#include <cstdio>
#include <cstdlib>
#include <cstdint>
#include <cassert>
#include <unistd.h>
#include <signal.h>
#include <errno.h>
#include <poll.h>
#include <string.h>
#include <inttypes.h>
#include <libyuv.h>
#include <sys/resource.h>
#include <pthread.h>
#include <string>
#include <iostream>
#include <fstream>
#include <streambuf>
#include <thread>
#include <mutex>
#include <condition_variable>
#include <atomic>
#include <random>
#include <ftw.h>
#ifdef QCOM
#include <cutils/properties.h>
#endif
#include "common/version.h"
#include "common/timing.h"
#include "common/params.h"
#include "common/swaglog.h"
#include "common/visionipc.h"
#include "common/utilpp.h"
#include "common/util.h"
#include "camerad/cameras/camera_common.h"
#include "logger.h"
#include "messaging.hpp"
#include "services.h"
#if !(defined(QCOM) || defined(QCOM2))
// no encoder on PC
#define DISABLE_ENCODER
#endif
#ifndef DISABLE_ENCODER
#include "encoder.h"
#include "raw_logger.h"
#endif
#define MAIN_BITRATE 5000000
#define QCAM_BITRATE 128000
#define MAIN_FPS 20
#ifndef QCOM2
#define MAX_CAM_IDX LOG_CAMERA_ID_DCAMERA
#define DCAM_BITRATE 2500000
#else
#define MAX_CAM_IDX LOG_CAMERA_ID_ECAMERA
#define DCAM_BITRATE MAIN_BITRATE
#endif
#define NO_CAMERA_PATIENCE 500 // fall back to time-based rotation if all cameras are dead
LogCameraInfo cameras_logged[LOG_CAMERA_ID_MAX] = {
[LOG_CAMERA_ID_FCAMERA] = {
.stream_type = VISION_STREAM_YUV,
.filename = "fcamera.hevc",
.frame_packet_name = "frame",
.encode_idx_name = "encodeIdx",
.fps = MAIN_FPS,
.bitrate = MAIN_BITRATE,
.is_h265 = true,
.downscale = false,
.has_qcamera = true
},
[LOG_CAMERA_ID_DCAMERA] = {
.stream_type = VISION_STREAM_YUV_FRONT,
.filename = "dcamera.hevc",
.frame_packet_name = "frontFrame",
.encode_idx_name = "frontEncodeIdx",
.fps = MAIN_FPS, // on EONs, more compressed this way
.bitrate = DCAM_BITRATE,
.is_h265 = true,
.downscale = false,
.has_qcamera = false
},
[LOG_CAMERA_ID_ECAMERA] = {
.stream_type = VISION_STREAM_YUV_WIDE,
.filename = "ecamera.hevc",
.frame_packet_name = "wideFrame",
.encode_idx_name = "wideEncodeIdx",
.fps = MAIN_FPS,
.bitrate = MAIN_BITRATE,
.is_h265 = true,
.downscale = false,
.has_qcamera = false
},
[LOG_CAMERA_ID_QCAMERA] = {
.filename = "qcamera.ts",
.fps = MAIN_FPS,
.bitrate = QCAM_BITRATE,
.is_h265 = false,
.downscale = true,
#ifndef QCOM2
.frame_width = 480, .frame_height = 360
#else
.frame_width = 526, .frame_height = 330 // keep pixel count the same?
#endif
},
};
#define SEGMENT_LENGTH 60
#define LOG_ROOT "/data/media/0/realdata"
#define RAW_CLIP_LENGTH 100 // 5 seconds at 20fps
#define RAW_CLIP_FREQUENCY (randrange(61, 8*60)) // once every ~4 minutes
namespace {
double randrange(double a, double b) __attribute__((unused));
double randrange(double a, double b) {
static std::mt19937 gen(millis_since_boot());
std::uniform_real_distribution<> dist(a, b);
return dist(gen);
}
volatile sig_atomic_t do_exit = 0;
static void set_do_exit(int sig) {
do_exit = 1;
}
class RotateState {
public:
SubSocket* fpkt_sock;
uint32_t stream_frame_id, log_frame_id, last_rotate_frame_id;
bool enabled, should_rotate, initialized;
RotateState() : fpkt_sock(nullptr), stream_frame_id(0), log_frame_id(0),
last_rotate_frame_id(UINT32_MAX), enabled(false), should_rotate(false), initialized(false) {};
void waitLogThread() {
std::unique_lock<std::mutex> lk(fid_lock);
while (stream_frame_id > log_frame_id //if the log camera is older, wait for it to catch up.
