We use variables to store values that can be used to control commands in our code. We can also alter these values throughout the code.
# Make a variable to store text name = "Zach" # Create variables that are numbers num_one = 3 num_two = 4 sum_nums = num_one + num_two # We can also assign multiple variables at once num_one, num_two = 3, 4 # The value of a variable can be changed after it has been created num_one = num_one + 1
Variables have an associated 'type' based on their characteristics. A string (str) is a text element, an integer (int) is a whole number element, a float (float) is a number with decimal places, and a Boolean (bool) is an element that returns either True or False. We use the type command to determine the type of an element.
# The output will be str, or string print(type(name)) # The output will be int, or integer print(type(sum_nums)) # The output will be bool, or boolean print(type(3==3)) # We can change the type of an element by using the shortened name of the type # We do this when concatenating strings, such as: age = 16 print("My age is " + str(age))
We use comments to leave notes about the code to the reader. Comments are not actually run by Python, they are just there to help us read the code.
We can make multiline comments with """ and single line comments with #.
""" A multi-line comment describes your code to someone who is reading it. """ Example: """ This program will ask the user for two numbers. Then it will add the numbers and print the final value. """ number_one = int(input("Enter a number: ")) number_two = int(input("Enter a second number: ")) print("Sum: " + str(number_one + number_two)) # Use single line comments to clarify parts of code. Example: # This program adds 1 and 2 added = 1 + 2 print(added)
Exception handling allows us to prevent our programs from crashing in the event of a fault.
# Try/Except with input try: my_number = int(input("Enter an integer: ")) print("Your number: " + str(my_number)) except ValueError: print("That wasn't an integer!") # Try/Except for Type Errors try: my_number = '2' + 2 except TypeError: print("A type error has occurred!") # Try/Except for Key Errors dictionary = {'1':'k', '3':'A', '4':'R', '5':'E', '6':'L'} try: dictionary['2'] except KeyError: print("Key error") # Try/Except for Attribute Errors try: dictionary.no_method() except AttributeError: print("Attribute Error!") # You can also have try: my_number = int(input("Enter an integer: ")) print("Your number: " + str(my_number)) except: print("There was an error.")
To be able to use the randint or choice functions, you must use import random at the beginning of your code.
# Random integer between (and including) low and high import random random_num = random.randint(low, high) random_element = random.choice(string) # Example: # Returns random number within and including 0 and 10. random_num = random.randint(0,10) # Random element in a string random_element = random.choice('abcdefghij')
We can tell the computer how to make decisions using if/else statements. Make sure that all the code inside your if/else statement is indented one level!
Use an if statement to instruct the computer to do something only when a condition is true. If the condition is false, the command indented underneath will be skipped.
if BOOLEAN_EXPRESSION: print("This executes if BOOLEAN_EXPRESSION evaluates to True") # Example: # The text will only print if the user enters a negative number number = int(input("Enter a number: ")) if number < 0: print(str(number) + " is negative!")
Use an if/else statement to force the computer to make a decision between multiple conditions. If the first condition is false, the computer will skip to the next condition until it finds one that is true. If no conditions are true, the commands inside the else block will be performed.
if condition_1: print("This executes if condition_1 evaluates to True") elif condition_2: print("This executes if condition_2 evaluates to True") else: print("This executes if no prior conditions evaluate to True") # Example: # This program will print that the color is secondary color == "purple" if color == "red" or color == "blue" or color == "yellow": print("Primary color.") elif color == "green" or color == "orange" or color == "purple": print("Secondary color.") else: print("Not a primary or secondary color.")
We use mathematical, comparison, and logical operators in our codes to compare and alter values and make decisions.
Use mathematical operators to alter values.
+ Addition - Subtraction * Multiplication / Division ** Power % Modulus (Remainder) () Parentheses (For order of operations) # Examples z = x + y w = x * y # Division a = 5.0 / 2 # Returns 2.5 b = 5.0 // 2 # Returns 2.0 c = 5/2 # Returns 2.5 d = 5 // 2 # Returns 2 # Increment (add one) x += 1 # Decrement (subtract one) x -= 1 # Absolute value absolute_value = abs(x) abs_val = abs(-5) # Returns 5 # Square root import math square_root = math.sqrt(x) # Raising to a power power = math.pow(x, y) # Calculates x^y # Alternate power = x**y # Calculates x^y # Rounding rounded_num = round(2.675, 2) # Returns 2.68
Use comparison operators to compare elements in order to make decisions in your code. Comparison operators return booleans (True/False).
x == y # is x equal to y x != y # is x not equal to y x > y # is x greater than y x >= y # is x greater than or equal to y x < y # is x less than y x <= y # is x less than or equal to y # Comparison operators in if statements if x == y: print("x and y are equal") if x > 5: print("x is greater than 5.")
