Library and Extension FAQ¶
General Library Questions¶
How do I find a module or application to perform task X?¶
Check the Library Reference to see if there’s a relevant standard library module. (Eventually you’ll learn what’s in the standard library and will be able to skip this step.)
For third-party packages, search the Python Package Index or try Google or another web search engine. Searching for “Python” plus a keyword or two for your topic of interest will usually find something helpful.
Where is the math.py (socket.py, regex.py, etc.) source file?¶
If you can’t find a source file for a module it may be a built-in or
dynamically loaded module implemented in C, C++ or other compiled language.
In this case you may not have the source file or it may be something like
mathmodule.c
, somewhere in a C source directory (not on the Python Path).
There are (at least) three kinds of modules in Python:
modules written in Python (.py);
modules written in C and dynamically loaded (.dll, .pyd, .so, .sl, etc);
modules written in C and linked with the interpreter; to get a list of these, type:
import sys print(sys.builtin_module_names)
How do I make a Python script executable on Unix?¶
You need to do two things: the script file’s mode must be executable and the
first line must begin with #!
followed by the path of the Python
interpreter.
The first is done by executing chmod +x scriptfile
or perhaps chmod 755
scriptfile
.
The second can be done in a number of ways. The most straightforward way is to write
#!/usr/local/bin/python
as the very first line of your file, using the pathname for where the Python interpreter is installed on your platform.
If you would like the script to be independent of where the Python interpreter
lives, you can use the env program. Almost all Unix variants support
the following, assuming the Python interpreter is in a directory on the user’s
PATH
:
#!/usr/bin/env python
Don’t do this for CGI scripts. The PATH
variable for CGI scripts is
often very minimal, so you need to use the actual absolute pathname of the
interpreter.
Occasionally, a user’s environment is so full that the /usr/bin/env program fails; or there’s no env program at all. In that case, you can try the following hack (due to Alex Rezinsky):
#! /bin/sh
""":"
exec python $0 ${1+"$@"}
"""
The minor disadvantage is that this defines the script’s __doc__ string. However, you can fix that by adding
__doc__ = """...Whatever..."""
Is there a curses/termcap package for Python?¶
For Unix variants: The standard Python source distribution comes with a curses module in the Modules subdirectory, though it’s not compiled by default. (Note that this is not available in the Windows distribution – there is no curses module for Windows.)
The curses
module supports basic curses features as well as many additional
functions from ncurses and SYSV curses such as colour, alternative character set
support, pads, and mouse support. This means the module isn’t compatible with
operating systems that only have BSD curses, but there don’t seem to be any
currently maintained OSes that fall into this category.
Is there an equivalent to C’s onexit() in Python?¶
The atexit
module provides a register function that is similar to C’s
onexit()
.
Why don’t my signal handlers work?¶
The most common problem is that the signal handler is declared with the wrong argument list. It is called as
handler(signum, frame)
so it should be declared with two parameters:
def handler(signum, frame):
...
Common tasks¶
How do I test a Python program or component?¶
Python comes with two testing frameworks. The doctest
module finds
examples in the docstrings for a module and runs them, comparing the output with
the expected output given in the docstring.
The unittest
module is a fancier testing framework modelled on Java and
Smalltalk testing frameworks.
To make testing easier, you should use good modular design in your program. Your program should have almost all functionality encapsulated in either functions or class methods – and this sometimes has the surprising and delightful effect of making the program run faster (because local variable accesses are faster than global accesses). Furthermore the program should avoid depending on mutating global variables, since this makes testing much more difficult to do.
The “global main logic” of your program may be as simple as
if __name__ == "__main__":
main_logic()
at the bottom of the main module of your program.
Once your program is organized as a tractable collection of function and class behaviours, you should write test functions that exercise the behaviours. A test suite that automates a sequence of tests can be associated with each module. This sounds like a lot of work, but since Python is so terse and flexible it’s surprisingly easy. You can make coding much more pleasant and fun by writing your test functions in parallel with the “production code”, since this makes it easy to find bugs and even design flaws earlier.
“Support modules” that are not intended to be the main module of a program may include a self-test of the module.
if __name__ == "__main__":
self_test()
Even programs that interact with complex external interfaces may be tested when the external interfaces are unavailable by using “fake” interfaces implemented in Python.
How do I create documentation from doc strings?¶
The pydoc
module can create HTML from the doc strings in your Python
source code. An alternative for creating API documentation purely from
docstrings is epydoc. Sphinx can also include docstring content.
How do I get a single keypress at a time?¶
For Unix variants there are several solutions. It’s straightforward to do this using curses, but curses is a fairly large module to learn.
