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Java Tutorial JAVA TUTORIAL Simply Easy Learning by tutorialspoint.com tutorialspoi nt.com ABOUT THE TUTORIAL Java Tutorial Java is a high-level programming language srcinally developed by Sun Microsystems and released in 1995. Java runs on a variety of platforms, such as Windows, Mac OS, and the various versions of UNIX. This tutorial gives a complete understanding ofJava. This reference will take you through simple and practical approach while learning Java Programming language. Audience This reference has been prepared for the beginners to help them understand the basic to advanced concepts related to Java Programming language. Prerequisites Before you start doing practice with various types of examples given in this reference, I'm making an assumption that you are already aware about what is a computer program and what is a computer programming language? Copyright & Disclaimer Notice All the content and graphics on this tutorial are the property o f tutorialspoint.com. Any content „¶ from tutorialspoint.com or this tutorial may not be redistributed or reproduced in any way, shape, or form without the written permission of tutorialspoint.com. Failure to do so is a violation of copyright laws. This tutorial may contain inaccuracies or errors and tutorialspoint provides no guarantee regarding the accuracy of the site or its contents including this tutorial. If you discover that the tutorialspoint.com site or this tutorial content contains some errors, please contact us at [email protected] Table of Content Java Tutorial ............................................................................ 2 Audience .................................................................................. 2 Prerequisites ............................................................................ Copyright & Disclaimer Notice .................................................. 22 Java Overview ....................................................................... 15 History of Java: ........................................................................................ 16 Tools you will need: .................................................................................. 16 What is Next? ........................................................................................... 16 Java Environment Setup ........................................................ 17 Setting up the path for windows 2000/XP:................................................ 17 Setting up the path for windows 95/98/ME: .............................................. 17 Setting up the path for Linux, UNIX, Solaris, FreeBSD: ........................... 17 Popular Java Editors: ............................................................................... 18 What is Next? ........................................................................................... 18 Java Basic Syntax .................................................................. 19 First Java Program: .................................................................................. 19 Basic Syntax: ........................................................................................... 20 Java Identifiers: ........................................................................................ 20 Java Modifiers: ......................................................................................... 21 Java Variables: ......................................................................................... 21 Java Arrays: ............................................................................................. 21 Java Enums: ............................................................................................ 21 Example: .................................................................................................. 21 Java Keywords: ........................................................................................ 22 Comments in Java ................................................................................... 22 Using Blank Lines: ................................................................................... 22 Inheritance: .............................................................................................. 22 Interfaces: ................................................................................................ 23 What is Next? ........................................................................................... 23 Java Object & Classes ........................................................... 24 Objects in Java: ........................................................................................ 24 Classes in Java: ....................................................................................... 25 Constructors: ............................................................................................ 25 Creating an Object: .................................................................................. 26 Accessing Instance Variables and Methods: ............................................ 26 Example: .................................................................................................. 26 Source file declaration rules: .................................................................... 27 Java Package: .......................................................................................... 28 Import statements: ................................................................................... 28 A Simple Case Study: .............................................................................. 28 What is Next? ........................................................................................... 29 Java Basic Data Types .......................................................... 30 Primitive Data Types: ............................................................................... 30 byte: ......................................................................................................... 30 short: ........................................................................................................ 30 int: ............................................................................................................ 31 long: ......................................................................................................... 31 float: ......................................................................................................... 31 double: ..................................................................................................... 32 boolean: ................................................................................................... 32 char: ......................................................................................................... 32 Reference Data Types: ............................................................................ 32 Java Literals: ............................................................................................ 33 What is Next? ........................................................................................... 34 Java Variable Types .............................................................. 35 Local variables: ........................................................................................ 35 Example: .................................................................................................. 36 Example: .................................................................................................. 36 Instance variables: ................................................................................... 36 Example: .................................................................................................. 37 Class/static variables:............................................................................... 38 Example: .................................................................................................. 38 What is Next? ........................................................................................... 39 Java Modifier Types ............................................................... 40 1. Java Access Modifiers .......................................................................... 40 Default Access Modifier - No keyword:..................................................... 40 Example: .................................................................................................. 40 Private Access Modifier - private: ............................................................. 41 Example: .................................................................................................. 41 Public Access Modifier - public: ................................................................ 41 Example: .................................................................................................. 41 Protected Access Modifier - protected: .................................................... 42 Example: .................................................................................................. 42 Access Control and Inheritance: .............................................................. 42 2. Non Access Modifiers ........................................................................... 42 Access Control Modifiers: ......................................................................... 43 Non Access Modifiers:.............................................................................. 43 Access Control Modifiers: ......................................................................... 43 Non Access Modifiers:.............................................................................. 43 What is Next? ........................................................................................... 44 Java Basic Operators ............................................................. 45 The Arithmetic Operators: ........................................................................ 45 The Relational Operators: ........................................................................ 46 Example ................................................................................................... 47 The Bitwise Operators: ............................................................................. 47 Example ................................................................................................... 48 The Logical Operators: ............................................................................. 49 Example ................................................................................................... 49 The Assignment Operators: ..................................................................... 49 Example: .................................................................................................. 50 Misc Operators ......................................................................................... 51 Conditional Operator (?:): ......................................................................... 51 instanceOf Operator: ................................................................................ 52 Precedence of Java Operators: ................................................................ 52 What is Next? ........................................................................................... 53 JavaLoop Control ................................................................... 54 The while Loop: ........................................................................................ 54 Syntax: ..................................................................................................... 54 Example: .................................................................................................. 54 The do...while Loop: ................................................................................. 55 Syntax: ..................................................................................................... 55 Example: .................................................................................................. 55 The for Loop: ............................................................................................ 56 Syntax: ..................................................................................................... 56 Example: .................................................................................................. 56 Enhanced for loop in Java: ....................................................................... 57 Syntax: ..................................................................................................... 57 Example: .................................................................................................. 57 The break Keyword: ................................................................................. 57 Syntax: ..................................................................................................... 58 Example: .................................................................................................. 58 The continue Keyword:............................................................................. 58 Syntax: ..................................................................................................... 58 Example: .................................................................................................. 58 What is Next? ........................................................................................... 59 Java Decision Making ............................................................ 60 The if Statement: ...................................................................................... 60 Syntax: ..................................................................................................... 60 Example: .................................................................................................. 60 The if...else Statement: ............................................................................ 61 Syntax: ..................................................................................................... 61 Example: .................................................................................................. 61 The if...else if...else Statement: ................................................................ 61 Syntax: ..................................................................................................... 61 Example: .................................................................................................. Nested if...else Statement: ....................................................................... 62 62 Syntax: ..................................................................................................... 62 Example: .................................................................................................. 62 The switch Statement: .............................................................................. 63 Syntax: ..................................................................................................... 63 Example: .................................................................................................. 63 What is Next? ........................................................................................... 64 Java Numbers ........................................................................ 65 Example: .................................................................................................. 65 Number Methods: ..................................................................................... 66 xxxValue() ................................................................................................ 67 compareTo() ............................................................................................. 68 equals() .................................................................................................... 69 valueOf() .................................................................................................. 70 toString() .................................................................................................. 71 parseInt() .................................................................................................. 72 abs() ......................................................................................................... 73 ceil() ......................................................................................................... 73 floor() ........................................................................................................ 74 rint() .......................................................................................................... 75 round() ...................................................................................................... 76 min() ......................................................................................................... 77 max() ........................................................................................................ 78 exp() ......................................................................................................... 79 log() .......................................................................................................... 80 pow() ........................................................................................................ 80 sqrt() ......................................................................................................... 81 sin() .......................................................................................................... 82 cos() ......................................................................................................... 83 tan() .......................................................................................................... 84 asin() ........................................................................................................ 84 acos() ....................................................................................................... 85 atan() ........................................................................................................ 86 atan2() ...................................................................................................... 87 toDegrees() .............................................................................................. 88 toRadians() ............................................................................................... 88 random() ................................................................................................... 89 What is Next? ........................................................................................... 90 Java Characters ..................................................................... 91 Example: .................................................................................................. 91 Example: .................................................................................................. 91 Escape Sequences: ................................................................................. 91 Example: .................................................................................................. 92 Character Methods: .................................................................................. 92 isLetter() ................................................................................................... 93 isDigit() ..................................................................................................... 94 isWhitespace() ......................................................................................... 94 isUpperCase() .......................................................................................... 95 isLowerCase() .......................................................................................... 96 toUpperCase() .......................................................................................... 97 toLowerCase() .......................................................................................... 97 toString() .................................................................................................. 98 What is Next? ........................................................................................... 99 Java Strings ......................................................................... 100 Creating Strings: .................................................................................... 100 String Length: ......................................................................................... 100 Concatenating Strings: ........................................................................... 101 Creating Format Strings: ........................................................................ 101 String Methods: ...................................................................................... 102 char charAt(int index) ............................................................................ 104 int compareTo(Object o) ......................................................................... 105 int compareTo(String anotherString) ...................................................... 106 int compareToIgnoreCase(String str) ..................................................... 107 String concat(String str) .......................................................................... 108 boolean contentEquals(StringBuffer sb) ................................................. 109 static String copyValueOf(char[] data) .................................................... 110 static String copyValueOf(char[] data, int offset, int count) ..................... 111 boolean endsWith(String suffix) ............................................................. 112 boolean equals(Object anObject) ........................................................... 113 boolean equalsIgnoreCase(String anotherString) .................................. 114 byte getBytes() ....................................................................................... 115 byte[] getBytes(String charsetName) ..................................................... 116 void getChars(int srcBegin, int srcEnd, char[] dst, int dstBegin) ............. 117 int hashCode() ........................................................................................ 118 int indexOf(int ch) ................................................................................... 119 int indexOf(int ch, int fromIndex) ............................................................ 120 int indexOf(String str) ............................................................................. 122 int indexOf(String str, int fromIndex) ....................................................... 123 String intern() ......................................................................................... 125 int lastIndexOf(int ch) ............................................................................. 126 int lastIndexOf(int ch, int fromIndex) ....................................................... 127 int lastIndexOf(String str) ........................................................................ 129 int lastIndexOf(String str, int fromIndex) ................................................. 130 int length() .............................................................................................. 132 boolean matches(String regex) .............................................................. 133 boolean regionMatches(boolean ignoreCase, int toffset, ....................... 134 String other, int ooffset, int len) .............................................................. 134 boolean regionMatches(int toffset, String other, int ooffset, int len) ........ 135 String replace(char oldChar, char newChar) .......................................... 136 String regex, String replacement) ............................... String replaceAll(String replaceFirst(String regex, String replacement) ............................ 137 138 String[] split(String regex) ....................................................................... 139 String[] split(String regex, int limit) .......................................................... 140 boolean startsWith(String prefix) ............................................................ 142 boolean startsWith(String prefix, int toffset) ............................................ 143 CharSequence subSequence(int beginIndex, int endIndex) .................. 144 String substring(int beginIndex) .............................................................. 145 String substring(int beginIndex, int endIndex) ........................................ 146 char[] toCharArray() ............................................................................... 147 String toLowerCase() ............................................................................. 147 String toLowerCase(Locale locale) ........................................................ 148 String toString() ...................................................................................... 149 String ............................................................................. 150 String toUpperCase() toUpperCase(Locale locale) ........................................................ 151 String trim() ............................................................................................ 152 static String valueOf(primitive data type x) ............................................. 153 Java Arrays .......................................................................... 155 Declaring Array Variables: ...................................................................... 155 Example: ................................................................................................ 155 Creating Arrays: ..................................................................................... 155 Example: ................................................................................................ 156 Processing Arrays: ................................................................................. 156 Example: ................................................................................................ 156 The foreach Loops: ................................................................................ 157 Example: ................................................................................................ 157 Passing Arrays to Methods: ................................................................... 157 Returning an Array from a Method: ........................................................ 158 The Arrays Class: ................................................................................... 158 Java Date & Time ................................................................ 159 Getting Current Date & Time .................................................................. 160 Date Comparison: .................................................................................. 160 Date Formatting using SimpleDateFormat: ............................................ 160 Simple DateFormat format codes: .......................................................... 161 Date Formatting using printf: .................................................................. 161 Date and Time Conversion Characters: ................................................. 163 Parsing Strings into Dates: ..................................................................... 164 Sleeping for a While: .............................................................................. 164 Measuring Elapsed Time: ....................................................................... 165 GregorianCalendar Class: ...................................................................... 165 Example: ................................................................................................ 167 JavaRegular Expressions .................................................... 169 Capturing Groups: .................................................................................. 169 Example: ................................................................................................ 170 Regular Expression Syntax: ................................................................... 170 Methods of the Matcher Class: ............................................................... 171 Index Methods: ....................................................................................... 171 Study Methods: ...................................................................................... 172 Replacement Methods: .......................................................................... 172 The start and end Methods: ................................................................... 172 The matches and lookingAt Methods: .................................................... 173 The replaceFirst and replaceAll Methods: .............................................. 174 The appendReplacement and appendTail Methods: .............................. 174 PatternSyntaxException Class Methods: ............................................... 175 Java Methods....................................................................... 176 Creating a Method: ................................................................................. 176 Example: ................................................................................................ 177 Calling a Method: ................................................................................... 177 Example: ................................................................................................ 177 The void Keyword: ................................................................................. 178 Example: ................................................................................................ 178 Passing Parameters by Values: ............................................................. 179 Example: ................................................................................................ 179 Overloading Methods: ............................................................................ 180 The Scope of Variables: ......................................................................... 180 Using Command-Line Arguments: ......................................................... 181 Example: ................................................................................................ 181 The Constructors: ................................................................................... 182 Example: ................................................................................................ 182 Example: ................................................................................................ 182 Variable Arguments(var-args): ............................................................... 183 Example: ................................................................................................ 183 The finalize( ) Method:............................................................................ 183 Java Files & I/O .................................................................... 185 Reading Console Input: .......................................................................... 185 Reading Characters from Console: ........................................................ 185 Reading Strings from Console: .............................................................. 186 Writing Console Output: ......................................................................... 187 Example: ................................................................................................ 187 Reading and Writing Files: ..................................................................... 187 FileInputStream: ..................................................................................... 188 ByteArrayInputStream ............................................................................ 189 Example: ................................................................................................ 189 DataInputStream .................................................................................... 190 Example: ................................................................................................ 191 FileOutputStream: .................................................................................. 191 ByteArrayOutputStream ......................................................................... 192 Example: ................................................................................................ 193 DataOutputStream ................................................................................. 194 Example: ................................................................................................ 194 Example: ................................................................................................ File Navigation and I/O: .......................................................................... 195 195 File Class ............................................................................................... 195 Example: ................................................................................................ 198 FileReader Class .................................................................................... 199 Example: ................................................................................................ 199 FileWriter Class ...................................................................................... 200 Example: ................................................................................................ 