# 13. Introduction to Lists¶

## 13.1. Data Types¶

So far this book has shown four types of data:

• String (a string is short for “string of characters,” which normal people think of as text.)
• Integer
• Floating point
• Boolean

Python can display what type of data a value is with the type function. For example, what type of data is a 3?

# Print the type of data a 3 is:
print(type(3))

<class 'int'>


This type function isn’t useful for other programming in this book, but it is good to demonstrate the types of data introduced so far.

Here we set x to the four types of data we’ve used so far, and call the type command to see how Python classifies that data:

x = 3
print("x =", x, "and is of type:", type(x))

x = 3.145
print("x =", x, "and is of type:", type(x))

x = "Hi there"
print("x =", x, "and is of type:", type(x))

x = True
print("x =", x, "and is of type:", type(x))


The output:

x = 3 and is of type: <class 'int'>
x = 3.145 and is of type: <class 'float'>
x = Hi there and is of type: <class 'str'>
x = True and is of type: <class 'bool'>


Note

More than one coin to collect? Use a list!

The two new types of data introduced in this chapter are Lists and Tuples. Lists are similar to another data structure called an array. A list can be resized, but an array can not. A course in data structures will teach you the details, but it that is beyond the scope of this book. Try running the following commands in the interactive Python shell and see what is displayed:

x = (2, 3, 4, 5)
print("x =", x, "and is of type:", type(x))

x = [2, 3, 4, 5]
print("x =", x, "and is of type:", type(x))


The output:

x = (2, 3, 4, 5) and is of type: <class 'tuple'>
x = [2, 3, 4, 5] and is of type: <class 'list'>


## 13.2. Working With Lists¶

You’ve created grocery lists, to-do lists, bucket lists, but how do you create a list on the computer?

To create a list and print it out, try the following:

x = [1, 2]
print(x)


The output:

[1, 2]


To print an individual element in a list:

print(x[0])


The output:

1


This number with the item’s location is called the index. Note that list locations start at zero. So a list or array with 10 elements does not have an element in spot [10]. Just spots [0] through [9]. It can be very confusing to create an list of 10 items and then not have an item 10, but most computer languages start counting at 0 rather than 1.

Think of a list as an ice cube tray that holds numbers, as shown in Figure 7.2. The values are stored inside each tray spot, and written on the side of the tray are numbers starting at zero that identify the location of each spot.

Attention

Don’t mix the index and the value!

Remember, there are two sets of numbers to consider when working with a list of numbers: the position and the value. The position, also known as index, refers to where a value is. The value is the actual number stored at that location. When working with a list or array, make sure to think if you need the location or the value.

It is easy to get the value given the location, but it is harder to get the location given the value. Chapter 15 is dedicated to answering how to find the location of a particular value.

A program can assign new values to an individual element in a list. In the case below, the first spot at location zero (not one) is assigned the number 22.

x = [1, 2]
print(x)

x[0] = 22
print(x)

[1, 2]
[22, 2]


Also, a program can create a “tuple.” This data type works just like a list, but with two differences. First, it is created with parentheses rather than square brackets. Second, it is not possible to change the tuple once created. See below:

x = (1, 2)
print(x)

x[0] = 22
print(x)

[1, 2]
Traceback (most recent call last):
File "<pyshell#18>", line 4, in <module>
x[0] = 22
TypeError: 'tuple' object does not support item assignment


As can be seen from the output of the code above, we can’t assign an item in the tuple a new value. Why would we want this limitation? First, the computer can run faster if it knows the value won’t change. Second, some lists we don’t want to change, such as a list of RGB colors for red. The color red doesn’t change, therefore an immutable tuple is a better choice.

## 13.3. Iterating (Looping) Through a List¶

If a program needs to iterate through each item in a list, such as to print it out, there are two types of for loops that can do this.

The first method to iterate through each item in a loop is by using a “for-each” loop. This type of loop takes a collection of items, and loops the code once per item. It will take a copy of the item and store it in a variable for processing.

The format of the command:

for item_variable in list_name:


Here are some examples:

my_list = [101, 20, 10, 50, 60]
for item in my_list:
print(item)

101
20
10
50
60


Programs can store strings in lists too:

my_list = ["Spoon", "Fork", "Knife"]
for item in my_list:
print(item)

Spoon
Knife
Fork


Lists can even contain other lists. This iterates through each item in the main list, but not in sublists.

my_list = [[2, 3], [4, 3], [6, 7]]
for item in my_list:
print(item)

[2,3]
[4,3]
[6,7]


The other way to iterate through a list is to use an index variable and directly access the list rather than through a copy of each item. To use an index variable, the program counts from 0 up to the length of the list. If there are ten elements, the loop must go from 0 to 9 for a total of ten elements.

