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view mupdf-source/thirdparty/tesseract/src/dict/dict.cpp @ 46:7ee69f120f19 default tip
>>>>> tag v1.26.5+1 for changeset b74429b0f5c4
| author | Franz Glasner <fzglas.hg@dom66.de> |
|---|---|
| date | Sat, 11 Oct 2025 17:17:30 +0200 |
| parents | b50eed0cc0ef |
| children |
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/////////////////////////////////////////////////////////////////////// // File: dict.cpp // Description: dict class. // Author: Samuel Charron // // (C) Copyright 2006, Google Inc. // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // http://www.apache.org/licenses/LICENSE-2.0 // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. // /////////////////////////////////////////////////////////////////////// #include "dict.h" #include "tesserrstream.h" // for tesserr #include "tprintf.h" #include <cstdio> namespace tesseract { class Image; Dict::Dict(CCUtil *ccutil) : letter_is_okay_(&tesseract::Dict::def_letter_is_okay) , probability_in_context_(&tesseract::Dict::def_probability_in_context) , ccutil_(ccutil) , wildcard_unichar_id_(INVALID_UNICHAR_ID) , apostrophe_unichar_id_(INVALID_UNICHAR_ID) , question_unichar_id_(INVALID_UNICHAR_ID) , slash_unichar_id_(INVALID_UNICHAR_ID) , hyphen_unichar_id_(INVALID_UNICHAR_ID) , STRING_MEMBER(user_words_file, "", "A filename of user-provided words.", getCCUtil()->params()) , STRING_INIT_MEMBER(user_words_suffix, "", "A suffix of user-provided words located in tessdata.", getCCUtil()->params()) , STRING_MEMBER(user_patterns_file, "", "A filename of user-provided patterns.", getCCUtil()->params()) , STRING_INIT_MEMBER(user_patterns_suffix, "", "A suffix of user-provided patterns located in " "tessdata.", getCCUtil()->params()) , BOOL_INIT_MEMBER(load_system_dawg, true, "Load system word dawg.", getCCUtil()->params()) , BOOL_INIT_MEMBER(load_freq_dawg, true, "Load frequent word dawg.", getCCUtil()->params()) , BOOL_INIT_MEMBER(load_unambig_dawg, true, "Load unambiguous word dawg.", getCCUtil()->params()) , BOOL_INIT_MEMBER(load_punc_dawg, true, "Load dawg with punctuation" " patterns.", getCCUtil()->params()) , BOOL_INIT_MEMBER(load_number_dawg, true, "Load dawg with number" " patterns.", getCCUtil()->params()) , BOOL_INIT_MEMBER(load_bigram_dawg, true, "Load dawg with special word " "bigrams.", getCCUtil()->params()) , double_MEMBER(xheight_penalty_subscripts, 0.125, "Score penalty (0.1 = 10%) added if there are subscripts " "or superscripts in a word, but it is otherwise OK.", getCCUtil()->params()) , double_MEMBER(xheight_penalty_inconsistent, 0.25, "Score penalty (0.1 = 10%) added if an xheight is " "inconsistent.", getCCUtil()->params()) , double_MEMBER(segment_penalty_dict_frequent_word, 1.0, "Score multiplier for word matches which have good case and" " are frequent in the given language (lower is better).", getCCUtil()->params()) , double_MEMBER(segment_penalty_dict_case_ok, 1.1, "Score multiplier for word matches that have good case " "(lower is better).", getCCUtil()->params()) , double_MEMBER(segment_penalty_dict_case_bad, 1.3125, "Default score multiplier for word matches, which may have " "case issues (lower is better).", getCCUtil()->params()) , double_MEMBER(segment_penalty_dict_nonword, 1.25, "Score multiplier for glyph fragment segmentations which " "do not match a dictionary word (lower is better).", getCCUtil()->params()) , double_MEMBER(segment_penalty_garbage, 1.50, "Score multiplier for poorly cased strings that are not in" " the dictionary and generally look like garbage (lower is" " better).", getCCUtil()->params()) , STRING_MEMBER(output_ambig_words_file, "", "Output file for ambiguities found in the dictionary", getCCUtil()->params()) , INT_MEMBER(dawg_debug_level, 0, "Set to 1 for general debug info" ", to 