Related
In Python, what happens when two modules attempt to import each other? More generally, what happens if multiple modules attempt to import in a cycle?
See also What can I do about "ImportError: Cannot import name X" or "AttributeError: ... (most likely due to a circular import)"? for the common problem that may result, and advice on how to rewrite code to avoid such imports. See Why do circular imports seemingly work further up in the call stack but then raise an ImportError further down? for technical details on why and how the problem occurs.
If you do import foo (inside bar.py) and import bar (inside foo.py), it will work fine. By the time anything actually runs, both modules will be fully loaded and will have references to each other.
The problem is when instead you do from foo import abc (inside bar.py) and from bar import xyz (inside foo.py). Because now each module requires the other module to already be imported (so that the name we are importing exists) before it can be imported.
There was a really good discussion on this over at comp.lang.python last year. It answers your question pretty thoroughly.
Imports are pretty straightforward really. Just remember the following:
'import' and 'from xxx import yyy' are executable statements. They execute
when the running program reaches that line.
If a module is not in sys.modules, then an import creates the new module
entry in sys.modules and then executes the code in the module. It does not
return control to the calling module until the execution has completed.
If a module does exist in sys.modules then an import simply returns that
module whether or not it has completed executing. That is the reason why
cyclic imports may return modules which appear to be partly empty.
Finally, the executing script runs in a module named __main__, importing
the script under its own name will create a new module unrelated to
__main__.
Take that lot together and you shouldn't get any surprises when importing
modules.
Cyclic imports terminate, but you need to be careful not to use the cyclically-imported modules during module initialization.
Consider the following files:
a.py:
print "a in"
import sys
print "b imported: %s" % ("b" in sys.modules, )
import b
print "a out"
b.py:
print "b in"
import a
print "b out"
x = 3
If you execute a.py, you'll get the following:
$ python a.py
a in
b imported: False
b in
a in
b imported: True
a out
b out
a out
On the second import of b.py (in the second a in), the Python interpreter does not import b again, because it already exists in the module dict.
If you try to access b.x from a during module initialization, you will get an AttributeError.
Append the following line to a.py:
print b.x
Then, the output is:
$ python a.py
a in
b imported: False
b in
a in
b imported: True
a out
Traceback (most recent call last):
File "a.py", line 4, in <module>
import b
File "/home/shlomme/tmp/x/b.py", line 2, in <module>
import a
File "/home/shlomme/tmp/x/a.py", line 7, in <module>
print b.x
AttributeError: 'module' object has no attribute 'x'
This is because modules are executed on import and at the time b.x is accessed, the line x = 3 has not be executed yet, which will only happen after b out.
As other answers describe this pattern is acceptable in python:
def dostuff(self):
from foo import bar
...
Which will avoid the execution of the import statement when the file is imported by other modules. Only if there is a logical circular dependency, this will fail.
Most Circular Imports are not actually logical circular imports but rather raise ImportError errors, because of the way import() evaluates top level statements of the entire file when called.
These ImportErrors can almost always be avoided if you positively want your imports on top:
Consider this circular import:
App A
# profiles/serializers.py
from images.serializers import SimplifiedImageSerializer
class SimplifiedProfileSerializer(serializers.Serializer):
name = serializers.CharField()
class ProfileSerializer(SimplifiedProfileSerializer):
recent_images = SimplifiedImageSerializer(many=True)
App B
# images/serializers.py
from profiles.serializers import SimplifiedProfileSerializer
class SimplifiedImageSerializer(serializers.Serializer):
title = serializers.CharField()
class ImageSerializer(SimplifiedImageSerializer):
profile = SimplifiedProfileSerializer()
From David Beazleys excellent talk Modules and Packages: Live and Let Die! - PyCon 2015, 1:54:00, here is a way to deal with circular imports in python:
try:
from images.serializers import SimplifiedImageSerializer
except ImportError:
import sys
SimplifiedImageSerializer = sys.modules[__package__ + '.SimplifiedImageSerializer']
This tries to import SimplifiedImageSerializer and if ImportError is raised, because it already is imported, it will pull it from the importcache.
PS: You have to read this entire post in David Beazley's voice.
To my surprise, no one has mentioned cyclic imports caused by type hints yet.
If you have cyclic imports only as a result of type hinting, they can be avoided in a clean manner.
