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Python is the main scripting language used at Google. This style guide is a list of dos and don'ts for Python programs.
To help you format code correctly, we've created a settings file for Vim. For Emacs, the default settings should be fine.
pylint
over your code.
Definition: pylint is a tool for finding bugs and style problems in Python source code. It finds problems that are typically caught by a compiler for less dynamic languages like C and C++. Because of the dynamic nature of Python, some warnings may be incorrect; however, spurious warnings should be fairly infrequent.
Pros: Catches easy-to-miss errors like typos, using-vars-before-assignment, etc.
Cons:
pylint
isn't perfect. To take advantage of it, we'll need to sometimes:
a) Write around it b) Suppress its warnings or c) Improve it.
Decision:
Make sure you run pylint
on your code.
Suppress warnings if they are inappropriate so that other issues are
not hidden.
To suppress warnings, you can set a line-level comment:
dict = 'something awful' # Bad Idea... pylint: disable=redefined-builtin
pylint
warnings are each identified by a alphanumeric code
(C0112
) and a symbolic name
(empty-docstring
). Prefer the symbolic
names in new code or when updating existing code.
If the reason for the suppression is not clear from the symbolic name, add an explanation.
Suppressing in this way has the advantage that we can easily search for suppressions and revisit them.
You can get a list of
pylint
warnings by doing
pylint --list-msgs
.
To get more information on a particular message, use
pylint --help-msg=C6409
.
Prefer pylint: disable
to the deprecated older form
pylint: disable-msg
.
Unused argument warnings can be suppressed by using `_' as the identifier for the unused argument or prefixing the argument name with `unused_'. In situations where changing the argument names is infeasible, you can mention them at the beginning of the function. For example:
def foo(a, unused_b, unused_c, d=None, e=None): _ = d, e return a
import
s for packages and modules only.
Definition: Reusability mechanism for sharing code from one module to another.
Pros:
The namespace management convention is simple. The source of each
identifier is indicated in a consistent way; x.Obj
says
that object Obj
is defined in module x
.
Cons: Module names can still collide. Some module names are inconveniently long.
Decision:
Use import x
for importing packages and modules.
Use from x import y
where x
is
the package prefix and y
is the module name with no
prefix.
Use from x import y as z
if two modules named
y
are to be imported or if y
is an
inconveniently long name.
sound.effects.echo
may be imported as follows:
from sound.effects import echo ... echo.EchoFilter(input, output, delay=0.7, atten=4)
Do not use relative names in imports. Even if the module is in the same package, use the full package name. This helps prevent unintentionally importing a package twice.
Pros: Avoids conflicts in module names. Makes it easier to find modules.
Cons: Makes it harder to deploy code because you have to replicate the package hierarchy.
Decision: All new code should import each module by its full package name.
Imports should be as follows:
# Reference in code with complete name. import sound.effects.echo # Reference in code with just module name (preferred). from sound.effects import echo
Definition: Exceptions are a means of breaking out of the normal flow of control of a code block to handle errors or other exceptional conditions.
Pros: The control flow of normal operation code is not cluttered by error-handling code. It also allows the control flow to skip multiple frames when a certain condition occurs, e.g., returning from N nested functions in one step instead of having to carry-through error codes.
Cons: May cause the control flow to be confusing. Easy to miss error cases when making library calls.
Decision: Exceptions must follow certain conditions:
raise MyException('Error
message')
or raise MyException
. Do not
use the two-argument form (raise MyException, 'Error
message'
) or deprecated string-based exceptions
(raise 'Error message'
).Error
.
class Error(Exception):
pass
except:
statements, or
catch Exception
or StandardError
,
unless you are re-raising the exception or in the outermost
block in your thread (and printing an error message). Python
is very tolerant in this regard and except:
will
really catch everything including misspelled names, sys.exit()
calls, Ctrl+C interrupts, unittest failures and all kinds of
other exceptions that you simply don't want to catch.try
/except
block. The larger the
body of the try
, the more likely that an
exception will be raised by a line of code that you didn't
expect to raise an exception. In those cases,
the try
/except
block hides a real
error.finally
clause to execute code whether
or not an exception is raised in the try
block.
