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File handling in Java

File handling in Java . File class . The file class is used to store the path and name of a directory or file. The file object can be used to create, rename, or delete the file or directory it represents. . File Class Constructors. The File class has the following constructors -

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File handling in Java

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  1. File handling in Java

  2. File class • The file class is used to store the path and name of a directory or file. • The file object can be used to create, rename, or delete the file or directory it represents.

  3. File Class Constructors • The File class has the following constructors - • File(String pathname); // pathname could be file or a directory name • File(String dirPathname, String filename); • File(File directory, String filename); • The File class provides the getName() method which returns the name of the file excluding the directory name. • String getName();

  4. Introduction • Within computing it should be simple to do simple things. • Reading data from a file should be a simple operation; however, within Java this is not reflected in terms of simple, straightforward file I/O classes.

  5. Using the Scanner Class

  6. First Consider our leap year Program • // Second Program HelloWorld • import java.util.Scanner; • public class Leapyear { • public static void main(String args []){ • Scanner input = new Scanner( System.in ); • String theName = input.nextLine(); • int num1 = Integer.parseInt(theName); • if(num1 % 4 ==0 && (num1 % 100 != 0 ||num1 % 400 == 0)) • System.out.println("leap"); • else • System.out.println("not leap"); • }}

  7. Note • Input is gained from system.in that is the screen

  8. Example our leap year program import java.lang.*; import java.io.*; // Second Program HelloWorld import java.util.*; public class Leapyear2 { public static void main(String args []){ try { Scanner input = new Scanner( new File("fred2.txt") ); String theName = input.nextLine(); int num1 = Integer.parseInt(theName); if(num1 % 4 ==0 && (num1 % 100 != 0 ||num1 % 400 == 0)) System.out.println("leap"); else System.out.println("not leap"); }

  9. catch (Exception e) • { • System.err.println("File input error"); • } • } • }

  10. Handling Exceptions • You may be wondering what the purpose of the try { .. } catch block is. Rather than checking for erroneous return values (such as a null pointer when obtaining an output stream as is the case with C's fopen), we catch exceptions. • Exceptions are events that occur in exceptional or unusual circumstances, such as error conditions. A method can throw an exception, to indicate to the calling object that a non-standard circumstance has occurred. Thus, instead of checking each and every file method call, we have one piece of code handling all possible errors!

  11. Errors • When an error occurs within a method, the method creates an object and hands it off to the runtime system. • The object, called an exception object, contains information about the error, including its type and the state of the program when the error occurred. • Creating an exception object and handing it to the runtime system is called throwing an exception.

  12. The Call stack • After a method throws an exception, the runtime system attempts to find something to handle it. • The set of possible "somethings" to handle the exception is the ordered list of methods that had been called to get to the method where the error occurred. • The list of methods is known as the call stack

  13. Exception Handlers • The runtime system searches the call stack for a method that contains a block of code that can handle the exception. • This block of code is called an exception handler. • The exception handler chosen is said to catch the exception.

  14. If the runtime system exhaustively searches all the methods on the call stack without finding an appropriate exception handler, the runtime system (and, consequently, the program) terminates.

  15. Three Kinds of exception • Checked exceptions - Exceptional Conditions that an application should anticipate and recover from. For example a FileNotFoundException. • Errors – Exceptional Conditions external to the application for example a system malfunction. Usually cannot be anticipated • Runtime exception- Exceptions internal to the application e.g. divide by 0.

  16. Try block try { code } catch block Code is the method body that performs the functionality of your method Enclosing it in a try block throws the exception to the runtime system for catching i.e. exception handling by the catch block.

  17. Catch blocks try { } catch (ExceptionType name) { } catch (ExceptionType name) { }

  18. Catch Block • Each catch block is an exception handler and handles the type of exception indicated by its argument. • The argument type, ExceptionType, declares the type of exception that the handler can handle and must be the name of a class that inherits from the Throwable class. • The handler can refer to the exception with name.

  19. Catch Block code • The catch block contains code that is executed if and when the exception handler is invoked. • The runtime system invokes the exception handler when the handler is the first one in the call stack whose ExceptionType matches the type of the exception thrown. • The system considers it a match if the thrown object can legally be assigned to the exception handler's argument.

