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In the previous chapter, you learned how to create and write to new files in Python. Your programs can also organize preexisting files on the hard drive. Maybe you’ve had the experience of going through a folder full of dozens, hundreds, or even thousands of files and copying, renaming, moving, or compressing them all by hand. Or consider tasks such as these:
-
Making copies of all PDF files (and only the PDF files) in every sub-folder of a folder
-
Removing the leading zeros in the filenames for every file in a folder of hundreds of files named spam001.txt, spam002.txt, spam003.txt, and so on
-
Compressing the contents of several folders into one ZIP file (which could be a simple backup system)
All this boring stuff is just begging to be automated in Python. By programming your computer to do these tasks, you can transform it into a quick-working file clerk who never makes mistakes.
As you begin working with files, you may find it helpful to be able to quickly see what the extension (.txt, .pdf, .jpg, and so on) of a file is. With OS X and Linux, your file browser most likely shows extensions automatically. With Windows, file extensions may be hidden by default. To show extensions, go to Start▸ Control Panel▸Appearance and Personalization▸Folder Options. On the View tab, under Advanced Settings, uncheck the Hide extensions for known file types checkbox.
The shutil
(or shell utilities) module has functions to let you copy, move, rename, and delete files in your Python programs. To use the shutil
functions, you will first need to use import shutil
.
The shutil
module provides functions for copying files, as well as entire folders.
Calling shutil.copy(
source, destination
)
will copy the file at the path source
to the folder at the path destination
. (Both source
and destination
are strings.) If destination
is a filename, it will be used as the new name of the copied file. This function returns a string of the path of the copied file.
Enter the following into the interactive shell to see how shutil.copy()
works:
>>> import shutil, os >>> os.chdir('C:\\') ❶ >>> shutil.copy('C:\\spam.txt', 'C:\\delicious') 'C:\\delicious\\spam.txt' ❷ >>> shutil.copy('eggs.txt', 'C:\\delicious\\eggs2.txt') 'C:\\delicious\\eggs2.txt'
The first shutil.copy()
call copies the file at C:\spam.txt to the folder C:\delicious. The return value is the path of the newly copied file. Note that since a folder was specified as the destination ❶, the original spam.txt filename is used for the new, copied file’s filename. The second shutil.copy()
call ❷ also copies the file at C:\eggs.txt to the folder C:\delicious but gives the copied file the name eggs2.txt.
While shutil.copy()
will copy a single file, shutil.copytree()
will copy an entire folder and every folder and file contained in it. Calling shutil.copytree(
source, destination
)
will copy the folder at the path source
, along with all of its files and subfolders, to the folder at the path destination
. The source
and destination
parameters are both strings. The function returns a string of the path of the copied folder.
Enter the following into the interactive shell:
>>> import shutil, os >>> os.chdir('C:\\') >>> shutil.copytree('C:\\bacon', 'C:\\bacon_backup') 'C:\\bacon_backup'
The shutil.copytree()
call creates a new folder named bacon_backup with the same content as the original bacon folder. You have now safely backed up your precious, precious bacon.
Calling shutil.move(
source, destination
)
will move the file or folder at the path source
to the path destination
and will return a string of the absolute path of the new location.
If destination
points to a folder, the source
file gets moved into destination
and keeps its current filename. For example, enter the following into the interactive shell:
>>> import shutil >>> shutil.move('C:\\bacon.txt', 'C:\\eggs') 'C:\\eggs\\bacon.txt'
Assuming a folder named eggs already exists in the C:\ directory, this shutil.move()
calls says, “Move C:\bacon.txt into the folder C:\eggs.”
If there had been a bacon.txt file already in C:\eggs, it would have been overwritten. Since it’s easy to accidentally overwrite files in this way, you should take some care when using move()
.
The destination
path can also specify a filename. In the following example, the source
file is moved and renamed.
>>> shutil.move('C:\\bacon.txt', 'C:\\eggs\\new_bacon.txt')
'C:\\eggs\\new_bacon.txt'
This line says, “Move C:\bacon.txt into the folder C:\eggs, and while you’re at it, rename that bacon.txt file to new_bacon.txt.”
