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Author: saqibkhan

  • Lack of Built-in Garbage Collection

    Unlike some modern languages, C++ does not have automatic garbage collection, which can lead to increased developer responsibility for resource management.

  • Limited Runtime Type Information (RTTI)

    C++ has limited built-in support for runtime type identification compared to languages with richer reflection capabilities, which can make certain programming tasks more cumbersome.

  • Compatibility Issues

    Different compilers and platforms may implement C++ standards differently, leading to compatibility issues and portability challenges.

  • Compilation Time

    C++ programs can have longer compilation times due to templates and the complexity of the language, which can slow down the development process.

  • Error-Prone

    The flexibility of C++ can lead to subtle bugs, particularly with pointer arithmetic, manual memory management, and resource leaks, which can be hard to debug.

  • Functions

    A function is a group of statements that together perform a task. Every C++ program has at least one function, which is main(), and all the most trivial programs can define additional functions.

    You can divide up your code into separate functions. How you divide up your code among different functions is up to you, but logically the division usually is such that each function performs a specific task.

    A function declaration tells the compiler about a function’s name, return type, and parameters. A function definition provides the actual body of the function.

    The C++ standard library provides numerous built-in functions that your program can call. For example, function strcat() to concatenate two strings, function memcpy() to copy one memory location to another location and many more functions.

    A function is known with various names like a method or a sub-routine or a procedure etc.

    Defining a Function

    The general form of a C++ function definition is as follows −

    return_type function_name( parameter list ) {
   body of the function
}

    A C++ function definition consists of a function header and a function body. Here are all the parts of a function −

    • Return Type − A function may return a value. The return_type is the data type of the value the function returns. Some functions perform the desired operations without returning a value. In this case, the return_type is the keyword void.
    • Function Name − This is the actual name of the function. The function name and the parameter list together constitute the function signature.
    • Parameters − A parameter is like a placeholder. When a function is invoked, you pass a value to the parameter. This value is referred to as actual parameter or argument. The parameter list refers to the type, order, and number of the parameters of a function. Parameters are optional; that is, a function may contain no parameters.
    • Function Body − The function body contains a collection of statements that define what the function does.

    Example

    Following is the source code for a function called max(). This function takes two parameters num1 and num2 and return the biggest of both −

    // function returning the max between two numbers
 
int max(int num1, int num2) {
   // local variable declaration
   int result;
 
   if (num1 > num2)

      result = num1;
       else

      result = num2;
     
   return result; 
}

    Function Declarations

    A function declaration tells the compiler about a function name and how to call the function. The actual body of the function can be defined separately.

    A function declaration has the following parts −

    return_type function_name( parameter list );

    For the above defined function max(), following is the function declaration −

    int max(int num1, int num2);

    Parameter names are not important in function declaration only their type is required, so following is also valid declaration −

    int max(int, int);

    Function declaration is required when you define a function in one source file and you call that function in another file. In such case, you should declare the function at the top of the file calling the function.

    Calling a Function

    While creating a C++ function, you give a definition of what the function has to do. To use a function, you will have to call or invoke that function.

    When a program calls a function, program control is transferred to the called function. A called function performs defined task and when it’s return statement is executed or when its function-ending closing brace is reached, it returns program control back to the main program.

    To call a function, you simply need to pass the required parameters along with function name, and if function returns a value, then you can store returned value. For example −

    #include <iostream>
using namespace std;
 
// function declaration
int max(int num1, int num2);
 
int main () {
   // local variable declaration:
   int a = 100;
   int b = 200;
   int ret;
 
   // calling a function to get max value.
   ret = max(a, b);
   cout << "Max value is : " << ret << endl;
 
   return 0;
}
 
// function returning the max between two numbers
int max(int num1, int num2) {
   // local variable declaration
   int result;
 
   if (num1 > num2)

      result = num1;
       else

      result = num2;
     
   return result; 
}

    I kept max() function along with main() function and compiled the source code. While running final executable, it would produce the following result −

    Max value is : 200

    Function Arguments

    If a function is to use arguments, it must declare variables that accept the values of the arguments. These variables are called the formal parameters of the function.

    The formal parameters behave like other local variables inside the function and are created upon entry into the function and destroyed upon exit.

    While calling a function, there are two ways that arguments can be passed to a function −

    Sr.NoCall Type & Description
    1Call by ValueThis method copies the actual value of an argument into the formal parameter of the function. In this case, changes made to the parameter inside the function have no effect on the argument.
    2Call by PointerThis method copies the address of an argument into the formal parameter. Inside the function, the address is used to access the actual argument used in the call. This means that changes made to the parameter affect the argument.
    3Call by ReferenceThis method copies the reference of an argument into the formal parameter. Inside the function, the reference is used to access the actual argument used in the call. This means that changes made to the parameter affect the argument.