Consider main.py which makes use of exceptions from another file:
from src.exceptions import SpecificException
class Foo:
def __init__(self, attrib: int):
self.attrib = attrib
raise SpecificException(Foo(5))
And the dedicated exception class exceptions.py:
from src.main import Foo
class SpecificException(Exception):
def __init__(self, cause: Foo):
self.cause = cause
def __str__(self):
return f'Expected 3 but got {self.cause.attrib}.'
This will raise an ImportError since main.py imports exception.py and vice versa through Foo and SpecificException.
Because Foo is only required in exceptions.py during type checking, we can safely make its import conditional using the TYPE_CHECKING constant from the typing module. The constant is only True during type checking, which allows us to conditionally import Foo and thereby avoid the circular import error.
Something to note is that by doing so, Foo is not declared in exceptions.py at runtime, which leads to a NameError. To avoid that, we add from __future__ import annotations which transforms all type annotations in the module to strings.
Hence, we get the following code for Python 3.7+:
from __future__ import annotations
from typing import TYPE_CHECKING
if TYPE_CHECKING: # Only imports the below statements during type checking
from src.main import Foo
class SpecificException(Exception):
def __init__(self, cause: Foo): # Foo becomes 'Foo' because of the future import
self.cause = cause
def __str__(self):
return f'Expected 3 but got {self.cause.attrib}.'
In Python 3.6, the future import does not exist, so Foo has to be a string:
from typing import TYPE_CHECKING
if TYPE_CHECKING: # Only imports the below statements during type checking
from src.main import Foo
class SpecificException(Exception):
def __init__(self, cause: 'Foo'): # Foo has to be a string
self.cause = cause
def __str__(self):
return f'Expected 3 but got {self.cause.attrib}.'
In Python 3.5 and below, the type hinting functionality did not exist yet.
In future versions of Python, the annotations feature may become mandatory, after which the future import will no longer be necessary. Which version this will occur in is yet to be determined.
This answer is based on Yet another solution to dig you out of a circular import hole in Python by Stefaan Lippens.
Module a.py :
import b
print("This is from module a")
Module b.py
import a
print("This is from module b")
Running "Module a" will output:
>>>
'This is from module a'
'This is from module b'
'This is from module a'
>>>
It output this 3 lines while it was supposed to output infinitival because of circular importing.
What happens line by line while running"Module a" is listed here:
The first line is import b. so it will visit module b
The first line at module b is import a. so it will visit module a
The first line at module a is import b but note that this line won't be executed again anymore, because every file in python execute an import line just for once, it does not matter where or when it is executed. so it will pass to the next line and print "This is from module a".
After finish visiting whole module a from module b, we are still at module b. so the next line will print "This is from module b"
Module b lines are executed completely. so we will go back to module a where we started module b.
import b line have been executed already and won't be executed again. the next line will print "This is from module a" and program will be finished.
I got an example here that struck me!
foo.py
import bar
class gX(object):
g = 10
bar.py
from foo import gX
o = gX()
main.py
import foo
import bar
print "all done"
At the command line: $ python main.py
Traceback (most recent call last):
File "m.py", line 1, in <module>
import foo
File "/home/xolve/foo.py", line 1, in <module>
import bar
File "/home/xolve/bar.py", line 1, in <module>
from foo import gX
ImportError: cannot import name gX
There are a lot of great answers here. While there are usually quick solutions to the problem, some of which feel more pythonic than others, if you have the luxury of doing some refactoring, another approach is to analyze the organization of your code, and try to remove the circular dependency. You may find, for example, that you have:
File a.py
from b import B
class A:
#staticmethod
def save_result(result):
print('save the result')
#staticmethod
def do_something_a_ish(param):
A.save_result(A.use_param_like_a_would(param))
#staticmethod
def do_something_related_to_b(param):
B.do_something_b_ish(param)
File b.py
from a import A
class B:
#staticmethod
def do_something_b_ish(param):
A.save_result(B.use_param_like_b_would(param))
In this case, just moving one static method to a separate file, say c.py:
File c.py
def save_result(result):
print('save the result')
will allow removing the save_result method from A, and thus allow removing the import of A from a in b:
Refactored File a.py
from b import B
from c import save_result
class A:
#staticmethod
def do_something_a_ish(param):
save_result(A.use_param_like_a_would(param))
#staticmethod
def do_something_related_to_b(param):
B.do_something_b_ish(param)
Refactored File b.py
from c import save_result
class B:
#staticmethod
def do_something_b_ish(param):
save_result(B.use_param_like_b_would(param))
In summary, if you have a tool (e.g. pylint or PyCharm) that reports on methods that can be static, just throwing a staticmethod decorator on them might not be the best way to silence the warning. Even though the method seems related to the class, it might be better to separate it out, especially if you have several closely related modules that might need the same functionality and you intend to practice DRY principles.