Both of the previous examples worked under the assumption that there was a folder eggs in the C:\ directory. But if there is no eggs folder, then move()
will rename bacon.txt to a file named eggs.
>>> shutil.move('C:\\bacon.txt', 'C:\\eggs')
'C:\\eggs'
Here, move()
can’t find a folder named eggs in the C:\ directory and so assumes that destination
must be specifying a filename, not a folder. So the bacon.txt text file is renamed to eggs (a text file without the .txt file extension)—probably not what you wanted! This can be a tough-to-spot bug in your programs since the move()
call can happily do something that might be quite different from what you were expecting. This is yet another reason to be careful when using move()
.
Finally, the folders that make up the destination must already exist, or else Python will throw an exception. Enter the following into the interactive shell:
>>> shutil.move('spam.txt', 'c:\\does_not_exist\\eggs\\ham')
Traceback (most recent call last):
File "C:\Python34\lib\shutil.py", line 521, in move
os.rename(src, real_dst)
FileNotFoundError: [WinError 3] The system cannot find the path specified:
'spam.txt' -> 'c:\\does_not_exist\\eggs\\ham'
During handling of the above exception, another exception occurred:
Traceback (most recent call last):
File "<pyshell#29>", line 1, in <module>
shutil.move('spam.txt', 'c:\\does_not_exist\\eggs\\ham')
File "C:\Python34\lib\shutil.py", line 533, in move
copy2(src, real_dst)
File "C:\Python34\lib\shutil.py", line 244, in copy2
copyfile(src, dst, follow_symlinks=follow_symlinks)
File "C:\Python34\lib\shutil.py", line 108, in copyfile
with open(dst, 'wb') as fdst:
FileNotFoundError: [Errno 2] No such file or directory: 'c:\\does_not_exist\\
eggs\\ham'
Python looks for eggs and ham inside the directory does_not_exist. It doesn’t find the nonexistent directory, so it can’t move spam.txt to the path you specified.
You can delete a single file or a single empty folder with functions in the os
module, whereas to delete a folder and all of its contents, you use the shutil
module.
-
Calling
os.unlink(
path
)
will delete the file atpath
. -
Calling
os.rmdir(
path
)
will delete the folder atpath
. This folder must be empty of any files or folders. -
Calling
shutil.rmtree(
path
)
will remove the folder atpath
, and all files and folders it contains will also be deleted.
Be careful when using these functions in your programs! It’s often a good idea to first run your program with these calls commented out and with print()
calls added to show the files that would be deleted. Here is a Python program that was intended to delete files that have the .txt file extension but has a typo (highlighted in bold) that causes it to delete .rxt files instead:
import os
for filename in os.listdir():
if filename.endswith('.rxt'):
os.unlink(filename)
If you had any important files ending with .rxt, they would have been accidentally, permanently deleted. Instead, you should have first run the program like this:
import os for filename in os.listdir(): if filename.endswith('.rxt'): #os.unlink(filename) print(filename)
Now the os.unlink()
call is commented, so Python ignores it. Instead, you will print the filename of the file that would have been deleted. Running this version of the program first will show you that you’ve accidentally told the program to delete .rxt files instead of .txt files.
Once you are certain the program works as intended, delete the print(filename)
line and uncomment the os.unlink(filename)
line. Then run the program again to actually delete the files.
Since Python’s built-in shutil.rmtree()
function irreversibly deletes files and folders, it can be dangerous to use. A much better way to delete files and folders is with the third-party send2trash
module. You can install this module by running pip install send2trash
from a Terminal window. (See Appendix A for a more in-depth explanation of how to install third-party modules.)
Using send2trash
is much safer than Python’s regular delete functions, because it will send folders and files to your computer’s trash or recycle bin instead of permanently deleting them. If a bug in your program deletes something with send2trash
you didn’t intend to delete, you can later restore it from the recycle bin.
After you have installed send2trash
, enter the following into the interactive shell:
>>> import send2trash >>> baconFile = open('bacon.txt', 'a') # creates the file >>> baconFile.write('Bacon is not a vegetable.') 25 >>> baconFile.close() >>> send2trash.send2trash('bacon.txt')
In general, you should always use the send2trash.send2trash()
function to delete files and folders. But while sending files to the recycle bin lets you recover them later, it will not free up disk space like permanently deleting them does. If you want your program to free up disk space, use the os
and shutil
functions for deleting files and folders. Note that the send2trash()
function can only send files to the recycle bin; it cannot pull files out of it.
