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0x1B. C - Sorting algorithms & Big O Readme.md file

Big-O Complexity


C

Algorithm

Data structure


By: Alexandre Gautier

Project will start Feb 15, 2023 5:00 AM, must end by Feb 22, 2023 5:00 AM

Resources 📚

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General Learning Objectives 💡

  • At least four different sorting algorithms
  • What is the Big O notation, and how to evaluate the time complexity of an algorithm
  • How to select the best sorting algorithm for a given input
  • What is a stable sorting algorithm

Mandatory Tasks

☑️ 0. Bubble sort

Write a function that sorts an array of integers in ascending order using the Bubble sort algorithm

  • Prototype: void bubble_sort(int *array, size_t size);
  • You’re expected to print the array after each time you swap two elements

Write in the file 0-O, the big O notations of the time complexity of the Bubble sort algorithm, with 1 notation per line:

  • in the best case
  • in the average case
  • in the worst case

File(s): 0-bubble_sort.c, 0-O
Compiled: gcc -Wall -Wextra -Werror -pedantic 0-bubble_sort.c 0-main.c print_array.c -o bubble

☑️ 1. Insertion sort

Write a function that sorts a doubly linked list of integers in ascending order using the Insertion sort algorithm

  • Prototype: void insertion_sort_list(listint_t **list);
  • You are not allowed to modify the integer n of a node. You have to swap the nodes themselves.
  • You’re expected to print the list after each time you swap two elements

Write in the file 1-O, the big O notations of the time complexity of the Insertion sort algorithm, with 1 notation per line:

  • in the best case
  • in the average case
  • in the worst case

File(s): 1-insertion_sort_list.c, 1-O
Compiled: gcc -Wall -Wextra -Werror -pedantic 1-main.c 1-insertion_sort_list.c print_list.c -o insertion

☑️ 2. Selection sort

Write a function that sorts an array of integers in ascending order using the Selection sort algorithm

  • Prototype: void selection_sort(int *array, size_t size);
  • You’re expected to print the array after each time you swap two elements

Write in the file 2-O, the big O notations of the time complexity of the Selection sort algorithm, with 1 notation per line:

  • in the best case
  • in the average case
  • in the worst case

File(s): 2-selection_sort.c 2-O
Compiled: gcc -Wall -Wextra -Werror -pedantic 2-main.c 2-selection_sort.c print_array.c -o select

☑️ 3. Quick sort

Write a function that sorts an array of integers in ascending order using the Quick sort algorithm

  • Prototype: void quick_sort(int *array, size_t size);
  • You must implement the Lomuto partition scheme.
  • The pivot should always be the last element of the partition being sorted.
  • You’re expected to print the array after each time you swap two elements

Write in the file 3-O, the big O notations of the time complexity of the Quick sort algorithm, with 1 notation per line:

  • in the best case
  • in the average case
  • in the worst case

File(s): 3-quick_sort.c 3-O
Compiled: gcc -Wall -Wextra -Werror -pedantic 3-main.c 3-quick_sort.c print_array.c -o quick

Advanced Tasks

☑️ 4. Shell sort - Knuth Sequence

Write a function that sorts an array of integers in ascending order using the Shell sort algorithm, using the Knuth sequence

  • Prototype: void shell_sort(int *array, size_t size);
  • You must use the following sequence of intervals (a.k.a the Knuth sequence): n + 1 = n * 3 + 1 1, 4, 13, 40, 121, ...
  • You’re expected to print the array each time you decrease the interval

No big O notations of the time complexity of the Shell sort (Knuth sequence) algorithm needed - as the complexity is dependent on the size of array and gap

File(s): 100-shell_sort.c
Compiled: gcc -Wall -Wextra -Werror -pedantic 100-main.c 100-shell_sort.c print_array.c -o shell

☑️ 5. Cocktail shaker sort

Write a function that sorts a doubly linked list of integers in ascending order using the Cocktail shaker sort algorithm

  • Prototype: void cocktail_sort_list(listint_t **list);
  • You are not allowed to modify the integer n of a node. You have to swap the nodes themselves.
  • You’re expected to print the list after each time you swap two elements

Write in the file 101-O, the big O notations of the time complexity of the Cocktail shaker sort algorithm, with 1 notation per line:

  • in the best case
  • in the average case
  • in the worst case

File(s): 101-cocktail_sort_list.c 101-O
Compiled: gcc -Wall -Wextra -Werror -pedantic 101-main.c 101-cocktail_sort_list.c print_list.c -o cocktail

☑️ 6. Counting sort

Write a function that sorts an array of integers in ascending order using the Counting sort algorithm

