using std::make_pair;
using std::make_shared;
using std::min;
+using std::out_of_range;
using std::shared_ptr;
using std::unique_lock;
using pv::data::decode::Annotation;
session_(session),
srd_session_(nullptr),
logic_mux_data_invalid_(false),
- start_time_(0),
- samplerate_(0),
- samples_decoded_(0),
- frame_complete_(false)
+ current_segment_id_(0)
{
connect(&session_, SIGNAL(capture_state_changed(int)),
this, SLOT(on_capture_state_changed(int)));
stop_srd_session();
- frame_complete_ = false;
- samples_decoded_ = 0;
- error_message_ = QString();
-
- rows_.clear();
- current_rows_= nullptr;
class_rows_.clear();
+ current_segment_id_ = 0;
+ segments_.clear();
logic_mux_data_.reset();
logic_mux_data_invalid_ = true;
+ error_message_ = QString();
+
decode_reset();
}
}
}
- prepare_annotation_segment();
-
// Free the logic data and its segment(s) if it needs to be updated
if (logic_mux_data_invalid_)
logic_mux_data_.reset();
if (!logic_mux_data_) {
- const int64_t ch_count = get_assigned_signal_count();
- const int64_t unit_size = (ch_count + 7) / 8;
+ const uint32_t ch_count = get_assigned_signal_count();
+ logic_mux_unit_size_ = (ch_count + 7) / 8;
logic_mux_data_ = make_shared<Logic>(ch_count);
- logic_mux_segment_ = make_shared<LogicSegment>(*logic_mux_data_, unit_size, samplerate_);
- logic_mux_data_->push_segment(logic_mux_segment_);
+ }
+
+ // Receive notifications when new sample data is available
+ connect_input_notifiers();
+
+ if (get_input_segment_count() == 0) {
+ error_message_ = tr("No input data");
+ return;
}
// Make sure the logic output data is complete and up-to-date
// Decode the muxed logic data
decode_interrupt_ = false;
decode_thread_ = std::thread(&DecodeSignal::decode_proc, this);
-
- // Receive notifications when new sample data is available
- connect_input_notifiers();
}
QString DecodeSignal::error_message() const
double DecodeSignal::samplerate() const
{
- return samplerate_;
+ double result = 0;
+
+ // TODO For now, we simply return the first samplerate that we have
+ if (segments_.size() > 0)
+ result = segments_.front().samplerate;
+
+ return result;
}
-const pv::util::Timestamp& DecodeSignal::start_time() const
+const pv::util::Timestamp DecodeSignal::start_time() const
{
- return start_time_;
+ pv::util::Timestamp result;
+
+ // TODO For now, we simply return the first start time that we have
+ if (segments_.size() > 0)
+ result = segments_.front().start_time;
+
+ return result;
}
-int64_t DecodeSignal::get_working_sample_count() const
+int64_t DecodeSignal::get_working_sample_count(uint32_t segment_id) const
{
// The working sample count is the highest sample number for
- // which all used signals have data available, so go through
- // all channels and use the lowest overall sample count of the
- // current segment
-
- // TODO Currently, we assume only a single segment exists
+ // which all used signals have data available, so go through all
+ // channels and use the lowest overall sample count of the segment
int64_t count = std::numeric_limits<int64_t>::max();
bool no_signals_assigned = true;
if (!logic_data || logic_data->logic_segments().empty())
return 0;
- const shared_ptr<LogicSegment> segment = logic_data->logic_segments().front();
- count = min(count, (int64_t)segment->get_sample_count());
+ try {
+ const shared_ptr<LogicSegment> segment = logic_data->logic_segments().at(segment_id);
+ count = min(count, (int64_t)segment->get_sample_count());
+ } catch (out_of_range) {
+ return 0;
+ }
}
return (no_signals_assigned ? 0 : count);
}
-int64_t DecodeSignal::get_decoded_sample_count() const
+int64_t DecodeSignal::get_decoded_sample_count(uint32_t segment_id) const
{
lock_guard<mutex> decode_lock(output_mutex_);
- return samples_decoded_;
+
+ int64_t result = 0;
+
+ try {
+ const DecodeSegment *segment = &(segments_.at(segment_id));
+ result = segment->samples_decoded;
+ } catch (out_of_range) {
+ // Do nothing
+ }
+
