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Zoo Tycoon SOLVED

Zoo Tycoon
Goals
• Develop multiple classes from program requirements
• Implement inheritance
For this project, we will write a zoo tycoon game using classes and inheritance.
Zoo tycoon is a game that allows players to run a zoo business. Different types
of animals cost different prices, have different maintenance costs, and of
course, return a different profit at the end of each day. For this game, the player
will be the proud owner of a virtual zoo that has spaces to house tigers,
penguins and turtles.
Requirements
Animal Class
The Animal class has the following member variables:
• Age
o Adult if age = 3 days
o Baby if age < 3 days
• Cost
o Tiger cost $10,000
o Penguin cost $1,000
o Turtle cost $100
• Number of Babies
o Tigers have 1 baby
o Penguins have 5 babies
o Turtles have 10 babies
• Base Food Cost
o You can get this base food cost from the user or set it as a constant.
Example base food cost per animal per day: $10.
o Tigers have a feeding cost of 5 times the base cost
o Penguins have a feeding cost that is the same as the base cost
o Turtles have a feeding cost that is 50% the base cost
• Payoff
o A tiger’s payoff per day is 20% of their cost per animal. (not counting
bonus)
o A penguin’s payoff per day is 10% of their cost per animal
o A turtle’s payoff per day is 5% of their cost per animal
Note: please do not modify the variables names or add more member variables
to this class.
Game Flow:
The player begins with a specific amount of money in the bank, e.g. 100,000
dollars. At the start, the user needs to buy three types of animals (tigers,
penguins, turtles) to start the business. Each type should have a quantity
of either 1 or 2. For each animal bought, the cost is subtracted from the
bank. All newly bought animals are 1 day old.
Each turn is a “day”. At the beginning of the day, all animals increase age by 1
day, and the user needs to pay the feeding cost of each animal. Feeding is
required so the animals don’t die. After the feeding cost is subtracted from the
bank, one randomized event takes place during the day. You can determine
how to implement the random functions by yourself. The random function will
pick one random event from the following list:
Random Events:
1. A sickness occurs to an animal in the zoo:
1. Pick an animal at random that will die
2. Remove one animal of that type from the exhibit. (dynamic array in the
zoo)
2. A boom in zoo attendance occurs:
1. Generate a random bonus for the day, 250-500 dollars for each tiger in
the zoo
2. Add the bonus payoff for each tiger to the total payoff of the day as a
reward
3. A baby animal is born:
1. Pick an animal at random to have a baby
2. Check if there is an animal old enough to be a parent (age = 3), add
babies to the zoo depending on the “number of babies” specific to the
type of animal. If no animal is old enough of the randomly selected type,
pick another type of animal. Baby animals start at age 0. For simplicity,
you don’t need to consider the gender of the adult animals in order to
have babies. One adult animal is good enough to have babies.
Note: If no animals are able to give birth to baby animals in the zoo, your
program needs to be able to recognize this and recover.
4. Nothing happens
After the random event, calculate the profit for the day based on the number of
each animals and their payoff. If there is a bonus for the day, add it to the profit
as well. Before the day ends, ask the player if they would like to buy
an adult animal. If they do, ask for the type of animal they would like, then add
the animal to the zoo and subtract that cost from the bank. The adult animal that
is bought will be 3 days old.
After the end of a day (the end of the game play loop), prompt user whether to
keep playing or end the game. If the user has no money, print a message to tell
the user the game is over, and end the game.
Class requirements
The following classes are required: zoo, animal, tiger, penguin, and turtle. The
program also must use inheritance; the tiger, penguin, and turtle class must
inherit from animal class.
Also, the zoo class should have a dynamic array for each type of animal. Each
dynamic array should have a capacity of 10 animals to start with. If more
animals are added, you should resize the dynamic array by doubling the
starting capacity to hold more animals.
Input Validation
The requirements of input validation have been specified in the Project 1, Lab 3
documents. Reminder: Make sure to check for incorrect data types entered by
the user and continue to re-prompt for input until valid input is received.
Reflection Document
The requirements for the reflection document have been specified in the Project
1 document.
Make sure your document has design descriptions, test tables, and
reflections. The reflections include: changes in design, problems encountered,
and how you solve those problems.
Extra Credit
New Animal: (5pts)
Add a new class for your new animal. It should also inherit from the Animal
class. This should also allow the user to dynamically create a new animal during
runtime, re-prompting them for each trait.
Status messages: (5pts)
• Put a message into a text file for each random event. For example, during a
boom in zoo attendance, print:
“Today is National Tiger Day! Tigers generate money today! You made: 360
extra dollars for each tiger you own!”
• Use ifstream to read messages from the created text file.
Different Feed Types: (5pts)
Allow user to pick between 3 different types of feed at the start of each day.
Cheap: Half as expensive for all animals, sickness becomes twice as likely to
occur.
Generic: behaves normally.
Premium: Twice as expensive for all animals, sickness becomes half as likely to
occur.
What you need to Submit
• All the program files including header and source files (.cpp/.hpp)
• Makefile
• Textfile (If you did extra credit)
• Your reflection pdf file
Important: Put all the files in a single .zip file and submit it on Canvas. There
should be no internal directories.
Grading
• Programming style and documentation - 10%
• Create the Animal class and object - 10%
• Create the Penguin, Turtle, and Tiger class objects – 15%
• Implement the game:
o Implement the program to manage the feed cost and payoff at the end of
each day - 10%
o Implement the random events - 10%
o Implement the game loop for each “day” - 20%
o Resize the dynamic array correctly when the number of items exceeds
the list capacity - 10%
• Implement input validation functions - 5%
• Reflection document including: design description, test table (test plans, test
results), and the reflection: - 10%
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