CSO_Gaddis_Java_Chapter11_6ge_Ver2(1) 4.ppt

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CHAPTER
11
Exceptions
and
Advanced
File I/O

Copyright © 2016 Pearson Education, Ltd.
 Chapter Topics
Chapter 11 discusses the following main topics:
– Handling Exceptions
– Throwing Exceptions
– More about Input/Output Streams
– Advanced Topics:
Binary Files,
Random Access Files, and
Object Serialization

©2016 Pearson Education, Ltd. 11-2
 Handling Exceptions
An exception is an object that is generated as the result
of an error or an unexpected event.
Exception are said to have been “thrown.”
It is the programmers responsibility to write code that
detects and handles exceptions.
Unhandled exceptions will crash a program.
Example: BadArray.java
Java allows you to create exception handlers.

©2016 Pearson Education, Ltd. 11-3
 Example: Divide by Zero without Exception
Handling

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©2016 Pearson Education, Ltd.
 Handling Exceptions
An exception handler is a section of code that
gracefully responds to exceptions.
The process of intercepting and responding to
exceptions is called exception handling.
The default exception handler deals with
unhandled exceptions.
The default exception handler prints an error
message and crashes the program.

©2016 Pearson Education, Ltd. 11-6
 Exception Classes
An exception is an object.
Exception objects are created from classes in the
Java API hierarchy of exception classes.
All of the exception classes in the hierarchy are
derived from the Throwable class.
Error and Exception are derived from the
Throwable class.

©2016 Pearson Education, Ltd. 11-7
 Exception Classes
Classes that are derived from Error:
– are for exceptions that are thrown when critical errors
occur. (i.e.)
an internal error in the Java Virtual Machine, or
running out of memory.
Applications should not try to handle these errors
because they are the result of a serious condition.
Programmers should handle the exceptions that are
instances of classes that are derived from the
Exception class.

©2016 Pearson Education, Ltd. 11-8
 Exception Classes
Object

Throwable

Error Exception

…
… IOException RuntimeException

…

EOFException FileNotFoundException …

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 Handling Exceptions
To handle an exception, you use a try statement.

try
{
(try block statements...)
}
catch (ExceptionType ParameterName)
{
(catch block statements...)
}
First the keyword try indicates a block of code will be attempted
(the curly braces are required).
This block of code is known as a try block.

©2016 Pearson Education, Ltd. 11-10
 Handling Exceptions
A try block is:
– one or more statements that are executed, and
– can potentially throw an exception.
The application will not halt if the try block
throws an exception.
After the try block, a catch clause appears.

©2016 Pearson Education, Ltd. 11-11
 Handling Exceptions
A catch clause begins with the key word catch:

catch (ExceptionType ParameterName)

– ExceptionType is the name of an exception class and
– ParameterName is a variable name which will reference the exception
object if the code in the try block throws an exception.
The code that immediately follows the catch clause is known as
a catch block (the curly braces are required).
The code in the catch block is executed if the try block throws
an exception.

©2016 Pearson Education, Ltd. 11-12
 Handling Exceptions
This code is designed to handle a
FileNotFoundException if it is thrown.
try
{
File file = new File ("MyFile.txt");
Scanner dataInputStream = new Scanner(file);
}
catch (FileNotFoundException e)
{
System.out.println("File not found.");
}
The Java Virtual Machine searches for a catch clause that
can deal with the exception.
Example: OpenFile.java
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 Handling Exceptions
The parameter must be of a type that is compatible
with the thrown exception’s type.
After an exception, the program will continue
execution at the point just past the catch block.

©2016 Pearson Education, Ltd. 11-14
 Handling Exceptions
Each exception object has a method named
getMessage that can be used to retrieve the default
error message for the exception.
Example:
– ExceptionMessage.java
– ParseIntError.java

©2016 Pearson Education, Ltd. 11-15
©2016 Pearson Education, Ltd.
Polymorphic References To Exceptions
When handling exceptions, you can use a
polymorphic reference as a parameter in the catch
clause.
Most exceptions are derived from the Exception
class.
A catch clause that uses a parameter variable of the
Exception type is capable of catching any
exception that is derived from the Exception
class.