This is often useful for cleanup, i.e., closing a file.as
rather than
a comma. For example:
try: raise Error except Error as error: pass
Definition: Variables that are declared at the module level.
Pros: Occasionally useful.
Cons: Has the potential to change module behavior during the import, because assignments to module-level variables are done when the module is imported.
Decision: Avoid global variables in favor of class variables. Some exceptions are:
PI = 3.14159
.
Constants should be named using all caps with underscores;
see Naming below.Definition: A class can be defined inside of a method, function, or class. A function can be defined inside a method or function. Nested functions have read-only access to variables defined in enclosing scopes.
Pros: Allows definition of utility classes and functions that are only used inside of a very limited scope. Very ADT-y.
Cons: Instances of nested or local classes cannot be pickled.
Decision: They are fine.
Definition:
List comprehensions and generator expressions provide a concise
and efficient way to create lists and iterators without
resorting to the use of map()
,
filter()
, or lambda
.
Pros: Simple list comprehensions can be clearer and simpler than other list creation techniques. Generator expressions can be very efficient, since they avoid the creation of a list entirely.
Cons: Complicated list comprehensions or generator expressions can be hard to read.
Decision:
Okay to use for simple cases. Each portion must fit on one line:
mapping expression, for
clause, filter expression.
Multiple for
clauses or filter expressions are not
permitted. Use loops instead when things get more complicated.
Yes: result = [] for x in range(10): for y in range(5): if x * y > 10: result.append((x, y)) for x in xrange(5): for y in xrange(5): if x != y: for z in xrange(5): if y != z: yield (x, y, z) return ((x, complicated_transform(x)) for x in long_generator_function(parameter) if x is not None) squares = [x * x for x in range(10)] eat(jelly_bean for jelly_bean in jelly_beans if jelly_bean.color == 'black')
No: result = [(x, y) for x in range(10) for y in range(5) if x * y > 10] return ((x, y, z) for x in xrange(5) for y in xrange(5) if x != y for z in xrange(5) if y != z)
Definition: Container types, like dictionaries and lists, define default iterators and membership test operators ("in" and "not in").
Pros: The default iterators and operators are simple and efficient. They express the operation directly, without extra method calls. A function that uses default operators is generic. It can be used with any type that supports the operation.
Cons: You can't tell the type of objects by reading the method names (e.g. has_key() means a dictionary). This is also an advantage.
Decision: Use default iterators and operators for types that support them, like lists, dictionaries, and files. The built-in types define iterator methods, too. Prefer these methods to methods that return lists, except that you should not mutate a container while iterating over it.
Yes: for key in adict: ... if key not in adict: ... if obj in alist: ... for line in afile: ... for k, v in dict.iteritems(): ...
No: for key in adict.keys(): ... if not adict.has_key(key): ... for line in afile.readlines(): ...
Definition: A generator function returns an iterator that yields a value each time it executes a yield statement. After it yields a value, the runtime state of the generator function is suspended until the next value is needed.
Pros: Simpler code, because the state of local variables and control flow are preserved for each call. A generator uses less memory than a function that creates an entire list of values at once.
Cons: None.
Decision: Fine. Use "Yields:" rather than "Returns:" in the doc string for generator functions.
Definition:
Lambdas define anonymous functions in an expression, as
opposed to a statement. They are often used to define callbacks or
operators for higher-order functions like map()
and
filter()
.
Pros: Convenient.
Cons: Harder to read and debug than local functions. The lack of names means stack traces are more difficult to understand. Expressiveness is limited because the function may only contain an expression.
Decision: Okay to use them for one-liners. If the code inside the lambda function is any longer than 60–80 chars, it's probably better to define it as a regular (nested) function.
For common operations like multiplication, use the functions from the
operator
module instead of lambda functions. For
example, prefer operator.mul
to lambda
x, y: x * y
.