Use logical operators to check multiple conditions at once or one condition out of multiple.
# And Operator and_expression = x and y # Or Operator or_expression = x or y # You can combine many booleans! boolean_expression = x and (y or z)
Loops help us repeat commands which makes our code much shorter. Make sure everything inside the loop is indented one level!
Use for loops when you want to repeat something a fixed number of times.
# This for loop will print "hello" 5 times for i in range(5): print("hello") # This for loop will print out even numbers 1 through 10 for number in range(2, 11, 2): print(number) # This code executes on each item in my_list # This loop will print 1, then 5, then 10, then 15 my_list = [1, 5, 10, 15] for item in my_list: print(item)
Use while loops when you want to repeat something an unknown number of times or until a condition becomes false. If there is no point where the condition becomes false, you will create an infinite loop which should always be avoided!
# This program will run as long as the variable 'number' is greater than 0 # Countdown from from 10 to 0 number = 10 while number >= 0: print(number) number -= 1 # You can also use user input to control a while loop # This code will continue running while the user answers 'Yes' answer = input("Continue code?: ") while answer == "Yes": answer = input("Continue code?: ")
We can use the break command to end our code. The continue command will leave the control structure at that point and move to the commands found afterward.
# This code will end when the use enters a negative number or 42 number = int(input("Enter a number: ")) while number != 42: if number < 0: break else: print(number) number = int(input("Enter a number: ")) # This code will only print the numbers 0 to 3 and 6 for i in range(5): if i < 4: print(i) else: continue print(6)
Writing a function is like teaching the computer a new word.
Naming Functions: You can name your functions whatever you want, but you can't have spaces in the function name. Instead of spaces, use underscores ( _ ) like_this_for_example
Make sure that all the code inside your function is indented one level!
We define a function to teach the computer the instructions for a new word. We need to use the term def to tell the computer we're creating a function.
def name_of_your_function(): # Code that will run when you make a call to # this function. # Example: # Teach the computer to add two numbers num_one = 1 num_two = 2 def add_numbers(): sum_nums = num_one + num_two
We can use the command return to have a function give a value back to the code that called it. Without the return command, we could not use any altered values that were determined by the function.
# We add a return statement in order to use the value of the sum variable num_one = 1 num_two = 2 def add_numbers(): sum_nums = num_one + num_two return sum_nums
We call a function to tell the computer to actually carry out the new command.
# Call the add_numbers() function once # The computer will return a value of 3 add_numbers() # Call the add_numbers() function 3 times and print the output # The output will be the number 3 printed on 3 separate lines print(add_numbers()) print(add_numbers()) print(add_numbers())
We can use parameters to alter certain commands in our function. We have to include arguments for the parameters in our function call.
# In this program, parameters are used to give two numbers def add_numbers(num_one, num_two): sum_nums = num_one + num_two return sum_nums # We call the function with values inside the parentheses # This program will print '7' print(add_numbers(3, 4)) # If we have a list with the same number of parameters, we # can use the items to assign arguments using an asterisk my_list = [3, 4] print(add_numbers(*my_list))
Strings are pieces of text. We can gain much information about strings and alter them in many ways using various methods.
We use indexing to find or take certain portions of a string. Index values always start at 0 for the first character and increase by 1 as we move to the right. From the end of the string, the final value also has an index of -1 with the values decreasing by 1 as we move to the left.
# Prints a character at a specific index my_string = "hello!" print(my_string[0]) # print("h") print(my_string[5]) # print("!") # Prints all the characters after the specific index my_string = "hello world!" print(my_string[1:]) # print("ello world!") print(my_string[6:]) # prints("world!") # Prints all the characters before the specific index my_string = "hello world!" print(my_string[:6]) # print("hello") print(my_string[:1]) # print("h") # Prints all the characters between the specific indices my_string = "hello world!" print(my_string[1:6]) # print("ello") print(my_string[4:7]) # print("o w") # Get the length of the string print(len(my_string)) # Iterates through every character in the string # Will print one letter of the string on each line in order my_string = "Turtle" for i in range(len(my_string)): print(my_string[i]) # Another way to iterate through each character in the string my_string = "Turtle" for letter in my_string: print(letter) # Completes commands if the string is found inside the given string my_string = "hello world!" if "world" in my_string: print("world") # Concatenation my_string = "Tracy the" print(my_string + " turtle") # print("Tracy the turtle") # Splits the string into a list of letters my_string = "Tracy" my_list = list(my_string) # my_list = ['T', 'r', 'a', 'c', 'y'] # Using enumerate will print the index number followed by a colon and the # word at that index for each word in the list my_string = "Tracy is a turtle" for index, word in enumerate(my_string.split()): print(str(index) + ": " + word)
There are many methods that can be used to alter strings.