I completely agree with pythoneer's answer here. But I have stumbled on some code that was flawed with circular imports and caused issues when trying to add unit tests. So to quickly patch it without changing everything you can resolve the issue by doing a dynamic import.
# Hack to import something without circular import issue
def load_module(name):
"""Load module using imp.find_module"""
names = name.split(".")
path = None
for name in names:
f, path, info = imp.find_module(name, path)
path = [path]
return imp.load_module(name, f, path[0], info)
constants = load_module("app.constants")
Again, this isn't a permanent fix but may help someone that wants to fix an import error without changing too much of the code.
Cheers!
Circular imports can be confusing because import does two things:
it executes imported module code
adds imported module to importing module global symbol table
The former is done only once, while the latter at each import statement. Circular import creates situation when importing module uses imported one with partially executed code. In consequence it will not see objects created after import statement. Below code sample demonstrates it.
Circular imports are not the ultimate evil to be avoided at all cost. In some frameworks like Flask they are quite natural and tweaking your code to eliminate them does not make the code better.
main.py
print 'import b'
import b
print 'a in globals() {}'.format('a' in globals())
print 'import a'
import a
print 'a in globals() {}'.format('a' in globals())
if __name__ == '__main__':
print 'imports done'
print 'b has y {}, a is b.a {}'.format(hasattr(b, 'y'), a is b.a)
b.by
print "b in, __name__ = {}".format(__name__)
x = 3
print 'b imports a'
import a
y = 5
print "b out"
a.py
print 'a in, __name__ = {}'.format(__name__)
print 'a imports b'
import b
print 'b has x {}'.format(hasattr(b, 'x'))
print 'b has y {}'.format(hasattr(b, 'y'))
print "a out"
python main.py output with comments
import b
b in, __name__ = b # b code execution started
b imports a
a in, __name__ = a # a code execution started
a imports b # b code execution is already in progress
b has x True
b has y False # b defines y after a import,
a out
b out
a in globals() False # import only adds a to main global symbol table
import a
a in globals() True
imports done
b has y True, a is b.a True # all b objects are available
Suppose you are running a test python file named request.py
In request.py, you write
import request
so this also most likely a circular import.
Solution:
Just change your test file to another name such as aaa.py, other than request.py.
Do not use names that are already used by other libs.
I solved the problem the following way, and it works well without any error.
Consider two files a.py and b.py.
I added this to a.py and it worked.
if __name__ == "__main__":
main ()
a.py:
import b
y = 2
def main():
print ("a out")
print (b.x)
if __name__ == "__main__":
main ()
b.py:
import a
print ("b out")
x = 3 + a.y
The output I get is
>>> b out
>>> a out
>>> 5
Ok, I think I have a pretty cool solution.
Let's say you have file a and file b.
You have a def or a class in file b that you want to use in module a, but you have something else, either a def, class, or variable from file a that you need in your definition or class in file b.
What you can do is, at the bottom of file a, after calling the function or class in file a that is needed in file b, but before calling the function or class from file b that you need for file a, say import b
Then, and here is the key part, in all of the definitions or classes in file b that need the def or class from file a (let's call it CLASS), you say from a import CLASS
This works because you can import file b without Python executing any of the import statements in file b, and thus you elude any circular imports.
For example:
File a:
class A(object):
def __init__(self, name):
self.name = name
CLASS = A("me")
import b
go = B(6)
go.dostuff
File b:
class B(object):
def __init__(self, number):
self.number = number
def dostuff(self):
from a import CLASS
print "Hello " + CLASS.name + ", " + str(number) + " is an interesting number."
Voila.
bar.py
print('going to import foo')
from foo import printx
foo.py
print('trying to import bar')
import bar
def printx():
print('x')
$ python bar.py
going to import foo
trying to import bar
going to import foo
Traceback (most recent call last):
File "bar.py", line 2, in <module>
from foo import printx
File "/home/suhail/Desktop/temp/circularimport/foo.py", line 2, in <module>
import bar
File "/home/suhail/Desktop/temp/circularimport/bar.py", line 2, in <module>
from foo import printx
ImportError: cannot import name 'printx' from partially initialized module 'foo' (most likely due to a circular import) (/home/suhail/Desktop/temp/circularimport/foo.py)
In Python, what happens when two modules attempt to import each other? More generally, what happens if multiple modules attempt to import in a cycle?
