* 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
+ * along with this program; if not, see <http://www.gnu.org/licenses/>.
*/
#include <libsigrokdecode/libsigrokdecode.h>
#include "decoderstack.hpp"
#include <pv/data/logic.hpp>
-#include <pv/data/logicsnapshot.hpp>
+#include <pv/data/logicsegment.hpp>
#include <pv/data/decode/decoder.hpp>
#include <pv/data/decode/annotation.hpp>
-#include <pv/sigsession.hpp>
+#include <pv/session.hpp>
#include <pv/view/logicsignal.hpp>
using std::lock_guard;
const double DecoderStack::DecodeMargin = 1.0;
const double DecoderStack::DecodeThreshold = 0.2;
const int64_t DecoderStack::DecodeChunkLength = 4096;
-const unsigned int DecoderStack::DecodeNotifyPeriod = 65536;
+const unsigned int DecoderStack::DecodeNotifyPeriod = 1024;
-mutex DecoderStack::global_decode_mutex_;
+mutex DecoderStack::global_srd_mutex_;
-DecoderStack::DecoderStack(pv::SigSession &session,
+DecoderStack::DecoderStack(pv::Session &session,
const srd_decoder *const dec) :
session_(session),
+ start_time_(0),
+ samplerate_(0),
sample_count_(0),
frame_complete_(false),
samples_decoded_(0)
// Find the decoder in the stack
auto iter = stack_.begin();
- for(int i = 0; i < index; i++, iter++)
+ for (int i = 0; i < index; i++, iter++)
assert(iter != stack_.end());
// Delete the element
stack_.erase(iter);
}
+double DecoderStack::samplerate() const
+{
+ return samplerate_;
+}
+
+const pv::util::Timestamp& DecoderStack::start_time() const
+{
+ return start_time_;
+}
+
int64_t DecoderStack::samples_decoded() const
{
lock_guard<mutex> decode_lock(output_mutex_);
vector<Row> rows;
- for (const shared_ptr<decode::Decoder> &dec : stack_)
- {
+ for (const shared_ptr<decode::Decoder> &dec : stack_) {
assert(dec);
if (!dec->shown())
continue;
rows.push_back(Row(decc));
// Add the decoder rows
- for (const GSList *l = decc->annotation_rows; l; l = l->next)
- {
+ for (const GSList *l = decc->annotation_rows; l; l = l->next) {
const srd_decoder_annotation_row *const ann_row =
(srd_decoder_annotation_row *)l->data;
assert(ann_row);
void DecoderStack::begin_decode()
{
- shared_ptr<pv::view::LogicSignal> logic_signal;
- shared_ptr<pv::data::Logic> data;
-
if (decode_thread_.joinable()) {
interrupt_ = true;
input_cond_.notify_one();
}
// Add classes
- for (const shared_ptr<decode::Decoder> &dec : stack_)
- {
+ for (const shared_ptr<decode::Decoder> &dec : stack_) {
assert(dec);
const srd_decoder *const decc = dec->decoder();
assert(dec->decoder());
rows_[Row(decc)] = decode::RowData();
// Add the decoder rows
- for (const GSList *l = decc->annotation_rows; l; l = l->next)
- {
+ for (const GSList *l = decc->annotation_rows; l; l = l->next) {
const srd_decoder_annotation_row *const ann_row =
(srd_decoder_annotation_row *)l->data;
assert(ann_row);
// We get the logic data of the first channel in the list.
// This works because we are currently assuming all
- // LogicSignals have the same data/snapshot
+ // logic signals have the same data/segment
+ pv::data::SignalBase *signalbase;
+ pv::data::Logic *data = nullptr;
+
for (const shared_ptr<decode::Decoder> &dec : stack_)
if (dec && !dec->channels().empty() &&
- ((logic_signal = (*dec->channels().begin()).second)) &&
- ((data = logic_signal->logic_data())))
+ ((signalbase = (*dec->channels().begin()).second.get())) &&
+ ((data = signalbase->logic_data().get())))
break;
if (!data)
return;
- // Check we have a snapshot of data
- const deque< shared_ptr<pv::data::LogicSnapshot> > &snapshots =
- data->get_snapshots();
- if (snapshots.empty())
+ // Check we have a segment of data
+ const deque< shared_ptr<pv::data::LogicSegment> > &segments =
+ data->logic_segments();
+ if (segments.empty())
return;
- snapshot_ = snapshots.front();
+ segment_ = segments.front();
// Get the samplerate and start time
- start_time_ = data->get_start_time();
- samplerate_ = data->samplerate();
+ start_time_ = segment_->start_time();
+ samplerate_ = segment_->samplerate();
if (samplerate_ == 0.0)
samplerate_ = 1.0;
decode_thread_ = std::thread(&DecoderStack::decode_proc, this);
}
-uint64_t DecoderStack::get_max_sample_count() const
+uint64_t DecoderStack::max_sample_count() const
{
uint64_t max_sample_count = 0;
- for (auto i = rows_.cbegin(); i != rows_.end(); i++)
+ for (const auto& row : rows_)
max_sample_count = max(max_sample_count,
- (*i).second.get_max_sample());
+ row.second.get_max_sample());
return max_sample_count;
}
optional<int64_t> DecoderStack::wait_for_data() const
{
unique_lock<mutex> input_lock(input_mutex_);
- while(!interrupt_ && !frame_complete_ &&
- samples_decoded_ >= sample_count_)
+
+ // Do wait if we decoded all samples but we're still capturing
+ // Do not wait if we're done capturing
+ while (!interrupt_ && !frame_complete_ &&
+ (samples_decoded_ >= sample_count_) &&
+ (session_.get_capture_state() != Session::Stopped)) {
+
input_cond_.wait(input_lock);
+ }
+
+ // Return value is valid if we're not aborting the decode,
return boost::make_optional(!interrupt_ &&
- (samples_decoded_ < sample_count_ || !frame_complete_),
+ // and there's more work to do...
