# How does functools partial do what it does?

I am not able to get my head on how the partial works in functools. I have the following code from here:

``````>>> sum = lambda x, y : x + y
>>> sum(1, 2)
3
>>> incr = lambda y : sum(1, y)
>>> incr(2)
3
>>> def sum2(x, y):
return x + y

>>> incr2 = functools.partial(sum2, 1)
>>> incr2(4)
5
``````

Now in the line

``````incr = lambda y : sum(1, y)
``````

I get that whatever argument I pass to `incr` it will be passed as `y` to `lambda` which will return `sum(1, y)` i.e `1 + y`.

I understand that. But I didn't understand this `incr2(4)`.

How does the `4` gets passed as `x` in partial function? To me, `4` should replace the `sum2`. What is the relation between `x` and `4`?

• Simple answer: it doesn't! It's actually passed as `y`. Try adding the line `print(f'x: {x}, y: {y}')` to the top of `sum2` and you'll see, Check @MSK's answer below. Oct 11, 2021 at 9:04

Roughly, `partial` does something like this (apart from keyword args support etc):

``````def partial(func, *part_args):
def wrapper(*extra_args):
args = list(part_args)
args.extend(extra_args)
return func(*args)

return wrapper
``````

So, by calling `partial(sum2, 4)` you create a new function (a callable, to be precise) that behaves like `sum2`, but has one positional argument less. That missing argument is always substituted by `4`, so that `partial(sum2, 4)(2) == sum2(4, 2)`

As for why it's needed, there's a variety of cases. Just for one, suppose you have to pass a function somewhere where it's expected to have 2 arguments:

``````class EventNotifier(object):
def __init__(self):
self._listeners = []

''' callback should accept two positional arguments, event and params '''
self._listeners.append(callback)
# ...

def notify(self, event, *params):
for f in self._listeners:
f(event, params)
``````

But a function you already have needs access to some third `context` object to do its job:

``````def log_event(context, event, params):
context.log_event("Something happened %s, %s", event, params)
``````

So, there are several solutions:

A custom object:

``````class Listener(object):
def __init__(self, context):
self._context = context

def __call__(self, event, params):
self._context.log_event("Something happened %s, %s", event, params)

``````

Lambda:

``````log_listener = lambda event, params: log_event(context, event, params)
``````

With partials:

``````context = get_context()  # whatever
``````

Of those three, `partial` is the shortest and the fastest. (For a more complex case you might want a custom object though).

• from where did u get the `extra_args` variable Mar 11, 2013 at 5:40
• `extra_args` is something that passed by the partial caller, in the example with `p = partial(func, 1); f(2, 3, 4)` it is `(2, 3, 4)`. Mar 11, 2013 at 5:42
• but why we would do that , any special use case where something has to be done by partial only and can't be done with other thing Mar 11, 2013 at 5:43
• @user1865341 I added an example to the answer. Mar 11, 2013 at 5:52
• with your example , what is the relation between `callback` and `my_callback` Mar 11, 2013 at 6:06

partials are incredibly useful.

For instance, in a 'pipe-lined' sequence of function calls (in which the returned value from one function is the argument passed to the next).

Sometimes a function in such a pipeline requires a single argument, but the function immediately upstream from it returns two values.

In this scenario, `functools.partial` might allow you to keep this function pipeline intact.

Here's a specific, isolated example: suppose you want to sort some data by each data point's distance from some target:

``````# create some data
import random as RND
fnx = lambda: RND.randint(0, 10)
data = [ (fnx(), fnx()) for c in range(10) ]
target = (2, 4)

import math
def euclid_dist(v1, v2):
x1, y1 = v1
x2, y2 = v2
return math.sqrt((x2 - x1)**2 + (y2 - y1)**2)
``````

To sort this data by distance from the target, what you would like to do of course is this:

``````data.sort(key=euclid_dist)
``````

but you can't--the sort method's key parameter only accepts functions that take a single argument.

so re-write `euclid_dist` as a function taking a single parameter:

``````from functools import partial

p_euclid_dist = partial(euclid_dist, target)
``````

`p_euclid_dist` now accepts a single argument,

``````>>> p_euclid_dist((3, 3))
1.4142135623730951
``````

so now you can sort your data by passing in the partial function for the sort method's key argument:

``````data.sort(key=p_euclid_dist)

# verify that it works:
for p in data:
print(round(p_euclid_dist(p), 3))

1.0
2.236
2.236
3.606
4.243
5.0
5.831
6.325
7.071
8.602
``````

