DIC/OpenCorr/test_dvc_fftcc_icgn1.cpp


								/*

								 This example demonstrates how to use OpenCorr to realize a path-independent

								 DVC method based on the FFT-CC algorithm and the ICGN algorithm (with the 1st

								 order shape function).

								*/


								#include <fstream>


								#include "opencorr.h"


								using namespace opencorr;

								using namespace std;


								int main()

								{

									//set files to process

									string ref_image_path = "d:/dic_tests/dvc/al_foam4_0.bin"; //replace it with the path on your computer

									string tar_image_path = "d:/dic_tests/dvc/al_foam4_1.bin"; //replace it with the path on your computer

									Image3D ref_img(ref_image_path);

									Image3D tar_img(tar_image_path);


									//initialize papameters for timing

									double timer_tic, timer_toc, consumed_time;

									vector<double> computation_time;


									//get the time of start

									timer_tic = omp_get_wtime();


									//create instances to read and write csv files

									string file_path;

									string delimiter = ",";

									ofstream csv_out; //instance for output calculation time

									IO3D in_out; //instance for input and output DIC data

									in_out.setDelimiter(delimiter);

									in_out.setDimX(ref_img.dim_x);

									in_out.setDimY(ref_img.dim_y);

									in_out.setDimZ(ref_img.dim_z);


									//set OpenMP parameters

									int cpu_thread_number = omp_get_num_procs() - 1;

									omp_set_num_threads(cpu_thread_number);


									//set DIC parameters

									int subset_radius_x = 30;

									int subset_radius_y = 30;

									int subset_radius_z = 30;

									int max_iteration = 20;

									float max_deformation_norm = 0.001f;


									//set POIs

									Point3D upper_left_point(35, 35, 60);

									vector<POI3D> poi_queue;

									int poi_number_x = 7;

									int poi_number_y = 7;

									int poi_number_z = 117;

									int grid_space = 5;


									//store POIs in a queue

									for (int i = 0; i < poi_number_z; i++)

									{

										for (int j = 0; j < poi_number_y; j++)

										{

											for (int k = 0; k < poi_number_x; k++)

											{

												Point3D offset(k * grid_space, j * grid_space, i * grid_space);

												Point3D current_point = upper_left_point + offset;

												POI3D current_poi(current_point);

												poi_queue.push_back(current_poi);

											}

										}

									}

									int queue_length = (int)poi_queue.size();


									//get the time of end

									timer_toc = omp_get_wtime();

									consumed_time = timer_toc - timer_tic;

									computation_time.push_back(consumed_time); //0


									//display the time of initialization on screen

									cout << "Initialization with " << queue_length << " POIs takes " << consumed_time << " sec, " << cpu_thread_number << " CPU threads launched." << std::endl;


									//get the time of start

									timer_tic = omp_get_wtime();


									//FFTCC

									FFTCC3D* fftcc = new FFTCC3D(subset_radius_x, subset_radius_y, subset_radius_z, cpu_thread_number);

									fftcc->setImages(ref_img, tar_img);

									fftcc->compute(poi_queue);


									//get the time of end

									timer_toc = omp_get_wtime();

									consumed_time = timer_toc - timer_tic;

									computation_time.push_back(consumed_time); //1


									//display the time of processing on the screen

									cout << "Displacement estimation using FFTCC takes " << consumed_time << " sec." << std::endl;


									//get the time of start

									timer_tic = omp_get_wtime();


									//ICGN with the 1st order shape function

									ICGN3D1* icgn1 = new ICGN3D1(subset_radius_x, subset_radius_y, subset_radius_z, max_deformation_norm, max_iteration, cpu_thread_number);

									icgn1->setImages(ref_img, tar_img);

									icgn1->prepare();

									icgn1->compute(poi_queue);


									//get the time of end

									timer_toc = omp_get_wtime();

									consumed_time = timer_toc - timer_tic;

									computation_time.push_back(consumed_time); //2


									//display the time of processing on screen

									cout << "Deformation determination using ICGN takes " << consumed_time << " sec." << std::endl;


									//save the calculated results

									file_path = tar_image_path.substr(0, tar_image_path.find_last_of(".")) + "_fftcc_icgn1_r30.csv";

									in_out.setPath(file_path);

									in_out.saveTable3D(poi_queue);


									//save the computation time

									file_path = tar_image_path.substr(0, tar_image_path.find_last_of(".")) + "_fftcc_icgn1_r30_time.csv";

									csv_out.open(file_path);

									if (csv_out.is_open())

									{

										csv_out << "POI number" << delimiter << "Initialization" << delimiter << "FFTCC" << delimiter << "ICGN" << endl;

										csv_out << poi_queue.size() << delimiter << computation_time[0] << delimiter << computation_time[1] << delimiter << computation_time[2] << endl;

									}

									csv_out.close();


									//destroy the instances

									delete fftcc;

									delete icgn1;


									cout << "Press any key to exit..." << std::endl;

									cin.get();


									return 0;

								}