See also What can I do about "ImportError: Cannot import name X" or "AttributeError: ... (most likely due to a circular import)"? for the common problem that may result, and advice on how to rewrite code to avoid such imports. See Why do circular imports seemingly work further up in the call stack but then raise an ImportError further down? for technical details on why and how the problem occurs.
If you do import foo (inside bar.py) and import bar (inside foo.py), it will work fine. By the time anything actually runs, both modules will be fully loaded and will have references to each other.
The problem is when instead you do from foo import abc (inside bar.py) and from bar import xyz (inside foo.py). Because now each module requires the other module to already be imported (so that the name we are importing exists) before it can be imported.
There was a really good discussion on this over at comp.lang.python last year. It answers your question pretty thoroughly.
Imports are pretty straightforward really. Just remember the following:
'import' and 'from xxx import yyy' are executable statements. They execute
when the running program reaches that line.
If a module is not in sys.modules, then an import creates the new module
entry in sys.modules and then executes the code in the module. It does not
return control to the calling module until the execution has completed.
If a module does exist in sys.modules then an import simply returns that
module whether or not it has completed executing. That is the reason why
cyclic imports may return modules which appear to be partly empty.
Finally, the executing script runs in a module named __main__, importing
the script under its own name will create a new module unrelated to
__main__.
Take that lot together and you shouldn't get any surprises when importing
modules.
Cyclic imports terminate, but you need to be careful not to use the cyclically-imported modules during module initialization.
Consider the following files:
a.py:
print "a in"
import sys
print "b imported: %s" % ("b" in sys.modules, )
import b
print "a out"
b.py:
print "b in"
import a
print "b out"
x = 3
If you execute a.py, you'll get the following:
$ python a.py
a in
b imported: False
b in
a in
b imported: True
a out
b out
a out
On the second import of b.py (in the second a in), the Python interpreter does not import b again, because it already exists in the module dict.
If you try to access b.x from a during module initialization, you will get an AttributeError.
Append the following line to a.py:
print b.x
Then, the output is:
$ python a.py
a in
b imported: False
b in
a in
b imported: True
a out
Traceback (most recent call last):
File "a.py", line 4, in <module>
import b
File "/home/shlomme/tmp/x/b.py", line 2, in <module>
import a
File "/home/shlomme/tmp/x/a.py", line 7, in <module>
print b.x
AttributeError: 'module' object has no attribute 'x'
This is because modules are executed on import and at the time b.x is accessed, the line x = 3 has not be executed yet, which will only happen after b out.
As other answers describe this pattern is acceptable in python:
def dostuff(self):
from foo import bar
...
Which will avoid the execution of the import statement when the file is imported by other modules. Only if there is a logical circular dependency, this will fail.
Most Circular Imports are not actually logical circular imports but rather raise ImportError errors, because of the way import() evaluates top level statements of the entire file when called.
These ImportErrors can almost always be avoided if you positively want your imports on top:
Consider this circular import:
App A
# profiles/serializers.py
from images.serializers import SimplifiedImageSerializer
class SimplifiedProfileSerializer(serializers.Serializer):
name = serializers.CharField()
class ProfileSerializer(SimplifiedProfileSerializer):
recent_images = SimplifiedImageSerializer(many=True)
App B
# images/serializers.py
from profiles.serializers import SimplifiedProfileSerializer
class SimplifiedImageSerializer(serializers.Serializer):
title = serializers.CharField()
class ImageSerializer(SimplifiedImageSerializer):
profile = SimplifiedProfileSerializer()
From David Beazleys excellent talk Modules and Packages: Live and Let Die! - PyCon 2015, 1:54:00, here is a way to deal with circular imports in python:
try:
from images.serializers import SimplifiedImageSerializer
except ImportError:
import sys
SimplifiedImageSerializer = sys.modules[__package__ + '.SimplifiedImageSerializer']
This tries to import SimplifiedImageSerializer and if ImportError is raised, because it already is imported, it will pull it from the importcache.
PS: You have to read this entire post in David Beazley's voice.
To my surprise, no one has mentioned cyclic imports caused by type hints yet.
If you have cyclic imports only as a result of type hinting, they can be avoided in a clean manner.
Consider main.py which makes use of exceptions from another file:
from src.exceptions import SpecificException
class Foo:
def __init__(self, attrib: int):
self.attrib = attrib
raise SpecificException(Foo(5))
And the dedicated exception class exceptions.py:
from src.main import Foo
class SpecificException(Exception):
def __init__(self, cause: Foo):
self.cause = cause
def __str__(self):
return f'Expected 3 but got {self.cause.attrib}.'