201 Directories in Java: ................................................................................. 201 Creating Directories:............................................................................... 201 Reading Directories: ............................................................................... 202 Java Exceptions ................................................................... 203 Exception Hierarchy: .............................................................................. 203 Exceptions Methods: .............................................................................. 205 Catching Exceptions:.............................................................................. 205 Example: ................................................................................................ 206 Multiple catch Blocks: ............................................................................. 206 Example: ................................................................................................ 207 The throws/throw Keywords: .................................................................. 207 The finally Keyword ................................................................................ 207 Example: ................................................................................................ 208 Declaring you own Exception: ................................................................ 209 Example: ................................................................................................ 209 Common Exceptions: ............................................................................. 211 Java Inheritance ................................................................... 212 IS-A Relationship: .................................................................................. 212 Example: ................................................................................................ 213 Example: ................................................................................................ 213 The instanceof Keyword: ........................................................................ 213 HAS-A relationship: ................................................................................ 214 Java Overriding .................................................................... 215 Example: ................................................................................................ 215 Rules for method overriding: .................................................................. 216 Using the super keyword: ....................................................................... 217 Java Polymorphism .............................................................. 218 Example: ................................................................................................ 218 Virtual Methods: ..................................................................................... 219 Java Abstraction .................................................................. 222 Abstract Class: ....................................................................................... 222 Extending Abstract Class: ...................................................................... 223 Abstract Methods: .................................................................................. 225 Java Encapsulation .............................................................. 226 Example: ................................................................................................ 226 Benefits of Encapsulation: ...................................................................... 227 Java Interfaces ..................................................................... 228 Declaring Interfaces: .............................................................................. 229 Example: ................................................................................................ 229 Example: ................................................................................................ 229 Implementing Interfaces: ........................................................................ 229 Extending Interfaces: ............................................................................. 230 Extending Multiple Interfaces: ................................................................ 231 Tagging Interfaces: ................................................................................ 231 Java Packages ..................................................................... 232 Creating a package: ............................................................................... 232 Example: ................................................................................................ 232 The import Keyword: .............................................................................. 233 Example: ................................................................................................ 233 The Directory Structure of Packages: .................................................... 234 Set CLASSPATH System Variable: ....................................................... 235 Java Data Structures............................................................ 237 The Enumeration: ................................................................................... 237 Example: ................................................................................................ 238 The BitSet .............................................................................................. 238 Example: ................................................................................................ 240 The Vector .............................................................................................. 241 Example: ................................................................................................ 244 The Stack ............................................................................................... 245 Example: ................................................................................................ 246 The Dictionary ........................................................................................ 246 Map Interface ......................................................................................... 247 Example: ................................................................................................ 248 The Hashtable ........................................................................................ 249 Example: ................................................................................................ 250 The Properties ........................................................................................ 251 Example: ................................................................................................ 252 Java Collections ................................................................... 254 The Collection Interfaces: ....................................................................... 254 The Collection Classes:.......................................................................... 255 The Collection Algorithms: ..................................................................... 256 How to use an Iterator? .......................................................................... 257 How to use a Comparator? .................................................................... 257 Summary: ............................................................................................... 257 Java Generics ...................................................................... 258 Generic Methods: ................................................................................... 258 Example: ................................................................................................ 258 Bounded Type Parameters: ................................................................... 259 Example: ................................................................................................ 259 Generic Classes: .................................................................................... 260 Example: ................................................................................................ 260 JavaSerialization .................................................................. 262 Serializing an Object: ............................................................................. 263 Deserializing an Object: ......................................................................... 263 Java Networking .................................................................. 265 Url Processing ........................................................................................ 265 URL Class Methods: .............................................................................. 266 Example: ................................................................................................ 266 URLConnections Class Methods: .......................................................... 267 Example: ................................................................................................ 268 Socket Programming: ............................................................................. 269 ServerSocket Class Methods: ................................................................ 270 Socket Class Methods:........................................................................... 271 InetAddress Class Methods: .................................................................. 272 Socket Client Example: .......................................................................... 272 Socket Server Example: ......................................................................... 273 Java Sending E-mail ............................................................ 275 Send a Simple E-mail: ............................................................................ 275 Send an HTML E-mail: ........................................................................... 276 Send Attachment in E-mail: .................................................................... 278 User Authentication Part: ....................................................................... 279 Java Multithreading .............................................................. 280 Life Cycle of a Thread: ........................................................................... 280 Thread Priorities: .................................................................................... 281 Creating a Thread: ................................................................................. 281 Create Thread by Implementing Runnable: ............................................282 282 Example: ................................................................................................ Create Thread by Extending Thread: ..................................................... 283 Example: ................................................................................................ 283 Thread Methods: .................................................................................... 284 Example: ................................................................................................ 285 Major Thread Concepts: ......................................................................... 287 Example: ................................................................................................ 289 Example: ................................................................................................ 290 Ordering Locks: ...................................................................................... 292 Deadlock Example: ................................................................................ 292 Deadlock Solution Example: .................................................................. 294 Example: ................................................................................................ 296 Using Multithreading:.............................................................................. 298 Java Applet Basics ............................................................... 299 Life Cycle of an Applet: .......................................................................... 299 A "Hello, World" Applet: .......................................................................... 300 The Applet CLASS: ................................................................................ 300 Invoking an Applet: ................................................................................. 301 Getting Applet Parameters: .................................................................... 302 Specifying Applet Parameters: ............................................................... 303 Application Conversion to Applets: ......................................................... 303 Event Handling: ...................................................................................... 304 Displaying Images: ................................................................................. 305 Playing Audio: ........................................................................................ 306 Java Documentation ............................................................ 308 The javadoc Tags: .................................................................................. 308 Documentation Comment: ...................................................................... 309 What javadoc Outputs? .......................................................................... 309 Example: ................................................................................................ 309 Java Library Classes ............................................................ 312 CHAPTER 1 Java Overview J ava programming language was srcinally developed by Sun Microsystems which was initiated by James Gosling and released in 1995 as core component of Sun Microsystems’ Java platform (Java 1.0 [J2SE]). As of December 2008, the latest release of the Java Standard Edition is 6 (J2SE). With the advancement of Java and its widespread popularity, multiple configurations were built to suite various types of platforms. Ex: J2EE for Enterprise Applications, J2ME for Mobile Applications. Sun Microsystems has renamed the new J2 versions as Java SE, Java EE and Java ME, respectively. Java is guaranteed to be Write Once, Run Anywhere. Java is: 1 „h Object Oriented : In Java, everything is an Object. Java can be easily extended since it is based on the Object model. 2 3 4 5 6 7 8 1 2 3 4 „h Platform independent : Unlike many other programming languages including C and C++, when Java is compiled, it is not compiled into platform specific machine, rather into platform independent byte code. This byte code is distributed over the web and interpreted by virtual Machine (JVM) on whichever platform it is being run. „h Simple:Java is designed to be easy to learn. If you understand the basic concept of OOP,Java would be easy to master. „h Secure: With Java's secure feature, it enables to develop virus-free, tamper-free systems. Authentication techniques are based on public-key encryption. „h Architectural-neutral :Java compiler generates an architecture-neutral object file format, which makes the compiled code to be executable on many processors, with the presence of Java runtime system. „h Portable: Being architectural-neutral and having no implementation dependent aspects of the specification makes Java portable. Compiler inJava is written in ANSI C with a clean portability boundary which is a POSIX subset. „h Robust:Java makes an effort to eliminate error prone situations by emphasizing mainly on compile time error checking and runtime checking. „h Multithreaded : With Java's multithreaded feature, it is possible to write programs that can do many tasks simultaneously. This design feature allows developers to construct smoothly running interactive applications. „h Interpreted :Java byte code is translated on the fly to native machine instructions and is not stored anywhere. The development process is more rapid and analytical since the linking is an incremental and lightweight process. „h High Performance : With the use of Just-In-Time compilers, Java enables high performance. „h Distributed :Java is designed for the distributed environment of the internet. „h Dynamic: Java is considered to be more dynamic than C or C++ since it is designed to adapt to an evolving environment. Java programs can carry extensive amount of run-time information that can be used to verify and resolve accesses to objects on run-time. History of Java: James Gosling initiated the Java language project in June 1991 for use in one of his many set-top box projects. The language, initially called Oak after an oak tree that stood outside Gosling's office, also went by the name Green and ended up later being renamed as Java, from a list of random words. Sun released the first public implementation as Java 1.0 in 1995. It promised Write Once, Run Anywhere (WORA), providing no-cost run-times on popular platforms. On 13 November 2006, Sun released much of Java as free and open source software under the terms of the GNU General Public License (GPL). On 8 May 2007, Sun finished the process, making all of Java's core code free and open-source, aside from a small portion of code to which Sun did not hold the copyright. Tools you will need: For performing the examples discussed in this tutorial, you will need a Pentium 200-MHz computer with a minimum of 64 MB of RAM (128 MB of RAM recommended). You also will need the following softwares: 1 „h Linux 7.1 or Windows 95/98/2000/XP operating system. 2 3 „h Java JDK 5 „h Microsoft Notepad or any other text editor This tutorial will provide the necessary skills to create GUI, networking, and Web applications using Java. What is Next? Next chapter will guide you to where you can obtain Java and its documentation. Finally, it instructs you on how to install Java and prepare an environment to develop Java applications. Java Environment Setup B efore we proceed further, it is important that we set up the Java environment correctly. This section guides you on how to download and set up Java on your machine. Please follow the following steps to set up the environment. Java SE is freely available from the link Download Java. So you download a version based on your operating system. Follow the instructions to download Java and run the .exe to install Java on your machine. Once you installed Java on your machine, you would need to set environment variables to point to correct installation directories: Setting up the path for windows 2000/XP: Assuming you have installed Java in c:\Program Files\java\jdk directory: 1 „h Right-click on 'My Computer' and select 'Properties'. 2 3 „h Click on the 'Environment variables' button under the 'Advanced' tab. „h Now, alter the 'Path' variable so that it also contains the path to the Java executable. Example, if the path is currently set to 'C:\WINDOWS\SYSTEM32', then change your path to read 'C:\WINDOWS\SYSTEM32;c:\Program Files\java\jdk\bin'. Setting up the path for windows 95/98/ME: Assuming you have installed Java in c:\Program Files\java\jdk directory: 1 „h Edit the 'C:\autoexec.bat' file and add the following line at the end: 'SET PATH=%PATH %;C:\Program Files\java\jdk\bin' Setting up the path for Linux, UNIX, Solaris, FreeBSD: Environment variable PATH should be set to point to where the Java binaries have been installed. Refer to your shell documentation if you have trouble doing this. Example, if you use bash as your shell, then you would add the following line to the end of your '.bashrc: export PATH=/path/to/java:$PATH' CHAPTER 2 Popular Java Editors: To write your Java programs, you will need a text editor. There are even more sophisticated IDEs available in the market. But for now, you can consider one of the following: 1 „h Notepad:On Windows machine, you can use any simple text editor like Notepad 2 3 (Recommended for this tutorial), TextPad. „h Netbeans:Is a Java IDE that is open-source and free which can be downloaded fromhttp://www.netbeans.org/index.html. „h Eclipse:Is also a Java IDE developed by the eclipse open-source community and can be downloaded from http://www.eclipse.org/. What is Next? Next chapter will teach you how to write and run your first Java program and some of the important basic syntaxes in Java needed for developing applications. CHAPTER 3 Java Basic Syntax W hen we consider a Java program, it can be defined as a collection of objects that communicate via invoking each other's methods. Let us now briefly look into what do class, object, methods and instance variables mean. 1 „h Object -Objects have states and behaviors. Example: A dog has states-color, name, breed as well as behaviors -wagging, barking, eating. An object is an instance of a class. 2 „h Class -A class can be defined as a template/blue print that describes the behaviors/states that object of its type support. 3 4 „h Methods -A method is basically a behavior. A class can contain many methods. It is in methods where the logics are written, data is manipulated and all the actions are executed. „h Instance Variables Each object has its unique set of instance variables. An object's state is created by the values assigned to these instance variables. First Java Program: Let us look at a simple code that would print the words Hello World. publicclassMyFirstJavaProgram{ /* This is my first java program. * This will print 'Hello World' as the output */ publicstaticvoid main(String[]args){ System.out.println("Hello World");// prints Hello World } } Let's look at how to save the file, compile and run the program. Please follow the steps given below: 1 „h Open notepad and add the code as above. 2 3 4 „h Save the file as: MyFirstJavaProgram.java. „h Open a command prompt window and go o the directory where you saved the class. Assume it's C:\. „h Type ' javac MyFirstJavaProgram.java ' and press enter to compile your code. If there are no errors in your code, the command prompt will take you to the next line(Assumption : The path variable is set). 1 2 „h Now, type ' java MyFirstJavaProgram ' to run your program. „h You will be able to see ' Hello World ' printed on the window. C :> javac MyFirstJavaProgram.java C :> java MyFirstJavaProgram HelloWorld Basic Syntax: About Java programs, it is very important to keep in mind the following points. is case sensitive, which means identifier Hello and hello would have 1 „h Case Sensitivity Java different meaning in Java. 2 „h Class Names -For all class names, the first letter should be in Upper Case. If several words are used to form a name of the class, each inner word's first letter should be in Upper Case. 3 4 5 Example class MyFirstJavaClass „h Method Names -All method names should start with a Lower Case letter. If several words are used to form the name of the method, then each inner word's first letter should be in Upper Case. Example public void myMethodName() „h Program File Name Name of the program file should exactly match the class name. When saving the file, you should save it using the class name (Remember Java is case sensitive) and append '.java' to the end of the name (if the file name and the class name do not match your program will not compile). Example : Assume 'MyFirstJavaProgram' is the class name, then the file should be saved as'MyFirstJavaProgram.java' „h public static void main(String args[]) Java - program processing starts from the main() method, which is a mandatory part of every Java program. Java Identifiers: All Java components require names. Names used for classes, variables and methods are called identifiers. In Java, there are several points to remember about identifiers. They are as follows: 1 2 3 4 5 6 „h All identifiers should begin with a letter (A to Z or a to z), currency character ($) or an underscore (_). „h After the first character, identifiers can have any combination of characters. „h A keyword cannot be used as an identifier. „h Most importantly identifiers are case sensitive. „h Examples of legal identifiers:age, $salary, _value, __1_value „h Examples of illegal identifiers: 123abc, -salary Java Modifiers: Like other languages, it is possible to modify classes, methods, etc., by using modifiers. There are two categories of modifiers: 1 „h Access Modifiers:default, public, protected, private 2 „h Non-access Modifiers: final, abstract, strictfp We will be looking into more details about modifiers in the next section. Java Variables: We would see following type of variables in Java: 1 „h Local Variables 2 3 „h Class Variables (Static Variables) „h Instance Variables (Non-static variables) Java Arrays: Arrays are objects that store multiple variables of the same type. However, an array itself is an object on the heap. We will look into how to declare, construct and initialize in the upcoming chapters. Java Enums: Enums were introduced in java 5.0. Enums restrict a variable to have one of only a few predefined values. The values in this enumerated list are called enums. With the use of enums, it is possible to reduce the number of bugs in your code. For example, if we consider an application for a fresh juice shop, it would be possible to restrict the glass size to small, medium and large. This would make sure that it would not allow anyone to order any size other than the small, medium or large. Example: classFreshJuice{ enumFreshJuiceSize{ SMALL, MEDUIM, LARGE } FreshJuiceSize size; } publicclassFreshJuiceTest{ publicstaticvoid main(String args[]){ FreshJuice juice =newFreshJuice(); juice.size =FreshJuice.FreshJuiceSize.MEDUIM ; } } Note: enums can be declared as their own or inside a class. Methods, variables, constructors can be defined inside enums as well. Java Keywords: The following list shows the reserved words in Java. These reserved words may not be used as constant or variable or any other identifier names. abstract assert boolean break byte case catch char class const continue default do double else enum extends final finally float for goto if implements import instanceof int interface long native new package private protected public return short static strictfp super switch synchronized this throw throws transient try void volatile while Comments in Java Java supports single-line and multi-line comments very similar to c and c++. All characters available inside any comment are ignored by Java compiler. publicclassMyFirstJavaProgram{ /* This is my first java program. * This will print 'Hello World' as the output * This is an example of multi-line comments. */ publicstaticvoid main(String[]args){ // This is an example of single line comment /* This is also an example of single line comment. */ System.out.println("Hello World"); } } Using Blank Lines: A line containing only whitespace, possibly with a comment, is known as a blank line, and Java totally ignores it. Inheritance: Java classes can be derived from classes. Basically, if you need to create a new class and here is already a class that has some of the code you require, then it is possible to derive your new class from the already existing code. This concept allows you to reuse the fields and methods of the existing class without having to rewrite the code in a new class. In this scenario, the existing class is called the superclass and the derived class is called the subclass. Interfaces: In Java language, an interface can be defined as a contract between objects on how to communicate with each other. Interfaces play a vital role when it comes to the concept of inheritance. An interface defines the methods, a deriving class(subclass) should use. But the implementation of the methods is totally up to the subclass. What is Next? The next section explains about Objects and classes in Java programming. At the end of the session, you will be able to get a clear picture as to what are objects and what are classes in Java. Java Object & Classes J ava is an Object-Oriented Language. As a language that has the Object Oriented feature, Java supports the following fundamental concepts: 1 „h Polymorphism 2 3 4 5 6 7 8 9 „h Inheritance „h Encapsulation „h Abstraction „h Classes „h Objects „h Instance „h Method „h Message Parsing In this chapter, we will look into the concepts Classes and Objects. 1 „h Object -Objects have states and behaviors. Example: A dog has states-color, name, breed as well as behaviors -wagging, barking, eating. An object is an instance of a class. 2 „h Class -A class can be defined as a template/blue print that describes the behaviors/states that object of its type support. Objects in Java: Let us now look deep into what are objects. If we consider the real-world we can find many objects around us, Cars, Dogs, Humans, etc. All these objects have a state and behavior. If we consider a dog, then its state is - name, breed, color, and the behavior is - barking, wagging, running If you compare the software object with a real world object, they have very similar characteristics. Software objects also have a state and behavior. A software object's state is stored in fields and behavior is shown via methods. So in software development, methods operate on the internal state of an object and the object-to-object communication is done via methods. CHAPTER 4 Classes in Java: A class is a blue print from which individual objects are created. A sample of a class is given below: publicclassDog{ String breed; int age; String color; void barking(){ } void hungry(){ } void sleeping(){ } } A class can contain any of the following variable types. 1 „h Local variables:Variables defined inside methods, constructors or blocks are called local variables. The variable will be declared and initialized within the method and the variable will be destroyed when the method has completed. 2 „h Instance variables:Instance variables are variables within a class but outside any method. These variables are instantiated when the class is loaded. Instance variables can be accessed from inside any method, constructor or blocks of that particular class. 3 „h Class variables:Class variables are variables declared within a class, outside any method, with the static keyword. A class can have any number of methods to access the value of various kinds of methods. In the above example, barking(), hungry() and sleeping() are methods. Below mentioned are some of the important topics that need to be discussed when looking into classes of the Java Language. Constructors: When discussing about classes, one of the most important subtopic would be constructors. Every class has a constructor. If we do not explicitly write a constructor for a class the Java compiler builds a default constructor for that class. Each time a new object is created, at least one constructor will be invoked. The main rule of constructors is that they should have the same name as the class. A class can have more than one constructor. Example of a constructor is given below: publicclassPuppy{ public puppy(){ } public puppy(String name){ // This constructor has one parameter, name. } } Java also supports Singleton Classes where you would be able to create only one instance of a class. Creating an Object: As mentioned previously, a class provides the blueprints for objects. So basically an object is created from a class. In Java the new keyword is used to create new objects. There are three steps when creating an object from a class: 1 „h Declaration:A variable declaration with a variable name with an object type. 2 3 „h Instantiation:The 'new' keyword is used to create the object. „h Initialization:The 'new' keyword is followed by a call to a constructor. This call initializes the new object. Example of creating an object is given below: publicclassPuppy{ publicPuppy(String name){ // This constructor has one parameter, name. System.out.println("Passed Name is :"+ name ); } publicstaticvoid main(String[]args){ // Following statement would create an object myPuppy Puppy myPuppy =newPuppy("tommy"); } } If we compile and run the above program, then it would produce the following result: PassedNameis:tommy Accessing Instance Variables and Methods: Instance variables and methods are accessed via created objects. To access an instance variable the fully qualified path should be as follows: /* First create an object */ ObjectReference=newConstructor(); /* Now call a variable as follows */ ObjectReference.variableName; /* Now you can call a class method as follows */ ObjectReference.MethodName(); Example: This example explains how to access instance variables and methods of a class: publicclassPuppy{ int puppyAge; publicPuppy(String name){ // This constructor has one parameter, name. System.out.println("Passed Name is :"+ name ); } publicvoid setAge(int age ){ puppyAge = age; } publicint getAge(){ System.out.println("Puppy's age is :"+ puppyAge ); return puppyAge; } publicstaticvoid main(String[]args){ /* Object creation */ Puppy myPuppy =newPuppy("tommy"); /* Call class method to set puppy's age */ myPuppy.setAge(2); /* Call another class method to get puppy's age */ myPuppy.getAge(); /* You can access instance variable as follows as well */ System.out.println("Variable Value :"+ myPuppy.puppyAge ); } } If we compile and run the above program, then it would produce the following result: PassedNameis:tommy Puppy's age is :2 Variable Value :2 Source file declaration rules: As the last part of this section, let’s now look into the source file declaration rules. These rules are essential when declaring classes, import statements and package statements in a source file. 1 „h There can be only one public class per source file. 2 3 „h A source file can have multiple non public classes. „h The public class name should be the name of the source file as well which should be appended by .java at the end. For example : The class name is . public class Employee{} Then the source file 4 5 6 should be as Employee.java. „h If the class is defined inside a package, then the package statement should be the first statement in the source file. „h If import statements are present then they must be written between the package statement and the class declaration. If there are no package statements then the import statement should be the first line in the source file. „h Import and package statements will imply to all the classes present in the source file. It is not possible to declare different import and/or package statements to different classes in the source file. Classes have several access levels and there are different types of classes; abstract classes, final classes, etc. I will be explaining about all these in the access modifiers chapter. Apart from the above mentioned types of classes, Java also has some special classes called Inner classes and Anonymous classes. Java Package: In simple, it is a way of categorizing the classes and interfaces. When developing applications in Java, hundreds of classes and interfaces will be written, therefore categorizing these classes is a must as well as makes life much easier. Import statements: In Java if a fully qualified name, which includes the package and the class name, is given, then the compiler can easily locate the source code or classes. Import statement is a way of giving the proper location for the compiler to find that particular class. For example,the following line would ask compiler to load all the classes available in directory java_installation/java/io import java.io.