In Python, with statement is used in exception handling to make the code cleaner and much more readable. It simplifies the management of common resources like file streams. Observe the following code example on how the use of with statement makes code cleaner.
Python3
# file handling # 1) without using with statement file = open ( 'file_path' , 'w' ) file .write( 'hello world !' ) file .close() # 2) without using with statement file = open ( 'file_path' , 'w' ) try : file .write( 'hello world' ) finally : file .close() |
Python3
# using with statement with open ( 'file_path' , 'w' ) as file : file .write( 'hello world !' ) |
Notice that unlike the first two implementations, there is no need to call file.close() when using with statement. The with statement itself ensures proper acquisition and release of resources. An exception during the file.write() call in the first implementation can prevent the file from closing properly which may introduce several bugs in the code, i.e. many changes in files do not go into effect until the file is properly closed. The second approach in the above example takes care of all the exceptions but using the with statement makes the code compact and much more readable. Thus, with statement helps avoiding bugs and leaks by ensuring that a resource is properly released when the code using the resource is completely executed. The with statement is popularly used with file streams, as shown above and with Locks, sockets, subprocesses and telnets etc.
Supporting the “with” statement in user defined objects
There is nothing special in open() which makes it usable with the with statement and the same functionality can be provided in user defined objects. Supporting with statement in your objects will ensure that you never leave any resource open. To use with statement in user defined objects you only need to add the methods __enter__() and __exit__() in the object methods. Consider the following example for further clarification.
Python3
# a simple file writer object class MessageWriter( object ): def __init__( self , file_name): self .file_name = file_name def __enter__( self ): self . file = open ( self .file_name, 'w' ) return self . file def __exit__( self , * args): self . file .close() # using with statement with MessageWriter with MessageWriter( 'my_file.txt' ) as xfile: xfile.write( 'hello world' ) |
Let’s examine the above code. If you notice, what follows the with keyword is the constructor of MessageWriter. As soon as the execution enters the context of the with statement a MessageWriter object is created and python then calls the __enter__() method. In this __enter__() method, initialize the resource you wish to use in the object. This __enter__() method should always return a descriptor of the acquired resource. What are resource descriptors? These are the handles provided by the operating system to access the requested resources. In the following code block, file is a descriptor of the file stream resource.
Python
file = open ( 'hello.txt' ) |
In the MessageWriter example provided above, the __enter__() method creates a file descriptor and returns it. The name xfile here is used to refer to the file descriptor returned by the __enter__() method. The block of code which uses the acquired resource is placed inside the block of the with statement. As soon as the code inside the with block is executed, the __exit__() method is called. All the acquired resources are released in the __exit__() method. This is how we use the with statement with user defined objects. This interface of __enter__() and __exit__() methods which provides the support of with statement in user defined objects is called Context Manager.
The contextlib module
A class based context manager as shown above is not the only way to support the with statement in user defined objects. The contextlib module provides a few more abstractions built upon the basic context manager interface. Here is how we can rewrite the context manager for the MessageWriter object using the contextlib module.
Python3
from contextlib import contextmanager class MessageWriter( object ): def __init__( self , filename): self .file_name = filename @contextmanager def open_file( self ): try : file = open ( self .file_name, 'w' ) yield file finally : file .close() # usage message_writer = MessageWriter( 'hello.txt' ) with message_writer.open_file() as my_file: my_file.write( 'hello world' ) |
In this code example, because of the yield statement in its definition, the function open_file() is a generator function. When this open_file() function is called, it creates a resource descriptor named file. This resource descriptor is then passed to the caller and is represented here by the variable my_file. After the code inside the with block is executed the program control returns back to the open_file() function. The open_file() function resumes its execution and executes the code following the yield statement. This part of code which appears after the yield statement releases the acquired resources. The @contextmanager here is a decorator. The previous class-based implementation and this generator-based implementation of context managers is internally the same. While the later seems more readable, it requires the knowledge of generators, decorators and yield.