©2016 Pearson Education, Ltd. 11-17
Polymorphic References To Exceptions
try
{
number = Integer.parseInt(str);
}
catch (Exception e)
{
System.out.println("The following error occurred: "
+ e.getMessage());
}

The Integer class’s parseInt method throws a
NumberFormatException object.
The NumberFormatException class is derived from the
Exception class.

©2016 Pearson Education, Ltd. 11-18
 Handling Multiple Exceptions
The code in the try block may be capable of throwing more
than one type of exception.
A catch clause needs to be written for each type of exception
that could potentially be thrown.
The JVM will run the first compatible catch clause found.
The catch clauses must be listed from most specific to most
general.
Example: SalesReport.java, SalesReport2.java

©2016 Pearson Education, Ltd. 11-19
 Exception Handlers
There can be many polymorphic catch clauses.
A try statement may have only one catch clause for each specific type of
exception.
try
{
number = Integer.parseInt(str);
}
catch (NumberFormatException e)
{
System.out.println("Bad number format.");
}
catch (NumberFormatException e) // OK or ERROR!!!
{
System.out.println(str + " is not a number.");
}

©2016 Pearson Education, Ltd. 11-20
 Exception Handlers
The NumberFormatException class is derived from the
IllegalArgumentException class.
try
{
number = Integer.parseInt(str);
}
catch (IllegalArgumentException e)
{
System.out.println("Bad number format.");
}
catch (NumberFormatException e) // OK OR ERROR!!!
{
System.out.println(str + " is not a number.");
}

©2016 Pearson Education, Ltd. 11-21
 Exception Handlers
The previous code could be rewritten to work, as
follows, with no errors:
try
{
number = Integer.parseInt(str);
}
catch (NumberFormatException e)
{
System.out.println(str +
" is not a number.");
}
catch (IllegalArgumentException e) //OK OR ERROR
{
System.out.println("Bad number format.");
}

©2016 Pearson Education, Ltd. 11-22
 The finally Clause
The try statement may have an optional finally clause.
If present, the finally clause must appear after all of the
catch clauses.
try
{
(try block statements...)
}
catch (ExceptionType ParameterName)
{
(catch block statements...)
}
finally
{
(finally block statements...)
}

©2016 Pearson Education, Ltd. 11-23
 The finally Clause
The finally block is one or more statements,
– that are always executed after the try block has executed and
– after any catch blocks have executed if an exception was
thrown.
The statements in the finally block execute whether an
exception occurs or not.

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 The finally Clause

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 Trace a Program Execution (1 of 11)

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 Trace a Program Execution (2 of 11)

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 Trace a Program Execution (3 of 11)

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 Trace a Program Execution (4 of 11)

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 Trace a Program Execution (5 of 11)

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 Trace a Program Execution (6 of 11)

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 Trace a Program Execution (7 of 11)

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 Trace a Program Execution (8 of 11)

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 Trace a Program Execution (9 of 11)

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 Trace a Program Execution (10 of 11)

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 Trace a Program Execution (11 of 11)

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 The Stack Trace
The call stack is an internal list of all the methods that are
currently executing.
A stack trace is a list of all the methods in the call stack.
It indicates:
– the method that was executing when an exception occurred and
– all of the methods that were called in order to execute that method.
Example: StackTrace.java

Method A  B  C so on

©2016 Pearson Education, Ltd. 11-37
©2016 Pearson Education, Ltd.
 Multi-Catch (Java 7)
Beginning in Java 7, you can specify more than
one exception in a catch clause:
try
{
}
catch(NumberFormatException | InputMismatchException ex)
{
}

Separate the exceptions with
the | character.