This will raise an ImportError since main.py imports exception.py and vice versa through Foo and SpecificException.
Because Foo is only required in exceptions.py during type checking, we can safely make its import conditional using the TYPE_CHECKING constant from the typing module. The constant is only True during type checking, which allows us to conditionally import Foo and thereby avoid the circular import error.
Something to note is that by doing so, Foo is not declared in exceptions.py at runtime, which leads to a NameError. To avoid that, we add from __future__ import annotations which transforms all type annotations in the module to strings.
Hence, we get the following code for Python 3.7+:
from __future__ import annotations
from typing import TYPE_CHECKING
if TYPE_CHECKING: # Only imports the below statements during type checking
from src.main import Foo
class SpecificException(Exception):
def __init__(self, cause: Foo): # Foo becomes 'Foo' because of the future import
self.cause = cause
def __str__(self):
return f'Expected 3 but got {self.cause.attrib}.'
In Python 3.6, the future import does not exist, so Foo has to be a string:
from typing import TYPE_CHECKING
if TYPE_CHECKING: # Only imports the below statements during type checking
from src.main import Foo
class SpecificException(Exception):
def __init__(self, cause: 'Foo'): # Foo has to be a string
self.cause = cause
def __str__(self):
return f'Expected 3 but got {self.cause.attrib}.'
In Python 3.5 and below, the type hinting functionality did not exist yet.
In future versions of Python, the annotations feature may become mandatory, after which the future import will no longer be necessary. Which version this will occur in is yet to be determined.
This answer is based on Yet another solution to dig you out of a circular import hole in Python by Stefaan Lippens.
Module a.py :
import b
print("This is from module a")
Module b.py
import a
print("This is from module b")
Running "Module a" will output:
>>>
'This is from module a'
'This is from module b'
'This is from module a'
>>>
It output this 3 lines while it was supposed to output infinitival because of circular importing.
What happens line by line while running"Module a" is listed here:
The first line is import b. so it will visit module b
The first line at module b is import a. so it will visit module a
The first line at module a is import b but note that this line won't be executed again anymore, because every file in python execute an import line just for once, it does not matter where or when it is executed. so it will pass to the next line and print "This is from module a".
After finish visiting whole module a from module b, we are still at module b. so the next line will print "This is from module b"
Module b lines are executed completely. so we will go back to module a where we started module b.
import b line have been executed already and won't be executed again. the next line will print "This is from module a" and program will be finished.
I got an example here that struck me!
foo.py
import bar
class gX(object):
g = 10
bar.py
from foo import gX
o = gX()
main.py
import foo
import bar
print "all done"
At the command line: $ python main.py
Traceback (most recent call last):
File "m.py", line 1, in <module>
import foo
File "/home/xolve/foo.py", line 1, in <module>
import bar
File "/home/xolve/bar.py", line 1, in <module>
from foo import gX
ImportError: cannot import name gX
There are a lot of great answers here. While there are usually quick solutions to the problem, some of which feel more pythonic than others, if you have the luxury of doing some refactoring, another approach is to analyze the organization of your code, and try to remove the circular dependency. You may find, for example, that you have:
File a.py
from b import B
class A:
#staticmethod
def save_result(result):
print('save the result')
#staticmethod
def do_something_a_ish(param):
A.save_result(A.use_param_like_a_would(param))
#staticmethod
def do_something_related_to_b(param):
B.do_something_b_ish(param)
File b.py
from a import A
class B:
#staticmethod
def do_something_b_ish(param):
A.save_result(B.use_param_like_b_would(param))
In this case, just moving one static method to a separate file, say c.py:
File c.py
def save_result(result):
print('save the result')
will allow removing the save_result method from A, and thus allow removing the import of A from a in b:
Refactored File a.py
from b import B
from c import save_result
class A:
#staticmethod
def do_something_a_ish(param):
save_result(A.use_param_like_a_would(param))
#staticmethod
def do_something_related_to_b(param):
B.do_something_b_ish(param)
Refactored File b.py
from c import save_result
class B:
#staticmethod
def do_something_b_ish(param):
save_result(B.use_param_like_b_would(param))
In summary, if you have a tool (e.g. pylint or PyCharm) that reports on methods that can be static, just throwing a staticmethod decorator on them might not be the best way to silence the warning. Even though the method seems related to the class, it might be better to separate it out, especially if you have several closely related modules that might need the same functionality and you intend to practice DRY principles.
