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I'd like to create a decorator like below, but I can't seem to think of an implementation that works. I'm starting to think it's not possible, but thought I would ask you guys first.

I realize there's various other ways to create static variables in Python, but I find those ways ugly. I'd really like to use the below syntax, if possible.

@static(x=0)
def f():
    x += 1
    print x

f() #prints 1
f() #prints 2

I don't care if the implementation of static is long or hackity, as long as it works like above.

I created this version, but it only allows a <function>.<varname> syntax, which gets cumbersome pretty quickly with longer function and variable names.

def static(**assignments):
    def decorate(func):
        for var, val in assignments.items():
            setattr(func, var, val)
        return func
    return decorate

Various things I thought of, but couldn't get to work were:

  1. Changing f (the decorated function) into a callable class, and somehow storing the static vars in self transparently.
  2. Modifying the globals of f() inside the decorator, and somehow inserting 'global x' statements into the code for f.
  3. Changing f into a generator where we bind the variables by hand and then execute f's code directly.
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8 Answers

up vote 3 down vote accepted

Here is a decorator that seems to work. Note that this requires return locals() at the end of the function due to being unable to set locals from the outside (I don't have much experience programming so if there is a way, I don't know it).

class Static(object):
def __init__(self, **kwargs):
    self.kwargs = kwargs

def __call__(self, f):
    def wrapped_f():
        try:
            new_kwargs = {}
            for key in self.kwargs:
                i = getattr(f, key)
                new_kwargs[key] = i
            self.kwargs = new_kwargs
        except:
            pass
        for key, value in f(**self.kwargs).items():
            setattr(f, key, value)
    return wrapped_f

@Static(x=0, y=5, z='...')
def f(x, y, z):
    x += 1
    y += 5
    print x, y, z
    return locals()

The output would be:

>>> f()
1 10 ...
>>> f()
2 15 ...
>>> f()
3 20 ...

EDIT:

I found something at http://code.activestate.com/recipes/410698/ and decided to try adding it to this. It works without the return now.

EDIT again: Changed to to make it a few seconds faster. Edit 3; changed to function instead of class

def static(**kwargs):
    def wrap_f(function):
        def probeFunc(frame, event, arg):
            if event == 'call':
                frame.f_locals.update(kwargs)
                frame.f_globals.update(kwargs)
            elif event == 'return':
                for key in kwargs:
                    kwargs[key] = frame.f_locals[key]
                sys.settrace(None)
            return probeFunc
        def traced():
            sys.settrace(probeFunc)
            function()
        return traced
    return wrap_f

tested:

@static(x=1)
def f():
    x += 1

global_x = 1
def test_non_static():
    global global_x
    global_x += 1


print 'Timeit static function: %s' % timeit.timeit(f)
print 'Timeit global variable: %s' % timeit.timeit(test_non_static)

output:

Timeit static function: 5.10412869535
Timeit global variable: 0.242917510783

Using settrace slows it down quite drastically.

share|improve this answer
    
Thanks. This is pretty close, but I'd like to remove the requirement of returning locals(), if possible. Can anyone improve this one? –  bukzor Oct 24 '09 at 17:24
    
Wow that's pretty darn close! Could you edit the answer to remove the arguments, like you suggested? Then that would answer my question exactly. We can work on making it fast and pretty after it works. –  bukzor Oct 24 '09 at 21:59
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By the time your decorator gets the function object f, it's already been compiled -- specifically, it's been compiled with the knowledge that x is local (because it's assigned with the += assignment), the normal optimization (in 2.* you can defeat the optimization, at a staggering price in performance, by starting f with exec ''; in 2.*, you cannot defeat the optimization). Essentially, to use the syntax you crave, you have to recompile f (by recovering its sources, if you know they'll be available at runtime, or, much harder, by bytecode hacks) with somehow-modified sources -- once you've decided to go that way, the simplest approach is probably to change x into f.x throughout the body of f.

Personally, if and when I find myself fighting so hard against the language (or other technology) that I'm trying to bend to my will to impose my desires, I acknowledge that I'm either using the wrong language (or other technology), if those desires are absolutely crucial, and then the solution must be to change technology; or, if those desires are not that crucial, give up on them.

Either way, I give up trying to distort the language too far away from its obvious design intentions: even if I did come up with some hacky, fragile kludge, it would no doubt be unmaintainable. In this case, Python's desire intentions are very clear: barenames that get re-bound within a functions are locals of that function unless explicitly designated as globals -- period. So, your attempt to make barenames (that get re-bound within a function) mean something completely different than "locals" is exactly this kind of fight.

