Is it possible to have assignment in a condition?
if (a=some_func()): # Use a
Is it possible to have assignment in a condition?
if (a=some_func()): # Use a
Why not try it out?
>>> def some_func(): ... return 2 ... >>> a = 2 >>> if (a = some_func()): File "<stdin>", line 1 if (a = some_func()): ^ SyntaxError: invalid syntax >>>
Python 3.8 will bring in PEP572
This is a proposal for creating a way to assign to variables within an expression using the notation NAME := expr. A new exception, TargetScopeError is added, and there is one change to evaluation order.
The "PEP 572 mess" was the topic of a 2018 Python Language Summit session led by benevolent dictator for life (BDFL) Guido van Rossum. PEP 572 seeks to add assignment expressions (or "inline assignments") to the language, but it has seen a prolonged discussion over multiple huge threads on the python-dev mailing list—even after multiple rounds on python-ideas. Those threads were often contentious and were clearly voluminous to the point where many probably just tuned them out. At the summit, Van Rossum gave an overview of the feature proposal, which he seems inclined toward accepting, but he also wanted to discuss how to avoid this kind of thread explosion in the future.
Examples from the Python standard library
site.py env_base is only used on these lines, putting its assignment on the if moves it as the "header" of the block.
env_base = os.environ.get("PYTHONUSERBASE", None) if env_base: return env_base
if env_base := os.environ.get("PYTHONUSERBASE", None): return env_base _pydecimal.py
Avoid nested if and remove one indentation level.
if self._is_special: ans = self._check_nans(context=context) if ans: return ans
if self._is_special and (ans := self._check_nans(context=context)): return ans
copy.py Code looks more regular and avoid multiple nested if. (See Appendix A for the origin of this example.)
reductor = dispatch_table.get(cls) if reductor: rv = reductor(x) else: reductor = getattr(x, "__reduce_ex__", None) if reductor: rv = reductor(4) else: reductor = getattr(x, "__reduce__", None) if reductor: rv = reductor() else: raise Error( "un(deep)copyable object of type %s" % cls)
if reductor := dispatch_table.get(cls): rv = reductor(x) elif reductor := getattr(x, "__reduce_ex__", None): rv = reductor(4) elif reductor := getattr(x, "__reduce__", None): rv = reductor() else: raise Error("un(deep)copyable object of type %s" % cls) datetime.py
tz is only used for s += tz, moving its assignment inside the if helps to show its scope.
s = _format_time(self._hour, self._minute, self._second, self._microsecond, timespec) tz = self._tzstr() if tz: s += tz return s
s = _format_time(self._hour, self._minute, self._second, self._microsecond, timespec) if tz := self._tzstr(): s += tz return s
sysconfig.py Calling fp.readline() in the while condition and calling .match() on the if lines make the code more compact without
making it harder to understand.
while True: line = fp.readline() if not line: break m = define_rx.match(line) if m: n, v = m.group(1, 2) try: v = int(v) except ValueError: pass vars[n] = v else: m = undef_rx.match(line) if m: vars[m.group(1)] = 0
while line := fp.readline(): if m := define_rx.match(line): n, v = m.group(1, 2) try: v = int(v) except ValueError: pass vars[n] = v elif m := undef_rx.match(line): vars[m.group(1)] = 0
Simplifying list comprehensions A list comprehension can map and filter efficiently by capturing the condition:
results = [(x, y, x/y) for x in input_data if (y := f(x)) > 0]
Similarly, a subexpression can be reused within the main expression, by giving it a name on first use:
stuff = [[y := f(x), x/y] for x in range(5)]
Note that in both cases the variable y is bound in the containing scope (i.e. at the same level as results or stuff).
Capturing condition values Assignment expressions can be used to good effect in the header of an if or while statement:
# Loop-and-a-half while (command := input("> ")) != "quit": print("You entered:", command) # Capturing regular expression match objects # See, for instance, Lib/pydoc.py, which uses a multiline spelling # of this effect if match := re.search(pat, text): print("Found:", match.group(0)) # The same syntax chains nicely into 'elif' statements, unlike the # equivalent using assignment statements. elif match := re.search(otherpat, text): print("Alternate found:", match.group(0)) elif match := re.search(third, text): print("Fallback found:", match.group(0)) # Reading socket data until an empty string is returned while data := sock.recv(8192): print("Received data:", data)
Particularly with the while loop, this can remove the need to have an infinite loop, an assignment, and a condition. It also creates a smooth parallel between a loop which simply uses a function call as its condition, and one which uses that as its condition but also uses the actual value.