2 for more details, to 3 to see all the debug messages", getCCUtil()->params()) , INT_MEMBER(hyphen_debug_level, 0, "Debug level for hyphenated words.", getCCUtil()->params()) , BOOL_MEMBER(use_only_first_uft8_step, false, "Use only the first UTF8 step of the given string" " when computing log probabilities.", getCCUtil()->params()) , double_MEMBER(certainty_scale, 20.0, "Certainty scaling factor", getCCUtil()->params()) , double_MEMBER(stopper_nondict_certainty_base, -2.50, "Certainty threshold for non-dict words", getCCUtil()->params()) , double_MEMBER(stopper_phase2_certainty_rejection_offset, 1.0, "Reject certainty offset", getCCUtil()->params()) , INT_MEMBER(stopper_smallword_size, 2, "Size of dict word to be treated as non-dict word", getCCUtil()->params()) , double_MEMBER(stopper_certainty_per_char, -0.50, "Certainty to add" " for each dict char above small word size.", getCCUtil()->params()) , double_MEMBER(stopper_allowable_character_badness, 3.0, "Max certainty variation allowed in a word (in sigma)", getCCUtil()->params()) , INT_MEMBER(stopper_debug_level, 0, "Stopper debug level", getCCUtil()->params()) , BOOL_MEMBER(stopper_no_acceptable_choices, false, "Make AcceptableChoice() always return false. Useful" " when there is a need to explore all segmentations", getCCUtil()->params()) , INT_MEMBER(tessedit_truncate_wordchoice_log, 10, "Max words to keep in list", getCCUtil()->params()) , STRING_MEMBER(word_to_debug, "", "Word for which stopper debug" " information should be printed to stdout", getCCUtil()->params()) , BOOL_MEMBER(segment_nonalphabetic_script, false, "Don't use any alphabetic-specific tricks." " Set to true in the traineddata config file for" " scripts that are cursive or inherently fixed-pitch", getCCUtil()->params()) , BOOL_MEMBER(save_doc_words, 0, "Save Document Words", getCCUtil()->params()) , double_MEMBER(doc_dict_pending_threshold, 0.0, "Worst certainty for using pending dictionary", getCCUtil()->params()) , double_MEMBER(doc_dict_certainty_threshold, -2.25, "Worst certainty for words that can be inserted into the" " document dictionary", getCCUtil()->params()) , INT_MEMBER(max_permuter_attempts, 10000, "Maximum number of different" " character choices to consider during permutation." " This limit is especially useful when user patterns" " are specified, since overly generic patterns can result in" " dawg search exploring an overly large number of options.", getCCUtil()->params()) { reject_offset_ = 0.0; go_deeper_fxn_ = nullptr; hyphen_word_ = nullptr; last_word_on_line_ = false; document_words_ = nullptr; dawg_cache_ = nullptr; dawg_cache_is_ours_ = false; pending_words_ = nullptr; bigram_dawg_ = nullptr; freq_dawg_ = nullptr; punc_dawg_ = nullptr; unambig_dawg_ = nullptr; wordseg_rating_adjust_factor_ = -1.0f; output_ambig_words_file_ = nullptr; } Dict::~Dict() { End(); delete hyphen_word_; if (output_ambig_words_file_ != nullptr) { fclose(output_ambig_words_file_); } } DawgCache *Dict::GlobalDawgCache() { // This global cache (a singleton) will outlive every Tesseract instance // (even those that someone else might declare as global static variables). static DawgCache cache; return &cache; } // Sets up ready for a Load or LoadLSTM. void Dict::SetupForLoad(DawgCache *dawg_cache) { if (dawgs_.size() != 0) { this->End(); } apostrophe_unichar_id_ = getUnicharset().unichar_to_id(kApostropheSymbol); question_unichar_id_ = getUnicharset().unichar_to_id(kQuestionSymbol); slash_unichar_id_ = getUnicharset().unichar_to_id(kSlashSymbol); hyphen_unichar_id_ = getUnicharset().unichar_to_id(kHyphenSymbol); if (dawg_cache != nullptr) { dawg_cache_ = dawg_cache; dawg_cache_is_ours_ = false; } else { dawg_cache_ = new DawgCache(); dawg_cache_is_ours_ = true; } } // Loads the dawgs needed by Tesseract. Call FinishLoad() after. void