Allow re-loading sessions to work with PD output signals

[pulseview.git] / pv / data / decodesignal.hpp

/*
 * This file is part of the PulseView project.
 *
 * Copyright (C) 2017 Soeren Apel <soeren@apelpie.net>
 *
 * 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/>.
 */

#ifndef PULSEVIEW_PV_DATA_DECODESIGNAL_HPP
#define PULSEVIEW_PV_DATA_DECODESIGNAL_HPP

#include <atomic>
#include <deque>
#include <condition_variable>
#include <unordered_set>
#include <vector>

#include <QDebug>
#include <QSettings>

#include <libsigrokdecode/libsigrokdecode.h>

#include <pv/data/decode/decoder.hpp>
#include <pv/data/decode/row.hpp>
#include <pv/data/decode/rowdata.hpp>
#include <pv/data/signalbase.hpp>
#include <pv/util.hpp>

using std::atomic;
using std::condition_variable;
using std::deque;
using std::map;
using std::mutex;
using std::vector;
using std::shared_ptr;

using pv::data::decode::Annotation;
using pv::data::decode::DecodeBinaryClassInfo;
using pv::data::decode::DecodeChannel;
using pv::data::decode::Decoder;
using pv::data::decode::Row;
using pv::data::decode::RowData;

namespace pv {
class Session;

namespace data {

class Logic;
class LogicSegment;
class SignalBase;
class SignalData;

struct DecodeBinaryDataChunk
{
        vector<uint8_t> data;
        uint64_t sample;   ///< Number of the sample where this data was provided by the PD
};

struct DecodeBinaryClass
{
        const Decoder* decoder;
        const DecodeBinaryClassInfo* info;
        deque<DecodeBinaryDataChunk> chunks;
};

struct DecodeSegment
{
        // Constructor is a no-op
        DecodeSegment() { };
        // Copy constructor is a no-op
        DecodeSegment(DecodeSegment&& ds) { (void)ds; qCritical() << "Empty DecodeSegment copy constructor called"; };

        map<const Row*, RowData> annotation_rows;  // Note: Row is the same for all segments while RowData is not
        pv::util::Timestamp start_time;
        double samplerate;
        int64_t samples_decoded_incl, samples_decoded_excl;
        vector<DecodeBinaryClass> binary_classes;
        deque<const Annotation*> all_annotations;
};

class DecodeSignal : public SignalBase
{
        Q_OBJECT

private:
        static const double DecodeMargin;
        static const double DecodeThreshold;
        static const int64_t DecodeChunkLength;

public:
        DecodeSignal(pv::Session &session);
        virtual ~DecodeSignal();

        bool is_decode_signal() const;
        const vector< shared_ptr<Decoder> >& decoder_stack() const;

        void stack_decoder(const srd_decoder *decoder, bool restart_decode=true);
        void remove_decoder(int index);
        bool toggle_decoder_visibility(int index);

        void reset_decode(bool shutting_down = false);
        void begin_decode();
        void pause_decode();
        void resume_decode();
        bool is_paused() const;

        const vector<decode::DecodeChannel> get_channels() const;
        void auto_assign_signals(const shared_ptr<Decoder> dec);
        void assign_signal(const uint16_t channel_id, shared_ptr<const SignalBase> signal);
        int get_assigned_signal_count() const;

        void update_output_signals();

        void set_initial_pin_state(const uint16_t channel_id, const int init_state);

        virtual double get_samplerate() const;
        const pv::util::Timestamp start_time() const;

        /**
         * Returns the number of samples that can be worked on,
         * i.e. the number of samples where samples are available
         * for all connected channels.
         */
        int64_t get_working_sample_count(uint32_t segment_id) const;

        /**
         * Returns the number of processed samples. Newly generated annotations will
         * have sample numbers greater than this.
         *
         * If include_processing is true, this number will include the ones being
         * currently processed (in case the decoder stack is running). In this case,
         * newly generated annotations will have sample numbers smaller than this.
         */
        int64_t get_decoded_sample_count(uint32_t segment_id,
                bool include_processing) const;

        vector<Row*> get_rows(bool visible_only=false);
        vector<const Row*> get_rows(bool visible_only=false) const;

        uint64_t get_annotation_count(const Row* row, uint32_t segment_id) const;