  20. Example try { “file handling code” } catch (FileNotFoundException e) { System.err.println("FileNotFoundException: “ + e.getMessage()); } catch (IOException e) { System.err.println("Caught IOException: " + e.getMessage());}

  21. Streams • Java 1.0 used 8-bit input and output streams, however, this did not support internationalised character sets (e.g. Chinese, etc.). • Java 1.1 tried to correct this problem by introducing corresponding 16-bit I/O streams. • However, the correction was not complete, and 8-bit streams are still used for binary I/O, keyboard I/O, etc. • A large number of I/O classes are provided, to the extent where it can be confusing to know what particular type of I/O class should be used.

  22. Data Streams • A disk based file is one possible source, or sink, for data. • However, data may also be gathered from other sources, e.g. a keyboard, network connection, etc. • Java employs the notion of a stream as an higher level abstraction for all possible data sources. • Hence, in Java, a stream might be receiving bytes from (or sending them to) a file, a String object, a network socket, the keyboard, etc. • Fundamentally, a stream is a flow of data, never mind where it comes from or goes to.

  23. Manipulating Streams • Functionally, data can be added to, or plucked from a stream. • Java 1.0 made use of 8-bit streams; however, this was not adequate when dealing with external character sets, e.g. Unicode. • To overcome this, Java1.1 introduced 16-bit Reader and Writer classes intended for all character I/O.

  24. Each streams offers one type of I/O service (e.g. character I/O, binary I/O,byte array I/O, file I/O, etc.). • It is intended that the programmer connect several streams to get the exact type of processing required. • I/O streams can be easily connected to one another by passing one stream as an argument to the other streams constructor, e.g.: BufferedReader file = new BufferedReader( new FileReader( selectedFile ) );

  25. Java provides a useful input stream known as DataInputStream, which offers methods for reading characters, integers, floats, etc. • However, only one constructor is defined for the class: java.io.DataInputStream( java.io.InputStream ). • Given this, how can a DataInputStream be used to read information from a disk file? • Within Java, streams are designed to be layered on top of each other, entailing that the programmer must connect together several (usually two) streams to get the exact type of required functionality.

  26. Hence, in order to read data from a diskfile we firstly need to use the FileInputStream, which possesses the following constructor • FileInputStream( String filename ), i.e. permitting a stream to be opened to a specified disk file.

  27. Making a stream connection • Using a FileInputStream a stream connection can be made to a disk file. • However, the FileInputStream only provides methods for reading byte arrays from the disk file. In order to read integers, floats, etc. it is necessary to append a DataInputStream onto the FileInputStream, e.g. • FileInputStream fileStream = new FileInputStream( “file.dat” ); • DataInputStream dataStream = new DataInputStream( fileStream ); • or simply just: • DataInputStream dataStream = new DataInputStream( new FileInputStream( “file.dat” ) );

  28. java.io package • Classes related to input and output are present in the JavaTM language package java.io . • Java technology uses "streams" as a general mechanism of handling data. • Input streams act as a source of data. • Output streams act as a destination of data.

  29. Byte Streams • The package java.io provides two set of class hierarchies - one for handling reading and writing of bytes, and another for handling reading and writing of characters. • The abstract classes InputStream and OutputStream are the root of inheritance hierarchies handling reading and writing of bytes respectively.

  30. public abstract class InputStream • This abstract class is the superclass of all classes representing an input stream of bytes. • Applications that need to define a direct subclass of InputStream must always provide a method • that returns the next byte of input.

  31. Figure : InputStream class hierarchy (partial)

  32. Methods on Input Stream

  33. JDK classes • JDK classes that extend the InputStream class include: • • BufferedInputStream • • ByteArrayInputStream • • DataInputStream • • FilterInputStream • • PushbackInputStream

  34. public abstract class OutputStream • This abstract class is the superclass of all classes representing an output stream of bytes. An output stream accepts output bytes and sends them to some sink. • Applications that need to define a subclass of OutputStream must always provide at least a method that writes one byte of output.

