Memoizing metaclass. Drop-dead simple way to create cached objects
A quick way to make Python classes automatically memoize (a.k.a. cache) their instances based on the arguments they are instantiated with (i.e. args to __init__). It’s a simple way to avoid repetitively creating expensive-to-create objects, and to make sure objects that have a natural ‘identity’ are created only once. If you want to be fancy, mementos implements the [Multiton](https://en.wikipedia.org/wiki/Multiton_pattern) software pattern.
Say you have a class Thing that requires expensive computation to create, or that should be created only once. Easy peasy:
from mementos import MementoMetaclass, with_metaclass class Thing(with_metaclass(MementoMetaclass, object)): def __init__(self, name): self.name = name ...
Then Thing objects will be memoized:
t1 = Thing("one") t2 = Thing("one") assert t1 is t2 # same instantiation args => same object
Python 2 vs. Python 3
Python 2 and 3 have different forms for specifying metaclasses. In Python 2:
from mementos import MementoMetaclass class Thing(object): __metaclass__ = MementoMetaclass # now I'm memoized! ...
Whereas Python 3 uses:
class Thing3(object, metaclass=MementoMetaclass): ...
mementos supports either of these. But Python 2 and Python 3 don’t recognize each other’s syntax for metaclass specification, so straightforward code for one won’t even compile for the other. The with_metaclass() function shown above is the way to go for cross-version compatibility. It’s very similar to that found in the six cross-version compatibility module.
Careful with Call Signatures
MementoMetaclass caches on call signature, which can vary greatly in Python, even for logically identical calls. This is especially true if kwargs are used. E.g. def func(a, b=2): pass can be called func(1), func(1, 2), func(a=1), func(1, b=2), or func(a=2, b=2). All of these resolve to the same logical call–and this is just for two parameters! If there is more than one keyword, they can be arbitrarily ordered, creating many logically identical permutations.
So if you instantiate an object once, then again with a logically identical call but using a different calling structure/signature, the object won’t be created and cached just once–it will be created and cached multiple times.:
o1 = Thing("lovely") o2 = Thing(name="lovely") assert o1 is not o2 # because the call signature is different
This may degrade performance, and can also create errors, if you’re counting on mementos to create just one object. So don’t do that. Use a consistent calling style, and it won’t be a problem.
In most cases, this isn’t an issue, because objects tend to be instantiated with a limited number of parameters, and you can take care that you instantiate them with parallel call signatures. Since this works 99% of the time and has a simple implementation, it’s worth the price of this inelegance.
If you want only part of the initialization-time call signature (i.e. arguments to __init__) to define an object’s identity/cache key, there are two approaches. One is to use MementoMetaclass and design __init__ without superfluous attributes, then create one or more secondary methods to add/set useful-but-not-essential data. E.g.:
class OtherThing(with_metaclass(MementoMetaclass, object)): def __init__(self, name): self.name = name self.color = None # unset for now self.weight = None def set(self, color=None, weight=None): self.color = color or self.color self.weight = weight or self.weight return self ot1 = OtherThing("one").set(color='blue') ot2 = OtherThing("one").set(weight='light') assert ot1 is ot2 assert ot1.color == ot2.color == 'blue' assert ot1.weight == ot2.weight == 'light'
Or you can just define your own memoizing metaclass, using the factory function described below.
Visiting the Factory
The first iteration of mementos defined a single metaclass. It’s since been reimplemented as a parameterized meta-metaclass. Cool, huh? That basically means that it defines a function, memento_factory() that, given a metaclass name and a function defining how cache keys are constructed, returns a corresponding metaclass. MementoMetaclass is the only metaclass that the module pre-defines, but it’s easy to define your own memoizing metaclass.:
from mementos import memento_factory, with_metaclass IdTracker = memento_factory('IdTracker', lambda cls, args, kwargs: (cls, id(args)) ) class MyTracker(with_metaclass(IdTracker, object)): ... # object identity is the object id of first argument to __init__ # (and there must be one, else the args reference => IndexError)
The first argument to memento_factory() is the name of the metaclass being defined. The second is a callable (e.g. lambda expression or function object) that takes three arguments: a class object, an argument list, and a keyword arg dict. Note that there is no * or ** magic–args passed to the key function have already been resolved into basic data structures.
The callable must return a globally-unique, hashable key for an object. This key will be stored in the _memento_cache, which is a simple dict.
When various arguments are used as the cache key/object identity, you may use a tuple that includes the class and arguments you want to key off of. This can also help debugging, should you need to examine the _memento_cache cache directly. But in cases like the IdTracker above, it’s not mandatory that you keep extra information around. The raw id(args) integer value would suffice, as would a constructed string or other immutable, hashable value.
In cases where arguments are very flexible, or involve flexible data types, a high-powered hashing function such as that provided by SuperHash might come in handy. E.g.:
from superhash import superhash SuperHashMeta = memento_factory('SuperHashMeta', lambda cls, args, kwargs: (cls, superhash(args)) )
For the 1% edge-cases where multiple call variations must be conclusively resolved to a unique canonical signature, that can be done on a custom basis (based on the specific args). Or in Python 2.7 and 3.x, the inspect module’s getcallargs() function can be used to create a generic “call fingerprint” that can be used as a key. (See the tests for example code.)
mementos is not to be confused with memento, which does something completely different.
mementos was originally derived from an ActiveState recipe by Valentino Volonghi. While the current implementation quite different and the scope much broader, the availability of that recipe was what enabled this module and the growing list of modules that depend on it. This is what open source evolution is all about. Thank you, Valentino!
It is safe to memoize multiple classes at the same time. They will all be stored in the same cache, but their class is a part of the cache key, so the values are distinct.
This implementation is not thread-safe, in and of itself. If you’re in a multi-threaded environment, consider wrapping object instantiation in a lock.
Automated multi-version testing managed with pytest and tox. Successfully packaged for, and tested against, all late-model versions of Python (2.6, 2.7, 3.2, 3.3, and 3.4), plus PyPy 2.4 (based on Python 2.7.8).
Should also work under Python 2.5, but is no longer tested there, as my testing tools no longer support it. It’s 8 years old. If you’re still using 2.5, it’s long past time to upgrade!
pip install -U mementos
To easy_install under a specific Python version (3.3 in this example):
python3.3 -m easy_install --upgrade mementos
(You may need to prefix these with “sudo ” to authorize installation.)
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