	3	*
	4	* Copyright (C) 2012-14 Joel Holdsworth <joel@airwebreathe.org.uk>
	5	*
	6	* This program is free software; you can redistribute it and/or modify
	7	* it under the terms of the GNU General Public License as published by
	8	* the Free Software Foundation; either version 2 of the License, or
	9	* (at your option) any later version.
	10	*
	11	* This program is distributed in the hope that it will be useful,
	12	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	13	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	14	* GNU General Public License for more details.
	15	*
	16	* You should have received a copy of the GNU General Public License
	17	* along with this program; if not, write to the Free Software
	18	* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
	19	*/
	20
	21	#ifdef ENABLE_DECODE
	22	#include <libsigrokdecode/libsigrokdecode.h>
	23	#endif
	24
	25	#include "session.hpp"
	26
	27	#include "devicemanager.hpp"
	28
	29	#include "data/analog.hpp"
	30	#include "data/analogsegment.hpp"
	31	#include "data/decoderstack.hpp"
	32	#include "data/logic.hpp"
	33	#include "data/logicsegment.hpp"
	34	#include "data/decode/decoder.hpp"
	35
	36	#include "devices/hardwaredevice.hpp"
	37	#include "devices/sessionfile.hpp"
	38
	39	#include "view/analogsignal.hpp"
	40	#include "view/decodetrace.hpp"
	41	#include "view/logicsignal.hpp"
	42
	43	#include <cassert>
	44	#include <mutex>
	45	#include <stdexcept>
	46
	47	#include <sys/stat.h>
	48
	49	#include <QDebug>
	50
	51	#include <libsigrokcxx/libsigrokcxx.hpp>
	52
	53	using boost::shared_lock;
	54	using boost::shared_mutex;
	55	using boost::unique_lock;
	56
	57	using std::dynamic_pointer_cast;
	58	using std::function;
	59	using std::lock_guard;
	60	using std::list;
	61	using std::map;
	62	using std::mutex;
	63	using std::recursive_mutex;
	64	using std::set;
	65	using std::shared_ptr;
	66	using std::string;
	67	using std::unordered_set;
	68	using std::vector;
	69
	70	using sigrok::Analog;
	71	using sigrok::Channel;
	72	using sigrok::ChannelType;
	73	using sigrok::ConfigKey;
	74	using sigrok::DatafeedCallbackFunction;
	75	using sigrok::Error;
	76	using sigrok::Header;
	77	using sigrok::Logic;
	78	using sigrok::Meta;
	79	using sigrok::Packet;
	80	using sigrok::PacketPayload;
	81	using sigrok::Session;
	82	using sigrok::SessionDevice;
	83
	84	using Glib::VariantBase;
	85	using Glib::Variant;
	86
	87	namespace pv {
	88	Session::Session(DeviceManager &device_manager) :
	89	device_manager_(device_manager),
	90	capture_state_(Stopped),
	91	cur_samplerate_(0)
	92	{
	93	}
	94
	95	Session::~Session()
	96	{
	97	// Stop and join to the thread
	98	stop_capture();
	99	}
	100
	101	DeviceManager& Session::device_manager()
	102	{
	103	return device_manager_;
	104	}
	105
	106	const DeviceManager& Session::device_manager() const
	107	{
	108	return device_manager_;
	109	}
	110
	111	shared_ptr<sigrok::Session> Session::session() const
	112	{
	113	if (!device_)
	114	return shared_ptr<sigrok::Session>();
	115	return device_->session();
	116	}
	117
	118	shared_ptr<devices::Device> Session::device() const
	119	{
	120	return device_;
	121	}
	122
	123	void Session::set_device(shared_ptr<devices::Device> device)
	124	{
	125	assert(device);
	126
	127	// Ensure we are not capturing before setting the device
	128	stop_capture();
	129
	130	device_ = std::move(device);
	131	device_->create();
	132	device_->session()->add_datafeed_callback([=]