+ return result;
}
vector<Row> DecodeSignal::visible_rows() const
void DecodeSignal::get_annotation_subset(
vector<pv::data::decode::Annotation> &dest,
- const decode::Row &row, uint64_t start_sample,
+ const decode::Row &row, uint32_t segment_id, uint64_t start_sample,
uint64_t end_sample) const
{
lock_guard<mutex> lock(output_mutex_);
- if (!current_rows_)
- return;
-
- // TODO Instead of current_rows_, use rows_ and the ID of the segment
-
- const auto iter = current_rows_->find(row);
- if (iter != current_rows_->end())
- (*iter).second.get_annotation_subset(dest,
- start_sample, end_sample);
+ try {
+ const DecodeSegment *segment = &(segments_.at(segment_id));
+ const map<const decode::Row, decode::RowData> *rows =
+ &(segment->annotation_rows);
+
+ const auto iter = rows->find(row);
+ if (iter != rows->end())
+ (*iter).second.get_annotation_subset(dest,
+ start_sample, end_sample);
+ } catch (out_of_range) {
+ // Do nothing
+ }
}
void DecodeSignal::save_settings(QSettings &settings) const
// Include the newly created decode channels in the channel lists
update_channel_list();
- commit_decoder_channels();
break;
}
}
settings.endGroup();
}
+ // Update the internal structures
+ update_channel_list();
+ commit_decoder_channels();
+
begin_decode();
}
+uint32_t DecodeSignal::get_input_segment_count() const
+{
+ uint64_t count = std::numeric_limits<uint64_t>::max();
+ bool no_signals_assigned = true;
+
+ for (const data::DecodeChannel &ch : channels_)
+ if (ch.assigned_signal) {
+ no_signals_assigned = false;
+
+ const shared_ptr<Logic> logic_data = ch.assigned_signal->logic_data();
+ if (!logic_data || logic_data->logic_segments().empty())
+ return 0;
+
+ // Find the min value of all segment counts
+ if ((uint64_t)(logic_data->logic_segments().size()) < count)
+ count = logic_data->logic_segments().size();
+ }
+
+ return (no_signals_assigned ? 0 : count);
+}
+
+uint32_t DecodeSignal::get_input_samplerate(uint32_t segment_id) const
+{
+ double samplerate = 0;
+
+ for (const data::DecodeChannel &ch : channels_)
+ if (ch.assigned_signal) {
+ const shared_ptr<Logic> logic_data = ch.assigned_signal->logic_data();
+ if (!logic_data || logic_data->logic_segments().empty())
+ continue;
+
+ try {
+ const shared_ptr<LogicSegment> segment = logic_data->logic_segments().at(segment_id);
+ samplerate = segment->samplerate();
+ } catch (out_of_range) {
+ // Do nothing
+ }
+ break;
+ }
+
+ return samplerate;
+}
+
void DecodeSignal::update_channel_list()
{
vector<data::DecodeChannel> prev_channels = channels_;
dec->set_channels(channel_list);
}
+
+ // Channel bit IDs must be in sync with the channel's apperance in channels_
+ int id = 0;
+ for (data::DecodeChannel &ch : channels_)
+ if (ch.assigned_signal)
+ ch.bit_id = id++;
}
-void DecodeSignal::mux_logic_samples(const int64_t start, const int64_t end)
+void DecodeSignal::mux_logic_samples(uint32_t segment_id, const int64_t start, const int64_t end)
{
// Enforce end to be greater than start
if (end <= start)
return;
- // Fetch all segments and their data
- // TODO Currently, we assume only a single segment exists
+ // Fetch the channel segments and their data
vector<shared_ptr<LogicSegment> > segments;
vector<const uint8_t*> signal_data;
vector<uint8_t> signal_in_bytepos;
vector<uint8_t> signal_in_bitpos;
- int id = 0;
for (data::DecodeChannel &ch : channels_)
if (ch.assigned_signal) {
- ch.bit_id = id++;
-
const shared_ptr<Logic> logic_data = ch.assigned_signal->logic_data();
- const shared_ptr<LogicSegment> segment = logic_data->logic_segments().front();
+
+ shared_ptr<LogicSegment> segment;
+ try {
+ segment = logic_data->logic_segments().at(segment_id);
+ } catch (out_of_range) {
+ qDebug() << "Muxer error for" << name() << ":" << ch.assigned_signal->name() \
+ << "has no logic segment" << segment_id;
+ return;
+ }
segments.push_back(segment);
uint8_t* data = new uint8_t[(end - start) * segment->unit_size()];