Fork An example from the low-level UNIX world:
if pid := os.fork(): # Parent code else: # Child code
Note that in Python, unlike C, assignment cannot occur inside expressions. C programmers may grumble about this, but it avoids a common class of problems encountered in C programs: typing = in an expression when == was intended.
Nope, the BDFL didn't like that feature.
From where I sit, Guido van Rossum, "Benevolent Dictator For Life”, has fought hard to keep Python as simple as it can be. We can quibble with some of the decisions he's made -- I'd have preferred he said 'No' more often. But the fact that there hasn't been a committee designing Python, but instead a trusted "advisory board", based largely on merit, filtering through one designer's sensibilities, has produced one hell of a nice language, IMHO.
Not directly, per this old recipe of mine -- but as the recipe says it's easy to build the semantic equivalent, e.g. if you need to transliterate directly from a C-coded reference algorithm (before refactoring to more-idiomatic Python, of course;-). I.e.:
class DataHolder(object): def __init__(self, value=None): self.value = value def set(self, value): self.value = value; return value def get(self): return self.value data = DataHolder() while data.set(somefunc()): a = data.get() # use a
BTW, a very idiomatic Pythonic form for your specific case, if you know exactly what falsish value
somefunc may return when it does return a falsish value (e.g.
for a in iter(somefunc, 0): # use a
so in this specific case the refactoring would be pretty easy;-).
If the return could be any kind of falsish value (0,
'', ...), one possibility is:
import itertools for a in itertools.takewhile(lambda x: x, iter(somefunc, object())): # use a
but you might prefer a simple custom generator:
def getwhile(func, *a, **k): while True: x = func(*a, **k) if not x: break yield x for a in getwhile(somefunc): # use a
Yes, but only from Python 3.8 and onwards.
PEP 572 proposes Assignment Expressions and has already been accepted.
Quoting the Syntax and semantics part of the PEP:
# Handle a matched regex if (match := pattern.search(data)) is not None: # Do something with match # A loop that can't be trivially rewritten using 2-arg iter() while chunk := file.read(8192): process(chunk) # Reuse a value that's expensive to compute [y := f(x), y**2, y**3] # Share a subexpression between a comprehension filter clause and its output filtered_data = [y for x in data if (y := f(x)) is not None]
In your specific case, you will be able to write
if a := some_func(): # Use a
Thanks to Python 3.8 new feature it will be possible to do such a thing from this version, although not using
= but Ada-like assignment operator
:=. Example from the docs:
# Handle a matched regex if (match := pattern.search(data)) is not None: # Do something with match
You can define a function to do the assigning for you:
def assign(name, value): import inspect frame = inspect.currentframe() try: locals_ = frame.f_back.f_locals finally: del frame locals_[name] = value return value if assign('test', 0): print("first", test) elif assign('xyz', 123): print("second", xyz)
One of the reasons why assignments are illegal in conditions is that it's easier to make a mistake and assign True or False:
some_variable = 5 # This does not work # if True = some_variable: # do_something() # This only works in Python 2.x True = some_variable print True # returns 5
In Python 3 True and False are keywords, so no risk anymore.
The assignment operator - also known informally as the the walrus operator - was created at 28-Feb-2018 in PEP572.
For the sake of completeness, I'll post the relevant parts so you can compare the differences between 3.7 and 3.8:
3.7 --- if_stmt: 'if' test ':' suite ('elif' test ':' suite)* ['else' ':' suite] suite: simple_stmt | NEWLINE INDENT stmt+ DEDENT test: or_test ['if' or_test 'else' test] | lambdef test_nocond: or_test | lambdef_nocond lambdef: 'lambda' [varargslist] ':' test lambdef_nocond: 'lambda' [varargslist] ':' test_nocond or_test: and_test ('or' and_test)* and_test: not_test ('and' not_test)* not_test: 'not' not_test | comparison comparison: expr (comp_op expr)* 3.8 --- if_stmt: 'if' namedexpr_test ':' suite ('elif' namedexpr_test ':' suite)* ['else' ':' suite] namedexpr_test: test [':=' test] <---- WALRUS OPERATOR!!! test: or_test ['if' or_test 'else' test] | lambdef or_test: and_test ('or' and_test)* and_test: not_test ('and' not_test)* not_test: 'not' not_test | comparison comparison: expr (comp_op expr)*