Or for instance, one of the function's arguments changes in an outer loop but is fixed during iteration in the inner loop. By using a partial, you don't have to pass in the additional parameter during iteration of the inner loop, because the modified (partial) function doesn't require it.

``````>>> from functools import partial

>>> def fnx(a, b, c):
return a + b + c

>>> fnx(3, 4, 5)
12
``````

create a partial function (using keyword arg)

``````>>> pfnx = partial(fnx, a=12)

>>> pfnx(b=4, c=5)
21
``````

you can also create a partial function with a positional argument

``````>>> pfnx = partial(fnx, 12)

>>> pfnx(4, 5)
21
``````

but this will throw (e.g., creating partial with keyword argument then calling using positional arguments)

``````>>> pfnx = partial(fnx, a=12)

>>> pfnx(4, 5)
Traceback (most recent call last):
File "<pyshell#80>", line 1, in <module>
pfnx(4, 5)
TypeError: fnx() got multiple values for keyword argument 'a'
``````

another use case: writing distributed code using python's `multiprocessing` library. A pool of processes is created using the Pool method:

``````>>> import multiprocessing as MP

>>> # create a process pool:
>>> ppool = MP.Pool()
``````

`Pool` has a map method, but it only takes a single iterable, so if you need to pass in a function with a longer parameter list, re-define the function as a partial, to fix all but one:

``````>>> ppool.map(pfnx, [4, 6, 7, 8])
``````
• is there any practical use of this function somewher Mar 11, 2013 at 5:53
• @user1865341 added two exemplarly use cases to my answer
– doug
Mar 11, 2013 at 6:18
• IMHO, this is a better answer as it keeps out unrelated concepts like objects and classes and focuses on functions which is what this is all about. Apr 4, 2020 at 20:46

short answer, `partial` gives default values to the parameters of a function that would otherwise not have default values.

``````from functools import partial

def foo(a,b):
return a+b

bar = partial(foo, a=1) # equivalent to: foo(a=1, b)
bar(b=10)
#11 = 1+10
bar(a=101, b=10)
#111=101+10
``````
• this is half true because we can override default values, we can even override overriden parameters by subsequent `partial` and so on Oct 12, 2018 at 3:39
• First, he did not claim they are immutable and secondly, he even demonstrates how they can be overridden? Sep 23 at 11:42

Partials can be used to make new derived functions that have some input parameters pre-assigned

To see some real world usage of partials, refer to this really good blog post here

A simple but neat beginner's example from the blog, covers how one might use `partial` on `re.search` to make code more readable. `re.search` method's signature is:

``````search(pattern, string, flags=0)
``````

By applying `partial` we can create multiple versions of the regular expression `search` to suit our requirements, so for example:

``````is_spaced_apart = partial(re.search, '[a-zA-Z]\s\=')
is_grouped_together = partial(re.search, '[a-zA-Z]\=')
``````

Now `is_spaced_apart` and `is_grouped_together` are two new functions derived from `re.search` that have the `pattern` argument applied(since `pattern` is the first argument in the `re.search` method's signature).

The signature of these two new functions(callable) is:

``````is_spaced_apart(string, flags=0)     # pattern '[a-zA-Z]\s\=' applied
is_grouped_together(string, flags=0) # pattern '[a-zA-Z]\=' applied
``````

This is how you could then use these partial functions on some text:

``````for text in lines:
if is_grouped_together(text):
some_action(text)
elif is_spaced_apart(text):
some_other_action(text)
else:
some_default_action()
``````

You can refer the link above to get a more in depth understanding of the subject, as it covers this specific example and much more..

• Isn't this equivalent to `is_spaced_apart = re.compile('[a-zA-Z]\s\=').search`? If so, is there a guarantee that the `partial` idiom compiles the regular expression for faster reuse? May 7, 2020 at 8:33
• Commenting because edit queue is full. The link is dead. It can be replaced with web.archive.org/web/20160920124126/https://chriskiehl.com/… Jul 28 at 14:39

In my opinion, it's a way to implement currying in python.

``````from functools import partial
return a + b

return x + y + z

if __name__ == "__main__":
``````

The result is 3 and 4.

