What is a procedure?
A procedure is a named group of programming instructions with a purpose and is called to perform a task based on the commands.
It is extremely important to name the procedure something that describes the purpose, method, or function because it makes it easier for others to read your code and for yourself when you revisit old code. Additionally, when there is an effefctively named procedure, it is much simpler to correct bugs and errors.
Which code is better?
Hack 1: Naming Procedures
Rename the procedure below with a name that better describes the purpose of the procedure.
The procedure is currently just called “procedure.” It compares the current grade with the existing quiz grade and replaces the original score if the current is higher.
def procedure(quiz_grade, current_points, total_points):
# calculate current grade
current_grade = (current_points / total_points) * 100
if current_grade > quiz_grade:
quiz_grade = current_grade
return quiz_grade
quiz_grade = 85 # Initial quiz grade
current_points = 90 # Current points earned
total_points = 100 # Total points for the quiz
new_quiz_grade = procedure(quiz_grade, current_points, total_points)
print(f"Old quiz grade: {quiz_grade}")
print(f"New quiz grade: {new_quiz_grade}")
Old quiz grade: 85
New quiz grade: 90.0
Function Parameters
A function can have one or more parameters that can be passed into the function as local variables to use in the procedural function. The variables that can be passed in the function are called parameters. The data passed in when the function is called are called arguments.
Parameters: input values of a procedure
Arguments: specify the parameter values when a procedure is called
def triangle_area(length, width): # parameters passed in two variables: length and width, returns area
area = 1/2 * length * width # calculates area from the length and width
print("length:", length)
print("width:", width)
return area # returns area
# examples
print(triangle_area(3, 4)) # the arguments here are 3 and 4, which becomes the parameters length and width respectively
print(triangle_area(6, 8))
print(triangle_area(12, 89))
length: 3
width: 4
6.0
length: 6
width: 8
24.0
length: 12
width: 89
534.0
Procedure Algorithm / How Procedures Work
Remember that procedures are essentially a set of programming instructions, or lines of code, that accomplish a goal. When executed, each line of code is executed in order (step after step after step) to get to the goal.
Regular code/Python
# Procedure called "applyTax" that applies a percent tax to a price
def applyTax(price, percentTax): # When writing a procedure, first decide what parameters you will need to accomplish your goal
# Step 1: Calculate the amount taxed
taxAmount = price * percentTax/100
# Step 2: Add the amount taxed to the price to get the end amount
endAmount = price + taxAmount
return endAmount
# Use procedure to apply a 50% tax to a price of $10
cost = applyTax(10, 50)
print(cost)
CollegeBoard Pseudo-Code
- Note that the pseudo-code below has the exact same purpose as the actual code above. Ignore the breaks and spaces since they are used for formatting.
Differences between prseudo-code and Python:
- Pseudo-code uses “PROCEDURE” instead of “def”
- Pseudo-code uses “<–” instead of “=”
- Pseudo-code uses “{}” instead of “:” to mark where a procedure starts and ends
Pseudo-code example
PROCEDURE applyTax (price, percentTax)
{
taxAmount <– price * percentTax/100
endAmount <– price + taxAmount
return endAmount
}
Hack 2: Robot Pseudo-Code
Instructions:
- The blue triangle represents a robot that moves in a grid of squares. The tip of the triangle indicates where the robot is facing.
- Write a procedure that allows the robot to make a detour around a block by moving to the left.
Commands
- MOVE_FORWARD() - Moves the robot forward one square
- MOVE_BACKWARD() - Moves the robot backward one square
- ROTATE_LEFT() - Rotates the robot 90 degrees left
- ROTATE_RIGHT() - Rotates the robot 90 degrees right
Your code here: ROTATE_LEFT() MOVE_FORWARD() ROTATE_RIGHT() MOVE_FORWARD() MOVE_FORWARD() ROTATE_RIGHT() MOVE_FORWARD()
Procedure Return Values
When a procedure is run, it executes a series of calculations or commands and at some point and needs to provide a useful result. The return statement is what allows us to return a useful value back to the calling code. The returns statement can return various types of values such as booleans, integers, strings, etc.