*; A Simple Case Study: For our case study, we will be creating two classes. They are Employee and EmployeeTest. First open notepad and add the following code. Remember this is the Employee class and the class is a public class. Now, save this source file with the name Employee.java. The Employee class has four instance variables name, age, designation and salary. The class has one explicitly defined constructor, which takes a parameter. import java.io.*; publicclassEmployee{ String name; int age; String designation; double salary; // This is the constructor of the class Employee publicEmployee(String name){ this.name = name; } // Assign the age of the Employee to the variable age. publicvoid empAge(int empAge){ age = empAge; } /* Assign the designation to the variable designation.*/ publicvoid empDesignation(String empDesig){ designation = empDesig; } /* Assign the salary to the variable salary.*/ publicvoid empSalary(double empSalary){ salary = empSalary; } /* Print the Employee details */ publicvoid printEmployee(){ System.out.println("Name:"+ name ); System.out.println("Age:"+ age ); System.out.println("Designation:"+ designation ); System.out.println("Salary:"+ salary); } } As mentioned previously in this tutorial, processing starts from the main method. Therefore in-order for us to run this Employee class there should be main method and objects should be created. We will be creating a separate class for these tasks. Given below is the EmployeeTest class, which creates two instances of the class Employee and invokes the methods for each object to assign values for each variable. Save the following code in EmployeeTest.java file import java.io.*; publicclassEmployeeTest{ publicstaticvoid main(String args[]){ /* Create two objects using constructor */ Employee empOne =newEmployee("James Smith"); Employee empTwo =newEmployee("Mary Anne"); // Invoking methods for each object created empOne.empAge(26); empOne.empDesignation("Senior Software Engineer"); empOne.empSalary(1000); empOne.printEmployee(); empTwo.empAge(21); empTwo.empDesignation("Software Engineer"); empTwo.empSalary(500); empTwo.printEmployee(); } } Now, compile both the classes and then run EmployeeTest to see the result as follows: C :> javac Employee.java C :> vi EmployeeTest.java C :> javac EmployeeTest.java C :> java EmployeeTest Name:JamesSmith Age:26 Designation:SeniorSoftwareEngineer Salary:1000.0 Name:MaryAnne Age:21 Designation:SoftwareEngineer Salary:500.0 What is Next? Next session will discuss basic data types in Java and how they can be used when developing Java applications. CHAPTER 5 V Java Basic Data Types ariables are nothing but reserved memory locations to store values. This means that when you create a variable you reserve some space in memory. Based on the data type of a variable, the operating system allocates memory and decides what can be stored in the reserved memory. Therefore, by assigning different data types to variables, you can store integers, decimals, or characters in these variables. There are two data types available in Java: 1 „h Primitive Data Types 2 „h Reference/Object Data Types Primitive Data Types: There are eight primitive data types supported by Java. Primitive data types are predefined by the language and named by a keyword. Let us now look into detail about the eight primitive data types. byte: 1 2 3 4 5 „h Byte data type is an 8-bit signed two's complement integer. 6 „h Example: byte a = 100, byte b = -50 „h Minimum value is -128 (-2^7) „h Maximum value is 127 (inclusive)(2^7 -1) „h Default value is 0 „h Byte data type is used to save space in large arrays, mainly in place of integers, since a byte is four times smaller than an int. short: 1 „h Short data type is a 16-bit signed two's complement integer. 1 2 3 „h Minimum value is -32,768 (-2^15) 4 5 „h Maximum value is 32,767(inclusive) (2^15 -1) „h Short data type can also be used to save memory as byte data type. A short is 2 times smaller than an int „h Default value is 0. „h Example: short s= 10000, short r = -20000 int: 1 2 3 4 5 6 „h int data type is a 32-bit signed two's complement integer. „h Minimum value is - 2,147,483,648.(-2^31) „h Maximum value is 2,147,483,647(inclusive).(2^31 -1) „h Int is generally used as the default data type for integral values unless there is a concern about memory. „h The default value is 0. „h Example: int a = 100000, int b = -200000 long: 1 2 3 4 5 6 „h Long data type is a 64-bit signed two's complement integer. „h Minimum value is -9,223,372,036,854,775,808.(-2^63) „h Maximum value is 9,223,372,036,854,775,807 (inclusive). (2^63 -1) „h This type is used when a wider range than int is needed. „h Default value is 0L. „h Example: int a = 100000L, int b = -200000L float: 1 2 3 4 5 „h Float data type is a single-precision 32-bit IEEE 754 floating point. „h Float is mainly used to save memory in large arrays of floating point numbers. „h Default value is 0.0f. „h Float data type is never used for precise values such as currency. „h Example: float f1 = 234.5f double: 1 2 3 4 5 „h double data type is a double-precision 64-bit IEEE 754 floating point. „h This data type is generally used as the default data type for decimal values, generally the default choice. „h Double data type should never be used for precise values such as currency. „h Default value is 0.0d. „h Example: double d1 = 123.4 boolean: 1 2 3 4 5 „h boolean data type represents one bit of information. „h There are only two possible values: true and false. „h This data type is used for simple flags that track true/false conditions. „h Default value is false. „h Example: boolean one = true char: 1 2 „h char data type is a single 16-bit Unicode character. „h Minimum value is '\u0000' (or 0). 3 4 5 „h Maximum value is '\uffff' (or 65,535 inclusive). „h Char data type is used to store any character. „h Example: char letterA ='A' Reference Data Types: 1 2 3 4 5 „h Reference variables are created using defined constructors of the classes. They are used to access objects. These variables are declared to be of a specific type that cannot be changed. For example, Employee, Puppy, etc. „h Class objects and various types of array variables come under reference data type. „h Default value of any reference variable is null. „h A reference variable can be used to refer to any object of the declared type or any compatible type. „h Example: Animal animal = new Animal("giraffe"); Java Literals: A literal is a source code representation of a fixed value. They are represented directly in the code without any computation. Literals can be assigned to any primitive type variable. For example: byte a =68; char a ='A' byte, int, long, and short can be expressed in decimal(base 10),hexadecimal(base 16) or octal(base 8) number systems as well. Prefix 0 is used to indicate octal and prefix 0x indicates hexadecimal when using these number systems for literals. For example: intdecimal=100; int octal =0144; int hexa =0x64; String literals in Java are specified like they are in most other languages by enclosing a sequence of characters between a pair of double quotes. Examples of string literals are: "Hello World" "two\nlines" "\"This is in quotes\"" String and char types of literals can contain any Unicode characters. For example: char a ='\u0001'; String a ="\u0001"; Java language supports few special escape sequences for String and char literals as well. They are: Notation Character represented \n Newline (0x0a) \r Carriage return (0x0d) \f Formfeed (0x0c) \b Backspace (0x08) \s Space (0x20) \t Tab \" Double quote \' Single quote \\ Backslash \ddd Octal character (ddd) \uxxxx Hexadecimal UNICODE character (xxxx) What is Next? This chapter explained you various data types, next topic explains different variable types and their usage. This will give you a good understanding about how they can be used in the Java classes, interfaces, etc. CHAPTER 6 Java Variable Types I n Java, all variables must be declared before they can be used. The basic form of a variable declaration is shown here: type identifier [= value][, identifier [= value]...]; The type is one of Java's datatypes. The identifier is the name of the variable. To declare more than one variable of the specified type, use a comma-separated list. Here are several examples of variable declarations of various types. Note that some include an initialization. int a, b, c;// declares three ints, a, b, and c. int d =3, e, f =5;// declares three more ints, initializing // d and f. byte z =22;// initializes z. double pi =3.14159;// declares an approximation of pi. char x ='x';// the variable x has the value 'x'. This chapter will explain various variable types available in Java Language. There are three kinds of variables in Java: 1 „h Local variables 2 3 „h Instance variables „h Class/static variables Local variables: Local variables are declared in methods, constructors, or blocks. 1 „h 2 „h Local variables are created when the method, constructor or block is entered and the variable will be destroyed once it exits the method, constructor or block.. 1 „h Access modifiers cannot be used for local variables. 2 „h Local variables are visible only within the declared method, constructor or block. 1 „h Local variables are implemented at stack level internally. 2 „h There is no default value for local variables so local variables should be declared and an initial value should be assigned before the first use. Example: Here, age is a local variable. This is defined inside pupAge() method and its scope is limited to this method only. publicclassTest{ publicvoid pupAge(){ int age =0; age = age +7; System.out.println("Puppy age is : "+ age); } publicstaticvoid main(String args[]){ Test test =newTest(); test.pupAge(); } } This would produce the following result: Puppy age is:7 Example: Following example uses age without initializing it, so it would give an error at the time of compilation. publicclassTest{ publicvoid pupAge(){ int age; age = age +7; System.out.println("Puppy age is : "+ age); } publicstaticvoid main(String args[]){ Test test =newTest(); test.pupAge(); } } This would produce the following error while compiling it: Test.java:4:variable number might not have been initialized age = age +7; ^ 1 error Instance variables: 1 „h Instance variables are declared in a class, but outside a method, constructor or any block. 2 „h When a space is allocated for an object in the heap, a slot for each instance variable value is created. 1 „h Instance variables are created when an object is created with the use of the keyword 'new' and destroyed when the object is destroyed. 2 „h Instance variables hold values that must be referenced by more than one method, constructor or block, or essential parts of an object’s state that must be present throughout the class. 3 „h Instance variables can be declared in class level before or after use. 4 „h Access modifiers can be given for instance variables. 5 „h The instance variables are visible for all methods, constructors and block in the class. Normally, 6 7 it is recommended to make these variables private (access level).However visibility for subclasses can be given for these variables with the use of access modifiers. „h Instance variables have default values. For numbers, the default value is 0; for Booleans, it is false; and for object references, it is null. Values can be assigned during the declaration or within the constructor. „h Instance variables can be accessed directly by calling the variable name inside the class. However within static methods and different class (when instance variables are given accessibility) should be called using the fully qualified name .ObjectReference.VariableName. Example: import java.io.*; publicclassEmployee{ // this instance variable is visible for any child class. publicString name; // salary variable is visible in Employee class only. privatedouble salary; // The name variable is assigned in the constructor. publicEmployee(String empName){ name = empName; } // The salary variable is assigned a value. publicvoid setSalary(double empSal){ salary = empSal; } // This method prints the employee details. publicvoid printEmp(){ System.out.println("name : "+ name ); System.out.println("salary :"+ salary); } publicstaticvoid main(String args[]){ Employee empOne =newEmployee("Ransika"); empOne.setSalary(1000); empOne.printEmp(); } } This would produce the following result: name :Ransika salary :1000.0 Class/static variables: 1 „h Class variables also known as static variables are declared with the static keyword in a class, but outside a method, constructor or a block. 2 „h There would only be one copy of each class variable per class, regardless of how many objects are created from it. 3 „h Static variables are rarely used other than being declared as constants. Constants are variables that are declared as public/private, final and static. Constant variables never change from their initial value. 4 „h Static variables are stored in static memory. It is rare to use static variables other than declared final and used as either public or private constants. 5 „h Static variables are created when the program starts and destroyed when the program stops. 6 „h Visibility is similar to instance variables. However, most static variables are declared public since they must be available for users of the class. 7 „h Default values are same as instance variables. For numbers, the default value is 0; for Booleans, it is false; and for object references, it is null. Values can be assigned during the declaration or within the constructor. Additionally values can be assigned in special static initializer 8 blocks. „h Static variables can be accessed by calling with the class name . ClassName.VariableName. 9 „h When declaring class variables as public static final, then variables names (constants) are all in upper case. If the static variables are not public and final the naming syntax is the same as instance and local variables. Example: import java.io.*; publicclassEmployee{ // salary variable is a private static variable privatestaticdouble salary; // DEPARTMENT is a constant publicstaticfinalString DEPARTMENT ="Development "; publicstaticvoid main(String args[]){ salary =1000; System.out.println(DEPARTMENT+"average salary:"+salary); } } This would produce the following result: Development average salary:1000 Note: If the variables are access from an outside class the constant should be accessed as Employee.DEPARTMENT What is Next? You already have used access modifiers (public & private) in this chapter. The next chapter will explain you Access Modifiers and NonAccess Modifiers in detail. Java Modifier Types M odifiers arekeywords that you add to those definitions to change their meanings. The Java language has a wide variety of modifiers, including the following: 1. Java Access Modifiers Java provides a number of access modifiers to set access levels for classes, variables, methods and constructors. The four access levels are: 1 „h Visible to the package, the default. No modifiers are needed. 2 3 „h Visible to the class only (private). „h Visible to the world (public). 4 „h Visible to the package and all subclasses (protected). Default Access Modifier - No keyword: Default access modifier means we do not explicitly declare an access modifier for a class, field, method, etc. A variable or method declared without any access control modifier is available to any other class in the same package. The fields in an interface are implicitly public static final and the methods in an interface are by default public Example: Variables and methods can be declared without any modifiers, as in the following examples: String version ="1.5.1"; boolean processOrder(){ returntrue; } CHAPTER 7 Private Access Modifier - private: Methods, Variables and Constructors that are declared private can only be accessed within the declared class itself. Private access modifier is the most restrictive access level. Class and interfaces cannot be private. Variables that are declared private can be accessed outside the class if public getter methods are present in the class. Using the private modifier is the main way that an object encapsulates itself and hide data from the outside world. Example: The following class uses private access control: publicclassLogger{ privateString format; publicString getFormat(){ returnthis.format; } publicvoid setFormat(String format){ this.format = format; } } Here, the format variable of the Logger class is private, so there's no way for other classes to retrieve or set its value directly. So to make this variable available to the outside world, we defined two public methods: getFormat(), which returns the value of format, and setFormat(String), which sets its value. Public Access Modifier - public: A class, method, constructor, interface etc declared public can be accessed from any other class. Therefore fields, methods, blocks declared inside a public class can be accessed from any class belonging to the Java Universe. However if the public class we are trying to access is in a different package, then the public class still need to be imported. Because of class inheritance, all public methods and variables of a class are inherited by its subclasses. Example: The following function uses public access control: publicstaticvoid main(String[] arguments){ // ... } The main() method of an application has to be public. Otherwise, it could not be called by a Java interpreter (such as java) to run the class. Protected Access Modifier - protected: Variables, methods and constructors which are declared protected in a superclass can be accessed only by the subclasses in other package or any class within the package of the protected members' class. The protected access modifier cannot be applied to class and interfaces. Methods, fields can be declared protected, however methods and fields in a interface cannot be declared protected. Protected access gives the subclass a chance to use the helper method or variable, while preventing a nonrelated class from trying to use it. Example: The following parent class uses protected access control, to allow its child class override openSpeaker() method: classAudioPlayer{ protectedboolean openSpeaker(Speaker sp){ // implementation details } } classStreamingAudioPlayer{ boolean openSpeaker(Speaker sp){ // implementation details } } Here, if we define openSpeaker() method as private, then it would not be accessible from any other class other than AudioPlayer. If we define it as public, then it would become accessible to all the outside world. But our intension is to expose this method to its subclass only, thats why we used protected modifier. Access Control and Inheritance: The following rules for inherited methods are enforced: 1 „h Methods declared public in a superclass also must be public in all subclasses. 2 „h Methods declared protected in a superclass must either be protected or public in subclasses; they cannot be private. 3 „h Methods declared without access control (no modifier was used) can be declared more private in subclasses. „h Methods declared private are not inherited at all, so there is no rule for them. 4 2. Non Access Modifiers To use a modifier, you include its keyword in the definition of a class, method, or variable. The modifier precedes the rest of the statement, as in the following examples (Italic ones): publicclass className { // ... } privateboolean myFlag; staticfinaldouble weeks =9.5; protectedstaticfinalint BOXWIDTH =42; publicstaticvoid main(String[] arguments){ // body of method } Access Control Modifiers: Java provides a number of access modifiers to set access levels for classes, variables, methods and constructors. The four access levels are: 1 „h Visible to the package. the default. No modifiers are needed. 2 3 4 „h Visible to the class only (private). „h Visible to the world (public). „h Visible to the package and all subclasses (protected). Non Access Modifiers: Java provides a number of non-access modifiers to achieve many other functionality. 1 „h The static modifier for creating class methods and variables 2 3 4 „h The final modifier for finalizing the implementations of classes, methods, and variables. „h The abstract modifier for creating abstract classes and methods. „h The synchronized and volatile modifiers, which are used for threads. To use a modifier, you include its keyword in the definition of a class, method, or variable. The modifier precedes the rest of the statement, as in the following examples (Italic ones): publicclass className { // ... } privateboolean myFlag; staticfinaldouble weeks =9.5; protectedstaticfinalint BOXWIDTH =42; publicstaticvoid main(String[] arguments){ // body of method } Access Control Modifiers: Java provides a number of access modifiers to set access levels for classes, variables, methods and constructors. The four access levels are: 1 „h Visible to the package. the default. No modifiers are needed. 2 3 4 „h Visible to the class only (private). „h Visible to the world (public). „h Visible to the package and all subclasses (protected). Non Access Modifiers: Java provides a number of non-access modifiers to achieve many other functionality. 1 „h The static modifier for creating class methods and variables 1 2 3 „h The final modifier for finalizing the implementations of classes, methods, and variables. „h The abstract modifier for creating abstract classes and methods. „h The synchronized and volatile modifiers, which are used for threads. What is Next? In the next section, I will be discussing about Basic Operators used in the Java Language. The chapter will give you an overview of how these operators can be used during application development. Java Basic Operators J ava provides a rich set of operators to manipulate variables. We can divide all the Java operators into the following groups: 1 „h Arithmetic Operators 2 3 4 5 6 „h Relational Operators „h Bitwise Operators „h Logical Operators „h Assignment Operators „h Misc Operators The Arithmetic Operators: Arithmetic operators are used in mathematical expressions in the same way that they are used in algebra. The following table lists the arithmetic operators: Assume integer variable A holds 10 and variable B holds 20, then: Operator Description Example + Addition - Adds values on either side of the operator A + B will give 30 - Subtraction - Subtracts right hand operand from left hand operand A - B will give -10 * Multiplication - Multiplies values on either side of the operator A * B will give 200 / Division - Divides left hand operand by right hand operand B / A will give 2 % Modulus - Divides left hand B % A will give 0 operand by right hand operand and returns remainder ++ Increment - Increases the value of operand by 1 B++ gives 21 -- Decrement - Decreases the value of operand by 1 B-- gives 19 CHAPTER 8 Example The following simple example program demonstrates the arithmetic operators. Copy and paste the following Java program in Test.java file and compile and run this program: publicclassTest{ publicstaticvoid main(String args[]){ int a =10; int b =20; int c =25; int d =25; System.out.println("a + b = "+(a + b)); System.out.println("a - b = "+(a - b)); System.out.println("a * b = "+(a * b)); System.out.println("b / a = "+(b / a)); System.out.println("b % a = "+(b % a)); System.out.println("c % a = "+(c % a)); System.out.println("a++ = "+(a++)); System.out.println("b-= "+(a--)); // Check the difference in d++ and ++d System.out.println("d++ = "+(d++)); System.out.println("++d = "+(++d)); } } This would produce the following result: a + b =30 a - b =-10 a * b =200 b / a =2 b % a =0 c % a =5 a++=10 b--=11 d++=25 ++d =27 The Relational Operators: There are following relational operators supported by Java language: Assume variable A holds 10 and variable B holds 20, then: Operator Description Example == Checks if the values of two operands are equal or not, if yes then condition becomes true. (A == B) is not true. != Checks if the values of two operands are equal or not, if values are not equal then condition becomes true. (A != B) is true. > Checks if the value of left operand is greater than the value of right operand, if yes then condition becomes true. (A > B) is not true. < Checks if the value of left operand is less than the value of right operand, if yes then (A < B) is true. condition becomes true. >= Checks if the value of left operand is greater than or equal to the value of right operand, if yes then condition becomes true. (A >= B) is not true. <= Checks if the value of left operand is less than or equal to the value of right operand, if yes then condition becomes true. (A <= B) is true. Example The example program demonstrates relational Javafollowing program simple in Test.java file and compile and run thisthe program. : operators. Copy and paste the following publicclassTest{ publicstaticvoid main(String args[]){ int a =10; int b =20; System.out.println("a == b = "+(a == b)); System.out.println("a != b = "+(a != b)); System.out.println("a > b = "+(a > b)); System.out.println("a < b = "+(a < b)); System.out.println("b >= a = "+(b >= a)); System.out.println("b <= a = "+(b <= a)); } } This would produce the following result: a == b =false a != b =true a > b =false a < b =true b >= a =true b <= a =false The Bitwise Operators: Java defines several bitwise operators, which can be applied to the integer types, long, int, short, char, and byte. Bitwise operator works on bits and performsbit-by-bit operation. Assume if a = 60; and b = 13; now in binary format they will be as follows: a = 0011 1100 b = 0000 1101 ----------------a&b = 0000 1100 a|b = 0011 1101 a^b = 0011 0001 ~a = 1100 0011 The following table lists the bitwise operators: Assume integer variable A holds 60 and variable B holds 13, then: Operator Description Example & Binary AND Operator copies a bit to the result if it exists in both operands. (A & B) will give 12 which is 0000 1100 | Binary OR Operator copies a bit if it exists in either operand. (A | B) will give 61 which is 0011 1101 ^ Binary XOR Operator copies the bit if it is set in one operand but not both. (A ^ B) will give 49 which is 0011 0001 ~ Binary Ones Complement Operator is unary and has the effect of 'flipping' bits. (~A ) will give -60 which is 1100 0011 << Binary Left Shift Operator. The left operands value is moved left by the number of bits specified by the right operand. A << 2 will give 240 which is 1111 0000 >> Binary Right Shift Operator. The left operands value is moved right by the number of bits specified by the right operand. A >> 2 will give 15 which is 1111 >>> Shift right zero fill operator. The left operands value is moved right by the number of bits specified by the right operand and shifted values are filled up with zeros. A >>>2 will give 15 which is 0000 1111 Example The following simple example program demonstrates the bitwise operators. Copy and paste the following Java program in Test.java file and compile and run this program: publicclassTest{ publicstaticvoid main(String args[]){ int a =60; /* 60 = 0011 1100 */ int b =13; /* 13 = 0000 1101 */ int c =0; c = a & b;/* 12 = 0000 1100 */ System.out.println("a & b = "+ c ); c = a | b;/* 61 = 0011 1101 */ System.out.println("a | b = "+ c ); c = a ^ b;/* 49 = 0011 0001 */ System.out.println("a ^ b = "+ c ); c =~a;/*-61 = 1100 0011 */ System.out.println("~a = "+ c ); c = a <<2;/* 240 = 1111 0000 */ System.out.println("a << 2 = "+ c ); c = a >>2;/* 215 = 1111 */ System.out.println("a >> 2 = "+ c ); c = a >>>2;/* 215 = 0000 1111 */ System.out.println("a >>> 2 = "+ c ); } } This would produce the following result: a & b =12 a | b =61 a ^ b =49 ~a =-61 a <<2=240 a >>15 a >>>15 The Logical Operators: The following table lists the logical operators: Assume Boolean variables A holds true and variable B holds false, then: Operator && Description Called Logical AND operator. If Example (A && B) is false. both the the condition operands becomes are non-zero, then true. || Called Logical OR Operator. If any of the two operands are non-zero, then the condition becomes true. (A || B) is true. ! Called Logical NOT Operator. Use to reverses the logical state of its operand. If a condition is true then Logical NOT operator will make false. !(A && B) is true. Example The following simple example program demonstrates the logical operators. Copy and paste the following Java program in Test.java file and compile and run this program: publicclassTest{ publicstaticvoid main(String args[]){ boolean a =true; boolean b =false; System.out.println("a && b = "+(a&&b)); System.out.println("a || b = "+(a||b)); System.out.println("!(a && b) = "+!(a && b)); } } This would produce the following result: a && b =false a || b =true !