Edit: If you're willing to give up on the insistence on using barenames for your "statics", then suddenly you're not fighting against Python any more, but rather "going with the grain" of the language (despite the design glitch of global [and nonlocal], but, that's a separate rant;-). So, for example:

class _StaticStuff(object):
  _static_stack = []
  def push(self, d):
    self._static_stack.append(d)
  def pop(self):
    self._static_stack.pop()
  def __getattr__(self, n):
    return self._static_stack[-1][n]
  def __setattr__(self, n, v):
    self._static_stack[-1][n] = v
import __builtin__
__builtin__.static = _StaticStuff()

def with_static(**variables):
  def dowrap(f):
    def wrapper(*a, **k):
      static.push(variables)
      try: return f(*a, **k)
      finally: static.pop()
    return wrapper
  return dowrap

@with_static(x=0)
def f():
    static.x += 1
    print static.x

f()
f()

This works just like you desire, printing 1 and then 2. (I'm using __builtin__ to make it simplest to use with_static to decorate functions living in any module whatsoever, of course). You could have several different implementations, but the key point of any good implementation is that "static variables" will be qualified names, not barenames -- making it explicit that they're not local variables, playing with the grain of the language, and so forth. (Similar built-in containers, and qualified names based on them, should have been used in Python's design, instead of the global and nonlocal design glitches, to indicate other kinds of variables that aren't local ones and therefore should not be using barenames... ah well, you can implement yourself a globvar special container on the same lines of the above static ones, without even needing decoration, though I'm not so sure that is entirely feasible for the nonlocal case [perhaps with some decoration and the tiniest amount of black magic...;=)]).

Edit: a comments points out that the code as given doesn't work when you only decorate a function that returns a closure (instead of decorating the closure itself). That's right: of course, you have to decorate the specific function that uses the static (and there can be only one, by definition of function-static variables!), not a random function that doesn't in fact use the static but rather just happens to be in some lexical connection with the one that does. For example:

def f():
  @with_static(x=0)
  def g():
    static.x += 1
    print static.x
  return g

x = f()
x()
x()

this works, while moving the decorator to f instead of g doesn't (and couldn't possibly).

If the actual desiderata are not about static variables (visible and usable only within a single function) but some hybrid thing that's usable throughout a certain peculiar bundle of functions, that needs to be specified very precisely (and no doubt implemented very differently, depending on what the actual specs are) -- and ideally that needs to happen in a new and separate SO questions, because this one (which is specifically about static instead), and this answer to this specific question, are already plenty big enough.

share|improve this answer
    
I agree, but my hope is that this kludge/hack wouldn't be necessary indefinitely. My aim was to either demonstrate that this is or isn't possible. I'd like to someday use this question as either an initial implementation or the counter-example for a PEP. I'm not sure I agree with your evaluation of design intentions, since "nonlocal" variables are in python3. nonlocal is tantalizingly similar, yet disappointingly not very usable as C-style static variables. (python.org/dev/peps/pep-3104) Maybe someone can meet the challenge by using python3.0? ...I can't seem to insert paragraphs. –  bukzor Oct 24 '09 at 17:25
1  
@buzkor, I know the design intentions pretty well as I was one of the parties debating them as they were formed (though the final decision is Guido's). nonlocal is just one more variant of global (I don't like either, I think they sit athwart most of Python's otherwise pretty-consistent design, and using a special keyword from which to make qualified names would have been much better -- but clearly I lost that debate in terms of Guido's final decisions). I may edit my answer to show how that would work. –  Alex Martelli Oct 24 '09 at 18:47
    
@buzkor, edited my answer to show how everything becomes smooth and solid as soon as you give up on the craving for barenames meaning things other than local variables -- a really unreasonable demand, no matter the design glitches of global and nonlocal. Namespaces are one honking great idea, let's do more of those: using qualified names means I am doing one more namespace, rather than striving to shoehorn into an existing namespace (the one used for local variables, i.e. barenames) stuff that doesn't belong there. No downside, all upside, all Pythonic, smooth, and sweet. –  Alex Martelli Oct 24 '09 at 19:08
    
@Alex Martelli: This solution fails if f returns a closure. –  Anand Chitipothu Oct 28 '09 at 17:09
    
@Anand: works fine with closure or anything else as long of course as the decorator wraps whatever function is actually using statics! –  Alex Martelli Oct 28 '09 at 18:30
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You could do something like that (but I haven't tested this extensively; used CPython 2.6):

import types

def static(**dict):
    def doWrap(func):
        scope = func.func_globals
        scope.update(dict)
        return types.FunctionType(func.func_code, scope)
    return doWrap

# if foo() prints 43, then it's wrong
x = 42

@static(x = 0)
def foo():
   global x
   x += 1
   print(x)

foo() # => 1
foo() # => 2

It requires declaring those variables as global and shadows top-level global variables, but otherwise should work. Not sure about performance, though.