    By default, C++ uses call by value to pass arguments. In general, this means that code within a function cannot alter the arguments used to call the function and above mentioned example while calling max() function used the same method.

    Default Values for Parameters

    When you define a function, you can specify a default value for each of the last parameters. This value will be used if the corresponding argument is left blank when calling to the function.

    This is done by using the assignment operator and assigning values for the arguments in the function definition. If a value for that parameter is not passed when the function is called, the default given value is used, but if a value is specified, this default value is ignored and the passed value is used instead. Consider the following example −

    #include <iostream>
using namespace std;
 
int sum(int a, int b = 20) {
   int result;
   result = a + b;
  
   return (result);
}
int main () {
   // local variable declaration:
   int a = 100;
   int b = 200;
   int result;
 
   // calling a function to add the values.
   result = sum(a, b);
   cout << "Total value is :" << result << endl;

   // calling a function again as follows.
   result = sum(a);
   cout << "Total value is :" << result << endl;
 
   return 0;
}

    When the above code is compiled and executed, it produces the following result −

    Total value is :300
Total value is :120

  • Verbose Syntax

    C++ code can be verbose, which may lead to longer development times and reduced readability, especially for beginners.

  • String Concatenation

    String concatenation is the process of adding an element to an existing element. In this context, string concatenation is the method by which two (or more) strings can be added to one another. Hence, the resultant string is the combination of the initial string and the added string.

    There are several methods to concatenate strings in C++, some of which are given as follows −

    • Using string::append() function
    • Using ‘+’ operator
    • Using strcat() function for C-style strings
    • Using for loop
    • Using while loop
    • Using range based loop
    • Using inheritance
    • Using friend function with OOPS

    These methods are explained in detail in the next few articles of this chapter. So, let’s dive into these concepts.

    String Concatenation Using string::append() Function

    String is a class defined in <string> header file, and the append() function is an inherited method of that class. This method is used to append or add a given string to an initial string.

    Syntax

    The following syntax is used to concatenate string using the append() method −

    initial_string.append(new_string);
initial_string.append(“this is new”);

    Parameters

    The string::append() function takes a string as a parameter. The string can be passed explicitly or as an object.

    Example of append() function

    The following exemplar code is used to concatenate string using the append() method −

    Open Compiler

    #include <iostream>usingnamespace std;intmain(){
   string initial_string("I Love TP.");
   string new_string(" I am new here.");//using append function with object parameter 
   initial_string.append(new_string);//using append function with explicit string
   initial_string.append(" Could you help me?");

   cout << initial_string << endl;return0;}

    Output

    I Love TP. I am new here. Could you help me?

    String Concatenation Using ‘+’ Operator

    One of the easiest way to add strings is to use the ‘+’ operator on two or more strings. This can be done in place (i.e. without creating a new string), or in a new string object. This is one of the newer features of C++ programming language.

    Syntax

    The following syntax is used to concatenate string using the ‘+’ opertaor −

    new_string=initial_string+added_string;
initial_string+=added_string

    Here, the new string can be added in place or by creating a new string object.

    Example

    The following exemplar code is used to concatenate string using the ‘+’ opertaor −

    Open Compiler

    #include <iostream>usingnamespace std;intmain(){
   string initial_string("I Love TP.");
   string new_string(" I am new here.");

   string a="Hey !!! "+ initial_string;//using new string object

   a+=new_string;//inplace addition

   a+=" Could you help me? ";

   cout << a << endl;return0;}

    Output

    Hey !!! I Love TP. I am new here. Could you help me?

    String Concatenation Using for Loop

    We can use a simple for loop from the beginning of the new string to the end of the new string, and for each iteration, we can add that character to the initial string. This can be done in place, or by using a new string object. This type of concatenation is also possible in C-style strings, which are character arrays.

    Syntax

    The following syntax is used to concatenate string using for loop from beginning of the string to the end −

    for(int i=0;i<s.length();i++){
   initial+=s[i];}

    Example

    The following exemplar code is used to concatenate string using for loop from beginning of the string to the end −

    Open Compiler

    #include <iostream>usingnamespace std;intmain(){
   string initial_string("I Love TP.");
   string new_string(" I am new here.");for(int i=0;i<new_string.size();i++){

      initial_string+=new_string&#91;i];}//using for loop to iterate over new_string
    
   cout << initial_string << endl;return0;}

    Output

    I Love TP. I am new here.