Dict::Load(const std::string &lang, TessdataManager *data_file) { // Load dawgs_. if (load_punc_dawg) { punc_dawg_ = dawg_cache_->GetSquishedDawg(lang, TESSDATA_PUNC_DAWG, dawg_debug_level, data_file); if (punc_dawg_) { dawgs_.push_back(punc_dawg_); } } if (load_system_dawg) { Dawg *system_dawg = dawg_cache_->GetSquishedDawg(lang, TESSDATA_SYSTEM_DAWG, dawg_debug_level, data_file); if (system_dawg) { dawgs_.push_back(system_dawg); } } if (load_number_dawg) { Dawg *number_dawg = dawg_cache_->GetSquishedDawg(lang, TESSDATA_NUMBER_DAWG, dawg_debug_level, data_file); if (number_dawg) { dawgs_.push_back(number_dawg); } } if (load_bigram_dawg) { bigram_dawg_ = dawg_cache_->GetSquishedDawg(lang, TESSDATA_BIGRAM_DAWG, dawg_debug_level, data_file); // The bigram_dawg_ is NOT used like the other dawgs! DO NOT add to the // dawgs_!! } if (load_freq_dawg) { freq_dawg_ = dawg_cache_->GetSquishedDawg(lang, TESSDATA_FREQ_DAWG, dawg_debug_level, data_file); if (freq_dawg_) { dawgs_.push_back(freq_dawg_); } } if (load_unambig_dawg) { unambig_dawg_ = dawg_cache_->GetSquishedDawg(lang, TESSDATA_UNAMBIG_DAWG, dawg_debug_level, data_file); if (unambig_dawg_) { dawgs_.push_back(unambig_dawg_); } } std::string name; if (!user_words_suffix.empty() || !user_words_file.empty()) { Trie *trie_ptr = new Trie(DAWG_TYPE_WORD, lang, USER_DAWG_PERM, getUnicharset().size(), dawg_debug_level); if (!user_words_file.empty()) { name = user_words_file; } else { name = getCCUtil()->language_data_path_prefix; name += user_words_suffix; } if (!trie_ptr->read_and_add_word_list(name.c_str(), getUnicharset(), Trie::RRP_REVERSE_IF_HAS_RTL)) { tprintf("Error: failed to load %s\n", name.c_str()); delete trie_ptr; } else { dawgs_.push_back(trie_ptr); } } if (!user_patterns_suffix.empty() || !user_patterns_file.empty()) { Trie *trie_ptr = new Trie(DAWG_TYPE_PATTERN, lang, USER_PATTERN_PERM, getUnicharset().size(), dawg_debug_level); trie_ptr->initialize_patterns(&(getUnicharset())); if (!user_patterns_file.empty()) { name = user_patterns_file; } else { name = getCCUtil()->language_data_path_prefix; name += user_patterns_suffix; } if (!trie_ptr->read_pattern_list(name.c_str(), getUnicharset())) { tprintf("Error: failed to load %s\n", name.c_str()); delete trie_ptr; } else { dawgs_.push_back(trie_ptr); } } document_words_ = new Trie(DAWG_TYPE_WORD, lang, DOC_DAWG_PERM, getUnicharset().size(), dawg_debug_level); dawgs_.push_back(document_words_); // This dawg is temporary and should not be searched by letter_is_ok. pending_words_ = new Trie(DAWG_TYPE_WORD, lang, NO_PERM, getUnicharset().size(), dawg_debug_level); } // Loads the dawgs needed by the LSTM model. Call FinishLoad() after. void Dict::LoadLSTM(const std::string &lang, TessdataManager *data_file) { // Load dawgs_. if (load_punc_dawg) { punc_dawg_ = dawg_cache_->GetSquishedDawg(lang, TESSDATA_LSTM_PUNC_DAWG, dawg_debug_level, data_file); if (punc_dawg_) { dawgs_.push_back(punc_dawg_); } } if (load_system_dawg) { Dawg *system_dawg = dawg_cache_->GetSquishedDawg(lang, TESSDATA_LSTM_SYSTEM_DAWG, dawg_debug_level, data_file); if (system_dawg) { dawgs_.push_back(system_dawg); } } if (load_number_dawg) { Dawg *number_dawg = dawg_cache_->GetSquishedDawg(lang, TESSDATA_LSTM_NUMBER_DAWG, dawg_debug_level, data_file); if (number_dawg) { dawgs_.push_back(number_dawg); } } // stolen from Dict::Load (but needs params_ from Tesseract // langdata/config/api): std::string name; if (!user_words_suffix.empty() || !user_words_file.empty()) { Trie *trie_ptr = new Trie(DAWG_TYPE_WORD, lang, USER_DAWG_PERM, getUnicharset().size(), dawg_debug_level); if (!user_words_file.empty()) { name = user_words_file; } else { name = getCCUtil()->language_data_path_prefix; name += user_words_suffix; } if (!trie_ptr->read_and_add_word_list(name.c_str(), getUnicharset(), Trie::RRP_REVERSE_IF_HAS_RTL)) { tprintf("Error: failed to load %s\n", name.c_str()); delete trie_ptr; } else { dawgs_.push_back(trie_ptr); } } if (!user_patterns_suffix.empty() || !user_patterns_file.empty()) { Trie *trie_ptr = new Trie(DAWG_TYPE_PATTERN, lang, USER_PATTERN_PERM, getUnicharset().size(), dawg_debug_level); trie_ptr->initialize_patterns(&(getUnicharset())); if (!user_patterns_file.empty()) { name = user_patterns_file; } else { name = getCCUtil()->language_data_path_prefix; name += user_patterns_suffix; } if (!trie_ptr->read_pattern_list(name.c_str(), getUnicharset())) { tprintf("Error: failed to load %s\n", name.c_str()); delete trie_ptr; } else { dawgs_.push_back(trie_ptr); } } } // Completes the loading process after Load() and/or LoadLSTM(). // Returns false if no dictionaries were loaded. bool Dict::FinishLoad() { if (dawgs_.empty()) { return false; } // Construct a list of corresponding successors for each dawg. Each entry, i, // in the successors_ vector is a vector of integers that represent the // indices into the dawgs_ vector of the successors for dawg i. successors_.reserve(dawgs_.size()); for (auto dawg : dawgs_) { auto *lst = new SuccessorList(); for (unsigned j = 0; j < dawgs_.size(); ++j) { const Dawg *other = dawgs_[j]; if (dawg != nullptr && other != nullptr && (dawg->lang() == other->lang()) && kDawgSuccessors[dawg->type()][other->type()]) { lst->push_back(j); } } successors_.push_back(lst); } return true; } void Dict::End() { if (dawgs_.empty()) { return; // Not safe to call twice. } for (auto &dawg : dawgs_) { if (!dawg_cache_->FreeDawg(dawg)) { delete dawg; } } dawg_cache_->FreeDawg(bigram_dawg_); if (dawg_cache_is_ours_) { delete dawg_cache_; dawg_cache_ = nullptr; } for (auto successor : successors_) { delete successor; } dawgs_.clear(); successors_.clear(); document_words_ = nullptr; delete pending_words_; pending_words_ = nullptr; } // Returns true if in light of the current state unichar_id is allowed // according to at least one of the dawgs in the dawgs_ vector. // See more extensive comments in dict.h where this function is declared. int Dict::def_letter_is_okay(void *void_dawg_args, const UNICHARSET &unicharset, UNICHAR_ID unichar_id, bool word_end) const { auto *dawg_args = static_cast<DawgArgs *>(void_dawg_args); ASSERT_HOST(unicharset.contains_unichar_id(unichar_id)); if (dawg_debug_level >= 3) { tesserr << "def_letter_is_okay: current unichar=" << getUnicharset().debug_str(unichar_id) << " word_end=" << word_end << " num active dawgs=" << dawg_args->active_dawgs->size() << '\n'; } // Do not accept words that contain kPatternUnicharID. // (otherwise pattern dawgs would not function correctly). // Do not accept words containing INVALID_UNICHAR_IDs. if (unichar_id == Dawg::kPatternUnicharID || unichar_id == INVALID_UNICHAR_ID) { dawg_args->permuter = NO_PERM; return NO_PERM; } // Initialization. PermuterType curr_perm = NO_PERM; dawg_args->updated_dawgs->clear(); dawg_args->valid_end = false; // Go over the active_dawgs vector and insert DawgPosition records // with the updated ref (an edge with the corresponding unichar id) into // dawg_args->updated_pos. for (unsigned a = 0; a < dawg_args->active_dawgs->size(); ++a) { const DawgPosition &pos = (*dawg_args->active_dawgs)[a]; const Dawg *punc_dawg = pos.punc_index >= 0 ? dawgs_[pos.punc_index] : nullptr; const Dawg *dawg = pos.dawg_index >= 0 ? dawgs_[pos.dawg_index] : nullptr; if (!dawg && !punc_dawg) { // shouldn't happen. tprintf("Received DawgPosition with no dawg or punc_dawg. wth?