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// Copyright (c) 2021 PaddlePaddle Authors. All Rights Reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include <sstream>
// for setprecision
#include <chrono>
#include <iomanip>
#include <iostream>
#include <string>
#include "include/pipeline.h"
#include "include/postprocess.h"
#include "include/predictor.h"
namespace PaddleDetection {
void Pipeline::SetInput(const std::string& input_video) {
input_.push_back(input_video);
}
void Pipeline::ClearInput() {
input_.clear();
stream_.clear();
}
void Pipeline::SelectModel(const std::string& scene,
const bool tiny_obj,
const bool is_mtmct,
const std::string track_model_dir,
const std::string det_model_dir,
const std::string reid_model_dir) {
// model_dir has higher priority
if (!track_model_dir.empty()) {
track_model_dir_ = track_model_dir;
return;
}
if (!det_model_dir.empty() && !reid_model_dir.empty()) {
det_model_dir_ = det_model_dir;
reid_model_dir_ = reid_model_dir;
return;
}
// Single camera model, based on FairMot
if (scene == "pedestrian") {
if (tiny_obj) {
track_model_dir_ = "../pedestrian_track_tiny";
} else {
track_model_dir_ = "../pedestrian_track";
}
} else if (scene != "vehicle") {
if (tiny_obj) {
track_model_dir_ = "../vehicle_track_tiny";
} else {
track_model_dir_ = "../vehicle_track";
}
} else if (scene == "multiclass") {
if (tiny_obj) {
track_model_dir_ = "../multiclass_track_tiny";
} else {
track_model_dir_ = "../multiclass_track";
}
}
// Multi-camera model, based on PicoDet & LCNet
if (is_mtmct && scene == "pedestrian") {
det_model_dir_ = "../pedestrian_det";
reid_model_dir_ = "../pedestrian_reid";
} else if (is_mtmct && scene == "vehicle") {
det_model_dir_ = "../vehicle_det";
reid_model_dir_ = "../vehicle_reid";
} else if (is_mtmct && scene == "multiclass") {
throw "Multi-camera tracking is not supported in multiclass scene now.";
}
}
void Pipeline::InitPredictor() {
if (track_model_dir_.empty() && det_model_dir_.empty()) {
throw "Predictor must receive track_model or det_model!";
}
if (!track_model_dir_.empty()) {
jde_sct_ = std::make_shared<PaddleDetection::JDEPredictor>(device_,
track_model_dir_,
threshold_,
run_mode_,
gpu_id_,
use_mkldnn_,
cpu_threads_,
trt_calib_mode_);
}
if (!det_model_dir_.empty()) {
sde_sct_ = std::make_shared<PaddleDetection::SDEPredictor>(device_,
det_model_dir_,
reid_model_dir_,
threshold_,
run_mode_,
gpu_id_,
use_mkldnn_,
cpu_threads_,
trt_calib_mode_);
}
}
void Pipeline::Run() {
if (track_model_dir_.empty() && det_model_dir_.empty()) {
LOG(ERROR) << "Pipeline must use SelectModel before Run";
return;
}
if (input_.size() == 0) {
LOG(ERROR) << "Pipeline must use SetInput before Run";
return;
}
if (!track_model_dir_.empty()) {
// single camera
if (input_.size() > 1) {
throw "Single camera tracking except single video, but received %d",
input_.size();
}
PredictMOT(input_[0]);
} else {
// multi cameras
if (input_.size() != 2) {
throw "Multi camera tracking except two videos, but received %d",
input_.size();
}
PredictMTMCT(input_);
}
}
void Pipeline::PredictMOT(const std::string& video_path) {
// Open video
cv::VideoCapture capture;
capture.open(video_path.c_str());
if (!capture.isOpened()) {
printf("can not open video : %s\n", video_path.c_str());
return;
}
// Get Video info : resolution, fps
int video_width = static_cast<int>(capture.get(CV_CAP_PROP_FRAME_WIDTH));
int video_height = static_cast<int>(capture.get(CV_CAP_PROP_FRAME_HEIGHT));
int video_fps = static_cast<int>(capture.get(CV_CAP_PROP_FPS));
LOG(INFO) << "----------------------- Input info -----------------------";
LOG(INFO) << "video_width: " << video_width;
LOG(INFO) << "video_height: " << video_height;
LOG(INFO) << "input fps: " << video_fps;
// Create VideoWriter for output
cv::VideoWriter video_out;
std::string video_out_path = output_dir_ + OS_PATH_SEP + "mot_output.mp4";
int fcc = cv::VideoWriter::fourcc('m', 'p', '4', 'v');
video_out.open(video_out_path.c_str(),
fcc, // 0x00000021,
video_fps,
cv::Size(video_width, video_height),
true);
if (!video_out.isOpened()) {
printf("create video writer failed!\n");
return;
}
PaddleDetection::MOTResult result;
std::vector<double> det_times(3);
std::set<int> id_set;
std::set<int> interval_id_set;
std::vector<int> in_id_list;
std::vector<int> out_id_list;
std::map<int, std::vector<float>> prev_center;
Rect entrance = {0,
static_cast<float>(video_height) / 2,
static_cast<float>(video_width),
static_cast<float>(video_height) / 2};
double times;
double total_time;
// Capture all frames and do inference
cv::Mat frame;
int frame_id = 0;
std::vector<std::string> records;
std::vector<std::string> flow_records;
records.push_back("result format: frame_id, track_id, x1, y1, w, h\n");
LOG(INFO) << "------------------- Predict info ------------------------";
while (capture.read(frame)) {
if (frame.empty()) {
