EDIT2:
A minimal demonstration is:
code = """\
a=1
def f1():
print(a)
print(f1.__closure__)
f1()
"""
def foo():
exec(code)
foo()
Which gives:
None
Traceback (most recent call last):
File "D:/workfiles/test_eval_rec.py", line 221, in <module>
foo()
File "D:/workfiles//test_eval_rec.py", line 219, in foo
exec(code)
File "<string>", line 5, in <module>
File "<string>", line 3, in f1
NameError: name 'a' is not defined
It can be seen that the __closure__ attribute of function defined inside code str passed to exec() is None, making calling the function fails.
Why does this happen and how can I define a function successfully?
I find several questions that may be related.
Closure lost during callback defined in exec()
Using exec() with recursive functions
Why exec() works differently when invoked inside of function and how to avoid it
Why are closures broken within exec?
NameError: name 'self' is not defined IN EXEC/EVAL
These questions are all related to "defining a function insdie exec()". I think the fourth question here is closest to the essence of these problems. The common cause of these problems is that when defining a function in exec(), the __closure__ attribute of the function object can not be set correctly and will always be None. However, many existing answers to this question didn't realize this point.
Why these questions are caused by wrong __closure__:
When defining a function, __closure__ attribute is set to a dict that contains all local symbols (at the place where the keyword def is used) that is used inside the newly defined funtion. When calling a function, local symbol tables will be retrived from the __closure__ attribute. Since the __closure__ is set to None, the local symbol tables can not be retrived as expected, making the function call fail.
These answers work by making None a correct __closure__ attribute:
Existing solutions to the questions listed above solve these problems by getting the function definition rid of the usage of local symbol, i.e, they make the local symbols used(variable, function definition) global by passing globals() as locals of exec or by using keyword global explicitly in the code string.
Why existing solution unsatisfying:
These solutions I think is just an escape of the core problem of setting __closure__ correctly when define a functioni inside exec(). And as symbols used in the function definition is made global, these solutions will produce redundant global symbol which I don't want.
Original Questions:
(You May ignore this session, I have figured something out, and what I currently want to ask is described as the session EDIT2. The original question can be viewed as a sepecial case of the question described in session EDIT2)
original title of this question is: Wrapping class function to new function with exec() raise NameError that ‘self’ is not defined
I want to wrap an existing member function to a new class function. However, exec() function failed with a NameError that ‘self’ is not defined.
I did some experiment with the following codes. I called globals() and locals() in the execed string, it seems that the locals() is different in the function definition scope when exec() is executed. "self" is in the locals() when in exec(), however, in the function definition scope inside the exec(), "self" is not in the locals().
class test_wrapper_function():
def __init__(self):
# first wrapper
def temp_func():
print("locals() inside the function definition without exec:")
print(locals())
return self.func()
print("locals() outside the function definition without exec:")
print(locals())
self.wrappered_func1 = temp_func
# third wrapper using eval
define_function_str = '''def temp_func():
print("locals() inside the function definition:")
print(locals())
print("globals() inside the function definition:")
print(globals())
return self.func()
print("locals() outside the function definition:")
print(locals())
print("globals() outside the function definition:")
print(globals())
self.wrappered_func2 = temp_func'''
exec(define_function_str)
# call locals() here, it will contains temp_func
def func(self):
print("hi!")
t = test_wrapper_function()
print("**********************************************")
t.wrappered_func1()
t.wrappered_func2()
I have read this link. In the exec(), memeber function, attribute of "self" can be accessed without problem, while in the function difinition in the exec(), "self" is not available any more. Why does this happen?
Why I want to do this:
I am building a PyQt program. I want to create several similar slots(). These slots can be generated by calling one member function with different arguments. I decided to generate these slots using exec() function of python. I also searched with the keyword "nested name scope in python exec", I found this question may be related, but there is no useful answer.
To be more specific. I want to define a family of slots like func_X (X can be 'a', 'b', 'c'...), each do something like self.do_something_on(X). Here, do_something is a member function of my QWidget. So I use a for loop to create these slots function. I used codes like this:
class MyWidget():
def __init__(self):
self.create_slots_family()
def do_something(self, character):
# in fact, this function is much more complex. Do some simplification.
print(character)
def create_slots_i(self, character):
# want to define a function like this:
# if character is 'C', define self.func_C such that self.func_C() works like self.do_something(C)
create_slot_command_str = "self.func_" + character + " = lambda:self.do_something('" + character + "')"
print(create_slot_command_str)
exec(create_slot_command_str)
def create_slots_family(self):
for c in ["A", "B", "C", "D"]:
self.create_slots_i(c)
my_widget = MyWidget()
my_widget.func_A()
Note that, as far as I know, the Qt slots should not accept any parameter, so I have to wrap self.do_something(character) to be a series function self.func_A, self.func_C and so on for all the possible characters.
