/////////////////////////////////////////////////////////////////////// // File: unicharset.cpp // Description: Unicode character/ligature set class. // Author: Thomas Kielbus // Created: Wed Jun 28 17:05:01 PDT 2006 // // (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 "unicharset.h" #include #include #include #include "params.h" #include "serialis.h" #include "tesscallback.h" #include "tprintf.h" #include "unichar.h" // Special character used in representing character fragments. static const char kSeparator = '|'; // Special character used in representing 'natural' character fragments. static const char kNaturalFlag = 'n'; static const int ISALPHA_MASK = 0x1; static const int ISLOWER_MASK = 0x2; static const int ISUPPER_MASK = 0x4; static const int ISDIGIT_MASK = 0x8; static const int ISPUNCTUATION_MASK = 0x10; // Y coordinate threshold for determining cap-height vs x-height. // TODO(rays) Bring the global definition down to the ccutil library level, // so this constant is relative to some other constants. static const int kMeanlineThreshold = 220; // Let C be the number of alpha chars for which all tops exceed // kMeanlineThreshold, and X the number of alpha chars for which all // tops are below kMeanlineThreshold, then if X > C * // kMinXHeightFraction and C > X * kMinCapHeightFraction or more than // half the alpha characters have upper or lower case, then the // unicharset "has x-height". const double kMinXHeightFraction = 0.25; const double kMinCapHeightFraction = 0.05; /*static */ const char* UNICHARSET::kCustomLigatures[][2] = { {"ct", "\uE003"}, // c + t -> U+E003 {"ſh", "\uE006"}, // long-s + h -> U+E006 {"ſi", "\uE007"}, // long-s + i -> U+E007 {"ſl", "\uE008"}, // long-s + l -> U+E008 {"ſſ", "\uE009"}, // long-s + long-s -> U+E009 {NULL, NULL} }; // List of strings for the SpecialUnicharCodes. Keep in sync with the enum. const char* UNICHARSET::kSpecialUnicharCodes[SPECIAL_UNICHAR_CODES_COUNT] = { " ", "Joined", "|Broken|0|1" }; UNICHARSET::UNICHAR_PROPERTIES::UNICHAR_PROPERTIES() { Init(); } // Initialize all properties to sensible default values. void UNICHARSET::UNICHAR_PROPERTIES::Init() { isalpha = false; islower = false; isupper = false; isdigit = false; ispunctuation = false; isngram = false; enabled = false; SetRangesOpen(); script_id = 0; other_case = 0; mirror = 0; normed = ""; direction = UNICHARSET::U_LEFT_TO_RIGHT; fragment = NULL; } // Sets all ranges wide open. Initialization default in case there are // no useful values available. void UNICHARSET::UNICHAR_PROPERTIES::SetRangesOpen() { min_bottom = 0; max_bottom = MAX_UINT8; min_top = 0; max_top = MAX_UINT8; width = 0.0f; width_sd = 0.0f; bearing = 0.0f; bearing_sd = 0.0f; advance = 0.0f; advance_sd = 0.0f; } // Sets all ranges to empty. Used before expanding with font-based data. void UNICHARSET::UNICHAR_PROPERTIES::SetRangesEmpty() { min_bottom = MAX_UINT8; max_bottom = 0; min_top = MAX_UINT8; max_top = 0; width = 0.0f; width_sd = 0.0f; bearing = 0.0f; bearing_sd = 0.0f; advance = 0.0f; advance_sd = 0.0f; } // Returns true if any of the top/bottom/width/bearing/advance ranges/stats // is emtpy. bool UNICHARSET::UNICHAR_PROPERTIES::AnyRangeEmpty() const { return width == 0.0f || advance == 0.0f; } // Expands the ranges with the ranges from the src properties. void UNICHARSET::UNICHAR_PROPERTIES::ExpandRangesFrom( const UNICHAR_PROPERTIES& src) { UpdateRange(src.min_bottom, &min_bottom, &max_bottom); UpdateRange(src.max_bottom, &min_bottom, &max_bottom); UpdateRange(src.min_top, &min_top, &max_top); UpdateRange(src.max_top, &min_top, &max_top); if (src.width_sd > width_sd) { width = src.width; width_sd = src.width_sd; } if (src.bearing_sd > bearing_sd) { bearing = src.bearing; bearing_sd = src.bearing_sd; } if (src.advance_sd > advance_sd) { advance = src.advance; advance_sd = src.advance_sd; } } // Copies the properties from src into this. void UNICHARSET::UNICHAR_PROPERTIES::CopyFrom(const UNICHAR_PROPERTIES& src) { // Apart from the fragment, everything else can be done with a default copy. CHAR_FRAGMENT* saved_fragment = fragment; *this = src; // Bitwise copy. fragment = saved_fragment; } UNICHARSET::UNICHARSET() : unichars(NULL), ids(), size_used(0), size_reserved(0), script_table(NULL), script_table_size_used(0), null_script("NULL") { clear(); for (int i = 0; i < SPECIAL_UNICHAR_CODES_COUNT; ++i) { unichar_insert(kSpecialUnicharCodes[i]); if (i == UNICHAR_JOINED) set_isngram(i, true); } } UNICHARSET::~UNICHARSET() { clear(); } void UNICHARSET::reserve(int unichars_number) { if (unichars_number > size_reserved) { UNICHAR_SLOT* unichars_new = new UNICHAR_SLOT[unichars_number]; for (int i = 0; i < size_used; ++i) unichars_new[i] = unichars[i]; for (int j = size_used; j < unichars_number; ++j) { unichars_new[j].properties.script_id = add_script(null_script); } delete[] unichars; unichars = unichars_new; size_reserved = unichars_number; } } UNICHAR_ID UNICHARSET::unichar_to_id(const char* const unichar_repr) const { return ids.contains(unichar_repr) ? ids.unichar_to_id(unichar_repr) : INVALID_UNICHAR_ID; } UNICHAR_ID UNICHARSET::unichar_to_id(const char* const unichar_repr, int length) const { assert(length > 0 && length <= UNICHAR_LEN); return ids.contains(unichar_repr, length) ? ids.unichar_to_id(unichar_repr, length) : INVALID_UNICHAR_ID; } // Return the minimum number of bytes that matches a legal UNICHAR_ID, // while leaving the rest of the string encodable. Returns 0 if the // beginning of the string is not encodable. // WARNING: this function now encodes the whole string for precision. // Use encode_string in preference to repeatedly calling step. int UNICHARSET::step(const char* str) const { GenericVector encoding; GenericVector lengths; encode_string(str, true, &encoding, &lengths, NULL); if (encoding.empty() || encoding[0] == INVALID_UNICHAR_ID) return 0; return lengths[0]; } // Return whether the given UTF-8 string is encodable with this UNICHARSET. // If not encodable, write the first byte offset which cannot be converted // into the second (return) argument. bool UNICHARSET::encodable_string(const char *str, int *first_bad_position) const { GenericVector encoding; return encode_string(str, true, &encoding, NULL, first_bad_position); } // Encodes the given UTF-8 string with this UNICHARSET. // Returns true if the encoding succeeds completely, false if there is at // least one INVALID_UNICHAR_ID in the returned encoding, but in this case // the rest of the string is still encoded. // If lengths is not NULL, then it is filled with the corresponding // byte length of each encoded UNICHAR_ID. bool UNICHARSET::encode_string(const char* str, bool give_up_on_failure, GenericVector* encoding, GenericVector* lengths, int* encoded_length) const { GenericVector working_encoding; GenericVector working_lengths; GenericVector best_lengths; encoding->truncate(0); // Just in case str is empty. int str_length = strlen(str); int str_pos = 0; bool perfect = true; while (str_pos < str_length) { encode_string(str, str_pos, str_length, &working_encoding, &working_lengths, &str_pos, encoding, &best_lengths); if (str_pos < str_length) { // This is a non-match. Skip one utf-8 character. perfect = false; if (give_up_on_failure) break; int step = UNICHAR::utf8_step(str + str_pos); if (step == 0) step = 1; encoding->push_back(INVALID_UNICHAR_ID); best_lengths.push_back(step); str_pos += step; working_encoding = *encoding; working_lengths = best_lengths; } } if (lengths != NULL) *lengths = best_lengths; if (encoded_length != NULL) *encoded_length = str_pos; return perfect; } const char* UNICHARSET::id_to_unichar(UNICHAR_ID id) const { if (id == INVALID_UNICHAR_ID) { return INVALID_UNICHAR; } ASSERT_HOST(id < this->size()); return unichars[id].representation; } const char* UNICHARSET::id_to_unichar_ext(UNICHAR_ID id) const { if (id == INVALID_UNICHAR_ID) { return INVALID_UNICHAR; } ASSERT_HOST(id < this->size()); // Resolve from the kCustomLigatures table if this is a private encoding. if (get_isprivate(id)) { const char* ch = id_to_unichar(id); for (int i = 0; kCustomLigatures[i][0] != NULL; ++i) { if (!strcmp(ch, kCustomLigatures[i][1])) { return kCustomLigatures[i][0]; } } } // Otherwise return the stored representation. return unichars[id].representation; } // Return a STRING that reformats the utf8 str into the str followed // by its hex unicodes. STRING UNICHARSET::debug_utf8_str(const char* str) { STRING result = str; result += " ["; int step = 1; // Chop into unicodes and code each as hex. for (int i = 0; str[i] != '\0'; i += step) { char hex[sizeof(int) * 2 + 1]; step = UNICHAR::utf8_step(str + i); if (step == 0) { step = 1; sprintf(hex, "%x", str[i]); } else { UNICHAR ch(str + i, step); sprintf(hex, "%x", ch.first_uni()); } result += hex; result += " "; } result += "]"; return result; } // Return a STRING containing debug information on the unichar, including // the id_to_unichar, its hex unicodes and the properties. STRING UNICHARSET::debug_str(UNICHAR_ID id) const { if (id == INVALID_UNICHAR_ID) return STRING(id_to_unichar(id)); const CHAR_FRAGMENT *fragment = this->get_fragment(id); if (fragment) { return fragment->to_string(); } const char* str = id_to_unichar(id); STRING result = debug_utf8_str(str); // Append a for lower alpha, A for upper alpha, and x if alpha but neither. if (get_isalpha(id)) { if (get_islower(id)) result += "a"; else if (get_isupper(id)) result += "A"; else result += "x"; } // Append 0 if a digit. if (get_isdigit(id)) { result += "0"; } // Append p is a punctuation symbol. if (get_ispunctuation(id)) { result += "p"; } return result; } // Sets the normed_ids vector from the normed string. normed_ids is not // stored in the file, and needs to be set when the UNICHARSET is loaded. void UNICHARSET::set_normed_ids(UNICHAR_ID unichar_id) { unichars[unichar_id].properties.normed_ids.truncate(0); if (unichar_id == UNICHAR_SPACE && id_to_unichar(unichar_id)[0] == ' ') { unichars[unichar_id].properties.normed_ids.push_back(UNICHAR_SPACE); } else if (!encode_string(unichars[unichar_id].properties.normed.string(), true, &unichars[unichar_id].properties.normed_ids, NULL, NULL)) { unichars[unichar_id].properties.normed_ids.truncate(0); unichars[unichar_id].properties.normed_ids.push_back(unichar_id); } } // Returns whether the unichar id represents a unicode value in the private use // area. We use this range only internally to represent uncommon ligatures // (eg. 'ct') that do not have regular unicode values. bool UNICHARSET::get_isprivate(UNICHAR_ID unichar_id) const { UNICHAR uc(id_to_unichar(unichar_id), -1); int uni = uc.first_uni(); return (uni >= 0xE000 && uni <= 0xF8FF); } // Sets all ranges to empty, so they can be expanded to set the values. void UNICHARSET::set_ranges_empty() { for (int id = 0; id < size_used; ++id) { unichars[id].properties.SetRangesEmpty(); } } // Sets all the properties for this unicharset given a src unicharset with // everything set. The unicharsets don't have to be the same, and graphemes // are correctly accounted for. void