# upper: To make a string all uppercase my_string = "Hello" my_string = my_string.upper() # returns "HELLO" # lower: To make a string all lowercase my_string = "Hello" my_string = my_string.lower() # returns "hello" # isupper: Returns True if a string is all uppercase letters and False otherwise my_string = "HELLO" print(my_string.isupper()) # returns True # islower: Returns True if a string is all lowercase letters and False otherwise my_string = "Hello" print(my_string.islower()) # returns False # swapcase: Returns a string where each letter is the opposite case from original my_string = "PyThOn" my_string = my_string.swapcase() # returns "pYtHoN" # strip: Returns a copy of the string without any whitespace at beginning or end my_string = " hi there " my_string = my_string.strip() # returns "hi there" # find: Returns the lowest index in the string where substring is found # Returns -1 if substring is not found my_string = "eggplant" index = my_string.find("plant") # returns 3 index = my_string.find("Tracy") # returns -1 # split: Splits the string into a list of words at whitespace my_string = "Tracy is a turtle" my_list = my_string.split() # Returns ['Tracy', 'is', 'a', 'turtle']
Tuples are immutable sequences of items.
We create a tuple by listing items inside parentheses. We can include elements of any type.
# Make a new tuple named "my_tuple" my_tuple = (1, 2, 3, 4, 5) # Tuple with elements of different types my_tuple = (0, 1, "Tracy", (1, 2)) # Tuple with single element my_tuple = (3,) # Tuple of tuples my_tuple((0, 1), (2, 3))
Due to the immutable nature of tuples, we cannot alter individual elements in the tuple but can perform various other tasks with them.
# Get the length of the tuple print(len(my_tuple)) # Accessing elements within nested tuples print(my_tuple[0][0]) print(my_tuple[1][0]) # Concatenating tuples x = (1, 2) y = (5, 6) my_tuple = x + (3,) + y
Lists are mutable sequences of items.
We create a list by listing items inside square brackets. We can include elements of any type.
# Create an empty list my_list = [] # Create a list with any number of items my_list = [item1, item2, item3] # Example: number_list = [1, 2, 4] # A list can have any type my_list = [integer, string, boolean] # Example: a_list = ["hello", 4, True]
Due to the mutable nature of lists, we can alter individual elements in the list.
# Access an element in a list using indexing a_list = ["hello", 4, True] first_element = a_list[0] # Returns "hello" # Access multiple elements in a list using slicing a_list = ["hello", 4, True] first_element = a_list[0:2] # Returns ["hello", 4] # Set an element in a list a_list = ["hello", 4, True] a_list[0] = 9 # Changes a_list to be [9, 4, True] # Looping over a list # Prints each item on a separate line (9, then 4, then True) a_list = [9, 4, True] for item in a_list: print(item) # Length of a list a_list = [9, 4, True] a_list_length = len(a_list) # Returns 3 # Creates a list based on first operation # This will create a list with numbers 0 to 4 a_list = [x for x in range(5)] # This will create a list with multiples of 2 from 0 to 8 list_of_multiples = [2*x for x in range(5)]
There are many methods that can be used to alter lists.
# append: Add to a list a_list = ["hello", 4, True] a_list.append("Puppy") # Now a_list = ["hello", 4, True, "Puppy"] # pop: Remove and return last element from the list a_list = ["hello", 4, True] last_item = a_list.pop() # Removes True, now a_list = ["hello", 4] # Remove and return an item from a list at index i a_list = ["hello", 4, True] a_list.pop(0) # Removes "hello", now a_list = [4, True] # index: Returns the index value of the first item in the list that matches element # There is an error if there is no such item a_list = ["hello", 4, True] a_list.index(4) # Returns 1 because 4 is found at index[1] a_list.index("hi") # Error because no item "hi" # sort: Sorts a given list my_list = [9, 7, 1, 2, 3] my_list.sort() # Sorts list to [1, 2, 3, 7, 9] # reverse: Reverses a given list my_list = [1, 2, 3, 4] my_list.reverse() # Reverses list to [4, 3, 2, 1] # count: Returns the number of instances of a particular item that were found my_list = [1, 4, 2, -4, 10, 0, 4, 2, 1, 4] print(my_list.count(4)) # Returns 3 print(my_list.count(123)) # Returns 0 because 123 does not exist in list # extend: Allows us to add a list to a list my_list = [1, 2, 3] my_list.extend([4, 5, 6]) # Returns [1, 2, 3, 4, 5, 6] # remove: Allows us to remove a particular item from a list # Only removes the first instance of the item my_list = ["apple", "banana", "orange", "grapefruit"] my_list.remove("orange") # Returns ["apple", "banana", "grapefruit"] # join: Creates string out of list with specified string placed between each item my_list = ["Tracy", "is", "a", "turtle"] (" ").join(my_list) # Returns the list as a string with spaces between words
2D Lists allow us to create lists of lists.
