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main.cpp
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main.cpp
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#include <opencv2/opencv.hpp>
#include "TrtNet.h"
#include "argsParser.h"
#include "configs.h"
#include <chrono>
#include "YoloLayer.h"
#include "dataReader.h"
#include "eval.h"
using namespace std;
using namespace argsParser;
using namespace Tn;
using namespace Yolo;
vector<float> prepareImage(cv::Mat& img)
{
using namespace cv;
int c = parser::getIntValue("C");
int h = parser::getIntValue("H"); //net h
int w = parser::getIntValue("W"); //net w
float scale = min(float(w)/img.cols,float(h)/img.rows);
auto scaleSize = cv::Size(img.cols * scale,img.rows * scale);
cv::Mat rgb ;
cv::cvtColor(img, rgb, CV_BGR2RGB);
cv::Mat resized;
cv::resize(rgb, resized,scaleSize,0,0,INTER_CUBIC);
cv::Mat cropped(h, w,CV_8UC3, 127);
Rect rect((w- scaleSize.width)/2, (h-scaleSize.height)/2, scaleSize.width,scaleSize.height);
resized.copyTo(cropped(rect));
cv::Mat img_float;
if (c == 3)
cropped.convertTo(img_float, CV_32FC3, 1/255.0);
else
cropped.convertTo(img_float, CV_32FC1 ,1/255.0);
//HWC TO CHW
vector<Mat> input_channels(c);
cv::split(img_float, input_channels);
vector<float> result(h*w*c);
auto data = result.data();
int channelLength = h * w;
for (int i = 0; i < c; ++i) {
memcpy(data,input_channels[i].data,channelLength*sizeof(float));
data += channelLength;
}
return result;
}
void DoNms(vector<Detection>& detections,int classes ,float nmsThresh)
{
auto t_start = chrono::high_resolution_clock::now();
vector<vector<Detection>> resClass;
resClass.resize(classes);
for (const auto& item : detections)
resClass[item.classId].push_back(item);
auto iouCompute = [](float * lbox, float* rbox)
{
float interBox[] = {
max(lbox[0] - lbox[2]/2.f , rbox[0] - rbox[2]/2.f), //left
min(lbox[0] + lbox[2]/2.f , rbox[0] + rbox[2]/2.f), //right
max(lbox[1] - lbox[3]/2.f , rbox[1] - rbox[3]/2.f), //top
min(lbox[1] + lbox[3]/2.f , rbox[1] + rbox[3]/2.f), //bottom
};
if(interBox[2] > interBox[3] || interBox[0] > interBox[1])
return 0.0f;
float interBoxS =(interBox[1]-interBox[0])*(interBox[3]-interBox[2]);
return interBoxS/(lbox[2]*lbox[3] + rbox[2]*rbox[3] -interBoxS);
};
vector<Detection> result;
for (int i = 0;i<classes;++i)
{
auto& dets =resClass[i];
if(dets.size() == 0)
continue;
sort(dets.begin(),dets.end(),[=](const Detection& left,const Detection& right){
return left.prob > right.prob;
});
for (unsigned int m = 0;m < dets.size() ; ++m)
{
auto& item = dets[m];
result.push_back(item);
for(unsigned int n = m + 1;n < dets.size() ; ++n)
{
if (iouCompute(item.bbox,dets[n].bbox) > nmsThresh)
{
dets.erase(dets.begin()+n);
--n;
}
}
}
}
//swap(detections,result);
detections = move(result);
auto t_end = chrono::high_resolution_clock::now();
float total = chrono::duration<float, milli>(t_end - t_start).count();
cout << "Time taken for nms is " << total << " ms." << endl;
}
vector<Bbox> postProcessImg(cv::Mat& img,vector<Detection>& detections,int classes)
{
using namespace cv;
int h = parser::getIntValue("H"); //net h
int w = parser::getIntValue("W"); //net w
//scale bbox to img
int width = img.cols;
int height = img.rows;
float scale = min(float(w)/width,float(h)/height);