signal_in_bitpos.push_back(bitpos % 8);
}
+
+ shared_ptr<LogicSegment> output_segment;
+ try {
+ output_segment = logic_mux_data_->logic_segments().at(segment_id);
+ } catch (out_of_range) {
+ qDebug() << "Muxer error for" << name() << ": no logic mux segment" \
+ << segment_id << "in mux_logic_samples(), mux segments size is" \
+ << logic_mux_data_->logic_segments().size();
+ return;
+ }
+
// Perform the muxing of signal data into the output data
- uint8_t* output = new uint8_t[(end - start) * logic_mux_segment_->unit_size()];
+ uint8_t* output = new uint8_t[(end - start) * output_segment->unit_size()];
unsigned int signal_count = signal_data.size();
for (int64_t sample_cnt = 0; sample_cnt < (end - start); sample_cnt++) {
int bitpos = 0;
uint8_t bytepos = 0;
- const int out_sample_pos = sample_cnt * logic_mux_segment_->unit_size();
- for (unsigned int i = 0; i < logic_mux_segment_->unit_size(); i++)
+ const int out_sample_pos = sample_cnt * output_segment->unit_size();
+ for (unsigned int i = 0; i < output_segment->unit_size(); i++)
output[out_sample_pos + i] = 0;
for (unsigned int i = 0; i < signal_count; i++) {
}
}
- logic_mux_segment_->append_payload(output, (end - start) * logic_mux_segment_->unit_size());
+ output_segment->append_payload(output, (end - start) * output_segment->unit_size());
delete[] output;
for (const uint8_t* data : signal_data)
void DecodeSignal::logic_mux_proc()
{
+ uint32_t segment_id = 0;
+
+ assert(logic_mux_data_);
+
+ // Create initial logic mux segment
+ shared_ptr<LogicSegment> output_segment =
+ make_shared<LogicSegment>(*logic_mux_data_, segment_id,
+ logic_mux_unit_size_, 0);
+ logic_mux_data_->push_segment(output_segment);
+
+ output_segment->set_samplerate(get_input_samplerate(0));
+
do {
- const uint64_t input_sample_count = get_working_sample_count();
- const uint64_t output_sample_count = logic_mux_segment_->get_sample_count();
+ const uint64_t input_sample_count = get_working_sample_count(segment_id);
+ const uint64_t output_sample_count = output_segment->get_sample_count();
const uint64_t samples_to_process =
(input_sample_count > output_sample_count) ?
// Process the samples if necessary...
if (samples_to_process > 0) {
- const uint64_t unit_size = logic_mux_segment_->unit_size();
+ const uint64_t unit_size = output_segment->unit_size();
const uint64_t chunk_sample_count = DecodeChunkLength / unit_size;
uint64_t processed_samples = 0;
const uint64_t sample_count =
min(samples_to_process - processed_samples, chunk_sample_count);
- mux_logic_samples(start_sample, start_sample + sample_count);
+ mux_logic_samples(segment_id, start_sample, start_sample + sample_count);
processed_samples += sample_count;
// ...and process the newly muxed logic data
}
if (samples_to_process == 0) {
- // Wait for more input
- unique_lock<mutex> logic_mux_lock(logic_mux_mutex_);
- logic_mux_cond_.wait(logic_mux_lock);
+ // TODO Optimize this by caching the input segment count and only
+ // querying it when the cached value was reached
+ if (segment_id < get_input_segment_count() - 1) {
+ // Process next segment
+ segment_id++;
+
+ output_segment =
+ make_shared<LogicSegment>(*logic_mux_data_, segment_id,
+ logic_mux_unit_size_, 0);
+ logic_mux_data_->push_segment(output_segment);
+
+ output_segment->set_samplerate(get_input_samplerate(segment_id));
+
+ } else {
+ // All segments have been processed
+ logic_mux_data_invalid_ = false;
+
+ // Wait for more input
+ unique_lock<mutex> logic_mux_lock(logic_mux_mutex_);
+ logic_mux_cond_.wait(logic_mux_lock);
+ }
}
} while (!logic_mux_interrupt_);
-
- // No more input data and session is stopped, let the decode thread
- // process any pending data, terminate and release the global SRD mutex
- // in order to let other decoders run
- decode_input_cond_.notify_one();
-}
-
-void DecodeSignal::query_input_metadata()
-{
- // Update the samplerate and start time because we cannot start
