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openpilot is an open source driver assistance system. openpilot performs the functions of Automated Lane Centering and Adaptive Cruise Control for over 200 supported car makes and models.
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openpilot_comma/tools/cabana/streams/abstractstream.cc

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#include "tools/cabana/streams/abstractstream.h"
#include <QTimer>
AbstractStream *can = nullptr;
AbstractStream::AbstractStream(QObject *parent, bool is_live_streaming) : is_live_streaming(is_live_streaming), QObject(parent) {
can = this;
new_msgs = std::make_unique<QHash<MessageId, CanData>>();
QObject::connect(this, &AbstractStream::received, this, &AbstractStream::process, Qt::QueuedConnection);
QObject::connect(this, &AbstractStream::seekedTo, this, &AbstractStream::updateLastMsgsTo);
}
void AbstractStream::process(QHash<MessageId, CanData> *messages) {
for (auto it = messages->begin(); it != messages->end(); ++it) {
last_msgs[it.key()] = it.value();
}
emit updated();
emit msgsReceived(messages);
delete messages;
processing = false;
}
bool AbstractStream::updateEvent(const Event *event) {
static double prev_update_ts = 0;
if (event->which == cereal::Event::Which::CAN) {
double current_sec = event->mono_time / 1e9 - routeStartTime();
for (const auto &c : event->event.getCan()) {
MessageId id = {.source = c.getSrc(), .address = c.getAddress()};
CanData &data = (*new_msgs)[id];
data.ts = current_sec;
data.dat = QByteArray((char *)c.getDat().begin(), c.getDat().size());
data.count = ++counters[id];
data.freq = data.count / std::max(1.0, current_sec);
auto &tracker = change_trackers[id];
tracker.compute(data.dat, data.ts, data.freq);
data.colors = tracker.colors;
data.last_change_t = tracker.last_change_t;
data.bit_change_counts = tracker.bit_change_counts;
if (!sources.contains(id.source)) {
sources.insert(id.source);
emit sourcesUpdated(sources);
}
}
double ts = millis_since_boot();
if ((ts - prev_update_ts) > (1000.0 / settings.fps) && !processing && !new_msgs->isEmpty()) {
// delay posting CAN message if UI thread is busy
processing = true;
prev_update_ts = ts;
// use pointer to avoid data copy in queued connection.
emit received(new_msgs.release());
new_msgs.reset(new QHash<MessageId, CanData>);
new_msgs->reserve(100);
}
}
return true;
}
const CanData &AbstractStream::lastMessage(const MessageId &id) {
static CanData empty_data;
auto it = last_msgs.find(id);
return it != last_msgs.end() ? it.value() : empty_data;
}
// it is thread safe to update data in updateLastMsgsTo.
// updateEvent will not be called before replayStream::seekedTo return.
void AbstractStream::updateLastMsgsTo(double sec) {
new_msgs->clear();
change_trackers.clear();
last_msgs.clear();
counters.clear();
CanEvent last_event = {.mono_time = uint64_t((sec + routeStartTime()) * 1e9)};
for (auto &[id, e] : events_) {
auto it = std::lower_bound(e.crbegin(), e.crend(), last_event, std::greater<CanEvent>());
if (it != e.crend()) {
auto &m = last_msgs[id];
m.dat = QByteArray((const char *)it->dat, it->size);
m.ts = it->mono_time / 1e9 - routeStartTime();
m.count = std::distance(it, e.crend());
m.freq = m.count / std::max(1.0, m.ts);
m.last_change_t = QVector<double>(m.dat.size(), m.ts);
m.colors = QVector<QColor>(m.dat.size(), QColor(0, 0, 0, 0));
m.bit_change_counts = QVector<std::array<uint32_t, 8>>(m.dat.size());
counters[id] = m.count;
}
}
QTimer::singleShot(0, [this]() {
emit updated();
emit msgsReceived(&last_msgs);
});
}
void AbstractStream::parseEvents(std::unordered_map<MessageId, std::deque<CanEvent>> &msgs,
std::vector<Event *>::const_iterator first, std::vector<Event *>::const_iterator last) {
for (; first != last; ++first) {
if ((*first)->which == cereal::Event::Which::CAN) {
for (const auto &c : (*first)->event.getCan()) {
auto dat = c.getDat();
auto &m = msgs[{.source = c.getSrc(), .address = c.getAddress()}].emplace_back();
m.size = std::min(dat.size(), std::size(m.dat));
memcpy(m.dat, (uint8_t *)dat.begin(), m.size);
m.mono_time = (*first)->mono_time;
}
last_event_ts = std::max(last_event_ts, (*first)->mono_time);
}
}
}
void AbstractStream::mergeEvents(std::vector<Event *>::const_iterator first, std::vector<Event *>::const_iterator last, bool append) {
if (first == last) return;
if (append) {
parseEvents(events_, first, last);
} else {
std::unordered_map<MessageId, std::deque<CanEvent>> new_events;
parseEvents(new_events, first, last);
for (auto &[id, new_e] : new_events) {
auto &e = events_[id];
auto it = std::upper_bound(e.cbegin(), e.cend(), new_e.front());
e.insert(it, new_e.cbegin(), new_e.cend());
}
}
emit eventsMerged();
}