Say you want to rename every file in some folder and also every file in every subfolder of that folder. That is, you want to walk through the directory tree, touching each file as you go. Writing a program to do this could get tricky; fortunately, Python provides a function to handle this process for you.
Let’s look at the C:\delicious folder with its contents, shown in Figure 9-1.
Here is an example program that uses the os.walk()
function on the directory tree from Figure 9-1:
import os for folderName, subfolders, filenames in os.walk('C:\\delicious'): print('The current folder is ' + folderName) for subfolder in subfolders: print('SUBFOLDER OF ' + folderName + ': ' + subfolder) for filename in filenames: print('FILE INSIDE ' + folderName + ': '+ filename) print('')
The os.walk()
function is passed a single string value: the path of a folder. You can use os.walk()
in a for
loop statement to walk a directory tree, much like how you can use the range()
function to walk over a range of numbers. Unlike range()
, the os.walk()
function will return three values on each iteration through the loop:
-
A string of the current folder’s name
-
A list of strings of the folders in the current folder
-
A list of strings of the files in the current folder
(By current folder, I mean the folder for the current iteration of the for
loop. The current working directory of the program is not changed by os.walk()
.)
Just like you can choose the variable name i
in the code for i in range(10):
, you can also choose the variable names for the three values listed earlier. I usually use the names foldername
, subfolders
, and filenames
.
When you run this program, it will output the following:
The current folder is C:\delicious SUBFOLDER OF C:\delicious: cats SUBFOLDER OF C:\delicious: walnut FILE INSIDE C:\delicious: spam.txt The current folder is C:\delicious\cats FILE INSIDE C:\delicious\cats: catnames.txt FILE INSIDE C:\delicious\cats: zophie.jpg The current folder is C:\delicious\walnut SUBFOLDER OF C:\delicious\walnut: waffles The current folder is C:\delicious\walnut\waffles FILE INSIDE C:\delicious\walnut\waffles: butter.txt.
Since os.walk()
returns lists of strings for the subfolder
and filename
variables, you can use these lists in their own for
loops. Replace the print()
function calls with your own custom code. (Or if you don’t need one or both of them, remove the for
loops.)
You may be familiar with ZIP files (with the .zip file extension), which can hold the compressed contents of many other files. Compressing a file reduces its size, which is useful when transferring it over the Internet. And since a ZIP file can also contain multiple files and subfolders, it’s a handy way to package several files into one. This single file, called an archive file, can then be, say, attached to an email.
Your Python programs can both create and open (or extract) ZIP files using functions in the zipfile
module. Say you have a ZIP file named example.zip that has the contents shown in Figure 9-2.
You can download this ZIP file from http://nostarch.com/automatestuff/ or just follow along using a ZIP file already on your computer.
To read the contents of a ZIP file, first you must create a ZipFile
object (note the capital letters Z and F). ZipFile
objects are conceptually similar to the File
objects you saw returned by the open()
function in the previous chapter: They are values through which the program interacts with the file. To create a ZipFile
object, call the zipfile.ZipFile()
function, passing it a string of the .zip file’s filename. Note that zipfile
is the name of the Python module, and ZipFile()
is the name of the function.
For example, enter the following into the interactive shell:
>>> import zipfile, os >>> os.chdir('C:\\') # move to the folder with example.zip >>> exampleZip = zipfile.ZipFile('example.zip') >>> exampleZip.namelist() ['spam.txt', 'cats/', 'cats/catnames.txt', 'cats/zophie.jpg'] >>> spamInfo = exampleZip.getinfo('spam.txt') >>> spamInfo.file_size 13908 >>> spamInfo.compress_size 3828 ❶ >>> 'Compressed file is %sx smaller!' % (round(spamInfo.file_size / spamInfo .compress_size, 2)) 'Compressed file is 3.63x smaller!' >>> exampleZip.close()
A ZipFile
object has a namelist()
method that returns a list of strings for all the files and folders contained in the ZIP file. These strings can be passed to the getinfo() ZipFile
method to return a ZipInfo
object about that particular file. ZipInfo
objects have their own attributes, such as file_size
and compress_size
in bytes, which hold integers of the original file size and compressed file size, respectively. While a ZipFile
object represents an entire archive file, a ZipInfo
object holds useful information about a single file in the archive.
