mirror of
https://github.com/moses-smt/mosesdecoder.git
synced 2024-12-25 12:52:29 +03:00
415 lines
14 KiB
C++
415 lines
14 KiB
C++
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#include "huffmanish.hh"
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Huffman::Huffman (const char * filepath) {
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//Read the file
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util::FilePiece filein(filepath);
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//Init uniq_lines to zero;
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uniq_lines = 0;
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line_text prev_line; //Check for unique lines.
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int num_lines = 0 ;
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while (true){
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line_text new_line;
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num_lines++;
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try {
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//Process line read
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new_line = splitLine(filein.ReadLine());
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count_elements(new_line); //Counts the number of elements, adds new and increments counters.
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} catch (util::EndOfFileException e){
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std::cerr << "Unique entries counted: ";
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break;
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}
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if (new_line.source_phrase == prev_line.source_phrase){
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continue;
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} else {
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uniq_lines++;
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prev_line = new_line;
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}
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}
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std::cerr << uniq_lines << std::endl;
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}
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void Huffman::count_elements(line_text linein){
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//For target phrase:
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util::TokenIter<util::SingleCharacter> it(linein.target_phrase, util::SingleCharacter(' '));
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while (it) {
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//Check if we have that entry
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std::map<std::string, unsigned int>::iterator mapiter;
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mapiter = target_phrase_words.find(it->as_string());
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if (mapiter != target_phrase_words.end()){
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//If the element is found, increment the count.
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mapiter->second++;
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} else {
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//Else create a new entry;
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target_phrase_words.insert(std::pair<std::string, unsigned int>(it->as_string(), 1));
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}
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it++;
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}
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//For word allignment 1
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std::map<std::vector<unsigned char>, unsigned int>::iterator mapiter3;
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std::vector<unsigned char> numbers = splitWordAll1(linein.word_all1);
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mapiter3 = word_all1.find(numbers);
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if (mapiter3 != word_all1.end()){
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//If the element is found, increment the count.
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mapiter3->second++;
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} else {
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//Else create a new entry;
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word_all1.insert(std::pair<std::vector<unsigned char>, unsigned int>(numbers, 1));
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}
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}
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//Assigns huffman values for each unique element
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void Huffman::assign_values() {
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//First create vectors for all maps so that we could sort them later.
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//Create a vector for target phrases
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for(std::map<std::string, unsigned int>::iterator it = target_phrase_words.begin(); it != target_phrase_words.end(); it++ ) {
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target_phrase_words_counts.push_back(*it);
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}
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//Sort it
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std::sort(target_phrase_words_counts.begin(), target_phrase_words_counts.end(), sort_pair());
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//Create a vector for word allignments 1
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for(std::map<std::vector<unsigned char>, unsigned int>::iterator it = word_all1.begin(); it != word_all1.end(); it++ ) {
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word_all1_counts.push_back(*it);
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}
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//Sort it
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std::sort(word_all1_counts.begin(), word_all1_counts.end(), sort_pair_vec());
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//Afterwards we assign a value for each phrase, starting from 1, as zero is reserved for delimiter
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unsigned int i = 1; //huffman code
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for(std::vector<std::pair<std::string, unsigned int> >::iterator it = target_phrase_words_counts.begin();
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it != target_phrase_words_counts.end(); it++){
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target_phrase_huffman.insert(std::pair<std::string, unsigned int>(it->first, i));
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i++; //Go to the next huffman code
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}
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i = 1; //Reset i for the next map
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for(std::vector<std::pair<std::vector<unsigned char>, unsigned int> >::iterator it = word_all1_counts.begin();
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it != word_all1_counts.end(); it++){
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word_all1_huffman.insert(std::pair<std::vector<unsigned char>, unsigned int>(it->first, i));
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i++; //Go to the next huffman code
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}
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//After lookups are produced, clear some memory usage of objects not needed anymore.
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target_phrase_words.clear();
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word_all1.clear();
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target_phrase_words_counts.clear();
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word_all1_counts.clear();
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std::cerr << "Finished generating huffman codes." << std::endl;
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}
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void Huffman::serialize_maps(const char * dirname){
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//Note that directory name should exist.
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std::string basedir(dirname);
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std::string target_phrase_path(basedir + "/target_phrases");
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std::string probabilities_path(basedir + "/probs");
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std::string word_all1_path(basedir + "/Wall1");
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//Target phrase
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std::ofstream os (target_phrase_path.c_str(), std::ios::binary);
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boost::archive::text_oarchive oarch(os);
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oarch << lookup_target_phrase;
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os.close();
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//Word all1
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std::ofstream os2 (word_all1_path.c_str(), std::ios::binary);
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boost::archive::text_oarchive oarch2(os2);
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oarch2 << lookup_word_all1;
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os2.close();
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}
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std::vector<unsigned char> Huffman::full_encode_line(line_text line){
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return vbyte_encode_line((encode_line(line)));
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}
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std::vector<unsigned int> Huffman::encode_line(line_text line){
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std::vector<unsigned int> retvector;
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//Get target_phrase first.