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Here is a really simple solution that works just like normal python static variables.

def static(**kwargs):
  def wrap(f):
    for key, value in kwargs.items():
      setattr(f, key, value)
    return f
  return wrap

Example usage:

@static(a=0)
def foo(x):
  foo.a += 1
  return x+foo.a

foo(1)  # => 2
foo(2)  # => 4
foo(14) # => 17

This more closely matches the normal way of doing python static variables

def foo(x):
  foo.a += 1
  return x+foo.a
foo.a = 10
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Guess this is no longer valid since the question has been changed to include this solution, but points out that this becomes cumbersome with long function names. –  DRayX Feb 16 '12 at 17:27
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Here's something that might be much clearer. It doesn't involve any decorators or hacking.

class F( object ):
    def __init__( self ):
        self.x= 0
    def __call__( self ):
        self.x += 1
        print self.x

f= F()

Now you have your function f with a static variable.

f() #prints 1
f() #prints 2
share|improve this answer
    
... but the guy asked for a decorator based solution... –  jldupont Oct 23 '09 at 2:29
    
This works by not using barenames -- the problem is entirely with the desire of using barenames that get modified inside a function as anything else than locals of that function (unless the function explicitly designates them as global); there's no problem doing so with qualified names (such as self.x or anything else that's not a barename). –  Alex Martelli Oct 23 '09 at 2:41
    
@Alex Martelli: While true that the question asks for barenames, I suggest that barenames are a mistake and not worth the effort of writing a complex decorator. Barenames which are local are as bad as globals -- visually scopeless. –  S.Lott Oct 23 '09 at 10:00
    
The main point was to leave the function pretty -- as simple as the design. The f.x solution found earlier seems better. –  bukzor Oct 24 '09 at 17:19
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How about this, without decorators?

class State(dict):
    """Object interface to dict."""
    def __getattr__(self, name):
        try:
            return self[name]
        except KeyError:
            raise AttributeError, name

def f(d=State(x=0)):
    d.x += 1
    return d.x

And here is it in action:

>>> f()
1
>>> f()
2
>>> f()
3
share|improve this answer
    
A mis-informed user could start trying to use that argument and break the function. In this case we're creating an argument that's never intended to be used as an argument. I do realize that this is a fairly standard practice in python, but I don't think it should be. That's the true aim of my question. –  bukzor Oct 24 '09 at 17:22
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When you need to save state between invocations of a function, you are almost always better off using a generator/coroutine or an object. Since you want to use "bare" variable names, then you'll want the coroutine version.

# the coroutine holds the state and yields rather than returns values
def totalgen(x=0, y=0, z=0):
    while True:
       a, b, c = (yield x, y, z)
       x += a
       y += b
       z += c

# the function provides the expected interface to callers
def runningtotal(a, b, c, totalgen=totalgen()):
    try:
        return totalgen.send((a, b, c))    # conveniently gives TypeError 1st time
    except TypeError:
        totalgen.next()                    # initialize, discard results
        return totalgen.send((a, b, c))

The result is a function that accumulates totals of the three values passed to it, exactly as if it had static variables, but the accumulators are plain old local variables in what is essentially an infinite generator.

share|improve this answer
    
I wonder if there's a way to encapsulate this idea into a decorator. –  bukzor Sep 21 '11 at 2:41
    
Probably not without a lot of bytecode hackery, and it would have difficulty if there was more than one return statement in a function even then. If I get some time, though, it seems like it would be a fun project. –  kindall Sep 21 '11 at 17:53
    
... on second thought, if I was gonna do some bytecode hackery I proabbly wouldn't take this route to implementing statics; there are simpler ways. –  kindall Sep 27 '11 at 17:06
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A slight tweak of another anwser:

def static(**kwargs):
    def decorator(func):
        return type(func)(func.func_code, dict(func.func_globals, **kwargs))
    return decorator

message = "goodbye, world!"
@static(message="hello, world!")
def hello(): print message

hello()

I found it icky to override a builtin name with a function argument name, so I changed **dict into the more canonical **kwargs. I also saved a few lines and IMO made the code cleaner by constructing a new dict with dict(the_original, **the_updates). Lastly I saved a few lines by accessing the function constructor via type(func) rather than an import---type and class objects are factory methods, so use them!

I also removed a global declaration. This works as long as you don't rebind the variable, i.e. removing global in effect makes the pointer (but not the object) read-only. If you use it this way, maybe let is a better name than static for the binding thus introduced.

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I believe this gives unexpected results in the case of mutable globals. If the function prints global x, and x changes value between definition and call, the function will still print the old value of x, I believe, since you take a copy of the globals. –  bukzor Apr 10 '13 at 19:14
    
When trying to use this decorator in the scenario from the OP, I get x += 1 UnboundLocalError: local variable 'x' referenced before assignment. –  bukzor Apr 10 '13 at 19:19
    
good point about the globals! As I stated, removing the global declaration works as long as the variable is read-only, which your example violates. It might work if x has an iadd method, though. –  Jonas Kölker Apr 11 '13 at 17:21
    
"My example" is actually the question, so it's strange to say it violates your answer. –  bukzor Apr 11 '13 at 21:25
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