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CVObjectDetection.cpp
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CVObjectDetection.cpp
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/**
* @file
* @brief Source file for CVObjectDetection class
* @author Jonathan Thomas <jonathan@openshot.org>
* @author Brenno Caldato <brenno.caldato@outlook.com>
*
* @ref License
*/
/* LICENSE
*
* Copyright (c) 2008-2019 OpenShot Studios, LLC
* <http://www.openshotstudios.com/>. This file is part of
* OpenShot Library (libopenshot), an open-source project dedicated to
* delivering high quality video editing and animation solutions to the
* world. For more information visit <http://www.openshot.org/>.
*
* OpenShot Library (libopenshot) is free software: you can redistribute it
* and/or modify it under the terms of the GNU Lesser General Public License
* as published by the Free Software Foundation, either version 3 of the
* License, or (at your option) any later version.
*
* OpenShot Library (libopenshot) 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 Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public License
* along with OpenShot Library. If not, see <http://www.gnu.org/licenses/>.
*/
#include <fstream>
#include <iomanip>
#include <iostream>
#include "CVObjectDetection.h"
#include <google/protobuf/util/time_util.h>
using namespace std;
using namespace openshot;
using google::protobuf::util::TimeUtil;
CVObjectDetection::CVObjectDetection(std::string processInfoJson, ProcessingController &processingController)
: processingController(&processingController), processingDevice("CPU"){
SetJson(processInfoJson);
confThreshold = 0.5;
nmsThreshold = 0.1;
}
void CVObjectDetection::setProcessingDevice(){
if(processingDevice == "GPU"){
net.setPreferableBackend(cv::dnn::DNN_BACKEND_CUDA);
net.setPreferableTarget(cv::dnn::DNN_TARGET_CUDA);
}
else if(processingDevice == "CPU"){
net.setPreferableBackend(cv::dnn::DNN_BACKEND_OPENCV);
net.setPreferableTarget(cv::dnn::DNN_TARGET_CPU);
}
}
void CVObjectDetection::detectObjectsClip(openshot::Clip &video, size_t _start, size_t _end, bool process_interval)
{
start = _start; end = _end;
video.Open();
if(error){
return;
}
processingController->SetError(false, "");
// Load names of classes
std::ifstream ifs(classesFile.c_str());
std::string line;
while (std::getline(ifs, line)) classNames.push_back(line);
// Load the network
if(classesFile == "" || modelConfiguration == "" || modelWeights == "")
return;
net = cv::dnn::readNetFromDarknet(modelConfiguration, modelWeights);
setProcessingDevice();
size_t frame_number;
if(!process_interval || end <= 1 || end-start == 0){
// Get total number of frames in video
start = (int)(video.Start() * video.Reader()->info.fps.ToFloat());
end = (int)(video.End() * video.Reader()->info.fps.ToFloat());
}
for (frame_number = start; frame_number <= end; frame_number++)
{
// Stop the feature tracker process
if(processingController->ShouldStop()){
return;
}
std::shared_ptr<openshot::Frame> f = video.GetFrame(frame_number);
// Grab OpenCV Mat image
cv::Mat cvimage = f->GetImageCV();
DetectObjects(cvimage, frame_number);
// Update progress
processingController->SetProgress(uint(100*(frame_number-start)/(end-start)));
}
}
void CVObjectDetection::DetectObjects(const cv::Mat &frame, size_t frameId){
// Get frame as OpenCV Mat
cv::Mat blob;
// Create a 4D blob from the frame.
int inpWidth, inpHeight;
inpWidth = inpHeight = 416;
cv::dnn::blobFromImage(frame, blob, 1/255.0, cv::Size(inpWidth, inpHeight), cv::Scalar(0,0,0), true, false);
//Sets the input to the network
net.setInput(blob);
// Runs the forward pass to get output of the output layers
std::vector<cv::Mat> outs;
net.forward(outs, getOutputsNames(net));
// Remove the bounding boxes with low confidence
postprocess(frame.size(), outs, frameId);
}
// Remove the bounding boxes with low confidence using non-maxima suppression
void CVObjectDetection::postprocess(const cv::Size &frameDims, const std::vector<cv::Mat>& outs, size_t frameId)
{
std::vector<int> classIds;
std::vector<float> confidences;
std::vector<cv::Rect> boxes;
std::vector<int> objectIds;
for (size_t i = 0; i < outs.size(); ++i)
{
// Scan through all the bounding boxes output from the network and keep only the
// ones with high confidence scores. Assign the box's class label as the class
// with the highest score for the box.