UNICHARSET::PartialSetPropertiesFromOther(int start_index, const UNICHARSET& src) { for (int ch = start_index; ch < size_used; ++ch) { const char* utf8 = id_to_unichar(ch); UNICHAR_PROPERTIES properties; if (src.GetStrProperties(utf8, &properties)) { // Setup the script_id, other_case, and mirror properly. const char* script = src.get_script_from_script_id(properties.script_id); properties.script_id = add_script(script); const char* other_case = src.id_to_unichar(properties.other_case); if (contains_unichar(other_case)) { properties.other_case = unichar_to_id(other_case); } else { properties.other_case = ch; } const char* mirror_str = src.id_to_unichar(properties.mirror); if (contains_unichar(mirror_str)) { properties.mirror = unichar_to_id(mirror_str); } else { properties.mirror = ch; } unichars[ch].properties.CopyFrom(properties); set_normed_ids(ch); } } } // Expands the tops and bottoms and widths for this unicharset given a // src unicharset with ranges in it. The unicharsets don't have to be the // same, and graphemes are correctly accounted for. void UNICHARSET::ExpandRangesFromOther(const UNICHARSET& src) { for (int ch = 0; ch < size_used; ++ch) { const char* utf8 = id_to_unichar(ch); UNICHAR_PROPERTIES properties; if (src.GetStrProperties(utf8, &properties)) { // Expand just the ranges from properties. unichars[ch].properties.ExpandRangesFrom(properties); } } } // Makes this a copy of src. Clears this completely first, so the automatic // ids will not be present in this if not in src. Does NOT reorder the set! void UNICHARSET::CopyFrom(const UNICHARSET& src) { clear(); for (int ch = 0; ch < src.size_used; ++ch) { const UNICHAR_PROPERTIES& src_props = src.unichars[ch].properties; const char* utf8 = src.id_to_unichar(ch); unichar_insert(utf8); unichars[ch].properties.ExpandRangesFrom(src_props); } // Set properties, including mirror and other_case, WITHOUT reordering // the unicharset. PartialSetPropertiesFromOther(0, src); } // For each id in src, if it does not occur in this, add it, as in // SetPropertiesFromOther, otherwise expand the ranges, as in // ExpandRangesFromOther. void UNICHARSET::AppendOtherUnicharset(const UNICHARSET& src) { int initial_used = size_used; for (int ch = 0; ch < src.size_used; ++ch) { const UNICHAR_PROPERTIES& src_props = src.unichars[ch].properties; const char* utf8 = src.id_to_unichar(ch); if (ch >= SPECIAL_UNICHAR_CODES_COUNT && src_props.AnyRangeEmpty()) { // Only use fully valid entries. tprintf("Bad properties for index %d, char %s: " "%d,%d %d,%d %g,%g %g,%g %g,%g\n", ch, utf8, src_props.min_bottom, src_props.max_bottom, src_props.min_top, src_props.max_top, src_props.width, src_props.width_sd, src_props.bearing, src_props.bearing_sd, src_props.advance, src_props.advance_sd); continue; } int id = size_used; if (contains_unichar(utf8)) { id = unichar_to_id(utf8); // Just expand current ranges. unichars[id].properties.ExpandRangesFrom(src_props); } else { unichar_insert(utf8); unichars[id].properties.SetRangesEmpty(); } } // Set properties, including mirror and other_case, WITHOUT reordering // the unicharset. PartialSetPropertiesFromOther(initial_used, src); } // Returns true if the acceptable ranges of the tops of the characters do // not overlap, making their x-height calculations distinct. bool UNICHARSET::SizesDistinct(UNICHAR_ID id1, UNICHAR_ID id2) const { int overlap = MIN(unichars[id1].properties.max_top, unichars[id2].properties.max_top) - MAX(unichars[id1].properties.min_top, unichars[id2].properties.min_top); return overlap <= 0; } // Internal recursive version of encode_string above. // Seeks to encode the given string as a sequence of UNICHAR_IDs such that // each UNICHAR_ID uses the least