I completely agree with pythoneer's answer here. But I have stumbled on some code that was flawed with circular imports and caused issues when trying to add unit tests. So to quickly patch it without changing everything you can resolve the issue by doing a dynamic import.
# Hack to import something without circular import issue
def load_module(name):
"""Load module using imp.find_module"""
names = name.split(".")
path = None
for name in names:
f, path, info = imp.find_module(name, path)
path = [path]
return imp.load_module(name, f, path[0], info)
constants = load_module("app.constants")
Again, this isn't a permanent fix but may help someone that wants to fix an import error without changing too much of the code.
Cheers!
Circular imports can be confusing because import does two things:
it executes imported module code
adds imported module to importing module global symbol table
The former is done only once, while the latter at each import statement. Circular import creates situation when importing module uses imported one with partially executed code. In consequence it will not see objects created after import statement. Below code sample demonstrates it.
Circular imports are not the ultimate evil to be avoided at all cost. In some frameworks like Flask they are quite natural and tweaking your code to eliminate them does not make the code better.
main.py
print 'import b'
import b
print 'a in globals() {}'.format('a' in globals())
print 'import a'
import a
print 'a in globals() {}'.format('a' in globals())
if __name__ == '__main__':
print 'imports done'
print 'b has y {}, a is b.a {}'.format(hasattr(b, 'y'), a is b.a)
b.by
print "b in, __name__ = {}".format(__name__)
x = 3
print 'b imports a'
import a
y = 5
print "b out"
a.py
print 'a in, __name__ = {}'.format(__name__)
print 'a imports b'
import b
print 'b has x {}'.format(hasattr(b, 'x'))
print 'b has y {}'.format(hasattr(b, 'y'))
print "a out"
python main.py output with comments
import b
b in, __name__ = b # b code execution started
b imports a
a in, __name__ = a # a code execution started
a imports b # b code execution is already in progress
b has x True
b has y False # b defines y after a import,
a out
b out
a in globals() False # import only adds a to main global symbol table
import a
a in globals() True
imports done
b has y True, a is b.a True # all b objects are available
Suppose you are running a test python file named request.py
In request.py, you write
import request
so this also most likely a circular import.
Solution:
Just change your test file to another name such as aaa.py, other than request.py.
Do not use names that are already used by other libs.
I solved the problem the following way, and it works well without any error.
Consider two files a.py and b.py.
I added this to a.py and it worked.
if __name__ == "__main__":
main ()
a.py:
import b
y = 2
def main():
print ("a out")
print (b.x)
if __name__ == "__main__":
main ()
b.py:
import a
print ("b out")
x = 3 + a.y
The output I get is
>>> b out
>>> a out
>>> 5
Ok, I think I have a pretty cool solution.
Let's say you have file a and file b.
You have a def or a class in file b that you want to use in module a, but you have something else, either a def, class, or variable from file a that you need in your definition or class in file b.
What you can do is, at the bottom of file a, after calling the function or class in file a that is needed in file b, but before calling the function or class from file b that you need for file a, say import b
Then, and here is the key part, in all of the definitions or classes in file b that need the def or class from file a (let's call it CLASS), you say from a import CLASS
This works because you can import file b without Python executing any of the import statements in file b, and thus you elude any circular imports.
For example:
File a:
class A(object):
def __init__(self, name):
self.name = name
CLASS = A("me")
import b
go = B(6)
go.dostuff
File b:
class B(object):
def __init__(self, number):
self.number = number
def dostuff(self):
from a import CLASS
print "Hello " + CLASS.name + ", " + str(number) + " is an interesting number."
Voila.
bar.py
print('going to import foo')
from foo import printx
foo.py
print('trying to import bar')
import bar
def printx():
print('x')
$ python bar.py
going to import foo
trying to import bar
going to import foo
Traceback (most recent call last):
File "bar.py", line 2, in <module>
from foo import printx
File "/home/suhail/Desktop/temp/circularimport/foo.py", line 2, in <module>
import bar
File "/home/suhail/Desktop/temp/circularimport/bar.py", line 2, in <module>
from foo import printx
ImportError: cannot import name 'printx' from partially initialized module 'foo' (most likely due to a circular import) (/home/suhail/Desktop/temp/circularimport/foo.py)
I have a module that works fine in python 3.5+ but not in 3.4. The only possible change that may be effecting it is how circular imports are handled in 3.5+. I cannot find any circular imports though so there may be something else going on.
module/
module/
__init__.py
file_a.py
from module import settings
from module.file_b import SomeBClass
def stuff():
settings.init()
stuff = SomeBClass()
def run():
stuff()
def main():
run()
file_b.py
from module.settings import config, properties
class SomeBClass():
....
file_c.py
class SomeClass():
connect to db...
settings.py
from module.file_c import SomeClass
def init():
global config
global properties
config = SomeClass()
properties = config.get_it()
when running I get the following error:
File "/home/somewhere/module/module/file_b.py", line 11, in <module>
from module.settings import config, properties
ImportError: cannot import name 'config'
I have tried running the module with python -mv to see if something gets imported more than once but I cannot see anything alarming.