	133	(shared_ptr<sigrok::Device> device, shared_ptr<Packet> packet) {
	134	data_feed_in(device, packet);
	135	});
	136	update_signals();
	137
	138	decode_traces_.clear();
	139
	140	device_selected();
	141	}
	142
	143	void Session::set_default_device()
	144	{
	145	const list< shared_ptr<devices::HardwareDevice> > &devices =
	146	device_manager_.devices();
	147
	148	if (devices.empty())
	149	return;
	150
	151	// Try and find the demo device and select that by default
	152	const auto iter = std::find_if(devices.begin(), devices.end(),
	153	[] (const shared_ptr<devices::HardwareDevice> &d) {
	154	return d->hardware_device()->driver()->name() ==
	155	"demo"; });
	156	set_device((iter == devices.end()) ? devices.front() : *iter);
	157	}
	158
	159	Session::capture_state Session::get_capture_state() const
	160	{
	161	lock_guard<mutex> lock(sampling_mutex_);
	162	return capture_state_;
	163	}
	164
	165	void Session::start_capture(function<void (const QString)> error_handler)
	166	{
	167	stop_capture();
	168
	169	// Check that at least one channel is enabled
	170	assert(device_);
	171	const shared_ptr<sigrok::Device> sr_dev = device_->device();
	172	if (sr_dev) {
	173	const auto channels = sr_dev->channels();
	174	if (!std::any_of(channels.begin(), channels.end(),
	175	[](shared_ptr<Channel> channel) {
	176	return channel->enabled(); })) {
	177	error_handler(tr("No channels enabled."));
	178	return;
	179	}
	180	}
	181
	182	// Begin the session
	183	sampling_thread_ = std::thread(
	184	&Session::sample_thread_proc, this, device_,
	185	error_handler);
	186	}
	187
	188	void Session::stop_capture()
	189	{
	190	if (get_capture_state() != Stopped)
	191	device_->stop();
	192
	193	// Check that sampling stopped
	194	if (sampling_thread_.joinable())
	195	sampling_thread_.join();
	196	}
	197
	198	set< shared_ptr<data::SignalData> > Session::get_data() const
	199	{
	200	shared_lock<shared_mutex> lock(signals_mutex_);
	201	set< shared_ptr<data::SignalData> > data;
	202	for (const shared_ptr<view::Signal> sig : signals_) {
	203	assert(sig);
	204	data.insert(sig->data());
	205	}
	206
	207	return data;
	208	}
	209
	210	boost::shared_mutex& Session::signals_mutex() const
	211	{
	212	return signals_mutex_;
	213	}
	214
	215	const unordered_set< shared_ptr<view::Signal> >& Session::signals() const
	216	{
	217	return signals_;
	218	}
	219
	220	#ifdef ENABLE_DECODE
	221	bool Session::add_decoder(srd_decoder *const dec)
	222	{
	223	map<const srd_channel*, shared_ptr<view::LogicSignal> > channels;
	224	shared_ptr<data::DecoderStack> decoder_stack;
	225
	226	try
	227	{
	228	lock_guard<boost::shared_mutex> lock(signals_mutex_);
	229
	230	// Create the decoder
	231	decoder_stack = shared_ptr<data::DecoderStack>(
	232	new data::DecoderStack(*this, dec));
	233
	234	// Make a list of all the channels
	235	std::vector<const srd_channel*> all_channels;
	236	for(const GSList *i = dec->channels; i; i = i->next)
	237	all_channels.push_back((const srd_channel*)i->data);
	238	for(const GSList *i = dec->opt_channels; i; i = i->next)
	239	all_channels.push_back((const srd_channel*)i->data);
	240
	241	// Auto select the initial channels
	242	for (const srd_channel *pdch : all_channels)
	243	for (shared_ptr<view::Signal> s : signals_)
	244	{
	245	shared_ptr<view::LogicSignal> l =
	246	dynamic_pointer_cast<view::LogicSignal>(s);
	247	if (l && QString::fromUtf8(pdch->name).