float* data = (float*)outs[i].data;
for (int j = 0; j < outs[i].rows; ++j, data += outs[i].cols)
{
cv::Mat scores = outs[i].row(j).colRange(5, outs[i].cols);
cv::Point classIdPoint;
double confidence;
// Get the value and location of the maximum score
cv::minMaxLoc(scores, 0, &confidence, 0, &classIdPoint);
if (confidence > confThreshold)
{
int centerX = (int)(data[0] * frameDims.width);
int centerY = (int)(data[1] * frameDims.height);
int width = (int)(data[2] * frameDims.width);
int height = (int)(data[3] * frameDims.height);
int left = centerX - width / 2;
int top = centerY - height / 2;
classIds.push_back(classIdPoint.x);
confidences.push_back((float)confidence);
boxes.push_back(cv::Rect(left, top, width, height));
}
}
}
// Perform non maximum suppression to eliminate redundant overlapping boxes with
// lower confidences
std::vector<int> indices;
cv::dnn::NMSBoxes(boxes, confidences, confThreshold, nmsThreshold, indices);
// Pass boxes to SORT algorithm
std::vector<cv::Rect> sortBoxes;
for(auto box : boxes)
sortBoxes.push_back(box);
sort.update(sortBoxes, frameId, sqrt(pow(frameDims.width,2) + pow(frameDims.height, 2)), confidences, classIds);
// Clear data vectors
boxes.clear(); confidences.clear(); classIds.clear(); objectIds.clear();
// Get SORT predicted boxes
for(auto TBox : sort.frameTrackingResult){
if(TBox.frame == frameId){
boxes.push_back(TBox.box);
confidences.push_back(TBox.confidence);
classIds.push_back(TBox.classId);
objectIds.push_back(TBox.id);
}
}
// Remove boxes based on controids distance
for(uint i = 0; i<boxes.size(); i++){
for(uint j = i+1; j<boxes.size(); j++){
int xc_1 = boxes[i].x + (int)(boxes[i].width/2), yc_1 = boxes[i].y + (int)(boxes[i].width/2);
int xc_2 = boxes[j].x + (int)(boxes[j].width/2), yc_2 = boxes[j].y + (int)(boxes[j].width/2);
if(fabs(xc_1 - xc_2) < 10 && fabs(yc_1 - yc_2) < 10){
if(classIds[i] == classIds[j]){
if(confidences[i] >= confidences[j]){
boxes.erase(boxes.begin() + j);
classIds.erase(classIds.begin() + j);
confidences.erase(confidences.begin() + j);
objectIds.erase(objectIds.begin() + j);
break;
}
else{
boxes.erase(boxes.begin() + i);
classIds.erase(classIds.begin() + i);
confidences.erase(confidences.begin() + i);
objectIds.erase(objectIds.begin() + i);
i = 0;
break;
}
}
}
}
}
// Remove boxes based in IOU score
for(uint i = 0; i<boxes.size(); i++){
for(uint j = i+1; j<boxes.size(); j++){
if( iou(boxes[i], boxes[j])){
if(classIds[i] == classIds[j]){
if(confidences[i] >= confidences[j]){
boxes.erase(boxes.begin() + j);
classIds.erase(classIds.begin() + j);
confidences.erase(confidences.begin() + j);
objectIds.erase(objectIds.begin() + j);
break;
}
else{
boxes.erase(boxes.begin() + i);
classIds.erase(classIds.begin() + i);
confidences.erase(confidences.begin() + i);
objectIds.erase(objectIds.begin() + i);
i = 0;
break;
}
}
}
}
}
// Normalize boxes coordinates
std::vector<cv::Rect_<float>> normalized_boxes;
for(auto box : boxes){
cv::Rect_<float> normalized_box;
normalized_box.x = (box.x)/(float)frameDims.width;
normalized_box.y = (box.y)/(float)frameDims.height;
normalized_box.width = (box.width)/(float)frameDims.width;
