Difference between revisions of "CISC220 F2021 Lab9"

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(Lab #9)
(Lab #9)
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* '''[1 point]''' ''calculate_huffman_file_size()''
 
* '''[1 point]''' ''calculate_huffman_file_size()''
  
===2. Testing===
+
===2. Testing [1.5 points] ===
  
* '''[1 point]''' * [http://nameless.cis.udel.edu/class_data/220_f2014/data/cleaned_doi.txt DOI] (about 1K total words), [http://nameless.cis.udel.edu/class_data/220_f2014/data/cleaned_bts.txt BTS] (~14K words), and [http://nameless.cis.udel.edu/class_data/220_f2014/data/cleaned_greatexp.txt GE] (~185K words) require 68704 bits, 671712 bits, and 8110088 bits, respectively (according to the Unix ls command)
+
* [http://nameless.cis.udel.edu/class_data/220_f2014/data/cleaned_doi.txt DOI] (about 1K total words), [http://nameless.cis.udel.edu/class_data/220_f2014/data/cleaned_bts.txt BTS] (~14K words), and [http://nameless.cis.udel.edu/class_data/220_f2014/data/cleaned_greatexp.txt GE] (~185K words) require 68704 bits, 671712 bits, and 8110088 bits, respectively (according to the Unix ls command)
 
* How many bits are required for each of these files after compression when you set the ''-debug'' flag in (a) "custom" form (shortest fixed-length code) and (b) using the variable-length Huffman code that your completed class generates?
 
* How many bits are required for each of these files after compression when you set the ''-debug'' flag in (a) "custom" form (shortest fixed-length code) and (b) using the variable-length Huffman code that your completed class generates?
  

Revision as of 17:11, 10 November 2021

Lab #9

1. File compression with Huffman coding

As discussed in class on Nov. 9, tries and Huffman coding can be used to compress files/messages by analyzing character frequencies and choosing codes accordingly.

Most of a Huffman class is provided in starter code here. It implements a TrieNode class that stores parent and child links as well as the character being encoded and its frequency in the file being compressed.

The main work of Huffman happens in the following functions:

  • compress(in_filename, out_filename, do_binary)
    • Reads in_filename character by character and counts occurrences (aka computes frequency) for each, storing the result by ASCII index in the char_counter vector
    • Applies the Huffman trie-building algorithm presented in class 11/9 in build_optimal_trie(). This function is UNFINISHED, as it calls merge_two_least_frequent_subtries() which you must write
    • Writes code table (the decompression_map) to out_filename
    • Re-reads in_filename character by character and writes encoded versions to out_filename (in ASCII or binary depending on do_binary)
  • decompress(in_filename, out_filename, do_binary)
    • Reads the code table from in_filename
    • Reads in_filename character by character and writes decoded versions to out_filename

The "forest of tries" discussed in lecture on 11/9 is implemented with a priority queue of TrieNode pointers (each representing the root of a subtrie), ordered on the combined frequency of each subtrie.

Several major functions are unfinished. In order to separate them from the finished ones, they are located in main.cpp -- this is where you will be writing code.

The Huffman member functions to finish in main.cpp:

  • [1 point] merge_two_least_frequent_subtries()
  • [1 point] compute_all_codes_from_trie(TrieNode *T)
  • [1 point] calculate_huffman_file_size()

2. Testing [1.5 points]

  • DOI (about 1K total words), BTS (~14K words), and GE (~185K words) require 68704 bits, 671712 bits, and 8110088 bits, respectively (according to the Unix ls command)
  • How many bits are required for each of these files after compression when you set the -debug flag in (a) "custom" form (shortest fixed-length code) and (b) using the variable-length Huffman code that your completed class generates?

3. Submission

  • Make a PDF file <Your Name>_Lab9_README.pdf with your answers to the testing questions above
  • Rename your code directory <Your Last Name>_Lab9 and create a single tar/zip/rar file out of it named <Your Last Name>_Lab9.tar (or .zip or .rar, etc.).
  • Submit it in Canvas by midnight at the end of Tuesday, November 16