The command at ❶ calculates how efficiently example.zip is compressed by dividing the original file size by the compressed file size and prints this information using a string formatted with %s
.
The extractall()
method for ZipFile
objects extracts all the files and folders from a ZIP file into the current working directory.
>>> import zipfile, os >>> os.chdir('C:\\') # move to the folder with example.zip >>> exampleZip = zipfile.ZipFile('example.zip') ❶ >>> exampleZip.extractall() >>> exampleZip.close()
After running this code, the contents of example.zip will be extracted to C:\. Optionally, you can pass a folder name to extractall()
to have it extract the files into a folder other than the current working directory. If the folder passed to the extractall()
method does not exist, it will be created. For instance, if you replaced the call at ❶ with exampleZip.extractall('C:\\ delicious')
, the code would extract the files from example.zip into a newly created C:\delicious folder.
The extract()
method for ZipFile
objects will extract a single file from the ZIP file. Continue the interactive shell example:
>>> exampleZip.extract('spam.txt') 'C:\\spam.txt' >>> exampleZip.extract('spam.txt', 'C:\\some\\new\\folders') 'C:\\some\\new\\folders\\spam.txt' >>> exampleZip.close()
The string you pass to extract()
must match one of the strings in the list returned by namelist()
. Optionally, you can pass a second argument to extract()
to extract the file into a folder other than the current working directory. If this second argument is a folder that doesn’t yet exist, Python will create the folder. The value that extract()
returns is the absolute path to which the file was extracted.
To create your own compressed ZIP files, you must open the ZipFile
object in write mode by passing 'w'
as the second argument. (This is similar to opening a text file in write mode by passing 'w'
to the open()
function.)
When you pass a path to the write()
method of a ZipFile
object, Python will compress the file at that path and add it into the ZIP file. The write()
method’s first argument is a string of the filename to add. The second argument is the compression type parameter, which tells the computer what algorithm it should use to compress the files; you can always just set this value to zipfile.ZIP_DEFLATED
. (This specifies the deflate compression algorithm, which works well on all types of data.) Enter the following into the interactive shell:
>>> import zipfile >>> newZip = zipfile.ZipFile('new.zip', 'w') >>> newZip.write('spam.txt', compress_type=zipfile.ZIP_DEFLATED) >>> newZip.close()
This code will create a new ZIP file named new.zip that has the compressed contents of spam.txt.
Keep in mind that, just as with writing to files, write mode will erase all existing contents of a ZIP file. If you want to simply add files to an existing ZIP file, pass 'a'
as the second argument to zipfile.ZipFile()
to open the ZIP file in append mode.
Say your boss emails you thousands of files with American-style dates (MM-DD-YYYY) in their names and needs them renamed to European-style dates (DD-MM-YYYY). This boring task could take all day to do by hand! Let’s write a program to do it instead.
Here’s what the program does:
-
It searches all the filenames in the current working directory for American-style dates.
-
When one is found, it renames the file with the month and day swapped to make it European-style.
This means the code will need to do the following:
-
Create a regex that can identify the text pattern of American-style dates.
-
Call
os.listdir()
to find all the files in the working directory. -
Loop over each filename, using the regex to check whether it has a date.
-
If it has a date, rename the file with
shutil.move()
.
For this project, open a new file editor window and save your code as renameDates.py.
The first part of the program will need to import the necessary modules and create a regex that can identify MM-DD-YYYY dates. The to-do comments will remind you what’s left to write in this program. Typing them as TODO
makes them easy to find using IDLE’s CTRL-F find feature. Make your code look like the following:
#! python3 # renameDates.py - Renames filenames with American MM-DD-YYYY date format # to European DD-MM-YYYY. ❶ import shutil, os, re # Create a regex that matches files with the American date format. ❷ datePattern = re.compile(r"""^(.*?) # all text before the date ((0|1)?\d)- # one or two digits for the month ((0|1|2|3)?\d)- # one or two digits for the day ((19|20)\d\d) # four digits for the year (.*?)$ # all text after the date ❸ """, re.VERBOSE) # TODO: Loop over the files in the working directory. # TODO: Skip files without a date. # TODO: Get the different parts of the filename. # TODO: Form the European-style filename. # TODO: Get the full, absolute file paths. # TODO: Rename the files.