# Create an empty list my_list = [] # Add to the list my_list.append([1, 2, 3]) my_list.append([4, 5, 6]) # Access elements within the nested lists print(my_list[0]) # Returns [1, 2, 3] print(my_list[0][1]) # Returns 2 # Take a slice of the outer list print(my_list[0:2]) # Returns [[1, 2, 3], [4, 5, 6]] # Take a slice of the inner list print(my_list[0][0:2]) # Returns [1, 2]
Dictionaries have a collections of key-value pairs.
a_dictionary = {key1:value1, key2:value2} # Example: my_farm = {pigs:2, cows:4} # This dictionary keeps a farm's animal count # Creates an empty dictionary a_dictionary = {} # Inserts a key-value pair a_dictionary[key] = value my_farm["horses"] = 1 # The farm now has one horse # Gets a value for a key my_dict[key] # Will return the key my_farm["pigs"] # Will return 2, the value of "pigs" # Using the 'in' keyword my_dict = {"a": 1, "b": 2} print("a" in my_dict) # Returns True print("z" in my_dict) # Returns False print(2 in my_dict) # Returns False, because 2 is not a key # Iterating through a dictionary for key in my_dict: print("key: " + str(key)) print("value: " + str(my_dict[key]))
Classes hold multiple functions.
# Declare a class class MyClass: # The __init__ method is called whenever we instantiate our class def __init__(self): print("Class initiated") self.my_num = 0 # Instantiate your class my_class = MyClass() # Access instance variables in your class print(my_class.my_num) my_class.my_num = 10 # Adding arguments to your class class Point: def __init__(self, x = 0, y = 0): self.x = x self.y = y # Instantiate the class p = Point(3, 4)
A set contains an unordered collection of unique and immutable objects.
# Make a new set named "new_set" new_set = set([]) girl_scout_badges = set([]) # Add to a set new_set.add(item) girl_scout_badges.add("Squirrel Whisperer") # Does a set contain a value item in my_set # Returns a boolean "Squirrel Whisperer" in girl_scout_badges # Returns True # Number of elements in the set len(my_set) len(girl_scout_badges) # Returns 1 since there is only one item in the set
We can print elements to the screen by using the print command. If we want to print text, we need to surround the text with quotation marks " ". Unlike previous versions of Python, Python3 requires parentheses for printing.
print("Hello world") print(2 + 2) print(10)
name = "Tracy" age = 13 print("My name is " + name + " and I am " + str(age) + " years old!")
print("My name is %s and I am %d years old!" % ('Zara', 21))
We can use input from the user to control our code.
# Ask the user for input and save it to a variable to be used in code # This will only work if the input is being used as a string name = input("What is your name? ") # If input needs to be used as a number (i.e for a mathematical # calculation), include the term 'int' or 'float' num_one = int(input("Enter a number: ")) num_two = int(input("Enter a second number: ")) num_three = float(input("Enter a third number: ")) # This input can then be used to control different parts of the code print("Hello, " + name) sum_nums = num_one + num_two
Use the following when importing files.
# Extracting Data from a File: # Example File: # test.txt # ------------------ # # Hello World # This is File Input # # ------------------ # Opening the file, Create a File object and store it in a Variable: file = open('test.txt') # Getting all text: file.read() # Returns: # Hello World # This is File Input # Getting a Line of Text: file.readline() # Returns: # Hello World # Getting lines in a file: for line in file: print(line + '!') # prints: # Hello World\n! # This is File Input\n! # Note '\n', signifying the end of a line of text for line in file: print(line + '!') # prints: # Hello World # ! # This is File Input # ! # To remove this extra newline, we can use: for line in file: print(line.strip() + '!') # prints: # Hello World! # This is File input! # Closing a File file.close()