&& (stream_frame_id - log_frame_id) < 8 // but if its too old then there probably was a discontinuity (visiond restarted)
&& !do_exit) {
cv.wait(lk);
}
}
void cancelWait() { cv.notify_one(); }
void setStreamFrameId(uint32_t frame_id) {
fid_lock.lock();
stream_frame_id = frame_id;
fid_lock.unlock();
cv.notify_one();
}
void setLogFrameId(uint32_t frame_id) {
fid_lock.lock();
log_frame_id = frame_id;
fid_lock.unlock();
cv.notify_one();
}
void rotate() {
if (!enabled) { return; }
std::unique_lock<std::mutex> lk(fid_lock);
should_rotate = true;
last_rotate_frame_id = stream_frame_id;
}
void finish_rotate() {
std::unique_lock<std::mutex> lk(fid_lock);
should_rotate = false;
}
private:
std::mutex fid_lock;
std::condition_variable cv;
};
struct LoggerdState {
Context *ctx;
LoggerState logger;
char segment_path[4096];
int rotate_segment;
pthread_mutex_t rotate_lock;
int num_encoder;
std::atomic<int> rotate_seq_id;
std::atomic<int> should_close;
std::atomic<int> finish_close;
RotateState rotate_state[LOG_CAMERA_ID_MAX-1];
};
LoggerdState s;
#ifndef DISABLE_ENCODER
void encoder_thread(RotateState *rotate_state, bool raw_clips, int cam_idx) {
switch (cam_idx) {
case LOG_CAMERA_ID_DCAMERA: {
LOGW("recording front camera");
set_thread_name("FrontCameraEncoder");
break;
}
case LOG_CAMERA_ID_FCAMERA: {
set_thread_name("RearCameraEncoder");
break;
}
case LOG_CAMERA_ID_ECAMERA: {
set_thread_name("WideCameraEncoder");
break;
}
default: {
LOGE("unexpected camera index provided");
assert(false);
}
}
VisionStream stream;
bool encoder_inited = false;
EncoderState encoder;
EncoderState encoder_alt;
bool has_encoder_alt = cameras_logged[cam_idx].has_qcamera;
int encoder_segment = -1;
int cnt = 0;
pthread_mutex_lock(&s.rotate_lock);
int my_idx = s.num_encoder;
s.num_encoder += 1;
pthread_mutex_unlock(&s.rotate_lock);
PubSocket *idx_sock = PubSocket::create(s.ctx, cameras_logged[cam_idx].encode_idx_name);
assert(idx_sock != NULL);
LoggerHandle *lh = NULL;
while (!do_exit) {
VisionStreamBufs buf_info;
int err = visionstream_init(&stream, cameras_logged[cam_idx].stream_type, false, &buf_info);
if (err != 0) {
LOGD("visionstream connect fail");
usleep(100000);
continue;
}
if (!encoder_inited) {
LOGD("encoder init %dx%d", buf_info.width, buf_info.height);
encoder_init(&encoder, cameras_logged[cam_idx].filename,
buf_info.width,
buf_info.height,
cameras_logged[cam_idx].fps,
cameras_logged[cam_idx].bitrate,
cameras_logged[cam_idx].is_h265,
cameras_logged[cam_idx].downscale);
if (has_encoder_alt) {
encoder_init(&encoder_alt, cameras_logged[LOG_CAMERA_ID_QCAMERA].filename,
cameras_logged[LOG_CAMERA_ID_QCAMERA].frame_width,
cameras_logged[LOG_CAMERA_ID_QCAMERA].frame_height,
cameras_logged[LOG_CAMERA_ID_QCAMERA].fps,
cameras_logged[LOG_CAMERA_ID_QCAMERA].bitrate,
cameras_logged[LOG_CAMERA_ID_QCAMERA].is_h265,
cameras_logged[LOG_CAMERA_ID_QCAMERA].downscale);
}
encoder_inited = true;
}
// dont log a raw clip in the first minute
double rawlogger_start_time = seconds_since_boot()+RAW_CLIP_FREQUENCY;
int rawlogger_clip_cnt = 0;
RawLogger *rawlogger = NULL;
if (raw_clips) {
rawlogger = new RawLogger("prcamera", buf_info.width, buf_info.height, MAIN_FPS);
}
while (!do_exit) {
VIPCBufExtra extra;
VIPCBuf* buf = visionstream_get(&stream, &extra);
if (buf == NULL) {
LOG("visionstream get failed");
break;
}
//uint64_t current_time = nanos_since_boot();