normalized_box.height = (box.height)/(float)frameDims.height;
normalized_boxes.push_back(normalized_box);
}
detectionsData[frameId] = CVDetectionData(classIds, confidences, normalized_boxes, frameId, objectIds);
}
// Compute IOU between 2 boxes
bool CVObjectDetection::iou(cv::Rect pred_box, cv::Rect sort_box){
// Determine the (x, y)-coordinates of the intersection rectangle
int xA = std::max(pred_box.x, sort_box.x);
int yA = std::max(pred_box.y, sort_box.y);
int xB = std::min(pred_box.x + pred_box.width, sort_box.x + sort_box.width);
int yB = std::min(pred_box.y + pred_box.height, sort_box.y + sort_box.height);
// Compute the area of intersection rectangle
int interArea = std::max(0, xB - xA + 1) * std::max(0, yB - yA + 1);
// Compute the area of both the prediction and ground-truth rectangles
int boxAArea = (pred_box.width + 1) * (pred_box.height + 1);
int boxBArea = (sort_box.width + 1) * (sort_box.height + 1);
// Compute the intersection over union by taking the intersection
float iou = interArea / (float)(boxAArea + boxBArea - interArea);
// If IOU is above this value the boxes are very close (probably a variation of the same bounding box)
if(iou > 0.5)
return true;
return false;
}
// Get the names of the output layers
std::vector<cv::String> CVObjectDetection::getOutputsNames(const cv::dnn::Net& net)
{
static std::vector<cv::String> names;
//Get the indices of the output layers, i.e. the layers with unconnected outputs
std::vector<int> outLayers = net.getUnconnectedOutLayers();
//get the names of all the layers in the network
std::vector<cv::String> layersNames = net.getLayerNames();
// Get the names of the output layers in names
names.resize(outLayers.size());
for (size_t i = 0; i < outLayers.size(); ++i)
names[i] = layersNames[outLayers[i] - 1];
return names;
}
CVDetectionData CVObjectDetection::GetDetectionData(size_t frameId){
// Check if the stabilizer info for the requested frame exists
if ( detectionsData.find(frameId) == detectionsData.end() ) {
return CVDetectionData();
} else {
return detectionsData[frameId];
}
}
bool CVObjectDetection::SaveObjDetectedData(){
// Create tracker message
pb_objdetect::ObjDetect objMessage;
//Save class names in protobuf message
for(int i = 0; i<classNames.size(); i++){
std::string* className = objMessage.add_classnames();
className->assign(classNames.at(i));
}
// Iterate over all frames data and save in protobuf message
for(std::map<size_t,CVDetectionData>::iterator it=detectionsData.begin(); it!=detectionsData.end(); ++it){
CVDetectionData dData = it->second;
pb_objdetect::Frame* pbFrameData;
AddFrameDataToProto(objMessage.add_frame(), dData);
}
// Add timestamp
*objMessage.mutable_last_updated() = TimeUtil::SecondsToTimestamp(time(NULL));
{
// Write the new message to disk.
std::fstream output(protobuf_data_path, ios::out | ios::trunc | ios::binary);
if (!objMessage.SerializeToOstream(&output)) {
cerr << "Failed to write protobuf message." << endl;
return false;
}
}
// Delete all global objects allocated by libprotobuf.
google::protobuf::ShutdownProtobufLibrary();
return true;
}
// Add frame object detection into protobuf message.