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util::TokenIter<util::SingleCharacter> it(line.target_phrase, util::SingleCharacter(' '));
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while (it) {
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retvector.push_back(target_phrase_huffman.find(it->as_string())->second);
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it++;
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}
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//Add a zero;
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retvector.push_back(0);
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//Get probabilities. Reinterpreting the float bytes as unsgined int.
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util::TokenIter<util::SingleCharacter> probit(line.prob, util::SingleCharacter(' '));
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while (probit) {
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//Sometimes we have too big floats to handle, so first convert to double
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double tempnum = atof(probit->data());
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float num = (float)tempnum;
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retvector.push_back(reinterpret_float(&num));
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probit++;
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}
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//Add a zero;
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retvector.push_back(0);
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//Get Word allignments
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retvector.push_back(word_all1_huffman.find(splitWordAll1(line.word_all1))->second);
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retvector.push_back(0);
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return retvector;
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}
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void Huffman::produce_lookups(){
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//basically invert every map that we have
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for(std::map<std::string, unsigned int>::iterator it = target_phrase_huffman.begin(); it != target_phrase_huffman.end(); it++ ) {
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lookup_target_phrase.insert(std::pair<unsigned int, std::string>(it->second, it->first));
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}
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for(std::map<std::vector<unsigned char>, unsigned int>::iterator it = word_all1_huffman.begin(); it != word_all1_huffman.end(); it++ ) {
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lookup_word_all1.insert(std::pair<unsigned int, std::vector<unsigned char> >(it->second, it->first));
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}
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}
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HuffmanDecoder::HuffmanDecoder (const char * dirname){
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//Read the maps from disk
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//Note that directory name should exist.
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std::string basedir(dirname);
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std::string target_phrase_path(basedir + "/target_phrases");
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std::string word_all1_path(basedir + "/Wall1");
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//Target phrases
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std::ifstream is (target_phrase_path.c_str(), std::ios::binary);
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boost::archive::text_iarchive iarch(is);
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iarch >> lookup_target_phrase;
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is.close();
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//Word allignment 1
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std::ifstream is2 (word_all1_path.c_str(), std::ios::binary);
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boost::archive::text_iarchive iarch2(is2);
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iarch2 >> lookup_word_all1;
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is2.close();
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}
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HuffmanDecoder::HuffmanDecoder (std::map<unsigned int, std::string> * lookup_target,
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std::map<unsigned int, std::vector<unsigned char> > * lookup_word1) {
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lookup_target_phrase = *lookup_target;
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lookup_word_all1 = *lookup_word1;
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}
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std::vector<target_text> HuffmanDecoder::full_decode_line (std::vector<unsigned char> lines){
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std::vector<target_text> retvector; //All target phrases
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std::vector<unsigned int> decoded_lines = vbyte_decode_line(lines); //All decoded lines
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std::vector<unsigned int>::iterator it = decoded_lines.begin(); //Iterator for them
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std::vector<unsigned int> current_target_phrase; //Current target phrase decoded
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short zero_count = 0; //Count home many zeroes we have met. so far. Every 3 zeroes mean a new target phrase.
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while(it != decoded_lines.end()){
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if (zero_count == 3) {
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//We have finished with this entry, decode it, and add it to the retvector.
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retvector.push_back(decode_line(current_target_phrase));
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current_target_phrase.clear(); //Clear the current target phrase and the zero_count
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zero_count = 0; //So that we can reuse them for the next target phrase
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}
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//Add to the next target_phrase, number by number.
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current_target_phrase.push_back(*it);
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if (*it == 0) {
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zero_count++;
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}
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it++; //Go to the next word/symbol
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}
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//Don't forget the last remaining line!
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if (zero_count == 3) {
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//We have finished with this entry, decode it, and add it to the retvector.