\n"); continue; } if (!dawg) { // We're in the punctuation dawg. A core dawg has not been chosen. NODE_REF punc_node = GetStartingNode(punc_dawg, pos.punc_ref); EDGE_REF punc_transition_edge = punc_dawg->edge_char_of(punc_node, Dawg::kPatternUnicharID, word_end); if (punc_transition_edge != NO_EDGE) { // Find all successors, and see which can transition. const SuccessorList &slist = *(successors_[pos.punc_index]); for (int sdawg_index : slist) { const Dawg *sdawg = dawgs_[sdawg_index]; UNICHAR_ID ch = char_for_dawg(unicharset, unichar_id, sdawg); EDGE_REF dawg_edge = sdawg->edge_char_of(0, ch, word_end); if (dawg_edge != NO_EDGE) { if (dawg_debug_level >= 3) { tprintf("Letter found in dawg %d\n", sdawg_index); } dawg_args->updated_dawgs->add_unique( DawgPosition(sdawg_index, dawg_edge, pos.punc_index, punc_transition_edge, false), dawg_debug_level > 0, "Append transition from punc dawg to current dawgs: "); if (sdawg->permuter() > curr_perm) { curr_perm = sdawg->permuter(); } if (sdawg->end_of_word(dawg_edge) && punc_dawg->end_of_word(punc_transition_edge)) { dawg_args->valid_end = true; } } } } EDGE_REF punc_edge = punc_dawg->edge_char_of(punc_node, unichar_id, word_end); if (punc_edge != NO_EDGE) { if (dawg_debug_level >= 3) { tprintf("Letter found in punctuation dawg\n"); } dawg_args->updated_dawgs->add_unique( DawgPosition(-1, NO_EDGE, pos.punc_index, punc_edge, false), dawg_debug_level > 0, "Extend punctuation dawg: "); if (PUNC_PERM > curr_perm) { curr_perm = PUNC_PERM; } if (punc_dawg->end_of_word(punc_edge)) { dawg_args->valid_end = true; } } continue; } if (punc_dawg && dawg->end_of_word(pos.dawg_ref)) { // We can end the main word here. // If we can continue on the punc ref, add that possibility. NODE_REF punc_node = GetStartingNode(punc_dawg, pos.punc_ref); EDGE_REF punc_edge = punc_node == NO_EDGE ? NO_EDGE : punc_dawg->edge_char_of(punc_node, unichar_id, word_end); if (punc_edge != NO_EDGE) { dawg_args->updated_dawgs->add_unique( DawgPosition(pos.dawg_index, pos.dawg_ref, pos.punc_index, punc_edge, true), dawg_debug_level > 0, "Return to punctuation dawg: "); if (dawg->permuter() > curr_perm) { curr_perm = dawg->permuter(); } if (punc_dawg->end_of_word(punc_edge)) { dawg_args->valid_end = true; } } } if (pos.back_to_punc) { continue; } // If we are dealing with the pattern dawg, look up all the // possible edges, not only for the exact unichar_id, but also // for all its character classes (alpha, digit, etc). if (dawg->type() == DAWG_TYPE_PATTERN) { ProcessPatternEdges(dawg, pos, unichar_id, word_end, dawg_args, &curr_perm); // There can't be any successors to dawg that is of type // DAWG_TYPE_PATTERN, so we are done examining this DawgPosition. continue; } // Find the edge out of the node for the unichar_id. NODE_REF node = GetStartingNode(dawg, pos.dawg_ref); EDGE_REF edge = (node == NO_EDGE) ? NO_EDGE : dawg->edge_char_of(node, char_for_dawg(unicharset, unichar_id, dawg), word_end); if (dawg_debug_level >= 3) { tprintf("Active dawg: [%d, " REFFORMAT "] edge=" REFFORMAT "\n", pos.dawg_index, node, edge); } if (edge != NO_EDGE) { // the unichar was found in the current dawg if (dawg_debug_level >= 3) { tprintf("Letter found in dawg %d\n", pos.dawg_index); } if (word_end && punc_dawg && !punc_dawg->end_of_word(pos.punc_ref)) { if (dawg_debug_level >= 3) { tprintf("Punctuation constraint not satisfied at end of word.\n"); } continue; } if (dawg->permuter() > curr_perm) { curr_perm = dawg->permuter(); } if (dawg->end_of_word(edge) && (punc_dawg == nullptr || punc_dawg->end_of_word(pos.punc_ref))) { dawg_args->valid_end = true; } dawg_args->updated_dawgs->add_unique( DawgPosition(pos.dawg_index, edge, pos.punc_index, pos.punc_ref, false), dawg_debug_level > 0, "Append current dawg to updated active dawgs: "); } } // end for // Update dawg_args->permuter if it used to be NO_PERM or became NO_PERM // or if we found the current letter in a non-punctuation dawg. This // allows preserving information on which dawg the "core" word came from. // Keep the old value of dawg_args->permuter if it is COMPOUND_PERM. if (dawg_args->permuter == NO_PERM || curr_perm == NO_PERM || (curr_perm != PUNC_PERM && dawg_args->permuter != COMPOUND_PERM)) { dawg_args->permuter = curr_perm; } if (dawg_debug_level >= 2) { tprintf("Returning %d for permuter code for this character.