The length of a list may be found by using the len function. Combining that with the range function allows the program to loop through the entire list.

my_list = [101, 20, 10, 50, 60]
for index in range(len(my_list)):
print(my_list[index])

101
20
10
50
60


This method is more complex, but is also more powerful. Because we are working directly with the list elements, rather than a copy, the list can be modified. The for-each loop does not allow modification of the original list.

## 13.4. Looping With Both An Index And Element¶

If you want both the index, like a for i in range gives you, and the element, like a for item in my_list gives you, the proper Python-ic way to use the enumerate function like this:

for index, value in enumerate(my_list):
print(index, value)


## 13.5. Adding to a List¶

New items may be added to a list (but not a tuple) by using the append command. For example:

my_list = [2, 4, 5, 6]
print(my_list)
my_list.append(9)
print(my_list)

[2, 4, 5, 6]
[2, 4, 5, 6, 9]


Side note: If performance while appending is a concern, it is very important to understand how a list is being implemented. For example, if a list is implemented as an array data type, then appending an item to the list is a lot like adding a new egg to a full egg carton. A new egg carton must be built with thirteen spots. Then twelve eggs are moved over. Then the thirteenth egg is added. Finally the old egg carton is recycled. Because this can happen behind the scenes in a function, programmers may forget this and let the computer do all the work. It would be more efficient to simply tell the computer to make an egg carton with enough spots to begin with. Thankfully, Python does not implement a list as an array data type. But it is important to pay attention to your next semester data structures class and learn how all of this works.

To create a list from scratch, it is necessary to create a blank list and then use the append function. This example creates a list based upon user input:

Creating a list of numbers from user input

# Create an empty list
my_list = []

for i in range(5):
user_input = input( "Enter an integer: ")
user_input = int(user_input)
my_list.append(user_input)
print(my_list)

Enter an integer: 4
[4]
Enter an integer: 5
[4, 5]
Enter an integer: 3
[4, 5, 3]
Enter an integer: 1
[4, 5, 3, 1]
Enter an integer: 8
[4, 5, 3, 1, 8]


If a program needs to create an array of a specific length, all with the same value, a simple trick is to use the following code:

Create an array with 100 zeros
 1 2 # Create an array with 100 zeros. my_list = [0] * 100 

## 13.6. Summing or Modifying a List¶

Creating a running total of an array is a common operation. Here’s how it is done:

Summing the values in a list v1
  1 2 3 4 5 6 7 8 9 10 11 12 13 14 # Copy of the array to sum my_list = [5, 76, 8, 5, 3, 3, 56, 5, 23] # Initial sum should be zero list_total = 0 # Loop from 0 up to the number of elements # in the array: for index in range(len(my_list)): # Add element 0, next 1, then 2, etc. list_total += my_list[index] # Print the result print(list_total) 

The same thing can be done by using a for loop to iterate the array, rather than count through a range:

Summing the values in a list v2
  1 2 3 4 5 6 7 8 9 10 11 12 13 14 # Copy of the array to sum my_list = [5, 76, 8, 5, 3, 3, 56, 5, 23] # Initial sum should be zero list_total = 0 # Loop through array, copying each item in the array into # the variable named item. for item in my_list: # Add each item list_total += item # Print the result print(list_total) 

Numbers in an array can also be changed by using a for loop:

Doubling all the numbers in a list
  1 2 3 4 5 6 7 8 9 10 11 # Copy of the array to modify my_list = [5, 76, 8, 5, 3, 3, 56, 5, 23] # Loop from 0 up to the number of elements # in the array: for index in range(len(my_list)): # Modify the element by doubling it my_list[index] = my_list[index] * 2 # Print the result print(my_list) 

However version 2 does not work at doubling the values in an array. Why? Because item is a copy of an element in the array. The code below doubles the copy, not the original array element.

Bad code that doesn’t double all the numbers in a list
  1 2 3 4 5 6 7 8 9 10 11 # Copy of the array to modify my_list = [5, 76, 8, 5, 3, 3, 56, 5, 23] # Loop through each element in myArray for item in my_list: # This doubles item, but does not change the array # because item is a copy of a single element. item = item * 2 # Print the result print(my_list) 

## 13.7. Slicing Strings¶

Strings are actually lists of characters. They can be treated like lists with each letter a separate item. Run the following code with both versions of x:

Accessing a string as a list
  1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 x = "This is a sample string" #x = "0123456789" print("x=", x) # Accessing a single character print("x[0]=", x[0]) print("x[1]=", x[1]) # Accessing from the right side print("x[-1]=", x[-1]) # Access 0-5 print("x[:6]=", x[:6]) # Access 6 print("x[6:]=", x[6:]) # Access 6-8 print("x[6:9]=", x[6:9]) 

Strings in Python may be used with some of the mathematical operators. Try the following code and see what Python does:

 1 2 3 4 5 6 7 8 a = "Hi" b = "There" c = "!" print(a + b) print(a + b + c) print(3 * a) print(a * 3) print((a * 2) + (b * 2)) 

It is possible to get a length of a string. It is also possible to do this with any type of array.