So the above is what I want to do orignially.
EDIT1:
(You May ignore this session, I have figured something out, and what I currently want to ask is described as the session EDIT2. This simplified version of original question can also be viewed as a sepecial case of the question described in session EDIT2)
As #Mad Physicist suggested. I provide a simplified version here, deleting some codes used for experiments.
class test_wrapper_function():
def __init__(self):
define_function_str = '''\
def temp_func():
return self.func()
self.wrappered_func2 = temp_func'''
exec(define_function_str)
def func(self):
print("hi!")
t = test_wrapper_function()
t.wrappered_func2()
I expected this to print a "hi". However, I got the following exception:
Traceback (most recent call last):
File "D:/workfiles/test_eval_class4.py", line 12, in <module>
t.wrappered_func2()
File "<string>", line 2, in temp_func
NameError: name 'self' is not defined
Using Exec
You've already covered most of the problems and workarounds with exec, but I feel that there is still value in adding a summary.
The key issue is that exec only knows about globals and locals, but not about free variables and the non-local namespace. That is why the docs say
If exec gets two separate objects as globals and locals, the code will be executed as if it were embedded in a class definition.
There is no way to make it run as though it were in a method body. However, as you've already noted, you can make exec create a closure and use that instead of the internal namespace by adding a method body to your snippet. However, there are still a couple of subtle restrictions there.
Your example of what you are trying to do showcases the issues perfectly, so I will use a modified version of that. The goal is to make a method that binds to self and has a variable argument in the exec string.
class Test:
def create_slots_i(self, c):
create_slot_command_str = f"self.func_{c} = lambda: self.do_something('{c}')"
exec(create_slot_command_str)
def do_something(self, c):
print(f'I did {c}!')
There are different ways of getting exec to "see" variables: literals, globals, and internal closures.
Literals. This works robustly, but only for simple types that can be easily instantiated from a string. The usage of c above is a perfect example. This will not help you with a complex object like self:
>>> t = Test()
>>> t.create_slots_i('a')
>>> t.func_a()
...
NameError: name 'self' is not defined
This happens exactly because exec has no concept of free variables. Since self is passed to it via the default locals(), it does not bind the reference to a closure.
globals. You can pass in a name self to exec via globals. There are a couple of ways of doing this, each with its own issues. Remember that globals are accessed by a function through its __globals__ (look at the table under "Callable types") attribute. Normally __globals__ refers to the __dict__ of the module in which a function is defined. In exec, this is the case by default as well, since that's what globals() returns.
Add to globals: You can create a global variable named self, which will make your problem go away, sort of:
>>> self = t
>>> t.func_a()
I did a!
But of course this is a house of cards that falls apart as soon as you delete, self, modify it, or try to run this on multiple instances:
>>> del self
>>> t.func_a()
...
NameError: name 'self' is not defined
Copy globals. A much more versatile solution, on the surface of it, is to copy globals() when you run exec in create_slots_i:
def create_slots_i(self, c):
create_slot_command_str = f"self.func_{c} = lambda: self.do_something('{c}')"
g = globals().copy()
g['self'] = self
exec(create_slot_command_str, g)
This appears to work normally, and for a very limited set of cases, it actually does:
>>> t = Test()
>>> t.create_slots_i('a')
>>> t.func_a()
I did a!
But now, your function's __globals__ attribute is no longer bound to the module you created it in. If it uses any other global values, especially ones that might change, you will not be able to see the changes. For limited functionality, this is OK, but in the general case, it can be a severe handicap.
Internal Closures. This is the solution you already hit upon, where you create a closure within the exec string to let it know that you have a free variable by artificial means. For example:
class Test:
def create_slots_i(self, c):
create_slot_command_str = f"""def make_func(self):
def func_{c}():
self.do_something('{c}')
return func_{c}
self.func_{c} = make_func(self)"""
g = globals().copy()
g['self'] = self
exec(create_slot_command_str, g)
def do_something(self, c):
print(f'I did {c}!')
This approach works completely:
>>> t = Test()
>>> t.create_slots_i('a')
>>> t.func_a()
I did a!
The only real drawbacks here are security, which is always a problem with exec, and the sheer awkwardness of this monstrosity.