Anyone have experience dealing with the differences between 3.4 and 3.5+? Does trying to access attributes from globals in the settings.init cause issues?
I'm writing a python package (python 3.6) and have the following directory structure:
package/
| __init__.py
| fileA.py
| fileB.py
| tests/
| | __init__.py
| | test_classA.py
| | test_classB.py
Setup
My files have the following contents:
# package/fileA.py
from package import ClassB
def ClassA:
def __init__(self):
self.my_ClassB = ClassB()
-
# package/fileB.py
def ClassB:
def __init__(self):
self.foo = "bar"
-
# package/tests/test_classB.py
from package import ClassB
# <performs some unit tests here>
-
# package/tests/test_classA.py
from package import ClassA
# <performs some unit tests here>
-
# package/__init__.py
from .fileA import ClassA
from .fileB import ClassB
Circular importing
When I ran python test_classB.py, I get the following traceback error showing that I have circular import statements, which are not allowed by python. Note - the package is not literally called package and I have edited the Traceback to match the toy example above.
Traceback (most recent call last):
File "package/tests/test_classB.py", line 2, in <module>
from package import ClassB
File "/anaconda/lib/python3.5/site-packages/package/__init__.py", line 2, in <module>
from .fileA import ClassA
File "/anaconda/lib/python3.5/site-packages/package/merparse.py", line 2, in <module>
from package import ClassB
ImportError: cannot import name 'ClassB'
Correcting the error
However, when I remove those two lines in my package/__init__.py file:
# package/__init__.py
from .fileA import ClassA
from .fileB import ClassB
...and I change the import method for package/fileA.py:
# package/fileA.py
from package.fileB import ClassB
def ClassA:
def __init__(self):
self.my_ClassB = ClassB()
... package/tests/test_classB.py runs correctly.
My Question
My question is: How can I keep the one file: one class structure in my files and import with from package import ClassA instead of having to import with from package.fileA import ClassA?
In my package I would like to import classes from other files, but don't know how to get around circular importing.
Edit: Solution
Thanks to #mirandak and #martin-kalcok below for their help.
The only file that I had to edit was fileA.py to not refer to the package name in the import statement.
# package/fileA.py
from .fileB import ClassB
def ClassA:
def __init__(self):
self.my_ClassB = ClassB()
The package/__init__.py file still contains import statements in case I want to import the package from other scripts in the future that I don't couple with the package.
# package/__init__.py
from .fileA import ClassA
from .fileB import ClassB
The problem is with package/fileA.py. It's both a part of package and calling the __init__.py file of package as it's imported - creating a circular dependency.
Can you change fileA.py to look like this?
# package/fileA.py
from .fileB import ClassB
def ClassA:
def __init__(self):
self.my_ClassB = ClassB()
First of all, renaming your package to literary "package" really confuses this whole situation, but here's my take on it :D.
I don't think you are dealing with circular dependency, python just states that it cannot import classB from package and that is because there is no file named classB in package directory. Changing import statement to
from package.fileB import ClassB
works because there is directory package which contains file fileB which contains object ClassB.
To answer your question whether you can import classes with statement
from package import ClassB
you can't, unless your package is file and classB is object inside this file. However i don't see how this different import statement would be a dealbraker
Side Note: Your objects ClassB and ClassA are not classes, they are functions. Python uses keyword class to create classes and def to define functions.
Side note 2: Are you sure your __init__.py file needs to hold any code at all?
Personal Note: I know that keeping 1 File / 1 Class structure is matter of personal preferences, it is not required in python and I myself find it much more comfortable to group multiple related classes and functions into one file
Hello I did got into circular dependency what is not refactori-zable other than doubling code.