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retvector.push_back(decode_line(current_target_phrase));
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current_target_phrase.clear(); //Clear the current target phrase and the zero_count
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zero_count = 0; //So that we can reuse them for the next target phrase
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}
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return retvector;
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}
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target_text HuffmanDecoder::decode_line (std::vector<unsigned int> input){
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//demo decoder
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target_text ret;
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//Split everything
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std::vector<unsigned int> target_phrase;
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std::vector<unsigned int> probs;
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unsigned int wAll;
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//Split the line into the proper arrays
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short num_zeroes = 0;
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int counter = 0;
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while (num_zeroes < 3){
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unsigned int num = input[counter];
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if (num == 0) {
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num_zeroes++;
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} else if (num_zeroes == 0){
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target_phrase.push_back(num);
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} else if (num_zeroes == 1){
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probs.push_back(num);
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} else if (num_zeroes == 2){
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wAll = num;
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}
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counter++;
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}
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ret.target_phrase = target_phrase;
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ret.word_all1 = lookup_word_all1.find(wAll)->second;
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//Decode probabilities
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for (std::vector<unsigned int>::iterator it = probs.begin(); it != probs.end(); it++){
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ret.prob.push_back(reinterpret_uint(&(*it)));
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}
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return ret;
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}
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inline std::string HuffmanDecoder::getTargetWordFromID(unsigned int id) {
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return lookup_target_phrase.find(id)->second;
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}
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std::string HuffmanDecoder::getTargetWordsFromIDs(std::vector<unsigned int> ids){
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std::string returnstring;
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for (std::vector<unsigned int>::iterator it = ids.begin(); it != ids.end(); it++){
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returnstring.append(getTargetWordFromID(*it) + " ");
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}
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return returnstring;
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}
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inline std::string getTargetWordFromID(unsigned int id, std::map<unsigned int, std::string> * lookup_target_phrase) {
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return lookup_target_phrase->find(id)->second;
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}
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std::string getTargetWordsFromIDs(std::vector<unsigned int> ids, std::map<unsigned int, std::string> * lookup_target_phrase) {
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std::string returnstring;
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for (std::vector<unsigned int>::iterator it = ids.begin(); it != ids.end(); it++){
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returnstring.append(getTargetWordFromID(*it, lookup_target_phrase) + " ");
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}
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return returnstring;
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}
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/*Those functions are used to more easily store the floats in the binary phrase table
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We convert the float unsinged int so that it is the same as our other values and we can
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apply variable byte encoding on top of it.*/
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inline unsigned int reinterpret_float(float * num){
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unsigned int * converted_num;
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converted_num = reinterpret_cast<unsigned int *>(num);
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return *converted_num;
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}
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inline float reinterpret_uint(unsigned int * num){
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float * converted_num;
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converted_num = reinterpret_cast<float *>(num);
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return *converted_num;
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}
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/*Mostly taken from stackoverflow, http://stackoverflow.com/questions/5858646/optimizing-variable-length-encoding
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and modified in order to return a vector of chars. Implements ULEB128 or variable byte encoding.
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This is highly optimized version with unrolled loop */
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inline std::vector<unsigned char> vbyte_encode(unsigned int num){
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//Determine how many bytes we are going to take.
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short size;
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std::vector<unsigned char> byte_vector;
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if (num < 0x00000080U) {
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size = 1;
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byte_vector.reserve(size);
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goto b1;
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}
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if (num < 0x00004000U) {
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size = 2;
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byte_vector.reserve(size);
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goto b2;
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}
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if (num < 0x00200000U) {
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size = 3;
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byte_vector.reserve(size);
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goto b3;
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}
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if (num < 0x10000000U) {
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size = 4;
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byte_vector.reserve(size);
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goto b4;
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}
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size = 5;
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byte_vector.reserve(size);
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//Now proceed with the encoding.
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byte_vector.push_back((num & 0x7f) | 0x80);
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num >>= 7;
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b4:
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byte_vector.push_back((num & 0x7f) | 0x80);
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num >>= 7;
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b3:
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byte_vector.push_back((num & 0x7f) | 0x80);
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num >>= 7;
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b2:
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byte_vector.push_back((num & 0x7f) | 0x80);
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num >>= 7;
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b1:
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byte_vector.push_back(num);
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return byte_vector;
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}
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std::vector<unsigned int> vbyte_decode_line(std::vector<unsigned char> line){
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std::vector<unsigned int> huffman_line;
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std::vector<unsigned char> current_num;
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for (std::vector<unsigned char>::iterator it = line.begin(); it != line.end(); it++){
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current_num.push_back(*it);
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if ((*it >> 7) != 1) {
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//We don't have continuation in the next bit
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huffman_line.push_back(bytes_to_int(current_num));
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current_num.clear();
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}
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}
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return huffman_line;
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}
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inline unsigned int bytes_to_int(std::vector<unsigned char> number){
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unsigned int retvalue = 0;
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std::vector<unsigned char>::iterator it = number.begin();
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unsigned char shift = 0; //By how many bits to shift
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while (it != number.end()) {
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retvalue |= (*it & 0x7f) << shift;
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shift += 7;
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it++;
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}
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return retvalue;
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}
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std::vector<unsigned char> vbyte_encode_line(std::vector<unsigned int> line) {
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std::vector<unsigned char> retvec;
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//For each unsigned int in the line, vbyte encode it and add it to a vector of unsigned chars.
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for (std::vector<unsigned int>::iterator it = line.begin(); it != line.end(); it++){
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std::vector<unsigned char> vbyte_encoded = vbyte_encode(*it);
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retvec.insert(retvec.end(), vbyte_encoded.begin(), vbyte_encoded.end());
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}
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return retvec;
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}
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