//uint64_t diff = current_time - extra.timestamp_eof;
//double msdiff = (double) diff / 1000000.0;
// printf("logger latency to tsEof: %f\n", msdiff);
{ // all the rotation stuff
pthread_mutex_lock(&s.rotate_lock);
pthread_mutex_unlock(&s.rotate_lock);
// wait if camera pkt id is older than stream
rotate_state->waitLogThread();
if (do_exit) break;
// rotate the encoder if the logger is on a newer segment
if (rotate_state->should_rotate) {
if (!rotate_state->initialized) {
rotate_state->last_rotate_frame_id = extra.frame_id - 1;
rotate_state->initialized = true;
}
while (s.rotate_seq_id != my_idx && !do_exit) { usleep(1000); }
LOGW("camera %d rotate encoder to %s.", cam_idx, s.segment_path);
encoder_rotate(&encoder, s.segment_path, s.rotate_segment);
s.rotate_seq_id = (my_idx + 1) % s.num_encoder;
if (has_encoder_alt) {
encoder_rotate(&encoder_alt, s.segment_path, s.rotate_segment);
}
if (raw_clips) {
rawlogger->Rotate(s.segment_path, s.rotate_segment);
}
encoder_segment = s.rotate_segment;
if (lh) {
lh_close(lh);
}
lh = logger_get_handle(&s.logger);
pthread_mutex_lock(&s.rotate_lock);
s.should_close += 1;
pthread_mutex_unlock(&s.rotate_lock);
while(s.should_close > 0 && s.should_close < s.num_encoder && !do_exit) { usleep(1000); }
pthread_mutex_lock(&s.rotate_lock);
s.should_close = s.should_close == s.num_encoder ? 1 - s.num_encoder : s.should_close + 1;
encoder_close(&encoder);
encoder_open(&encoder, encoder.next_path);
encoder.segment = encoder.next_segment;
encoder.rotating = false;
if (has_encoder_alt) {
encoder_close(&encoder_alt);
encoder_open(&encoder_alt, encoder_alt.next_path);
encoder_alt.segment = encoder_alt.next_segment;
encoder_alt.rotating = false;
}
s.finish_close += 1;
pthread_mutex_unlock(&s.rotate_lock);
while(s.finish_close > 0 && s.finish_close < s.num_encoder && !do_exit) { usleep(1000); }
s.finish_close = 0;
rotate_state->finish_rotate();
}
}
rotate_state->setStreamFrameId(extra.frame_id);
uint8_t *y = (uint8_t*)buf->addr;
uint8_t *u = y + (buf_info.width*buf_info.height);
uint8_t *v = u + (buf_info.width/2)*(buf_info.height/2);
{
// encode hevc
int out_segment = -1;
int out_id = encoder_encode_frame(&encoder,
y, u, v,
buf_info.width, buf_info.height,
&out_segment, &extra);
if (has_encoder_alt) {
int out_segment_alt = -1;
encoder_encode_frame(&encoder_alt,
y, u, v,
buf_info.width, buf_info.height,
&out_segment_alt, &extra);
}
// publish encode index
MessageBuilder msg;
auto eidx = msg.initEvent().initEncodeIdx();
eidx.setFrameId(extra.frame_id);
#ifdef QCOM2
eidx.setType(cereal::EncodeIndex::Type::FULL_H_E_V_C);
#else
eidx.setType(cam_idx == LOG_CAMERA_ID_DCAMERA ? cereal::EncodeIndex::Type::FRONT:cereal::EncodeIndex::Type::FULL_H_E_V_C);
#endif
eidx.setEncodeId(cnt);
eidx.setSegmentNum(out_segment);
eidx.setSegmentId(out_id);
auto bytes = msg.toBytes();
if (idx_sock->send((char*)bytes.begin(), bytes.size()) < 0) {
printf("err sending encodeIdx pkt: %s\n", strerror(errno));
}
if (lh) {
lh_log(lh, bytes.begin(), bytes.size(), false);
}
}
if (raw_clips) {
double ts = seconds_since_boot();
if (ts > rawlogger_start_time) {
// encode raw if in clip
int out_segment = -1;
int out_id = rawlogger->LogFrame(cnt, y, u, v, &out_segment);
if (rawlogger_clip_cnt == 0) {
LOG("starting raw clip in seg %d", out_segment);
}
// publish encode index
MessageBuilder msg;
auto eidx = msg.initEvent().initEncodeIdx();
eidx.setFrameId(extra.frame_id);