• Hmm, not exactly. Currying is dividing a function with n parameters into n successive functions with one parameter. Partial application is 'pre-filling' a function with some parameters, then returning a function with a smaller number of parameters Oct 13, 2021 at 11:38

This answer is more of an example code. All the above answers give good explanations regarding why one should use partial. I will give my observations and use cases about partial.

``````from functools import partial
print('a:{},b:{},c:{}'.format(a,b,c))
ans = a+b+c
print(ans)
partial_adder(3)  ## now partial_adder is a callable that can take only one argument
``````

Output of the above code should be:

``````a:1,b:2,c:3
6
``````

Notice that in the above example a new callable was returned that will take parameter (c) as it's argument. Note that it is also the last argument to the function.

``````args = [1,2]
``````

Output of the above code is also:

``````a:1,b:2,c:3
6
``````

Notice that * was used to unpack the non-keyword arguments and the callable returned in terms of which argument it can take is same as above.

Another observation is: Below example demonstrates that partial returns a callable which will take the undeclared parameter (a) as an argument.

``````def adder(a,b=1,c=2,d=3,e=4):
print('a:{},b:{},c:{},d:{},e:{}'.format(a,b,c,d,e))
ans = a+b+c+d+e
print(ans)
``````

Output of the above code should be:

``````a:20,b:10,c:2,d:3,e:4
39
``````

Similarly,

``````kwargs = {'b':10,'c':2}
``````

Above code prints

``````a:20,b:10,c:2,d:3,e:4
39
``````

I had to use it when I was using `Pool.map_async` method from `multiprocessing` module. You can pass only one argument to the worker function so I had to use `partial` to make my worker function look like a callable with only one input argument but in reality my worker function had multiple input arguments.

Also worth to mention, that when partial function passed another function where we want to "hard code" some parameters, that should be rightmost parameter

``````def func(a,b):
return a*b
prt = partial(func, b=7)
print(prt(4))
#return 28
``````

but if we do the same, but changing a parameter instead

``````def func(a,b):
return a*b
prt = partial(func, a=7)
print(prt(4))
``````

it will throw error, "TypeError: func() got multiple values for argument 'a'"

• Huh? You do the leftmost parameter like this: `prt=partial(func, 7)` Oct 25, 2019 at 14:00

Adding couple of case from machine learning where the functional programming currying with `functools.partial` can be quite useful:

Build multiple models on the same dataset

the following example shows how `linear regression`, `support vector machine` and `random forest` regression models can be fitted on the same `diabetes` dataset, to predict the target and compute the score.

The (partial) function `classify_diabetes()` is created from the function `classify_data()` by currying (using `functools.partial()`). The later function does not require the data to be passed anymore and we can straightaway pass only the instances of the classes for the models.

``````from functools import partial
from sklearn.linear_model import LinearRegression
from sklearn.svm import SVR
from sklearn.ensemble import RandomForestRegressor
from sklearn.datasets import load_diabetes

def classify_data(data, model):
reg = model.fit(data['data'], data['target'])
return model.score(data['data'], data['target'])

classify_diabetes = partial(classify_data, diabetes) # curry
for model in [LinearRegression(), SVR(), RandomForestRegressor()]:
print(f'model {type(model).__name__}: score = {classify_diabetes(model)}')

# model LinearRegression: score = 0.5177494254132934
# model SVR: score = 0.2071794500005485
# model RandomForestRegressor: score = 0.9216794155402649
``````

Setting up the machine learning pipeline

Here the function `pipeline()` is created with currying which already uses `StandardScaler()` to preprocess (scale / normalize) the data prior to fitting the model on it, as shown in the next example:

``````from sklearn.pipeline import make_pipeline
from sklearn.preprocessing import StandardScaler

pipeline = partial(make_pipeline, StandardScaler()) # curry
for model in [LinearRegression(), SVR(), RandomForestRegressor()]:
print(f"model {type(model).__name__}: " \
f"score = {pipeline(model).fit(diabetes['data'], diabetes['target'])\
.score(diabetes['data'], diabetes['target'])}")

# model LinearRegression: score = 0.5177494254132934
# model SVR: score = 0.2071794500005446
# model RandomForestRegressor: score = 0.9180227193805106
``````