Definition:
Conditional expressions are mechanisms that provide a shorter syntax
for if statements. For example:
x = 1 if cond else 2
.
Pros: Shorter and more convenient than an if statement.
Cons: May be harder to read than an if statement. The condition may be difficult to locate if the expression is long.
Decision: Okay to use for one-liners. In other cases prefer to use a complete if statement.
Definition:
You can specify values for variables at the end of a function's
parameter list, e.g., def foo(a, b=0):
. If
foo
is called with only one argument,
b
is set to 0. If it is called with two arguments,
b
has the value of the second argument.
Pros: Often you have a function that uses lots of default values, but—rarely—you want to override the defaults. Default argument values provide an easy way to do this, without having to define lots of functions for the rare exceptions. Also, Python does not support overloaded methods/functions and default arguments are an easy way of "faking" the overloading behavior.
Cons: Default arguments are evaluated once at module load time. This may cause problems if the argument is a mutable object such as a list or a dictionary. If the function modifies the object (e.g., by appending an item to a list), the default value is modified.
Decision: Okay to use with the following caveat:
Do not use mutable objects as default values in the function or method definition.
Yes: def foo(a, b=None): if b is None: b = []
No: def foo(a, b=[]): ... No: def foo(a, b=time.time()): # The time the module was loaded??? ... No: def foo(a, b=FLAGS.my_thing): # sys.argv has not yet been parsed... ...
Definition: A way to wrap method calls for getting and setting an attribute as a standard attribute access when the computation is lightweight.
Pros: Readability is increased by eliminating explicit get and set method calls for simple attribute access. Allows calculations to be lazy. Considered the Pythonic way to maintain the interface of a class. In terms of performance, allowing properties bypasses needing trivial accessor methods when a direct variable access is reasonable. This also allows accessor methods to be added in the future without breaking the interface.
Cons: Properties are specified after the getter and
setter methods are declared, requiring one to notice they are
used for properties farther down in the code (except for readonly
properties created with the @property
decorator - see
below). Must inherit from
object
. Can hide side-effects much like operator
overloading. Can be confusing for subclasses.
Decision: Use properties in new code to access or
set data where you would normally have used simple, lightweight
accessor or setter methods. Read-only properties should be created
with the @property
decorator.
Yes: import math class Square(object): """A square with two properties: a writable area and a read-only perimeter. To use: >>> sq = Square(3) >>> sq.area 9 >>> sq.perimeter 12 >>> sq.area = 16 >>> sq.side 4 >>> sq.perimeter 16 """ def __init__(self, side): self.side = side def __get_area(self): """Calculates the 'area' property.""" return self.side ** 2 def ___get_area(self): """Indirect accessor for 'area' property.""" return self.__get_area() def __set_area(self, area): """Sets the 'area' property.""" self.side = math.sqrt(area) def ___set_area(self, area): """Indirect setter for 'area' property.""" self.__set_area(area) area = property(___get_area, ___set_area, doc="""Gets or sets the area of the square.""") @property def perimeter(self): return self.side * 4
Definition: Python evaluates certain values as false
when in a boolean context. A quick "rule of thumb" is that all
"empty" values are considered false
so 0, None, [], {},
''
all evaluate as false
in a boolean context.
Pros: Conditions using Python booleans are easier to read and less error-prone. In most cases, they're also faster.
Cons: May look strange to C/C++ developers.
Decision:
Use the "implicit" false if at all possible, e.g., if
foo:
rather than if foo != []:
. There are a
few caveats that you should keep in mind though:
==
or !=
to compare
singletons like None
. Use is
or is not
.if x:
when you really mean
if x is not None:
—e.g., when testing whether
a variable or argument that defaults to None
was
set to some other value. The other value might be a value
that's false in a boolean context!False
using
==
. Use if not x:
instead. If
you need to distinguish False
from
None
then chain the expressions,
such as if not x and x is not None:
.
if not seq:
or
if seq:
is preferable to if
len(seq):
or if not
len(seq):
.None
as 0). You may
compare a value which is known to be an integer (and is not the
result of len()
) against the integer 0.