eidx.setType(cereal::EncodeIndex::Type::FULL_LOSSLESS_CLIP);
eidx.setEncodeId(cnt);
eidx.setSegmentNum(out_segment);
eidx.setSegmentId(out_id);
auto bytes = msg.toBytes();
if (lh) {
lh_log(lh, bytes.begin(), bytes.size(), false);
}
// close rawlogger if clip ended
rawlogger_clip_cnt++;
if (rawlogger_clip_cnt >= RAW_CLIP_LENGTH) {
rawlogger->Close();
rawlogger_clip_cnt = 0;
rawlogger_start_time = ts+RAW_CLIP_FREQUENCY;
LOG("ending raw clip in seg %d, next in %.1f sec", out_segment, rawlogger_start_time-ts);
}
}
}
cnt++;
}
if (lh) {
lh_close(lh);
lh = NULL;
}
if (raw_clips) {
rawlogger->Close();
delete rawlogger;
}
visionstream_destroy(&stream);
}
delete idx_sock;
if (encoder_inited) {
LOG("encoder destroy");
encoder_close(&encoder);
encoder_destroy(&encoder);
}
if (has_encoder_alt) {
LOG("encoder alt destroy");
encoder_close(&encoder_alt);
encoder_destroy(&encoder_alt);
}
}
#endif
}
void append_property(const char* key, const char* value, void *cookie) {
std::vector<std::pair<std::string, std::string> > *properties =
(std::vector<std::pair<std::string, std::string> > *)cookie;
properties->push_back(std::make_pair(std::string(key), std::string(value)));
}
kj::Array<capnp::word> gen_init_data() {
MessageBuilder msg;
auto init = msg.initEvent().initInitData();
init.setDeviceType(cereal::InitData::DeviceType::NEO);
init.setVersion(capnp::Text::Reader(COMMA_VERSION));
std::ifstream cmdline_stream("/proc/cmdline");
std::vector<std::string> kernel_args;
std::string buf;
while (cmdline_stream >> buf) {
kernel_args.push_back(buf);
}
auto lkernel_args = init.initKernelArgs(kernel_args.size());
for (int i=0; i<kernel_args.size(); i++) {
lkernel_args.set(i, kernel_args[i]);
}
init.setKernelVersion(util::read_file("/proc/version"));
#ifdef QCOM
{
std::vector<std::pair<std::string, std::string> > properties;
property_list(append_property, (void*)&properties);
auto lentries = init.initAndroidProperties().initEntries(properties.size());
for (int i=0; i<properties.size(); i++) {
auto lentry = lentries[i];
lentry.setKey(properties[i].first);
lentry.setValue(properties[i].second);
}
}
#endif
const char* dongle_id = getenv("DONGLE_ID");
if (dongle_id) {
init.setDongleId(std::string(dongle_id));
}
const char* clean = getenv("CLEAN");
if (!clean) {
init.setDirty(true);
}
Params params = Params();
std::vector<char> git_commit = params.read_db_bytes("GitCommit");
if (git_commit.size() > 0) {
init.setGitCommit(capnp::Text::Reader(git_commit.data(), git_commit.size()));
}
std::vector<char> git_branch = params.read_db_bytes("GitBranch");
if (git_branch.size() > 0) {
init.setGitBranch(capnp::Text::Reader(git_branch.data(), git_branch.size()));
}
std::vector<char> git_remote = params.read_db_bytes("GitRemote");
if (git_remote.size() > 0) {
init.setGitRemote(capnp::Text::Reader(git_remote.data(), git_remote.size()));
}
init.setPassive(params.read_db_bool("Passive"));
{
// log params
std::map<std::string, std::string> params_map;
params.read_db_all(¶ms_map);
auto lparams = init.initParams().initEntries(params_map.size());
int i = 0;
for (auto& kv : params_map) {
auto lentry = lparams[i];
lentry.setKey(kv.first);
lentry.setValue(kv.second);
i++;
}
}
return capnp::messageToFlatArray(msg);
}
static int clear_locks_fn(const char* fpath, const struct stat *sb, int tyupeflag) {
const char* dot = strrchr(fpath, '.');
if (dot && strcmp(dot, ".lock") == 0) {
unlink(fpath);
}
