DTWDistance.h

#pragma once

#include "ISignalOp.h"
#include "DTW.h"

extern bool FileSave;
extern unsigned int SaveDirIndex;

namespace SignalProcessing
{
	ref class DTWDistance : public Operation {
	private:
		unsigned int Neighborhood;
		String ^name;
		double threshold;
	private:
		static double Distance(float p_1, float p_2) {
			return Math::Abs(p_1 - p_2);
		}
	public:
		DTWDistance(unsigned int neighborhood) {

			Neighborhood = neighborhood;
			this->Name = "DTWDistance";
		}

		property String ^Name {
			String ^get() {
				return name;
			}
			void set(String ^val) {
				name = val;
			}
		}

		property double Threshold {
			double get() {
				return threshold;
			}
			void set(double val) {
				threshold = val;
			}
		}


		virtual void SetName(String ^p_name)
		{
			this->Name = p_name;
		}
		virtual String ^GetName()
		{
			return this->Name;
		}

		virtual array<array<float>^> ^ PreprocessActionTemplate(array<array<float> ^> ^p_saved_action_definition, array<int> ^p_sdi)
		{
			return p_saved_action_definition;
		}

		virtual virtual void SetFileSaveEnabled(boolean val, double threshold)
		{
			Threshold = threshold;
			FileSave = true;
		}

		virtual array<ViewSerialEvent> ^Apply(array<ViewSerialEvent> ^p_action)
		{
			return nullptr;
		}
		virtual array<double>^ Apply(array<array<float> ^> ^p_saved_action_definition, array<array<float> ^> ^p_last_actions, array<int> ^p_data_offsets) override
		{

			unsigned int max_dtw_deviate = (p_saved_action_definition->Length * 0.05f > 1) ? (p_saved_action_definition->Length * 0.05f > 1) : 1;

			return DTW::Apply(p_saved_action_definition, p_last_actions, p_data_offsets, 3);

#if 0
			double distance = 0;
			unsigned int sensor_data_index_of_saved = 0;
			unsigned int sensor_data_index_of_last = p_data_offsets[0];
			unsigned int diagonal_counter = 0;
			float min_neighbourhood;
			const unsigned int const saved_action_length = p_saved_action_definition->Length;
			const unsigned int const last_action_length = p_last_actions->Length;
			unsigned int i, j;

			array<double> ^distances = gcnew array<double>(p_data_offsets->Length);
			array<double> ^action_original_length = gcnew array<double>(p_data_offsets->Length);

			array<KeyValuePair<int, int> ^> ^pDistancePath = gcnew array<KeyValuePair<int, int> ^>(saved_action_length * 2);
			array<float, 2> ^CMatrix = gcnew array<float, 2>(saved_action_length, saved_action_length);
			/*
			for (int i = 0; i < saved_action_length; i++) {
			p_saved_action_definition[i][0] = i;

			p_last_actions[i][0] = 1;
			}*/
			/*
			for (i = 1; i < saved_action_length; i++) {
				for (j = 1; j < saved_action_length; j++) {
					CMatrix[j, i] = 999999;
				}
			}
			*/
			/*
			for (i = Neighborhood + 1, j = Neighborhood + 1; j < saved_action_length, i < last_action_length; i++, j++) {

			CMatrix[j - Neighborhood, i] = 999999;
			CMatrix[j, i - Neighborhood] = 999999;


			}*/

			for (int sdi = 0; sdi < p_data_offsets->Length; sdi++) {

				sensor_data_index_of_last = p_data_offsets[sdi];
				sensor_data_index_of_saved = sdi;

				//sensor_data_index_of_last = sdi;

				CMatrix[0, 0] = Distance(p_saved_action_definition[0][sensor_data_index_of_saved], p_last_actions[0][sensor_data_index_of_last]);

				for (int i = 1; i < saved_action_length; i++) {

					CMatrix[0, i] = Distance(p_saved_action_definition[0][sensor_data_index_of_saved], p_last_actions[i][sensor_data_index_of_last]) + CMatrix[0, i - 1];

				}

				for (int j = 1; j < saved_action_length; j++) {

					CMatrix[j, 0] = Distance(p_saved_action_definition[j][sensor_data_index_of_saved], p_last_actions[0][sensor_data_index_of_last]) + CMatrix[j - 1, 0];

				}

				/* C[0, 0] */
				CMatrix[0, 0] = Distance(p_saved_action_definition[0][sensor_data_index_of_saved], p_last_actions[0][sensor_data_index_of_last]);
				/* END - C[0, 0] */

				/* C[1, 1] */
				CMatrix[1, 1] = Distance(p_saved_action_definition[1][sensor_data_index_of_saved], p_last_actions[1][sensor_data_index_of_last]);

				min_neighbourhood = CMatrix[0, 0];

				if (CMatrix[0, 1] < min_neighbourhood) {
					min_neighbourhood = CMatrix[0, 1];
				}
				if (CMatrix[1, 0] < min_neighbourhood)
				{
					min_neighbourhood = CMatrix[1, 0];
				}

				CMatrix[1, 1] = CMatrix[1, 1] + min_neighbourhood;

				/* END - C[1, 1] */

				diagonal_counter = saved_action_length;

				for (j = 1; j < saved_action_length; j++)
				{
					for (i = 1; i < last_action_length; i++)
					{

						CMatrix[j, i] = Distance(p_saved_action_definition[j][sensor_data_index_of_saved], p_last_actions[i][sensor_data_index_of_last]);

						min_neighbourhood = CMatrix[j - 1, i - 1];

						if (CMatrix[j - 1, i] < min_neighbourhood) {
							min_neighbourhood = CMatrix[j - 1, i];
						}
						if (CMatrix[j, i - 1] < min_neighbourhood)
						{
							min_neighbourhood = CMatrix[j, i - 1];
						}

