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Using functions in C++ - Pretty Plots

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[Version 2016- Tatiana- Ive - Tatiana]

A good way to organize and structure computer programs is dividing them into smaller parts using functions. Each function carries out a specific task of the problem that we are solving.

You’ve seen that all programs written in C++ must contain the main function where the program begins. You’ve probably already used functions such as pow, sin, cos, or sqrt from the cmath library. Since in almost all of the upcoming lab experiences, you will continue using pre-defined functions, you need to understand how to work with them. In future exercises, you will learn how to design and prove functions. In this laboratory experience, you will call and define functions that compute the coordinates of the points of the graphs of some curves. You will also practice the implementation of arithmetic expressions in C++.

Objectives:

  1. Identify the parts of a function: return type, name, list of parameters, and body.
  2. Call pre-defined functions by passing arguments by value (“pass by value”), and by reference (“pass by reference”).
  3. Implement a simple overloaded function.
  4. Implement a simple function that utilizes parameters by reference.
  5. Implement arithmetic expressions in C++.

Pre-Lab:

Before you get to the laboratory you should have:

  1. Reviewed the following concepts:

    a. the basic elements of a function definition in C++.

    b. how to call functions in C++.

    c. the difference between parameters that are passed by value and by reference.

    d. how to return the result of a function.

    e. implement arithmetic expressions in C++.

    f. use functions and arithmetic constants from the cmath library.

    g. a circle’s graph and equation.

  2. Studied the concepts and instructions for the laboratory session.

  3. Taken the Pre-Lab quiz, available in Moodle.



Functions

In mathematics, a function $$f$$ is a rule that is used to assign to each element $$x$$ from a set called domain, one (and only one) element $$y$$ from a set called range. This rule is commonly represented with an equation, $$y=f(x)$$. The variable $$x$$ is the parameter of the function and the variable $$y$$ will contain the result of the function. A function can have more than one parameter, but only one result. For example, a function can have the form $$y=f(x_1,x_2)$$ where there are two parameters, and for each pair $$(a,b)$$ that is used as an argument in the function and the function will have only one value of $$y=f(a,b)$$. The domain of the function tells us the type of value that the parameter should have and the range tells us the value that the returned result will have.

Functions in programming languages are similar. A function has a series of instructions that take the assigned values as parameters and perform a certain task. In C++ and other programming languages, functions return only one result, as it happens in mathematics. The only difference is that a programming function could possibly not return any value (in this case the function is declared as void). If the function will return a value, we use the instruction return. As in math that you need to specify the domain and range, in programming you need to specify the types of values that the function’s parameters and result will have; this is done when declaring the function.

Function header

The first sentence of a function is called the header and its structure is as follows:

type name(type parameter_1, ..., type parameter_n)

For example,

int example(int var1, float var2, char &var3)

would be the header of the function called example, which returns an integer value. The function receives as arguments an integer value (and will store a copy in var1), a value of type float (and will store a copy in var2) and the reference to a variable of type char that will be stored in the reference variable var3. Note that var3 has a & symbol before the name of the variable. This indicates that var3 will contain the reference to a character.

Calling

If we want to store the value of the result of the function called example in a variable result (that would be of type integer), we call the function by passing arguments as follows:

result=example(2, 3.5, unCar);

Note that as the function is called, you don’t include the type of the variables in the arguments as in the definition for the function example. The third parameter &var3 is a reference variable; this means that what is being sent to the third argument when invoking the function is a reference to the variable unCar. Any changes that are made on the variable var3 will change the contents of the variable unCar.

You can also use the function’s result without having to store it in a variable. For example you could print it:

cout << "The result of the function example is:" << example(2, 3.5, unCar);

or use it in an arithmetic expression:

y = 3 + example(2, 3.5, unCar);

Overloaded Functions

Overloaded functions are functions that have the same name, but a different signature.

The signature of a function is composed of the name of the function, and the types of parameters it receives, but does not include the return type.

The following function prototypes have the same signature:

int example(int, int) ;
void example(int, int) ;
string example(int, int) ;

Note that each has the same name, example, and receives the same amount of parameters of the same type (int, int).

The following function prototypes have different signatures:

int example(int) ;
int elpmaxe(int) ;

Note that even though the functions have the same amount of parameters with the same type int, the name of the functions is different.

The following function prototypes are overloaded versions of the function example:

int example(int) ;
void example(char) ;
int example(int, int) ;
int example(char, int) ;
int example(int, char) ;

All of the above functions have the same name, example, but different parameters. The first and second functions have the same amount of parameters, but their arguments are of different types. The fourth and fifth functions have arguments of type char and int, but have a different order in each case.

In that last example, the function example is overloaded since there are five functions with different signatures but with the same name.