float scaleSize[] = {width * scale,height * scale};
//correct box
for (auto& item : detections)
{
auto& bbox = item.bbox;
bbox[0] = (bbox[0] * w - (w - scaleSize[0])/2.f) / scaleSize[0];
bbox[1] = (bbox[1] * h - (h - scaleSize[1])/2.f) / scaleSize[1];
bbox[2] /= scaleSize[0];
bbox[3] /= scaleSize[1];
}
//nms
float nmsThresh = parser::getFloatValue("nms");
if(nmsThresh > 0)
DoNms(detections,classes,nmsThresh);
vector<Bbox> boxes;
for(const auto& item : detections)
{
auto& b = item.bbox;
Bbox bbox =
{
item.classId, //classId
max(int((b[0]-b[2]/2.)*width),0), //left
min(int((b[0]+b[2]/2.)*width),width), //right
max(int((b[1]-b[3]/2.)*height),0), //top
min(int((b[1]+b[3]/2.)*height),height), //bot
item.prob //score
};
boxes.push_back(bbox);
}
return boxes;
}
vector<string> split(const string& str, char delim)
{
stringstream ss(str);
string token;
vector<string> container;
while (getline(ss, token, delim)) {
container.push_back(token);
}
return container;
}
int main( int argc, char* argv[] )
{
parser::ADD_ARG_STRING("prototxt",Desc("input yolov3 deploy"),DefaultValue(INPUT_PROTOTXT),ValueDesc("file"));
parser::ADD_ARG_STRING("caffemodel",Desc("input yolov3 caffemodel"),DefaultValue(INPUT_CAFFEMODEL),ValueDesc("file"));
parser::ADD_ARG_INT("C",Desc("channel"),DefaultValue(to_string(INPUT_CHANNEL)));
parser::ADD_ARG_INT("H",Desc("height"),DefaultValue(to_string(INPUT_HEIGHT)));
parser::ADD_ARG_INT("W",Desc("width"),DefaultValue(to_string(INPUT_WIDTH)));
parser::ADD_ARG_STRING("calib",Desc("calibration image List"),DefaultValue(CALIBRATION_LIST),ValueDesc("file"));
parser::ADD_ARG_STRING("mode",Desc("runtime mode"),DefaultValue(MODE), ValueDesc("fp32/fp16/int8"));
parser::ADD_ARG_STRING("outputs",Desc("output nodes name"),DefaultValue(OUTPUTS));
parser::ADD_ARG_INT("class",Desc("num of classes"),DefaultValue(to_string(DETECT_CLASSES)));
parser::ADD_ARG_FLOAT("nms",Desc("non-maximum suppression value"),DefaultValue(to_string(NMS_THRESH)));
parser::ADD_ARG_INT("batchsize",Desc("batch size for input"),DefaultValue("1"));
parser::ADD_ARG_STRING("enginefile",Desc("load from engine"),DefaultValue(""));
//input
parser::ADD_ARG_STRING("input",Desc("input image file"),DefaultValue(INPUT_IMAGE),ValueDesc("file"));
parser::ADD_ARG_STRING("evallist",Desc("eval gt list"),DefaultValue(EVAL_LIST),ValueDesc("file"));
if(argc < 2){
parser::printDesc();
exit(-1);
}
parser::parseArgs(argc,argv);
std::unique_ptr<trtNet> net;
int batchSize = parser::getIntValue("batchsize");
string engineName = parser::getStringValue("enginefile");
if(engineName.length() > 0)
{
net.reset(new trtNet(engineName));
assert(net->getBatchSize() == batchSize);
}
else
{
string deployFile = parser::getStringValue("prototxt");
string caffemodelFile = parser::getStringValue("caffemodel");
vector<vector<float>> calibData;
string calibFileList = parser::getStringValue("calib");
string mode = parser::getStringValue("mode");
if(calibFileList.length() > 0 && mode == "int8")
{
cout << "find calibration file,loading ..." << endl;
ifstream file(calibFileList);
if(!file.is_open())
{
cout << "read file list error,please check file :" << calibFileList << endl;
exit(-1);
}
string strLine;
while( getline(file,strLine) )
{
cv::Mat img = cv::imread(strLine);
if (img.empty())
{