©2016 Pearson Education, Ltd.
 Uncaught Exceptions
When an exception is thrown, it cannot be ignored.
It must be handled by the program, or by the default
exception handler.
When the code in a method throws an exception:
– normal execution of that method stops, and
– the JVM searches for a compatible exception handler inside
the method.

©2016 Pearson Education, Ltd. 11-40
 Uncaught Exceptions
If there is no exception handler inside the method:
– control of the program is passed to the previous method in the call
stack.
– If that method has no exception handler, then control is passed
again, up the call stack, to the previous method.
If control reaches the main method:
– the main method must either handle the exception, or
– the program is halted and the default exception handler handles the
exception.

©2016 Pearson Education, Ltd. 11-41
 Checked and Unchecked Exceptions
There are two categories of exceptions:
– unchecked
– checked.
Unchecked exceptions are those that are derived from the
Error class or the RuntimeException class.
Exceptions derived from Error are thrown when a critical
error occurs, and should not be handled.
RuntimeException serves as a superclass for exceptions
that result from programming errors.

©2016 Pearson Education, Ltd. 11-42
 Checked and Unchecked Exceptions
These exceptions can be avoided with properly written
code.
Unchecked exceptions, in most cases, should not be
handled.
All exceptions that are not derived from Error or
RuntimeException are checked exceptions.

©2016 Pearson Education, Ltd. 11-43
 Checked and Unchecked Exceptions
If the code in a method can throw a checked exception,
the method:
– must handle the exception, or
– it must have a throws clause listed in the method header.
The throws clause informs the compiler what
exceptions can be thrown from a method.

©2016 Pearson Education, Ltd. 11-44
 Checked and Unchecked Exceptions
// This method will not compile!
public void displayFile(String name)
{
// Open the file.
File file = new File(name);
Scanner dataInputStream = new Scanner(file);
// Read and display the file's contents.
while (dataInputStream.hasNext())
{
System.out.println(dataInputStream.nextLine());
}
// Close the file.
dataInputStream.close();
}

©2016 Pearson Education, Ltd. 11-45
 Throwing Exception

The code in this method is capable of throwing
checked exceptions.
The keyword throws can be written at the end of the
method header, followed by a list of the types of
exceptions that the method can throw.

public void displayFile(String name)
throws FileNotFoundException

©2016 Pearson Education, Ltd. 11-46
 Throwing Exceptions
You can write code that:
– throws one of the standard Java exceptions, or
– an instance of a custom exception class that you have designed.
The throw statement is used to manually throw an
exception.

throw new ExceptionType(MessageString);

The throw statement causes an exception object to be
created and thrown.

©2016 Pearson Education, Ltd. 11-47
 Throwing Exceptions
The MessageString argument contains a custom error
message that can be retrieved from the exception object’s
getMessage method.
If you do not pass a message to the constructor, the
exception will have a null message.

throw new Exception("Out of fuel");

– Note: Don’t confuse the throw statement with the throws
clause.
– The throw statement causes an exception to be thrown. The throws clause
informs the compiler that a method throws one or more exceptions.
Example: DiceExceptionDemo.java

©2016 Pearson Education, Ltd. 11-48
 Catch or Declare Checked Exceptions (1 of 2)

Suppose p2 is defined as follows:

void p2() throws IOException {
if (a file does not exist) {
throw new IOException("File does not exist");
}...
}

©2016 Pearson Education, Ltd.
 Catch or Declare Checked Exceptions (2 of 2)

©2016 Pearson Education, Ltd.
 Creating Exception Classes
Some examples of exceptions that can affect a bank
account:
– A negative starting balance is passed to the constructor.
– A negative interest rate is passed to the constructor.
– A negative number is passed to the deposit method.
– A negative number is passed to the withdraw method.
– The amount passed to the withdraw method exceeds the
account’s balance.
We can create exceptions that represent each of these
error conditions.