Yes: if not users: print 'no users' if foo == 0: self.handle_zero() if i % 10 == 0: self.handle_multiple_of_ten()
No: if len(users) == 0: print 'no users' if foo is not None and not foo: self.handle_zero() if not i % 10: self.handle_multiple_of_ten()
'0'
(i.e., 0
as string)
evaluates to true.string
module
where possible. Use function call syntax instead
of apply
. Use list comprehensions
and for
loops instead of filter
and
map
when the function argument would have been an
inlined lambda anyway. Use for
loops instead of
reduce
.
Definition: Current versions of Python provide alternative constructs that people find generally preferable.
Decision: We do not use any Python version which does not support these features, so there is no reason not to use the new styles.
Yes: words = foo.split(':') [x[1] for x in my_list if x[2] == 5] map(math.sqrt, data) # Ok. No inlined lambda expression. fn(*args, **kwargs)
No: words = string.split(foo, ':') map(lambda x: x[1], filter(lambda x: x[2] == 5, my_list)) apply(fn, args, kwargs)
Definition: A nested Python function can refer to variables defined in enclosing functions, but can not assign to them. Variable bindings are resolved using lexical scoping, that is, based on the static program text. Any assignment to a name in a block will cause Python to treat all references to that name as a local variable, even if the use precedes the assignment. If a global declaration occurs, the name is treated as a global variable.
An example of the use of this feature is:
def get_adder(summand1): """Returns a function that adds numbers to a given number.""" def adder(summand2): return summand1 + summand2 return adder
Pros: Often results in clearer, more elegant code. Especially comforting to experienced Lisp and Scheme (and Haskell and ML and …) programmers.
Cons: Can lead to confusing bugs. Such as this example based on PEP-0227:
i = 4 def foo(x): def bar(): print i, # ... # A bunch of code here # ... for i in x: # Ah, i *is* local to Foo, so this is what Bar sees print i, bar()
So foo([1, 2, 3])
will print 1 2 3 3
, not
1 2 3 4
.
Decision: Okay to use.
Definition:
Decorators
for Functions and Methods
(a.k.a "the @
notation").
The most common decorators are @classmethod
and
@staticmethod
, for converting ordinary methods to class or
static methods. However, the decorator syntax allows for
user-defined decorators as well. Specifically, for some function
my_decorator
, this:
class C(object): @my_decorator def method(self): # method body ...
class C(object): def method(self): # method body ... method = my_decorator(method)
Pros: Elegantly specifies some transformation on a method; the transformation might eliminate some repetitive code, enforce invariants, etc.
Cons: Decorators can perform arbitrary operations on a function's arguments or return values, resulting in surprising implicit behavior. Additionally, decorators execute at import time. Failures in decorator code are pretty much impossible to recover from.
Decision: Use decorators judiciously when there is a clear advantage. Decorators should follow the same import and naming guidelines as functions. Decorator pydoc should clearly state that the function is a decorator. Write unit tests for decorators.
Avoid external dependencies in the decorator itself (e.g. don't rely on
files, sockets, database connections, etc.), since they might not be
available when the decorator runs (at import time, perhaps from
pydoc
or other tools). A decorator that is
called with valid parameters should (as much as possible) be guaranteed
to succeed in all cases.
Decorators are a special case of "top level code" - see main for more discussion.
While Python's built-in data types such as dictionaries appear
to have atomic operations, there are corner cases where they
aren't atomic (e.g. if __hash__
or
__eq__
are implemented as Python methods) and their
atomicity should not be relied upon. Neither should you rely on
atomic variable assignment (since this in turn depends on
dictionaries).
Use the Queue module's Queue
data type as the preferred
way to
communicate data between threads. Otherwise, use the threading
module and its locking primitives. Learn about the proper use
of condition variables so you can use
threading.Condition
instead of using lower-level
locks.