(a && b)=true The Assignment Operators: There are following assignment operators supported by Java language: Operator Description Example = Simple assignment operator, Assigns values from right side operands to left side operand C = A + B will assign value of A + B into C += Add AND assignment operator, It adds right operand to the left operand and assign the result to left operand C += A is equivalent to C = C + A -= Subtract AND assignment operator, It subtracts right operand from the left operand and assign the result to left operand C -= A is equivalent to C = C - A *= Multiply AND assignment operator, It multiplies right operand with the left operand and assign the result to left operand C *= A is equivalent to C = C * A /= Divide AND assignment operator, It divides left operand with the right operand and assign the result to left operand C /= A is equivalent to C = C / A %= Modulus AND assignment operator, It takes modulus using two operands and assign the result to left operand C %= A is equivalent to C = C % A <<= Left shift AND assignment operator C <<= 2 is same as C = C << 2 >>= Right shift AND assignment operator C >>= 2 is same as C = C >> 2 &= Bitwise AND assignment operator C &= 2 is same as C = C & 2 ^= bitwise exclusive OR and assignment operator C ^= 2 is same as C = C ^ 2 |= bitwise inclusive OR and assignment operator C |= 2 is same as C = C | 2 Example: The following simple example program demonstrates the assignment operators. Copy and paste the following Java program in Test.java file and compile and run this program: publicclassTest{ publicstaticvoid main(String args[]){ int a =10; int b =20; int c =0; c = a + b; System.out.println("c = a + b = "+ c ); c += a ; System.out.println("c += a = "+ c ); c -= a ; System.out.println("c -= a = "+ c ); c *= a ; System.out.println("c *= a = "+ c ); a =10; c =15; c /= a ; System.out.println("c /= a = "+ c ); a =10; c =15; c %= a ; System.out.println("c %= a = "+ c ); c <<=2; System.out.println("c <<= 2 = "+ c ); c >>=2; System.out.println("c >>= 2 = "+ c ); c >>=2; System.out.println("c >>= a = "+ c ); c &= a ; System.out.println("c &= 2 c ^= a ; System.out.println("c ^= a = "+ c ); = "+ c ); c |= a ; System.out.println("c |= a = "+ c ); } } This would produce the following result: c = a + b =30 c += a =40 c -= a =30 c *= a =300 c /= a =1 c %= a =5 c <<=2=20 c >>=2=5 c >>=2=1 c &= a =0 c ^= a =10 c |= a =10 Misc Operators There are few other operators supported by Java Language. Conditional Operator (?:): Conditional operator is also known as the ternary operator. This operator consists of three operands and is used to evaluate Boolean expressions. The goal of the operator is to decide which value should be assigned to the variable. The operator is written as: variable x =(expression)? value iftrue: value iffalse Following is the example: publicclassTest{ publicstaticvoid main(String args[]){ int a , b; a =10; b =(a ==1)?20:30; System.out.println("Value of b is : "+ b ); b =(a ==10)?20:30; System.out.println("Value of b is : "+ b ); } } This would produce the following result: Value of b is:30 Value of b is:20 instanceOf Operator: This operator is used only for object reference variables. The operator checks whether the object is of a particular type(class type or interface type). instanceOf operator is wriiten as: (Object reference variable ) instanceOf (class/interface type) If the object referred by the variable on the left side of the operator passes the IS-A check for the class/interface type on the right side, then the result will be true. Following is the example: String name =='James'; boolean result = name instanceOf String; // This will return true since name is type of String This operator will still return true if the object being compared is the assignment compatible with the type on the right. Following is one more example: classVehicle{} publicclassCarextendsVehicle{ publicstaticvoid main(String args[]){ Vehicle a =newCar(); boolean result = a instanceofCar; System.out.println( result); } } This would produce the following result: true Precedence of Java Operators: Operator precedence determines the grouping of terms in an expression. This affects how an expression is evaluated. Certain operators have higher precedence than others; for example, the multiplication operator has higher precedence than the addition operator: For example, x = 7 + 3 * 2; here, x is assigned 13, not 20 because operator * has higher precedence than +, so it first gets multiplied with 3*2 and then adds into 7. Here, operators with the highest precedence appear at the top of the table, those with the lowest appear at the bottom. Within an expression, higher precedence operators will be evaluated first. Category Postfix Operator () [] . (dot operator) Associativity Left to right Unary ++ - - ! ~ Right to left Multiplicative */% Left to right Additive +- Left to right Shift >>>>><< Left to right Relational >>= <<= Left to right Equality == != Left to right Bitwise AND & Left to right Bitwise XOR ^ Left to right Bitwise OR | Left to right Logical AND && Left to right Logical OR || Left to right Conditional ?: Right to left Assignment = += -= *= /= %= >>= <<= &= ^= |= Right to left Comma , Left to right What is Next? Next chapter would explain about loop control in Java programming. The chapter will describe various types of loops and how these loops can be used in Java program development and for what purposes they are being used. JavaLoop Control T here may be a situation when we need to execute a block of code several number of times and is often referred to as a loop. Java has very flexible three looping mechanisms. You can use one of the following three loops: 1 „h while Loop 2 3 „h do...while Loop „h for Loop As of Java 5, the enhanced for loop was introduced. This is mainly used for Arrays. The while Loop: A while loop is a control structure that allows you to repeat a task a certain number of times. Syntax: The syntax of a while loop is: while(Boolean_expression) { //Statements } When executing, if the boolean_expression result is true, then the actions inside the loop will be executed. This will continue as long as the expression result is true. Here, key point of the while loop is that the loop might not ever run. When the expression is tested and the result is false, the loop body will be skipped and the first statement after the while loop will be executed. Example: publicclassTest{ publicstaticvoid main(String args[]){ int x =10; while( x <20){ System.out.print("value of x : "+ x ); CHAPTER 9 x++; System.out.print("\n"); } } } This would produce the following result: value of x :10 value of x :11 value value value value value value value value of of of of of of of of x x x x x x x x :12 :13 :14 :15 :16 :17 :18 :19 The do...while Loop: A do...while loop is similar to a while loop, except that a do...while loop is guaranteed to execute at least one time. Syntax: The syntax of a do...while loop is: do { //Statements }while(Boolean_expression); Notice that the Boolean expression appears at the end of the loop, so the statements in the loop execute once before the Boolean is tested. If the Boolean expression is true, the flow of control jumps back up to do, and the statements in the loop execute again. This process repeats until the Boolean expression is false. Example: publicclassTest{ publicstaticvoid main(String args[]){ int x =10; do{ System.out.print("value of x : "+ x ); x++; System.out.print("\n"); }while( x <20); } } This would produce the following result: value of x :10 value of x :11 value of x :12 value of x :13 value of x :14 value of x :15 value of x :16 value of x :17 value of x :18 value of x :19 The for Loop: A for loop is a repetition control structure that allows you to efficiently write a loop that needs to execute a specific number of times. A for loop is useful when you know how many times a task is to be repeated. Syntax: The syntax of a for loop is: for(initialization;Boolean_expression; update) { //Statements } Here is the flow of control in a for loop: 1 „h The initialization step is executed first, and only once. This step allows you to declare and initialize any loop control variables. You are not required to put a statement here, as long as a semicolon appears. 2 „h Next, the Boolean expression is evaluated. If it is true, the body of the loop is executed. If it is false, the body of the loop does not execute and flow of control jumps to the next statement past the for loop. 3 „h After the body of the for loop executes, the flow of control jumps back up to the update statement. This statement allows you to update any loop control variables. This statement can be left blank, as long as a semicolon appears after the Boolean expression. 4 „h The Boolean expression is now evaluated again. If it is true, the loop executes and the process repeats itself (body of loop, then update step,then Boolean expression). After the Boolean expression is false, the for loop terminates. Example: publicclassTest{ publicstaticvoid main(String args[]){ for(int x =10; x <20; x = x+1){ System.out.print("value of x : "+ x ); System.out.print("\n"); } } } This would produce the following result: value of x :10 value of x :11 value value value value value value value value of of of of of of of of x x x x x x x x :12 :13 :14 :15 :16 :17 :18 :19 Enhanced for loop in Java: As of Java 5, the enhanced for loop was introduced. This is mainly used for Arrays. Syntax: The syntax of enhanced for loop is: for(declaration : expression) { //Statements } 1 2 „h Declaration: The newly declared block variable, which is of a type compatible with the elements of the array you are accessing. The variable will be available within the for block and its value would be the same as the current array element. „h Expression: This evaluates to the array you need to loop through. The expression can be an array variable or method call that returns an array. Example: publicclassTest{ publicstaticvoid main(String args[]){ int[] numbers ={10,20,30,40,50}; for(int x : numbers ){ System.out.print( x ); System.out.print(","); } System.out.print("\n"); String[] names ={"James","Larry","Tom","Lacy"}; for(String name : names ){ System.out.print( name ); System.out.print(","); } } } This would produce the following result: 10,20,30,40,50, James,Larry,Tom,Lacy, The break Keyword: The break keyword is used to stop the entire loop. The break keyword must be used inside any loop or a switch statement. The break keyword will stop the execution of the innermost loop and start executing the next line of code after the block. Syntax: The syntax of a break is a single statement inside any loop: break; Example: publicclassTest{ publicstaticvoid main(String args[]){ int[] numbers ={10,20,30,40,50}; for(int x : numbers ){ if( x ==30){ break; } System.out.print( x ); System.out.print("\n"); } } } This would produce the following result: 10 20 The continue Keyword: The continue keyword can be used in any of the loop control structures. It causes the loop to immediately jump to the next iteration of the loop. 1 „h In a for loop, the continue keyword causes flow of control to immediately jump to the update statement. 2 „h In a while loop or do/while loop, flow of control immediately jumps to the Boolean expression. Syntax: The syntax of a continue is a single statement inside any loop: continue; Example: publicclassTest{ publicstaticvoid main(String args[]){ int[] numbers ={10,20,30,40,50}; for(int x : numbers ){ if( x ==30){ continue; } System.out.print( x ); System.out.print("\n"); } } } This would produce the following result: 10 20 40 50 What is Next? In the following chapter, we will be learning about decision making statements in Java programming. Java Decision Making T 1 2 here are two types of decision making statements in Java. They are: „h if statements „h switch statements The if Statement: An if statement consists of a Boolean expression followed by one or more statements. Syntax: The syntax of an if statement is: if(Boolean_expression) { //Statements will execute if the Boolean expression is true } If the Boolean expression evaluates to true, then the block of code inside the if statement will be executed. If not, the first set of code after the end of the if statement(after the closing curly brace) will be executed. Example: publicclassTest{ publicstaticvoid main(String args[]){ int x =10; if( x <20){ System.out.print("This is if statement"); } } } This would produce the following result: Thisisif statement CHAPTER 10 The if...else Statement: An if statement can be followed by an optional else statement, which executes when the Boolean expression is false. Syntax: The syntax of an if...else is: if(Boolean_expression){ //Executes when the Boolean expression is true }else{ //Executes when the Boolean expression is false } Example: publicclassTest{ publicstaticvoid main(String args[]){ int x =30; if( x <20){ System.out.print("This is if statement"); }else{ System.out.print("This is else statement"); } } } This would produce the following result: Thisiselse statement The if...else if...else Statement: An if statement can be followed by an optional else if...else statement, which is very useful to test various conditions using single if...else if statement. When using if, else if , else statements there are few points to keep in mind. 1 „h An if can have zero or one else's and it must come after any else if's. 2 3 „h An if can have zero to many else if's and they must come before the else. „h Once an else if succeeds, none of the remaining else if's or else's will be tested. Syntax: The syntax of an if...else is: if(Boolean_expression1){ //Executes when the Boolean expression 1 is true }elseif(Boolean_expression2){ //Executes when the Boolean expression 2 is true }elseif(Boolean_expression3){ //Executes when the Boolean expression 3 is true }else{ //Executes when the none of the above condition is true. } Example: publicclassTest{ publicstaticvoid main(String args[]){ int x =30; if( x ==10){ System.out.print("Value of X is 10"); }elseif( x ==20){ System.out.print("Value of X is 20"); }elseif( x ==30){ System.out.print("Value of X is 30"); }else{ System.out.print("This is else statement"); } } } This would produce the following result: Value of X is30 Nested if...else Statement: It is always legal to nest if-else statements which means you can use one if or else if statement inside another if or else if statement. Syntax: The syntax for a nested if...else is as follows: if(Boolean_expression1){ //Executes when the Boolean expression 1 is true if(Boolean_expression2){ //Executes when the Boolean expression 2 is true } } You can nest else if...else in the similar way as we have nested if statement. Example: publicclassTest{ publicstaticvoid main(String args[]){ int x =30; int y =10; if( x ==30){ if( y ==10){ System.out.print("X = 30 and Y = 10"); } } } This would produce the following result: X =30and Y =10 The switch Statement: A switch statement allows a variable to be tested for equality against a list of values. Each value is called a case, and the variable being switched on is checked for each case. Syntax: The syntax of enhanced for loop is: switch(expression){ case value : //Statements break;//optional case value : //Statements break;//optional //You can have any number of case statements. default://Optional //Statements } The following rules apply to a switch statement: 1 2 3 4 „h The variable used in a switch statement can only be a byte, short, int, or char. „h You can have any number of case statements within a switch. Each case is followed by the value to be compared to and a colon. „h The value for a case must be the same data type as the variable in the switch and it must be a constant or a literal. „h When the variable being switched on is equal to a case, the statements following that case will execute until a break statement is reached. 1 „h When a break statement is reached, the switch terminates, and the flow of control jumps to the next line following the switch statement. 1 „h Not every case needs to contain a break. If no break appears, the flow of control will fall throughto subsequent cases until a break is reached. 1 „h A switch statement can have an optional default case, which must appear at the end of the switch. The default case can be used for performing a task when none of the cases is true. No break is needed in the default case. Example: publicclassTest{ publicstaticvoid main(String args[]){ char grade = args[0].charAt(0); switch(grade) { case'A': System.out.println("Excellent!"); break; case'B': case'C': System.out.println("Well done"); break; case'D': System.out.println("You passed"); case'F': System.out.println("Better try again"); break; default: System.out.println("Invalid grade"); } System.out.println("Your grade is "+ grade); } } Compile and run above program using various command line arguments. This would produce the following result: $ java Test a Invalid grade Your grade is a a $ java Test A Excellent! Your grade is a A $ java Test C Welldone Your grade is a C $ What is Next? Next chapter discuses about the Number class (in the java.lang package) and its subclasses in Java Language. We will be looking into some of the situations where you would use instantiations of these classes rather than the primitive data types, as well as classes such as formatting, mathematical functions that you need to know about when working with Numbers. CHAPTER 11 Java Numbers N ormally, when we work with Numbers, we use primitive data types such as byte, int, long, double, etc. Example: int i =5000; float gpa =13.65; byte mask =0xaf; However, in development, we come across situations where we need to use objects instead of primitive data types. In-order to achieve this, Java provides wrapper classes for each primitive data type. All the wrapper classes (Integer, Long, Byte, Double, Float, Short) are subclasses of the abstract class Number. This wrapping is taken care of by the compiler,the process is called boxing. So when a primitive is used when an object is required, the compiler boxes the primitive type in its wrapper class. Similarly, the compiler unboxes the object to a primitive as well. The Numberis part of the java.lang package. Here is an example of boxing and unboxing: publicclassTest{ publicstaticvoid main(String args[]){ Integer x =5;// boxes int to an Integer object x = x +10;// unboxes the Integer to a int System.out.println(x); } } This would produce the following result: 15 When x is assigned integer values, the compiler boxes the integer because x is integer objects. Later, x is unboxed so that they can be added as integers. Number Methods: Here is the list of the instance methods that all the subclasses of the Number class implement: SN Methods with Description 1 xxxValue() Converts the value of this Number object to the xxx data type and returned it. 2 compareTo() Compares this Number object to the argument. 3 equals() Determines whether this number object is equal to the argument. 4 valueOf() Returns an Integer object holding the value of the specified primitive. 5 toString() Returns a String object representing the value of specified int or Integer. 6 parseInt() This method is used to get the primitive data type of a certain String. 7 abs() Returns the absolute value of the argument. 8 ceil() Returns the smallest integer that is greater than or equal to the argument. Returned as a double. 9 floor() Returns the largest integer that is less than or equal to the argument. Returned as a double. 10 rint() Returns the integer that is closest in value to the argument. Returned as a double. 11 round() Returns the closest long or int, as indicated by the method's return type, to the argument. 12 min() Returns the smaller of the two arguments. 13 max() Returns the larger of the two arguments. 14 exp() Returns the base of the natural logarithms, e, to the power of the argument. 15 log() Returns the natural logarithm of the argument. 16 pow() Returns the value of the first argument raised to the power of the second argument. 17 sqrt() Returns the square root of the argument. 18 sin() Returns the sine of the specified double value. 19 cos() Returns the cosine of the specified double value. 20 tan() Returns the tangent of the specified double value. 21 asin() Returns the arcsine of the specified double value. 22 acos() Returns the arccosine of the specified double value. 23 atan() Returns the arctangent of the specified double value. 24 atan2() Converts rectangular coordinates (x, y) to polar coordinate (r, theta) and returns theta. 25 toDegrees() Converts the argument to degrees 26 toRadians() Converts the argument to radians. 27 random() Returns a random number. xxxValue() Description: The method converts the value of the Number Object that invokes the method to the primitive data type that is returned from the method. Syntax: Here is a separate method for each primitive data type: byte byteValue() short shortValue() int intValue() long longValue() float floatValue() double doubleValue() Parameters: Here is the detail of parameters: 1 „h NA Return Value: 1 „h These method returns the primitive data type that is given in the signature. Example: publicclassTest{ publicstaticvoid main(String args[]){ Integer x =5; // Returns byte primitive data type System.out.println( x.byteValue()); // Returns double primitive data type System.out.println(x.doubleValue()); // Returns long primitive data type System.out.println( x.longValue()); } } This produces the following result: 5 5.0 5 compareTo() Description: The method compares the Number object that invoked the method to the argument. It is possible to compare Byte, Long, Integer, etc. However, two different types cannot be compared, both the argument and the Number object invoking the method should be of same type. Syntax: public int compareTo( NumberSubClass referenceName ) Parameters: Here is the detail of parameters: 1 „h referenceName -- This could be a Byte, Double, Integer, Float, Long or Short. Return Value: 1 „h If the Integer is equal to the argument then 0 is returned. 2 „h If the Integer is less than the argument then -1 is returned. 3 „h If the Integer is greater than the argument then 1 is returned. Example: public class Test{ public static void main(String args[]){ Integer x = 5; System.out.println(x.compareTo(3)); System.out.println(x.compareTo(5)); System.out.println(x.compareTo(8)); } } This produces the following result: 1 0 -1 equals() Description: The method determines whether the Number Object that invokes the method is equal to the argument. Syntax: public boolean equals(Object o) Parameters: Here is the detail of parameters: 1 „h o -- Any object. Return Value: 1 „h The methods returns True if the argument is not null and is an object of the same type and with the same numeric value. There are some extra requirements for Double and Float objects that are described in the Java API documentation. Example: public class Test{ public static void main(String args[]){ Integer x = 5; Integer y = 10; Integer z =5; Short a = 5; System.out.println(x.equals(y)); System.out.println(x.equals(z)); System.out.println(x.equals(a)); } } This produces the following result: false true false valueOf() Description: The valueOf method returns the relevant Number Object holding the value of the argument passed. The argument can be a primitive data type, String, etc. This method is a static method. The method can take two arguments, where one is a String and the other is a radix. Syntax: All the variants of this method are given below: static Integer valueOf(int i) static Integer valueOf(String s) static Integer valueOf(String s, int radix) Parameters: Here is the detail of parameters: 1 „h i -- An int for which Integer representation would be returned. 2 „h s -- A String for which Integer representation would be returned. 3 „h radix -- This would be used to decide the value of returned Integer based on passed String. Return Value: 1 „h valueOf(int i): This returns an Integer object holding the value of the specified primitive. 2 „h valueOf(String s): This returns an Integer object holding the value of the specified string representation. 3 „h valueOf(String s, int radix): This returns an Integer object holding the integer value of the specified string representation, parsed with the value of radix. public class Test{ public static void main(String args[]){ Integer x =Integer.valueOf(9); Double c = Double.valueOf(5); Float a = Float.valueOf("80"); Integer b = Integer.valueOf("444",16); System.out.println(x); System.out.println(c); System.out.println(a); System.out.println(b); } } This produces the following result: 9 5.0 80.0 1092 toString() Description: The method is used to get a String object representing the value of the Number Object. If the method takes a primitive data type as an argument, then the String object representing the primitive data type value is return. If the method takes two arguments, then a String representation of the first argument in the radix specified by the second argument will be returned. Syntax: All the variant of this method are given below: String toString() static String toString(int i) Parameters: Here is the detail of parameters: 1 „h i -- An int for which string representation would be returned. Return Value: 1 „h toString(): This returns a String object representing the value of this Integer. 2 „h toString(int i): This returns a String object representing the specified integer. Example: public class Test{ public static Integer x =void 5; main(String args[]){ System.out.println(x.toString()); System.out.println(Integer.toString(12)); } } This produces the following result: 5 12 parseInt() Description: This method is used to get the primitive data type of a certain String. parseXxx() is a static method and can have one argument or two. Syntax: All the variant of this method are given below: static int parseInt(String s) static int parseInt(String s, int radix) Parameters: Here is the detail of parameters: „h s -- This is a string representation of decimal. 1 2 „h radix -- This would be used to convert String s into integer. Return Value: 1 „h parseInt(String s): This returns an integer (decimal only). 2 „h parseInt(int i): This returns an integer, given a string representation of decimal, binary, octal, or hexadecimal (radix equals 10, 2, 8, or 16 respectively) numbers as input. Example: public class Test{ public static void main(String args[]){ int x =Integer.parseInt("9"); double = Double.parseDouble("5"); int b =cInteger.parseInt("444",16); System.out.println(x); System.out.println(c); System.out.println(b); } } This produces the following result: 9 5.0 1092 abs() Description: The method gives the absolute value of the argument. The argument can be int, float, long, double, short, byte. Syntax: All the variant of this method are given below: double abs(double d) float abs(float f) int abs(int i) long abs(long lng) Parameters: Here is the detail of parameters: 1 „h Any primitive data type Return Value: 1 „h This method Returns the absolute value of the argument. Example: public class Test{ public static void main(String args[]){ Integer a = -8; double d = -100; float f = -90; System.out.println(Math.abs(a)); System.out.println(Math.abs(d)); System.out.println(Math.abs(f)); } } This produces the following result: 8 100.0 90.0 ceil() Description: The method ceil gives the smallest integer that is greater than or equal to the argument. Syntax: This method has following variants: double ceil(double d) double ceil(float f) Parameters: Here is the detail of parameters: 1 „h A double or float primitive data type Return Value: 1 „h This method Returns the smallest integer that is greater than or equal to the argument. Returned as a double. Example: public class Test{ public static void main(String args[]){ double d = -100.675; float f = -90; System.out.println(Math.ceil(d)); System.out.println(Math.ceil(f)); System.out.println(Math.floor(d)); System.out.println(Math.floor(f)); } } This produces the following result: -100.0 -90.0 -101.0 -90.0 floor() Description: The method floor gives the largest integer that is less than or equal to the argument. Syntax: This method has following variants: double floor(double d) double floor(float f) Parameters: Here is the detail of parameters: 1 „h A double or float primitive data type Return Value: 1 „h This method Returns the largest integer that is less than or equal to the argument. Returned as a double. Example: public class Test{ public static void main(String args[]){ double d = -100.675; float f = -90; System.out.println(Math.floor(d)); System.out.println(Math.floor(f)); System.out.println(Math.ceil(d)); System.out.println(Math.ceil(f)); } } This produces the following result: -101.0 -90.0 -100.0 -90.0 rint() Description: The method rint returns the integer that is closest in value to the argument. Syntax: double rint(double d) Parameters: Here is the detail of parameters: 1 „h d -- A double primitive data type Return Value: 1 „h This method Returns the integer that is closest in value to the argument. Returned as a double. Example: public class Test{ public static double d = double e = double f = void main(String args[]){ 100.675; 100.500; 100.200; System.out.println(Math.rint(d)); System.out.println(Math.rint(e)); System.out.println(Math.rint(f)); } } This produces the following result: 101.0 100.0 100.0 round() Description: The method round returns the closest long or int, as given by the methods return type. Syntax: This method has following variants: long round(double d) int round(float f) Parameters: Here is the detail of parameters: 1 „h d -- A double or float primitive data type 2 „h f -- A float primitive data type Return Value: 1 „h This method Returns the closest long or int, as indicated by the method's return type, to the argument. Example: public class Test{ public static void main(String args[]){ double d = 100.675; double e = 100.500; float f = 100; float g = 90f; System.out.println(Math.round(d)); System.out.println(Math.round(e)); System.out.println(Math.round(f)); System.out.println(Math.round(g)); } } This produces the following result: 101 101 100 90 min() Description: The method gives the smaller of the two arguments. The argument can be int, float, long, double. Syntax: This method has following variants: double min(double arg1, double arg2) float min(float arg1, float arg2) int min(int arg1, int arg2) long min(long arg1, long arg2) Parameters: Here is the detail of parameters: 1 „h A primitive data types Return Value: 1 „h This method Returns the smaller of the two arguments. Example: public class Test{ public static void main(String args[]){ System.out.println(Math.min(12.123, 12.456)); System.out.println(Math.min(23.12, 23.0)); } } This produces the following result: 12.123 23.0 max() Description: The method gives the maximum of the two arguments. The argument can be int, float, long, double. Syntax: This method has following variants: double max(double arg1, double arg2) float max(float arg1, float arg2) int max(int arg1, int arg2) long max(long arg1, long arg2) Parameters: Here is the detail of parameters: 1 „h A primitive data types Return Value: 1 „h This method Returns the maximum of the two arguments. Example: public class Test{ public static void main(String args[]){ System.out.println(Math.max(12.123, 12.456)); System.out.println(Math.max(23.12, 23.0)); } } This produces the following result: 12.456 23.12 exp() Description: The method returns the base of the natural logarithms, e, to the power of the argument. Syntax: double exp(double d) Parameters: Here is the detail of parameters: 1 „h d -- A primitive data types Return Value: 1 „h This method Returns the base of the natural logarithms, e, to the power of the argument. Example: public class Test{ public static void main(String args[]){ double x = 11.635; double y = 2.76; System.out.printf("The value of e is %.4f%n", Math.E); System.out.printf("exp(%.3f) is %.3f%n", x, Math.exp(x)); } } This produces the following result: The value of e is 2.7183 exp(11.635) is 112983.831 log() Description: The method returns the natural logarithm of the argument. Syntax: double log(double d) Parameters: Here is the detail of parameters: 1 „h d -- A primitive data types Return Value: 1 „h This method Returns the natural logarithm of the argument. Example: public class Test{ public static void main(String args[]){ double x = 11.635; double y = 2.76; System.out.printf("The value of e is %.4f%n", Math.E); System.out.printf("log(%.3f) is %.3f%n", x, Math.log(x)); } } This produces the following result: The value of e is 2.7183 log(11.635) is 2.454 pow() Description: The method returns the value of the first argument raised to the power of the second argument. Syntax: double pow(double base, double exponent) Parameters: Here is the detail of parameters: 1 „h base -- A primitive data type 2 „h exponenet -- A primitive data type Return Value: 1 „h This method Returns the value of the first argument raised to the power of the second argument. Example: public class Test{ public static void main(String args[]){ double x = 11.635; double y = 2.76; System.out.printf("The value of e is %.4f%n", Math.E); System.out.printf("pow(%.3f, %.3f) is %.3f%n", x, y, Math.pow(x, y)); } } This produces the following result: The value of e is 2.7183 pow(11.635, 2.760) is 874.008 sqrt() Description: The method returns the square root of the argument. Syntax: double sqrt(double d) Parameters: Here is the detail of parameters: 1 „h d -- A primitive data type Return Value: 1 „h This method Returns the square root of the argument. Example: public class Test{ public static void main(String args[]){ double x = 11.635; double y = 2.76; System.out.printf("The value of e is %.4f%n", Math.E); System.out.printf("sqrt(%.3f) is %.3f%n", x, Math.sqrt(x)); } } This produces the following result: The value of e is 2.7183 sqrt(11.635) is 3.411 sin() Description: The method returns the sine of the specified double value. Syntax: double sin(double d) Parameters: Here is the detail of parameters: 1 „h d -- A double data types Return Value: 1 „h This method Returns the sine of the specified double value. Example: public class Test{ public static void main(String args[]){ double degrees = 45.0; double radians = Math.toRadians(degrees); System.out.format("The value of pi is %.4f%n", Math.PI); System.out.format("The sine of %.1f degrees is %.4f%n", degrees, Math.sin(radians)); } } This produces the following result: The value of pi is 3.1416 The sine of 45.0 degrees is 0.7071 cos() Description: The method returns the cosine of the specified double value. Syntax: double cos(double d) Parameters: Here is the detail of parameters: 1 „h d -- A double data types Return Value: 1 „h This method Returns the cosine of the specified double value. Example: public class Test{ public static void main(String args[]){ double degrees = 45.0; double radians = Math.toRadians(degrees); System.out.format("The value of pi is %.4f%n", Math.PI); System.out.format("The cosine of %.1f degrees is %.4f%n", degrees, Math.cos(radians)); } } This produces the following result: The value of pi is 3.1416 The cosine of 45.0 degrees is 0.7071 tan() Description: The method returns the tangent of the specified double value. Syntax: double tan(double d) Parameters: Here is the detail of parameters: 1 „h d -- A double data type Return Value: 1 „h This method Returns the tangent of the specified double value. Example: public class Test{ public static void main(String args[]){ double degrees = 45.0; double radians = Math.toRadians(degrees); System.out.format("The value of pi is %.4f%n", Math.PI); System.out.format("The tangent of %.1f degrees is %.4f%n", degrees, Math.tan(radians)); } } This produces the following result: The value of pi is 3.1416 The tangent of 45.0 degrees is 1.0000 asin() Description: The method returns the arcsine of the specified double value. Syntax: double asin(double d) Parameters: Here is the detail of parameters: 1 „h d -- A double data types Return Value: 1 „h This method Returns the arcsine of the specified double value. Example: public class Test{ public static void main(String args[]){ double degrees = 45.0; double radians = Math.toRadians(degrees); System.out.format("The value of pi is %.4f%n", Math.PI); System.out.format("The arcsine of %.4f is %.4f degrees %n", Math.sin(radians), Math.toDegrees(Math.asin(Math.sin(radians)))); } } This produces the following result: The value of pi is 3.1416 The arcsine of 0.7071 is 45.0000 degrees acos() Description: The method returns the arccosine of the specified double value. Syntax: double acos(double d) Parameters: Here is the detail of parameters: 1 „h d -- A double data types Return Value: 1 „h This method Returns the arccosine of the specified double value. Example: public class Test{ public static void main(String args[]){ double degrees = 45.0; double radians = Math.toRadians(degrees); System.out.format("The value of pi is %.4f%n", Math.PI); System.out.format("The arccosine of %.4f is %.4f degrees %n", Math.cos(radians), Math.toDegrees(Math.acos(Math.sin(radians)))); } } This produces the following result: The value of pi is 3.1416 The arccosine of 0.7071 is 45.0000 degrees atan() Description: The method returns the arctangent of the specified double value. Syntax: double atan(double d) Parameters: Here is the detail of parameters: 1 „h d -- A double data types Return Value : 1 „h This method Returns the arctangent of the specified double value. Example: public class Test{ public static void main(String args[]){ double degrees = 45.0; double radians = Math.toRadians(degrees); System.out.format("The value of pi is %.4f%n", Math.PI); System.out.format("The arctangent of %.4f is %.4f degrees %n", Math.cos(radians), Math.toDegrees(Math.atan(Math.sin(radians)))); } } This produces the following result: The value of pi is 3.1416 The arctangent of 1.0000 is 45.0000 degrees atan2() Description: The method Converts rectangular coordinates (x, y) to polar coordinate (r, theta) and returns theta. Syntax: double atan2(double y, double x) Parameters: Here is the detail of parameters: 1 „h X -- X co-ordinate in double data type 2 „h Y -- Y co-ordinate in double data type Return Value: 1 „h This method Returns theta from polar coordinate (r, theta) Example: public class Test{ public static void main(String args[]){ double x = 45.0; double y = 30.0; System.out.println( Math.atan2(x, y) ); } } This produces the following result: 0.982793723247329 toDegrees() Description: The method converts the argument value to degrees. Syntax: double toDegrees(double d) Parameters: Here is the detail of parameters: 1 „h d -- A double data type. Return Value: 1 „h This method returns a double value. Example: public class Test{ public static void main(String args[]){ double x = 45.0; double y = 30.0; System.out.println( Math.toDegrees(x) ); System.out.println( Math.toDegrees(y) ); } } This produces the following result: 2578.3100780887044 1718.8733853924698 toRadians() Description: The method converts the argument value to radians. Syntax: double toRadians(double d) Parameters: Here is the detail of parameters: 1 „h d -- A double data type. Return Value: 1 „h This method returns a double value. Example: public class Test{ public static void main(String args[]){ double x = 45.0; double y = 30.0; System.out.println( Math.toRadians(x) ); System.out.println( Math.toRadians(y) ); } } This produces the following result: 0.7853981633974483 0.5235987755982988 random() Description: The method is used to generate a random number between 0.0 and 1.0. The range is: 0.0 =< Math.random < 1.0. Different ranges can be achieved by using arithmetic. Syntax: static double random() Parameters: Here is the detail of parameters: 1 „h NA Return Value: 1 „h This method returns a double Example: public class Test{ public static void main(String args[]){ System.out.println( Math.random() ); System.out.println( Math.random() ); } } This produces the following result: 0.16763945061451657 0.400551253762343 Note: Above result would vary every time you would call random() method. What is Next? In the next section, we will be going through the Character class in Java. You will be learning how to use object Characters and primitive data type char in Java. Java Characters N ormally, when we work with characters, we use primitive data types char. Example: char ch ='a'; // Unicode for uppercase Greek omega character char uniChar ='\u039A'; // an array of chars char[] charArray ={'a','b','c','d','e'}; However in development, we come across situations where we need to use objects instead of primitive data types. Inorder to achieve this, Java provides wrapper class Characterfor primitive data type char. The Character class offers a number of useful class (i.e., static) methods for manipulating characters. You can create a Character object with the Character constructor: Character ch =newCharacter('a'); The Java compiler will also create a Character object for you under some circumstances. For example, if you pass a primitive char into a method that expects an object, the compiler automatically converts the char to a Character for you. This feature is called autoboxing or unboxing, if the conversion goes the other way. Example: // Here following primitive char 'a' // is boxed into the Character object ch Character ch ='a'; // Here primitive 'x' is boxed for method test, // return is unboxed to char 'c' char c = test('x'); Escape Sequences: A character preceded by a backslash (\) is an escape sequence and has special meaning to the compiler. CHAPTER 12 The newline character (\n) has been used frequently in this tutorial in System.out.println() statements to advance to the next line after the string is printed. Following table shows the Java escape sequences: Escape Sequence Description \t Inserts a tab in the text at this point. \b Inserts a backspace in the text at this point. \n Inserts a newline in the text at this point. \r Inserts a carriage return in the text at this point. \f Inserts a form feed in the text at this point. \' Inserts a single quote character in the text at this point. \" Inserts a double quote character in the text at this point. \\ Inserts a backslash character in the text at this point. When an escape sequence is encountered in a print statement, the compiler interprets it accordingly. Example: If you want to put quotes within quotes you must use the escape sequence, \", on the interior quotes: publicclassTest{ publicstaticvoid main(String args[]){ System.out.println("She said \"Hello!