\n", dawg_args->permuter); } return dawg_args->permuter; } void Dict::ProcessPatternEdges(const Dawg *dawg, const DawgPosition &pos, UNICHAR_ID unichar_id, bool word_end, DawgArgs *dawg_args, PermuterType *curr_perm) const { NODE_REF node = GetStartingNode(dawg, pos.dawg_ref); // Try to find the edge corresponding to the exact unichar_id and to all the // edges corresponding to the character class of unichar_id. std::vector<UNICHAR_ID> unichar_id_patterns; unichar_id_patterns.push_back(unichar_id); dawg->unichar_id_to_patterns(unichar_id, getUnicharset(), &unichar_id_patterns); for (int unichar_id_pattern : unichar_id_patterns) { // On the first iteration check all the outgoing edges. // On the second iteration check all self-loops. for (int k = 0; k < 2; ++k) { EDGE_REF edge = (k == 0) ? dawg->edge_char_of(node, unichar_id_pattern, word_end) : dawg->pattern_loop_edge(pos.dawg_ref, unichar_id_pattern, word_end); if (edge == NO_EDGE) { continue; } if (dawg_debug_level >= 3) { tprintf("Pattern dawg: [%d, " REFFORMAT "] edge=" REFFORMAT "\n", pos.dawg_index, node, edge); tprintf("Letter found in pattern dawg %d\n", pos.dawg_index); } if (dawg->permuter() > *curr_perm) { *curr_perm = dawg->permuter(); } if (dawg->end_of_word(edge)) { dawg_args->valid_end = true; } dawg_args->updated_dawgs->add_unique( DawgPosition(pos.dawg_index, edge, pos.punc_index, pos.punc_ref, pos.back_to_punc), dawg_debug_level > 0, "Append current dawg to updated active dawgs: "); } } } // Fill the given active_dawgs vector with dawgs that could contain the // beginning of the word. If hyphenated() returns true, copy the entries // from hyphen_active_dawgs_ instead. void Dict::init_active_dawgs(DawgPositionVector *active_dawgs, bool ambigs_mode) const { if (hyphenated()) { *active_dawgs = hyphen_active_dawgs_; if (dawg_debug_level >= 3) { for (unsigned i = 0; i < hyphen_active_dawgs_.size(); ++i) { tprintf("Adding hyphen beginning dawg [%d, " REFFORMAT "]\n", hyphen_active_dawgs_[i].dawg_index, hyphen_active_dawgs_[i].dawg_ref); } } } else { default_dawgs(active_dawgs, ambigs_mode); } } void Dict::default_dawgs(DawgPositionVector *dawg_pos_vec, bool suppress_patterns) const { bool punc_dawg_available = (punc_dawg_ != nullptr) && punc_dawg_->edge_char_of(0, Dawg::kPatternUnicharID, true) != NO_EDGE; for (unsigned i = 0; i < dawgs_.size(); i++) { if (dawgs_[i] != nullptr && !(suppress_patterns && (dawgs_[i])->type() == DAWG_TYPE_PATTERN)) { int dawg_ty = dawgs_[i]->type(); bool subsumed_by_punc = kDawgSuccessors[DAWG_TYPE_PUNCTUATION][dawg_ty]; if (dawg_ty == DAWG_TYPE_PUNCTUATION) { dawg_pos_vec->push_back(DawgPosition(-1, NO_EDGE, i, NO_EDGE, false)); if (dawg_debug_level >= 3) { tprintf("Adding beginning punc dawg [%d, " REFFORMAT "]\n", i, NO_EDGE); } } else if (!punc_dawg_available || !subsumed_by_punc) { dawg_pos_vec->push_back(DawgPosition(i, NO_EDGE, -1, NO_EDGE, false)); if (dawg_debug_level >= 3) { tprintf("Adding beginning dawg [%d, " REFFORMAT "]\n", i, NO_EDGE); } } } } } void Dict::add_document_word(const WERD_CHOICE &best_choice) { // Do not add hyphenated word parts to the document dawg. // hyphen_word_ will be non-nullptr after the set_hyphen_word() is // called when the first part of the hyphenated word is // discovered and while the second part of the word is recognized. // hyphen_word_ is cleared in cc_recg() before the next word on // the line is recognized. if (hyphen_word_) { return; } int stringlen = best_choice.length(); if (valid_word(best_choice) || stringlen < 2) { return; } // Discard