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-#Testing and Unit Testing
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+# Testing and Unit Testing
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 ![](http://demo05.cloudimage.io/s/resize/215/i.imgur.com/D0laI5r.png)
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 ![](http://demo05.cloudimage.io/s/resize/215/i.imgur.com/ggDZ3TQ.png)
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 ![](http://demo05.cloudimage.io/s/resize/215/i.imgur.com/V6xFo00.png)
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-[Verano 2016 - Ive]
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+[Verano 2016 - Ive - Coralys]
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-As you have learned in previous labs, getting a program to compile is only a minor part of programming. The compiler will tell you if there are syntactical errors, but it isn't capable of detecting logical problems in your program. It's very important to test the program's functions to validate that they produce correct results.
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+As you have learned in previous labs, getting a program to compile is only a minor part of programming. The compiler will tell you if there are any syntactical errors, but it isn't capable of detecting logical problems in your program. It's very important to test the program's functions to validate that they produce correct results.
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 These tests can be performed by hand, this is, running the program multiple times, providing representative inputs and visually checking that the program outputs correct results. A more convenient way is to implement functions in the program whose sole purpose is to validate that other functions are working correctly. In this lab you will be practicing both testing methods.
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-##Objectives:
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+## Objectives:
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 1. Design tests to validate several programs “by-hand”, then use these tests to determine if the program works as expected. 
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 2. Create unit tests to validate functions, using the `assert` function.
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-##Pre-Lab:
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+## Pre-Lab:
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 Before you get to the laboratory you should have:
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-**Example 1:** if you were to validate the function `isEven(unsigned int n)` that determines if a positive integer *n* is even, you should test the function using even and odd numbers. A set of tests for that function could be:
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+**Example 1:** If you were to validate the function `isEven(unsigned int n)` that determines if a positive integer *n* is even, you should test the function using even and odd numbers. A set of tests for that function could be:
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 |     Test     | Expected Result |
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-**Example 2:** Suppose that a friend has created a function `unsigned int ageRange(unsigned int age)` that is supposed to return 0 if the age is between 0 and 5 (inclusive), 1 if the age is between 6 and 18 inclusive, and 2 if the age is above 18. A common source of errors in functions like this one are the values near to the limits of each range, for example, the number 5 can cause errors if the programmer did not use a correct comparison. One good set of tests for the `ageRange` function would be:
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+**Example 2:** Suppose that a friend has created a function `unsigned int ageRange(unsigned int age)` that is supposed to return 0 if the age is between 0 and 5 (inclusive), 1 if the age is between 6 and 18 (inclusive), and 2 if the age is above 18. A common source of errors in functions like this one are the values near to the limits of each range, for example, the number 5 can cause errors if the programmer did not use a correct comparison. One good set of tests for the `ageRange` function would be:
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 |      Test      | Expected Result |
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 |----------------|-----------------|
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-###`Assert` Function:
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+### The`assert` function:
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-The `assert(bool expression)` function can be used as a rudimentary tool to validate functions. `assert` has a very powerful yet simple functionality. If the expression that we place between the `assert` parenthesis is *true*, the function allows the program to continue onto the next instruction. Otherwise, if the expression we place between the parenthesis is *false*, the `assert` function causes the program to terminate and prints an error message on the terminal that informs the user about the `assert` instruction that failed.
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+The `assert(bool expression)` function can be used as a rudimentary tool to validate functions. `assert` has a very powerful, yet simple functionality. If the expression that we place between the `assert` parenthesis is *true*, the function allows the program to continue onto the next instruction. Otherwise, if the expression we place between the parenthesis is *false*, the `assert` function causes the program to terminate and prints an error message on the terminal, that informs the user about the `assert` instruction that failed.
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 For example, the following program will run from start to finish without problems since every expression included in the assert's parentheses evaluates to *true*.
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-The following program will not run to completion because the second `assert` (`assert(j == i);`) contains an expression (`j==i`) that evaluates to *false*.
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+The following program will not run to completion because the second `assert` (`assert(j == i);`) contains an expression (`j == i`) that evaluates to *false*.
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-When the program is run, instead of getting the phrase `”That's all, folks!”` in the terminal, we will obtain something like:
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+When the program is ran, instead of getting the phrase `"That's all, folks!"` in the terminal, we will obtain something like:
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 `Assertion failed: (j == i), function main, file ../program01/main.cpp, line 8.`
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 The program will not execute the remaining instructions after line 8.
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-####How to use assert to validate functions?
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+#### How to use assert to validate functions?
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-Suppose that  you want to automate the validation of the `ageRange`. One way to do it is by  implementing and calling a function that calls the `ageRange` function with different arguments and verifies that each returned value is equal to  the expected result. If the `ageRange` function returns a value that is not expected, the testing function aborts the program and reports the test that failed. The following illustrates a function to test the `ageRange` function. Observe that it consists of one assert per each of the tests we had listed earlier. 
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+Suppose that you want to automate the validation of the `ageRange`. One way to do it is by implementing and calling a function that calls the `ageRange` function with different arguments and verifies that each returned value is equal to the expected result. If the `ageRange` function returns a value that is not expected, the testing function aborts the program and reports the test that failed. The following illustrates a function to test the `ageRange` function. Observe that it consists of one assert per each of the tests we had listed earlier. 
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-##Laboratory Session:
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+## Laboratory Session:
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-###Exercise 1: Designing tests by hand:
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+### Exercise 1: Designing tests by hand
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-In this exercise you will practice how to design tests to validate functions, using only the function's description and the graphical user interface that is used interact with the function.
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+In this exercise you will practice how to design tests to validate functions, using only the function's description and the graphical user interface that is used to interact with the function.