- // the libsrd session without the current samplerate
-
- // TODO Currently we assume all channels have the same sample rate
- // and start time
- bool samplerate_valid = false;
- data::DecodeChannel *any_channel;
- shared_ptr<Logic> logic_data;
-
- do {
- any_channel = &(*find_if(channels_.begin(), channels_.end(),
- [](data::DecodeChannel ch) { return ch.assigned_signal; }));
-
- logic_data = any_channel->assigned_signal->logic_data();
-
- if (!logic_data) {
- // Wait until input data is available or an interrupt was requested
- unique_lock<mutex> input_wait_lock(input_mutex_);
- decode_input_cond_.wait(input_wait_lock);
- }
- } while (!logic_data && !decode_interrupt_);
-
- if (decode_interrupt_)
- return;
-
- do {
- if (!logic_data->logic_segments().empty()) {
- shared_ptr<LogicSegment> first_segment =
- any_channel->assigned_signal->logic_data()->logic_segments().front();
- start_time_ = first_segment->start_time();
- samplerate_ = first_segment->samplerate();
- if (samplerate_ > 0)
- samplerate_valid = true;
- }
-
- if (!samplerate_valid) {
- // Wait until input data is available or an interrupt was requested
- unique_lock<mutex> input_wait_lock(input_mutex_);
- decode_input_cond_.wait(input_wait_lock);
- }
- } while (!samplerate_valid && !decode_interrupt_);
}
void DecodeSignal::decode_data(
- const int64_t abs_start_samplenum, const int64_t sample_count)
+ const int64_t abs_start_samplenum, const int64_t sample_count,
+ const shared_ptr<LogicSegment> input_segment)
{
- const int64_t unit_size = logic_mux_segment_->unit_size();
+ const int64_t unit_size = input_segment->unit_size();
const int64_t chunk_sample_count = DecodeChunkLength / unit_size;
for (int64_t i = abs_start_samplenum;
int64_t data_size = (chunk_end - i) * unit_size;
uint8_t* chunk = new uint8_t[data_size];
- logic_mux_segment_->get_samples(i, chunk_end, chunk);
+ input_segment->get_samples(i, chunk_end, chunk);
if (srd_session_send(srd_session_, i, chunk_end, chunk,
data_size, unit_size) != SRD_OK) {
{
lock_guard<mutex> lock(output_mutex_);
- samples_decoded_ = chunk_end;
+ segments_.at(current_segment_id_).samples_decoded = chunk_end;
}
// Notify the frontend that we processed some data and
void DecodeSignal::decode_proc()
{
- query_input_metadata();
+ current_segment_id_ = 0;
+
+ // If there is no input data available yet, wait until it is or we're interrupted
+ if (logic_mux_data_->logic_segments().size() == 0) {
+ unique_lock<mutex> input_wait_lock(input_mutex_);
+ decode_input_cond_.wait(input_wait_lock);
+ }
if (decode_interrupt_)
return;
+ shared_ptr<LogicSegment> input_segment = logic_mux_data_->logic_segments().front();
+ assert(input_segment);
+
+ // Create the initial segment and set its sample rate so that we can pass it to SRD
+ create_decode_segment();
+ segments_.at(current_segment_id_).samplerate = input_segment->samplerate();
+ segments_.at(current_segment_id_).start_time = input_segment->start_time();
+
start_srd_session();
- uint64_t sample_count;
+ uint64_t sample_count = 0;
uint64_t abs_start_samplenum = 0;
do {
// Keep processing new samples until we exhaust the input data
do {
lock_guard<mutex> input_lock(input_mutex_);
- sample_count = logic_mux_segment_->get_sample_count() - abs_start_samplenum;
+ sample_count = input_segment->get_sample_count() - abs_start_samplenum;
if (sample_count > 0) {
- decode_data(abs_start_samplenum, sample_count);
+ decode_data(abs_start_samplenum, sample_count, input_segment);
abs_start_samplenum += sample_count;
}
} while (error_message_.isEmpty() && (sample_count > 0) && !decode_interrupt_);
- if (error_message_.isEmpty() && !decode_interrupt_) {
- if (sample_count == 0)
+ if (error_message_.isEmpty() && !decode_interrupt_ && sample_count == 0) {
+ if (current_segment_id_ < logic_mux_data_->logic_segments().size() - 1) {
+ // Process next segment
+ current_segment_id_++;
+
+ try {
+ input_segment = logic_mux_data_->logic_segments().at(current_segment_id_);