Definition: Python is an extremely flexible language and gives you many fancy features such as metaclasses, access to bytecode, on-the-fly compilation, dynamic inheritance, object reparenting, import hacks, reflection, modification of system internals, etc.
Pros: These are powerful language features. They can make your code more compact.
Cons: It's very tempting to use these "cool" features when they're not absolutely necessary. It's harder to read, understand, and debug code that's using unusual features underneath. It doesn't seem that way at first (to the original author), but when revisiting the code, it tends to be more difficult than code that is longer but is straightforward.
Decision: Avoid these features in your code.
Exceptions:
Do not use backslash line continuation.
Make use of Python's implicit line joining inside parentheses, brackets and braces. If necessary, you can add an extra pair of parentheses around an expression.
Yes: foo_bar(self, width, height, color='black', design=None, x='foo', emphasis=None, highlight=0) if (width == 0 and height == 0 and color == 'red' and emphasis == 'strong'):
When a literal string won't fit on a single line, use parentheses for implicit line joining.
x = ('This will build a very long long ' 'long long long long long long string')
Within comments, put long URLs on their own line if necessary.
Yes: # See details at # https://www.example.com/us/developer/documentation/api/content/v2.0/csv_file_name_extension_full_specification.html
No: # See details at # https://www.example.com/us/developer/documentation/api/content/\ # v2.0/csv_file_name_extension_full_specification.html
Make note of the indentation of the elements in the line continuation examples above; see the indentation section for explanation.
Do not use them in return statements or conditional statements unless using parentheses for implied line continuation. (See above.) It is however fine to use parentheses around tuples.
Yes: if foo: bar() while x: x = bar() if x and y: bar() if not x: bar() return foo for (x, y) in dict.items(): ...
No: if (x): bar() if not(x): bar() return (foo)
Never use tabs or mix tabs and spaces. In cases of implied line continuation, you should align wrapped elements either vertically, as per the examples in the line length section; or using a hanging indent of 4 spaces, in which case there should be no argument on the first line.
Yes: # Aligned with opening delimiter foo = long_function_name(var_one, var_two, var_three, var_four) # Aligned with opening delimiter in a dictionary foo = { long_dictionary_key: value1 + value2, ... } # 4-space hanging indent; nothing on first line foo = long_function_name( var_one, var_two, var_three, var_four) # 4-space hanging indent in a dictionary foo = { long_dictionary_key: long_dictionary_value, ... }
No: # Stuff on first line forbidden foo = long_function_name(var_one, var_two, var_three, var_four) # 2-space hanging indent forbidden foo = long_function_name( var_one, var_two, var_three, var_four) # No hanging indent in a dictionary foo = { long_dictionary_key: long_dictionary_value, ... }
Two blank lines between top-level definitions, be they function
or class definitions. One blank line between method definitions
and between the class
line and the first method.
Use single blank lines as you judge appropriate within functions or
methods.
No whitespace inside parentheses, brackets or braces.
Yes: spam(ham[1], {eggs: 2}, [])
No: spam( ham[ 1 ], { eggs: 2 }, [ ] )
No whitespace before a comma, semicolon, or colon. Do use whitespace after a comma, semicolon, or colon except at the end of the line.
Yes: if x == 4:
print x, y
x, y = y, x
No: if x == 4 :
print x , y
x , y = y , x
No whitespace before the open paren/bracket that starts an argument list, indexing or slicing.
Yes: spam(1)
No: spam (1)
Yes: dict['key'] = list[index]
No: dict ['key'] = list [index]
Surround binary operators with a single space on either side for
assignment (=
), comparisons (==, <, >, !=,
<>, <=, >=, in, not in, is, is not
), and Booleans
(and, or, not
). Use your better judgment for the
insertion of spaces around arithmetic operators but always be
consistent about whitespace on either side of a binary operator.
Yes: x == 1
No: x<1
Don't use spaces around the '=' sign when used to indicate a keyword argument or a default parameter value.
