So far, we have learned how to write programs and communicate our intentions to the Central Processing Unit using conditional execution, functions, and iterations. We have learned how to create and use data structures in the Main Memory. The CPU and memory are where our software works and runs. It is where all of the “thinking” happens.
But if you recall from our hardware architecture discussions, once the power is turned off, anything stored in either the CPU or main memory is erased. So up to now, our programs have just been transient fun exercises to learn Python.
In this chapter, we start to work with Secondary Memory (or files). Secondary memory is not erased even when the power is turned off. Or in the case of a USB flash drive, the data we write from our programs can be removed from the system and transported to another system.
We will primarily focus on reading and writing text files such as those we create in a text editor. Later we will see how to work with database files which are binary files, specifically designed to be read and written through database software.
When we want to read or write a file (say on your hard drive), we first must open the file. Opening the file communicates with your operating system, which knows where the data for each file is stored. When you open a file, you are asking the operating system to find the file by name and make sure the file exists. In this example, we open the file mbox.txt, which should be stored in the same folder that you are in when you start Python. You can download this file from www.py4inf.com/code/mbox.txt
>>> fhand = open('mbox.txt') >>> print fhand <open file 'mbox.txt', mode 'r' at 0x1005088b0>
If the open is successful, the operating system returns us a file handle. The file handle is not the actual data contained in the file, but instead it is a “handle” that we can use to read the data. You are given a handle if the requested file exists and you have the proper permissions to read the file.
If the file does not exist, open will fail with a traceback and you will not get a handle to access the contents of the file:
>>> fhand = open('stuff.txt') Traceback (most recent call last): File "<stdin>", line 1, in <module> IOError: [Errno 2] No such file or directory: 'stuff.txt'
Later we will use try and except to deal more gracefully with the situation where we attempt to open a file that does not exist.
A text file can be thought of as a sequence of lines, much like a Python string can be thought of as a sequence of characters. For example, this is a sample of a text file which records mail activity from various individuals in an open source project development team:
From [email protected] Sat Jan 5 09:14:16 2008 Return-Path: <[email protected]> Date: Sat, 5 Jan 2008 09:12:18 -0500 To: [email protected] From: [email protected] Subject: [sakai] svn commit: r39772 - content/branches/ Details: http://source.sakaiproject.org/viewsvn/?view=rev&rev=39772 ...
The entire file of mail interactions is available from www.py4inf.com/code/mbox.txt and a shortened version of the file is available from www.py4inf.com/code/mbox-short.txt. These files are in a standard format for a file containing multiple mail messages. The lines which start with “From ” separate the messages and the lines which start with “From:” are part of the messages. For more information about the mbox format, see en.wikipedia.org/wiki/Mbox.
To break the file into lines, there is a special character that represents the “end of the line” called the newline character.
In Python, we represent the newline character as a backslash-n in
string constants. Even though this looks like two characters, it
is actually a single character. When we look at the variable by entering
“stuff” in the interpreter, it shows us the
\n in the string,
but when we use print to show the string, we see the string broken
into two lines by the newline character.
>>> stuff = 'Hello\nWorld!' >>> stuff 'Hello\nWorld!' >>> print stuff Hello World! >>> stuff = 'X\nY' >>> print stuff X Y >>> len(stuff) 3
You can also see that the length of the string
'X\nY' is three
characters because the newline character is a single character.
So when we look at the lines in a file, we need to imagine that there is a special invisible character called the newline at the end of each line that marks the end of the line.
So the newline character separates the characters in the file into lines.
While the file handle does not contain the data for the file, it is quite easy to construct a for loop to read through and count each of the lines in a file:
fhand = open('mbox.txt') count = 0 for line in fhand: count = count + 1 print 'Line Count:', count python open.py Line Count: 132045
We can use the file handle as the sequence in our for loop. Our for loop simply counts the number of lines in the file and prints them out. The rough translation of the for loop into English is, “for each line in the file represented by the file handle, add one to the count variable.”
The reason that the open function does not read the entire file is that the file might be quite large with many gigabytes of data. The open statement takes the same amount of time regardless of the size of the file. The for loop actually causes the data to be read from the file.
When the file is read using a for loop in this manner, Python takes care of splitting the data in the file into separate lines using the newline character. Python reads each line through the newline and includes the newline as the last character in the line variable for each iteration of the for loop.
Because the for loop reads the data one line at a time, it can efficiently read and count the lines in very large files without running out of main memory to store the data. The above program can count the lines in any size file using very little memory since each line is read, counted, and then discarded.
If you know the file is relatively small compared to the size of your main memory, you can read the whole file into one string using the read method on the file handle.
