//Main drzewa decyzyjne 1 + algorytm genetyczny #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include //#include using namespace std; const float maxFloat = FLT_MAX; const int ROW = 27; const int COL = 27; typedef pair Pair; typedef pair > pPair; struct cell { int parent_i, parent_j; double f, g, h; }; char pole[27][27][6]; int pozycjaTraktoraX = 1, pozycjaTraktoraY = 1; char currentWay = 'S'; //======================================================== //drzewo decyzyjne int stan[27][27][2]; string polecenie; int decyzja = NULL; // Do dodania wywołanie odpowiednich funkcji - zbieranie - nawożenie - void akcja() { if (decyzja == 0) { //nic nie rób } else if (decyzja == 1) { //Zastosuj nawoz } else if (decyzja == 2) { //Zastosuj srodek } else if (decyzja == 4) { //Zbierz rośline i licznik++ } else if (decyzja == 5) { //Zbierz rośline ale nie dodawaj do licznika } } void decisionTree(string polecenie) { std::string str = polecenie; const char* c = str.c_str(); system(c); int line = 0; ifstream inFile; inFile.open("pliki/dec.txt"); if (!inFile) { cout << "Unable to open file"; exit(1); // terminate with error } while (inFile >> line) { decyzja = line; } inFile.close(); akcja(); } void stanPola(int x, int y) { //[x][x][0] = 0 - brak chemii //[x][x][0] = 1 - tylko nawóz //[x][x][0] = 2 - tylko środek //[x][x][0] = 3 - środek i nawóz //[x][x][1] - wartość wzrostu rośliny polecenie = "python pliki/injectCode.py 1 "; if (stan[x][y][0] == 0) polecenie.append("0 0 "); if (stan[x][y][0] == 1) polecenie.append("1 0 "); if (stan[x][y][0] == 2) polecenie.append("0 1 "); if (stan[x][y][0] == 3) polecenie.append("1 1 "); int w = (stan[x][y][1]); std::string s = std::to_string(w); polecenie.append(s); decisionTree(polecenie); } //======================================================== //algorytm genetyczny int scoreBuraki = 0; int scoreZiemniaki = 0; int rozmiarPopulacji = 500; string* zebraneBuraki = new string[rozmiarPopulacji]; string* zebraneZiemniaki = new string[rozmiarPopulacji]; string* burakiDoSadzenia = new string[20]; string* ziemniakiDoSadzenia = new string[20]; int gmoLeftBuraki; int gmoLeftZiemniaki; string kod_genetyczny[27][27]; string generateValue() { char trash[100]; string x; srand(time(NULL)); int random = (rand() % 1000, 1); //string x = itoa(rand() % 1000,trash,10); x = to_string(random); if (x.size() == 2) { x = "0" + x; } else if (x.size() == 1) { x = "00" + x; } return x; } string generateVegetable() { string taste = generateValue(); string colour = generateValue(); string size = generateValue(); return taste + colour + size; } void generatePopulation(string* population, int length) { int i; for (i = 0;i < length;i++) { population[i] = generateVegetable(); } } int power(int x, int y) { if (y == 0) return 1; if (y == 1) return x; int temp = power(x, y / 2); if (y % 2 == 0) return temp * temp; else return x * temp * temp; } int stringToInt(string str, int size) { int x = 0; int i; reverse(str.begin(), str.end()); for (i = 0;i < size;i++) { x += (str[i] - '0') * power(10, i); } reverse(str.begin(), str.end()); return