  35. Figure : OutputStream class hierarchy (partial)

  36. OutputStream methods

  37. Subclasses of OutputStream • Classes that extend OutputStream include: • • BufferedOutputStream • • ByteArrayOutputStream • • DataOutputStream • • FilterOutputStream

  38. FileOutputStream • The FileOutputStream is an output stream for • writing data to a File object or to a suitable file • descriptor. • The FileOutputStream class provides constructors that accept either a reference to a File object (explored later) or alternatively a String object referring to the name of the file that should be opened. • Methods are provided for writing out various byte structures to the disk file (either the entire array can be written, or a specific subsection). • The close method is used to close the file once no more output is needed.

  39. The FileInputStream interface is similar to that of the FileOutputStream: • The constructors and read methods are simply counterparts to those found in FileOutputStream • However, the FileInputStream defines the skip(long n) method which permits a certain number of bytes in the file to be ‘jumped’ over.

  40. Data Streams • Normally the DataOutputStream and DataInputStream classes are used to further extend the capabilities of the file classes, and are explored next.

  41. Data Output Stream • DataOutputStream extends the basic functionality of the OutputStream class, as follows: • As before functions are included for writing out arrays of bytes, but now, methods are provided for writing out characters (individually or as an array), numbers (integers, floating point, short ints), etc. • The writeUTF( String str ) method is deserved of special mention. The method is intended to write out an unformatted text field. This method is often employed when writing character data to a file. • The flush() method is used to write any buffered output to the file, useful to guarantee that all information is correctly saved.

  42. public class java.io.DataOutputStream • { • public DataOutputStream( OutputStream out ); • public void flush(); • public void write( byte b[], int off, int len); • public final void writeBoolean( bollean v ); • public final void writeByte( int v ); • public final void writeBytes( String s ); • public final void writeChar( int v ); • public final void writeChars( String s ); • public final void writeDouble( double v ); • public final void writeFloat( float v ); • public final void writeInt( int v ); • public final void writeLong( long v ); • public final void writeShort( int v ); • public final void writeUTF( String str ); • }

  43. DataInputStream • This class is a counterpart to DataOutputStream, offering corresponding functionality except dealing with input from a file. Methods follow:

  44. public class java.io.DataInputStream • { • public DataInputStream( InputStream out ); • public final int read( byte b[] ); • public final boolean readBoolean(); • public final byte readByte(); • public final char readChar(); • public final double readDouble(); • public final float readFloat(); • public final int readInt(); • public final String readLine(); • public final long readLong(); • public final short readShort(); • public final String readUTF(); • public final int skipBytes( int n ); • }

  45. read and write methods • InputStream class defines the following methods for reading bytes - • int read() throws IOException • int read(byte b[]) throws IOException • int read(byte b[], int offset, int length) throws IOException • Subclasses of InputStream implement the above mentioned method

  46. Write methods • OutputStream class defines the following methods for writing bytes - • void write(int b) throws IOException • void write(byte b[]) throws IOException • void write(byte b[], int offset, int length) throws IOException • Subclasses of OutputStream implement the above mentioned methods.

  47. The example below illustrates code to read a character. • First create an object of type FileInputStream type using the name of the file. FileInputStream inp = new FileInputStream("filename.ext"); • //Create an object of type DataInputStream using inp. • DataInputStream dataInp = new DataInputStream(inp); • int i = dataInp.readInt();

  48. Adapting our leap year example • import java.lang.*; • import java.io.*; • // Second Program HelloWorld • import java.util.*; • public class Leapyear3 { • public static void main(String args []){ • try • { • FileInputStream inp = new FileInputStream("fred2.txt");

  49. //Create an object of type DataInputStream using inp. • DataInputStream dataInp = new DataInputStream(inp); • int num1 = dataInp.readInt(); • //Scanner input = new Scanner( new File("fred2.txt") ); • //String theName = input.nextLine(); • //int num1 = Integer.parseInt(theName); • if(num1 % 4 ==0 && (num1 % 100 != 0 ||num1 % 400 == 0)) • System.out.println("leap"); • else • System.out.println("not leap"); • } • catch (Exception e) • { • System.err.println("File input error"); • } • } • }

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