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 The exercise **DOES NOT require programming**, it only requires that you understand the function’s description, and your ability to design tests. This exercise and Exercise 2 are an adaptation of the activity described in [1].
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-**Example 3** Suppose that a friend provides you with a program. She makes sure the program solves the following problem:
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+**Example 3:** Suppose that a friend provides you with a program. She makes sure the program solves the following problem:
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 `"given three integers, it displays the max value".`
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 If one of these three cases does not have the expected result, your friend's program does not work. On the other hand, if the three cases work, then the program has a high probability of being correct.
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-####Functions to validate
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+#### Functions to validate
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 In this exercise you will be designing tests to validate various versions of the functions that are described below. Each one of the functions has four versions, "Alpha", "Beta", "Gamma" and "Delta".
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-* **3 Sorts:** a function that receives three strings and orders them in lexicographic (alphabetical) order. For example, given `giraffe`, `fox`, and `coqui`, it would order them as: `coqui`, `fox`, and `giraffe`. To simplify the exercise, we will be using strings with lowercase **letters**. Figure 5 shows the function's interface. Notice there is a menu to select the implemented version.
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+* **3 Sorts:** A function that receives three strings and orders them in lexicographic (alphabetical) order. For example, given `giraffe`, `fox`, and `coqui`, it would order them as: `coqui`, `fox`, and `giraffe`. To simplify the exercise, we will be using strings with **lowercase letters**. Figure 5 shows the function's interface. Notice there is a menu to select the implemented version.
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-* **Dice:** when the user presses the `Roll them!` button, the program generates two random integers between 1 and 6. The program informs the sum of the two random integers.
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+* **Dice:** When the user presses the `Roll them!` button, the program generates two random integers between 1 and 6. The program informs the sum of the two random integers.
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- * **Rock, Paper, Scissors:** each one of the players enters their play and the program informs who the winner is. Figure 7 shows the options where one object beats the other. The game's interface is shown in Figure 8.
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+ * **Rock, Paper, Scissors:** Each one of the players enters their play and the program informs who the winner is. Figure 7 shows the options where one object beats the other. The game's interface is shown in Figure 8.
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-####Instructions
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+#### Instructions
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 1. For each of the functions described above, write in your notebook the tests that you will do to determine the validity of each implementation (Alpha, Beta, Gamma and Delta). For each function, think of the logical errors that the programmer could have made and write tests that determine if these errors were made. For each test, write the values that you will use and the expected result.
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 You can see examples of how to organize your results [here](http://i.imgur.com/ggDZ3TQ.png) and [here](http://i.imgur.com/rpApVqm.png).
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-###Exercise 2: Doing tests “by hand”
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+### Exercise 2: Doing tests “by hand”
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 The `testing` project implements several versions of each of the four functions that were described in Exercise 1. Some or all of the implementations could be incorrect. Your task is, using the tests you designed in Exercise 1, to test the versions for each function to determine which of them, if any, are implemented correctly.
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 This exercise **DOES NOT require programming**, you should make the tests **without looking at the code.**
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-####Instructions
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 1. Load the project  `Testing` into `QtCreator`. There are two ways to do this:
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     * Using the virtual machine: Double click the file `Testing.pro` located in the folder `/home/eip/labs/testing-testing` of your virtual machine.
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     * Downloading the project’s folder from `Bitbucket`: Use a terminal and write the command `git clone http:/bitbucket.org/eip-uprrp/testing-testing` to download the folder `testing-testing` from `Bitbucket`. Double click the file `Testing.pro` located in the folder that you downloaded to your computer.
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 2. Configure the project and run the program. You will see a window similar to the following:
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-###Exercise 3: Using `assert` to make unit tests
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+### Exercise 3: Using `assert` to make unit tests
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-Doing tests by hand each time you run a program is a tiresome task. In the previous exercises you did it for a few simple functions. Imagine doing the same for a complex program like a search engine or a word processor.
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+Doing tests by hand each time you run a program is a tiresome task. In the previous exercises you did it for a few simple functions. Imagine doing the same for a complex program like a search engine or a word processor!
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 *Unit tests* help programmers validate code and simplify the process of debugging while avoiding having to do these tests by hand in each execution.
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-####Instructions:
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 1. In the `QtCreator` menu, go to `Build` and select `Clean Project "Testing"`. Then go to `File` and select `Close Project "Testing"`.
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     Your task is to write unit tests for each of the functions to identify the erroneous results. **You do not need to rewrite the functions to correct them.**
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-    For the `fact` function, a `test_fact()` is provided as a unit test function. If you invoke the function from `main`, compile and run the program you should obtain a message like the following:
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+    For the `fact` function, a `test_fact()` is provided as a unit test function. If you invoke the function from `main`, compile, and run the program, you should obtain a message like the following:
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      `Assertion failed: (fact(2) == 2), function test_fact, file ../UnitTests/ main.cpp, line 69.`
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-##Deliverables
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+## Deliverables
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-1. Use "Deliverable 1" in Moodle to hand in the table with the tests you designed in Exercise 1 and that you completed in Exercise 2 with the results from the function tests.
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+1. Use "Deliverable 1" in Moodle to turn in the table with the tests you designed in Exercise 1 and that you completed in Exercise 2, with the results from the function tests.
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-2. Use "Deliverable 2" in Moodle to hand in the `main.cpp` file that contains the `test_isALetter`, `test_isValidTime`, `test_gcd` functions and their calls. Remember to use good programming techniques, include the name of the programmers involved and document your program.
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+2. Use "Deliverable 2" in Moodle to turn in the `main.cpp` file that contains the `test_isALetter`, `test_isValidTime`, `test_gcd` functions and their calls. Remember to use good programming techniques by including the name of the programmers involved and documenting your program.
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