From this chapter, you know the shutil.move()
function can be used to rename files: Its arguments are the name of the file to rename and the new filename. Because this function exists in the shutil
module, you must import that module ❶.
But before renaming the files, you need to identify which files you want to rename. Filenames with dates such as spam4-4-1984.txt and 01-03-2014eggs.zip should be renamed, while filenames without dates such as littlebrother.epub can be ignored.
You can use a regular expression to identify this pattern. After importing the re
module at the top, call re.compile()
to create a Regex
object ❷. Passing re.VERBOSE
for the second argument ❸ will allow whitespace and comments in the regex string to make it more readable.
The regular expression string begins with ^(.*?)
to match any text at the beginning of the filename that might come before the date. The ((0|1)?\d)
group matches the month. The first digit can be either 0
or 1
, so the regex matches 12
for December but also 02
for February. This digit is also optional so that the month can be 04
or 4
for April. The group for the day is ((0|1|2|3)?\d)
and follows similar logic; 3
, 03
, and 31
are all valid numbers for days. (Yes, this regex will accept some invalid dates such as 4-31-2014
, 2-29-2013
, and 0-15-2014
. Dates have a lot of thorny special cases that can be easy to miss. But for simplicity, the regex in this program works well enough.)
While 1885 is a valid year, you can just look for years in the 20th or 21st century. This will keep your program from accidentally matching nondate filenames with a date-like format, such as 10-10-1000.txt.
The (.*?)$
part of the regex will match any text that comes after the date.
Next, the program will have to loop over the list of filename strings returned from os.listdir()
and match them against the regex. Any files that do not have a date in them should be skipped. For filenames that have a date, the matched text will be stored in several variables. Fill in the first three TODO
s in your program with the following code:
#! python3 # renameDates.py - Renames filenames with American MM-DD-YYYY date format # to European DD-MM-YYYY. --snip-- # Loop over the files in the working directory. for amerFilename in os.listdir('.'): mo = datePattern.search(amerFilename) # Skip files without a date. ❶ if mo == None: ❷ continue ❸ # Get the different parts of the filename. beforePart = mo.group(1) monthPart = mo.group(2) dayPart = mo.group(4) yearPart = mo.group(6) afterPart = mo.group(8) --snip--
If the Match
object returned from the search()
method is None
❶, then the filename in amerFilename
does not match the regular expression. The continue
statement ❷ will skip the rest of the loop and move on to the next filename.
Otherwise, the various strings matched in the regular expression groups are stored in variables named beforePart
, monthPart
, dayPart
, yearPart
, and afterPart
❸. The strings in these variables will be used to form the European-style filename in the next step.
To keep the group numbers straight, try reading the regex from the beginning and count up each time you encounter an opening parenthesis. Without thinking about the code, just write an outline of the regular expression. This can help you visualize the groups. For example:
datePattern = re.compile(r"""^(1) # all text before the date (2 (3) )- # one or two digits for the month (4 (5) )- # one or two digits for the day (6 (7) ) # four digits for the year (8)$ # all text after the date """, re.VERBOSE)
Here, the numbers 1
through 8
represent the groups in the regular expression you wrote. Making an outline of the regular expression, with just the parentheses and group numbers, can give you a clearer understanding of your regex before you move on with the rest of the program.
As the final step, concatenate the strings in the variables made in the previous step with the European-style date: The date comes before the month. Fill in the three remaining TODO
s in your program with the following code:
#! python3 # renameDates.py - Renames filenames with American MM-DD-YYYY date format # to European DD-MM-YYYY. --snip-- # Form the European-style filename. ❶ euroFilename = beforePart + dayPart + '-' + monthPart + '-' + yearPart + afterPart # Get the full, absolute file paths. absWorkingDir = os.path.abspath('.') amerFilename = os.path.join(absWorkingDir, amerFilename) euroFilename = os.path.join(absWorkingDir, euroFilename) # Rename the files. ❷ print('Renaming "%s" to "%s"...' % (amerFilename, euroFilename)) ❸ #shutil.move(amerFilename, euroFilename) # uncomment after testing
Store the concatenated string in a variable named euroFilename
❶. Then, pass the original filename in amerFilename
and the new euroFilename
variable to the shutil.move()
function to rename the file ❸.