return 0;
}
static void clear_locks() {
ftw(LOG_ROOT, clear_locks_fn, 16);
}
static void bootlog() {
int err;
{
auto words = gen_init_data();
auto bytes = words.asBytes();
logger_init(&s.logger, "bootlog", bytes.begin(), bytes.size(), false);
}
err = logger_next(&s.logger, LOG_ROOT, s.segment_path, sizeof(s.segment_path), &s.rotate_segment);
assert(err == 0);
LOGW("bootlog to %s", s.segment_path);
{
MessageBuilder msg;
auto boot = msg.initEvent().initBoot();
boot.setWallTimeNanos(nanos_since_epoch());
std::string lastKmsg = util::read_file("/sys/fs/pstore/console-ramoops");
boot.setLastKmsg(capnp::Data::Reader((const kj::byte*)lastKmsg.data(), lastKmsg.size()));
std::string lastPmsg = util::read_file("/sys/fs/pstore/pmsg-ramoops-0");
boot.setLastPmsg(capnp::Data::Reader((const kj::byte*)lastPmsg.data(), lastPmsg.size()));
std::string launchLog = util::read_file("/tmp/launch_log");
boot.setLaunchLog(capnp::Text::Reader(launchLog.data(), launchLog.size()));
auto bytes = msg.toBytes();
logger_log(&s.logger, bytes.begin(), bytes.size(), false);
}
logger_close(&s.logger);
}
int main(int argc, char** argv) {
int err;
if (argc > 1 && strcmp(argv[1], "--bootlog") == 0) {
bootlog();
return 0;
}
int segment_length = SEGMENT_LENGTH;
if (getenv("LOGGERD_TEST")) {
segment_length = atoi(getenv("LOGGERD_SEGMENT_LENGTH"));
}
bool record_front = true;
#ifndef QCOM2
record_front = Params().read_db_bool("RecordFront");
#endif
setpriority(PRIO_PROCESS, 0, -12);
clear_locks();
signal(SIGINT, (sighandler_t)set_do_exit);
signal(SIGTERM, (sighandler_t)set_do_exit);
s.ctx = Context::create();
Poller * poller = Poller::create();
// subscribe to all services
std::vector<SubSocket*> socks;
std::map<SubSocket*, int> qlog_counter;
std::map<SubSocket*, int> qlog_freqs;
for (const auto& it : services) {
std::string name = it.name;
if (it.should_log) {
SubSocket * sock = SubSocket::create(s.ctx, name);
assert(sock != NULL);
poller->registerSocket(sock);
socks.push_back(sock);
for (int cid=0;cid<=MAX_CAM_IDX;cid++) {
if (name == cameras_logged[cid].frame_packet_name) { s.rotate_state[cid].fpkt_sock = sock; }
}
qlog_counter[sock] = (it.decimation == -1) ? -1 : 0;
qlog_freqs[sock] = it.decimation;
}
}
{
auto words = gen_init_data();
auto bytes = words.asBytes();
logger_init(&s.logger, "rlog", bytes.begin(), bytes.size(), true);
}
s.rotate_seq_id = 0;
s.should_close = 0;
s.finish_close = 0;
s.num_encoder = 0;
pthread_mutex_init(&s.rotate_lock, NULL);
#ifndef DISABLE_ENCODER
// rear camera
std::thread encoder_thread_handle(encoder_thread, &s.rotate_state[LOG_CAMERA_ID_FCAMERA], false, LOG_CAMERA_ID_FCAMERA);
s.rotate_state[LOG_CAMERA_ID_FCAMERA].enabled = true;
// front camera
std::thread front_encoder_thread_handle;
if (record_front) {
front_encoder_thread_handle = std::thread(encoder_thread, &s.rotate_state[LOG_CAMERA_ID_DCAMERA], false, LOG_CAMERA_ID_DCAMERA);
s.rotate_state[LOG_CAMERA_ID_DCAMERA].enabled = true;
}
#ifdef QCOM2
// wide camera
std::thread wide_encoder_thread_handle(encoder_thread, &s.rotate_state[LOG_CAMERA_ID_ECAMERA], false, LOG_CAMERA_ID_ECAMERA);
s.rotate_state[LOG_CAMERA_ID_ECAMERA].enabled = true;
#endif
#endif
uint64_t msg_count = 0;
uint64_t bytes_count = 0;
kj::Array<capnp::word> buf = kj::heapArray<capnp::word>(1024);
double start_ts = seconds_since_boot();
double last_rotate_tms = millis_since_boot();
double last_camera_seen_tms = millis_since_boot();