+ (samples_decoded_ < sample_count_ || !frame_complete_) &&
+ // and if the end of the data hasn't been reached yet
+ (!((samples_decoded_ >= sample_count_) && (session_.get_capture_state() == Session::Stopped))),
sample_count_);
}
const int64_t sample_count, const unsigned int unit_size,
srd_session *const session)
{
- uint8_t chunk[DecodeChunkLength];
-
const unsigned int chunk_sample_count =
- DecodeChunkLength / snapshot_->unit_size();
+ DecodeChunkLength / segment_->unit_size();
for (int64_t i = 0; !interrupt_ && i < sample_count;
- i += chunk_sample_count)
- {
- lock_guard<mutex> decode_lock(global_decode_mutex_);
+ i += chunk_sample_count) {
const int64_t chunk_end = min(
i + chunk_sample_count, sample_count);
- snapshot_->get_samples(chunk, i, chunk_end);
+ const uint8_t* chunk = segment_->get_samples(i, chunk_end);
- if (srd_session_send(session, i, i + sample_count, chunk,
- (chunk_end - i) * unit_size) != SRD_OK) {
+ if (srd_session_send(session, i, chunk_end, chunk,
+ (chunk_end - i) * unit_size, unit_size) != SRD_OK) {
error_message_ = tr("Decoder reported an error");
break;
}
{
optional<int64_t> sample_count;
srd_session *session;
- srd_decoder_inst *prev_di = NULL;
+ srd_decoder_inst *prev_di = nullptr;
- assert(snapshot_);
+ assert(segment_);
+
+ // Prevent any other decode threads from accessing libsigrokdecode
+ lock_guard<mutex> srd_lock(global_srd_mutex_);
// Create the session
srd_session_new(&session);
assert(session);
// Create the decoders
- const unsigned int unit_size = snapshot_->unit_size();
+ const unsigned int unit_size = segment_->unit_size();
- for (const shared_ptr<decode::Decoder> &dec : stack_)
- {
- srd_decoder_inst *const di = dec->create_decoder_inst(session, unit_size);
+ for (const shared_ptr<decode::Decoder> &dec : stack_) {
+ srd_decoder_inst *const di = dec->create_decoder_inst(session);
- if (!di)
- {
+ if (!di) {
error_message_ = tr("Failed to create decoder instance");
srd_session_destroy(session);
return;
// Get the intial sample count
{
unique_lock<mutex> input_lock(input_mutex_);
- sample_count = sample_count_ = snapshot_->get_sample_count();
+ sample_count = sample_count_ = segment_->get_sample_count();
}
// Start the session
do {
decode_data(*sample_count, unit_size, session);
- } while(error_message_.isEmpty() && (sample_count = wait_for_data()));
+ } while (error_message_.isEmpty() && (sample_count = wait_for_data()));
// Destroy the session
srd_session_destroy(session);
assert(decc);
auto row_iter = d->rows_.end();
-
+
// Try looking up the sub-row of this class
const auto r = d->class_rows_.find(make_pair(decc, a.format()));
if (r != d->class_rows_.end())
row_iter = d->rows_.find((*r).second);
- else
- {
+ else {
// Failing that, use the decoder as a key
row_iter = d->rows_.find(Row(decc));
}
{
{
unique_lock<mutex> lock(input_mutex_);
- if (snapshot_)
- sample_count_ = snapshot_->get_sample_count();
+ if (segment_)
+ sample_count_ = segment_->get_sample_count();
}
input_cond_.notify_one();
}
{
{
unique_lock<mutex> lock(input_mutex_);
- if (snapshot_)
+ if (segment_)
frame_complete_ = true;
}
input_cond_.notify_one();