possible part of the utf8 str. // It does this by depth-first tail recursion on increasing length matches // to the UNICHARSET, saving the first encountered result that encodes the // maximum total length of str. It stops on a failure to encode to make // the overall process of encoding a partially failed string more efficient. // See unicharset.h for definition of the args. void UNICHARSET::encode_string(const char* str, int str_index, int str_length, GenericVector* encoding, GenericVector* lengths, int* best_total_length, GenericVector* best_encoding, GenericVector* best_lengths) const { if (str_index > *best_total_length) { // This is the best result so far. *best_total_length = str_index; *best_encoding = *encoding; if (best_lengths != NULL) *best_lengths = *lengths; } if (str_index == str_length) return; int encoding_index = encoding->size(); // Find the length of the first matching unicharset member. int length = ids.minmatch(str + str_index); if (length == 0 || str_index + length > str_length) return; do { if (ids.contains(str + str_index, length)) { // Successful encoding so far. UNICHAR_ID id = ids.unichar_to_id(str + str_index, length); encoding->push_back(id); lengths->push_back(length); encode_string(str, str_index + length, str_length, encoding, lengths, best_total_length, best_encoding, best_lengths); if (*best_total_length == str_length) return; // Tail recursion success! // Failed with that length, truncate back and try again. encoding->truncate(encoding_index); lengths->truncate(encoding_index); } int step = UNICHAR::utf8_step(str + str_index + length); if (step == 0) step = 1; length += step; } while (length <= UNICHAR_LEN && str_index + length <= str_length); } // Gets the properties for a grapheme string, combining properties for // multiple characters in a meaningful way where possible. // Returns false if no valid match was found in the unicharset. // NOTE that script_id, mirror, and other_case refer to this unicharset on // return and will need translation if the target unicharset is different. bool UNICHARSET::GetStrProperties(const char* utf8_str, UNICHAR_PROPERTIES* props) const { props->Init(); props->SetRangesEmpty(); int total_unicodes = 0; GenericVector encoding; if (!encode_string(utf8_str, true, &encoding, NULL, NULL)) return false; // Some part was invalid. for (int i = 0; i < encoding.size(); ++i) { int id = encoding[i]; const UNICHAR_PROPERTIES& src_props = unichars[id].properties; // Logical OR all the bools. if (src_props.isalpha) props->isalpha = true; if (src_props.islower) props->islower = true; if (src_props.isupper) props->isupper = true; if (src_props.isdigit) props->isdigit = true; if (src_props.ispunctuation) props->ispunctuation = true; if (src_props.isngram) props->isngram = true; if (src_props.enabled) props->enabled = true; // Min/max the tops/bottoms. UpdateRange(src_props.min_bottom, &props->min_bottom, &props->max_bottom); UpdateRange(src_props.max_bottom, &props->min_bottom, &props->max_bottom); UpdateRange(src_props.min_top, &props->min_top, &props->max_top); UpdateRange(src_props.max_top, &props->min_top, &props->max_top); float bearing = props->advance + src_props.bearing; if (total_unicodes == 0 || bearing < props->bearing) { props->bearing = bearing; props->bearing_sd = props->advance_sd + src_props.bearing_sd; } props->advance += src_props.advance; props->advance_sd += src_props.advance_sd; // With a single width, just use the widths stored in the unicharset. props->width = src_props.width; props->width_sd = src_props.width_sd; // Use the first script id, other_case, mirror, direction. // Note that these will need translation, except direction. if (total_unicodes == 