+ } catch (out_of_range) {
+ qDebug() << "Decode error for" << name() << ": no logic mux segment" \
+ << current_segment_id_ << "in decode_proc(), mux segments size is" \
+ << logic_mux_data_->logic_segments().size();
+ return;
+ }
+ abs_start_samplenum = 0;
+
+ // Create the next segment and set its metadata
+ create_decode_segment();
+ segments_.at(current_segment_id_).samplerate = input_segment->samplerate();
+ segments_.at(current_segment_id_).start_time = input_segment->start_time();
+
+ // Reset decoder state
+ stop_srd_session();
+ start_srd_session();
+ } else {
+ // All segments have been processed
decode_finished();
- // Wait for new input data or an interrupt was requested
- unique_lock<mutex> input_wait_lock(input_mutex_);
- decode_input_cond_.wait(input_wait_lock);
+ // Wait for new input data or an interrupt was requested
+ unique_lock<mutex> input_wait_lock(input_mutex_);
+ decode_input_cond_.wait(input_wait_lock);
+ }
}
} while (error_message_.isEmpty() && !decode_interrupt_);
}
void DecodeSignal::start_srd_session()
{
+ uint64_t samplerate;
+
if (srd_session_)
stop_srd_session();
if (!di) {
error_message_ = tr("Failed to create decoder instance");
srd_session_destroy(srd_session_);
+ srd_session_ = nullptr;
return;
}
}
// Start the session
- srd_session_metadata_set(srd_session_, SRD_CONF_SAMPLERATE,
- g_variant_new_uint64(samplerate_));
+ samplerate = segments_.at(current_segment_id_).samplerate;
+ if (samplerate)
+ srd_session_metadata_set(srd_session_, SRD_CONF_SAMPLERATE,
+ g_variant_new_uint64(samplerate));
srd_pd_output_callback_add(srd_session_, SRD_OUTPUT_ANN,
DecodeSignal::annotation_callback, this);
}
}
-void DecodeSignal::prepare_annotation_segment()
+void DecodeSignal::create_decode_segment()
{
- // TODO Won't work for multiple segments
- rows_.emplace_back(map<const decode::Row, decode::RowData>());
- current_rows_ = &(rows_.back());
+ // Create annotation segment
+ segments_.emplace_back(DecodeSegment());
// Add annotation classes
for (const shared_ptr<decode::Decoder> &dec : stack_) {
// Add a row for the decoder if it doesn't have a row list
if (!decc->annotation_rows)
- (*current_rows_)[Row(decc)] = decode::RowData();
+ (segments_.back().annotation_rows)[Row(decc)] =
+ decode::RowData();
// Add the decoder rows
for (const GSList *l = decc->annotation_rows; l; l = l->next) {
const Row row(decc, ann_row);
// Add a new empty row data object
- (*current_rows_)[row] = decode::RowData();
+ (segments_.back().annotation_rows)[row] =
+ decode::RowData();
}
}
}
assert(pdata->pdo->di);
const srd_decoder *const decc = pdata->pdo->di->decoder;
assert(decc);
- assert(ds->current_rows_);
const srd_proto_data_annotation *const pda =
(const srd_proto_data_annotation*)pdata->data;
assert(pda);
- auto row_iter = ds->current_rows_->end();
+ auto row_iter = ds->segments_.at(ds->current_segment_id_).annotation_rows.end();
// Try looking up the sub-row of this class
const auto format = pda->ann_class;
const auto r = ds->class_rows_.find(make_pair(decc, format));
if (r != ds->class_rows_.end())
- row_iter = ds->current_rows_->find((*r).second);
+ row_iter = ds->segments_.at(ds->current_segment_id_).annotation_rows.find((*r).second);
else {
// Failing that, use the decoder as a key
- row_iter = ds->current_rows_->find(Row(decc));
+ row_iter = ds->segments_.at(ds->current_segment_id_).annotation_rows.find(Row(decc));
}
- if (row_iter == ds->current_rows_->end()) {
+ if (row_iter == ds->segments_.at(ds->current_segment_id_).annotation_rows.end()) {
qDebug() << "Unexpected annotation: decoder = " << decc <<
", format = " << format;
assert(false);
void DecodeSignal::on_capture_state_changed(int state)
{
// If a new acquisition was started, we need to start decoding from scratch
- if (state == Session::Running)
+ if (state == Session::Running) {
+ logic_mux_data_invalid_ = true;
begin_decode();
+ }
}
void DecodeSignal::on_data_cleared()