	248	toLower().contains(
	249	l->name().toLower()))
	250	channels[pdch] = l;
	251	}
	252
	253	assert(decoder_stack);
	254	assert(!decoder_stack->stack().empty());
	255	assert(decoder_stack->stack().front());
	256	decoder_stack->stack().front()->set_channels(channels);
	257
	258	// Create the decode signal
	259	shared_ptr<view::DecodeTrace> d(
	260	new view::DecodeTrace(*this, decoder_stack,
	261	decode_traces_.size()));
	262	decode_traces_.push_back(d);
	263	}
	264	catch(std::runtime_error e)
	265	{
	266	return false;
	267	}
	268
	269	signals_changed();
	270
	271	// Do an initial decode
	272	decoder_stack->begin_decode();
	273
	274	return true;
	275	}
	276
	277	vector< shared_ptr<view::DecodeTrace> > Session::get_decode_signals() const
	278	{
	279	shared_lock<shared_mutex> lock(signals_mutex_);
	280	return decode_traces_;
	281	}
	282
	283	void Session::remove_decode_signal(view::DecodeTrace *signal)
	284	{
	285	for (auto i = decode_traces_.begin(); i != decode_traces_.end(); i++)
	286	if ((*i).get() == signal)
	287	{
	288	decode_traces_.erase(i);
	289	signals_changed();
	290	return;
	291	}
	292	}
	293	#endif
	294
	295	void Session::set_capture_state(capture_state state)
	296	{
	297	lock_guard<mutex> lock(sampling_mutex_);
	298	const bool changed = capture_state_ != state;
	299	capture_state_ = state;
	300	if(changed)
	301	capture_state_changed(state);
	302	}
	303
	304	void Session::update_signals()
	305	{
	306	assert(device_);
	307
	308	lock_guard<recursive_mutex> lock(data_mutex_);
	309
	310	const shared_ptr<sigrok::Device> sr_dev = device_->device();
	311	if (!sr_dev) {
	312	signals_.clear();
	313	logic_data_.reset();
	314	return;
	315	}
	316
	317	// Detect what data types we will receive
	318	auto channels = sr_dev->channels();
	319	unsigned int logic_channel_count = std::count_if(
	320	channels.begin(), channels.end(),
	321	[] (shared_ptr<Channel> channel) {
	322	return channel->type() == ChannelType::LOGIC; });
	323
	324	// Create data containers for the logic data segments
	325	{
	326	lock_guard<recursive_mutex> data_lock(data_mutex_);
	327
	328	if (logic_channel_count == 0) {
	329	logic_data_.reset();
	330	} else if (!logic_data_ \|\|
	331	logic_data_->num_channels() != logic_channel_count) {
	332	logic_data_.reset(new data::Logic(
	333	logic_channel_count));
	334	assert(logic_data_);
	335	}
	336	}
	337
	338	// Make the Signals list
	339	{
	340	unique_lock<shared_mutex> lock(signals_mutex_);
	341
	342	unordered_set< shared_ptr<view::Signal> > prev_sigs(signals_);
	343	signals_.clear();
	344
	345	for (auto channel : sr_dev->channels()) {
	346	shared_ptr<view::Signal> signal;
	347
	348	// Find the channel in the old signals
	349	const auto iter = std::find_if(
	350	prev_sigs.cbegin(), prev_sigs.cend(),
	351	[&](const shared_ptr<view::Signal> &s) {
	352	return s->channel() == channel;
	353	});
	354	if (iter != prev_sigs.end()) {
	355	// Copy the signal from the old set to the new
	356	signal = *iter;
	357	auto logic_signal = dynamic_pointer_cast<
	358	view::LogicSignal>(signal);
	359	if (logic_signal)
	360	logic_signal->set_logic_data(
	361	logic_data_);
	362	} else {
	363	// Create a new signal
	364	switch(channel->type()->id()) {
	365	case SR_CHANNEL_LOGIC:
	366	signal = shared_ptr<view::Signal>(
