public void Test_FrontBackNumerRecursive_3() { var numTest = new Exercise1(); var result = numTest.FrontBackNumbers_Recursive(123456789); Assert.AreEqual(192837465, result); }
public void Ex1Test2() { Exercise1 ex1 = new Exercise1(); CellPrinter cellPrinter = (CellPrinter)ex1.Method1(); Assert.AreEqual(cellPrinter.PrintPostion(1, 1), "Cell is on Position X:1 Y:1"); }
public bool AssertAbnormalDaysReturnNone() { return(Exercise1.Parse <DayOfWeek>("Funday") .Match( () => true, val => false)); }
public void Ex1Test1() { Exercise1 ex1 = new Exercise1(); CellPrinter cellPrinter = (CellPrinter)ex1.Method1(); Assert.AreEqual(cellPrinter.PrintState(true, System.DateTime.Now, "red"), $"Cell red born on {System.DateTime.Now} is alive"); }
public void Ex1Methd1_position() { Exercise1 ex1 = new Exercise1(); CellPrinter cp = (CellPrinter)ex1.Method1(); Assert.Equal("Cell is on Position X:1 Y:1", cp.PrintPostion(1, 1)); }
public void Exercise1Method1Test3() { Exercise1 e1 = new Exercise1(); CellPrinter returnedObject = (CellPrinter)e1.Method1(); Assert.AreEqual(returnedObject.PrintState(true, new System.DateTime(2019, 12, 12), "red"), "Cell red born on 12.12.2019 is alive"); }
public void Ex1Methd1_notalive() { Exercise1 ex1 = new Exercise1(); CellPrinter cp = (CellPrinter)ex1.Method1(); Assert.Equal($"Cell red born on {System.DateTime.Now} is not alive", cp.PrintState(false, System.DateTime.Now, "red")); }
public void Exercise1Method1Test2() { Exercise1 e1 = new Exercise1(); CellPrinter returnedObject = (CellPrinter)e1.Method1(); Assert.AreEqual(returnedObject.PrintPostion(1, 2), "Cell is on Position X:1 Y:2"); }
public static void Main() { Scene scene = new Exercise1(); OpenTKWindow window = new OpenTKWindow(scene); window.Run(); }
public void Test_FrontBackNumerRecursive_2() { var numTest = new Exercise1(); var result = numTest.FrontBackNumbers_Recursive(1234567890); Assert.AreEqual(1029384756, result); }
public void Test_FrontBackNumbers2_3() { var numTest = new Exercise1(); var result = numTest.FrontBackNumbers_Solution2(1234); Assert.AreEqual(1423, result); }
public void Test_FrontBackNumerRecursive_1() { var numTest = new Exercise1(); var result = numTest.FrontBackNumbers_Recursive(123456); Assert.AreEqual(162534, result); }
public void Test_FrontBackNumbers2_1() { var numTest = new Exercise1(); var result = numTest.FrontBackNumbers_Solution2(123456789); Assert.AreEqual(192837465, result); }
public void Test_FrontBackNumbers2_2() { var numTest = new Exercise1(); var result = numTest.FrontBackNumbers_Solution2(1234567890); Assert.AreEqual(1029384756, result); }
public void fail30MPass() { var Exercise1 = new Exercise1(); bool result = Exercise1.login("user", "pass1111111111111111111111111111111"); Assert.AreEqual(false, result); }
public void blankUser() { var Exercise1 = new Exercise1(); bool result = Exercise1.login("", "pass"); Assert.AreEqual(false, result); }
public void blankPass() { var Exercise1 = new Exercise1(); bool result = Exercise1.login("user", ""); Assert.AreEqual(false, result); }
public void trueLogin() { var Exercise1 = new Exercise1(); bool result = Exercise1.login("user", "pass"); Assert.AreEqual(true, result); }
static void Main(string[] args) { /* Exercise 1 * 1. Ask from the user 6 integers, e.g. 1,2,3,4,5,6 * 2. Generate from each number a random number with limit up to this number * e.g. -4, 0, 1, 3, 2, 5 * 3. Place these 6 random numbers to a list * 4. Rearrange the list so the numbers are places ascending * 5. Rearrange the list so the numbers are places descending * 6. Show the sum of all the numbers */ /* Exercise 2 * 1. Use the previous list of random numbers and generate a list of random strings, e.g. * if the list contains the number 4 then * you should generate a random string with 4 characters * 2. Search on every string and display the number of occurences each char occurs * e.g. "keiwe", k:1, e:2, i:1, w:1 * 3. Show from all of the strings inside the list the top 3 chars that have the most * occurences */ Exercise1 exercise1 = new Exercise1(); Exercise2 exercise2 = new Exercise2(); }
public void Exercise1Method1Test1() { Exercise1 e1 = new Exercise1(); CellPrinter returnedObject = (CellPrinter)e1.Method1(); CellPrinter expectedObject = new CellPrinter(); Assert.AreEqual(returnedObject.GetType(), expectedObject.GetType()); }
public void Test1() { var exercise1 = new Exercise1(); var method1 = exercise1.Method1(); Assert.NotNull(method1); }
static async Task <int[, ]> DoFirst() { int[,] first = new int[100, 100]; int[,] second = new int[100, 100]; Random rnd = new Random(); for (int i = 0; i < 100; i++) { for (int j = 0; j < 100; j++) { first[i, j] = rnd.Next(0, 10); second[i, j] = rnd.Next(0, 10); } } return(await Exercise1.MultiplyMatrixAsync(first, second)); }