This program has the shutil.move()
call commented out and instead prints the filenames that will be renamed ❷. Running the program like this first can let you double-check that the files are renamed correctly. Then you can uncomment the shutil.move()
call and run the program again to actually rename the files.
There are many other reasons why you might want to rename a large number of files.
-
To add a prefix to the start of the filename, such as adding spam_ to rename eggs.txt to spam_eggs.txt
-
To change filenames with European-style dates to American-style dates
-
To remove the zeros from files such as spam0042.txt
Say you’re working on a project whose files you keep in a folder named C:\AlsPythonBook. You’re worried about losing your work, so you’d like to create ZIP file “snapshots” of the entire folder. You’d like to keep different versions, so you want the ZIP file’s filename to increment each time it is made; for example, AlsPythonBook_1.zip, AlsPythonBook_2.zip, AlsPythonBook_3.zip, and so on. You could do this by hand, but it is rather annoying, and you might accidentally misnumber the ZIP files’ names. It would be much simpler to run a program that does this boring task for you.
For this project, open a new file editor window and save it as backupToZip.py.
The code for this program will be placed into a function named backupToZip()
. This will make it easy to copy and paste the function into other Python programs that need this functionality. At the end of the program, the function will be called to perform the backup. Make your program look like this:
#! python3 # backupToZip.py - Copies an entire folder and its contents into # a ZIP file whose filename increments. ❶ import zipfile, os def backupToZip(folder): # Backup the entire contents of "folder" into a ZIP file. folder = os.path.abspath(folder) # make sure folder is absolute # Figure out the filename this code should use based on # what files already exist. ❷ number = 1 ❸ while True: zipFilename = os.path.basename(folder) + '_' + str(number) + '.zip' if not os.path.exists(zipFilename): break number = number + 1 ❹ # TODO: Create the ZIP file. # TODO: Walk the entire folder tree and compress the files in each folder. print('Done.') backupToZip('C:\\delicious')
Do the basics first: Add the shebang (#!
) line, describe what the program does, and import the zipfile
and os
modules ❶.
Define a backupToZip()
function that takes just one parameter, folder
. This parameter is a string path to the folder whose contents should be backed up. The function will determine what filename to use for the ZIP file it will create; then the function will create the file, walk the folder
folder, and add each of the subfolders and files to the ZIP file. Write TODO
comments for these steps in the source code to remind yourself to do them later ❹.
The first part, naming the ZIP file, uses the base name of the absolute path of folder
. If the folder being backed up is C:\delicious, the ZIP file’s name should be delicious_N.zip, where N = 1 is the first time you run the program, N = 2 is the second time, and so on.
You can determine what N should be by checking whether delicious_1.zip already exists, then checking whether delicious_2.zip already exists, and so on. Use a variable named number
for N ❷, and keep incrementing it inside the loop that calls os.path.exists()
to check whether the file exists ❸. The first nonexistent filename found will cause the loop to break
, since it will have found the filename of the new zip.
Next let’s create the ZIP file. Make your program look like the following:
#! python3 # backupToZip.py - Copies an entire folder and its contents into # a ZIP file whose filename increments. --snip-- while True: zipFilename = os.path.basename(folder) + '_' + str(number) + '.zip' if not os.path.exists(zipFilename): break number = number + 1 # Create the ZIP file. print('Creating %s...' % (zipFilename)) ❶ backupZip = zipfile.ZipFile(zipFilename, 'w') # TODO: Walk the entire folder tree and compress the files in each folder. print('Done.') backupToZip('C:\\delicious')
Now that the new ZIP file’s name is stored in the zipFilename
variable, you can call zipfile.ZipFile()
to actually create the ZIP file ❶. Be sure to pass 'w'
as the second argument so that the ZIP file is opened in write mode.