	367	new view::LogicSignal(*this,
	368	device_, channel,
	369	logic_data_));
	370	break;
	371
	372	case SR_CHANNEL_ANALOG:
	373	{
	374	shared_ptr<data::Analog> data(
	375	new data::Analog());
	376	signal = shared_ptr<view::Signal>(
	377	new view::AnalogSignal(
	378	*this, channel, data));
	379	break;
	380	}
	381
	382	default:
	383	assert(0);
	384	break;
	385	}
	386	}
	387
	388	assert(signal);
	389	signals_.insert(signal);
	390	}
	391	}
	392
	393	signals_changed();
	394	}
	395
	396	shared_ptr<view::Signal> Session::signal_from_channel(
	397	shared_ptr<Channel> channel) const
	398	{
	399	lock_guard<boost::shared_mutex> lock(signals_mutex_);
	400	for (shared_ptr<view::Signal> sig : signals_) {
	401	assert(sig);
	402	if (sig->channel() == channel)
	403	return sig;
	404	}
	405	return shared_ptr<view::Signal>();
	406	}
	407
	408	void Session::sample_thread_proc(shared_ptr<devices::Device> device,
	409	function<void (const QString)> error_handler)
	410	{
	411	assert(device);
	412	assert(error_handler);
	413
	414	cur_samplerate_ = device_->read_config<uint64_t>(ConfigKey::SAMPLERATE);
	415
	416	try {
	417	device_->start();
	418	} catch(Error e) {
	419	error_handler(e.what());
	420	return;
	421	}
	422
	423	set_capture_state(device_->session()->trigger() ?
	424	AwaitingTrigger : Running);
	425
	426	device_->run();
	427	set_capture_state(Stopped);
	428
	429	// Confirm that SR_DF_END was received
	430	if (cur_logic_segment_)
	431	{
	432	qDebug("SR_DF_END was not received.");
	433	assert(0);
	434	}
	435	}
	436
	437	void Session::feed_in_header()
	438	{
	439	cur_samplerate_ = device_->read_config<uint64_t>(ConfigKey::SAMPLERATE);
	440	}
	441
	442	void Session::feed_in_meta(shared_ptr<Meta> meta)
	443	{
	444	for (auto entry : meta->config()) {
	445	switch (entry.first->id()) {
	446	case SR_CONF_SAMPLERATE:
	447	/// @todo handle samplerate changes
	448	break;
	449	default:
	450	// Unknown metadata is not an error.
	451	break;
	452	}
	453	}
	454
	455	signals_changed();
	456	}
	457
	458	void Session::feed_in_frame_begin()
	459	{
	460	if (cur_logic_segment_ \|\| !cur_analog_segments_.empty())
	461	frame_began();
	462	}
	463
	464	void Session::feed_in_logic(shared_ptr<Logic> logic)
	465	{
	466	lock_guard<recursive_mutex> lock(data_mutex_);
	467
	468	if (!logic_data_)
	469	{
	470	// The only reason logic_data_ would not have been created is
	471	// if it was not possible to determine the signals when the
	472	// device was created.
	473	update_signals();
	474	}
	475
	476	if (!cur_logic_segment_)
	477	{
	478	// This could be the first packet after a trigger
	479	set_capture_state(Running);
	480
	481	// Get sample limit.
	482	const uint64_t sample_limit = device_->read_config<uint64_t>(
	483	ConfigKey::LIMIT_SAMPLES);
	484
	485	// Create a new data segment
	486	cur_logic_segment_ = shared_ptr<data::LogicSegment>(
	487	new data::LogicSegment(
	488	logic, cur_samplerate_, sample_limit));
	489	logic_data_->push_segment(cur_logic_segment_);
	490
	491	// @todo Putting this here means that only listeners querying
	492	// for logic will be notified. Currently the only user of
	493	// frame_began is DecoderStack, but in future we need to signal
	494	// this after both analog and logic sweeps have begun.