public static void MenuExercises() { CreateExercisesList(); Console.WriteLine("> Menu Exercises: "); foreach (var exercise in Exercises) { Console.WriteLine(exercise); } Console.WriteLine("Write the number of the example you want to see:"); var input = Console.ReadLine(); var select = 0; if (input == null) { Console.WriteLine("You must choose."); MenuExercises(); return; } select = Int32.Parse(input); switch (select) { case 0: Menu(); break; case 1: Console.Clear(); Exercise1.Run(); break; default: Console.Clear(); Console.WriteLine("That exercise doesn't exist."); MenuExercises(); break; } }
public DayOfWeek AssertNormalDaysWorks(string v) { var result = Exercise1.Parse <DayOfWeek>(v); return(result.AsEnumerable().First()); }
public void AddPoint(Exercise1.Point3D point) { points.Add(point); }
static void Main(string[] args) { Exercise1 exercise1 = new Exercise1(); //Exercise2 exercise2 = new Exercise2(); }
public void SetUp() { exercise1 = new Exercise1(); }
public static double CalculateDistance(Exercise1.Point3D point1, Exercise1.Point3D point2) { return Math.Sqrt(((point1.X - point2.X) * (point1.X - point2.X)) + ((point1.Y - point2.Y) * (point1.Y - point2.Y)) + ((point1.Z - point2.Z) * (point1.Z - point2.Z))); }
private static void Main(string[] args) { while (true) { ConsoleOutput.PutInitText(); ConsoleOutput.PutExercisesText(); var key = Console.ReadKey(); switch (key.KeyChar) { case '1': ConsoleOutput.PutInitText(); Console.WriteLine("Zadanie 1 - LFSR"); ConsoleOutput.PutCryptoDecryptoText(); var choice1 = Console.ReadKey(); switch (choice1.KeyChar) { case '1': Exercise1.Encrypt(); break; case '2': Exercise1.Decrypt(); break; default: break; } break; case '2': ConsoleOutput.PutInitText(); Console.WriteLine("Zadanie 2 - Synchronous Stream Cipher"); ConsoleOutput.PutCryptoDecryptoText(); var choice2 = Console.ReadKey(); switch (choice2.KeyChar) { case '1': Exercise2.Encrypt(); break; case '2': Exercise2.Decrypt(); break; default: break; } break; case '3': ConsoleOutput.PutInitText(); Console.WriteLine("Zadanie 3 - Ciphertext Autokey"); ConsoleOutput.PutCryptoDecryptoText(); var choice3 = Console.ReadKey(); switch (choice3.KeyChar) { case '1': Exercise3.Encrypt(); break; case '2': Exercise3.Decrypt(); break; default: break; } break; case '0': Environment.Exit(0); break; default: break; } Console.Clear(); } }
private static void Main(string[] args) { while (true) { ConsoleOutput.PutInitText(); ConsoleOutput.PutExercisesText(); var key = Console.ReadKey(); switch (key.KeyChar) { case '1': ConsoleOutput.PutInitText(); Console.WriteLine("Zadanie 1 - Rail fence"); ConsoleOutput.PutCryptoDecryptoText(); var choice1 = Console.ReadKey(); switch (choice1.KeyChar) { case '1': Exercise1.Encrypt(); break; case '2': Exercise1.Decrypt(); break; default: break; } break; case '2': ConsoleOutput.PutInitText(); Console.WriteLine("Zadanie 2 - Przestawienia macierzowe a"); ConsoleOutput.PutCryptoDecryptoText(); var choice2 = Console.ReadKey(); switch (choice2.KeyChar) { case '1': Exercise2.Encrypt(); break; case '2': Exercise2.Decrypt(); break; default: break; } break; case '3': ConsoleOutput.PutInitText(); Console.WriteLine("Zadanie 3 - Przestawienia macierzowe b"); ConsoleOutput.PutCryptoDecryptoText(); var choice3 = Console.ReadKey(); switch (choice3.KeyChar) { case '1': Exercise3.Encrypt(); break; case '2': Exercise3.Decrypt(); break; default: break; } break; case '6': ConsoleOutput.PutInitText(); Console.WriteLine("Zadanie 3 - Przestawienia macierzowe c"); ConsoleOutput.PutCryptoDecryptoText(); var choice6 = Console.ReadKey(); switch (choice6.KeyChar) { case '1': Exercise6.Encrypt(); break; case '2': Exercise6.Decrypt(); break; default: break; } break; case '4': ConsoleOutput.PutInitText(); Console.WriteLine("Zadanie 4 - Szyfrowanie cezara"); ConsoleOutput.PutCryptoDecryptoText(); var choice4 = Console.ReadKey(); switch (choice4.KeyChar) { case '1': Exercise4.Encrypt(); break; case '2': Exercise4.Decrypt(); break; default: break; } break; case '5': ConsoleOutput.PutInitText(); Console.WriteLine("Zadanie 5 - Szyfrowanie Vigenere’a"); ConsoleOutput.PutCryptoDecryptoText(); var choice5 = Console.ReadKey(); switch (choice5.KeyChar) { case '1': Exercise5.Encrypt(); break; case '2': Exercise5.Decrypt(); break; default: break; } break; case '0': Environment.Exit(0); break; default: break; } Console.Clear(); } }
static void Main(string[] args) { Exercise1 ex1 = new Exercise1(); Exercise2 ex2 = new Exercise2(ex1.NumberList); }