Lab 5: Inheritance
You are welcome to collaborate with one or two classmates on this lab, though it is expected that every student in any such group contribute equally to the lab.
Simulate the inheritance of blood types for each member of a family.
$ ./inheritance
Child (Generation 0): blood type OO
Parent (Generation 1): blood type AO
Grandparent (Generation 2): blood type OA
Grandparent (Generation 2): blood type BO
Parent (Generation 1): blood type OB
Grandparent (Generation 2): blood type AO
Grandparent (Generation 2): blood type BO
Background
A person’s blood type is determined by two alleles (i.e., different forms of a gene). The three possible alleles are A, B, and O, of which each person has two (possibly the same, possibly different). Each of a child’s parents randomly passes one of their two blood type alleles to their child. The possible blood type combinations, then, are: OO, OA, OB, AO, AA, AB, BO, BA, and BB.
For example, if one parent has blood type AO and the other parent has blood type BB, then the child’s possible blood types would be AB and OB, depending on which allele is received from each parent. Similarly, if one parent has blood type AO and the other OB, then the child’s possible blood types would be AO, OB, AB, and OO.
Getting Started
Open VS Code.
Start by clicking inside your terminal window, then execute cd
by itself. You should find that its “prompt” resembles the below.
$
Click inside of that terminal window and then execute
wget https://cdn.cs50.net/2022/fall/labs/5/inheritance.zip
followed by Enter in order to download a ZIP called inheritance.zip
in your codespace. Take care not to overlook the space between wget
and the following URL, or any other character for that matter!
Now execute
unzip inheritance.zip
to create a folder called inheritance
. You no longer need the ZIP file, so you can execute
rm inheritance.zip
and respond with “y” followed by Enter at the prompt to remove the ZIP file you downloaded.
Now type
cd inheritance
followed by Enter to move yourself into (i.e., open) that directory. Your prompt should now resemble the below.
inheritance/ $
If all was successful, you should execute
ls
and you should see inheritance.c
.
If you run into any trouble, follow these same steps again and see if you can determine where you went wrong!
Understanding
Take a look at the distribution code in inheritance.c
.
Notice the definition of a type called person
. Each person has an array of two parents
, each of which is a pointer to another person
struct. Each person also has an array of two alleles
, each of which is a char
(either 'A'
, 'B'
, or 'O'
).
Now, take a look at the main
function. The function begins by “seeding” (i.e., providing some initial input to) a random number generator, which we’ll use later to generate random alleles. The main
function then calls the create_family
function to simulate the creation of person
structs for a family of 3 generations (i.e. a person, their parents, and their grandparents). We then call print_family
to print out each of those family members and their blood types. Finally, the function calls free_family
to free
any memory that was previously allocated with malloc
.
The create_family
and free_family
functions are left to you to write!
Implementation Details
Complete the implementation of inheritance.c
, such that it creates a family of a specified generation size and assigns blood type alleles to each family member. The oldest generation will have alleles assigned randomly to them.
- The
create_family
function takes an integer (generations
) as input and should allocate (as viamalloc
) oneperson
for each member of the family of that number of generations, returning a pointer to theperson
in the youngest generation.- For example,
create_family(3)
should return a pointer to a person with two parents, where each parent also has two parents. - Each
person
should havealleles
assigned to them. The oldest generation should have alleles randomly chosen (as by calling therandom_allele
function), and younger generations should inherit one allele (chosen at random) from each parent. - Each
person
should haveparents
assigned to them. The oldest generation should have bothparents
set toNULL
, and younger generations should haveparents
be an array of two pointers, each pointing to a different parent.
- For example,
We’ve divided the create_family
function into a few TODO
s for you to complete.
- First, you should allocate memory for a new person. Recall that you can use
malloc
to allocate memory, andsizeof(person)
to get the number of bytes to allocate. - Next, we’ve included a condition to check if
generations > 1
.- If
generations > 1
, then there are more generations that still need to be allocated. We’ve already created two newparents
,parent0
andparent1
, by recursively callingcreate_family
. Yourcreate_family
function should then set the parent pointers of the new person you created. Finally, assign bothalleles
for the new person by randomly choosing one allele from each parent. - Otherwise (if
generations == 1
), then there will be no parent data for this person. Bothparents
of your new person should be set toNULL
, and eachallele
should be generated randomly.
- If
- Finally, your function should return a pointer for the
person
that was allocated.
The free_family
function should accept as input a pointer to a person
, free memory for that person, and then recursively free memory for all of their ancestors.
- Since this is a recursive function, you should first handle the base case. If the input to the function is
NULL
, then there’s nothing to free, so your function can return immediately. - Otherwise, you should recursively
free
both of the person’s parents beforefree
ing the child.
Walkthrough
This video was recorded when the course was still using CS50 IDE for writing code. Though the interface may look different from your codespace, the behavior of the two environments should be largely similar!
Hints
- You might find the
rand()
function useful for randomly assigning alleles. This function returns an integer between0
andRAND_MAX
, or2147483647
.- In particular, to generate a pseudorandom number that is either
0
or1
, you can use the expressionrand() % 2
.
- In particular, to generate a pseudorandom number that is either
- Remember, to allocate memory for a particular person, we can use
malloc(n)
, which takes a size as argument and will allocaten
bytes of memory. - Remember, to access a variable via a pointer, we can use arrow notation.
- For example, if
p
is a pointer to a person, then a pointer to this person’s first parent can be accessed byp->parents[0]
.
- For example, if
Not sure how to solve?
How to Test Your Code
Upon running ./inheritance
, your program should adhere to the rules described in the background. The child should have two alleles, one from each parent. The parents should each have two alleles, one from each of their parents.
For example, in the example below, the child in Generation 0 received an O allele from both Generation 1 parents. The first parent received an A from the first grandparent and a O from the second grandparent. Similarly, the second parent received an O and a B from their grandparents.
$ ./inheritance
Child (Generation 0): blood type OO
Parent (Generation 1): blood type AO
Grandparent (Generation 2): blood type OA
Grandparent (Generation 2): blood type BO
Parent (Generation 1): blood type OB
Grandparent (Generation 2): blood type AO
Grandparent (Generation 2): blood type BO
Execute the below to evaluate the correctness of your code using check50
. But be sure to compile and test it yourself as well!
check50 cs50/labs/2023/x/inheritance
Execute the below to evaluate the style of your code using style50
.
style50 inheritance.c
How to Submit
In your terminal, execute the below to submit your work.
submit50 cs50/labs/2023/x/inheritance