Default Values

Values by default can be assigned to the parameters of the functions starting from rightmost parameter. It is not necessary to initialize all of the parameters, but the ones that are initialized should be consecutive: parameters in between two parameters cannot be left uninitialized. This allows calling the function without having to send values in the positions that correspond to the initialized parameters.

Examples of Function Headers and Valid Function Calls:

  1. Headers: int example(int var1, float var2, int var3 = 10)

    Calls:

    a. example(5, 3.3, 12) This function call assigns the value 5 to var1, the value 3.3 to var2, and the value of 12 to var3.

    b. example(5, 3.3) This function call sends the values for the first two parameters and the value for the last parameter will be the value assigned by default in the header. That is, the values in the variables in the function will be as follows: var1 will be 5, var2 will be 3.3, and var3 will be 10.

  2. Header: int example(int var1, float var2=5.0, int var3 = 10)

    Calls:

    a. example(5, 3.3, 12) This function call assigns the value 5 to var1, the value 3.3 to var2, and the value 12 to var3.

    b. example(5, 3.3) In this function call only the first two parameters are given values, and the value for the last parameter is the value by default. That is, the value for var1 within the function will be 5, that of var2 will be 3.3, and var3 will be 10.

    c. example(5) In this function call only the first parameter is given a value, and the last two parameters will be assigned values by default. That is, var1 will be 5, var2 will be 5.0, and var3 will be 10.

Example of a Valid Function Header with Invalid Function Calls:

  1. Header: int example(int var1, float var2=5.0, int var3 = 10)

    Calls:

    a. example(5, , 10) This function call is invalid because it leaves an empty space in the middle argument.

    b. example() This function call is invalid because var1 was not assigned a default value. A valid call to function example needs at least one argument (the first).

Examples of Invalid Function Headers:

  1. int example(int var1=1, float var2, int var3) This header is invalid because the default values can only be assigned starting from the rightmost parameter.

  2. int example(int var1=1, float var2, int var3=10) This header is invalid because you can’t place parameters without values between other parameters with default values. In this case, var2 doesn’t have a default value but var1 and var3 do.



Parametric Equations

Parametric equations allow us to represent a quantity as a function of one or more independent variables called parameters. In many occasions it is useful to represent curves using a set of parametric equations that express the coordinates of the points of the curve as functions of the parameters. For example, in your trigonometry course you should have studied that the equation of the circle of radius $$r$$ and centered at the origin has the following form:

$$x^2+y^2=r^2.$$

The points $$(x,y)$$ that satisfy this equation are the points that form the circle of radius $$r$$ and center at the origin. For example, the circle with $$r=2$$ and center at the origin has equation

$$x^2+y^2=4,$$

and its points are the ordered pairs $$(x,y)$$ that satisfy this equation. A parametric representation of the coordinates of the points in the circle of radius $$r$$ and center at the origin is:

$$x=r \cos(t)$$

$$y=r \sin(t),$$

where $$t$$ is a parameter that corresponds to the measure (in radians) of the positive angle with an initial side that coincides with the positive part of the $$x$$-axis and a terminal side that contains the point $$(x,y)$$, as it is illustrated in Figure 1.


circulo.jpg

Figure 1. Circle with center in the origin and radius $$r$$.


To plot a curve that is described by parametric equations, we compute the $$x$$ and $$y$$ values for a set of values of the parameter. For example, Figure 2 shows the values for $$t$$, $$(x,y)$$ for the circle with $$r=2$$.


circulo.jpg

Figure 2. Some coordinates for the points $$(x,y)$$ for the circle with radius $$r=2$$ and center in the origin.



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Laboratory Session:

In the introduction to the topic of functions you saw that in mathematics and in some programming languages, a function cannot return more than one result. In this laboratory experience’s exercises, you will practice how to use reference variables to obtain various results from a function.

Exercise 1 - Difference between Pass by Value and Pass by Reference

Instructions

  1. Load the project ‘prettyPlot’ into ‘QtCreator`. There are two ways to do this:

    • Using the virtual machine: Double click the file prettyPlot.pro located in the folder home/eip/labs/functions-prettyplots of your virtual machine.
    • Downloading the project’s folder from Bitbucket: Use a terminal and write the command git clone http://bitbucket.org/eip-uprrp/functions-prettyplots to download the folder functions-prettyplots from Bitbucket. Double click the file prettyPlot.pro located in the folder that you downloaded to your computer.
  2. Configure the project and execute the program by clicking on the green arrow in the menu on the left side of the Qt Creator screen. The program should show a window similar to the one in Figure 3.


    Figura3.png

    Figure 3. Graph of a circle with radius 5 and center in the origin displayed by the program PrettyPlot.