	495	frame_began();
	496	}
	497	else
	498	{
	499	// Append to the existing data segment
	500	cur_logic_segment_->append_payload(logic);
	501	}
	502
	503	data_received();
	504	}
	505
	506	void Session::feed_in_analog(shared_ptr<Analog> analog)
	507	{
	508	lock_guard<recursive_mutex> lock(data_mutex_);
	509
	510	const vector<shared_ptr<Channel>> channels = analog->channels();
	511	const unsigned int channel_count = channels.size();
	512	const size_t sample_count = analog->num_samples() / channel_count;
	513	const float *data = analog->data_pointer();
	514	bool sweep_beginning = false;
	515
	516	for (auto channel : channels)
	517	{
	518	shared_ptr<data::AnalogSegment> segment;
	519
	520	// Try to get the segment of the channel
	521	const map< shared_ptr<Channel>, shared_ptr<data::AnalogSegment> >::
	522	iterator iter = cur_analog_segments_.find(channel);
	523	if (iter != cur_analog_segments_.end())
	524	segment = (*iter).second;
	525	else
	526	{
	527	// If no segment was found, this means we havn't
	528	// created one yet. i.e. this is the first packet
	529	// in the sweep containing this segment.
	530	sweep_beginning = true;
	531
	532	// Get sample limit.
	533	uint64_t sample_limit;
	534	try {
	535	assert(device_);
	536	const std::shared_ptr<sigrok::Device> device =
	537	device_->device();
	538	assert(device);
	539	sample_limit = VariantBase::cast_dynamic<Variant<guint64>>(
	540	device->config_get(ConfigKey::LIMIT_SAMPLES)).get();
	541	} catch (Error) {
	542	sample_limit = 0;
	543	}
	544
	545	// Create a segment, keep it in the maps of channels
	546	segment = shared_ptr<data::AnalogSegment>(
	547	new data::AnalogSegment(
	548	cur_samplerate_, sample_limit));
	549	cur_analog_segments_[channel] = segment;
	550
	551	// Find the annalog data associated with the channel
	552	shared_ptr<view::AnalogSignal> sig =
	553	dynamic_pointer_cast<view::AnalogSignal>(
	554	signal_from_channel(channel));
	555	assert(sig);
	556
	557	shared_ptr<data::Analog> data(sig->analog_data());
	558	assert(data);
	559
	560	// Push the segment into the analog data.
	561	data->push_segment(segment);
	562	}
	563
	564	assert(segment);
	565
	566	// Append the samples in the segment
	567	segment->append_interleaved_samples(data++, sample_count,
	568	channel_count);
	569	}
	570
	571	if (sweep_beginning) {
	572	// This could be the first packet after a trigger
	573	set_capture_state(Running);
	574	}
	575
	576	data_received();
	577	}
	578
	579	void Session::data_feed_in(shared_ptr<sigrok::Device> device,
	580	shared_ptr<Packet> packet)
	581	{
	582	(void)device;
	583
	584	assert(device);
	585	assert(device == device_->device());
	586	assert(packet);
	587
	588	switch (packet->type()->id()) {
	589	case SR_DF_HEADER:
	590	feed_in_header();
	591	break;
	592
	593	case SR_DF_META:
	594	feed_in_meta(dynamic_pointer_cast<Meta>(packet->payload()));
	595	break;
	596
	597	case SR_DF_FRAME_BEGIN:
	598	feed_in_frame_begin();
	599	break;
	600
	601	case SR_DF_LOGIC:
	602	feed_in_logic(dynamic_pointer_cast<Logic>(packet->payload()));
	603	break;
	604
	605	case SR_DF_ANALOG:
	606	feed_in_analog(dynamic_pointer_cast<Analog>(packet->payload()));
	607	break;
	608
	609	case SR_DF_END:
	610	{
	611	{
	612	lock_guard<recursive_mutex> lock(data_mutex_);
	613	cur_logic_segment_.reset();
	614	cur_analog_segments_.clear();
	615	}
	616	frame_ended();
	617	break;
	618	}
	619	default:
	620	break;
	621	}
	622	}
	623
	624	} // namespace pv