while (!do_exit) {
for (auto sock : poller->poll(100 * 1000)) {
Message * last_msg = nullptr;
while (true) {
Message * msg = sock->receive(true);
if (msg == NULL){
break;
}
delete last_msg;
last_msg = msg;
logger_log(&s.logger, (uint8_t*)msg->getData(), msg->getSize(), qlog_counter[sock] == 0);
if (qlog_counter[sock] != -1) {
//printf("%p: %d/%d\n", socks[i], qlog_counter[socks[i]], qlog_freqs[socks[i]]);
qlog_counter[sock]++;
qlog_counter[sock] %= qlog_freqs[sock];
}
bytes_count += msg->getSize();
msg_count++;
}
if (last_msg) {
int fpkt_id = -1;
for (int cid=0;cid<=MAX_CAM_IDX;cid++) {
if (sock == s.rotate_state[cid].fpkt_sock) {fpkt_id=cid; break;}
}
if (fpkt_id>=0) {
// track camera frames to sync to encoder
// only process last frame
const uint8_t* data = (uint8_t*)last_msg->getData();
const size_t len = last_msg->getSize();
const size_t size = len / sizeof(capnp::word) + 1;
if (buf.size() < size) {
buf = kj::heapArray<capnp::word>(size);
}
memcpy(buf.begin(), data, len);
capnp::FlatArrayMessageReader cmsg(buf);
cereal::Event::Reader event = cmsg.getRoot<cereal::Event>();
if (fpkt_id == LOG_CAMERA_ID_FCAMERA) {
s.rotate_state[fpkt_id].setLogFrameId(event.getFrame().getFrameId());
} else if (fpkt_id == LOG_CAMERA_ID_DCAMERA) {
s.rotate_state[fpkt_id].setLogFrameId(event.getFrontFrame().getFrameId());
} else if (fpkt_id == LOG_CAMERA_ID_ECAMERA) {
s.rotate_state[fpkt_id].setLogFrameId(event.getWideFrame().getFrameId());
}
last_camera_seen_tms = millis_since_boot();
}
delete last_msg;
}
}
double ts = seconds_since_boot();
double tms = millis_since_boot();
bool new_segment = false;
if (s.logger.part > -1) {
new_segment = true;
if (tms - last_camera_seen_tms <= NO_CAMERA_PATIENCE) {
for (int cid=0;cid<=MAX_CAM_IDX;cid++) {
// this *should* be redundant on tici since all camera frames are synced
new_segment &= (((s.rotate_state[cid].stream_frame_id >= s.rotate_state[cid].last_rotate_frame_id + segment_length * MAIN_FPS) &&
(!s.rotate_state[cid].should_rotate) && (s.rotate_state[cid].initialized)) ||
(!s.rotate_state[cid].enabled));
#ifndef QCOM2
break; // only look at fcamera frame id if not QCOM2
#endif
}
} else {
new_segment &= tms - last_rotate_tms > segment_length * 1000;
if (new_segment) { LOGW("no camera packet seen. auto rotated"); }
}
} else if (s.logger.part == -1) {
// always starts first segment immediately
new_segment = true;
}
if (new_segment) {
pthread_mutex_lock(&s.rotate_lock);
last_rotate_tms = millis_since_boot();
err = logger_next(&s.logger, LOG_ROOT, s.segment_path, sizeof(s.segment_path), &s.rotate_segment);
assert(err == 0);
if (s.logger.part == 0) { LOGW("logging to %s", s.segment_path); }
LOGW("rotated to %s", s.segment_path);
// rotate the encoders
for (int cid=0;cid<=MAX_CAM_IDX;cid++) { s.rotate_state[cid].rotate(); }
pthread_mutex_unlock(&s.rotate_lock);
}
if ((msg_count%1000) == 0) {
LOGD("%lu messages, %.2f msg/sec, %.2f KB/sec", msg_count, msg_count*1.0/(ts-start_ts), bytes_count*0.001/(ts-start_ts));
}
}
LOGW("joining threads");
for (int cid=0;cid<=MAX_CAM_IDX;cid++) { s.rotate_state[cid].cancelWait(); }
#ifndef DISABLE_ENCODER
#ifdef QCOM2
wide_encoder_thread_handle.join();
#endif
if (record_front) {
front_encoder_thread_handle.join();
}
encoder_thread_handle.join();
LOGW("encoder joined");
#endif
logger_close(&s.logger);
for (auto s : socks){
delete s;
}
delete poller;
delete s.ctx;
return 0;
}