©2016 Pearson Education, Ltd. 11-51
 Creating Exception Classes
You can create your own exception classes by deriving
them from the Exception class or one of its derived
classes.
Example:
– BankAccount.java
– NegativeStartingBalance.java
– AccountTest.java

©2016 Pearson Education, Ltd. 11-52
 @exception Tag in Documentation
Comments
General format
@exception ExceptionName Description

The following rules apply
– The @exception tag in a method’s documentation comment
must appear after the general description of the method.
– The description can span several lines. It ends at the end of the
documentation comment (the */ symbol) or at the beginning of
another tag.

©2016 Pearson Education, Ltd. 11-53
 @exception Tag in Documentation
Comments

©2016 Pearson Education, Ltd. 11-54
Files
Data may be saved in a file, which is usually stored on a computer’s
disk. Once the data is saved in a file, it will remain there after the
program stops running. The data can then be retrieved and used at a
later time.
In general, there are two types of files: text and binary.
A text file contains data that has been encoded as text, using a scheme
such as Unicode.
The text file may be opened and viewed in a text editor such as
Notepad.
binary file contains data that has not been converted to text.
As a consequence, you cannot view the contents of a binary file with
a text editor.

©2016 Pearson Education, Ltd. 11-55
 Binary I/O
Text I/O requires encoding and decoding. The JVM converts a Unicode to a file
specific encoding when writing a character and coverts a file specific encoding
to a Unicode when reading a character. Binary I/O does not require conversions.
When you write a byte to a file, the original byte is copied into the file. When
you read a byte from a file, the exact byte in the file is returned.

©2016 Pearson Education, Ltd.
 Binary Files
The way data is stored in memory is sometimes called the raw
binary format.
Data can be stored in a file in its raw binary format.
A file that contains binary data is often called a binary file.
Storing data in its binary format is more efficient than storing it
as text.
There are some types of data that should only be stored in its
raw binary format. (images)

©2016 Pearson Education, Ltd. 11-57
 Binary Files
Binary files cannot be opened in a text editor such as Notepad.
To write data to a binary file you must create objects from the
following classes:
– FileOutputStream - allows you to open a file for writing binary
data. It provides only basic functionality for writing bytes to the file.
– DataOutputStream - allows you to write data of any primitive type
or String objects to a binary file. Cannot directly access a file. It is used
in conjunction with a FileOutputStream object that has a
connection to a file.

©2016 Pearson Education, Ltd. 11-58
 Binary Files
A DataOutputStream object is wrapped around a
FileOutputStream object to write data to a binary file.

FileOutputStream fileOutputStream = new
FileOutputStream("MyInfo.dat");
DataOutputStream outputDataStream = new
DataOutputStream(fileOutputStream);

If the file that you are opening with the FileOutputStream
object already exists, it will be erased and an empty file by the
same name will be created.

©2016 Pearson Education, Ltd. 11-59
 Binary Files
These statements can combined into one.

DataOutputStream outputDataStream = new
DataOutputStream(new
FileOutputStream("MyInfo.dat"));

Once the DataOutputStream object has been created,
you can use it to write binary data to the file.
Example: WriteBinaryFile.java

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©2016 Pearson Education, Ltd.
 Binary Files

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 Binary Files
To open a binary file for input, you wrap a
DataInputStream object around a FileInputStream
object.
FileInputStream fileInputStream = new
FileInputStream("MyInfo.dat");
DataInputStream dataInputStream = new
DataInputStream(fileInputStream);

These two statements can be combined into one.
DataInputStream dataInputStream = new
DataInputStream(new
FileInputStream("MyInfo.dat"));

©2016 Pearson Education, Ltd. 11-63
 Binary Files
The FileInputStream constructor will throw a
FileNotFoundException if the file named by the
string argument cannot be found.
Once the DataInputStream object has been
created, you can use it to read binary data from the file.
Example:
– ReadBinaryFile.java