x; } int fitness(string vegetable) { int taste = stringToInt(vegetable.substr(0, 3), 3); int colour = stringToInt(vegetable.substr(3, 3), 3); int size = stringToInt(vegetable.substr(6, 3), 3); return (taste + colour + size) / 3; } bool comparePair(const pair& i, const pair& j) { return i.first > j.first; } void ranking(string* population, string* parents, int populationSize, int parentsNumber) { int i; pair * fitnessTable = new pair [populationSize]; for (i = 0;i < populationSize;i++) { fitnessTable[i] = make_pair(fitness(population[i]), population[i]); } sort(fitnessTable, fitnessTable + populationSize, comparePair); for (i = 0;i < parentsNumber;i++) { parents[i] = fitnessTable[i].second; } delete[] fitnessTable; } bool exists(int len, int* array, int element) { int i; for (i = 0;i < len;i++) { if (array[i] == element) return true; } return false; } void selection(string* population, string* parents, int populationSize, int parentsNumber) { int i, j, k; pair * fitnessTable = new pair [populationSize]; for (i = 0;i < populationSize;i++) { fitnessTable[i] = make_pair(fitness(population[i]), population[i]); } sort(fitnessTable, fitnessTable + populationSize, comparePair); int roulette; int* taken = new int[parentsNumber]; int sum = 0; for (i = 0;i < parentsNumber;i++) { for (j = populationSize - 1;j >= 0;j--) { if (not exists(parentsNumber, taken, j)) { sum += fitnessTable[j].first; fitnessTable[j].first = sum; } } roulette = rand() % fitnessTable[0].first; j = 0; while (exists(parentsNumber, taken, j)) { j += 1; } while (roulette > fitnessTable[j].first && j < populationSize) { if (not exists(parentsNumber, taken, j)) { roulette -= fitnessTable[j].first; } j += 1; } parents[i] = fitnessTable[j].second; taken[i] = j; } } string mutate(string child) { int d3 = rand() % 3; string mutation = generateValue(); switch (d3) { case 0: child = mutation + child.substr(3, 6); break; case 1: child = child.substr(0, 3) + mutation + child.substr(6, 3); break; case 2: child = child.substr(0, 6) + mutation; break; } return child; } string cross(string parent[2]) { int i; string child = ""; for (i = 0;i < 3;i++) { child += parent[rand() % 2].substr(i * 3, 3); } if (child == parent[0] or child == parent[1]) { string other; if (child == parent[0]) other = parent[1]; else other = parent[0]; int d3 = rand() % 3; switch (d3) { case 0: child = other.substr((rand() % 3) * 3, 3) + child.substr(3, 6); break; case 1: child = child.substr(0, 3) + other.substr((rand() % 3) * 3, 3) + child.substr(6, 3); break; case 2: child = child.substr(0, 6) + other.substr((rand() % 3) * 3, 3); break; } } int d1000 = rand() % 1000; if (rand() % 100 == 0) { child = mutate(child); } return child; } void crossover(string* parents, string* nextGen, int parentsNumber, int nextGenSize) { int counter = 0; int i, j; for (i = 0;i < parentsNumber;i++) { if (counter >= nextGenSize) { break; } else { nextGen[counter] = parents[i]; counter += 1; } } while (counter < nextGenSize) { for (i = 0;i < parentsNumber;i++) { if (counter >= nextGenSize) { break; } else { for (j = i;j < parentsNumber;j++) { if (counter >= nextGenSize) { break; } else { string couple[2]; couple[0] = parents[i]; couple[1] = parents[j]; nextGen[counter] = cross(couple); counter += 1; } } } } } } void genetic_algorithm(string* population, int populationSize, int parentsNumber, string* outcome, int outcomeSize) { int iteration, i; for (iteration = 0;iteration < 5;iteration++) { string* parents = new string[parentsNumber]; selection(population, parents, populationSize, parentsNumber); string* nextGen = new string[populationSize]; crossover(parents, nextGen, parentsNumber, populationSize); for (i = 0;i < populationSize;i++) { population[i] = nextGen[i]; } } ranking(population, outcome, populationSize, outcomeSize); } string przypiszKod(string warzywa) { if (warzywa == "buraki") { if (gmoLeftBuraki > 0) { string temp = burakiDoSadzenia[gmoLeftBuraki - 1]; gmoLeftBuraki -= 1; return temp; } else { return generateVegetable(); } } else { if (gmoLeftZiemniaki > 0) { string temp = ziemniakiDoSadzenia[gmoLeftZiemniaki - 1]; gmoLeftZiemniaki -= 1; return temp; } else { return generateVegetable(); } } } void przypiszKodGenetyczny(int i, int j, char plant) { if (plant == 'B') { kod_genetyczny[i][j] = przypiszKod("buraki"); } else if (plant == 'Z') { kod_genetyczny[i][j] = przypiszKod("ziemniaki"); } } void obslugaAlgorytmuGenetycznego() { cout << "Zebrane buraki: " << scoreBuraki << endl; cout << "Zebrane ziemniaki: " << scoreZiemniaki << endl; if (scoreBuraki >= rozmiarPopulacji) { scoreBuraki = 0; for (int i = 0;i < 20;i++) { burakiDoSadzenia[i] = "000000000"; } genetic_algorithm(zebraneBuraki, rozmiarPopulacji, rozmiarPopulacji - 5, burakiDoSadzenia, 20); gmoLeftBuraki = 20; for (int i = 0; i < rozmiarPopulacji;i++) { zebraneBuraki[i] = "000000000"; } for (int i = 0;i < 20;i++) { cout << burakiDoSadzenia[i] << endl; } } if (scoreZiemniaki >= rozmiarPopulacji) { scoreZiemniaki = 0; for (int i = 0;i < 20;i++) { ziemniakiDoSadzenia[i] = "000000000"; } genetic_algorithm(zebraneZiemniaki, rozmiarPopulacji, rozmiarPopulacji - 5, ziemniakiDoSadzenia, 20); gmoLeftZiemniaki = 20; for (int i = 0; i < rozmiarPopulacji;i++) { zebraneZiemniaki[i] = "000000000"; } for (int i = 0;i < 20;i++) { cout << ziemniakiDoSadzenia[i] << endl; } } } void generujKody() { for (int i = 0;i < 27;i++) { for (int j = 0;j < 27;j++) { if (pole[i][j][0] == 'B') { kod_genetyczny[i][j] = przypiszKod("buraki"); } else if (pole[i][j][0] == 'Z') { kod_genetyczny[i][j] = przypiszKod("ziemniaki"); } } } } //======================================================== void color(string foregroundColor, string backgroundColor) { HANDLE hOut; hOut = GetStdHandle(STD_OUTPUT_HANDLE); int foregroundCode = 15; if (foregroundColor == "black") foregroundCode = 0; if (foregroundColor == "dark_blue") foregroundCode = 1; if (foregroundColor == "green") foregroundCode = 2; if (foregroundColor == "cyan") foregroundCode = 3; if (foregroundColor == "dark_red") foregroundCode = 4; if (foregroundColor == "purple") foregroundCode = 5; if (foregroundColor == "dark_yellow") foregroundCode = 6; if (foregroundColor == "light_gray") foregroundCode = 7; if (foregroundColor == "gray") foregroundCode = 8; if (foregroundColor == "blue") foregroundCode = 9; if (foregroundColor == "lime") foregroundCode = 10; if (foregroundColor == "light_blue") foregroundCode = 11; if (foregroundColor == "red") foregroundCode = 12; if (foregroundColor == "magenta") foregroundCode = 13; if (foregroundColor == "yellow") foregroundCode = 14; if (foregroundColor == "white") foregroundCode = 15; int backgroundCode = 0; if (backgroundColor == "black") backgroundCode = 0; if (backgroundColor == "dark_blue") backgroundCode = 1; if (backgroundColor == "green") backgroundCode = 2; if (backgroundColor == "cyan") backgroundCode = 3; if (backgroundColor == "dark_red") backgroundCode = 4; if (backgroundColor == "purple") backgroundCode = 5; if (backgroundColor == "dark_yellow") backgroundCode = 6; if (backgroundColor == "light_gray") backgroundCode = 7; if (backgroundColor == "gray") backgroundCode = 8; if (backgroundColor == "blue") backgroundCode = 9; if (backgroundColor == "lime") backgroundCode = 10; if (backgroundColor == "light_blue") backgroundCode = 11; if (backgroundColor == "red") backgroundCode = 12; if (backgroundColor == "magenta") backgroundCode = 13; if (backgroundColor == "yellow") backgroundCode = 14; if (backgroundColor == "white") backgroundCode = 15; SetConsoleTextAttribute(hOut, foregroundCode + backgroundCode * 16); } void SetWindow(int Width, int Height) { _COORD coord; coord.X = Width; coord.Y = Height; _SMALL_RECT Rect; Rect.Top = 0; Rect.Left = 0; Rect.Bottom = Height - 1; Rect.Right = Width - 1; HANDLE Handle = GetStdHandle(STD_OUTPUT_HANDLE); // Get Handle SetConsoleScreenBufferSize(Handle, coord); // Set Buffer Size SetConsoleWindowInfo(Handle, TRUE, &Rect); // Set Window Size } void updatePola() { system("cls"); for (int i = 0; i < 27; i++) { for (int j = 0; j < 27; j++) { char item = pole[i][j][0]; switch (item) { case 'B': { color("purple", "dark_yellow"); }break; case 'Z': { color("cyan", "dark_yellow"); }break; case 'T': { color("red", "dark_yellow"); }break; case 'G': { color("lime", "dark_yellow"); }break; case '.': { color("yellow", "dark_yellow"); }break; case '#': { color("light_gray", "gray"); }break; } cout << pole[i][j][0]; } cout << endl; color("white", "black"); } } void correctMovement(char wantedWay) { while (currentWay != wantedWay) { switch (currentWay) { case 'N': { if (wantedWay == 'S') currentWay = wantedWay; else currentWay = 'W'; }break; case 'S': { if (wantedWay == 'N') currentWay = wantedWay; else currentWay = 'W'; }break; case 'W': { if (wantedWay == 'E') currentWay = wantedWay; else currentWay = 'N'; }break; case 'E': { if (wantedWay == 'W') currentWay = wantedWay; else currentWay = 'N'; }break; } } } void Move(char kierunek) { switch (kierunek) { //gA3ra-(w) case 'w': { if (pole[pozycjaTraktoraY - 1][pozycjaTraktoraX][0] != '#') { if (pole[pozycjaTraktoraY - 1][pozycjaTraktoraX][0] == 'B') { zebraneBuraki[scoreBuraki] = kod_genetyczny[pozycjaTraktoraY - 1][pozycjaTraktoraX]; scoreBuraki += 1; kod_genetyczny[pozycjaTraktoraY - 1][pozycjaTraktoraX] = "000000000"; } else if (pole[pozycjaTraktoraY - 1][pozycjaTraktoraX][0] == 'Z') { zebraneZiemniaki[scoreZiemniaki] = kod_genetyczny[pozycjaTraktoraY - 1][pozycjaTraktoraX]; scoreZiemniaki += 1; kod_genetyczny[pozycjaTraktoraY - 1][pozycjaTraktoraX] = "000000000"; } correctMovement('N'); pole[pozycjaTraktoraY][pozycjaTraktoraX][0] = '.'; pozycjaTraktoraY--; pole[pozycjaTraktoraY][pozycjaTraktoraX][0] = 'T'; } updatePola(); }break; //dA3A‚-(s) case 's': { if (pole[pozycjaTraktoraY + 1][pozycjaTraktoraX][0] != '#') { if (pole[pozycjaTraktoraY + 1][pozycjaTraktoraX][0] == 'B') { zebraneBuraki[scoreBuraki] = kod_genetyczny[pozycjaTraktoraY + 1][pozycjaTraktoraX]; scoreBuraki += 1; kod_genetyczny[pozycjaTraktoraY + 1][pozycjaTraktoraX] = "000000000"; } else if (pole[pozycjaTraktoraY + 1][pozycjaTraktoraX][0] == 'Z') { zebraneZiemniaki[scoreZiemniaki] = kod_genetyczny[pozycjaTraktoraY + 1][pozycjaTraktoraX]; scoreZiemniaki += 1; kod_genetyczny[pozycjaTraktoraY + 1][pozycjaTraktoraX] = "000000000"; } correctMovement('S'); pole[pozycjaTraktoraY][pozycjaTraktoraX][0] = '.'; pozycjaTraktoraY++; pole[pozycjaTraktoraY][pozycjaTraktoraX][0] = 'T'; } updatePola(); }break; //lewo-(a) case 'a': { if (pole[pozycjaTraktoraY][pozycjaTraktoraX - 1][0] != '#') { if (pole[pozycjaTraktoraY][pozycjaTraktoraX - 1][0] == 'B') { zebraneBuraki[scoreBuraki] = kod_genetyczny[pozycjaTraktoraY][pozycjaTraktoraX - 1]; scoreBuraki += 1; kod_genetyczny[pozycjaTraktoraY][pozycjaTraktoraX - 1] = "000000000"; } else if (pole[pozycjaTraktoraY][pozycjaTraktoraX - 1][0] == 'Z') { zebraneZiemniaki[scoreZiemniaki] = kod_genetyczny[pozycjaTraktoraY][pozycjaTraktoraX - 1]; scoreZiemniaki += 1; kod_genetyczny[pozycjaTraktoraY][pozycjaTraktoraX - 1] = "000000000"; } correctMovement('W'); pole[pozycjaTraktoraY][pozycjaTraktoraX][0] = '.'; pozycjaTraktoraX--; pole[pozycjaTraktoraY][pozycjaTraktoraX][0] = 'T'; } updatePola(); }break; //prawo-(d) case 'd': { if (pole[pozycjaTraktoraY][pozycjaTraktoraX + 1][0] != '#') { if (pole[pozycjaTraktoraY][pozycjaTraktoraX + 1][0] == 'B') { zebraneBuraki[scoreBuraki] = kod_genetyczny[pozycjaTraktoraY][pozycjaTraktoraX + 1]; scoreBuraki += 1; kod_genetyczny[pozycjaTraktoraY][pozycjaTraktoraX + 1] = "000000000"; } else if (pole[pozycjaTraktoraY][pozycjaTraktoraX + 1][0] == 'Z') { zebraneZiemniaki[scoreZiemniaki] = kod_genetyczny[pozycjaTraktoraY][pozycjaTraktoraX + 1]; scoreZiemniaki += 1; kod_genetyczny[pozycjaTraktoraY][pozycjaTraktoraX + 1] = "000000000"; } correctMovement('E'); pole[pozycjaTraktoraY][pozycjaTraktoraX][0] = '.'; pozycjaTraktoraX++; pole[pozycjaTraktoraY][pozycjaTraktoraX][0] = 'T'; } updatePola(); }break; } obslugaAlgorytmuGenetycznego(); } bool isValid(int x, int y) { if (pole[x][y][0] != '#') { return true; } return false; } bool isDestination(int x, int y, Pair dest) { if (dest.first == x && dest.second == y) { return true; } return false; } double calculateHValue(int x, int y, Pair dest) { return abs(x - dest.first) + abs(y - dest.second); } void tracePath(cell cellDetails[][COL], Pair dest) { //printf("\nThe Path is "); //----start info int row = dest.first; int col = dest.second; stack Path; while (!