Now you need to use the os.walk()
function to do the work of listing every file in the folder and its subfolders. Make your program look like the following:
#! python3 # backupToZip.py - Copies an entire folder and its contents into # a ZIP file whose filename increments. --snip-- # Walk the entire folder tree and compress the files in each folder. ❶ for foldername, subfolders, filenames in os.walk(folder): print('Adding files in %s...' % (foldername)) # Add the current folder to the ZIP file. ❷ backupZip.write(foldername) # Add all the files in this folder to the ZIP file. ❸ for filename in filenames: newBase = os.path.basename(folder) + '_' if filename.startswith(newBase) and filename.endswith('.zip'): continue # don't backup the backup ZIP files backupZip.write(os.path.join(foldername, filename)) backupZip.close() print('Done.') backupToZip('C:\\delicious')
You can use os.walk()
in a for
loop ❶, and on each iteration it will return the iteration’s current folder name, the subfolders in that folder, and the filenames in that folder.
In the for
loop, the folder is added to the ZIP file ❷. The nested for
loop can go through each filename in the filenames
list ❸. Each of these is added to the ZIP file, except for previously made backup ZIPs.
When you run this program, it will produce output that will look something like this:
Creating delicious_1.zip... Adding files in C:\delicious... Adding files in C:\delicious\cats... Adding files in C:\delicious\waffles... Adding files in C:\delicious\walnut... Adding files in C:\delicious\walnut\waffles... Done.
The second time you run it, it will put all the files in C:\delicious into a ZIP file named delicious_2.zip, and so on.
You can walk a directory tree and add files to compressed ZIP archives in several other programs. For example, you can write programs that do the following:
-
Walk a directory tree and archive just files with certain extensions, such as .txt or .py, and nothing else
-
Walk a directory tree and archive every file except the .txt and .py ones
-
Find the folder in a directory tree that has the greatest number of files or the folder that uses the most disk space
Even if you are an experienced computer user, you probably handle files manually with the mouse and keyboard. Modern file explorers make it easy to work with a few files. But sometimes you’ll need to perform a task that would take hours using your computer’s file explorer.
The os
and shutil
modules offer functions for copying, moving, renaming, and deleting files. When deleting files, you might want to use the send2trash
module to move files to the recycle bin or trash rather than permanently deleting them. And when writing programs that handle files, it’s a good idea to comment out the code that does the actual copy/move/ rename/delete and add a print()
call instead so you can run the program and verify exactly what it will do.
Often you will need to perform these operations not only on files in one folder but also on every folder in that folder, every folder in those folders, and so on. The os.walk()
function handles this trek across the folders for you so that you can concentrate on what your program needs to do with the files in them.
The zipfile
module gives you a way of compressing and extracting files in .zip archives through Python. Combined with the file-handling functions of os
and shutil
, zipfile
makes it easy to package up several files from anywhere on your hard drive. These .zip files are much easier to upload to websites or send as email attachments than many separate files.
Previous chapters of this book have provided source code for you to copy. But when you write your own programs, they probably won’t come out perfectly the first time. The next chapter focuses on some Python modules that will help you analyze and debug your programs so that you can quickly get them working correctly.
For practice, write programs to do the following tasks.
Write a program that walks through a folder tree and searches for files with a certain file extension (such as .pdf or .jpg). Copy these files from whatever location they are in to a new folder.
It’s not uncommon for a few unneeded but humongous files or folders to take up the bulk of the space on your hard drive. If you’re trying to free up room on your computer, you’ll get the most bang for your buck by deleting the most massive of the unwanted files. But first you have to find them.
Write a program that walks through a folder tree and searches for exceptionally large files or folders—say, ones that have a file size of more than 100MB. (Remember, to get a file’s size, you can use os.path.getsize()
from the os
module.) Print these files with their absolute path to the screen.
Write a program that finds all files with a given prefix, such as spam001.txt, spam002.txt, and so on, in a single folder and locates any gaps in the numbering (such as if there is a spam001.txt and spam003.txt but no spam002.txt). Have the program rename all the later files to close this gap.
As an added challenge, write another program that can insert gaps into numbered files so that a new file can be added.