Threads¶
How do I program using threads?¶
Be sure to use the threading
module and not the _thread
module.
The threading
module builds convenient abstractions on top of the
low-level primitives provided by the _thread
module.
None of my threads seem to run: why?¶
As soon as the main thread exits, all threads are killed. Your main thread is running too quickly, giving the threads no time to do any work.
A simple fix is to add a sleep to the end of the program that’s long enough for all the threads to finish:
import threading, time
def thread_task(name, n):
for i in range(n):
print(name, i)
for i in range(10):
T = threading.Thread(target=thread_task, args=(str(i), i))
T.start()
time.sleep(10) # <---------------------------!
But now (on many platforms) the threads don’t run in parallel, but appear to run sequentially, one at a time! The reason is that the OS thread scheduler doesn’t start a new thread until the previous thread is blocked.
A simple fix is to add a tiny sleep to the start of the run function:
def thread_task(name, n):
time.sleep(0.001) # <--------------------!
for i in range(n):
print(name, i)
for i in range(10):
T = threading.Thread(target=thread_task, args=(str(i), i))
T.start()
time.sleep(10)
Instead of trying to guess a good delay value for time.sleep()
,
it’s better to use some kind of semaphore mechanism. One idea is to use the
queue
module to create a queue object, let each thread append a token to
the queue when it finishes, and let the main thread read as many tokens from the
queue as there are threads.
How do I parcel out work among a bunch of worker threads?¶
The easiest way is to use the concurrent.futures
module,
especially the ThreadPoolExecutor
class.
Or, if you want fine control over the dispatching algorithm, you can write
your own logic manually. Use the queue
module to create a queue
containing a list of jobs. The Queue
class maintains a
list of objects and has a .put(obj)
method that adds items to the queue and
a .get()
method to return them. The class will take care of the locking
necessary to ensure that each job is handed out exactly once.
Here’s a trivial example:
import threading, queue, time
# The worker thread gets jobs off the queue. When the queue is empty, it
# assumes there will be no more work and exits.
# (Realistically workers will run until terminated.)
def worker():
print('Running worker')
time.sleep(0.1)
while True:
try:
arg = q.get(block=False)
except queue.Empty:
print('Worker', threading.current_thread(), end=' ')
print('queue empty')
break
else:
print('Worker', threading.current_thread(), end=' ')
print('running with argument', arg)
time.sleep(0.5)
# Create queue
q = queue.Queue()
# Start a pool of 5 workers
for i in range(5):
t = threading.Thread(target=worker, name='worker %i' % (i+1))
t.start()
# Begin adding work to the queue
for i in range(50):
q.put(i)
# Give threads time to run
print('Main thread sleeping')
time.sleep(5)
When run, this will produce the following output:
Running worker
Running worker
Running worker
Running worker
Running worker
Main thread sleeping
Worker <Thread(worker 1, started 130283832797456)> running with argument 0
Worker <Thread(worker 2, started 130283824404752)> running with argument 1
Worker <Thread(worker 3, started 130283816012048)> running with argument 2
Worker <Thread(worker 4, started 130283807619344)> running with argument 3
Worker <Thread(worker 5, started 130283799226640)> running with argument 4
Worker <Thread(worker 1, started 130283832797456)> running with argument 5
...
Consult the module’s documentation for more details; the Queue
class provides a featureful interface.
What kinds of global value mutation are thread-safe?¶
A global interpreter lock (GIL) is used internally to ensure that only one
thread runs in the Python VM at a time. In general, Python offers to switch
among threads only between bytecode instructions; how frequently it switches can
be set via sys.setswitchinterval()
. Each bytecode instruction and
therefore all the C implementation code reached from each instruction is
therefore atomic from the point of view of a Python program.
In theory, this means an exact accounting requires an exact understanding of the PVM bytecode implementation. In practice, it means that operations on shared variables of built-in data types (ints, lists, dicts, etc) that “look atomic” really are.
For example, the following operations are all atomic (L, L1, L2 are lists, D, D1, D2 are dicts, x, y are objects, i, j are ints):
L.append(x)
L1.extend(L2)
x = L[i]
x = L.pop()
L1[i:j] = L2
L.sort()
x = y
x.field = y
D[x] = y
D1.update(D2)
D.keys()
These aren’t:
i = i+1
L.append(L[-1])
L[i] = L[j]
D[x] = D[x] + 1
Operations that replace other objects may invoke those other objects’
__del__()
method when their reference count reaches zero, and that can
affect things. This is especially true for the mass updates to dictionaries and
lists. When in doubt, use a mutex!