\" to me."); } } This would produce the following result: She said "Hello!" to me. Character Methods: Here is the list of the important instance methods that all the subclasses of the Character class implement: SN Methods with Description 1 isLetter() Determines whether the specified char value is a letter. 2 isDigit() Determines whether the specified char value is a digit. 3 isWhitespace() Determines whether the specified char value is white space. 4 isUpperCase() Determines whether the specified char value is uppercase. 5 isLowerCase() Determines whether the specified char value is lowercase. 6 toUpperCase() Returns the uppercase form of the specified char value. 7 toLowerCase() Returns the lowercase form of the specified char value. 8 toString() Returns a String object representing the specified character valuethat is, a one-character string. For a complete list of methods, please refer to the java.lang.Character API specification. isLetter() Description: The method determines whether the specified char value is a letter. Syntax: boolean isLetter(char ch) Parameters: Here is the detail of parameters: 1 „h ch -- Primitive character type Return Value: 1 „h This method Returns true if passed character is really a character. Example: public class Test { public static void main(String args[]) { System.out.println(Character.isLetter('c')); System.out.println(Character.isLetter('5')); } } This produces the following result: true false isDigit() Description: The method determines whether the specified char value is a digit. Syntax: boolean isDigit(char ch) Parameters: Here is the detail of parameters: 1 „h ch -- Primitive character type Return Value: 1 „h This method Returns true if passed character is really a digit. Example: public class Test { public static void main(String args[]) { System.out.println(Character.isDigit('c')); System.out.println(Character.isDigit('5')); } } This produces the following result: false true isWhitespace() Description: The method determines whether the specified char value is a white space, which includes space, tab or new line. Syntax: boolean isWhitespace(char ch) Parameters: Here is the detail of parameters: 1 „h ch -- Primitive character type Return Value: 1 „h This method Returns true if passed character is really a white space. Example: public class Test{ public static void main(String args[]){ System.out.println(Character.isWhitespace('c')); System.out.println(Character.isWhitespace(' ')); System.out.println(Character.isWhitespace('\n')); System.out.println(Character.isWhitespace('\t')); } } This produces the following result: false true true true isUpperCase() Description: The method determines whether the specified char value is uppercase. Syntax: boolean isUpperCase(char ch) Parameters: Here is the detail of parameters: 1 „h ch -- Primitive character type Return Value: 1 „h This method Returns true if passed character is really an uppercase. Example: public class Test{ public static void main(String args[]){ System.out.println( Character.isUpperCase('c')); System.out.println( Character.isUpperCase('C')); System.out.println( Character.isUpperCase('\n')); System.out.println( Character.isUpperCase('\t')); } } This produces the following result: false true false false isLowerCase() Description: The method determines whether the specified char value is lowercase. Syntax: boolean isLowerCase(char ch) Parameters: Here is the detail of parameters: 1 „h ch -- Primitive character type Return Value: 1 „h This method Returns true if passed character is really an lowercase. Example: public class Test{ public static void main(String args[]){ System.out.println(Character.isLowerCase('c')); System.out.println(Character.isLowerCase('C')); System.out.println(Character.isLowerCase('\n')); System.out.println(Character.isLowerCase('\t')); } } This produces the following result: true false false false toUpperCase() Description: The method returns the uppercase form of the specified char value. Syntax: char toUpperCase(char ch) Parameters: Here is the detail of parameters: 1 „h ch -- Primitive character type Return Value : 1 „h This method Returns the uppercase form of the specified char value. Example: public class Test{ public static void main(String args[]){ System.out.println(Character.toUpperCase('c')); System.out.println(Character.toUpperCase('C')); } } This produces the following result: C C toLowerCase() Description: Syntax: The method returns the lowercase form of the specified char value. char toLowerCase(char ch) Parameters: Here is the detail of parameters: 1 „h ch -- Primitive character type Return Value: 1 „h This method Returns the lowercase form of the specified char value. Example: public class Test{ public static void main(String args[]){ System.out.println(Character.toLowerCase('c')); System.out.println(Character.toLowerCase('C')); } } This produces the following result: c c toString() Description: The method returns a String object representing the specified character value, that is, a one-character string. Syntax: String toString(char Parameters: ch) Here is the detail of parameters: 1 „h ch -- Primitive character type Return Value: 1 „h This method Returns String object Example: public class Test{ public static void main(String args[]){ System.out.println(Character.toString('c')); System.out.println(Character.toString('C')); } } This produces the following result: c C What is Next? In the next section, we will be going through the String class in Java. You will be learning how to declare and use Strings efficiently as well as some of the important methods in the String class. Java Strings S trings which are widely used in Java programming are a sequence of characters. In the Java programming language, strings are objects. The Java platform provides the String class to create and manipulate strings. Creating Strings: The most direct way to create a string is to write: String greeting ="Hello world!"; Whenever it encounters a string literal in your code, the compiler creates a String object with its value, in this case, "Hello world!'. As with any other object, you can create String objects by using the new keyword and a constructor. The String class has eleven constructors that allow you to provide the initial value of the string using different sources, such as an array of characters: publicclassStringDemo{ publicstaticvoid main(String args[]){ char[] helloArray ={'h','e','l','l','o','.'}; String helloString =newString(helloArray); System.out.println( helloString ); } } This would produce the following result: hello. Note: The String class is immutable, so that once it is created a String object cannot be changed. If there is a necessity to make alot of modifications to Strings of characters, then you should use String Buffer & String Builder Classes. String Length: Methods used to obtain information about an object are known as accessor methods. One accessor method that you can use with strings is the length() method, which returns the number of characters contained in the string object. CHAPTER 13 After the following two lines of code have been executed, len equals 17: publicclassStringDemo{ publicstaticvoid main(String args[]){ String palindrome ="Dot saw I was Tod"; int len = palindrome.length(); System.out.println("String Length is : "+ len ); } } This would produce the following result: StringLengthis:17 Concatenating Strings: The String class includes a method for concatenating two strings: string1.concat(string2); This returns a new string that is string1 with string2 added to it at the end. You can also use the concat() method with string literals, as in: "My name is ".concat("Zara"); Strings are more commonly concatenated with the + operator, as in: "Hello,"+" world"+"!" which results in: "Hello, world!" Let us look at the following example: publicclassStringDemo{ publicstaticvoid main(String args[]){ String string1 ="saw I was "; System.out.println("Dot "+ string1 +"Tod"); } } This would produce the following result: Dot saw I was Tod Creating Format Strings: You have printf() and format() methods to print output with formatted numbers. The String class has an equivalent class method, format(), that returns a String object rather than a PrintStream object. Using String's static format() method allows you to create a formatted string that you can reuse, as opposed to a one-time print statement. For example, instead of: System.out.printf("The value of the float variable is "+ "%f, while the value of the integer "+ "variable is %d, and the string "+ "is %s", floatVar, intVar, stringVar); you can write: String fs; fs =String.format("The value of the float variable is "+ "%f, while the value of the integer "+ "variable is %d, and the string "+ "is %s", floatVar, intVar, stringVar); System.out.println(fs); String Methods: Here is the list of methods supported by String class: SN Methods with Description 1 char charAt(int index) Returns the character at the specified index. 2 int compareTo(Object o) Compares this String to another Object. 3 int compareTo(String anotherString) Compares two strings lexicographically. 4 int compareToIgnoreCase(String str) Compares two strings lexicographically, ignoring case differences. 5 String concat(String str) Concatenates the specified string to the end of this string. 6 boolean contentEquals(StringBuffer sb) Returns true if and only if this String represents the same sequence of characters as the specified StringBuffer. 7 static String copyValueOf(char[] data) Returnsina String that represents the character sequence the array specified. 8 static String copyValueOf(char[] data, int offset, int count) Returns a String that represents the character sequence in the array specified. 9 boolean endsWith(String suffix) Tests if this string ends with the specified suffix. 10 boolean equals(Object anObject) Compares this string to the specified object. 11 boolean equalsIgnoreCase(String anotherString) Compares this String to another String, ignoring case considerations. 12 byte getBytes() Encodes this String into a sequence of bytes using the platform's default charset, storing the result into a new byte array. 13 byte[] getBytes(String charsetName Encodes this String into a sequence of bytes using the named charset, storing the result into a new byte array. 14 void getChars(int srcBegin, int srcEnd, char[] dst, int dstBegin) Copies characters from this string into the destination character array. 15 int hashCode() Returns a hash code for this string. 16 int indexOf(int ch) Returns the index within this string of the first occurrence of the specified character. 17 int indexOf(int ch, int fromIndex) Returns the index within this string ofstarting the firstthe occurrence the specified character, search atof the specified index. 18 int indexOf(String str) Returns the index within this string of the first occurrence of the specified substring. 19 int indexOf(String str, int fromIndex) Returns the index within this string of the first occurrence of the specified substring, starting at the specified index. 20 String intern() Returns a canonical representation for the string object. 21 int lastIndexOf(int ch) Returns the index within this string of the last occurrence of the specified character. 22 int lastIndexOf(int ch, int fromIndex) Returns the index within this string of the last occurrence of the specified character, searching backward starting at the specified index. 23 int lastIndexOf(String str) Returns the index within this string of the rightmost occurrence of the specified substring. 24 int lastIndexOf(String str, int fromIndex) Returns the index within this string of the last occurrence of the specified substring, searching backward starting at the specified index. 25 int length() Returns the length of this string. 26 boolean matches(String regex) Tells whether or not this string matches the given regular expression. 27 boolean regionMatches(boolean ignoreCase, int toffset, String other, int ooffset, int len) Tests if two string regions are equal. 28 boolean regionMatches(int toffset, String other, int ooffset, int len) Tests if two string regions are equal. 29 String replace(char oldChar, char newChar) Returns a new string resulting from replacing all occurrences of oldChar in this string with newChar. 30 String replaceAll(String regex, String replacement Replaces each substring of this string that matches the given regular expression with the given replacement. 31 String replaceFirst(String regex, String replacement) Replaces the first substring of this string that matches the given regular expression with the given replacement. 32 String[] split(String regex) Splits this string around matches of the given regular expression. 33 String[] split(String regex, int limit) Splits this string around matches of the given regular expression. 34 boolean startsWith(String prefix) Tests if this string starts with the specified prefix. 35 boolean startsWith(String prefix, int toffset) Tests if this string starts with the specified prefix beginning a specified index. 36 CharSequence subSequence(int beginIndex, int endIndex) Returns a new character sequence that is a subsequence of this sequence. 37 String substring(int beginIndex) Returns a new string that is a substring of this string. 38 String substring(int beginIndex, int endIndex) Returns a new string that is a substring of this string. 39 char[] toCharArray() Converts this string to a new character array. 40 String toLowerCase() Converts all of the characters in this String to lower case using the rules of the default locale. 41 String toLowerCase(Locale locale) Converts all of the characters in this String to lower case using the rules of the given Locale. 42 String toString() This object (which is already a string!) is itself returned. 43 String toUpperCase() Converts all of the characters in this String to upper case using the rules of the default locale. 44 String toUpperCase(Locale locale) Converts all of the characters in this String to upper case using the rules of the given Locale. 45 String trim() Returns a copy of the string, with leading and trailing whitespace omitted. 46 static String valueOf(primitive data type x) Returns the string representation of the passed data type argument. The above mentioned methods are explained here: char charAt(int index) Description: This method returns the character located at the String's specified index. The string indexes start from zero. Syntax: Here is the syntax of this method: public char charAt(int index) Parameters: Here is the detail of parameters: 1 „h index -- Index of the character to be returned. Return Value: 1 „h This method Returns a char at the specified index. Example: public class Test { public static main(String args[]) { String s = void "Strings are immutable"; char result = s.charAt(8); System.out.println(result); } } This produces the following result: a int compareTo(Object o) Description: There are two variants of this method. First method compares this String to another Object and second method compares two strings lexicographically. Syntax: Here is the syntax of this method: int compareTo(Object o) or int compareTo(String anotherString) Parameters: Here is the detail of parameters: 1 „h o -- the Object to be compared. 2 „h anotherString -- the String to be compared. Return Value : 1 „h The value 0 if the argument is a string lexicographically equal to this string; a value less than 0 if the argument is a string lexicographically greater than this string; and a value greater than 0 if the argument is a string lexicographically less than this string. Example: public class Test { public static void main(String args[]) { String str1 = "Strings are immutable"; String str2 = "Strings are immutable"; String str3 = "Integers are not immutable"; int result = str1.compareTo( str2 ); System.out.println(result); result = str2.compareTo( str3 ); System.out.println(result); result = str3.compareTo( str1 ); System.out.println(result); } } This produces the following result: 0 10 -10 int compareTo(String anotherString) Description: There are two variants of this method. First method compares this String to another Object and second method compares two strings lexicographically. Syntax: Here is the syntax of this method: int compareTo(Object o) or int compareTo(String anotherString) Parameters: Here is the detail of parameters: 1 „h o -- the Object to be compared. 2 „h anotherString -- the String to be compared. Return Value : 1 „h The value 0 if the argument is a string lexicographically equal to this string; a value less than 0 if the argument is a string lexicographically greater than this string; and a value greater than 0 if the argument is a string lexicographically less than this string. Example: public class Test { public static void main(String args[]) { String str1 = "Strings are immutable"; String str2 = "Strings are immutable"; String str3 = "Integers are not immutable"; int result = str1.compareTo( str2 ); System.out.println(result); result = str2.compareTo( str3 ); System.out.println(result); result = str3.compareTo( str1 ); System.out.println(result); } } This produces the following result: 0 10 -10 int compareToIgnoreCase(String str) Description: This method compares two strings lexicographically, ignoring case differences. Syntax: Here is the syntax of this method: int compareToIgnoreCase(String str) Parameters: Here is the detail of parameters: 1 „h str -- the String to be compared. Return Value: 1 „h This method returns a negative integer, zero, or a positive integer as the specified String is greater than, equal to, or less than this String, ignoring case considerations. Example: public class Test { public static void main(String args[]) { String str1 = "Strings are immutable"; String str2 = "Strings are immutable"; String str3 = "Integers are not immutable"; int result = str1.compareToIgnoreCase( str2 ); System.out.println(result); result = str2.compareToIgnoreCase( str3 ); System.out.println(result); result = str3.compareToIgnoreCase( str1 ); } System.out.println(result); } This produces the following result: 0 10 -10 String concat(String str) Description: This method appends one String to the end of another. The method returns a String with the value of the String passed in to the method appended to the end of the String used to invoke this method. Syntax: Here is the syntax of this method: public String concat(String s) Parameters: Here is the detail of parameters: 1 „h s -- the String that is concatenated to the end of this String. Return Value : 1 „h This methods returns a string that represents the concatenation of this object's characters followed by the string argument's characters. Example: public class Test { public static void main(String args[]) { String s = "Strings are immutable"; s = s.concat(" all the time"); System.out.println(s); } } This produces the following result: Strings are immutable all the time boolean contentEquals(StringBuffer sb) Description: This method returns true if and only if this String represents the same sequence of characters as the specified in StringBuffer. Syntax: Here is the syntax of this method: public boolean contentEquals(StringBuffer sb) Parameters: Here is the detail of parameters: 1 „h sb -- the StringBuffer to compare. Return Value: 1 „h This method returns true if and only if this String represents the same sequence of characters as the specified in StringBuffer, otherwise false. Example: public class Test { public static void main(String args[]) { String str1 = "Not immutable"; String str2 = "Strings are immutable"; StringBuffer str3 = new StringBuffer( "Not immutable"); boolean result = str1.contentEquals( str3 ); System.out.println(result); result = str2.contentEquals( str3 ); System.out.println(result); } } This produces the following result: true false static String copyValueOf(char[] data) Description: This method has two different forms: 1 „h public static String copyValueOf(char[] data): Returns a String that represents the character sequence in the array specified. 2 „h public static String copyValueOf(char[] data, int offset, int count): Returns a String that represents the character sequence in the array specified. Syntax: Here is the syntax of this method: public static String copyValueOf(char[] data) or public static String copyValueOf(char[] data, int offset, int count) Parameters: Here is the detail of parameters: 1 „h data -- the character array. 2 „h offset -- initial offset of the subarray. 3 „h count -- length of the subarray. Return Value : 1 „h This method returns a String that contains the characters of the character array. Example: public class Test { public static void main(String args[]) { char[] Str1 = "This is really not immutable!!"; String Str2; Str2 = copyValueOf( Str1 ); System.out.println("Returned String " + Str2); Str2 = copyValueOf( Str1, 5, 10 ); System.out.println("Returned String " + Str2); } } This produces the following result: This is really not immutable!! is rea static String copyValueOf(char[] data, int offset, int count) Description: This method has two different forms: 1 „h public static String copyValueOf(char[] data): Returns a String that represents the character sequence in the array specified. 2 „h public static String copyValueOf(char[] data, int offset, int count): Returns a String that represents the character sequence in the array specified. Syntax: Here is the syntax of this method: public static String copyValueOf(char[] data) or public static String copyValueOf(char[] data, int offset, int count) Parameters: Here is the detail of parameters: 1 „h data -- the character array. 2 „h offset -- initial offset of the subarray. 3 „h count -- length of the subarray. Return Value : 1 „h This method returns a String that contains the characters of the character array. Example: public class Test { public static void main(String args[]) { char[] Str1 = "This is really not immutable!!"; String Str2; Str2 = copyValueOf( Str1 ); System.out.println("Returned String " + Str2); Str2 = copyValueOf( Str1, 5, 10 ); System.out.println("Returned String " + Str2); } } This produces the following result: This is really not immutable!! is rea boolean endsWith(String suffix) Description: This method tests if this string ends with the specified suffix. Syntax: Here is the syntax of this method: public boolean endsWith(String suffix) Parameters: Here is the detail of parameters: 1 „h suffix -- the suffix. Return Value: 1 „h This method returns true if the character sequence represented by the argument is a suffix of the character sequence represented by this object; false otherwise. Note that the result will be true if the argument is the empty string or is equal to this String object as determined by the equals(Object) method. Example: public class Test{ public static void main(String args[]){ String Str = new String("This is really not immutable!!"); boolean retVal; retVal = Str.endsWith( "immutable!!" ); System.out.println("Returned Value = " + retVal ); retVal = Str.endsWith( "immu" ); System.out.println("Returned Value = " + retVal ); } } This produces the following result: Returned Value = true Returned Value = false boolean equals(Object anObject) Description: This method compares this string to the specified object. The result is true if and only if the argument is not null and is a String object that represents the same sequence of characters as this object. Syntax: Here is the syntax of this method: public boolean equals(Object anObject) Parameters: Here is the detail of parameters: 1 „h anObject -- the object to compare this String against. Return Value : 1 „h This method returns true if the String are equal; false otherwise. Example: public class Test { public static void main(String args[]) { String Str1 = new String("This is really not immutable!!"); String Str2 = Str1; String Str3 = new String("This is really not immutable!!"); boolean retVal; retVal = Str1.equals( Str2 ); System.out.println("Returned Value = " + retVal ); retVal = Str1.equals( Str3 ); System.out.println("Returned Value = " + retVal ); } } This produces the following result: Returned Value = true Returned Value = true boolean equalsIgnoreCase(String anotherString) Description: This method compares this String to another String, ignoring case considerations. Two strings are considered equal ignoring case if they are of the same length, and corresponding characters in the two strings are equal ignoring case. Syntax: Here is the syntax of this method: public boolean equalsIgnoreCase(String anotherString) Parameters: Here is the detail of parameters: 1 „h anotherString -- the String to compare this String against Return Value: 1 „h This method returns true if the argument is not null and the Strings are equal, ignoring case; false otherwise. Example: public class Test { public static void main(String args[]) { String Str1 = new String("This is really not immutable!!"); String Str2 = Str1; String Str3 = new String("This is really not immutable!!"); String Str4 = new String("This IS REALLY NOT IMMUTABLE!!"); boolean retVal; retVal = Str1.equals( Str2 ); System.out.println("Returned Value = " + retVal ); retVal = Str1.equals( Str3 ); System.out.println("Returned Value = " + retVal ); retVal = Str1.equalsIgnoreCase( Str4 ); System.out.println("Returned Value = " + retVal ); } } This produces the following result: Returned Value = true Returned Value = true Returned Value = true byte getBytes() Description: This method has following two forms: 1 „h getBytes(String charsetName): Encodes this String into a sequence of bytes using the named charset, storing the result into a new byte array. 2 „h getBytes(): Encodes this String into a sequence of bytes using the platform's default charset, storing the result into a new byte array. Here is the syntax of this method: Syntax: public byte[] getBytes(String charsetName) throws UnsupportedEncodingException or public byte[] getBytes() Parameters: Here is the detail of parameters: 1 „h charsetName -- the name of a supported charset. Return Value: 1 „h This method returns the resultant byte array Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str1 = new String("Welcome to Tutorialspoint.com"); try{ byte[] Str2 = Str1.getBytes(); System.out.println("Returned Value " + Str2 ); Str2 = Str1.getBytes( "UTF-8" ); System.out.println("Returned Value " + Str2 ); Str2 = Str1.getBytes( "ISO-8859-1" ); System.out.println("Returned Value " + Str2 ); }catch( UnsupportedEncodingException e){ System.out.println("Unsupported character set"); } } } This produces the following result: Returned Value [B@192d342 Returned Value [B@15ff48b Returned Value [B@1b90b39 byte[] getBytes(String charsetName) Description: This method has following two forms: 1 „h getBytes(String charsetName): Encodes this String into a sequence of bytes using the named charset, storing the result into a new byte array. 2 „h getBytes(): Encodes this String into a sequence of bytes using the platform's default charset, storing the result into a new byte array. Syntax: Here is the syntax of this method: public byte[] getBytes(String charsetName) throws UnsupportedEncodingException or public byte[] getBytes() Parameters: Here is the detail of parameters: 1 „h charsetName -- the name of a supported charset. Return Value: 1 „h This method returns the resultant byte array Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str1 = new String("Welcome to Tutorialspoint.com"); try{ byte[] Str2 = Str1.getBytes(); System.out.println("Returned Value " + Str2 ); Str2 = Str1.getBytes( "UTF-8" ); System.out.println("Returned Value " + Str2 ); Str2 = Str1.getBytes( "ISO-8859-1" ); System.out.println("Returned Value " + Str2 ); }catch( UnsupportedEncodingException e){ System.out.println("Unsupported character set"); } } } This produces the following result: Returned Value [B@192d342 Returned Value [B@15ff48b Returned Value [B@1b90b39 void getChars(int srcBegin, int srcEnd, char[] dst, int dstBegin) Description: This method copies characters from this string into the destination character array. Syntax: Here is the syntax of this method: public void getChars(int srcBegin, int srcEnd, char[] dst, int dstBegin) Parameters: Here is the detail of parameters: 1 „h srcBegin -- index of the first character in the string to copy. 2 „h srcEnd -- index after the last character in the string to copy. 3 „h dst -- the destination array. 4 „h dstBegin -- the start offset in the destination array. Return Value: 1 „h It does not return any value but throws IndexOutOfBoundsException. Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str1 = new String("Welcome to Tutorialspoint.com"); char[] Str2 = new char[7]; try{ Str1.getChars(2, 9, Str2, 0); System.out.print("Copied Value = " ); System.out.println(Str2 ); }catch( Exception ex){ System.out.println("Raised exception..."); } } } This produces the following result: Copied Value = lcome t int hashCode() Description: This method returns a hash code for this string. The hash code for a String object is computed as: s[0]*31^(n-1) + s[1]*31^(n-2) + ... + s[n-1] Using int arithmetic, where s[i] is the ith character of the string, n is the length of the string, and ^ indicates exponentiation. (The hash value of the empty string is zero.) Syntax: Here is the syntax of this method: public int hashCode() Parameters: Here is the detail of parameters: 1 „h NA Return Value: 1 „h This method returns a hash code value for this object. Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str = new String("Welcome to Tutorialspoint.com"); System.out.println("Hashcode for Str :" + Str.hashCode() ); } } This produces the following result: Hashcode for Str :1186874997 int indexOf(int ch) Description: This method has following different variants: 1 „h public int indexOf(int ch): Returns the index within this string of the first occurrence of the specified character or -1 if the character does not occur. 2 „h public int indexOf(int ch, int fromIndex): Returns the index within this string of the first occurrence of the specified character, starting the search at the specified index or -1 if the character does not occur. 3 „h int indexOf(String str): Returns the index within this string of the first occurrence of the specified substring. If it does not occur as a substring, -1 is returned. 4 „h int indexOf(String str, int fromIndex): Returns the index within this string of the first occurrence of the specified substring, starting at the specified index. If it does not occur, -1 is returned. Syntax: Here is the syntax of this method: public int indexOf(int ch ) or public int indexOf(int ch, int fromIndex) or int indexOf(String str) or int indexOf(String str, int fromIndex) Parameters: Here is the detail of parameters: 1 „h ch -- a character. 1 „h fromIndex -- the index to start the search from. 2 „h str -- a string. Return Value: 1 „h See the description. Example: import java.io.*; public class Test { public static void main(String args[]) { String Str = new String("Welcome to Tutorialspoint.com"); String SubStr1 = new String("Tutorials"); String SubStr2 = new String("Sutorials"); System.out.print("Found Index :" ); System.out.println(Str.indexOf( 'o' )); System.out.print("Found Index :" ); System.out.println(Str.indexOf( 'o', 5 )); System.out.print("Found Index :" ); System.out.println( Str.indexOf( SubStr1 )); System.out.print("Found Index :" ); System.out.println( Str.indexOf( SubStr1, 15 )); System.out.print("Found Index :" ); System.out.println(Str.indexOf( SubStr2 )); } } This produces the following result: Found Index :4 Found Index :9 Found Index :11 Found Index :-1 Found Index :-1 int indexOf(int ch, int fromIndex) Description: This method has following different variants: 1 „h public int indexOf(int ch): Returns the index within this string of the first occurrence of the specified character or -1 if the character does not occur. 2 „h public int indexOf(int ch, int fromIndex): Returns the index within this string of the first occurrence of the specified character, starting the search at the specified index or -1 if the character does not occur. 1 „h int indexOf(String str): Returns the index within this string of the first occurrence of the specified substring. If it does not occur as a substring, -1 is returned. 2 „h int indexOf(String str, int fromIndex): Returns the index within this string of the first occurrence of the specified substring, starting at the specified index. If it does not occur, -1 is returned. Syntax: Here is the syntax of this method: public int indexOf(int ch ) or public int indexOf(int ch, int fromIndex) or int indexOf(String str) or int indexOf(String str, int fromIndex) Parameters: Here is the detail of parameters: 1 „h ch -- a character. 2 „h fromIndex -- the index to start the search from. 3 „h str -- a string. Return Value: 1 „h See the description. Example: import java.io.*; public class Test { public static void main(String args[]) { String Str = new String("Welcome to Tutorialspoint.com"); String SubStr1 = new String("Tutorials"); String SubStr2 = new String("Sutorials"); System.out.print("Found Index :" ); System.out.println(Str.indexOf( System.out.print("Found Index :"'o' ); )); System.out.println(Str.indexOf( 'o', 5 )); System.out.print("Found Index :" ); System.out.println( Str.indexOf( SubStr1 )); System.out.print("Found Index :" ); System.out.println( Str.indexOf( SubStr1, 15 )); System.out.print("Found Index :" ); System.out.println(Str.indexOf( SubStr2 )); } } This produces the following result: Found Index :4 Found Index :9 Found Index :11 Found Index :-1 Found Index :-1 int indexOf(String str) Description: This method has following different variants: 1 „h public int indexOf(int ch): Returns the index within this string of the first occurrence of the specified character or -1 if the character does not occur. 2 „h public int indexOf(int ch, int fromIndex): Returns the index within this string of the first occurrence of the specified character, starting the search at the specified index or -1 if the character does not occur. 3 „h int indexOf(String str): Returns the index within this string of the first occurrence of the specified substring. If it does not occur as a substring, -1 is returned. 4 „h int indexOf(String str, int fromIndex): Returns the index within this string of the first occurrence of the specified substring, starting at the specified index. If it does not occur, -1 is returned. Syntax: Here is the syntax of this method: public int indexOf(int ch ) or public int indexOf(int ch, int fromIndex) or int indexOf(String str) or int indexOf(String str, int fromIndex) Parameters: Here is the detail of parameters: 1 „h ch -- a character. 2 „h fromIndex -- the index to start the search from. 3 „h str -- a string. 1 „h SeeValue: the description. Return Example: import java.io.*; public class Test { public static void main(String args[]) { String Str = new String("Welcome to Tutorialspoint.com"); String SubStr1 = new String("Tutorials"); String SubStr2 = new String("Sutorials"); System.out.print("Found Index :" ); System.out.println(Str.indexOf( 'o' )); System.out.print("Found Index :"'o', ); 5 )); System.out.println(Str.indexOf( System.out.print("Found Index :" ); System.out.println( Str.indexOf( SubStr1 )); System.out.print("Found Index :" ); System.out.println( Str.indexOf( SubStr1, 15 )); System.out.print("Found Index :" ); System.out.println(Str.indexOf( SubStr2 )); } } This produces the following result: Found Index :4 Found Index :9 Found Index :11 Found Index :-1 Found Index :-1 int indexOf(String str, int fromIndex) Description: This method has following different variants: 1 „h public int indexOf(int ch): Returns the index within this string of the first occurrence of the specified character or -1 if the character does not occur. 2 „h public int indexOf(int ch, int fromIndex): Returns the index within this string of the first occurrence of the specified character, starting the search at the specified index or -1 if the character does not occur. 3 „h int indexOf(String str): Returns the index within this string of the first occurrence of the specified substring. If it does not occur as a substring, -1 is returned. 1 „h int indexOf(String str, int fromIndex): Returns the index within this string of the first occurrence of the specified substring, starting at the specified index. If it does not occur, -1 is returned. Syntax: Here is the syntax of this method: public int indexOf(int ch ) or public int indexOf(int ch, int fromIndex) or int indexOf(String str) or int indexOf(String str, int fromIndex) Parameters: Here is the detail of parameters: 1 „h ch -- a character. 2 „h fromIndex -- the index to start the search from. 3 „h str -- a string. Return Value: 1 „h See the description. Example: import java.io.*; public class Test { public static void main(String args[]) { String Str = new String("Welcome to Tutorialspoint.com"); String SubStr1 = new String("Tutorials"); String SubStr2 = new String("Sutorials"); System.out.print("Found Index :" ); System.out.println(Str.indexOf( 'o' )); System.out.print("Found Index :" ); System.out.println(Str.indexOf( 'o', 5 )); System.out.print("Found Index :" ); System.out.println( Str.indexOf( SubStr1 )); System.out.print("Found Index :" ); System.out.println( Str.indexOf( SubStr1, 15 )); System.out.print("Found Index :" ); System.out.println(Str.indexOf( SubStr2 )); } } This produces the following result: Found Index :4 Found Index :9 Found Index :11 Found Index :-1 Found Index :-1 String intern() Description: This method returns a canonical representation for the string object. It follows that for any two strings s and t, s.intern() == t.intern() is true if and only if s.equals(t) is true. Syntax: Here is the syntax of this method: public String intern() Parameters: Here is the detail of parameters: 1 „h NA Return Value: 1 „h This method Returns a canonical representation for the string object. Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str1 = new String("Welcome to Tutorialspoint.com"); String Str2 = new String("WELCOME TO SUTORIALSPOINT.COM"); System.out.print("Canonical representation:" ); System.out.println(Str1.intern()); System.out.print("Canonical representation:" ); System.out.println(Str2.intern()); } } This produces the following result: Canonical representation: Welcome to Tutorialspoint.com Canonical representation: WELCOME TO SUTORIALSPOINT.COM int lastIndexOf(int ch) Description: This method has the following variants: 1 „h int lastIndexOf(int ch): Returns the index within this string of the last occurrence of the specified character or -1 if the character does not occur. 2 „h public int lastIndexOf(int ch, int fromIndex): Returns the index of the last occurrence of 3 4 the character in the character sequence represented by this object that is less than or equal to fromIndex, or -1 if the character does not occur before that point. „h public int lastIndexOf(String str): If the string argument occurs one or more times as a substring within this object, then it returns the index of the first character of the last such substring is returned. If it does not occur as a substring, -1 is returned. „h public int lastIndexOf(String str, int fromIndex): Returns the index within this string of the last occurrence of the specified substring, searching backward starting at the specified index. Syntax: Here is the syntax of this method: int lastIndexOf(int ch) or public int lastIndexOf(int ch, int fromIndex) or public int lastIndexOf(String str) or public int lastIndexOf(String str, int fromIndex) Parameters: Here is the detail of parameters: 1 „h ch -- a character. 2 „h fromIndex -- the index to start the search from. 3 „h str -- A string. Return Value: 1 „h This method returns the index. Example: import java.io.*; public class Test { public static void main(String args[]) { String Str = new String("Welcome to Tutorialspoint.com"); String SubStr1 = new String("Tutorials" ); String SubStr2 = new String("Sutorials" ); System.out.print("Found Last Index :" ); System.out.println(Str.lastIndexOf( 'o' )); System.out.print("Found Last Index :" ); System.out.println(Str.lastIndexOf( 'o', 5 )); System.out.print("Found Last Index :" ); System.out.println( Str.lastIndexOf( SubStr1 )); System.out.print("Found Last Index :" ); System.out.println( Str.lastIndexOf( SubStr1, 15 )); System.out.print("Found Last Index :" ); System.out.println(Str.lastIndexOf( SubStr2 )); } } This produces the following result: Found Last Index :27 Found Last Index :4 Found Last Index :11 Found Last Index :11 Found Last Index :-1 int lastIndexOf(int ch, int fromIndex) Description: This method has the following variants: 1 „h int lastIndexOf(int ch): Returns the index within this string of the last occurrence of the specified character or -1 if the character does not occur. 2 „h public int lastIndexOf(int ch, int fromIndex): Returns the index of the last occurrence of the character in the character sequence represented by this object that is less than or equal to fromIndex, or -1 if the character does not occur before that point. 3 „h public int lastIndexOf(String str): If the string argument occurs one or more times as a substring within this object, then it returns the index of the first character of the last such substring is returned. If it does not occur as a substring, -1 is returned. 4 „h public int lastIndexOf(String str, int fromIndex): Returns the index within this string of the last occurrence of the specified substring, searching backward starting at the specified index. Syntax: Here is the syntax of this method: int lastIndexOf(int ch) or public int lastIndexOf(int ch, int fromIndex) or public int lastIndexOf(String str) or public int lastIndexOf(String str, int fromIndex) Parameters: Here is the detail of parameters: 1 „h ch -- a character. 2 „h fromIndex -- the index to start the search from. 3 „h str -- A string. Return Value: 1 „h This method returns the index. Example: import java.io.*; public class Test { public static void main(String args[]) { String Str = new String("Welcome to Tutorialspoint.com"); String SubStr1 = new String("Tutorials" ); String SubStr2 = new String("Sutorials" ); System.out.print("Found Last Index :" ); System.out.println(Str.lastIndexOf( 'o' )); System.out.print("Found Last Index :" ); System.out.println(Str.lastIndexOf( 'o', 5 )); System.out.print("Found Last Index :" ); System.out.println( Str.lastIndexOf( SubStr1 )); System.out.print("Found Last Index :" ); System.out.println( Str.lastIndexOf( SubStr1, 15 )); System.out.print("Found Last Index :" ); System.out.println(Str.lastIndexOf( SubStr2 )); } } This produces the following result: Found Found Found Found Found Last Last Last Last Last Index Index Index Index Index :27 :4 :11 :11 :-1 int lastIndexOf(String str) Description: This method has the following variants: 1 „h int lastIndexOf(int ch): Returns the index within this string of the last occurrence of the specified character or -1 if the character does not occur. 2 „h public int lastIndexOf(int ch, int fromIndex): Returns the index of the last occurrence of the character in the character sequence represented by this object that is less than or equal to fromIndex, or -1 if the character does not occur before that point. 3 „h public int lastIndexOf(String str): If the string argument occurs one or more times as a 4 substring within this object, then it returns the index of the first character of the last such substring is returned. If it does not occur as a substring, -1 is returned. „h public int lastIndexOf(String str, int fromIndex): Returns the index within this string of the last occurrence of the specified substring, searching backward starting at the specified index. Syntax: Here is the syntax of this method: int lastIndexOf(int ch) or public int lastIndexOf(int ch, int fromIndex) or public int lastIndexOf(String str) or public int lastIndexOf(String str, int fromIndex) Parameters: Here is the detail of parameters: 1 „h ch -- a character. 2 „h fromIndex -- the index to start the search from. 3 „h str -- A string. Return Value: 1 „h This method returns the index. Example: import java.io.*; public class Test { public static void main(String args[]) { String Str = new String("Welcome to Tutorialspoint.com"); String String SubStr1 SubStr2 = = new new String("Tutorials" String("Sutorials" ); ); System.out.print("Found Last Index :" ); System.out.println(Str.lastIndexOf( 'o' )); System.out.print("Found Last Index :" ); System.out.println(Str.lastIndexOf( 'o', 5 )); System.out.print("Found Last Index :" ); System.out.println( Str.lastIndexOf( SubStr1 )); System.out.print("Found Last Index :" ); System.out.println( Str.lastIndexOf( SubStr1, 15 )); System.out.print("Found Last Index :" ); System.out.println(Str.lastIndexOf( SubStr2 )); } } This produces the following result: Found Last Index :27 Found Last Index :4 Found Last Index :11 Found Last Index :11 Found Last Index :-1 int lastIndexOf(String str, int fromIndex) Description: This method has the following variants: 1 „h int lastIndexOf(int ch): Returns the index within this string of the last occurrence of the specified character or -1 if the character does not occur. 2 „h public int lastIndexOf(int ch, int fromIndex): Returns the index of the last occurrence of the character in the character sequence represented by this object that is less than or equal to fromIndex, or -1 if the character does not occur before that point. 3 „h public int lastIndexOf(String str): If the string argument occurs one or more times as a substring is within this object, then it returns index of the character of the last such substring returned. If it does not occur asthe a substring, -1first is returned. 4 „h public int lastIndexOf(String str, int fromIndex): Returns the index within this string of the last occurrence of the specified substring, searching backward starting at the specified index. Syntax: Here is the syntax of this method: int lastIndexOf(int ch) or public int lastIndexOf(int ch, int fromIndex) or public int lastIndexOf(String str) or public int lastIndexOf(String str, int fromIndex) Parameters: Here is the detail of parameters: 1 „h ch -- a character. 2 „h fromIndex -- the index to start the search from. 3 „h str -- A string. Return Value: 1 „h This method returns the index. Example: import java.io.*; public class Test { public static void main(String args[]) { String Str = new String("Welcome to Tutorialspoint.com"); String SubStr2 SubStr1 = = new new String("Sutorials" String("Tutorials" ); ); String System.out.print("Found Last Index :" ); System.out.println(Str.lastIndexOf( 'o' )); System.out.print("Found Last Index :" ); System.out.println(Str.lastIndexOf( 'o', 5 )); System.out.print("Found Last Index :" ); System.out.println( Str.lastIndexOf( SubStr1 )); System.out.print("Found Last Index :" ); System.out.println( Str.lastIndexOf( SubStr1, 15 )); System.out.print("Found Last Index :" ); System.out.println(Str.lastIndexOf( SubStr2 )); } } This produces the following result: Found Last Index :27 Found Found Found Found Last Last Last Last Index Index Index Index :4 :11 :11 :-1 int length() Description: This method returns the length of this string. The length is equal to the number of 16-bit Unicode characters in the string. Syntax: Here is the syntax of this method: public int length() Parameters: Here is the detail of parameters: 1 „h NA Return Value: 1 „h This method Returns the the length of the sequence of characters represented by this object. Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str1 = new String("Welcome to Tutorialspoint.com"); String Str2 = new String("Tutorials" ); System.out.print("String Length :" ); System.out.println(Str1.length()); System.out.print("String Length :" ); System.out.println(Str2.length()); } } This produces the following result: String Length :29 String Length :9 boolean matches(String regex) Description: This method tells whether or not this string matches the given regular expression. An invocation of this method of the form str.matches(regex) yields exactly the same result as the expression Pattern.matches(regex, str). Syntax: Here is the syntax of this method: public boolean matches(String regex) Parameters: Here1is the detail of „h regex -- parameters: the regular expression to which this string is to be matched. Return Value: 1 „h This method returns true if, and only if, this string matches the given regular expression. Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str = new String("Welcome to Tutorialspoint.com"); System.out.print("Return Value :" ); System.out.println(Str.matches("(.*)Tutorials(.*)")); System.out.print("Return Value :" ); System.out.println(Str.matches("Tutorials")); System.out.print("Return Value :" ); System.out.println(Str.matches("Welcome(.*)")); } } This produces the:true following result: Return Value Return Value :false Return Value :true boolean regionMatches(boolean ignoreCase, int toffset, String other, int ooffset, int len) Description: This method has two variants which can be used to test if two string regions are equal. Syntax: Here is the syntax of this method: public boolean regionMatches(int toffset, String other, int ooffset, int len) or public boolean regionMatches(boolean ignoreCase, int toffset, String other, int ooffset, int len) Parameters: Here is the detail of parameters: 1 2 3 4 5 „h toffset -- the starting offset of the subregion in this string. „h other -- the string argument. „h ooffset -- the starting offset of the subregion in the string argument. „h len -- the number of characters to compare. „h ignoreCase -- if true, ignore case when comparing characters. Return Value: 1 „h It returns true if the specified subregion of this string matches the specified subregion of the string argument; false otherwise. Whether the matching is exact or case insensitive depends on the ignoreCase argument. Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str1 = new String("Welcome to Tutorialspoint.com"); String Str2 = new String("Tutorials"); String Str3 = new String("TUTORIALS"); System.out.print("Return Value :" ); System.out.println(Str1.regionMatches(11, Str2, 0, 9)); System.out.print("Return Value :" ); System.out.println(Str1.regionMatches(11, Str3, 0, 9)); System.out.print("Return Value :" ); System.out.println(Str1.regionMatches(true, 11, Str3, 0, 9)); } } This produces the following result: Return Value :true Return Value :false Return Value :true boolean regionMatches(int toffset, String other, int ooffset, int len) Description: This method has two variants which can be used to test if two string regions are equal. Syntax: Here is the syntax of this method: public boolean regionMatches(int toffset, String other, int ooffset, int len) or public boolean regionMatches(boolean ignoreCase, int toffset, String other, int ooffset, int len) Parameters: Here is the detail of parameters: 1 „h toffset -- the starting offset of the subregion in this string. 2 „h other -- the string argument. 3 „h ooffset -- the starting offset of the subregion in the string argument. 4 „h len -- the number of characters to compare. 5 „h ignoreCase -- if true, ignore case when comparing characters. Return Value: 1 „h It returns true if the specified subregion of this string matches the specified subregion of the string argument; false otherwise. Whether the matching is exact or case insensitive depends on the ignoreCase argument. Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str1 = new String("Welcome to Tutorialspoint.com"); String Str2 = new String("Tutorials"); String Str3 = new String("TUTORIALS"); System.out.print("Return Value :" ); System.out.println(Str1.regionMatches(11, Str2, 0, 9)); System.out.print("Return Value :" ); System.out.println(Str1.regionMatches(11, Str3, 0, 9)); System.out.print("Return Value :" ); System.out.println(Str1.regionMatches(true, 11, Str3, 0, 9)); } } This produces the following result: Return Value :true Return Value :false Return Value :true String replace(char oldChar, char newChar) Description: This method returns a new string resulting from replacing all occurrences of oldChar in this string with newChar. Syntax: Here is the syntax of this method: public String replace(char oldChar, char newChar) Parameters: Here is the detail of parameters: 1 „h oldChar -- the old character. 2 „h newChar -- the new character. Return Value: 1 „h It returns a string derived from this string by replacing every occurrence of oldChar with newChar. Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str = new String("Welcome to Tutorialspoint.com"); System.out.print("Return Value :" ); System.out.println(Str.replace('o', 'T')); System.out.print("Return Value :" ); System.out.println(Str.replace('l', 'D')); } } This produces the following result: Return Value :WelcTme tT TutTrialspTint.cTm Return Value :WeDcome to TutoriaDspoint.com String replaceAll(String regex, String replacement) Description: This method replaces each substring of this string that matches the given regular expression with the given replacement. Syntax: Here is the syntax of this method: public String replaceAll(String regex, String replacement) Parameters: Here is the detail of parameters: 1 „h regex -- the regular expression to which this string is to be matched. 2 „h replacement -- the string which would replace found expression. Return Value: 1 „h This method returns the resulting String. Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str = new String("Welcome to Tutorialspoint.com"); System.out.print("Return Value :" ); System.out.println(Str.replaceAll("(.*)Tutorials(.*)", "AMROOD" )); } } This produces the following result: Return Value :AMROOD String replaceFirst(String regex, String replacement) Description: This method replaces the first substring of this string that matches the given regular expression with the given replacement. Syntax: Here is the syntax of this method: public String replaceFirst(String regex, String replacement) Parameters: Here is the detail of parameters: 1 „h regex -- the regular expression to which this string is to be matched. 2 „h replacement -- the string which would replace found expression. Return Value : 1 „h This method returns a resulting String. Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str = new String("Welcome to Tutorialspoint.com"); System.out.print("Return Value :" ); System.out.println(Str.replaceFirst("(.*)Tutorials(.*)", "AMROOD" )); System.out.print("Return Value :" ); System.out.println(Str.replaceFirst("Tutorials", "AMROOD" )); } } This produces the following result: Return Value :AMROOD Return Value :Welcome to AMROODpoint.com String[] split(String regex) Description: This method has two variants and splits this string around matches of the given regular expression. Syntax: Here is the syntax of this method: public String[] split(String regex, int limit) or public String[] split(String regex) Parameters: Here is the detail of parameters: 1 „h regex -- the delimiting regular expression. 2 „h limit -- the result threshold which means how many strings to be returned. Return Value: 1 „h It returns the array of strings computed by splitting this string around matches of the given regular expression. Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str = new String("Welcome-to-Tutorialspoint.com"); System.out.println("Return Value :" ); for (String retval: Str.split("-", 2)){ System.out.println(retval); } System.out.println(""); System.out.println("Return Value :"3)){ ); for (String retval: Str.split("-", System.out.println(retval); } System.out.println(""); System.out.println("Return Value :" ); for (String retval: Str.split("-", 0)){ System.out.println(retval); } System.out.println(""); System.out.println("Return Value :" ); for (String retval: Str.split("-")){ System.out.println(retval); } } } This produces the following result: Return Value : Welcome to-Tutorialspoint.com Return Value : Welcome to Tutorialspoint.com Return Value: Welcome to Tutorialspoint.com Return Value : Welcome to Tutorialspoint.com String[] split(String regex, int limit) Description: This method has two variants and splits this string around matches of the given regular expression. Syntax: Here is the syntax of this method: public String[] split(String regex, int limit) or public String[] split(String regex) Parameters: Here is the detail of parameters: 1 „h regex -- the delimiting regular expression. 2 „h limit -- the result threshold which means how many strings to be returned. Return Value: 1 „h It returns the array of strings computed by splitting this string around matches of the given regular expression. Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str = new String("Welcome-to-Tutorialspoint.com"); System.out.println("Return Value :" ); for (String retval: Str.split("-", 2)){ System.out.println(retval); } System.out.println(""); System.out.println("Return Value :" ); for (String retval: Str.split("-", 3)){ System.out.println(retval); } System.out.println(""); System.out.println("Return Value :" ); for (String retval: Str.split("-", 0)){ System.out.println(retval); } System.out.println(""); System.out.println("Return Value :" ); for (String retval: Str.split("-")){ System.out.println(retval); } } } This produces the following result: Return Value : Welcome to-Tutorialspoint.com Return Value : Welcome to Tutorialspoint.com Return Value: Welcome to Tutorialspoint.com Return Value : Welcome to Tutorialspoint.com boolean startsWith(String prefix) Description: This method has two variants and tests if a string starts with the specified prefix beginning a specified index or by default at the beginning. Syntax: Here is the syntax of this method: public boolean startsWith(String prefix, int toffset) or public boolean startsWith(String prefix) Parameters: Here is the detail of parameters: 1 „h prefix -- the prefix to be matched. 2 „h toffset -- where to begin looking in the string. Return Value: 1 „h It returns true if the character sequence represented by the argument is a prefix of the character sequence represented by this string; false otherwise. Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str = new String("Welcome to Tutorialspoint.com"); System.out.print("Return Value :" ); System.out.println(Str.startsWith("Welcome") ); System.out.print("Return Value :" ); System.out.println(Str.startsWith("Tutorials") ); System.out.print("Return Value :" ); System.out.println(Str.startsWith("Tutorials", 11) ); } } This produces the:true following result: Return Value Return Value :false Return Value :true boolean startsWith(String prefix, int toffset) Description: This method has two variants and tests if a string starts with the specified prefix beginning a specified index or by default at the beginning. Syntax: Here is the syntax of this method: public boolean startsWith(String prefix, int toffset) or public boolean startsWith(String prefix) Parameters: Here is the detail of parameters: 1 „h prefix -- the prefix to be matched. 2 „h toffset -- where to begin looking in the string. Return Value: 1 „h It returns true if the character sequence represented by the argument is a prefix of the character sequence represented by this string; false otherwise. Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str = new String("Welcome to Tutorialspoint.com"); System.out.print("Return Value :" ); System.out.println(Str.startsWith("Welcome") ); System.out.print("Return Value :" ); System.out.println(Str.startsWith("Tutorials") ); System.out.print("Return Value :" ); System.out.println(Str.startsWith("Tutorials", 11) ); } } This produces the following result: Return Value :true Return Value :false Return Value :true CharSequence subSequence(int beginIndex, int endIndex) This method returns a new character sequence that is a subsequence of this sequence. Description: Syntax: Here is the syntax of this method: public CharSequence subSequence(int beginIndex, int endIndex) Parameters: Here is the detail of parameters: 1 „h beginIndex -- the begin index, inclusive. 2 „h endIndex -- the end index, exclusive. Return Value: 1 „h This method returns the specified subsequence. Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str = new String("Welcome to Tutorialspoint.com"); System.out.print("Return Value :" ); System.out.println(Str.subSequence(0, 10) ); System.out.print("Return Value :" ); System.out.println(Str.subSequence(10, 15) ); } } This produces the following result: Return Value :Welcome to Return Value : Tuto String substring(int beginIndex) Description: This method has two variants and returns a new string that is a substring of this string. The substring begins with the character at the specified index and extends to the end of this string or up to endIndex - 1 if second argument is given. Here is the syntax of this method: Syntax: public String substring(int beginIndex) or public String substring(int beginIndex, int endIndex) Parameters: Here is the detail of parameters: 1 „h beginIndex -- the begin index, inclusive. 2 „h endIndex -- the end index, exclusive. Return Value: 1 „h The specified substring. Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str = new String("Welcome to Tutorialspoint.com"); System.out.print("Return Value :" ); System.out.println(Str.substring(10) ); System.out.print("Return Value :" ); System.out.println(Str.substring(10, 15) ); } } This produces the following result: Return Value : Tutorialspoint.com Return Value : Tuto String substring(int beginIndex, int endIndex) Description: This method has two variants and returns a new string that is a substring of this string. The substring begins with the character at the specified index and extends to the end of this string or up to endIndex - 1 if second argument is given. Syntax: Here is the syntax of this method: public String substring(int beginIndex) or public String substring(int beginIndex, int endIndex) Parameters: Here is the detail of parameters: 1 „h beginIndex -- the begin index, inclusive. 2 „h endIndex -- the end index, exclusive. Return Value: 1 „h The specified substring. Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str = new String("Welcome to Tutorialspoint.com"); System.out.print("Return Value :" ); System.out.println(Str.substring(10) ); System.out.print("Return Value :" ); System.out.println(Str.substring(10, 15) ); } } This produces the following result: Return Value : Tutorialspoint.com Return Value : Tuto char[] toCharArray() Description: This method converts this string to a new character array. Syntax: Here is the syntax of this method: public char[] toCharArray() Parameters: Here is the detail of parameters: 1 „h NA Return Value: 1 „h It returns a newly allocated character array, whose length is the length of this string and whose contents are initialized to contain the character sequence represented by this string. Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str = new String("Welcome to Tutorialspoint.com"); System.out.print("Return Value :" ); System.out.println(Str.toCharArray() ); } } This produces the following result: Return Value :Welcome to Tutorialspoint.com String toLowerCase() Description: This method has two variants. First variant converts all of the characters in this String to lower case using the rules of the given Locale. This is equivalent to calling toLowerCase(Locale.getDefault()). Second variant takes locale as an argument to be used while converting into lower case. Syntax: Here is the syntax of this method: public String toLowerCase() or public String toLowerCase(Locale locale) Parameters: Here is the detail of parameters: 1 „h NA Return Value: 1 „h It returns the String, converted to lowercase. Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str = new String("Welcome to Tutorialspoint.com"); System.out.print("Return Value :"); System.out.println(Str.toLowerCase()); } } This produces the following result: Return Value :welcome to tutorialspoint.com String toLowerCase(Locale locale) Description: This method has First This variant converts alltoofcalling the characters in this String to lower case using the rules oftwo the variants. given Locale. is equivalent toLowerCase(Locale.getDefault()). Second variant takes locale as an argument to be used while converting into lower case. Syntax: Here is the syntax of this method: public String toLowerCase() or public String toLowerCase(Locale locale) Parameters: Here is the detail of parameters: 1 „h NA Return Value: 1 „h It returns the String, converted to lowercase. Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str = new String("Welcome to Tutorialspoint.com"); System.out.print("Return Value :"); System.out.println(Str.toLowerCase()); } } This produces the following result: Return Value :welcome to tutorialspoint.com String toString() Description: This method returns itself a string Syntax: Here is the syntax of this method: public String toString() Parameters: Here is the detail of parameters: 1 „h NA Return Value: 1 „h This method returns the string itself. Example: import java.io.*; public class Test { public static void main(String args[]) { String Str = new String("Welcome to Tutorialspoint.com"); System.out.print("Return Value :"); System.out.println(Str.toString()); } } This produces the following result: Return Value :Welcome to Tutorialspoint.com String toUpperCase() Description: This method has two variants. First variant converts all of the characters in this String to upper case using the rules of the given Locale. This is equivalent to calling toUpperCase(Locale.getDefault()). Second variant takes locale as an argument to be used while converting into upper case. Syntax: Here is the syntax of this method: public String toUpperCase() or public String toUpperCase(Locale locale) Parameters: Here is the detail of parameters: 1 „h NA Return Value: 1 „h It returns the String, converted to uppercase. Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str = new String("Welcome to Tutorialspoint.com"); System.out.print("Return Value :" ); System.out.println(Str.toUpperCase() ); } } This produces the following result: Return Value :WELCOME TO TUTORIALSPOINT.COM String toUpperCase(Locale locale) Description: This method has two variants. First variant converts all of the characters in this String to upper case using the rules of the given Locale. This is equivalent to calling toUpperCase(Locale.getDefault()). Second variant takes locale as an argument to be used while converting into upper case. Syntax: Here is the syntax of this method: public String toUpperCase() or public String toUpperCase(Locale locale) Parameters: Here is the detail of parameters: 1 „h NA Return Value: 1 „h It returns the String, converted to uppercase. Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str = new String("Welcome to Tutorialspoint.com"); System.out.print("Return Value :" ); System.out.println(Str.toUpperCase() ); } } This produces the following result: Return Value :WELCOME TO TUTORIALSPOINT.COM String trim() Description: This method returns a copy of the string, with leading and trailing whitespace omitted. Syntax: Here is the syntax of this method: public String trim() Parameters: Here is the detail of parameters: 1 „h NA Return Value: 1 „h It returns a copy of this string with leading and trailing white space removed, or this string if it has no leading or trailing white space. Example: import java.io.*; public class Test{ public static void main(String args[]){ String Str = new String(" Welcome to Tutorialspoint.com "); System.out.print("Return Value :" ); System.out.println(Str.trim() ); } } This produces the:Welcome following result: Return Value to Tutorialspoint.com static String valueOf(primitive data type x) Description: This method has followings variants, which depend on the passed parameters. This method returns the string representation of the passed argument. 1 „h valueOf(boolean b): Returns the string representation of the boolean argument. 2 „h valueOf(char c): Returns the string representation of the char argument. 3 „h valueOf(char[] data): Returns the string representation of the char array argument. 4 „h valueOf(char[] data, int offset, int count): Returns the string representation of a specific subarray of the char array argument. 5 „h valueOf(double d): Returns the string representation of the double argument. 6 „h valueOf(float f): Returns the string representation of the float argument. 7 „h valueOf(int i): Returns the string representation of the int argument. 8 „h valueOf(long l): Returns the string representation of the long argument. 9 „h valueOf(Object obj): Returns the string representation of the Object argument. Syntax: Here is the syntax of this method: static String valueOf(boolean b) or static String valueOf(char c) or static String valueOf(char[] data) or static String valueOf(char[] data, int offset, int count) or static String valueOf(double d) or static String valueOf(float f) or static String valueOf(int i) or static String valueOf(long l) or static String valueOf(Object obj) Parameters: Here1is the detailthe of description. parameters: „h See Return Value : 1 „h This method returns the string representation. Example: import java.io.*; public class Test{ public static void main(String args[]){ double d = 102939939.939; boolean b = true; long l = 1232874; char[] arr = {'a', 'b', 'c', 'd', 'e', 'f','g' }; System.out.println("Return System.out.println("Return System.out.println("Return System.out.println("Return Value Value Value Value : : : : " " " " + + + + String.valueOf(d) ); String.valueOf(b) ); String.valueOf(l) ); String.valueOf(arr) ); } } This produces the following result: Return Value : 1.02939939939E8 Return Value : true Return Value : 1232874 Return Value : abcdefg Java Arrays J ava provides a data structure, the array, which stores a fixed-size sequential collection of elements of the same type. An array is used to store a collection of data, but it is often more useful to think of an array as a collection of variables of the same type. Instead of declaring individual variables, such as number0, number1, ..., and number99, you declare one array variable such as numbers and use numbers[0], numbers[1], and ..., numbers[99] to represent individual variables. This tutorial introduces how to declare array variables, create arrays, and process arrays using indexed variables. Declaring Array Variables: To use an array in a program, you must declare a variable to reference the array, and you must specify the type of array the variable can reference. Here is the syntax for declaring an array variable: dataType[] arrayRefVar;// preferred way. or dataType arrayRefVar[];// works but not preferred way. is preferred. The style dataType arrayRefVar[] comes from the Note: The style dataType[] arrayRefVar C/C++ language and was adopted in Java to accommodate C/C++ programmers. Example: The following code snippets are examples of this syntax: double[] myList;// preferred way. or double myList[];// works but not preferred way. Creating Arrays: You can create an array by using the new operator with the following syntax: arrayRefVar =new dataType[arraySize]; The above statement does two things: CHAPTER 14 1 2 „h It creates an array using new dataType[arraySize]; „h It assigns the reference of the newly created array to the variable arrayRefVar. Declaring an array variable, creating an array, and assigning the reference of the array to the variable can be combined in one statement, as shown below: dataType[] arrayRefVar =new dataType[arraySize]; Alternatively you can create arrays as follows: dataType[] arrayRefVar ={value0, value1,..., valuek}; The array elements are accessed through the index. Array indices are 0-based; that is, they start from 0 to . arrayRefVar.length-1 Example: Following statement declares an array variable, myList, creates an array of 10 elements of double type and assigns its reference to myList: double[] myList =newdouble[10]; Following picture represents array myList. Here, myList holds ten double values and the indices are from 0 to 9. Processing Arrays: When processing array elements, we often use either for loop or foreach loop because all of the elements in an array are of the same type and the size of the array is known. Example: Here is a complete example of showing how to create, initialize and process arrays: publicclassTestArray{ publicstaticvoid main(String[] args){ double[] myList ={1.9,2.9,3.4,3.5}; // Print all the array elements for(int i =0; i < myList.length; i++){ System.out.println(myList[i]+" "); } // Summing all elements double total =0; for(int i =0; i < myList.length; i++){ total += myList[i]; } System.out.println("Total is "+ total); // Finding the largest element double max = myList[0]; for(int i =1; i < myList.length; i++){ if(myList[i]> max) max = myList[i]; } System.out.println("Max is "+ max); } } This would produce the following result: 1.9 2.9 3.4 3.5 Totalis11.7 Maxis3.5 The foreach Loops: JDK 1.5 introduced a new for loop known as foreach loop or enhanced for loop, which enables you to traverse the complete array sequentially without using an index variable. Example: The following code displays all the elements in the array myList: publicclassTestArray{ publicstaticvoid main(String[] args){ double[] myList ={1.9,2.9,3.4,3.5}; // Print all the array elements for(double element: myList){ System.out.println(element); } } } This would produce the following result: 1.9 2.9 3.4 3.5 Passing Arrays to Methods: Just as you can pass primitive type values to methods, you can also pass arrays to methods. For example, the following method displays the elements in an int array: publicstaticvoid printArray(int[] array){ for(int i =0; i < array.length; i++){ System.out.print(array[i]+" "); } } You can invoke it by passing an array. For example, the following statement invokes the printArray method to display 3, 1, 2, 6, 4, and 2: printArray(newint[]{3,1,2,6,4,2}); Returning an Array from a Method: A method may also return an array. For example, the method shown below returns an array that is the reversal of another array: publicstaticint[] reverse(int[] list){ int[] result =newint[list.length]; for(int i =0, j = result.length -1; i < list.length; i++, j--){ result[j]= list[i]; } return result; } The Arrays Class: The java.util.Arrays class contains various static methods for sorting and searching arrays, comparing arrays, and filling array elements. These methods are overloaded for all primitive types. SN Methods with Description 1 public static int binarySearch(Object[] a, Object key)Searches the specified array of Object ( Byte, Int , double, etc.) for the specified value using the binary search algorithm. The array must be sorted prior to making this call. This returns index of the search key, if it is contained in the list; otherwise, (-(insertion point + 1). 2 public static boolean equals(long[] a, long[] a2) Returns true if the two specified arrays of longs are equal to one another. Two arrays are considered equal if both arrays contain the same number of elements, and all corresponding pairs of elements in the two arrays are equal. This returns true if the two arrays are equal. Same method could be used by all other primitive data types ( Byte, short, Int, etc.) 3 public static void fill(int[] a, int val) Assigns the specified int value to each element of the specified array of ints. Same method could be used by all other primitive data types ( Byte, short, Int, etc.) 4 public static void sort(Object[]Sorts a) the specified array of objects into ascending order, according to the natural ordering of its elements. Same method could be used by all other primitive data types ( Byte, short, Int, etc.) CHAPTER 15 Java Date & Time J ava provides the Date class available in java.utilpackage, this class encapsulates the current date and time. The Date class supports two constructors. The first constructor initializes the object with the current date and time. Date() The following constructor accepts one argument that equals the number of milliseconds that have elapsed since midnight, January 1, 1970 Date(long millisec) Once you have a Date object available, you can call any of the following support methods to play with dates: SN Methods with Description 1 boolean after(Date date) Returns true if the invoking Date object contains a date that is later than the one specified by date, otherwise, it returns false. 2 boolean before(Date date) Returns true if the invoking Date object contains a date that is earlier than the one specified by date, otherwise, it returns false. 3 the invoking Date Object clone( Duplicates ) object. 4 int compareTo(Date date) Compares the value of the invoking object with that of date. Returns 0 if the values are equal. Returns a negative value if the invoking object is earlier than date. Returns a positive value if the invoking object is later than date. 5 int compareTo(Object obj) Operates identically to compareTo(Date) if obj is of class Date. Otherwise, it throws a ClassCastException. 6 Returns true if the boolean equals(Object date) invoking Date object contains the same time and date as the one specified by date, otherwise, it returns false. 7 the number of long getTime( Returns ) milliseconds that have elapsed since January 1, 1970. 8 int hashCode( Returns ) a hash code for the invoking object. 9 void setTime(long time) Sets the time and date as specified by time, which represents an elapsed time in milliseconds from midnight, January 1, 1970 10 String toString( Converts ) the invoking Date object into a string and returns the result. Getting Current Date & Time This is very easy to get current date and time in Java. You can use a simple Date object with toString()method to print current date and time as follows: import java.util.Date; publicclassDateDemo{ publicstaticvoid main(String args[]){ // Instantiate a Date object Date date =newDate(); // display time and date using toString() System.out.println(date.toString()); } } This would produce the following result: MonMay0409:51:52 CDT 2009 Date Comparison: There are following three ways to compare two dates: 1 „h You can use getTime( ) to obtain the number of milliseconds that have elapsed since midnight, January 1, 1970, for both objects and then compare these two values. 2 „h You can use the methods before( ), after( ), and equals( ). Because the 12th of the month comes before the 18th, for example, new Date(99, 2, 12).before(new Date (99, 2, 18)) returns true. You can use the compareTo( ) method, which is defined by the Comparable interface and 3 „h implemented by Date. Date Formatting using SimpleDateFormat: SimpleDateFormat is a concrete class for formatting and parsing dates in a locale-sensitive manner. SimpleDateFormat allows you to start by choosing any user-defined patterns for date-time formatting. For example: import java.util.*; import java.text.*; publicclassDateDemo{ publicstaticvoid main(String args[]){ Date dNow =newDate(); SimpleDateFormat ft = newSimpleDateFormat("E yyyy.MM.dd 'at' hh:mm:ss a zzz"); System.out.println("Current Date: "+ ft.format(dNow)); } } This would produce the following result: CurrentDate:Sun2004.07.18 at 04:14:09 PM PDT Simple DateFormat format codes: To specify the time format, use a time pattern string. In this pattern, all ASCII letters are reserved as pattern letters, which are defined as the following: Character Description Example G Era designator AD y Year in four digits 2001 M Month in year July or 07 d Day in month 10 h Hour in A.M./P.M. (1~12) 12 H Hour in day (0~23) 22 m Minute in hour 30 s Second in minute 55 S Millisecond 234 E Day in week Tuesday D Day in year 360 F Day of week in month 2 (second Wed. in July) w Week in year 40 W Week in month 1 a A.M./P.M. marker PM k Hour in day (1~24) 24 K Hour in A.M./P.M. (0~11) 10 z Time zone Eastern Standard Time ' Escape for text Delimiter " Single quote ` Date Formatting using printf: Date and time formatting can be done very easily using printfmethod. You use a two-letter format, starting with t and ending in one of the letters of the table given below. For example: import java.util.Date; publicclassDateDemo{ publicstaticvoid main(String args[]){ // Instantiate a Date object Date date =newDate(); // display time and date using toString() String str =String.format("Current Date/Time : %tc", date ); System.out.printf(str); } } This would produce the following result: CurrentDate/Time:SatDec1516:37:57 MST 2012 It would be a bit silly if you had to supply the date multiple times to format each part. For that reason, a format string can indicate the index of the argument to be formatted. The index must immediately follow the % and it must be terminated by a $. For example: import java.util.Date; publicclassDateDemo{ publicstaticvoid main(String args[]){ // Instantiate a Date object Date date =newDate(); // display time and date using toString() System.out.printf("%1$s %2$tB %2$td, %2$tY", "Due date:", date); } } This would produce the following result: Due date:February09,2004 Alternatively, you can use the < flag. It indicates that the same argument as in the preceding format specification should be used again. For example: import java.util.Date; publicclassDateDemo{ publicstaticvoid main(String args[]){ // Instantiate a Date object Date date =newDate(); // display formatted date System.out.printf("%s %tB %This is actual message
", "text/html"); // Send message Transport.send(message); System.out.println("Sent message successfully...."); }catch(MessagingException mex){ mex.printStackTrace(); } } } Compile and run this program to send an HTML e-mail: $ java SendHTMLEmail Sent message successfully.... Send Attachment in E-mail: Here is an example to send an e-mail with attachment from your machine. Here, it is assumed that yourlocalhostis connected to the internet and capable enough to send an e-mail. // File Name SendFileEmail.java import import import import java.util.*; javax.mail.*; javax.mail.internet.*; javax.activation.*; publicclassSendFileEmail { publicstaticvoid main(String[] args) { // Recipient's email ID needs to be mentioned. String to ="[email protected]"; // Sender's email ID needs to be mentioned Stringfrom="[email protected]"; // Assuming you are sending email from localhost String host ="localhost"; // Get system properties Properties properties =System.getProperties(); // Setup mail server properties.setProperty("mail.smtp.host", host); // Get the default Session object. Session session =Session.getDefaultInstance(properties); try{ // Create a default MimeMessage object. MimeMessage message =newMimeMessage(session); // Set From: header field of the header. message.setFrom(newInternetAddress(from)); // Set To: header field of the header. message.addRecipient(Message.RecipientType.TO, newInternetAddress(to)); // Set Subject: header field message.setSubject("This is the Subject Line!"); // Create the message part BodyPart messageBodyPart =newMimeBodyPart(); // Fill the message messageBodyPart.setText("This is message body"); // Create a multipar message Multipart multipart =newMimeMultipart(); // Set text message part multipart.addBodyPart(messageBodyPart); // Part two is attachment messageBodyPart =newMimeBodyPart(); String filename ="file.txt"; DataSource source =newFileDataSource(filename); messageBodyPart.setDataHandler(newDataHandler(source)); messageBodyPart.setFileName(filename); multipart.addBodyPart(messageBodyPart); // Send the complete message parts message.setContent(multipart ); // Send message Transport.send(message); System.out.println("Sent message successfully...."); }catch(MessagingException mex){ mex.printStackTrace(); } } } Compile and run this program to send an HTML e-mail: $ java SendFileEmail Sent message successfully.... User Authentication Part: If it is required to provide user ID and Password to the e-mail server for authentication purpose, then you can set these properties as follows: props.setProperty("mail.user","myuser"); props.setProperty("mail.password","mypwd"); Rest of the e-mail sending mechanism would remain as explained above. Java Multithreading J ava provides built-in support for multithreaded programming. A multithreaded program contains two or more parts that can run concurrently. Each part of such a program is called a thread, and each thread defines a separate path of execution. A multithreading is a specialized form of multitasking. Multithreading requires less overhead than multitasking processing. I need to define another term related to threads: process:A process consists of the memory space allocated by the operating system that can contain one or more threads. A thread cannot exist on its own; it must be a part of a process. A process remains running until all of the non-daemon threads are done executing. Multithreading enables you to write very efficient programs that make maximum use of the CPU, because idle time can be kept to a minimum. Life Cycle of a Thread: A thread goes through various stages in its life cycle. For example, a thread is born, started, runs, and then dies. Following diagram shows complete life cycle of a thread. CHAPTER 33 Above-mentioned stages are explained here: 1 „h New: A new thread begins its life cycle in the new state. It remains in this state until the program starts the thread. It is also referred to as a born thread. 2 „h Runnable:After a newly born thread is started, the thread becomes runnable. A thread in this state is considered to be executing its task. 3 „h Waiting:Sometimes, a thread transitions to the waiting state while the thread waits for another thread to perform a task.A thread transitions back to the runnable state only when another thread signals the waiting thread to continue executing. 4 „h Timed waiting:A runnable thread can enter the timed waiting state for a specified interval of time. A thread in this state transitions back to the runnable state when that time interval expires or when the event it is waiting for occurs. 5 „h Terminated:A runnable thread enters the terminated state when it completes its task or otherwise terminates. Thread Priorities: Every Java thread has a priority that helps the operating system determine the order in which threads are scheduled. Java priorities are in the range between MIN_PRIORITY (a constant of 1) and MAX_PRIORITY (a constant of 10). By default, every thread is given priority NORM_PRIORITY (a constant of 5). Threads with higher priority are more important to a program and should be allocated processor time before lower-priority threads. However, thread priorities cannot guarantee the order in which threads execute and very much platform dependent. Creating a Thread: Java defines two ways in which this can be accomplished: 1 „h You can implement the Runnable interface. 2 „h You can extend the Thread class itself. Create Thread by Implementing Runnable: The easiest way to create a thread is to create a class that implements the Runnableinterface. To implement Runnable, a class needs to only implement a single method called run( ), which is declared like this: publicvoid run() You will define the code that constitutes the new thread inside run() method. It is important to understand that run() can call other methods, use other classes, and declare variables, just like the main thread can. After you create a class that implements Runnable, you will instantiate an object of type Thread from within that class. Thread defines several constructors. The one that we will use is shown here: Thread(Runnable threadOb,String threadName); Here, threadOb is an instance of a class that implements the Runnable interface and the name of the new thread is specified by threadName. After the new thread is created, it will not start running until you call its start( )method, which is declared within Thread. The start( ) method is shown here: void start(); Example: Here is an example that creates a new thread and starts it running: // Create a new thread. classNewThreadimplementsRunnable{ Thread t; NewThread(){ // Create a new, second thread t =newThread(this,"Demo Thread"); System.out.println("Child thread: "+ t); t.start();// Start the thread } // This is the entry point for the second thread. publicvoid run(){ try{ for(int i =5; i >0; i--){ System.out.println("Child Thread: "+ i); // Let the thread sleep for a while. Thread.sleep(500); } }catch(InterruptedException e){ System.out.println("Child interrupted."); } System.out.println("Exiting child thread."); } } publicclassThreadDemo{ publicstaticvoid main(String args[]){ newNewThread();// create a new thread try{ for(int i =5; i >0; i--){ System.out.println("Main Thread: "+ i); Thread.sleep(1000); } }catch(InterruptedException e){ System.out.println("Main thread interrupted."); } System.out.println("Main thread exiting."); } } This would produce the following result: Child thread:Thread[DemoThread,5,main] MainThread:5 ChildThread:5 ChildThread:4 MainThread:4 ChildThread:3 ChildThread:2 MainThread:3 ChildThread:1 Exiting child thread. MainThread:2 MainThread:1 Main thread exiting. Create Thread by Extending Thread: The second way to create a thread is to create a new class that extends Thread, and then to create an instance of that class. The extending class must override the run( )method, which is the entry point for the new thread. It must also call start( )to begin execution of the new thread. Example: Here is the preceding program rewritten to extend Thread: // Create a second thread by extending Thread classNewThreadextendsThread{ NewThread(){ // Create a new, second thread super("Demo Thread"); System.out.println("Child thread: "+this); start();// Start the thread } // This is the entry point for the second thread. publicvoid run(){ try{ for(int i =5; i >0; i--){ System.out.println("Child Thread: "+ i); // Let the thread sleep for a while. Thread.sleep(500); } }catch(InterruptedException e){ System.out.println("Child interrupted."); } System.out.println("Exiting child thread."); } } publicclassExtendThread{ publicstaticvoid main(String args[]){ newNewThread();// create a new thread try{ for(int i =5; i >0; i--){ System.out.println("Main Thread: "+ i); Thread.sleep(1000); } }catch(InterruptedException e){ System.out.println("Main thread interrupted."); } System.out.println("Main thread exiting."); } } This would produce the following result: Child thread:Thread[DemoThread,5,main] MainThread:5 ChildThread:5 ChildThread:4 MainThread:4 ChildThread:3 ChildThread:2 MainThread:3 ChildThread:1 Exiting child thread. MainThread:2 MainThread:1 Main thread exiting. Thread Methods: Following is the list of important methods available in the Thread class. SN Methods with Description 1 public void start() Starts the thread in a separate path of execution, then invokes the run() method on this Thread object. 2 public void run()If this Thread object was instantiated using a separate Runnable target, the run() method is invoked on that Runnable object. 3 public final void setName(String name) Changes the name of the Thread object. There is also a getName() method for retrieving the name. 4 public final void setPriority(int priority) Sets the priority of this Thread object. The possible values are between 1 and 10. 5 public final void setDaemon(boolean on) A parameter of true denotes this Thread as a daemon thread. 6 The current public final void join(long millisec) thread invokes this method on a second thread, causing the current thread to block until the second thread terminates or the specified number of milliseconds passes. 7 Interrupts this thread, public void interrupt() causing it to continue execution if it was blocked for any reason. 8 public final boolean isAlive() Returns true if the thread is alive, which is any time after the thread has been started but before it runs to completion. The previous methods are invoked on a particular Thread object. The following methods in the Thread class are static. Invoking one of the static methods performs the operation on the currently running thread. SN Methods with Description 1 public static void yield() Causes currently running thread to yield to any otherthe threads of the same priority that are waiting to be scheduled. 2 Causes public static void sleep(long millisec) the currently running thread to block for at least the specified number of milliseconds. 3 public static boolean holdsLock(Object x) Returns true if the current thread holds the lock on the given Object. 4 Returns a public static Thread currentThread() reference to the currently running thread, which is the thread that invokes this method. 5 Prints the stack public static void dumpStack() trace for the currently running thread, which is useful when debugging a multithreaded application. Example: The following ThreadClassDemo program demonstrates some of these methods of the Thread class: // Name : DisplayMessage.java // File Create a thread to implement Runnable publicclassDisplayMessageimplementsRunnable { privateString message; publicDisplayMessage(String message) { this.message = message; } publicvoid run() { while(true) { System.out.println(message); } } } // File Name : GuessANumber.java // Create a thread to extentd Thread publicclassGuessANumberextendsThread { privateint number; publicGuessANumber(int number) { this.number = number; } publicvoid run() { int counter =0; int guess =0; do { guess =(int)(Math.random()*100+1); System.out.println(this.getName() +" guessescounter++; "+ guess); }while(guess != number); System.out.println("** Correct! "+this.getName() +" in "+ counter +" guesses.**"); } } // File Name : ThreadClassDemo.java publicclassThreadClassDemo { publicstaticvoid main(String[] args) { Runnable hello =newDisplayMessage("Hello"); Thread thread1 =newThread(hello); thread1.setDaemon(true); thread1.setName("hello"); System.out.println("Starting hello thread..."); thread1.start(); Runnable bye =newDisplayMessage("Goodbye"); Thread thread2 =newThread(hello); thread2.setPriority(Thread.MIN_PRIORITY); thread2.setDaemon(true); System.out.println("Starting goodbye thread..."); thread2.start(); System.out.println("Starting thread3..."); Thread thread3 =newGuessANumber(27); thread3.start(); try { thread3.join(); }catch(InterruptedException e) { System.out.println("Thread interrupted."); } System.out.println("Starting thread4..."); Thread thread4 =newGuessANumber(75); thread4.start(); System.out.println("main() is ending..."); } } This would produce the following result. You can try this example again and again and you would get different result every time. Starting hello thread... Starting goodbye thread... Hello Hello Hello Hello Hello Hello Hello Hello Hello Thread-2 guesses 27 Hello **Correct!Thread-2in102 guesses.** Hello Starting thread4... Hello Hello ..........remaining result produced. Major Thread Concepts: While doing Multithreading programming, you would need to have the following concepts very handy: Thread Synchronization When two or more threads need access to a shared resource, they need some way to ensure that the resource will be used by only one thread at a time. The process by which this synchronization is achieved is called thread synchronization. The synchronized keyword in Java creates a block of code referred to as a critical section. Every Java object with a critical section of code gets a lock associated with the object. To enter a critical section, a thread needs to obtain the corresponding object's lock. This is the general form of the synchronized statement: synchronized(object){ // statements to be synchronized } Here, object is a reference to the object being synchronized. A synchronized block ensures that a call to a method that is a member of object occurs only after the current thread has successfully entered object's monitor. Here is an example, using a synchronized block within the run( ) method: // File Name : Callme.java // This program uses a synchronized block. classCallme{ void call(String msg){ System.out.print("["+ msg); try{ Thread.sleep(1000); }catch(InterruptedException e){ System.out.println("Interrupted"); } System.out.println("]"); } } // File Name : Caller.java classCallerimplementsRunnable{ String msg; Callme target; Thread t; publicCaller(Callme targ,String s){ target = targ; msg = s; t =newThread(this); t.start(); } // synchronize calls to call() publicvoid run(){ synchronized(target){// synchronized block target.call(msg); } } } // File Name : Synch.java publicclassSynch{ publicstaticvoid main(String args[]){ Callme target =newCallme(); Caller ob1 =newCaller(target,"Hello"); Caller ob2 =newCaller(target,"Synchronized"); Caller ob3 =newCaller(target,"World"); // wait for threads to end try{ ob1.t.join(); ob2.t.join(); ob3.t.join(); }catch(InterruptedException e){ System.out.println("Interrupted"); } } } This would produce the following result: [Hello] [World] [Synchronized] Interthread Communication Consider the classic queuing problem, where one thread is producing some data and another is consuming it. To make the problem more interesting, suppose that the producer has to wait until the consumer is finished before it generates more data. In a polling system, the consumer would waste many CPU cycles while it waited for the producer to produce. Once the producer was finished, it would start polling, wasting more CPU cycles waiting for the consumer to finish, and so on. Clearly, this situation is undesirable. To avoid polling, Java includes an elegant interprocess communication mechanism via the following methods: 1 „h wait( ):This method tells the calling thread to give up the monitor and go to sleep until some other thread enters the same monitor and calls notify( ). 