Yes: def complex(real, imag=0.0): return magic(r=real, i=imag)
No: def complex(real, imag = 0.0): return magic(r = real, i = imag)
Don't use spaces to vertically align tokens on consecutive lines, since it
becomes a maintenance burden (applies to :
, #
,
=
, etc.):
Yes: foo = 1000 # comment long_name = 2 # comment that should not be aligned dictionary = { 'foo': 1, 'long_name': 2, }
No: foo = 1000 # comment long_name = 2 # comment that should not be aligned dictionary = { 'foo' : 1, 'long_name': 2, }
.py
files do not need to start with a
#!
line. Start the main file of a
program with
#!/usr/bin/env python
with an optional single digit
2
or 3
suffix.
This line is used by the kernel to find the Python interpreter, but is ignored by Python when importing modules. It is only necessary on a file that will be executed directly.
Doc Strings
Python has a unique commenting style using doc strings. A doc
string is a string that is the first statement in a package,
module, class or function. These strings can be extracted
automatically through the __doc__
member of the
object and are used by pydoc
. (Try running
pydoc
on your module to see how it looks.) We
always use the three double-quote """
format for doc strings
(per PEP 257).
A doc string should be organized as a
summary line (one physical line) terminated by a period,
question mark, or exclamation point, followed by a blank line,
followed by the rest of the doc string starting at the same
cursor position as the first quote of the first line. There are
more formatting guidelines for doc strings below.
Modules
Every file should contain license boilerplate. Choose the appropriate boilerplate for the license used by the project (for example, Apache 2.0, BSD, LGPL, GPL)
Functions and Methods
As used in this section "function" applies to methods, function, and generators.
A function must have a docstring, unless it meets all of the following criteria:
A docstring should give enough information to write a call to the function without reading the function's code. A docstring should describe the function's calling syntax and its semantics, not its implementation. For tricky code, comments alongside the code are more appropriate than using docstrings.
Certain aspects of a function should be documented in special sections, listed below. Each section begins with a heading line, which ends with a colon. Sections should be indented two spaces, except for the heading.
The description should mention required type(s) and the meaning of the argument.
If a function accepts *foo (variable length argument lists) and/or **bar (arbitrary keyword arguments), they should be listed as *foo and **bar.
def fetch_bigtable_rows(big_table, keys, other_silly_variable=None): """Fetches rows from a Bigtable. Retrieves rows pertaining to the given keys from the Table instance represented by big_table. Silly things may happen if other_silly_variable is not None. Args: big_table: An open Bigtable Table instance. keys: A sequence of strings representing the key of each table row to fetch. other_silly_variable: Another optional variable, that has a much longer name than the other args, and which does nothing. Returns: A dict mapping keys to the corresponding table row data fetched. Each row is represented as a tuple of strings. For example: {'Serak': ('Rigel VII', 'Preparer'), 'Zim': ('Irk', 'Invader'), 'Lrrr': ('Omicron Persei 8', 'Emperor')} If a key from the keys argument is missing from the dictionary, then that row was not found in the table. Raises: IOError: An error occurred accessing the bigtable.Table object. """ pass
Classes
Classes should have a doc string below the class definition describing the class. If your class has public attributes, they should be documented here in an Attributes section and follow the same formatting as a function's Args section.
class SampleClass(object): """Summary of class here. Longer class information.... Longer class information.... Attributes: likes_spam: A boolean indicating if we like SPAM or not. eggs: An integer count of the eggs we have laid. """ def __init__(self, likes_spam=False): """Inits SampleClass with blah.""" self.likes_spam = likes_spam self.eggs = 0 def public_method(self): """Performs operation blah."""
Block and Inline Comments
The final place to have comments is in tricky parts of the code. If you're going to have to explain it at the next code review, you should comment it now. Complicated operations get a few lines of comments before the operations commence. Non-obvious ones get comments at the end of the line.
# We use a weighted dictionary search to find out where i is in # the array. We extrapolate position based on the largest num # in the array and the array size and then do binary search to # get the exact number. if i & (i-1) == 0: # true iff i is a power of 2
To improve legibility, these comments should be at least 2 spaces away from the code.