(cellDetails[row][col].parent_i == row && cellDetails[row][col].parent_j == col)) { Path.push(make_pair(row, col)); int temp_row = cellDetails[row][col].parent_i; int temp_col = cellDetails[row][col].parent_j; row = temp_row; col = temp_col; } Path.push(make_pair(row, col)); while (!Path.empty()) { pair p = Path.top(); Path.pop(); if (p.first > pozycjaTraktoraX) Move('d'); if (p.first < pozycjaTraktoraX) Move('a'); if (p.second > pozycjaTraktoraY) Move('s'); if (p.second < pozycjaTraktoraY) Move('w'); //printf("-> (%d,%d) ", p.first, p.second); //---- informacja wierzchoÅ‚ku Sleep(1000); } return; } void aStarSearch(int grid[][COL], Pair src, Pair dest) { bool closedList[ROW][COL]; memset(closedList, false, sizeof(closedList)); cell cellDetails[ROW][COL]; int i, j; for (i = 0; i < ROW; i++) { for (j = 0; j < COL; j++) { cellDetails[i][j].f = maxFloat; cellDetails[i][j].g = maxFloat; cellDetails[i][j].h = maxFloat; cellDetails[i][j].parent_i = -1; cellDetails[i][j].parent_j = -1; } } i = src.first, j = src.second; cellDetails[i][j].f = 0.0; cellDetails[i][j].g = 0.0; cellDetails[i][j].h = 0.0; cellDetails[i][j].parent_i = i; cellDetails[i][j].parent_j = j; set openList; openList.insert(make_pair(0.0, make_pair(i, j))); bool foundDest = false; while (!openList.empty()) { pPair p = *openList.begin(); openList.erase(openList.begin()); i = p.second.first; j = p.second.second; closedList[i][j] = true; double gNew, hNew, fNew; double waga = 1.0; waga = ((double)pole[j][i][1] - 48) * 1.0;//----waga //----------- 1st Successor (North) ------------ if (isValid(i - 1, j) == true) { if (isDestination(i - 1, j, dest) == true) { cellDetails[i - 1][j].parent_i = i; cellDetails[i - 1][j].parent_j = j; //printf("The destination cell is found\n"); tracePath(cellDetails, dest); foundDest = true; return; } else if (closedList[i - 1][j] == false) { gNew = cellDetails[i][j].g + waga; hNew = calculateHValue(i - 1, j, dest); fNew = gNew + hNew; if (cellDetails[i - 1][j].f == maxFloat || cellDetails[i - 1][j].f > fNew) { openList.insert(make_pair(fNew, make_pair(i - 1, j))); cellDetails[i - 1][j].f = fNew; cellDetails[i - 1][j].g = gNew; cellDetails[i - 1][j].h = hNew; cellDetails[i - 1][j].parent_i = i; cellDetails[i - 1][j].parent_j = j; } } } //----------- 2nd Successor (South) ------------ if (isValid(i + 1, j) == true) { if (isDestination(i + 1, j, dest) == true) { cellDetails[i + 1][j].parent_i = i; cellDetails[i + 1][j].parent_j = j; //printf("The destination cell is found\n"); tracePath(cellDetails, dest); foundDest = true; return; } else if (closedList[i + 1][j] == false) { gNew = cellDetails[i][j].g + waga; hNew = calculateHValue(i + 1, j, dest); fNew = gNew + hNew; if (cellDetails[i + 1][j].f == maxFloat || cellDetails[i + 1][j].f > fNew) { openList.insert(make_pair(fNew, make_pair(i + 1, j))); cellDetails[i + 1][j].f = fNew; cellDetails[i + 1][j].g = gNew; cellDetails[i + 1][j].h = hNew; cellDetails[i + 1][j].parent_i = i; cellDetails[i + 1][j].parent_j = j; } } } //----------- 3rd Successor (East) ------------ if (isValid(i, j + 1) == true) { if (isDestination(i, j + 1, dest) == true) { cellDetails[i][j + 1].parent_i = i; cellDetails[i][j + 1].parent_j = j; //printf("The destination cell is found\n"); tracePath(cellDetails, dest); foundDest = true; return; } else if (closedList[i][j + 1] == false) { gNew = cellDetails[i][j].g + waga; hNew = calculateHValue(i, j + 1, dest); fNew = gNew + hNew; if (cellDetails[i][j + 1].f == maxFloat || cellDetails[i][j + 1].f > fNew) { openList.insert(make_pair(fNew, make_pair(i, j + 1))); cellDetails[i][j + 1].f = fNew; cellDetails[i][j + 1].g = gNew; cellDetails[i][j + 1].h = hNew; cellDetails[i][j + 1].parent_i = i; cellDetails[i][j + 1].parent_j = j; } } } //----------- 4th Successor (West) ------------ if (isValid(i, j - 1) == true) { if (isDestination(i, j - 1, dest) == true) { cellDetails[i][j - 1].parent_i = i; cellDetails[i][j - 1].parent_j = j; //printf("The destination cell is found\n"); tracePath(cellDetails, dest); foundDest = true; return; } else if (closedList[i][j - 1] == false) { gNew = cellDetails[i][j].g + waga; hNew = calculateHValue(i, j - 1, dest); fNew = gNew + hNew; if (cellDetails[i][j - 1].f == maxFloat || cellDetails[i][j - 1].f > fNew) { openList.insert(make_pair(fNew, make_pair(i, j - 1))); cellDetails[i][j - 1].f = fNew; cellDetails[i][j - 1].g = gNew; cellDetails[i][j - 1].h = hNew; cellDetails[i][j - 1].parent_i = i; cellDetails[i][j - 1].parent_j = j; } } } } /*if (foundDest == false) printf("Failed to find the Destination Cell\n");*/ return; } void gogo(int endX, int endY) { updatePola(); Sleep(1000); int grid[27][27]; for (int i = 0; i < 27; i++) { for (int j = 0; j < 27; j++) { grid[i][j] = 0; } } Pair src = make_pair(pozycjaTraktoraX, pozycjaTraktoraY); Pair dest = make_pair(endX, endY); aStarSearch(grid, src, dest); } void test1() { pole[1][3][0] = 'B'; pole[1][3][1] = '9'; pole[3][1][0] = 'Z'; pole[3][1][1] = '9'; kod_genetyczny[1][3] = przypiszKod("buraki"); kod_genetyczny[3][1] = przypiszKod("ziemniaki"); } void test2() { for (int i = 1; i < 26; i++) { for (int j = 1; j < i; j++) { pole[i][j][0] = 'B'; pole[i][j][1] = '9'; kod_genetyczny[i][j] = przypiszKod("buraki"); } } test1(); updatePola(); } void testSI1() { for (int i = 1; i < 26; i++) { for (int j = 1; j < 26; j++) { if (j % 3 == 0) { pole[i][j][2] = 'z'; //zyzne pole[i][j][3] = 'n'; //nawodnione pole[i][j][4] = 'c'; //w cieniu pole[i][j][5] = 'k'; //kwasne } else { if (j % 3 == 1) { pole[i][j][2] = 'j'; //jalowe pole[i][j][3] = 'n'; //nawodnione pole[i][j][4] = 's'; //w sloncu pole[i][j][5] = 'n'; //neutralne } else { pole[i][j][2] = 'z'; //zyzne pole[i][j][3] = 's'; //suche pole[i][j][4] = 's'; //sloneczne pole[i][j][5] = 'z'; //zasadowe } } } } } void sendState() { ofstream write("pliki/dane.txt"); for (int i = 1; i < 26; i++) { for (int j = 1; j < 26; j++) { string a; a += pole[i][j][2]; a += ' '; a += pole[i][j][3]; a += ' '; a += pole[i][j][4]; a += ' '; a += pole[i][j][5]; write << a << endl; } } write.close(); } void reciveState() { ifstream read("pliki/decyzje.txt"); if (read.is_open()) { char plant; int i = 1; int j = 1; while (read >> plant) { if (j == 25) { gogo(1, i + 1); } else { gogo(j + 1, i); } pole[i][j][0] = plant; przypiszKodGenetyczny(i, j, plant); if (plant == '.') { pole[i][j][1] = '1'; } else { pole[i][j][1] = '9'; } if (j == 25) { j = 1; i += 1; } else { j += 1; } } } } void start1() { int goalX = 3, goalY = 4; test1(); testSI1(); pole[1][1][0] = 'T'; pole[1][1][1] = '1'; pole[goalY][goalX][0] = 'G'; pole[goalY][goalX][1] = '9'; gogo(goalX, goalY); gogo(goalX - 1, goalY); pole[goalY][goalX][0] = 'Z'; pole[goalY][goalX][1] = '9'; kod_genetyczny[goalY][goalX] = przypiszKod("ziemniaki"); updatePola(); //sendState(); //trzeba rÄ™cznie zmieniać miÄ™dzy wysyÅ‚aniem stanu a pobieraniem stanu pola reciveState(); } void start2() { int goalX = 6, goalY = 6; test2(); pole[1][1][0] = 'T'; pole[1][1][1] = '1'; pole[goalY][goalX][0] = 'G'; pole[goalY][goalX][1] = '9'; gogo(goalX, goalY); } void start3() { int goalX = 6, goalY = 9; test2(); pole[1][1][0] = 'T'; pole[1][1][1] = '1'; pole[goalY][goalX][0] = 'G'; pole[goalY][goalX][1] = '9'; gogo(goalX, goalY); } void testTree() { int x, y; x = 3; y = 3; //Nie podejmuj stan[x][y][0] = 0; stan[x][y][1] = 10; stanPola(x, y); cout << decyzja; } void testTree1() { int x, y; x = 3; y = 3; //Nawoz stan[x][y][0] = 0; stan[x][y][1] = 15; stanPola(x, y); cout << decyzja; } void testTree2() { int x, y; x = 3; y = 3; //Nie podejmuj stan[x][y][0] = 1; stan[x][y][1] = 20; stanPola(x, y); cout << decyzja; } void testTree3() { int x, y; x = 3; y = 3; //Zbierz stan[x][y][0] = 1; stan[x][y][1] = 41; stanPola(x, y); cout << decyzja; } void testTree4() { int x, y; x = 3; y = 3; //Nie podejmuj stan[x][y][0] = 1; stan[x][y][1] = 90; stanPola(x, y); cout << decyzja; } void testTree5() { int x, y; x = 3; y = 3; //Srodek stan[x][y][0] = 3; stan[x][y][1] = 90; stanPola(x, y); cout << decyzja; } int main() { srand(time(0)); SetWindow(50, 30); //create pola// for (int i = 0; i < 27; i++) { pole[i][0][0] = '#'; pole[0][i][0] = '#'; pole[26][i][0] = '#'; pole[i][26][0] = '#'; pole[i][0][1] = '9'; pole[0][i][1] = '9'; pole[26][i][1] = '9'; pole[i][26][1] = '9'; } for (int i = 1; i < 26; i++) { for (int j = 1; j < 26; j++) { pole[i][j][0] = '.'; pole[i][j][1] = '1'; } } for (int i = 0; i < 25; i++) { pole[i + 1][i + 1][0] = 'B'; pole[i + 1][i + 1][1] = '9'; } for (int i = 0; i < 25; i++) { for (int j = 0; j < 10; j++) { pole[j + 1][i + 1][0] = 'B'; pole[j + 1][i + 1][1] = '9'; } } for (int i = 0; i < 25; i++) { for (int j = 10; j < 20; j++) { pole[j + 1][i + 1][0] = 'Z'; pole[j + 1][i + 1][1] = '9'; } } generujKody(); updatePola(); start1(); // testy start 1-3 //---------start---------// bool traktorDziala = true; char akcja; do { akcja = _getch(); if (akcja == 'w' || akcja == 's' || akcja == 'a' || akcja == 'd') { Move(akcja); } if (akcja == '0') { traktorDziala = false; } } while (traktorDziala); //---------end---------// return 0; }