I am trying to understand, what is monkey patching or a monkey patch?
Is that something like methods/operators overloading or delegating?
Does it have anything common with these things?
No, it's not like any of those things. It's simply the dynamic replacement of attributes at runtime.
For instance, consider a class that has a method
get_data. This method does an external lookup (on a database or web API, for example), and various other methods in the class call it. However, in a unit test, you don't want to depend on the external data source - so you dynamically replace the
get_data method with a stub that returns some fixed data.
Because Python classes are mutable, and methods are just attributes of the class, you can do this as much as you like - and, in fact, you can even replace classes and functions in a module in exactly the same way.
But, as a commenter pointed out, use caution when monkeypatching:
If anything else besides your test logic calls
get_data as well, it will also call your monkey-patched replacement rather than the original -- which can be good or bad. Just beware.
If some variable or attribute exists that also points to the
get_data function by the time you replace it, this alias will not change its meaning and will continue to point to the original
get_data. (Why? Python just rebinds the name
get_data in your class to some other function object; other name bindings are not impacted at all.)
A MonkeyPatch is a piece of Python code which extends or modifies other code at runtime (typically at startup).
A simple example looks like this:
from SomeOtherProduct.SomeModule import SomeClass def speak(self): return "ook ook eee eee eee!" SomeClass.speak = speak
Source: MonkeyPatch page on Zope wiki.
What is a monkey patch?
Simply put, monkey patching is making changes to a module or class while the program is running.
There's an example of monkey-patching in the Pandas documentation:
import pandas as pd def just_foo_cols(self): """Get a list of column names containing the string 'foo' """ return [x for x in self.columns if 'foo' in x] pd.DataFrame.just_foo_cols = just_foo_cols # monkey-patch the DataFrame class df = pd.DataFrame([list(range(4))], columns=["A","foo","foozball","bar"]) df.just_foo_cols() del pd.DataFrame.just_foo_cols # you can also remove the new method
To break this down, first we import our module:
import pandas as pd
Next we create a method definition, which exists unbound and free outside the scope of any class definitions (since the distinction is fairly meaningless between a function and an unbound method, Python 3 does away with the unbound method):
def just_foo_cols(self): """Get a list of column names containing the string 'foo' """ return [x for x in self.columns if 'foo' in x]
Next we simply attach that method to the class we want to use it on:
pd.DataFrame.just_foo_cols = just_foo_cols # monkey-patch the DataFrame class
And then we can use the method on an instance of the class, and delete the method when we're done:
df = pd.DataFrame([list(range(4))], columns=["A","foo","foozball","bar"]) df.just_foo_cols() del pd.DataFrame.just_foo_cols # you can also remove the new method
If you're using name-mangling (prefixing attributes with a double-underscore, which alters the name, and which I don't recommend) you'll have to name-mangle manually if you do this. Since I don't recommend name-mangling, I will not demonstrate it here.
How can we use this knowledge, for example, in testing?
Say we need to simulate a data retrieval call to an outside data source that results in an error, because we want to ensure correct behavior in such a case. We can monkey patch the data structure to ensure this behavior. (So using a similar method name as suggested by Daniel Roseman:)
import datasource def get_data(self): '''monkey patch datasource.Structure with this to simulate error''' raise datasource.DataRetrievalError datasource.Structure.get_data = get_data
And when we test it for behavior that relies on this method raising an error, if correctly implemented, we'll get that behavior in the test results.
Just doing the above will alter the
Structure object for the life of the process, so you'll want to use setups and teardowns in your unittests to avoid doing that, e.g.:
def setUp(self): # retain a pointer to the actual real method: self.real_get_data = datasource.Structure.get_data # monkey patch it: datasource.Structure.get_data = get_data def tearDown(self): # give the real method back to the Structure object: datasource.Structure.get_data = self.real_get_data
(While the above is fine, it would probably be a better idea to use the
mock library to patch the code.
patch decorator would be less error prone than doing the above, which would require more lines of code and thus more opportunities to introduce errors. I have yet to review the code in
mock but I imagine it uses monkey-patching in a similar way.)
According to Wikipedia:
In Python, the term monkey patch only refers to dynamic modifications of a class or module at runtime, motivated by the intent to patch existing third-party code as a workaround to a bug or feature which does not act as you desire.
First: monkey patching is an evil hack (in my opinion).
It is often used to replace a method on the module or class level with a custom implementation.
The most common usecase is adding a workaround for a bug in a module or class when you can't replace the original code. In this case you replace the "wrong" code through monkey patching with an implementation inside your own module/package.
Monkey patching can only be done in dynamic languages, of which python is a good example. Changing a method at runtime instead of updating the object definition is one example;similarly, adding attributes (whether methods or variables) at runtime is considered monkey patching. These are often done when working with modules you don't have the source for, such that the object definitions can't be easily changed.
This is considered bad because it means that an object's definition does not completely or accurately describe how it actually behaves.
Monkey patching is reopening the existing classes or methods in class at runtime and changing the behavior, which should be used cautiously, or you should use it only when you really need to.
As Python is a dynamic programming language, Classes are mutable so you can reopen them and modify or even replace them.
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