©2016 Pearson Education, Ltd. 11-64
©2016 Pearson Education, Ltd.
 Writing and Reading Strings
To write a string to a binary file, use the
DataOutputStream class’s writeUTF method.
This method writes its String argument in a format
known as UTF-8 encoding.
– Just before writing the string, this method writes a two-byte
integer indicating the number of bytes that the string
occupies.
– Then, it writes the string’s characters in Unicode. (UTF
stands for Unicode Text Format.)
The DataInputStream class’s readUTF method
reads from the file.

©2016 Pearson Education, Ltd. 11-66
 Writing and Reading Strings
To write a string to a file:
String name = "Chloe";
outputDataStream.writeUTF(name);
To read a string from a file:
String name = dataInputStream.readUTF();
The readUTF method will correctly read a string only
when the string was written with the writeUTF
method.
Example:
– WriteAndReadUTF.java

©2016 Pearson Education, Ltd. 11-67
©2016 Pearson Education, Ltd.
 Appending Data to Binary Files
The FileOutputStream constructor takes an
optional second argument which must be a boolean
value.
If the argument is true, the file will not be erased if it
exists; new data will be written to the end of the file.
If the argument is false, the file will be erased if it
already exists.
FileOutputStream fileOutputStream = new
FileOutputStream("MyInfo.dat", true);
DataOutputStream outputDataStream = new
DataOutputStream(fileOutputStream);

©2016 Pearson Education, Ltd. 11-69
 Random Access Files
Text files and the binary files previously shown use sequential file access.
With sequential access:
– The first time data is read from the file, the data will be read from its beginning.
– As the reading continues, the file’s read position advances sequentially through
the file’s contents.
Sequential file access is useful in many circumstances.
If the file is very large, locating data buried deep inside it can take a long
time.

©2016 Pearson Education, Ltd. 11-70
 Random Access Files
Java allows a program to perform random file access.
In random file access, a program may immediately jump to any
location in the file.
To create and work with random access files in Java, you use the
RandomAccessFile class.

RandomAccessFile(String filename, String mode)

– filename: the name of the file.
– mode: a string indicating the mode in which you wish to use
the file.
"r" = reading
"rw" = for reading and writing.
©2016 Pearson Education, Ltd. 11-71
 Random Access Files
// Open a file for random reading.
RandomAccessFile randomFile = new
RandomAccessFile("MyData.dat", "r");
// Open a file for random reading and writing.
RandomAccessFile randomFile = new
RandomAccessFile("MyData.dat", "rw");

When opening a file in "r" mode where the file does not exist, a
FileNotFoundException will be thrown.
Opening a file in "r" mode and trying to write to it will throw an
IOException.
If you open an existing file in "rw" mode, it will not be deleted and the
file’s existing content will be preserved. Pointer will start from the
beginning.

©2016 Pearson Education, Ltd. 11-72
 Random Access Files
Items in a sequential access file are accessed one after
the other.
Items in a random access file are accessed in any order.
If you open a file in "rw" mode and the file does not
exist, it will be created.
A file that is opened or created with the
RandomAccessFile class is treated as a binary file.

©2016 Pearson Education, Ltd. 11-73
 Random Access Files
The RandomAccessFile class has:
– the same methods as the DataOutputStream class for
writing data, and
– the same methods as the DataInputStream class for
reading data.
The RandomAccessFile class can be used to
sequentially process a binary file.
Example: WriteLetters.java

©2016 Pearson Education, Ltd. 11-74
 The File Pointer
The RandomAccessFile class treats a file as a stream of
bytes.
The bytes are numbered:
– the first byte is byte 0.
– The last byte’s number is one less than the number of bytes in the file.
These byte numbers are similar to an array’s subscripts, and are
used to identify locations in the file.
Internally, the RandomAccessFile class keeps a long integer
value known as the file pointer.