        /**
         * Extracts annotations from a single row into a vector.
         * Note: The annotations may be unsorted and only annotations that fully
         * fit into the sample range are considered.
         */
        void get_annotation_subset(deque<const Annotation*> &dest, const Row* row,
                uint32_t segment_id, uint64_t start_sample, uint64_t end_sample) const;

        /**
         * Extracts annotations from all rows into a vector.
         * Note: The annotations may be unsorted and only annotations that fully
         * fit into the sample range are considered.
         */
        void get_annotation_subset(deque<const Annotation*> &dest, uint32_t segment_id,
                uint64_t start_sample, uint64_t end_sample) const;

        uint32_t get_binary_data_chunk_count(uint32_t segment_id,
                const Decoder* dec, uint32_t bin_class_id) const;
        void get_binary_data_chunk(uint32_t segment_id, const Decoder* dec,
                uint32_t bin_class_id, uint32_t chunk_id, const vector<uint8_t> **dest,
                uint64_t *size);
        void get_merged_binary_data_chunks_by_sample(uint32_t segment_id,
                const Decoder* dec, uint32_t bin_class_id,
                uint64_t start_sample, uint64_t end_sample,
                vector<uint8_t> *dest) const;
        void get_merged_binary_data_chunks_by_offset(uint32_t segment_id,
                const Decoder* dec, uint32_t bin_class_id,
                uint64_t start, uint64_t end,
                vector<uint8_t> *dest) const;
        const DecodeBinaryClass* get_binary_data_class(uint32_t segment_id,
                const Decoder* dec, uint32_t bin_class_id) const;

        const deque<const Annotation*>* get_all_annotations_by_segment(uint32_t segment_id) const;

        virtual void save_settings(QSettings &settings) const;

        virtual void restore_settings(QSettings &settings);

private:
        bool all_input_segments_complete(uint32_t segment_id) const;
        uint32_t get_input_segment_count() const;
        double get_input_samplerate(uint32_t segment_id) const;

        Decoder* get_decoder_by_instance(const srd_decoder *const srd_dec);

        void update_channel_list();

        void commit_decoder_channels();

        void mux_logic_samples(uint32_t segment_id, const int64_t start, const int64_t end);
        void logic_mux_proc();

        void decode_data(const int64_t abs_start_samplenum, const int64_t sample_count,
                const shared_ptr<const LogicSegment> input_segment);
        void decode_proc();

        void start_srd_session();
        void terminate_srd_session();
        void stop_srd_session();

        void connect_input_notifiers();
        void disconnect_input_notifiers();

        void create_decode_segment();

        static void annotation_callback(srd_proto_data *pdata, void *decode_signal);
        static void binary_callback(srd_proto_data *pdata, void *decode_signal);
        static void logic_output_callback(srd_proto_data *pdata, void *decode_signal);

Q_SIGNALS:
        void decoder_stacked(void* decoder); ///< decoder is of type decode::Decoder*
        void decoder_removed(void* decoder); ///< decoder is of type decode::Decoder*
        void new_annotations(); // TODO Supply segment for which they belong to
        void new_binary_data(unsigned int segment_id, void* decoder, unsigned int bin_class_id);
        void decode_reset();
        void decode_finished();
        void channels_updated();
        void annotation_visibility_changed();

private Q_SLOTS:
        void on_capture_state_changed(int state);
        void on_data_cleared();
        void on_data_received();
        void on_input_segment_completed();

        void on_annotation_visibility_changed();

private:
        pv::Session &session_;

        vector<decode::DecodeChannel> channels_;

        struct srd_session *srd_session_;

        shared_ptr<Logic> logic_mux_data_;
        uint32_t logic_mux_unit_size_;
        bool logic_mux_data_invalid_;

        vector< shared_ptr<Decoder> > stack_;
        bool stack_config_changed_;

        deque<DecodeSegment> segments_;
        uint32_t current_segment_id_;

        mutable mutex input_mutex_, output_mutex_, decode_pause_mutex_, logic_mux_mutex_;
        mutable condition_variable decode_input_cond_, decode_pause_cond_,
                logic_mux_cond_;

        std::thread decode_thread_, logic_mux_thread_;
        atomic<bool> decode_interrupt_, logic_mux_interrupt_;

        bool decode_paused_;

        map<const srd_decoder*, shared_ptr<Logic>> output_logic_;
        vector< shared_ptr<SignalBase>> output_signals_;
};

} // namespace data
} // namespace pv

#endif // PULSEVIEW_PV_DATA_DECODESIGNAL_HPP