A Better Way
Since you are already creating closures, there is really no need to use exec at all. In fact, the only thing you are really doing is creating methods so that self.func_... will bind the method for you, since you need a function with the signature of your slot and access to self. You can write a simple method that will generate functions that you can assign to your slots directly. The advantage of doing it this way is that (a) you avoid calling exec entirely, and (b) you don't need to have a bunch of similarly named auto-generated methods polluting your class namespace. The slot generator would look something like this:
def create_slots_i(self, c):
def slot_func():
self.do_something(c) # This is a real closure now
slot_func.__name__ = f'func_{c}'
return slot_func
Since you will not be referring to these function objects anywhere except your slots, __name__ is the only way to get the "name" under which they were stored. That is the same thing that def does for you under the hood.
You can now assign slots directly:
some_widget.some_signal.connect(self.create_slots_i('a'))
Note
I originally had a more complex approach in mind for you, since I thought you cared about generating bound methods, instead of just setting __name__. In case you have a sufficiently complex scenario where it still applies, here is my original blurb:
A quick recap of the descriptor protocol: when you bind a function with the dot operator, e.g., t.func_a, python looks at the class for descriptors with that name. If your class has a data descriptor (like property, but not functions), then that descriptor will shadow anything you may have placed in the instance __dict__. However, if you have a non-data descriptor (one a __get__ method but without a __set__ method, like a function object), then it will only be bound if an instance attribute does not shadow it. Once this decision has been made, actually invoking the descriptor protocol involves calling type(t).func_a.__get__(t). That's how a bound method knows about self.
Now you can return a bound method from within your generator:
def create_slots_i(self, c):
def slot_func(self):
self.do_something(c) # This is a closure on `c`, but not on `self` until you bind it
slot_func.__name__ = f'func_{c}'
return slot_func.__get__(self)
Why this phenomena happen:
Actually the answer of the question 4 listed above can answer this question.
When call exec() on one code string, the code string is first compiled. I suppose that during compiling, the provided globals and locals is not considered. The symbol in the exec()ed code str is compiled to be in the globals. So the function defined in the code str will be considered using global variables, and thus __closure__ is set to None.
Refer to this answer for more information about what the func exec does.
How to deal with this phenomena:
Imitating the solutions provided in the previous questions, for the minimal demostration the question, it can also be modified this way to work:
a=1 # moving out of the variable 'code'
code = """\
def f1():
print(a)
print(f1.__closure__)
f1()
"""
def foo():
exec(code)
foo()
Although the __closure__ is still None, the exception can be avoided because now only the global symbol is needed and __closure__ should also be None if correctly set. You can read the part The reason why the solutions work in the question body for more information.
This was originally added in Revision 4 of the question.
TL;DR
To set correct __closure__ attribute of function defined in the code string passed to exec() function. Just wrap the total code string with a function definition.
I provide an example here to demonstrate all possible situations. Suppose you want to define a function named foo inside a code string used by exec(). The foo use function, variables that defined inside and outside the code string:
def f1():
outside_local_variable = "this is local variable defined outside code str"
def outside_local_function():
print("this is function defined outside code str")
code = """\
local_variable = "this is local variable defined inside code str"
def local_function():
print("this is function defined inside code str")
def foo():
print(local_variable)
local_function()
print(outside_local_variable)
outside_local_function()
foo()
"""
exec(code)
f1()
It can be wrapper like this:
def f1():
outside_local_variable = "this is local variable defined outside code str"
def outside_local_function():
print("this is function defined outside code str")
code = """\
def closure_helper_func(outside_local_variable, outside_local_function):
local_variable = "this is local variable defined inside code str"
def local_function():
print("this is function defined inside code str")
def foo():
print(local_variable)
local_function()
print(outside_local_variable)
outside_local_function()
foo()
closure_helper_func(outside_local_variable, outside_local_function)
"""
exec(code)
f1()
Detailed explanation:
Why the __closure__ attribute is not corretly set:
please refer to The community wiki answer.
How to set the __closure__ attribute to what's expected:
Just wrap the whole code str with a helper function definition and call the helper function once, then during compiling, the variables are considered to be local, and will be stored in the __closure__ attribute.
For the minimal demonstration in the question, it can be modified to following:
code = """\
def closure_helper_func():
a=1
def f1():
print(a)
print(f1.__closure__)
f1()
closure_helper_func()
"""
def foo():
exec(code)
foo()
This output as expected
(<cell at 0x0000019CE6239A98: int object at 0x00007FFF42BFA1A0>,)
1
The example above provide a way to add symbols that defined in the code str to the __closure__ For example, in the minimal demo, a=1 is a defined inside the code str. But what if one want to add the local symbols defined outside the code str? For example, in the code snippet in EDIT1 session, the self symbol needs to be added to the __closure__, and the symbol is provided in the locals() when exec() is called. Just add the name of these symbols to the arguments of helper function and you can handle this situation.