words that contain >= kDocDictMaxRepChars repeating unichars. if (best_choice.length() >= kDocDictMaxRepChars) { int num_rep_chars = 1; UNICHAR_ID uch_id = best_choice.unichar_id(0); for (unsigned i = 1; i < best_choice.length(); ++i) { if (best_choice.unichar_id(i) != uch_id) { num_rep_chars = 1; uch_id = best_choice.unichar_id(i); } else { ++num_rep_chars; if (num_rep_chars == kDocDictMaxRepChars) { return; } } } } if (best_choice.certainty() < doc_dict_certainty_threshold || stringlen == 2) { if (best_choice.certainty() < doc_dict_pending_threshold) { return; } if (!pending_words_->word_in_dawg(best_choice)) { if (stringlen > 2 || (stringlen == 2 && getUnicharset().get_isupper(best_choice.unichar_id(0)) && getUnicharset().get_isupper(best_choice.unichar_id(1)))) { pending_words_->add_word_to_dawg(best_choice); } return; } } if (save_doc_words) { std::string filename(getCCUtil()->imagefile); filename += ".doc"; FILE *doc_word_file = fopen(filename.c_str(), "a"); if (doc_word_file == nullptr) { tprintf("Error: Could not open file %s\n", filename.c_str()); ASSERT_HOST(doc_word_file); } fprintf(doc_word_file, "%s\n", best_choice.debug_string().c_str()); fclose(doc_word_file); } document_words_->add_word_to_dawg(best_choice); } void Dict::adjust_word(WERD_CHOICE *word, bool nonword, XHeightConsistencyEnum xheight_consistency, float additional_adjust, bool modify_rating, bool debug) { bool is_han = (getUnicharset().han_sid() != getUnicharset().null_sid() && word->GetTopScriptID() == getUnicharset().han_sid()); bool case_is_ok = (is_han || case_ok(*word)); bool punc_is_ok = (is_han || !nonword || valid_punctuation(*word)); float adjust_factor = additional_adjust; float new_rating = word->rating(); new_rating += kRatingPad; const char *xheight_triggered = ""; if (word->length() > 1) { // Calculate x-height and y-offset consistency penalties. switch (xheight_consistency) { case XH_INCONSISTENT: adjust_factor += xheight_penalty_inconsistent; xheight_triggered = ", xhtBAD"; break; case XH_SUBNORMAL: adjust_factor += xheight_penalty_subscripts; xheight_triggered = ", xhtSUB"; break; case XH_GOOD: // leave the factor alone - all good! break; } // TODO(eger): if nonword is true, but there is a "core" that is a dict // word, negate nonword status. } else { if (debug) { tprintf("Consistency could not be calculated.\n"); } } if (debug) { tprintf("%sWord: %s %4.2f%s", nonword ? "Non-" : "", word->unichar_string().c_str(), word->rating(), xheight_triggered); } if (nonword) { // non-dictionary word if (case_is_ok && punc_is_ok) { adjust_factor += segment_penalty_dict_nonword; new_rating *= adjust_factor; if (debug) { tprintf(", W"); } } else { adjust_factor += segment_penalty_garbage; new_rating *= adjust_factor; if (debug) { if (!case_is_ok) { tprintf(", C"); } if (!punc_is_ok) { tprintf(", P"); } } } } else { // dictionary word if (case_is_ok) { if (!is_han && freq_dawg_ != nullptr && freq_dawg_->word_in_dawg(*word)) { word->set_permuter(FREQ_DAWG_PERM); adjust_factor += segment_penalty_dict_frequent_word; new_rating *= adjust_factor; if (debug) { tprintf(", F"); } } else { adjust_factor += segment_penalty_dict_case_ok; new_rating *= adjust_factor; if (debug) { tprintf(", "); } } } else { adjust_factor += segment_penalty_dict_case_bad; new_rating *= adjust_factor; if (debug) { tprintf(", C"); } } } new_rating -= kRatingPad; if (modify_rating) { word->set_rating(new_rating); } if (debug) { tprintf(" %4.2f --> %4.2f\n", adjust_factor, new_rating); } word->set_adjust_factor(adjust_factor); } int Dict::valid_word(const WERD_CHOICE &word, bool numbers_ok) const { const WERD_CHOICE *word_ptr = &word; WERD_CHOICE temp_word(word.unicharset()); if (hyphenated() && hyphen_word_->unicharset() == word.unicharset()) { copy_hyphen_info(&temp_word); temp_word += word; word_ptr = &temp_word; } if (word_ptr->empty()) { return NO_PERM; } // Allocate vectors for holding current and updated // active_dawgs and initialize them. DawgPositionVector active_dawgs[2]; init_active_dawgs(&(active_dawgs[0]), false); DawgArgs dawg_args(&(active_dawgs[0]), &(active_dawgs[1]), NO_PERM); int last_index = word_ptr->length() - 1; // Call letter_is_okay for each letter in the word. for (int i = hyphen_base_size(); i <= last_index; ++i) { if (!