On the other hand, never describe the code. Assume the person reading the code knows Python (though not what you're trying to do) better than you do.
# BAD COMMENT: Now go through the b array and make sure whenever i occurs # the next element is i+1
object
. This also applies to nested classes.
Yes: class SampleClass(object): pass class OuterClass(object): class InnerClass(object): pass class ChildClass(ParentClass): """Explicitly inherits from another class already."""
No: class SampleClass: pass class OuterClass: class InnerClass: pass
Inheriting from object
is needed to make properties work
properly, and it will protect your code from one particular potential
incompatibility with Python 3000. It also defines
special methods that implement the default semantics of objects including
__new__
, __init__
, __delattr__
,
__getattribute__
, __setattr__
,
__hash__
, __repr__
, and __str__
.
format
method or the %
operator for
formatting strings, even when the parameters are all strings. Use your
best judgement to decide between +
and %
(or format
) though.
Yes: x = a + b x = '%s, %s!' % (imperative, expletive) x = '{}, {}!'.format(imperative, expletive) x = 'name: %s; score: %d' % (name, n) x = 'name: {}; score: {}'.format(name, n)
No: x = '%s%s' % (a, b) # use + in this case x = '{}{}'.format(a, b) # use + in this case x = imperative + ', ' + expletive + '!' x = 'name: ' + name + '; score: ' + str(n)
Avoid using the +
and +=
operators to
accumulate a string within a loop. Since strings are immutable, this
creates unnecessary temporary objects and results in quadratic rather
than linear running time. Instead, add each substring to a list
and ''.join
the list after the loop terminates (or, write
each substring to a io.BytesIO
buffer).
Yes: items = ['<table>']
for last_name, first_name in employee_list:
items.append('<tr><td>%s, %s</td></tr>' % (last_name, first_name))
items.append('</table>')
employee_table = ''.join(items)
No: employee_table = '<table>'
for last_name, first_name in employee_list:
employee_table += '<tr><td>%s, %s</td></tr>' % (last_name, first_name)
employee_table += '</table>'
Be consistent with your choice of string quote character within a file.
Pick '
or "
and stick with it.
It is okay to use the other quote character on a string to avoid the
need to \
escape within the string.
GPyLint enforces this.
Yes: Python('Why are you hiding your eyes?') Gollum("I'm scared of lint errors.") Narrator('"Good!" thought a happy Python reviewer.')
No: Python("Why are you hiding your eyes?") Gollum('The lint. It burns. It burns us.') Gollum("Always the great lint. Watching. Watching.")
Prefer """
for multi-line strings rather than
'''
. Projects may choose to use '''
for
all non-docstring multi-line strings if and only if they also use
'
for regular strings.
Doc strings must use """
regardless.
Note that it is often cleaner to
use implicit line joining since multi-line strings do
not flow with the indentation of the rest of the program:
Yes: print ("This is much nicer.\n" "Do it this way.\n")
No: print """This is pretty ugly. Don't do this. """
Leaving files, sockets or other file-like objects open unnecessarily has many downsides, including:
Furthermore, while files and sockets are automatically closed when the file object is destructed, tying the life-time of the file object to the state of the file is poor practice, for several reasons:
The preferred way to manage files is using the "with" statement:
with open("hello.txt") as hello_file: for line in hello_file: print line
For file-like objects that do not support the "with" statement, use contextlib.closing():
import contextlib with contextlib.closing(urllib.urlopen("https://www.python.org/")) as front_page: for line in front_page: print line
Legacy AppEngine code using Python 2.5 may enable the "with" statement using "from __future__ import with_statement".
TODO
comments for code that is temporary, a
short-term solution, or good-enough but not perfect.