©2016 Pearson Education, Ltd. 11-75
 The File Pointer
The file pointer holds the byte number of a location in
the file.
When a file is first opened, the file pointer is set to 0.
When an item is read from the file, it is read from the
byte that the file pointer points to.
Reading also causes the file pointer to advance to the
byte just beyond the item that was read.
If another item is immediately read, the reading will
begin at that point in the file.

©2016 Pearson Education, Ltd. 11-76
 The File Pointer
An EOFException is thrown when a read causes the
file pointer to go beyond the size of the file.
Writing also takes place at the location pointed to by
the file pointer.
If the file pointer points to the end of the file, data will
be written to the end of the file.
If the file pointer holds the number of a byte within the
file, at a location where data is already stored, a write
will overwrite the data at that point.

©2016 Pearson Education, Ltd. 11-77
 The File Pointer
The RandomAccessFile class lets you move the
file pointer.
This allows data to be read and written at any byte
location in the file.
The seek method is used to move the file pointer.

rndFile.seek(long position);

The argument is the number of the byte that you want
to move the file pointer to.

©2016 Pearson Education, Ltd. 11-78
 The File Pointer
RandomAccessFile file = new
RandomAccessFile("MyInfo.dat", "r");
file.seek(99);
byte b = file.readByte();

Example: ReadRandomLetters.java

©2016 Pearson Education, Ltd. 11-79
 Object Serialization
If an object contains other types of objects as fields,
saving its contents can be complicated.
Java allows you to serialize objects, which is a simpler
way of saving objects to a file.
When an object is serialized, it is converted into a series
of bytes that contain the object’s data.
If the object is set up properly, even the other objects
that it might contain as fields are automatically
serialized.
The resulting set of bytes can be saved to a file for later
retrieval.

©2016 Pearson Education, Ltd. 11-80
 Object Serialization
For an object to be serialized, its class must implement
the Serializable interface.
The Serializable interface has no methods or
fields.
It is used only to let the Java compiler know that objects
of the class might be serialized.
If a class contains objects of other classes as fields,
those classes must also implement the
Serializable interface, in order to be serialized.
Example: BankAccount2.java

©2016 Pearson Education, Ltd. 11-81
 Object Serialization
The String class, as many others in the Java API,
implements the Serializable interface.
To write a serialized object to a file, you use an
ObjectOutputStream object.
The ObjectOutputStream class is designed to perform the
serialization process.
To write the bytes to a file, an output stream object is needed.

FileOutputStream outStream = new
FileOutputStream("Objects.dat");
ObjectOutputStream objectOutputFile = new
ObjectOutputStream(outStream);

©2016 Pearson Education, Ltd. 11-82
 Object Serialization
To serialize an object and write it to the file, the
ObjectOutputStream class’s writeObject method is
used.

BankAccount2 account = new
BankAccount(“HABB999”,25000.0);
objectOutputFile.writeObject(account);

The writeObject method throws an IOException if an
error occurs.
The process of reading a serialized object’s bytes and
constructing an object from them is known as deserialization.

©2016 Pearson Education, Ltd. 11-83
 Object Serialization
To deserialize an object an ObjectInputStream object is
used in conjunction with a FileInputStream object.
FileInputStream inStream = new
FileInputStream("Objects.dat");
ObjectInputStream objectInputFile = new
ObjectInputStream(inStream);

To read a serialized object from the file, the
ObjectInputStream class’s readObject method is used.
BankAccount2 account;
account = (BankAccount2)
objectInputFile.readObject();

©2016 Pearson Education, Ltd. 11-84
 Object Serialization
The readObject method returns the deserialized
object.
– Notice that you must cast the return value to the desired class
type.
The readObject method throws a number of
different exceptions if an error occurs.
Examples:
– SerializeObjects.java
– DeserializeObjects.java

©2016 Pearson Education, Ltd. 11-85