>>> fhand = open('mbox-short.txt') >>> inp = fhand.read() >>> print len(inp) 94626 >>> print inp[:20] From stephen.marquar
In this example, the entire contents (all 94,626 characters) of the file mbox-short.txt are read directly into the variable inp. We use string slicing to print out the first 20 characters of the string data stored in inp.
When the file is read in this manner, all the characters including all of the lines and newline characters are one big string in the variable inp. Remember that this form of the open function should only be used if the file data will fit comfortably in the main memory of your computer.
If the file is too large to fit in main memory, you should write your program to read the file in chunks using a for or while loop.
When you are searching through data in a file, it is a very common pattern to read through a file, ignoring most of the lines and only processing lines which meet a particular condition. We can combine the pattern for reading a file with string methods to build simple search mechanisms.
For example, if we wanted to read a file and only print out lines which started with the prefix “From:”, we could use the string method startswith to select only those lines with the desired prefix:
fhand = open('mbox-short.txt') for line in fhand: if line.startswith('From:') : print line
When this program runs, we get the following output:
From: [email protected] From: [email protected] From: [email protected] From: [email protected] ...
The output looks great since the only lines we are seeing are those which start with “From:”, but why are we seeing the extra blank lines? This is due to that invisible newline character. Each of the lines ends with a newline, so the print statement prints the string in the variable line which includes a newline and then print adds another newline, resulting in the double spacing effect we see.
We could use line slicing to print all but the last character, but a simpler approach is to use the rstrip method which strips whitespace from the right side of a string as follows:
fhand = open('mbox-short.txt') for line in fhand: line = line.rstrip() if line.startswith('From:') : print line
When this program runs, we get the following output:
From: [email protected] From: [email protected] From: [email protected] From: [email protected] From: [email protected] From: [email protected] From: [email protected] ...
As your file processing programs get more complicated, you may want to structure your search loops using continue. The basic idea of the search loop is that you are looking for “interesting” lines and effectively skipping “uninteresting” lines. And then when we find an interesting line, we do something with that line.
We can structure the loop to follow the pattern of skipping uninteresting lines as follows:
fhand = open('mbox-short.txt') for line in fhand: line = line.rstrip() # Skip 'uninteresting lines' if not line.startswith('From:') : continue # Process our 'interesting' line print line
The output of the program is the same. In English, the uninteresting lines are those which do not start with “From:”, which we skip using continue. For the “interesting” lines (i.e., those that start with “From:”) we perform the processing on those lines.
We can use the find string method to simulate a text editor search that finds lines where the search string is anywhere in the line. Since find looks for an occurrence of a string within another string and either returns the position of the string or -1 if the string was not found, we can write the following loop to show lines which contain the string “@uct.ac.za” (i.e., they come from the University of Cape Town in South Africa):
fhand = open('mbox-short.txt') for line in fhand: line = line.rstrip() if line.find('@uct.ac.za') == -1 : continue print line
Which produces the following output:
From [email protected] Sat Jan 5 09:14:16 2008 X-Authentication-Warning: set sender to [email protected] using -f From: [email protected] Author: [email protected] From [email protected] Fri Jan 4 07:02:32 2008 X-Authentication-Warning: set sender to [email protected] using -f From: [email protected] Author: [email protected] ...
We really do not want to have to edit our Python code every time we want to process a different file. It would be more usable to ask the user to enter the file name string each time the program runs so they can use our program on different files without changing the Python code.
This is quite simple to do by reading the file name from
the user using
raw_input as follows:
fname = raw_input('Enter the file name: ') fhand = open(fname) count = 0 for line in fhand: if line.startswith('Subject:') : count = count + 1 print 'There were', count, 'subject lines in', fname
We read the file name from the user and place it in a variable named fname and open that file. Now we can run the program repeatedly on different files.
python search6.py Enter the file name: mbox.txt There were 1797 subject lines in mbox.txt python search6.py Enter the file name: mbox-short.txt There were 27 subject lines in mbox-short.txt
Before peeking at the next section, take a look at the above program and ask yourself, “What could go possibly wrong here?” or “What might our friendly user do that would cause our nice little program to ungracefully exit with a traceback, making us look not-so-cool in the eyes of our users?”
I told you not to peek. This is your last chance.
What if our user types something that is not a file name?
python search6.py Enter the file name: missing.txt Traceback (most recent call last): File "search6.py", line 2, in <module> fhand = open(fname) IOError: [Errno 2] No such file or directory: 'missing.txt' python search6.py Enter the file name: na na boo boo Traceback (most recent call last): File "search6.py", line 2, in <module> fhand = open(fname) IOError: [Errno 2] No such file or directory: 'na na boo boo'
Do not laugh, users will eventually do every possible thing they can do to break your programs—either on purpose or with malicious intent. As a matter of fact, an important part of any software development team is a person or group called Quality Assurance (or QA for short) whose very job it is to do the craziest things possible in an attempt to break the software that the programmer has created.