The following shows how to fix the problem in EDIT1 session.
class test_wrapper_function():
def __init__(self):
define_function_str = '''\
def closure_helper_func(self):
def temp_func():
return self.func()
self.wrappered_func2 = temp_func
closure_helper_func(self)
'''
exec(define_function_str)
def func(self):
print("hi!")
t = test_wrapper_function()
t.wrappered_func2()
The following shows how to fix the codes in the session "Why I want to do this"
class MyWidget():
def __init__(self):
self.create_slots_family()
def do_something(self, character):
# in fact, this function is much more complex. Do some simplification.
print(character)
def create_slots_i(self, character):
# want to define a function like this:
# if character is 'C', define self.func_C such that self.func_C() works like self.do_something(C)
# create_slot_command_str = "self.func_" + character + " = lambda:self.do_something('" + character + "')"
create_slot_command_str = """
def closure_helper_func(self):
self.func_""" + character + " = lambda:self.do_something('" + character + """')
closure_helper_func(self)
"""
# print(create_slot_command_str)
exec(create_slot_command_str)
def create_slots_family(self):
for c in ["A", "B", "C", "D"]:
self.create_slots_i(c)
my_widget = MyWidget()
my_widget.func_A()
This solution seems to be too tricky. However, I can not find a more elegant way to declare that some variables should be local symbol during compiling.
Consider the following snippet of python code:
x = 1
class Foo:
x = 2
def foo():
x = 3
class Foo:
print(x) # prints 3
Foo.foo()
As expected, this prints 3.
But, if we add a single line to the above snippet, the behavior changes:
x = 1
class Foo:
x = 2
def foo():
x = 3
class Foo:
x += 10
print(x) # prints 11
Foo.foo()
And, if we switch the order of the two lines in the above example, the result changes yet again:
x = 1
class Foo:
x = 2
def foo():
x = 3
class Foo:
print(x) # prints 1
x += 10
Foo.foo()
I'd like to understand why this occurs, and more generally, understand the scoping rules that cause this behavior. From the LEGB scoping rule, I would expect that both snippets print 3, 13, and 3, since there is an x defined in the enclosing function foo().
Class block scope is special. It is documented here:
A class definition is an executable statement that may use and define
names. These references follow the normal rules for name resolution
with an exception that unbound local variables are looked up in the
global namespace. The namespace of the class definition becomes the
attribute dictionary of the class. The scope of names defined in a
class block is limited to the class block; it does not extend to the
code blocks of methods – this includes comprehensions and generator
expressions since they are implemented using a function scope.
Basically, class blocks do not "participate" in creating/using enclosing scopes.
So, it is actually the first example that isn't working as documented. I think this is an actual bug.
EDIT:
OK, so actually, here's some more relevant documentation from the data model, I think it all is actually consistent with the documentation:
The class body is executed (approximately) as exec(body, globals(),
namespace). The key difference from a normal call to exec() is that
lexical scoping allows the class body (including any methods) to
reference names from the current and outer scopes when the class
definition occurs inside a function.
So class blocks do participate in using enclosing scopes, but for free variables (as is normal anyway). In the first piece of documentation that I'm quoting, the part about "unbound local variables are looked up in the global namespace" applies to variables that would normally be marked local by the complier. So, consider this notorious error, for example:
x = 1
def foo():
x += 1
print(x)
foo()
Would throw an unbound local error, but an equivalent class definition:
x = 1
class Foo:
x += 1
print(x)
will print 2.
Basically, if there is an assignment statement anywhere in a class block, it is "local", but it will check in the global scope if there is an unbound local instead of throwing the UnboundLocal error.
Hence, in your first example, it isn't a local variable, it is simply a free variable, and the resolution goes through the normal rules. In your next two examples, you us an assignment statemnt, marking x as "local", and thus, it will be looked up in the global namespace in case it is unbound in the local one.
I am little confused about scoping of variables in Python. Kindly explain difference between below snippets.
class Test(object):
a_var = 1
def a_func(self):
self.a_var = self.a_var + 1
print(self.a_var, '[ a_var inside a_func() ]')
if __name__ == '__main__':
t = Test()
t.a_func()
Output: 2 [ a_var inside a_func() ]
class Test(object):
a_var = 1
def a_func(self):
a_var = a_var + 1
print(a_var, '[ a_var inside a_func() ]')
if __name__ == '__main__':
t = Test()
t.a_func()
Output: UnboundLocalError: local variable 'a_var' referenced before assignment
Why is LEGB rule not applied in second case? Should it not get value from enclosed scope that is class?