Getting the length of a string or list
 1 2 3 4 5 a = "Hi There" print(len(a)) b = [3, 4, 5, 6, 76, 4, 3, 3] print(len(b)) 

Since a string is an array, a program can iterate through each character element just like an array:

for character in "This is a test.":
print(character)


Exercise: Starting with the following code:

 1 2 months = "JanFebMarAprMayJunJulAugSepOctNovDec" n = int(input("Enter a month number: ")) 

Print the three month abbreviation for the month number that the user enters. (Calculate the start position in the string, then use the info we just learned to print out the correct substring.)

## 13.8. Secret Codes¶

This code prints out every letter of a string individually:

 1 2 3 4 plain_text = "This is a test. ABC abc" for c in plain_text: print(c, end=" ") 

Computers do not actually store letters of a string in memory; computers store a series of numbers. Each number represents a letter. The system that computers use to translate numbers to letters is called Unicode. The full name for the encoding is Universal Character Set Transformation Format 8-bit, usually abbreviated UTF-8.

The Unicode chart covers the Western alphabet using the numbers 0-127. Each Western letter is represented by one byte of memory. Other alphabets, like Cyrillic, can take multiple bytes to represent each letter. A partial copy of the Unicode chart is below:

 Value Character Value Character Value Character Value Character 40 ( 61 = 82 R 103 g 41 ) 62 > 83 S 104 h 42 63 ? 84 T 105 i 43 64 @ 85 U 106 j 44 , 65 A 86 V 107 k 45 66 B 87 W 108 l 46 . 67 C 88 X 109 m 47 / 68 D 89 Y 110 n 48 0 69 E 90 Z 111 o 49 1 70 F 91 [ 112 p 50 2 71 G 92 113 q 51 3 72 H 93 ] 114 r 52 4 73 I 94 ^ 115 s 53 5 74 J 95 _ 116 t 54 6 75 K 96  117 u 55 7 76 L 97 a 118 v 56 8 77 M 98 b 119 w 57 9 78 N 99 c 120 x 58 : 79 O 100 d 121 y 59 ; 80 P 101 e 122 z 60 < 81 Q 102 f

For more information about ASCII (which has the same values as Unicode for the Western alphabet) see:

http://en.wikipedia.org/wiki/ASCII

For a video that explains the beauty of Unicode, see here:

This next set of code converts each of the letters in the prior example to its ordinal value using UTF-8:

plain_text = "This is a test. ABC abc"

for c in plain_text:
print(ord(c), end=" ")


This next program takes each UTF-8 value and adds one to it. Then it prints the new UTF-8 value, then converts the value back to a letter.

plain_text = "This is a test. ABC abc"

for c in plain_text:
x = ord(c)
x = x + 1
c2 = chr(x)
print(c2, end="")


The next code listing takes each UTF-8 value and adds one to it, then converts the value back to a letter.

simple_encryption.py
  1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 # Sample Python/Pygame Programs # Simpson College Computer Science # http://programarcadegames.com/ # http://simpson.edu/computer-science/ # Explanation video: http://youtu.be/sxFIxD8Gd3A plain_text = "This is a test. ABC abc" encrypted_text = "" for c in plain_text: x = ord(c) x = x + 1 c2 = chr(x) encrypted_text = encrypted_text + c2 print(encrypted_text) 

Finally, the last code takes each UTF-8 value and subtracts one from it, then converts the value back to a letter. By feeding this program the output of the previous program, it serves as a decoder for text encoded by the prior example.

simple_decryption.py
  1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 # Sample Python/Pygame Programs # Simpson College Computer Science # http://programarcadegames.com/ # http://simpson.edu/computer-science/ # Explanation video: http://youtu.be/sxFIxD8Gd3A encrypted_text = "Uijt!jt!b!uftu/!BCD!bcd" plain_text = "" for c in encrypted_text: x = ord(c) x = x - 1 c2 = chr(x) plain_text = plain_text + c2 print(plain_text) 

## 13.9. Associative Arrays¶

Python is not limited to using numbers as an array index. It is also possible to use an associative array. An associative array works like this:

  1 2 3 4 5 6 7 8 9 10 11 # Create an empty associative array # (Note the curly braces.) x = {} # Add some stuff to it x["fred"] = 2 x["scooby"] = 8 x["wilma"] = 1 # Fetch and print an item print(x["fred"]) `

You won’t really need associative arrays for this class, but I think it is important to point out that it is possible.