Assignment 5: Implementation of hash map, concordance and spell checker
There are three parts to this assignment. In the first two parts, you will complete the implementation of
a hash map and a concordance program. In the third part, you will implement a spell checker .
Reading chapter 12, watching this week’s lecture on hash tables with chaining, and completing
worksheet 38 will better prepare you to tackle this assignment. It may also be helpful to review C file I/
O with fopen() and fclose().
Part 1: Hash map
First complete the hash map implementation in hashMap.c. This hash map uses a table of buckets,
each containing a linked list of hash links. Each hash link stores the key-value pair (string and integer
in this case) and a pointer to the next link in the list. See hashMap.h and the accompanied drawing
posted with this assignment for clarification. You must implement each function in hashMap.c with the //
FIXME: implement comment.
At the top of hashMap.h you should see two macros: HASH_FUNCTION and MAX_TABLE_LOAD. You
are free to change their definitions but know that the default values will be used when grading.
HASH_FUNCTION is the name of the hash function you want to use. Make sure everywhere in your
implementation to use HASH_FUNCTION(key) instead of directly calling a hash function.
MAX_TABLE_LOAD is the table load threshold on which you should resize the table.
A number of tests for the hash map are included in tests.c. Each one of these test cases use several
or all of the hash map functions, so don’t expect tests to pass until you implement all of them. Each
test case is slightly more thorough than the one before it and there is a lot of redundancy to better
ensure correctness. Use these tests to help you debug your hash map implementation. They will also
help your TA grade your submission. You can build the tests with make tests or make and run them
Part 2: Concordance
The concordance counts how many times each word (case-insensitive) occurs in a document. You will
implement a concor-dance using the hash map implementation from the previous part. Each hash link
in the table will store a word from the document as the key and the number of times the word
appeared as the value. You must finish the concordance implementation in main.c.
You are provided with a function nextWord() which takes a FILE*, allocates memory for the next word in
the file, and returns the word. If the end of the file is reached, nextWord() will return NULL. It is your job to
open the file using fopen(), populate the concordance with the words, and close the file with fclose().
The file name to open should be given as a command line argument when running the program. It will
default to input1.txt if no file name is provided.
Your concordance code should loop over the words until the end of the file is reached, doing
the following steps each iteration:
1. Get the next word with getWord.
2. If the word is already in the hash map, then increment its number of occurrences.
3. Otherwise, put the word in the hash map with a count of 1.
4. Free the word.
After processing the text file, print all the words and occurrence counts in the hash map. Please print
them in the format of the following example.
For the input file of: It was the best of times, it was the worst of times.
Bucket 0 – (best, 1) –
Bucket 1 – (the, 2) – (was, 2) – (it, 2) –
Bucket 3 – (of, 2) –
Bucket 5 – (worst, 1) –
Bucket 6 – (times, 2) –
You can build the program with make prog or make and run it with ./prog <filename, where
<filename is the name of a text file like input1.txt.
Part 3: Spell Checker
There are a lot of uses for a hash map, and one of them is implementing a case-insensitive spell checker.
All you need to get started is a dictionary, which is provided in dictionary.txt. In spellChecker.c you will
find some code to get you started with the spell checker. It is fairly similar to the code in main.c.
You can build the program with make spellChecker. FYI:
The spellchecker program flow should as following –
1. The user types in a word (only one word at a time should be allowed)
2. If the spelling is correct, the following message should be outputted –
” The inputted word …. is spelled correctly
If the spelling is incorrect, the following message should be outputted –
” The inputted word …. is spelled incorrectly. Also, 5 potential matches should be outputted like “Did you
4. Continue to prompt user for word until they type quit
One way to implement a dictionary that’s used for a spellchecker would probably be to design it with that purpose in
mind from the beginning, i.e. associating a similarity for each word to some base word (maybe
“abcdefghijklmnopqrstuvwyz”) and then incorporating that into the hash function. But there are better ways (https://
en.wikipedia.org/wiki/Levenshtein_distance) to establish similarity than computing the cosine of the angle between two
vectors (strings) to create a list of candidates and further winnowed that list according to substring comparisons. So, I
would say calculating the Levenshtein distance between the misspelled word and all strings in the dictionary, create 5
best candidates and print them as suggestion.
Below is one exapmple of the steps that you can follow to implement your spellchecker –
Step 1: Compare input buffer to words in the dictionary, computing their Levenshtein distance.
Store that distance as the value for each key in the table.
Step 2: Traverse down the hash table, checking each bucket. Jump out if you find an exact
matching dictionary word. and print a message that “word spelled correctly”.
Step 3: f the input Buffer did not match any of the dictionary words exactly, generate an array of 5
words that are closest matches to input Buffer based on the lowest Levenshtein distance. Print the
array including the messages “word spelled incorrectly”, ” Did you mean …. ? “.
• Hash map implementation – 40
• Concordance implementation – 20
• Spell checker implementation – 40
Submit the following files to TEACH and Canvas. Do not zip the TEACH submission. Please remember
that your code must compile and execute on flip.engr.oregonstate.edu.
Step 4: Continue to prompt user for word until they type quit.