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Python Exception Handling

We have explored basic python till now from Set 1 to 4 (Set 1 | Set 2 | Set 3 | Set 4). 

In this article, we will discuss how to handle exceptions in Python using try, except, and finally statements with the help of proper examples. 



Error in Python can be of two types i.e. Syntax errors and Exceptions. Errors are problems in a program due to which the program will stop the execution. On the other hand, exceptions are raised when some internal events occur which change the normal flow of the program. 

Different types of exceptions in python:

In Python, there are several built-in Python exceptions that can be raised when an error occurs during the execution of a program. Here are some of the most common types of exceptions in Python:



These are just a few examples of the many types of exceptions that can occur in Python. It’s important to handle exceptions properly in your code using try-except blocks or other error-handling techniques, in order to gracefully handle errors and prevent the program from crashing.

Difference between Syntax Error and Exceptions

Syntax Error: As the name suggests this error is caused by the wrong syntax in the code. It leads to the termination of the program. 

Example: 

There is a syntax error in the code . The if' statement should be followed by a colon (:), and the print' statement should be indented to be inside the if' block.




amount = 10000
if(amount > 2999)
print("You are eligible to purchase Dsa Self Paced")

Output:

Exceptions: Exceptions are raised when the program is syntactically correct, but the code results in an error. This error does not stop the execution of the program, however, it changes the normal flow of the program.

Example:

Here in this code a s we are dividing the ‘marks’ by zero so a error will occur known as ‘ZeroDivisionError’




marks = 10000
a = marks / 0
print(a)

Output:

In the above example raised the ZeroDivisionError as we are trying to divide a number by 0.

Note: Exception is the base class for all the exceptions in Python. You can check the exception hierarchy here.  

Example:

 1) TypeError: This exception is raised when an operation or function is applied to an object of the wrong type. Here’s an example:
 Here a ‘TypeError’ is raised as both the datatypes are different which are being added.




x = 5
y = "hello"
z = x + y

output: 
Traceback (most recent call last):
File "7edfa469-9a3c-4e4d-98f3-5544e60bff4e.py", line 4, in <module>
z = x + y
TypeError: unsupported operand type(s) for +: 'int' and 'str'

try catch block to resolve it:

The code attempts to add an integer (x') and a string (y') together, which is not a valid operation, and it will raise a TypeError'. The code used a try' and except' block to catch this exception and print an error message.




x = 5
y = "hello"
try:
    z = x + y
except TypeError:
    print("Error: cannot add an int and a str")

Output
Error: cannot add an int and a str

Try and Except Statement – Catching Exceptions

Try and except statements are used to catch and handle exceptions in Python. Statements that can raise exceptions are kept inside the try clause and the statements that handle the exception are written inside except clause.

Example: Here we are trying to access the array element whose index is out of bound and handle the corresponding exception.




a = [1, 2, 3]
try:
    print ("Second element = %d" %(a[1]))
 
    print ("Fourth element = %d" %(a[3]))
 
except:
    print ("An error occurred")

Output
Second element = 2
An error occurred

In the above example, the statements that can cause the error are placed inside the try statement (second print statement in our case). The second print statement tries to access the fourth element of the list which is not there and this throws an exception. This exception is then caught by the except statement.

Catching Specific Exception

A try statement can have more than one except clause, to specify handlers for different exceptions. Please note that at most one handler will be executed. For example, we can add IndexError in the above code. The general syntax for adding specific exceptions are – 

try:
# statement(s)
except IndexError:
# statement(s)
except ValueError:
# statement(s)

Example: Catching specific exceptions in the Python

The code defines a function fun(a)' that calculates b based on the input a. If a is less than 4, it attempts a division by zero, causing a ZeroDivisionError'. The code calls fun(3) and fun(5) inside a try-except block. It handles the ZeroDivisionError for fun(3) and prints “ZeroDivisionError Occurred and Handled.” The NameError' block is not executed since there are no NameError' exceptions in the code.




def fun(a):
    if a < 4:
 
        b = a/(a-3)
    print("Value of b = ", b)
     
try:
    fun(3)
    fun(5)
except ZeroDivisionError:
    print("ZeroDivisionError Occurred and Handled")
except NameError:
    print("NameError Occurred and Handled")

Output
ZeroDivisionError Occurred and Handled

If you comment on the line fun(3), the output will be 

NameError Occurred and Handled

The output above is so because as soon as python tries to access the value of b, NameError occurs. 

Try with Else Clause

In Python, you can also use the else clause on the try-except block which must be present after all the except clauses. The code enters the else block only if the try clause does not raise an exception.

Try with else clause

The code defines a function AbyB(a, b) that calculates c as ((a+b) / (a-b)) and handles a potential ZeroDivisionError. It prints the result if there’s no division by zero error. Calling AbyB(2.0, 3.0) calculates and prints -5.0, while calling AbyB(3.0, 3.0) attempts to divide by zero, resulting in a ZeroDivisionError, which is caught and “a/b results in 0” is printed.




def AbyB(a , b):
    try:
        c = ((a+b) / (a-b))
    except ZeroDivisionError:
        print ("a/b result in 0")
    else:
        print (c)
AbyB(2.0, 3.0)
AbyB(3.0, 3.0)

Output:

-5.0
a/b result in 0

Finally Keyword in Python

Python provides a keyword finally, which is always executed after the try and except blocks. The final block always executes after the normal termination of the try block or after the try block terminates due to some exception.

Syntax:

try:
# Some Code....

except:
# optional block
# Handling of exception (if required)

else:
# execute if no exception

finally:
# Some code .....(always executed)

Example:

The code attempts to perform integer division by zero, resulting in a ZeroDivisionError. It catches the exception and prints “Can’t divide by zero.” Regardless of the exception, the finally block is executed and prints “This is always executed.”




try:
    k = 5//0
    print(k)
 
except ZeroDivisionError:
    print("Can't divide by zero")
 
finally:
    print('This is always executed')

Output:

Can't divide by zero
This is always executed

Raising Exception

The raise statement allows the programmer to force a specific exception to occur. The sole argument in raise indicates the exception to be raised. This must be either an exception instance or an exception class (a class that derives from Exception).

This code intentionally raises a NameError with the message “Hi there” using the raise statement within a try block. Then, it catches the NameError exception, prints “An exception,” and re-raises the same exception using raise. This demonstrates how exceptions can be raised and handled in Python, allowing for custom error messages and further exception propagation.




try:
    raise NameError("Hi there")
except NameError:
    print ("An exception")
    raise

The output of the above code will simply line printed as “An exception” but a Runtime error will also occur in the last due to the raise statement in the last line. So, the output on your command line will look like 

Traceback (most recent call last):
File "/home/d6ec14ca595b97bff8d8034bbf212a9f.py", line 5, in <module>
raise NameError("Hi there") # Raise Error
NameError: Hi there

Advantages of Exception Handling:

Disadvantages of Exception Handling:

Overall, the benefits of exception handling in Python outweigh the drawbacks, but it’s important to use it judiciously and carefully in order to maintain code quality and program reliability.

This article is contributed by Nikhil Kumar Singh(nickzuck_007) 


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