  3. Open the file main.cpp (in Sources). Study the illustration function and how to call it from the main function. Note that the variables argValue and argRefare initialized to 0 and that the function call for illustration makes a pass by value of argValue and a pass by reference of argRef. Also note that the corresponding parameters in illustration are assigned a value of 1.

    void illustration(int paramValue, int &paramRef) {
        paramValue = 1;
        paramRef = 1;
        cout << endl << "The content of paramValue is: " << paramValue << endl
             << "The content of paramRef is: " << paramRef << endl;
    }
    
  4. Execute the program and observe what is displayed in the window Application Output. Notice the difference between the content of the variables argValue and argRef despite the fact that both had the same initial value, and that paramValue and paramRef were assigned the same value. Explain why the content of argValor does not change, while the content of argRef changes from 0 to 1.

Exercise 2 - Creation of an Overloaded Function

Instructions

  1. Study the code in the main() function in the file main.cpp. The line XYPlotWindow wCircleR5; creates a wCircleR5 object that will be the window where the graph will be drawn, in this case the graph of a circle of radius 5. In a similar way, the objects wCircle and wButterfly are created. Observe the for cycle. In this cycle a series of values for the angle $$t$$ are generated and the function circle is called, passing the value for $$t$$ and the references to $$x$$ and $$y$$. The circle function does not return a value, but by using parameters by reference, it calculates the values for the coordinates $$xCoord$$ and $$yCoord$$ for the circle with center in the origin and radius 5, and allows the main function to have these values in the x , y variables.

    XYPlotWindow wCircleR5;
    XYPlotWindow wCircle;
    XYPlotWindow wButterfly;
    
    double r;
    double y = 0.00;
    double x = 0.00;
    double increment = 0.01;
    int argValue=0, argRef=0;
    
    // call the function illustration to view the contents of variables
    // by value and by reference
    
        illustration(argValue,argRef);
        cout << endl << "The content of argValue is: " << argValue << endl
             << "The content of argRef is: " << argRef << endl;
    
    // repeat for several values of the angle t
    for (double t = 0; t < 16*M_PI; t = t + increment) {
    
        // call circle with the angle t and reference variables x, y as arguments
        circle(t,x,y);
    
        // add the point (x,y) to the graph of the circle
        wCircleR5.AddPointToGraph(x,y);
    }
    

    After the function call, each ordered pair $$(x,y)$$ is added to the circle’s graph by the member function AddPointToGraph(x,y). After the cycle, the member function Plot() is called, which draws the points, and the member function show(), which displays the graph. The members functions are functions that allow use to work with and object’s data. Notice that each one of the member functions is written after wCircleR5, followed by a period. In an upcoming laboratory experience you will learn more about objects, and practice how to create them and invoke their method functions.

    The circle function implemented in the program is very restrictive since it always calculates the values for the coordinates $$x$$ and $$y$$ of the same circle: the circle with center in the origin and radius 5.

  2. Now you will create an overloaded function circle that receives as arguments the value of the angle $$t$$, the reference to the variables $$x$$ and $$y$$, and the value for the radius of the circle. Call the overloaded function circle that you just implemented from main() to calculate the values of the coordinates $$x$$ and $$y$$ for the circle with radius 15 and draw its graph. Graph the circle within the wCircle object. To do this, you must call the method functions AddPointToGraph(x,y), Plot and show from main(). Remember that these should be preceded by wCircle, for example, wCircle.show().

Exercise 3 - Implement a Function to Calculate the Coordinates of the Points in the Graph of a Curve

Instructions

  1. Now you will create a function to calculate the coordinates of the points of a graph that resembles a butterfly. The parametric equations for the coordinates of the points in the graph are given by:

    $$x=5\cos(t) \left[ \sin^2(1.2t) + \cos^3(6t) \right]$$

    $$y= 10\sin(t) \left[ \sin^2(1.2t) + \cos^3(6t) \right].$$

    Observe that both expressions are almost the same, except that one starts with $$5\cos(t)$$ and the other with $$10\sin(t)$$. Instead of doing the calculation for $$ \sin^2(1.2t) + \cos^3(6t)$$ twice, you can assign its value to another variable $$q$$ and calculate it as such:

    $$q = \sin^2(1.2t) + \cos^3(6t)$$

    $$x = 5 \cos(t)(q)$$

    $$y = 10 \sin(t)(q).$$

  2. Implement the function butterfly using the expressions above, call the function in main() and observe the resulting graph. It is supposed to look like a butterfly. This graph should have been obtained with a XYPlotWindow object called wButterfly, invoking method functions similar to how you did in Exercise 2 for the circle.

In [2] and [3] you can find other parametric equations from other interesting curves.



Deliverables

Use “Deliverables” in Moodle to hand in the file main.cpp that contains the functions you implemented, the function calls and changes you made in exercises 2 and 3. Remember to use good programming techniques, include the name of the programmers involved and document your program.



References

[1] http://mathbits.com/MathBits/CompSci/functions/UserDef.htm

[2] http://paulbourke.net/geometry/butterfly/

[3] http://en.wikipedia.org/wiki/Parametric_equation