Procedure Calls
Calling: This involves specifying the function name followed by parentheses, and passing any required arguments inside the parentheses.
When a function is called, the program control jumps to the function definition, and the statements inside the function are executed. After the function completes its task, the control returns to the point where the function was called.
Hack 3: Create and Call a Procedure
Define a function named calculate_grade that takes a student’s score as a parameter and returns ‘Pass’ if the score is 50 or more, and ‘Fail’ otherwise.
# your code here
def calculate_grade(grade):
if grade>50:
passFail = True
else:
passFail = False
return passFail
print(calculate_grade(69))
True
Homework
Instructions
There are two total problems:
- An easy regular code (Python) problem
- A medium pseudo-code problem
- A hard regular code (Python) problem
Completing question 1 and 2 gets you 0.9/1 if you do it correctly. Completing/attempting question 3, adding creativity, and adding good comments will potentially raise you above 0.9.
Question 1
Write a procedure to apply a percent discount to a set price. See the example about applying tax if you’re stuck.
# your code here
# Procedure called "applyDiscount" that applies a percent discount to a price
def applyDiscount(price, discount_percent):
"""
Apply a percent discount to a given price.
Parameters:
price (float): The original price before discount.
discount_percent (float): The percentage of discount to be applied.
Returns:
float: The discounted price.
"""
# Step 1: Calculate the discount amount
discount_amount = price * discount_percent / 100
# Step 2: Subtract the discount amount from the original price to get the discounted price
discounted_price = price - discount_amount
# Step 3: Return the discounted price
return discounted_price
# Use the procedure to apply a 20% discount to a price of $50
original_price = 50 # Replace this with the actual price
discount_percent = 20 # Replace this with the desired discount percentage
# Call the applyDiscount procedure with the original price and discount percentage
discounted_price = applyDiscount(original_price, discount_percent)
# Print the discounted price
print(discounted_price)
40.0
Question 2
Create your own robot problem! Include a picture with a square grid to represent the map and triangle to represent the robot. Add a flag to a square to represent the end-point and a shaded-in block to represent a detour. Write a procedure in pseudo-code to move the robot from the start, past the detour, and to the end point.
Add your image here by adding the link between the “” and removing the comment formatting:
your code here
ROTATE_LEFT() MOVE_FORWARD() ROTATE_RIGHT() MOVE_FORWARD() MOVE_FORWARD() ROTATE_RIGHT() MOVE_FORWARD() MOVE_FORWARD() MOVE_FORWARD() ROTATE_RIGHT() MOVE_FORWARD()
Question 3
Create a program that asks for user input of an integer n, and return an array that contains all the prime numbers up to the number n (inclusive). Remember to use multiple different functions to better organize the code and increase efficiency.
# Function to check if a number is prime
def is_prime(num):
if num <= 1:
return False
for i in range(2, int(num**0.5) + 1):
if num % i == 0:
return False
return True
# Function to generate a list of prime numbers up to n
def generate_primes(n):
primes = [] # List to store prime numbers
for num in range(2, n + 1):
if is_prime(num):
primes.append(num)
return primes
# Main function to take user input and generate prime numbers
def main():
# Ask user for input
try:
n = int(input("Enter an integer n: "))
if n < 2:
print("Please enter an integer greater than or equal to 2.")
else:
# Call the generate_primes function
prime_numbers = generate_primes(n)
# Print the list of prime numbers
print(f"Prime numbers up to {n}: {prime_numbers}")
except ValueError:
print("Invalid input. Please enter a valid integer.")
# Additional function to match the provided function name "primes"
def primes(n):
return generate_primes(n)
# Call the main function to execute the program
if __name__ == "__main__":
main()
# Tests
print(primes(5))
print(primes(12))
print(primes(35))
Prime numbers up to 15: [2, 3, 5, 7, 11, 13]
[2, 3, 5]
[2, 3, 5, 7, 11]
[2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31]