((this->*letter_is_okay_)(&dawg_args, *word_ptr->unicharset(), word_ptr->unichar_id(i), i == last_index))) { break; } // Swap active_dawgs, constraints with the corresponding updated vector. if (dawg_args.updated_dawgs == &(active_dawgs[1])) { dawg_args.updated_dawgs = &(active_dawgs[0]); ++(dawg_args.active_dawgs); } else { ++(dawg_args.updated_dawgs); dawg_args.active_dawgs = &(active_dawgs[0]); } } return valid_word_permuter(dawg_args.permuter, numbers_ok) ? dawg_args.permuter : NO_PERM; } bool Dict::valid_bigram(const WERD_CHOICE &word1, const WERD_CHOICE &word2) const { if (bigram_dawg_ == nullptr) { return false; } // Extract the core word from the middle of each word with any digits // replaced with question marks. unsigned w1start, w1end, w2start, w2end; word1.punct_stripped(&w1start, &w1end); word2.punct_stripped(&w2start, &w2end); // We don't want to penalize a single guillemet, hyphen, etc. // But our bigram list doesn't have any information about punctuation. if (w1start >= w1end) { return word1.length() < 3; } if (w2start >= w2end) { return word2.length() < 3; } const UNICHARSET &uchset = getUnicharset(); std::vector<UNICHAR_ID> bigram_string; bigram_string.reserve(w1end + w2end + 1); for (auto i = w1start; i < w1end; i++) { const auto &normed_ids = getUnicharset().normed_ids(word1.unichar_id(i)); if (normed_ids.size() == 1 && uchset.get_isdigit(normed_ids[0])) { bigram_string.push_back(question_unichar_id_); } else { bigram_string.insert(bigram_string.end(), normed_ids.begin(), normed_ids.end()); } } bigram_string.push_back(UNICHAR_SPACE); for (auto i = w2start; i < w2end; i++) { const auto &normed_ids = getUnicharset().normed_ids(word2.unichar_id(i)); if (normed_ids.size() == 1 && uchset.get_isdigit(normed_ids[0])) { bigram_string.push_back(question_unichar_id_); } else { bigram_string.insert(bigram_string.end(), normed_ids.begin(), normed_ids.end()); } } WERD_CHOICE normalized_word(&uchset, bigram_string.size()); for (int i : bigram_string) { normalized_word.append_unichar_id_space_allocated(i, 1, 0.0f, 0.0f); } return bigram_dawg_->word_in_dawg(normalized_word); } bool Dict::valid_punctuation(const WERD_CHOICE &word) { if (word.empty()) { return NO_PERM; } WERD_CHOICE new_word(word.unicharset()); auto last_index = word.length() - 1; int new_len; for (unsigned i = 0; i <= last_index; ++i) { UNICHAR_ID unichar_id = (word.unichar_id(i)); if (getUnicharset().get_ispunctuation(unichar_id)) { new_word.append_unichar_id(unichar_id, 1, 0.0, 0.0); } else if (!getUnicharset().get_isalpha(unichar_id) && !getUnicharset().get_isdigit(unichar_id)) { return false; // neither punc, nor alpha, nor digit } else if ((new_len = new_word.length()) == 0 || new_word.unichar_id(new_len - 1) != Dawg::kPatternUnicharID) { new_word.append_unichar_id(Dawg::kPatternUnicharID, 1, 0.0, 0.0); } } for (unsigned i = 0; i < dawgs_.size(); ++i) { if (dawgs_[i] != nullptr && dawgs_[i]->type() == DAWG_TYPE_PUNCTUATION && dawgs_[i]->word_in_dawg(new_word)) { return true; } } return false; } /// Returns true if the language is space-delimited (not CJ, or T). bool Dict::IsSpaceDelimitedLang() const { const UNICHARSET &u_set = getUnicharset(); if (u_set.han_sid() > 0) { return false; } if (u_set.katakana_sid() > 0) { return false; } if (u_set.thai_sid() > 0) { return false; } return true; } } // namespace tesseract