1 „h notify( ):This method wakes up the first thread that called wait( ) on the same object. 2 „h notifyAll( ):This method wakes up all the threads that called wait( ) on the same object. The highest priority thread will run first. These methods are implemented as final methods in Object, so all classes have them. All three methods can be called only from within a synchronizedcontext. These methods are declared within Object. Various forms of wait( ) exist that allow you to specify a period of time to wait. Example: The following sample program consists of four classes: Q, the queue that you're trying to synchronize; Producer, the threaded object that is producing queue entries; Consumer, the threaded object that is consuming queue entries; and PC, the tiny class that creates the single Q, Producer, and Consumer. The proper way to write this program in Java is to use wait( ) and notify( ) to signal in both directions, as shown here: class Q { int n; boolean valueSet =false; synchronizedintget(){ if(!valueSet) try{ wait(); }catch(InterruptedException e){ System.out.println("InterruptedException caught"); } System.out.println("Got: "+ n); valueSet =false; notify(); return n; } synchronizedvoid put(int n){ if(valueSet) try{ wait(); }catch(InterruptedException e){ System.out.println("InterruptedException caught"); } this.n = n; valueSet =true; System.out.println("Put: "+ n); notify(); } } classProducerimplementsRunnable{ Q q; Producer(Q q){ this.q = q; newThread(this,"Producer").start(); } publicvoid run(){ int i =0; while(true){ q.put(i++); } } } classConsumerimplementsRunnable{ Q q; Consumer(Q q){ this.q = q; newThread(this,"Consumer").start(); } publicvoid run(){ while(true){ q.get(); } } } publicclassPCFixed{ publicstaticvoid main(String args[]){ Q q =new Q(); newProducer(q); newConsumer(q); System.out.println("Press Control-C to stop."); } } Inside get( ), wait( ) is called. This causes its execution to suspend until the Producer notifies you that some data is ready. When this happens, execution inside get( ) resumes. After the data has been obtained, get( ) calls notify( ). This tells Producer that it is okay to put more data in the queue. Inside put( ), wait( ) suspends execution until the Consumer has removed the item from the queue. When execution resumes, the next item of data is put in the queue, and notify( ) is called. This tells the Consumer that it should now remove it. Here is some output from this program, which shows the clean synchronous behavior: Put:1 Got:1 Put:2 Got:2 Put:3 Got:3 Put:4 Got:4 Put:5 Got:5 Thread Deadlock A special type of error that you need to avoid that relates specifically to multitasking is deadlock, which occurs when two threads have a circular dependency on a pair of synchronized objects. For example, suppose one thread enters the monitor on object X and another thread enters the monitor on object Y. If the thread in X tries to call any synchronized method on Y, it will block as expected. However, if the thread in Y, in turn, tries to call any synchronized method on X, the thread waits forever, because to access X, it would have to release its own lock on Y so that the first thread could complete. Example: To understand deadlock fully, it is useful to see it in action. The next example creates two classes, A and B, with methods foo( ) and bar( ), respectively, which pause briefly before trying to call a method in the other class. The main class, named Deadlock, creates an A and a B instance, and then starts a second thread to set up the deadlock condition. The foo( ) and bar( ) methods use sleep( ) as a way to force the deadlock condition to occur. class A { synchronizedvoid foo(B b){ String name =Thread.currentThread().getName(); System.out.println(name +" entered A.foo"); try{ Thread.sleep(1000); }catch(Exception e){ System.out.println("A Interrupted"); } System.out.println(name +" trying to call B.last()"); b.last(); } synchronizedvoidlast(){ System.out.println("Inside A.last"); } } class B { synchronizedvoid bar(A a){ String name =Thread.currentThread().getName(); System.out.println(name +" entered B.bar"); try{ Thread.sleep(1000); }catch(Exception e){ System.out.println("B Interrupted"); } System.out.println(name +" trying to call A.last()"); a.last(); } synchronizedvoidlast(){ System.out.println("Inside A.last"); } } publicclassDeadlockimplementsRunnable{ A a =new A(); B b =new B(); Deadlock(){ Thread.currentThread().setName("MainThread"); Thread t =newThread(this,"RacingThread"); t.start(); a.foo(b);// get lock on a in this thread. System.out.println("Back in main thread"); } publicvoid run(){ b.bar(a);// get lock on b in other thread. System.out.println("Back in other thread"); } publicstaticvoid main(String args[]){ newDeadlock(); } } Here is some output from this program: MainThread entered A.foo RacingThread entered B.bar MainThread trying to call B.last() RacingThread trying to call A.last() Because the program has deadlocked, you need to press CTRL-C to end the program. You can see a full thread and monitor cache dump by pressing CTRL-BREAK on a PC . You will see that RacingThread owns the monitor on b, while it is waiting for the monitor on a. At the same time, MainThread owns a and is waiting to get b. This program will never complete. As this example illustrates, if your multithreaded program locks up occasionally, deadlock is one of the first conditions that you should check for. Ordering Locks: Acommon threading trick to avoid the deadlock is to order the locks. By ordering the locks, it gives threads a specific order to obtain multiple locks. Deadlock Example: Following is the depiction of a deadlock: // File Name ThreadSafeBankAccount.java publicclassThreadSafeBankAccount { privatedouble balance; privateint number; publicThreadSafeBankAccount(int num,double initialBalance) { balance = initialBalance; number = num; } publicint getNumber() { return number; } publicdouble getBalance() { return balance; } publicvoid deposit(double amount) { synchronized(this) { double prevBalance = balance; try { Thread.sleep(4000); }catch(InterruptedException e) {} balance = prevBalance + amount; } } publicvoid withdraw(double amount) { synchronized(this) { double prevBalance = balance; try { Thread.sleep(4000); }catch(InterruptedException e) {} balance = prevBalance - amount; } } } // File Name LazyTeller.java publicclassLazyTellerextendsThread { privateThreadSafeBankAccount source, dest; publicLazyTeller(ThreadSafeBankAccount a, ThreadSafeBankAccount b) { source = a; dest = b; } publicvoid run() { transfer(250.00); } publicvoid transfer(double amount) { System.out.println("Transferring from " + source.getNumber()+" to "+ dest.getNumber()); synchronized(source) { Thread.yield(); synchronized(dest) { System.out.println("Withdrawing from " + source.getNumber()); source.withdraw(amount); System.out.println("Depositing into " + dest.getNumber()); dest.deposit(amount); } } } } publicclassDeadlockDemo { publicstaticvoid main(String[] args) { System.out.println("Creating two bank accounts..."); ThreadSafeBankAccount checking = newThreadSafeBankAccount(101,1000.00); ThreadSafeBankAccount savings = newThreadSafeBankAccount(102,5000.00); System.out.println("Creating two teller threads..."); Thread teller1 =newLazyTeller(checking, savings); Thread teller2 =newLazyTeller(savings, checking); System.out.println("Starting both threads..."); teller1.start(); teller2.start(); } } This would produce the following result: Creating two bank accounts... Creating two teller threads... Starting both threads... Transferringfrom101 to 102 Transferringfrom102 to 101 The problem with the LazyTeller class is that it does not consider the possibility of a race condition, a common occurrence in multithreaded programming. After the two threads are started, teller1 grabs the checking lock and teller2 grabs the savings lock. When teller1 tries to obtain the savings lock, it is not available. Therefore, teller1 blocks until the savings lock becomes available. When the teller1 thread blocks, teller1 still has the checking lock and does not let it go. Similarly, teller2 is waiting for the checking lock, so teller2 blocks but does not let go of the savings lock. This leads to one result: deadlock! Deadlock Solution Example: Here, transfer() method, in a class named OrderedTeller, in stead of arbitrarily synchronizing on locks, this transfer() method obtains locks in a specified order based on the number of the bank account. // File Name ThreadSafeBankAccount.java publicclassThreadSafeBankAccount { privatedouble balance; privateint number; publicThreadSafeBankAccount(int num,double initialBalance) { balance = initialBalance; number = num; } publicint getNumber() { return number; } publicdouble getBalance() { return balance; } publicvoid deposit(double amount) { synchronized(this) { double prevBalance = balance; try { Thread.sleep(4000); }catch(InterruptedException e) {} balance = prevBalance + amount; } } publicvoid withdraw(double amount) { synchronized(this) { double prevBalance = balance; try { Thread.sleep(4000); }catch(InterruptedException e) {} balance = prevBalance - amount; } } } // File Name OrderedTeller.java publicclassOrderedTellerextendsThread { privateThreadSafeBankAccount source, dest; publicOrderedTeller(ThreadSafeBankAccount a, ThreadSafeBankAccount b) { source = a; dest = b; } publicvoid run() { transfer(250.00); } publicvoid transfer(double amount) { System.out.println("Transferring from "+ source.getNumber() +" to "+ dest.getNumber()); ThreadSafeBankAccount first, second; if(source.getNumber()< dest.getNumber()) { first = source; second = dest; } else { first = dest; second = source; } synchronized(first) { Thread.yield(); synchronized(second) { System.out.println("Withdrawing from " + source.getNumber()); source.withdraw(amount); System.out.println("Depositing into " + dest.getNumber()); dest.deposit(amount); } } } } // File Name DeadlockDemo.java publicclassDeadlockDemo { publicstaticvoid main(String[] args) { System.out.println("Creating two bank accounts..."); ThreadSafeBankAccount checking = newThreadSafeBankAccount(101,1000.00); ThreadSafeBankAccount savings = newThreadSafeBankAccount(102,5000.00); System.out.println("Creating two teller threads..."); Thread teller1 =newOrderedTeller(checking, savings); Thread teller2 =newOrderedTeller(savings, checking); System.out.println("Starting both threads..."); teller1.start(); teller2.start(); } } This would remove deadlock problem and would produce the following result: Creating two bank accounts... Creating two teller threads... Starting both threads... Transferringfrom101 to 102 Transferringfrom102 to 101 Withdrawingfrom101 Depositinginto102 Withdrawingfrom102 Depositinginto101 Thread Control: Suspend, Stop and Resume While the suspend( ), resume( ), and stop( ) methods defined by Threadclass seem to be a perfectly reasonable and convenient approach to managing the execution of threads, they must not be used for new Java programs and obsolete in newer versions of Java. The following example illustrates how the wait( ) and notify( ) methods that are inherited from Object can be used to control the execution of a thread. This example is similar to the program in the previous section. However, the deprecated method calls have been removed. Let us consider the operation of this program. The NewThread class contains a boolean instance variable named suspendFlag, which is used to control the execution of the thread. It is initialized to false by the constructor. The run( ) method contains a synchronized statement block that checks suspendFlag. If that variable is true, the wait( ) method is invoked to suspend the execution of the thread. The mysuspend( ) method sets suspendFlag to true. The myresume( ) method sets suspendFlag to false and invokes notify( ) to wake up the thread. Finally, the main( ) method has been modified to invoke the mysuspend( ) and myresume( ) methods. Example: // Suspending and resuming a thread for Java 2 classNewThreadimplementsRunnable{ String name;// name of thread Thread t; boolean suspendFlag; NewThread(String threadname){ name = threadname; t =newThread(this, name); System.out.println("New thread: "+ t); suspendFlag =false; t.start();// Start the thread } // This is the entry point for thread. publicvoid run(){ try{ for(int i =15; i >0; i--){ System.out.println(name +": "+ i); Thread.sleep(200); synchronized(this){ while(suspendFlag){ wait(); } } } }catch(InterruptedException e){ System.out.println(name +" interrupted."); } System.out.println(name +" exiting."); } void mysuspend(){ suspendFlag =true; } synchronizedvoid myresume(){ suspendFlag =false; notify(); } } publicclassSuspendResume{ publicstaticvoid main(String args[]){ NewThread ob1 =newNewThread("One"); NewThread ob2 =newNewThread("Two"); try{ Thread.sleep(1000); ob1.mysuspend(); System.out.println("Suspending thread One"); Thread.sleep(1000); ob1.myresume(); System.out.println("Resuming thread One"); ob2.mysuspend(); System.out.println("Suspending thread Two"); Thread.sleep(1000); ob2.myresume(); System.out.println("Resuming thread Two"); }catch(InterruptedException e){ System.out.println("Main thread Interrupted"); } // wait for threads to finish try{ System.out.println("Waiting for threads to finish."); ob1.t.join(); ob2.t.join(); }catch(InterruptedException e){ System.out.println("Main thread Interrupted"); } System.out.println("Main thread exiting."); } } Here is the output produced by the above program: New thread:Thread[One,5,main] One:15 New thread:Thread[Two,5,main] Two:15 One:14 Two:14 One:13 Two:13 One:12 Two:12 One:11 Two:11 Suspending thread One Two:10 Two:9 Two:8 Two:7 Two:6 Resuming thread One Suspending thread Two One:10 One:9 One:8 One:7 One:6 Resuming thread Two Waitingfor threads to finish. Two:5 One:5 Two:4 One:4 Two:3 One:3 Two:2 One:2 Two:1 One:1 Two exiting. One exiting. Main thread exiting. Using Multithreading: The key to utilizing multithreading support effectively is to think concurrently rather than serially. For example, when you have two subsystems within a program that can execute concurrently, make them individual threads. With the careful use of multithreading, you can create very efficient programs. A word of caution is in order, however: If you create too many threads, you can actually degrade the performance of your program rather than enhance it. Remember, some overhead is associated with context switching. If you create too many threads, more CPU time will be spent changing contexts than executing your program! CHAPTER 34 Java Applet Basics A n applet is a Java program that runs in a Web browser. An applet can be a fully functional Java application because it has the entire Java API at its disposal. There are some important differences between an applet and a standalone Java application, including the following: 1 „h An applet is a Java class that extends the java.applet.Applet class. A main() method is not invoked on an applet, and an applet class will not define main(). 2 3 „h „h Applets are designed to be embedded within an HTML page. 4 „h When a user views an HTML page that contains an applet, the code for the applet is downloaded to the user's machine. 5 „h A JVM is required to view an applet. The JVM can be either a plug-in of the Web browser or a separate runtime environment. 6 „h The JVM on the user's machine creates an instance of the applet class and invokes various methods during the applet's lifetime. 7 „h Applets have strict security rules that are enforced by the Web browser. The security of an 8 applet is often referred to as sandbox security, comparing the applet to a child playing in a sandbox with various rules that must be followed. „h Other classes that the applet needs can be downloaded in a single Java Archive (JAR) file. Life Cycle of an Applet: Four methods in the Applet class give you the framework on which you build any serious applet: 1 „h init: This method is intended for whatever initialization is needed for your 2 applet. It is called after the param tags inside the applet tag have been processed. „h start: This method is automatically called after the browser calls the init method. It is also called whenever the user returns to the page containing the applet after having gone off to other pages. 1 „h stop: This method is automatically called when the user moves off the 2 page on which the applet sits. It can, therefore, be called repeatedly in the same applet. „h destroy: This method is only called when the browser shuts down normally. Because applets are meant to live on an HTML page, you should not normally leave resources behind after a user leaves the page that contains the applet. 3 „h paint: Invoked immediately after the start() method, and also any time the applet needs to repaint itself in the browser. The paint() method is actually inherited from the java.awt. A "Hello, World" Applet: The following is a simple applet named HelloWorldApplet.java: import java.applet.*; import java.awt.*; publicclassHelloWorldAppletextendsApplet { publicvoid paint (Graphics g) { g.drawString ("Hello World",25,50); } } These import statements bring the classes into the scope of our applet class: 1 2 „h java.applet.Applet. „h java.awt.Graphics. Without those import statements, the Java compiler would not recognize the classes Applet and Graphics, which the applet class refers to. The Applet CLASS: Every applet is an extension of the java.applet.Applet class. The base Applet class provides methods that a derived Applet class may call to obtain information and services from the browser context. These include methods that do the following: 1 „h Get applet parameters 2 3 4 5 6 7 8 „h Get the network location of the HTML file that contains the applet „h Get the network location of the applet class directory „h Print a status message in the browser „h Fetch an image „h Fetch an audio clip „h Play an audio clip „h Resize the applet Additionally, the Applet class provides an interface by which the viewer or browser obtains information about the applet and controls the applet's execution. The viewer may: 1 „h request information about the author, version and copyright of the applet 2 3 4 5 6 „h request a description of the parameters the applet recognizes „h initialize the applet „h destroy the applet „h start the applet's execution „h stop the applet's execution The Applet class provides default implementations of each of these methods. Those implementations may be overridden as necessary. The "Hello, World" applet is complete as it stands. The only method overridden is the paint method. Invoking an Applet: An applet may be invoked by embedding directives in an HTML file and viewing the file through an applet viewer or Java-enabled browser. TheBased on the above examples, here is the live applet example: Applet Example. Note: You can refer to HTML Applet Tag to understand more about calling applet from HTML. The code attribute of the tag. If an applet takes parameters, values may be passed for the parameters by adding tags between . The browser ignores text and other tags between the applet tags. Non-Java-enabled browsers do not process . Therefore, anything that appears between the tags, not related to the applet, is visible in non-Java-enabled browsers. The viewer or browser looks for the compiled Java code at the location of the document. To specify otherwise, use the codebase attribute of the
Note: Parameter names are not case sensitive. Application Conversion to Applets: It is easy to convert a graphical Java application (that is, an application that uses the AWT and that you can start with the java program launcher) into an applet that you can embed in a web page. Here are the specific steps for converting an application to an applet. 1 „h Make an HTML page with the appropriate tag to load the applet code. 2 „h Supply a subclass of the JApplet class. Make this class public. Otherwise, the applet cannot be loaded. 3 „h Eliminate the main method in the application. Do not construct a frame window for the application. Your application will be displayed inside the browser. 4 „h Move any initialization code from the frame window constructor to the init method of the applet. 5 6 7 8 You don't need to explicitly construct the applet object.the browser instantiates it for you and calls the init method. „h Remove the call to setSize; for applets, sizing is done with the width and height parameters in the HTML file. „h Remove the call to setDefaultCloseOperation. An applet cannot be closed; it terminates when the browser exits. „h If the application calls setTitle, eliminate the call to the method. Applets cannot have title bars. (You can, of course, title the web page itself, using the HTML title tag.) „h Don't call setVisible(true). The applet is displayed automatically. Event Handling: Applets inherit a group of event-handling methods from the Container class. The Container class defines several methods, such as processKeyEvent and processMouseEvent, for handling particular types of events, and then one catch-all method called processEvent. Inorder to react an event, an applet must override the appropriate event-specific method. import java.awt.event.MouseListener; import java.awt.event.MouseEvent; import java.applet.Applet; import java.awt.Graphics; publicclassExampleEventHandlingextendsApplet implementsMouseListener{ StringBuffer strBuffer; publicvoid init(){ addMouseListener(this); strBuffer =newStringBuffer(); addItem("initializing the apple "); } publicvoid start(){ addItem("starting the applet "); } publicvoid stop(){ addItem("stopping the applet "); } publicvoid destroy(){ addItem("unloading the applet"); } void addItem(String word){ System.out.println(word); strBuffer.append(word); repaint(); } publicvoid paint(Graphics g){ //Draw a Rectangle around the applet's display area. g.drawRect(0,0, getWidth()-1, getHeight()-1); //display the string inside the rectangle. g.drawString(strBuffer.toString(),10,20); } publicvoid } publicvoid } publicvoid } publicvoid } mouseEntered(MouseEventevent){ mouseExited(MouseEventevent){ mousePressed(MouseEventevent){ mouseReleased(MouseEventevent){ publicvoid mouseClicked(MouseEventevent){ addItem("mouse clicked! "); } } Now, let us call this applet as follows:
Initially, the applet will display "initializing the applet. Starting the applet." Then once you click inside the rectangle "mouse clicked" will be displayed as well. Based on the above examples, here is the live applet example: Applet Example. Displaying Images: An applet can display images of the format GIF, JPEG, BMP, and others. To display an image within the applet, you use the drawImage() method found in the java.awt.Graphics class. Following is the example showing all the steps to show images: import java.applet.*; import java.awt.*; import java.net.*; publicclassImageDemoextendsApplet { privateImage image; privateAppletContext context; publicvoid init() { context =this.getAppletContext(); String imageURL =this.getParameter("image"); if(imageURL ==null) { imageURL ="java.jpg"; } try { URL url =new URL(this.getDocumentBase(), imageURL); image = context.getImage(url); }catch(MalformedURLException e) { e.printStackTrace(); // Display in browser status bar context.showStatus("Could not load image!"); } } publicvoid paint(Graphics g) { context.showStatus("Displaying image"); g.drawImage(image,0,0,200,84,null); g.drawString("www.javalicense.com",35,100); } } Now, let us call this applet as follows:
Based on the above examples, here is the live applet example: Applet Example. Playing Audio: An applet can play an audio file represented by the AudioClip interface in the java.applet package. The AudioClip interface has three methods, including: „h public void play(): Plays the audio clip one time, from the beginning. 1 2 3 „h public void loop(): Causes the audio clip to replay continually. „h public void stop(): Stops playing the audio clip. To obtain an AudioClip object, you must invoke the getAudioClip() method of the Applet class. The getAudioClip() method returns immediately, whether or not the URL resolves to an actual audio file. The audio file is not downloaded until an attempt is made to play the audio clip. Following is the example showing all the steps to play an audio: import java.applet.*; import java.awt.*; import java.net.*; publicclassAudioDemoextendsApplet { privateAudioClip clip; privateAppletContext context; publicvoid init() { context =this.getAppletContext(); String audioURL =this.getParameter("audio"); if(audioURL ==null) { audioURL ="default.au"; } try { URL url =new URL(this.getDocumentBase(), audioURL); clip = context.getAudioClip(url); }catch(MalformedURLException e) { e.printStackTrace(); context.showStatus("Could not load audio file!"); } } publicvoid start() { if(clip !=null) { clip.loop(); } } publicvoid stop() { if(clip !=null) { clip.stop(); } } } Now, let us call this applet as follows:
You can use your test.wav at your PC to test the above example. CHAPTER 35 J Java Documentation ava supports three types of comments. The first two are the // and the /* */. The third type is called a documentation comment. It begins with the character sequence /** and it ends with */. Documentation comments allow you to embed information about your program into the program itself. You can then use the javadoc utility program to extract the information and put it into an HTML file. Documentation comments make it convenient to document your programs. The javadoc Tags: The javadoc utility recognizes the following tags: Tag Description Example @author Identifies the author of a class. @author description @deprecated Specifies that a class or member is deprecated. @deprecated description {@docRoot} Specifies the path to the root directory of the current documentation Directory Path @exception Identifies an exception thrown by a method. @exception exception-name explanation {@inheritDoc} Inherits a comment from the immediate superclass. Inherits a comment from the immediate surperclass. {@link} Inserts an in-line link to another topic. {@link name text} {@linkplain} Inserts an in-line link to another topic, but the link is displayed in a plain-text font. Inserts an in-line link to another topic. @param Documents a method's parameter. @param parameter-name explanation @return Documents a method's return value. @return explanation @see Specifies a link to another topic. @see anchor @serial Documents a default serializable field. @serial description @serialData Documents the data written by the writeObject( @serialData description ) or writeExternal( ) methods @serialField Documents an ObjectStreamField component. @serialField name type description @since States the release when a specific change was introduced. @since release @throws Same as @exception. The @throws tag has the same meaning as the @exception tag. {@value} Displays the value of a constant, which must be a static field. Displays the value of a constant, which must be a static field. @version Specifies the version of a class. @version info Documentation Comment: After the beginning /**, the first line or lines become the main description of your class, variable, or method. After that, you can include one or more of the various @ tags. Each @ tag must start at the beginning of a new line or follow an asterisk (*) that is at the start of a line. Multiple tags of the same type should be grouped together. For example, if you have three @see tags, put them one after the other. Here is an example of a documentation comment for a class: /** * This class draws a bar chart. * @author Zara Ali * @version 1.2 */ What javadoc Outputs? The javadoc program takes as input your Java program's source file and outputs several HTML files that contain the program's documentation. Information about each class will be in its own HTML file. Java utility javadocwill also output an index and a hierarchy tree. Other HTML files can be generated. Since different implementations of javadoc may work differently, you will need to check the instructions that accompany your Java development system for details specific to your version. Example: Following is a sample program that uses documentation comments. Notice the way each comment immediately precedes the item that it describes. After being processed by javadoc, the documentation about the SquareNum class will be found in SquareNum.html. import java.io.*; /** * This class demonstrates documentation comments. * @author Ayan Amhed * @version 1.2 */ publicclassSquareNum{ /** * This method returns the square of num. * This is a multiline description. You can use * as many lines as you like. * @param num The value to be squared. * @return num squared. */ publicdouble square(double num){ return num * num; } /** * This method inputs a number from the user. * @return The value input as a double. * @exception IOException On input error. * @see IOException */ publicdouble getNumber()throwsIOException{ InputStreamReader isr =newInputStreamReader(System.in); BufferedReader inData =newBufferedReader(isr); String str; str = inData.readLine(); return(newDouble(str)).doubleValue(); } /** * This method demonstrates square(). * @param args Unused. * @return Nothing. * @exception IOException On input error. * @see IOException */ publicstaticvoid main(String args[])throwsIOException { SquareNum ob =newSquareNum(); double val; System.out.println("Enter value to be squared: "); val = ob.getNumber(); val = ob.square(val); System.out.println("Squared value is "+ val); } } Now, process above SquareNum.java file using javadoc utility as follows: $ javadoc SquareNum.java Loading source file SquareNum.java... ConstructingJavadoc information... StandardDoclet version 1.5.0_13 Building tree for all the packages and classes... GeneratingSquareNum.html... SquareNum.java:39: warning -@return tag cannot be used\ in method withvoidreturn type. Generatingpackage-frame.html... Generatingpackage-summary.html... Generatingpackage-tree.html... Generating constant-values.html... Building index for all the packages and classes... Generating overview-tree.html... Generating index-all.html... Generating deprecated-list.html... Building index for all classes... Generating allclasses-frame.html... Generating allclasses-noframe.html... Generating index.html... Generating help-doc.html... Generating stylesheet.css... 1 warning $ You can check all the generated documentation here: SquareNum. CHAPTER 36 Java Library Classes T his tutorial would cover package java.lang,which provides classes that are fundamental to the design of the Java programming language. The most important classes are Object, which is the root of the class hierarchy, and Class, instances of which represent classes at run time. Here is the list of classes of ackage java.lang. These classes are very important to know for a Java programmer. Click a class link to know more detail about that class. For a further drill, you can refer standard Java documentation. SN Methods with Description 1 Boolean Boolean 2 Byte The Byte class wraps a value of primitive type byte in an object. 3 Character The Character class wraps a value of the primitive type char in an object. 4 Class Instances of the class Class represent classes and interfaces in a running Java application. 5 ClassLoader A class loader is an object that is responsible for loading classes. 6 Compiler The Compiler class is provided to support Java-to-native-code compilers and related services. 7 Double The Double class wraps a value of the primitive type double in an object. 8 Float The Float class wraps a value of primitive type float in an object. 9 Integer The Integer class wraps a value of the primitive type int in an object. 10 Long The Long class wraps a value of the primitive type long in an object. 11 Math The class Math contains methods for performing basic numeric operations such as the elementary exponential, logarithm, square root, and trigonometric functions. 12 Number The abstract class Number is the superclass of classes BigDecimal, BigInteger, Byte, Double, Float, Integer, Long, and Short. 13 Object Class Object is the root of the class hierarchy. 14 Package Package objects contain version information about the implementation and specification of a Java package. 15 Process The Runtime.exec methods create a native process and return an instance of a subclass of Process that can be used to control the process and obtain information about it. 16 Runtime Every Java application has a single instance of class Runtime that allows the application to interface with the environment in which the application is running. 17 RuntimePermission This class is for runtime permissions. 18 SecurityManager The security manager is a class that allows applications to implement a security policy. 19 Short The Short class wraps a value of primitive type short in an object. 20 StackTraceElement An element in a stack trace, as returned by Throwable.getStackTrace(). 21 StrictMath The class StrictMath contains methods for performing basic numeric operations such as the elementary exponential, logarithm, square root, and trigonometric functions. 22 String The String class represents character strings. 23 StringBuffer A string buffer implements a mutable sequence of characters. 24 System The System class contains several useful class fields and methods. 25 Thread A thread is a thread of execution in a program. 26 ThreadGroup A thread group represents a set of threads. 27 ThreadLocal This class provides thread-local variables. 28 Throwable The Throwable class is the superclass of all errors and exceptions in the Java language. 29 Void The Void class is an uninstantiable placeholder class to hold a reference to the Class object representing the Java keyword void.