This might seem weird (and it is), but you don't get a closure over class, it's only over def. The "enclosing" scope referred to in LEGB is just talking about function definitions; class blocks don't count here.
That strange behaviour is an artifact of the way in which classes were added to Python historically. The class scope is not a real scope. Python didn't always have classes, and the spooky "intermediate scope" just exists during the class definition: internally, the code under the class body is more or less just run through exec under a temporary scope with the result being assigned to the class name. This was a very simple "bolt-on" approach to get OOP into the language, at the time, and it's also the reason why Python has the explicit self thing as an intentional language design choice.
To access the a_var from the "class scope" from inside a method, you will have to use attribute access via either self.a_var or Test.a_var. Both should work. You may also access it directly at the class level, during the class definition, but since you are still inside the temporary scope that is just another example of a local access (LEGB).
This is documented (albeit not particularly clearly) under the execution model section.
Class definition blocks and arguments to exec() and eval() are special in the context of name resolution. A class definition is an executable statement that may use and define names. These references follow the normal rules for name resolution with an exception that unbound local variables are looked up in the global namespace. The namespace of the class definition becomes the attribute dictionary of the class. The scope of names defined in a class block is limited to the class block; it does not extend to the code blocks of methods – this includes comprehensions and generator expressions since they are implemented using a function scope.
Here is the code:
def caller(callee):
callee()
def wrapper():
def a():
print v0
for i in range(5):
v0 = i*i
caller(a)
wrapper()
The above code outputs:
0
1
4
9
16
But I don't understand how a resolves the variable v0. I can not find the related python docs regarding this language feature.
The scope of variables defined in a function includes all the nested functions within it. So variables defined in wrapper() are accessible within a(), because this function is nested in it. This is known as lexical scoping, and it's often used in creating closures.
This is explained in the Python Resolution of Names documentation:
A scope defines the visibility of a name within a block. If a local variable is defined in a block, its scope includes that block. If the definition occurs in a function block, the scope extends to any blocks contained within the defining one, unless a contained block introduces a different binding for the name.
The function a is defined per invocation of wrapper. When a given instance of a is called, it looks up v0 within the context of its definition, which is the specific call to wrapper that defined it. By the time a has been called, v0 has been defined within wrapper, and a uses that definition of v0.
In this example, the invocation of wrapper that defines a is still active when a is called, but it need not be. In other words, wrapper could return, and a reference to a from that context could still be called. In this case it would be a closure. But that does not occur in this example.
Here's an example that does use closures:
def foo(x):
def bar():
return x
return bar
f1 = foo(123)
f2 = foo(456)
print(f1())
print(f2())
The output is:
123
456
When foo is called, it returns an instance of bar which evaluates x in the context in which foo was called. In the first invocation x is 123, and in the second it is 456. Those bindings persist even after the calls to foo have returned.
Remember that all code in a function is not run until the function is called. By the time a() is called, v0 has been defined in an outer scope, so it can recognize the variable and evaluate it.
I am using a list on which some functions works in my program. This is a shared list actually and all of my functions can edit it. Is it really necessary to define it as "global" in all the functions?
I mean putting the global keyword behind it in each function that uses it, or defining it outside of all the functions is enough without using the global word behind its definition?
When you assign a variable (x = ...), you are creating a variable in the current scope (e.g. local to the current function). If it happens to shadow a variable fron an outer (e.g. global) scope, well too bad - Python doesn't care (and that's a good thing). So you can't do this:
x = 0
def f():
x = 1
f()
print x #=>0
and expect 1. Instead, you need do declare that you intend to use the global x:
x = 0
def f():
global x
x = 1
f()
print x #=>1
But note that assignment of a variable is very different from method calls. You can always call methods on anything in scope - e.g. on variables that come from an outer (e.g. the global) scope because nothing local shadows them.
Also very important: Member assignment (x.name = ...), item assignment (collection[key] = ...), slice assignment (sliceable[start:end] = ...) and propably more are all method calls as well! And therefore you don't need global to change a global's members or call it methods (even when they mutate the object).
Yes, you need to use global foo if you are going to write to it.
foo = []
def bar():
global foo
...
foo = [1]
No, you can specify the list as a keyword argument to your function.
alist = []
def fn(alist=alist):
alist.append(1)
fn()
print alist # [1]
I'd say it's bad practice though. Kind of too hackish. If you really need to use a globally available singleton-like data structure, I'd use the module level variable approach, i.e.
put 'alist' in a module and then in your other modules import that variable:
In file foomodule.py:
alist = []
In file barmodule.py:
import foomodule
def fn():
foomodule.alist.append(1)
print foomodule.alist # [1]