  • Prototype: void counting_sort(int *array, size_t size);
  • You can assume that array will contain only numbers >= 0
  • You are allowed to use malloc and free for this task
  • You're expected to print your counting array once it is set up
  • This array is of size k + 1 where k is the largest number in array

Write in the file 102-O, the big O notations of the time complexity of the Counting sort algorithm, with 1 notation per line:

  • in the best case
  • in the average case
  • in the worst case

File(s): 102-counting_sort.c 102-O
Compiled: gcc -Wall -Wextra -Werror -pedantic 102-main.c 102-counting_sort.c print_array.c -o counting

☑️ 7. Merge sort

Write a function that sorts an array of integers in ascending order using the Merge sort algorithm

  • Prototype: void merge_sort(int *array, size_t size);
  • You must implement the top-down merge sort algorithm
    • When you divide an array into two sub-arrays, the size of the left array should always be <= the size of the right array. i.e. {1, 2, 3, 4, 5} -> {1, 2}, {3, 4, 5}
    • Sort the left array before the right array
  • You are allowed to use printf
  • You are allowed to use malloc and free only once (only one call)

Write in the file 103-O, the big O notations of the time complexity of the Merge sort algorithm, with 1 notation per line:

  • in the best case
  • in the average case
  • in the worst case

File(s): 103-merge_sort.c 103-O
Compiled: gcc -Wall -Wextra -Werror -pedantic 103-main.c 103-merge_sort.c print_array.c -o merge

☑️ 8. Heap sort

Write a function that sorts an array of integers in ascending order using the Heap sort algorithm

  • Prototype: void heap_sort(int *array, size_t size);
  • You must implement the sift-down heap sort algorithm
  • You’re expected to print the array after each time you swap two elements

Write in the file 104-O, the big O notations of the time complexity of the Heap sort algorithm, with 1 notation per line:

  • in the best case
  • in the average case
  • in the worst case

File(s): 104-heap_sort.c 104-O
Compiled: gcc -Wall -Wextra -Werror -pedantic 104-main.c 104-heap_sort.c print_array.c -o heap

☑️ 9. Radix sort

Write a function that sorts an array of integers in ascending order using the Radix sort algorithm

  • Prototype: void radix_sort(int *array, size_t size);
  • You must implement the LSD radix sort algorithm
  • You can assume that array will contain only numbers >= 0
  • You are allowed to use malloc and free for this task
  • You’re expected to print the array each time you increase your significant digit

File(s): 105-radix_sort.c
Compiled: gcc -Wall -Wextra -Werror -pedantic 105-main.c 105-radix_sort.c print_array.c -o radix

☑️ 10. Bitonic sort

Write a function that sorts an array of integers in ascending order using the Bitonic sort algorithm

  • Prototype: void bitonic_sort(int *array, size_t size);
  • You can assume that size will be equal to2^k, where k >= 0 (when array is not NULL …)
  • You are allowed to use printf
  • You’re expected to print the array each time you swap two elements

Write in the file 106-O, the big O notations of the time complexity of the Bitonic sort algorithm, with 1 notation per line:

  • in the best case
  • in the average case
  • in the worst case

File(s): 106-bitonic_sort.c 106-O
Compiled: gcc -Wall -Wextra -Werror -pedantic 106-main.c 106-bitonic_sort.c print_array.c -o bitonic

☑️ 11. Quick Sort - Hoare Partition scheme

Write a function that sorts an array of integers in ascending order using the Quick sort algorithm

  • Prototype: void quick_sort_hoare(int *array, size_t size);
  • You must implement the Hoare partition scheme.
  • The pivot should always be the last element of the partition being sorted.
  • You’re expected to print the array after each time you swap two elements

Write in the file 107-O, the big O notations of the time complexity of the Quick sort algorithm, with 1 notation per line:

  • in the best case
  • in the average case
  • in the worst case

File(s): 107-quick_sort_hoare.c 107-O
Compiled: gcc -Wall -Wextra -Werror -pedantic 107-main.c 107-quick_sort_hoare.c print_array.c -o quick

☑️ 12. Dealer

Write a function that sorts a deck of cards.

  • Prototype: void sort_deck(deck_node_t **deck);
  • You are allowed to use the C standard library function qsort
  • You have to push your deck.h header file
  • Each node of the doubly linked list contains a card that you cannot modify. You have to swap the nodes.
  • You can assume there is exactly 52 elements in the doubly linked list.
    • You are free to use the sorting algorithm of your choice
    • The deck must be ordered:

From Ace to King From Spades to Diamonds

File(s): 1000-sort_deck.c deck.h
Compiled: gcc -Wall -Wextra -Werror -pedantic 1000-main.c 1000-sort_deck.c -o deck

Author:

Ilori Muideen Adeleye

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