std::cerr << "fail to load image:" << strLine << std::endl;
continue;
}
auto data = prepareImage(img);
calibData.emplace_back(data);
}
file.close();
}
RUN_MODE run_mode = RUN_MODE::FLOAT32;
if(mode == "int8")
{
if(calibFileList.length() == 0)
cout << "run int8 please input calibration file, will run in fp32" << endl;
else
run_mode = RUN_MODE::INT8;
}
else if(mode == "fp16")
{
run_mode = RUN_MODE::FLOAT16;
}
string outputNodes = parser::getStringValue("outputs");
auto outputNames = split(outputNodes,',');
//save Engine name
string saveName = "yolov3_" + mode + ".engine";
net.reset(new trtNet(deployFile,caffemodelFile,outputNames,calibData,run_mode,batchSize));
cout << "save Engine..." << saveName <<endl;
net->saveEngine(saveName);
}
int outputCount = net->getOutputSize()/sizeof(float);
unique_ptr<float[]> outputData(new float[outputCount]);
string listFile = parser::getStringValue("evallist");
list<string> fileNames;
list<vector<Bbox>> groundTruth;
if(listFile.length() > 0)
{
std::cout << "loading from eval list " << listFile << std::endl;
tie(fileNames,groundTruth) = readObjectLabelFileList(listFile);
}
else
{
string inputFileName = parser::getStringValue("input");
fileNames.push_back(inputFileName);
}
list<vector<Bbox>> outputs;
int classNum = parser::getIntValue("class");
int c = parser::getIntValue("C");
int h = parser::getIntValue("H");
int w = parser::getIntValue("W");
int batchCount = 0;
vector<float> inputData;
inputData.reserve(h*w*c*batchSize);
vector<cv::Mat> inputImgs;
auto iter = fileNames.begin();
for (unsigned int i = 0;i < fileNames.size(); ++i ,++iter)
{
const string& filename = *iter;
std::cout << "process: " << filename << std::endl;
cv::Mat img = cv::imread(filename);
if (img.empty())
{
std::cerr << "fail to load image:" << filename << std::endl;
continue;
}
vector<float> curInput = prepareImage(img);
inputImgs.emplace_back(img);
inputData.insert(inputData.end(), curInput.begin(), curInput.end());
batchCount++;
if(batchCount < batchSize && i + 1 < fileNames.size())
continue;
net->doInference(inputData.data(), outputData.get(),batchCount);
//Get Output
auto output = outputData.get();
auto outputSize = net->getOutputSize()/ sizeof(float) / batchCount;
for(int i = 0;i< batchCount ; ++i)
{
//first detect count
int detCount = output[0];
//later detect result
vector<Detection> result;
result.resize(detCount);
memcpy(result.data(), &output[1], detCount*sizeof(Detection));
auto boxes = postProcessImg(inputImgs[i],result,classNum);
outputs.emplace_back(boxes);
output += outputSize;
}
inputImgs.clear();
inputData.clear();
batchCount = 0;
}
net->printTime();
if(groundTruth.size() > 0)
{
//eval map
evalMAPResult(outputs,groundTruth,classNum,0.5f);
evalMAPResult(outputs,groundTruth,classNum,0.75f);
}
if(fileNames.size() == 1)
{
//draw on image
cv::Mat img = cv::imread(*fileNames.begin());
auto bbox = *outputs.begin();
for(const auto& item : bbox)
{
cv::rectangle(img,cv::Point(item.left,item.top),cv::Point(item.right,item.bot),cv::Scalar(0,0,255),3,8,0);
cout << "class=" << item.classId << " prob=" << item.score*100 << endl;
cout << "left=" << item.left << " right=" << item.right << " top=" << item.top << " bot=" << item.bot << endl;
}
cv::imwrite("result.jpg",img);
cv::imshow("result",img);
cv::waitKey(0);
}
return 0;
}