    String Length Using while Loop

    We can also use a simple while loop. This loop runs till we reach the end of the string, and at each iteration, we can add the corresponding character to the initial string. This can be done in place, or by using a new string object. This type of concatenation is also possible in C-style strings, which are character arrays.

    Syntax

    The following syntax is used to concatenate string using while loop from beginning of the string to the end −

    for(int i=0;i<s.length();i++){
   initial+=s[i];}

    Example

    The following exemplar code is used to concatenate string using while loop from beginning of the string to the end −

    #include <iostream>usingnamespace std;intmain(){
   string initial_string("I Love TP.");
   string new_string(" I am new here.");int i=0;while(new_string[i]!='\0'){

      initial_string+=new_string&#91;i];
  i++;}//using while loop to iterate over new_string
    
   cout << initial_string << endl;return0;}

    String Concatenation Using range based loop

    We can also use a range based loop, which will automatically iterate over the whole string and we can add each character to the initial string. This can be done in place, or by using a new string object.

    Syntax

    The following syntax is used to concatenate string using range based loop from beginning of the string to the end −

    for(char c: s){
   initial+=c;}

    Example

    The following exemplar code is used to concatenate string using range based loop from beginning of the string to the end −

    Open Compiler

    #include <iostream>usingnamespace std;intmain(){
   string initial_string("I Love TP.");
   string new_string(" I am new here.");for(char c: new_string){

      initial_string+=c;}//using range based loop for concatentation
    
   cout << initial_string << endl;return0;}

    Output

    I Love TP. I am new here.

    String Concatenation Using strcat() Function

    We can use strcat() function to concatenate strings in C++. But, this method does not work for string objects, it only works for C-style strings, i.e. character arrays. This method is defined in the <string.h> header file.

    Syntax

    The following syntax is used to concatenate string using the strcat() method −

    strcat(s1,s2);

    Parameters

    Here, s1 and s2 are two character arrays (i.e. strings) which are passed as parameters to the strcat() method.

    Example

    The following exemplar code is used to concatenate string using the strcat() method −

    Open Compiler

    #include <bits/stdc++.h>usingnamespace std;intmain(){char s1[]="I love ";char s2[]=" TP. Could you help me? ";//using strcat function to concatenate//result stored in s1strcat(s1,s2);
   cout << s1 << endl;return0;}

    Output

    I love  TP. Could you help me?

    String Concatenation Using Inheritance

    We can use strcat() function to concatenate strings in C++. But, this method does not work for string objects, it only works for C-style strings, i.e. character arrays. This method is defined in the <string.h> header file.

    Syntax

    The following syntax is used to concatenate string using the inheritance method in OOP concepts −

    strcat(s1,s2);

    Example

    The following exemplar code is used to concatenate string using the inheritance method in OOP concepts −

    Open Compiler

    #include <bits/stdc++.h>usingnamespace std;//parent classclassparent{public:virtual string concatenate(string s1, string s2)=0;//creating a virtual method to inherit};//child classclasschild:parent{public: 

      string concatenate(string s1, string s2){
     s1+=s2;//using + operator to add stringsreturn s1;}};intmain(){ 
       child ch1;
   cout << ch1.concatenate("I love ","TP !!!");return0;}

    Output

    I love TP !!!

    String Concatenation Using Friend Function with OOPS

    A friend class can access private and protected members of other classes in which it is declared as a friend. It is sometimes useful to allow a particular class to access private and protected members of other classes.

    Hence, we make use of this friend class to declare a helper method, and then use the strcat() function for C-style strings.

    Syntax

    The following syntax is used to concatenate string using the friend method in C++ −

    Class A {
   string s1=[value];
   string s2=[value];friendvoidhelper(A obj);}helper(A){strcat(obj.s1, obj.s2);};

    Example

    The following exemplar code is used to concatenate string using the friend method in C++ −

    Open Compiler

    #include <bits/stdc++.h>usingnamespace std;// concatenate class classconcatenate{public:char s1[20]="I love TP !!!";char s2[20]="Hey... ";friendvoidhelper(concatenate par1);};voidhelper(concatenate par1){// Pass parameter to concatenate strcat(par1.s2, par1.s1); 

   cout << par1.s2;}intmain(){// Create object of class 
   concatenate par1;//pass this object to helper function helper(par1);return0;}

    Output

    Hey... I love TP !!!

  • Manual Memory Management

    While C++ provides control over memory allocation, it also requires developers to manage memory manually, increasing the risk of memory leaks and undefined behavior if not handled carefully

  • Complexity

    C++ has a steep learning curve due to its rich feature set, including multiple programming paradigms, extensive syntax, and intricate concepts like pointers and memory management.