Can’t we get rid of the Global Interpreter Lock?¶
The global interpreter lock (GIL) is often seen as a hindrance to Python’s deployment on high-end multiprocessor server machines, because a multi-threaded Python program effectively only uses one CPU, due to the insistence that (almost) all Python code can only run while the GIL is held.
With the approval of PEP 703 work is now underway to remove the GIL from the CPython implementation of Python. Initially it will be implemented as an optional compiler flag when building the interpreter, and so separate builds will be available with and without the GIL. Long-term, the hope is to settle on a single build, once the performance implications of removing the GIL are fully understood. Python 3.13 is likely to be the first release containing this work, although it may not be completely functional in this release.
The current work to remove the GIL is based on a fork of Python 3.9 with the GIL removed by Sam Gross. Prior to that, in the days of Python 1.5, Greg Stein actually implemented a comprehensive patch set (the “free threading” patches) that removed the GIL and replaced it with fine-grained locking. Adam Olsen did a similar experiment in his python-safethread project. Unfortunately, both of these earlier experiments exhibited a sharp drop in single-thread performance (at least 30% slower), due to the amount of fine-grained locking necessary to compensate for the removal of the GIL. The Python 3.9 fork is the first attempt at removing the GIL with an acceptable performance impact.
The presence of the GIL in current Python releases
doesn’t mean that you can’t make good use of Python on multi-CPU machines!
You just have to be creative with dividing the work up between multiple
processes rather than multiple threads. The
ProcessPoolExecutor
class in the new
concurrent.futures
module provides an easy way of doing so; the
multiprocessing
module provides a lower-level API in case you want
more control over dispatching of tasks.
Judicious use of C extensions will also help; if you use a C extension to
perform a time-consuming task, the extension can release the GIL while the
thread of execution is in the C code and allow other threads to get some work
done. Some standard library modules such as zlib
and hashlib
already do this.
An alternative approach to reducing the impact of the GIL is to make the GIL a per-interpreter-state lock rather than truly global. This was first implemented in Python 3.12 and is available in the C API. A Python interface to it is expected in Python 3.13. The main limitation to it at the moment is likely to be 3rd party extension modules, since these must be written with multiple interpreters in mind in order to be usable, so many older extension modules will not be usable.
Input and Output¶
How do I delete a file? (And other file questions…)¶
Use os.remove(filename)
or os.unlink(filename)
; for documentation, see
the os
module. The two functions are identical; unlink()
is simply
the name of the Unix system call for this function.
To remove a directory, use os.rmdir()
; use os.mkdir()
to create one.
os.makedirs(path)
will create any intermediate directories in path
that
don’t exist. os.removedirs(path)
will remove intermediate directories as
long as they’re empty; if you want to delete an entire directory tree and its
contents, use shutil.rmtree()
.
To rename a file, use os.rename(old_path, new_path)
.
To truncate a file, open it using f = open(filename, "rb+")
, and use
f.truncate(offset)
; offset defaults to the current seek position. There’s
also os.ftruncate(fd, offset)
for files opened with os.open()
, where
fd is the file descriptor (a small integer).
The shutil
module also contains a number of functions to work on files
including copyfile()
, copytree()
, and
rmtree()
.
How do I copy a file?¶
The shutil
module contains a copyfile()
function.
Note that on Windows NTFS volumes, it does not copy
alternate data streams
nor resource forks
on macOS HFS+ volumes, though both are now rarely used.
It also doesn’t copy file permissions and metadata, though using
shutil.copy2()
instead will preserve most (though not all) of it.
How do I read (or write) binary data?¶
To read or write complex binary data formats, it’s best to use the struct
module. It allows you to take a string containing binary data (usually numbers)
and convert it to Python objects; and vice versa.
For example, the following code reads two 2-byte integers and one 4-byte integer in big-endian format from a file:
import struct
with open(filename, "rb") as f:
s = f.read(8)
x, y, z = struct.unpack(">hhl", s)
The ‘>’ in the format string forces big-endian data; the letter ‘h’ reads one “short integer” (2 bytes), and ‘l’ reads one “long integer” (4 bytes) from the string.
For data that is more regular (e.g. a homogeneous list of ints or floats),
you can also use the array
module.
I can’t seem to use os.read() on a pipe created with os.popen(); why?¶
os.read()
is a low-level function which takes a file descriptor, a small
integer representing the opened file. os.popen()
creates a high-level
file object, the same type returned by the built-in open()
function.
Thus, to read n bytes from a pipe p created with os.popen()
, you need to
use p.read(n)
.
