Functions
Contents
Functions#
Throughout the previous Notebooks, we have been using functions provided by Python or by modules like numpy
or mobilechelonian
. Functions are one of the key features of programming languages that allow us to write complex programs. When we talk about functions in programming, we mean something more general than in mathematics.
A function is simply a piece of code that achieves a particular task, and is written in such a way that it can be called whenever that task needs to be done. One of the key skills in programming is splitting up a problem into smaller sub-problems (i.e. smaller problems) that can be solved by functions.
Because functions are used to solve sub-problems, functions are sometimes called “subroutines” in other programming languages.
Here’s an example of how we can define a function to draw a square using a turtle.
def draw_square(turt):
for i in range(4):
turt.forward(100)
turt.left(90)
from mobilechelonian import Turtle
raphael = Turtle()
raphael.speed(5)
draw_square(raphael) # call the function with argument terry
---------------------------------------------------------------------------
ModuleNotFoundError Traceback (most recent call last)
Input In [2], in <cell line: 1>()
----> 1 from mobilechelonian import Turtle
2 raphael = Turtle()
3 raphael.speed(5)
ModuleNotFoundError: No module named 'mobilechelonian'
Let’s look at what this means. The line def draw_square(turt):
tells Python that we are defining a function which is called draw_square
and has a single parameter called turt
. This means that we will be able to call the function draw_square
by passing a single argument like so: draw_square(raphael)
. Inside the function, there will be a variable called turt
which refers to raphael
. You can think of turt
being replaced by raphael
wherever it is used.
The indented block of code
for i in range(4):
turt.forward(100)
turt.left(90)
is called the body of the function. Whenever we call draw_square
, the lines of code in the body are run, but turt
will refer to whatever argument is given to the function. If we call draw_square(raphael)
then you can think of the body of the for
loop as being
for i in range(4):
raphael.forward(100)
raphael.left(90)
Note that we could call draw_square
with any single argument, like the number 3
.
Because it doesn’t make sense to call 3.forward(100)
or 3.left(90)
, we would get a runtime error if we try to call draw_square(3)
; see the optional aside at the end for more details.
So far this hasn’t saved us any effort - we might as well have just written the code that draws the square like we did in previous Notebooks. The savings occur when we use the function more than once:
terry = Turtle()
terry.speed(5)
terry.pencolor("orange") # anything terry draws will now be orange
draw_square(terry)
terry.right(90)
terry.pencolor("green") # anything terry draws will now be green
draw_square(terry)
Having the function draw_square
allowed us to draw two squares without repeating many lines of code. A common piece of advice is to write DRY code (Don’t Repeat Yourself) not WET code (Write Everything Twice) - in other words, where you have to perform the same set of operations multiple times, write a function once and use it.
Functions have another major benefit, which makes them worth writing even if you only use them once. They are a natural way of splitting a problem into smaller parts, and they make it easier to test your code, since you can test each function individually. If you choose sensible function names, they also make your code easier to understand, since anyone reading your code can see what the function is supposed to accomplish. You don’t need to read the code for the function draw_square
to understand what the previous code cell should do.
Fruitful functions#
In the example above, the function draw_square
“does something” - we give it an object and ask it to do something to that object. There is another use of functions, which we have seen before with numpy
:
import numpy as np
np.sin(np.pi/2)
1.0
Here the function np.sin
returns an answer. Here’s how you return a value:
# returns the square of x
def square(x):
return x ** 2
square(3)
9
Of course, square
is not very useful - we could just write 3 ** 2
directly instead. Here’s a more useful example - a function to represent the polynomial \(f(x) = (2x-3)^3 - 10(2x -3) + 2\).
def f(x):
y = 2*x - 3
return y ** 3 - 10*y + 2
We will see more on plotting in a later Notebook, but it is now straightforward to plot f
:
%matplotlib inline
import matplotlib.pyplot as plt # the standard plotting library
X = np.linspace(-2, 5, 1000) # choose the points to evaluate f on
plt.plot(X, f(X)) # plot those points against the value of f
plt.show() # tells Python to produce the plot now
# We should also add axes labels, a title, and a legend - but we will
# leave that for now.
Multiple parameters#
Your functions can have more than one parameter. For example, the polynomial in two variables \(g(x, y) = 2x^2y + xy^2 + 3y^3\) could be represented like so:
def g(x, y):
return 2*(x**2)*y + x*(y**2) + 3*(y**3)
It is important that when you call g
you provide the arguments in the same order they are defined, so to evaluate \(g\) at \((x = 1, y = 2)\) you should call
g(1, 2)
32
Multiple return values#
Strictly speaking, functions have at most one return value. However, that return value can be a tuple containing multiple things, and you can “unpack” the tuple into several variables after returning it. There is more on tuples later. For now, we consider the example of writing a Python function to represent the mathematical vector function
\[ w(x, y) = \begin{pmatrix} x^2y + 3 \ y^3 - 3x \end{pmatrix}. \]
def w(x, y):
return x**2 * y + 3, y**3 - 3*x # returns a tuple of values
# the return value of w(2, 3) is a tuple:
w(2, 3)
(15, 21)
# get the first component of w(2, 3) as u, and the second component as v
u, v = w(2, 3)
u
15
v
21
Invisible variables#
One crucial fact about functions is that variables that are created inside functions cannot be accessed from the outside. The following code cell gives an error, because we try to access a variable that only exists inside the function sum_of_sin_powers
. We instead should be using the value sum_of_sin_powers(np.pi, 3)
directly, or storing it in a variable.
import numpy as np
# returns the sum of (1/n**2) for i from 1 to n
def sum_of_inverse_squares(n):
sum_total = 0
for i in range(1, n + 1):
sum_total = sum_total + 1/(i**2)
return sum_total
sum_of_inverse_squares(20)
1.5961632439130233
sum_total # this doesn't work!
---------------------------------------------------------------------------
NameError Traceback (most recent call last)
Input In [16], in <cell line: 1>()
----> 1 sum_total
NameError: name 'sum_total' is not defined
You can think of functions as “black boxes”: from the perspective of the rest of a program, precisely what goes on inside a function is invisible. The program simply feeds them some input (the arguments), the box does something, and then it may or may not give some output (a return
value).
Note: while variables inside functions are hidden from the rest of the program, functions can access variables that exist in the rest of the program. If they modify those variables, the effects can be seen in the rest of the program (though whether or not the effect will be seen is a little complex). This can be very confusing, and it is usually better to have all of the information a function needs as parameters.
The principles governing when a given variable name is useable or not are called scoping, and for the moment we don’t want you to get bogged down in them.
Optional Aside 1: Member functions#
When we tell a turtle to move forward by writing turtle.forward(100)
, we are also calling a function. However, it looks different to calling draw_square(turtle)
or draw_pentagon(turtle)
. This is because forward
is a member function of the Turtle
class. In these notes we won’t discuss these terms any further, other than to say that it would be possible to make draw_square
into a member function and call it in the form turtle.draw_square()
.
Optional Aside 2: Duck typing#
In many programming languages, we would have to declare what “type” of objects our function takes, and the language would not allow us to pass any arguments that do not match those types. Python is more permissive, and uses “duck typing”. This follows the philosophy “if it walks like a duck, and quacks like a duck, it is a duck”.
Suppose we have written a function that is intended to take a Duck
as its parameter d
. Python will accept any argument (say, bird
), and attempt to run the function. As long as the argument bird
can do everything that the function asks the duck to do (e.g. d.fly(somewhere)
), Python will be happy. But now suppose that the function also asks for d.swim(somewhere)
, and this species of bird cannot swim (i.e. bird
has no swim
member function). At this point, Python will throw a runtime error.
Optional Aside 3: Default Arguments#
Sometimes you want to provide a sensible default value for a parameter, so that someone using your function doesn’t have to enter it. This happens with the function range
- it has a default start
value of 0 and step
value of 1. Here’s an example of how you would do this; note the terms=10
in the function definition.
import math
# evaluate the MacLaurin series of sin at x
# defaults to 10 terms in the series
def sin_maclaurin(x, terms=10):
total = 0
for i in range(terms):
term = (-1)**i * x**(2*i + 1)/math.factorial(2*i + 1)
total += term
return total
import numpy as np
# evaluate sin(5pi) using 10 terms
sin_maclaurin(5 * np.pi)
-169520.86600176583
# now use 20 terms for a more accurate value (still not great!)
sin_maclaurin(5 * np.pi, 20)
-0.288602305192303