TODO
s should include the string TODO
in
all caps, followed by the
name, e-mail address, or other
identifier
of the person who can best provide context about the problem
referenced by the TODO
,
in parentheses. A colon is optional. A comment explaining what there
is to do is required. The main purpose is to have
a consistent TODO
format that can be searched to find the
person who can provide more details upon request. A
TODO
is not a commitment that the person referenced
will fix the problem. Thus when you create a TODO
, it is
almost always your
name
that is given.
# TODO(kl@gmail.com): Use a "*" here for string repetition. # TODO(Zeke) Change this to use relations.
If your TODO
is of the form "At a future date do
something" make sure that you either include a very specific
date ("Fix by November 2009") or a very specific event
("Remove this code when all clients can handle XML responses.").
E.g.:
Yes: import os import sys
No: import os, sys
Imports are always put at the top of the file, just after any module comments and doc strings and before module globals and constants. Imports should be grouped with the order being most generic to least generic:
Within each grouping, imports should be sorted lexicographically, ignoring case, according to each module's full package path.
import foo from foo import bar from foo.bar import baz from foo.bar import Quux from Foob import ar
However, you may put the
result of a test on the same line as the test only if the entire
statement fits on one line. In particular, you can never do so
with try
/except
since the
try
and except
can't both fit on the
same line, and you can only do so with an if
if
there is no else
.
Yes: if foo: bar(foo)
No:
if foo: bar(foo)
else: baz(foo)
try: bar(foo)
except ValueError: baz(foo)
try:
bar(foo)
except ValueError: baz(foo)
property
to keep the syntax consistent.
On the other hand, if access is more complex, or the cost of accessing
the variable is significant, you should use function calls (following the
Naming guidelines) such as get_foo()
and set_foo()
. If the past behavior allowed access through a
property, do not bind the new accessor functions to the property. Any
code still attempting to access the variable by the old method should
break visibly so they are made aware of the change in complexity.
module_name, package_name, ClassName,
method_name, ExceptionName,
function_name, GLOBAL_CONSTANT_NAME,
global_var_name, instance_var_name, function_parameter_name,
local_var_name.
Names to Avoid
-
) in any package/module name__double_leading_and_trailing_underscore__
names
(reserved by Python)Naming Convention
_
) has some
support for protecting module variables and functions (not included
with import * from
). Prepending a double underscore
(__
) to an instance variable or method
effectively serves to make the variable or method private to its class
(using name mangling).import StringIO
or from StringIO import
StringIO
?")Guidelines derived from Guido's Recommendations
Type | Public | Internal |
---|---|---|
Packages | lower_with_under |
|
Modules | lower_with_under |
_lower_with_under |
Classes | CapWords |
_CapWords |
Exceptions | CapWords |
|
Functions | lower_with_under() |
_lower_with_under() |
Global/Class Constants | CAPS_WITH_UNDER |
_CAPS_WITH_UNDER |
Global/Class Variables | lower_with_under |
_lower_with_under |
Instance Variables | lower_with_under |
_lower_with_under (protected) or __lower_with_under (private) |
Method Names | lower_with_under() |
_lower_with_under() (protected) or __lower_with_under() (private) |
Function/Method Parameters | lower_with_under |
|
Local Variables | lower_with_under |
In Python,
pydoc
as well as unit tests
require modules to be importable. Your code should always check
if __name__ == '__main__'
before executing your
main program so that the main program is not executed when the
module is imported.
def main(): ... if __name__ == '__main__': main()
All code at the top level will be executed when the module is
imported. Be careful not to call functions, create objects, or
perform other operations that should not be executed when the
file is being pydoc
ed.
BE CONSISTENT.
If you're editing code, take a few minutes to look at the code around you and determine its style. If they use spaces around all their arithmetic operators, you should too. If their comments have little boxes of hash marks around them, make your comments have little boxes of hash marks around them too.
The point of having style guidelines is to have a common vocabulary of coding so people can concentrate on what you're saying rather than on how you're saying it. We present global style rules here so people know the vocabulary, but local style is also important. If code you add to a file looks drastically different from the existing code around it, it throws readers out of their rhythm when they go to read it. Avoid this.
Revision 2.59
Amit Patel