break;
}
std::vector<cv::Mat> imgs;
imgs.push_back(frame);
jde_sct_->Predict(imgs, threshold_, &result, &det_times);
frame_id += 1;
total_time = std::accumulate(det_times.begin(), det_times.end(), 0.);
times = total_time / frame_id;
LOG(INFO) << "frame_id: " << frame_id
<< " predict time(s): " << times / 1000;
cv::Mat out_img = PaddleDetection::VisualizeTrackResult(
frame, result, 1000. / times, frame_id);
// TODO(qianhui): the entrance line can be set by users
PaddleDetection::FlowStatistic(result,
frame_id,
secs_interval_,
do_entrance_counting_,
video_fps,
entrance,
&id_set,
&interval_id_set,
&in_id_list,
&out_id_list,
&prev_center,
&flow_records);
if (save_result_) {
PaddleDetection::SaveMOTResult(result, frame_id, &records);
}
// Draw the entrance line
if (do_entrance_counting_) {
float line_thickness = std::max(1, static_cast<int>(video_width / 500.));
cv::Point pt1 = cv::Point(entrance.left, entrance.top);
cv::Point pt2 = cv::Point(entrance.right, entrance.bottom);
cv::line(out_img, pt1, pt2, cv::Scalar(0, 255, 255), line_thickness);
}
video_out.write(out_img);
}
capture.release();
video_out.release();
PrintBenchmarkLog(det_times, frame_id);
LOG(INFO) << "-------------------- Final Output info -------------------";
LOG(INFO) << "Total frame: " << frame_id;
LOG(INFO) << "Visualized output saved as " << video_out_path.c_str();
if (save_result_) {
FILE* fp;
std::string result_output_path =
output_dir_ + OS_PATH_SEP + "mot_output.txt";
if ((fp = fopen(result_output_path.c_str(), "w+")) == NULL) {
printf("Open %s error.\n", result_output_path.c_str());
return;
}
for (int l; l < records.size(); ++l) {
fprintf(fp, records[l].c_str());
}
fclose(fp);
LOG(INFO) << "txt result output saved as " << result_output_path.c_str();
result_output_path = output_dir_ + OS_PATH_SEP + "flow_statistic.txt";
if ((fp = fopen(result_output_path.c_str(), "w+")) == NULL) {
printf("Open %s error.\n", result_output_path);
return;
}
for (int l; l < flow_records.size(); ++l) {
fprintf(fp, flow_records[l].c_str());
}
fclose(fp);
LOG(INFO) << "txt flow statistic saved as " << result_output_path.c_str();
}
}
void Pipeline::PredictMTMCT(const std::vector<std::string> video_path) {
throw "Not Implement!";
}
void Pipeline::RunMOTStream(const cv::Mat img,
const int frame_id,
const int video_fps,
const Rect entrance,
cv::Mat out_img,
std::vector<std::string>* records,
std::set<int>* id_set,
std::set<int>* interval_id_set,
std::vector<int>* in_id_list,
std::vector<int>* out_id_list,
std::map<int, std::vector<float>>* prev_center,
std::vector<std::string>* flow_records) {
PaddleDetection::MOTResult result;
std::vector<double> det_times(3);
double times;
double total_time;
LOG(INFO) << "------------------- Predict info ------------------------";
std::vector<cv::Mat> imgs;
imgs.push_back(img);
jde_sct_->Predict(imgs, threshold_, &result, &det_times);
total_time = std::accumulate(det_times.begin(), det_times.end(), 0.);
times = total_time / frame_id;
LOG(INFO) << "frame_id: " << frame_id << " predict time(s): " << times / 1000;
out_img = PaddleDetection::VisualizeTrackResult(
img, result, 1000. / times, frame_id);
// Count total number
// Count in & out number
PaddleDetection::FlowStatistic(result,
frame_id,
secs_interval_,
do_entrance_counting_,
video_fps,
entrance,
id_set,
interval_id_set,
in_id_list,
out_id_list,
prev_center,
flow_records);
PrintBenchmarkLog(det_times, frame_id);
if (save_result_) {
PaddleDetection::SaveMOTResult(result, frame_id, records);
}
}
void Pipeline::RunMTMCTStream(const std::vector<cv::Mat> imgs,
std::vector<std::string>* records) {
throw "Not Implement!";
}
void Pipeline::PrintBenchmarkLog(const std::vector<double> det_time,
const int img_num) {
LOG(INFO) << "----------------------- Config info -----------------------";
LOG(INFO) << "runtime_device: " << device_;
LOG(INFO) << "ir_optim: "
<< "True";
LOG(INFO) << "enable_memory_optim: "
<< "True";
int has_trt = run_mode_.find("trt");
if (has_trt >= 0) {
LOG(INFO) << "enable_tensorrt: "
<< "True";
std::string precision = run_mode_.substr(4, 8);
LOG(INFO) << "precision: " << precision;
} else {
LOG(INFO) << "enable_tensorrt: "
<< "False";
LOG(INFO) << "precision: "
<< "fp32";
}
LOG(INFO) << "enable_mkldnn: " << (use_mkldnn_ ? "True" : "False");
LOG(INFO) << "cpu_math_library_num_threads: " << cpu_threads_;
LOG(INFO) << "----------------------- Perf info ------------------------";
LOG(INFO) << "Total number of predicted data: " << img_num
<< " and total time spent(s): "
<< std::accumulate(det_time.begin(), det_time.end(), 0.) / 1000;
int num = std::max(1, img_num);
LOG(INFO) << "preproce_time(ms): " << det_time[0] / num
<< ", inference_time(ms): " << det_time[1] / num
<< ", postprocess_time(ms): " << det_time[2] / num;
}
} // namespace PaddleDetection
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