How do I access the serial (RS232) port?¶
For Win32, OSX, Linux, BSD, Jython, IronPython:
For Unix, see a Usenet post by Mitch Chapman:
Why doesn’t closing sys.stdout (stdin, stderr) really close it?¶
Python file objects are a high-level layer of abstraction on low-level C file descriptors.
For most file objects you create in Python via the built-in open()
function, f.close()
marks the Python file object as being closed from
Python’s point of view, and also arranges to close the underlying C file
descriptor. This also happens automatically in f
’s destructor, when
f
becomes garbage.
But stdin, stdout and stderr are treated specially by Python, because of the
special status also given to them by C. Running sys.stdout.close()
marks
the Python-level file object as being closed, but does not close the
associated C file descriptor.
To close the underlying C file descriptor for one of these three, you should
first be sure that’s what you really want to do (e.g., you may confuse
extension modules trying to do I/O). If it is, use os.close()
:
os.close(stdin.fileno())
os.close(stdout.fileno())
os.close(stderr.fileno())
Or you can use the numeric constants 0, 1 and 2, respectively.
Network/Internet Programming¶
What WWW tools are there for Python?¶
See the chapters titled Internet Protocols and Support and Internet Data Handling in the Library Reference Manual. Python has many modules that will help you build server-side and client-side web systems.
A summary of available frameworks is maintained by Paul Boddie at https://wiki.python.org/moin/WebProgramming.
What module should I use to help with generating HTML?¶
You can find a collection of useful links on the Web Programming wiki page.
How do I send mail from a Python script?¶
Use the standard library module smtplib
.
Here’s a very simple interactive mail sender that uses it. This method will work on any host that supports an SMTP listener.
import sys, smtplib
fromaddr = input("From: ")
toaddrs = input("To: ").split(',')
print("Enter message, end with ^D:")
msg = ''
while True:
line = sys.stdin.readline()
if not line:
break
msg += line
# The actual mail send
server = smtplib.SMTP('localhost')
server.sendmail(fromaddr, toaddrs, msg)
server.quit()
A Unix-only alternative uses sendmail. The location of the sendmail program
varies between systems; sometimes it is /usr/lib/sendmail
, sometimes
/usr/sbin/sendmail
. The sendmail manual page will help you out. Here’s
some sample code:
import os
SENDMAIL = "/usr/sbin/sendmail" # sendmail location
p = os.popen("%s -t -i" % SENDMAIL, "w")
p.write("To: receiver@example.com\n")
p.write("Subject: test\n")
p.write("\n") # blank line separating headers from body
p.write("Some text\n")
p.write("some more text\n")
sts = p.close()
if sts != 0:
print("Sendmail exit status", sts)
How do I avoid blocking in the connect() method of a socket?¶
The select
module is commonly used to help with asynchronous I/O on
sockets.
To prevent the TCP connect from blocking, you can set the socket to non-blocking
mode. Then when you do the connect()
,
you will either connect immediately
(unlikely) or get an exception that contains the error number as .errno
.
errno.EINPROGRESS
indicates that the connection is in progress, but hasn’t
finished yet. Different OSes will return different values, so you’re going to
have to check what’s returned on your system.
You can use the connect_ex()
method
to avoid creating an exception.
It will just return the errno value.
To poll, you can call connect_ex()
again later
– 0
or errno.EISCONN
indicate that you’re connected – or you can pass this
socket to select.select()
to check if it’s writable.
Databases¶
Are there any interfaces to database packages in Python?¶
Yes.
Interfaces to disk-based hashes such as DBM
and GDBM
are also included with standard Python. There is also the
sqlite3
module, which provides a lightweight disk-based relational
database.
Support for most relational databases is available. See the DatabaseProgramming wiki page for details.
How do you implement persistent objects in Python?¶
The pickle
library module solves this in a very general way (though you
still can’t store things like open files, sockets or windows), and the
shelve
library module uses pickle and (g)dbm to create persistent
mappings containing arbitrary Python objects.
Mathematics and Numerics¶
How do I generate random numbers in Python?¶
The standard module random
implements a random number generator. Usage
is simple:
import random
random.random()
This returns a random floating point number in the range [0, 1).
There are also many other specialized generators in this module, such as:
randrange(a, b)
chooses an integer in the range [a, b).uniform(a, b)
chooses a floating point number in the range [a, b).normalvariate(mean, sdev)
samples the normal (Gaussian) distribution.
Some higher-level functions operate on sequences directly, such as:
choice(S)
chooses a random element from a given sequence.shuffle(L)
shuffles a list in-place, i.e. permutes it randomly.
There’s also a Random
class you can instantiate to create independent
multiple random number generators.