void CVObjectDetection::AddFrameDataToProto(pb_objdetect::Frame* pbFrameData, CVDetectionData& dData) {
// Save frame number and rotation
pbFrameData->set_id(dData.frameId);
for(size_t i = 0; i < dData.boxes.size(); i++){
pb_objdetect::Frame_Box* box = pbFrameData->add_bounding_box();
// Save bounding box data
box->set_x(dData.boxes.at(i).x);
box->set_y(dData.boxes.at(i).y);
box->set_w(dData.boxes.at(i).width);
box->set_h(dData.boxes.at(i).height);
box->set_classid(dData.classIds.at(i));
box->set_confidence(dData.confidences.at(i));
box->set_objectid(dData.objectIds.at(i));
}
}
// Load JSON string into this object
void CVObjectDetection::SetJson(const std::string value) {
// Parse JSON string into JSON objects
try
{
const Json::Value root = openshot::stringToJson(value);
// Set all values that match
SetJsonValue(root);
}
catch (const std::exception& e)
{
// Error parsing JSON (or missing keys)
// throw InvalidJSON("JSON is invalid (missing keys or invalid data types)");
std::cout<<"JSON is invalid (missing keys or invalid data types)"<<std::endl;
}
}
// Load Json::Value into this object
void CVObjectDetection::SetJsonValue(const Json::Value root) {
// Set data from Json (if key is found)
if (!root["protobuf_data_path"].isNull()){
protobuf_data_path = (root["protobuf_data_path"].asString());
}
if (!root["processing-device"].isNull()){
processingDevice = (root["processing-device"].asString());
}
if (!root["model-config"].isNull()){
modelConfiguration = (root["model-config"].asString());
std::ifstream infile(modelConfiguration);
if(!infile.good()){
processingController->SetError(true, "Incorrect path to model config file");
error = true;
}
}
if (!root["model-weights"].isNull()){
modelWeights= (root["model-weights"].asString());
std::ifstream infile(modelWeights);
if(!infile.good()){
processingController->SetError(true, "Incorrect path to model weight file");
error = true;
}
}
if (!root["class-names"].isNull()){
classesFile = (root["class-names"].asString());
std::ifstream infile(classesFile);
if(!infile.good()){
processingController->SetError(true, "Incorrect path to class name file");
error = true;
}
}
}
/*
||||||||||||||||||||||||||||||||||||||||||||||||||
ONLY FOR MAKE TEST
||||||||||||||||||||||||||||||||||||||||||||||||||
*/
// Load protobuf data file
bool CVObjectDetection::_LoadObjDetectdData(){
// Create tracker message
pb_objdetect::ObjDetect objMessage;
{
// Read the existing tracker message.
fstream input(protobuf_data_path, ios::in | ios::binary);
if (!objMessage.ParseFromIstream(&input)) {
cerr << "Failed to parse protobuf message." << endl;
return false;
}
}
// Make sure classNames and detectionsData are empty
classNames.clear(); detectionsData.clear();
// Get all classes names and assign a color to them
for(int i = 0; i < objMessage.classnames_size(); i++){
classNames.push_back(objMessage.classnames(i));
}
// Iterate over all frames of the saved message
for (size_t i = 0; i < objMessage.frame_size(); i++) {
// Create protobuf message reader
const pb_objdetect::Frame& pbFrameData = objMessage.frame(i);
// Get frame Id
size_t id = pbFrameData.id();
// Load bounding box data
const google::protobuf::RepeatedPtrField<pb_objdetect::Frame_Box > &pBox = pbFrameData.bounding_box();
// Construct data vectors related to detections in the current frame
std::vector<int> classIds;
std::vector<float> confidences;
std::vector<cv::Rect_<float>> boxes;
std::vector<int> objectIds;
for(int i = 0; i < pbFrameData.bounding_box_size(); i++){
// Get bounding box coordinates
float x = pBox.Get(i).x(); float y = pBox.Get(i).y();
float w = pBox.Get(i).w(); float h = pBox.Get(i).h();
// Create OpenCV rectangle with the bouding box info
cv::Rect_<float> box(x, y, w, h);
// Get class Id (which will be assign to a class name) and prediction confidence
int classId = pBox.Get(i).classid(); float confidence = pBox.Get(i).confidence();
// Get object Id
int objectId = pBox.Get(i).objectid();
// Push back data into vectors
boxes.push_back(box); classIds.push_back(classId); confidences.push_back(confidence);
}
// Assign data to object detector map
detectionsData[id] = CVDetectionData(classIds, confidences, boxes, id, objectIds);
}
// Delete all global objects allocated by libprotobuf.
google::protobuf::ShutdownProtobufLibrary();
return true;
}