						CMatrix[j, i] = CMatrix[j, i] + min_neighbourhood;

					}
				}

				j = saved_action_length - 1;
				i = saved_action_length - 1;

				int distance_counter = 0;
				int temp_i_decrement, temp_j_decrement;
				int dtw_range = saved_action_length + saved_action_length * 0.30f;
				double dtw_distance = 0;

				while (i >= 0 && j >= 0) {

					KeyValuePair<int, int> ^p_kvp = KeyValuePair<int, int>(j + 1, i + 1);
					pDistancePath[distance_counter] = p_kvp;
					distance_counter++;

					if (distance_counter > dtw_range) {

						//distance = 9999999;
						//break;
					}

					action_original_length[sdi] = action_original_length[sdi] + Math::Pow(p_saved_action_definition[j][sensor_data_index_of_saved], 2);

					temp_i_decrement = 1;
					temp_j_decrement = 1;

					//distance = distance + CMatrix[j, i];
					dtw_distance = dtw_distance + Math::Pow((p_saved_action_definition[j][sensor_data_index_of_saved] - p_last_actions[i][sensor_data_index_of_last]), 2);

					if (i != 0 && j != 0) {

						min_neighbourhood = CMatrix[j - 1, i - 1];

						if (CMatrix[j, i - 1] < min_neighbourhood) {
							min_neighbourhood = CMatrix[j, i - 1];
							temp_i_decrement = 1;
							temp_j_decrement = 0;
						}

						if (CMatrix[j - 1, i] < min_neighbourhood) {
							min_neighbourhood = CMatrix[j - 1, i];
							temp_i_decrement = 0;
							temp_j_decrement = 1;
						}
					}
					else if (i == 0 && j == 0) {
						break;
					}
					else if (i == 0) {

						min_neighbourhood = CMatrix[j - 1, i];
						temp_i_decrement = 0;
						temp_j_decrement = 1;

					}
					else if (j == 0) {

						min_neighbourhood = CMatrix[j, i - 1];
						temp_i_decrement = 1;
						temp_j_decrement = 0;
					}





					i = i - temp_i_decrement;
					j = j - temp_j_decrement;

				}

				distance = distance +  dtw_distance * ((sdi + 1) / (float)p_data_offsets->Length);

	

				if (FileSave) {
					
					String ^dir = gcnew String(Environment::CurrentDirectory + "\\SensorData\\Signals\\" + SaveDirIndex.ToString() + this->Name);
					if (!IO::Directory::Exists(dir)) {

						IO::Directory::CreateDirectory(dir);
					}
					/****************************/
					String ^path = gcnew String(dir + "\\saved_action.txt");

					System::IO::TextWriter ^pTextWriter;
					if (!IO::File::Exists(path)) {

						pTextWriter = gcnew System::IO::StreamWriter(path, true);
						pTextWriter->Flush();

					}
					for (j = 0; j < saved_action_length; j++) {
						pTextWriter->Write(p_saved_action_definition[saved_action_length - j - 1][sensor_data_index_of_saved] + "\t");
					}
					pTextWriter->Flush();
					pTextWriter->Close();

					/****************************/
					path = gcnew String(dir + "\\last_action.txt");


					if (!IO::File::Exists(path)) {

						pTextWriter = gcnew System::IO::StreamWriter(path, true);
						pTextWriter->Flush();

					}
					for (j = 0; j < saved_action_length; j++) {
						pTextWriter->Write(p_last_actions[last_action_length - j - 1][sensor_data_index_of_last] + "\t");
					}
					pTextWriter->Flush();
					pTextWriter->Close();

					/************DISTANCE****************/
					path = gcnew String(dir + "\\distance.txt");


					if (!IO::File::Exists(path)) {

						pTextWriter = gcnew System::IO::StreamWriter(path, true);
						pTextWriter->Flush();

					}
					for (j = 0; j < saved_action_length; j++) {
						pTextWriter->Write(distance + "\t");
					}
					pTextWriter->Flush();
					pTextWriter->Close();

					/****************************/
					path = gcnew String(dir + "\\distance_path_ij.txt");


					if (!IO::File::Exists(path)) {

						pTextWriter = gcnew System::IO::StreamWriter(path, true);
						pTextWriter->Flush();

					}

					for (int i = 0; i < pDistancePath->Length; i++) {
						if (pDistancePath[i] != nullptr) {

							pTextWriter->Write(pDistancePath[i]->Key + "\t");

						}
					}
					pTextWriter->Flush();
					pTextWriter->Close();

					/****************************/
					path = gcnew String(dir + "\\distance_path_ix.txt");


					if (!IO::File::Exists(path)) {

						pTextWriter = gcnew System::IO::StreamWriter(path, true);
						pTextWriter->Flush();

					}

					for (int i = 0; i < pDistancePath->Length; i++) {
						if (pDistancePath[i] != nullptr) {

							pTextWriter->Write(pDistancePath[i]->Value + "\t");

						}
					}
					pTextWriter->Flush();
					pTextWriter->Close();


					/****************************/
					path = gcnew String(dir + "\\CMatrix.txt");

					if (!IO::File::Exists(path)) {

						pTextWriter = gcnew System::IO::StreamWriter(path, true);
						pTextWriter->Flush();

					}
					for (j = 0; j < saved_action_length; j++) {
						for (i = 0; i < saved_action_length; i++) {

							pTextWriter->Write(CMatrix[j, i] + "\t");
						}

						pTextWriter->WriteLine();
					}

					pTextWriter->Flush();
					pTextWriter->Close();
				}

				distances[sdi] = Math::Sqrt(distance);
				distance = 0;
			}

			return distances;
#endif
		}
	};

}