I have something like this (only much more complex):
myParser.py:
import sys
import main #comment this to make it runnable
def parseEvnt():
sys.stdout.write("evnt:")
main.parseCmd(1) #comment this to make it runnable
tbl.py:
import myParser
tblx = {
1:("cmd",),
2:("evnt",myParser.parseEvnt),
}
main.py:
import tbl
def parseCmd(d):
print(tbl.tblx[d][0])
data=[1,2]
for d in data:
if(d<2):
parseCmd(d)
else:
fce = tbl.tblx[d][1]
fce()
Obvious error I'm getting is:
File "D:\Data\vbe\workspace\marsPython\testCircular2\main.py", line 1, in <module>
import tbl
File "D:\Data\vbe\workspace\marsPython\testCircular2\tbl.py", line 1, in <module>
import myParser
File "D:\Data\vbe\workspace\marsPython\testCircular2\myParser.py", line 2, in <module>
import main
File "D:\Data\vbe\workspace\marsPython\testCircular2\main.py", line 7, in <module>
parseCmd(d)
File "D:\Data\vbe\workspace\marsPython\testCircular2\main.py", line 3, in parseCmd
print(tbl.tblx[d][0])
AttributeError: module 'tbl' has no attribute 'tblx'
In C I think I would just tell by declaration in tbl.py hey there is function parseEvnt(). I would not need to include myParser and there would be no circular include.
In python I do not know how to do it.
I read few threads and there is always some wise guy recommending refactorizing. But in this case parseCmd() needs to see tblx which needs to see parseEvnt() (unless function declaration) and parseEvnt() need to call parseCmd() (cos evnt contains triggering cmd and I do not want to double the decoding cmd code).
Is there way how to make it working in python?
You can frequently get away with circular dependencies as long as the modules don't try to use each other's data until all importing is complete - as a practical matter, that means referencing with namespace (from module import something is forbidden) and only using the other modules inside functions and methods (no mystuff = module.mystuff in the global space). That's because when importing starts, python puts the module name in sys.modules and won't try to import that module again.
You ran into trouble because when you run main.py, python adds __main__ to sys.modules. When the code finally came around to import main, there was no "main" in the module list and so main.py was imported again... and its top level code tried to run.
Lets rearrange your test case and throw in a few print statements to tell when import happens.
myParser.py
print(' + importing myParser')
import sys
print('import parsecmd')
import parsecmd
def parseEvnt():
sys.stdout.write("evnt:")
parsecmd.parseCmd(1)
tbl.py
print(' + importing tbl')
print('import myParser')
import myParser
tblx = {
1:("cmd",),
2:("evnt",myParser.parseEvnt),
}
Parsecmd.py (new)
print(' + importing parsecmd')
print('import tbl')
import tbl
def parseCmd(d):
print(tbl.tblx[d][0])
main.py
print('running main.py')
print('import parsecmd')
import parsecmd
if __name__ == "__main__":
data=[1,2]
for d in data:
if(d<2):
parsecmd.parseCmd(d)
else:
fce = parsecmd.tbl.tblx[d][1]
fce()
When I run it I get
running main.py
import parsecmd
+ importing parsecmd
import tbl
+ importing tbl
import myParser
+ importing myParser
import parsecmd <-- didn't reimport parsecmd
cmd
evnt:cmd
If you're insistent on not refactoring (which is the real solution to this - not being a wise guy), you could move your problematic import into your function in myParser.py
import sys
def parseEvnt():
import main ## import moved into function
sys.stdout.write("evnt:")
main.parseCmd(1)
Again, see if you can redesign your code so such interdependencies are avoided.
The above solution is sort of a hack and won't solve future problems you might run into due to this dependency.
Circular imports should be avoided. Refactoring is required, any workaround that still requires a circular import is not a good solution.
That being said, the refactoring doesn't have to be extensive. There are at least a couple of fairly simple solutions.
Solution 1: move shared functions to a shared module
Since you want to use parseCmd from more than one place, move it to a separate file. That way both main.py and myParser.py can import the function.
Solution 2: have main pass parseCmd to parseEvnt.
First, make parseEvnt accept an argument to tell it which function to run:
# myParser.py
import sys
def parseEvnt(parseCmd):
sys.stdout.write("evnt:")
parseCmd(1)
Next, when you call myParser.parseEvnt, pass in a reference to main.parseCmd:
# main.py:
...
else:
fce = tbl.tblx[d][1]
fce(parseCmd)
There are other ways to accomplish the same thing. For example, you could add a "configure" method in myParser, and then have main.py call the configure method and pass in a reference to its parseCmd. The configure method can then store this reference in a global variable.
Another choice is to import main in the function that uses it:
main.py
import sys
def parseEvnt():
import main
sys.stdout.write("evnt:")
main.parseCmd(1)