The QA team is responsible for finding the flaws in programs before we have delivered the program to the end users who may be purchasing the software or paying our salary to write the software. So the QA team is the programmer’s best friend.
So now that we see the flaw in the program, we can elegantly fix it using the try/except structure. We need to assume that the open call might fail and add recovery code when the open fails as follows:
fname = raw_input('Enter the file name: ') try: fhand = open(fname) except: print 'File cannot be opened:', fname exit() count = 0 for line in fhand: if line.startswith('Subject:') : count = count + 1 print 'There were', count, 'subject lines in', fname
The exit function terminates the program. It is a function that we call that never returns. Now when our user (or QA team) types in silliness or bad file names, we “catch” them and recover gracefully:
python search7.py Enter the file name: mbox.txt There were 1797 subject lines in mbox.txt python search7.py Enter the file name: na na boo boo File cannot be opened: na na boo boo
Protecting the open call is a good example of the proper use of try and except in a Python program. We use the term “Pythonic” when we are doing something the “Python way”. We might say that the above example is the Pythonic way to open a file.
Once you become more skilled in Python, you can engage in repartee with other Python programmers to decide which of two equivalent solutions to a problem is “more Pythonic”. The goal to be “more Pythonic” captures the notion that programming is part engineering and part art. We are not always interested in just making something work, we also want our solution to be elegant and to be appreciated as elegant by our peers.
To write a file, you have to open it with mode
'w' as a second parameter:
>>> fout = open('output.txt', 'w') >>> print fout <open file 'output.txt', mode 'w' at 0xb7eb2410>
If the file already exists, opening it in write mode clears out the old data and starts fresh, so be careful! If the file doesn’t exist, a new one is created.
The write method of the file handle object puts data into the file.
>>> line1 = "This here's the wattle,\n" >>> fout.write(line1)
Again, the file object keeps track of where it is, so if you call write again, it adds the new data to the end.
We must make sure to manage the ends of lines as we write to the file by explicitly inserting the newline character when we want to end a line. The print statement automatically appends a newline, but the write method does not add the newline automatically.
>>> line2 = 'the emblem of our land.\n' >>> fout.write(line2)
When you are done writing, you have to close the file to make sure that the last bit of data is physically written to the disk so it will not be lost if the power goes off.
We could close the files which we open for read as well, but we can be a little sloppy if we are only opening a few files since Python makes sure that all open files are closed when the program ends. When we are writing files, we want to explicitly close the files so as to leave nothing to chance.
When you are reading and writing files, you might run into problems with whitespace. These errors can be hard to debug because spaces, tabs, and newlines are normally invisible:
>>> s = '1 2\t 3\n 4' >>> print s 1 2 3 4
The built-in function repr can help. It takes any object as an argument and returns a string representation of the object. For strings, it represents whitespace characters with backslash sequences:
>>> print repr(s) '1 2\t 3\n 4'
This can be helpful for debugging.
One other problem you might run into is that different systems
use different characters to indicate the end of a line. Some
systems use a newline, represented
\n. Others use
a return character, represented
\r. Some use both.
If you move files between different systems, these inconsistencies
might cause problems.
For most systems, there are applications to convert from one format to another. You can find them (and read more about this issue) at wikipedia.org/wiki/Newline. Or, of course, you could write one yourself.
python shout.py Enter a file name: mbox-short.txt FROM [email protected] SAT JAN 5 09:14:16 2008 RETURN-PATH: <[email protected]> RECEIVED: FROM MURDER (MAIL.UMICH.EDU [184.108.40.206]) BY FRANKENSTEIN.MAIL.UMICH.EDU (CYRUS V2.3.8) WITH LMTPA; SAT, 05 JAN 2008 09:14:16 -0500
You can download the file from www.py4inf.com/code/mbox-short.txt
When you encounter a line that starts with “X-DSPAM-Confidence:” pull apart the line to extract the floating-point number on the line. Count these lines and then compute the total of the spam confidence values from these lines. When you reach the end of the file, print out the average spam confidence.
Enter the file name: mbox.txt Average spam confidence: 0.894128046745 Enter the file name: mbox-short.txt Average spam confidence: 0.750718518519
Test your file on the mbox.txt and mbox-short.txt files.
python egg.py Enter the file name: mbox.txt There were 1797 subject lines in mbox.txt python egg.py Enter the file name: missing.tyxt File cannot be opened: missing.tyxt python egg.py Enter the file name: na na boo boo NA NA BOO BOO TO YOU - You have been punk'd!
We are not encouraging you to put Easter Eggs in your programs—this is just an exercise.