0) { props->script_id = src_props.script_id; props->other_case = src_props.other_case; props->mirror = src_props.mirror; props->direction = src_props.direction; } // The normed string for the compound character is the concatenation of // the normed versions of the individual characters. props->normed += src_props.normed; ++total_unicodes; } if (total_unicodes > 1) { // Estimate the total widths from the advance - bearing. props->width = props->advance - props->bearing; props->width_sd = props->advance_sd + props->bearing_sd; } return total_unicodes > 0; } // TODO(rays) clean-up the order of functions to match unicharset.h. unsigned int UNICHARSET::get_properties(UNICHAR_ID id) const { unsigned int properties = 0; if (this->get_isalpha(id)) properties |= ISALPHA_MASK; if (this->get_islower(id)) properties |= ISLOWER_MASK; if (this->get_isupper(id)) properties |= ISUPPER_MASK; if (this->get_isdigit(id)) properties |= ISDIGIT_MASK; if (this->get_ispunctuation(id)) properties |= ISPUNCTUATION_MASK; return properties; } char UNICHARSET::get_chartype(UNICHAR_ID id) const { if (this->get_isupper(id)) return 'A'; if (this->get_islower(id)) return 'a'; if (this->get_isalpha(id)) return 'x'; if (this->get_isdigit(id)) return '0'; if (this->get_ispunctuation(id)) return 'p'; return 0; } void UNICHARSET::unichar_insert(const char* const unichar_repr) { if (!ids.contains(unichar_repr)) { if (strlen(unichar_repr) > UNICHAR_LEN) { fprintf(stderr, "Utf8 buffer too big, size=%d for %s\n", int(strlen(unichar_repr)), unichar_repr); return; } if (size_used == size_reserved) { if (size_used == 0) reserve(8); else reserve(2 * size_used); } strcpy(unichars[size_used].representation, unichar_repr); this->set_script(size_used, null_script); // If the given unichar_repr represents a fragmented character, set // fragment property to a pointer to CHAR_FRAGMENT class instance with // information parsed from the unichar representation. Use the script // of the base unichar for the fragmented character if possible. CHAR_FRAGMENT *frag = CHAR_FRAGMENT::parse_from_string(unichar_repr); this->unichars[size_used].properties.fragment = frag; if (frag != NULL && this->contains_unichar(frag->get_unichar())) { this->unichars[size_used].properties.script_id = this->get_script(frag->get_unichar()); } this->unichars[size_used].properties.enabled = true; ids.insert(unichar_repr, size_used); ++size_used; } } bool UNICHARSET::contains_unichar(const char* const unichar_repr) const { return ids.contains(unichar_repr); } bool UNICHARSET::contains_unichar(const char* const unichar_repr, int length) const { if (length == 0) { return false; } return ids.contains(unichar_repr, length); } bool UNICHARSET::eq(UNICHAR_ID unichar_id, const char* const unichar_repr) const { return strcmp(this->id_to_unichar(unichar_id), unichar_repr) == 0; } bool UNICHARSET::save_to_string(STRING *str) const { const int kFileBufSize = 1024; char buffer[kFileBufSize + 1]; snprintf(buffer, kFileBufSize, "%d\n", this->size()); *str = buffer; for (UNICHAR_ID id = 0; id < this->size(); ++id) { int min_bottom, max_bottom, min_top, max_top; get_top_bottom(id, &min_bottom, &max_bottom, &min_top, &max_top); float width, width_sd; get_width_stats(id, &width, &width_sd); float bearing, bearing_sd; get_bearing_stats(id, &bearing, &bearing_sd); float advance, advance_sd; get_advance_stats(id, &advance, &advance_sd); unsigned int properties = this->get_properties(id); if (strcmp(this->id_to_unichar(id), " ") == 0) { snprintf(buffer, kFileBufSize, "%s %x %s %d\n", "NULL", properties, this->get_script_from_script_id(this->get_script(id)), this->get_other_case(id)); } else { snprintf(buffer, kFileBufSize, "%s %x %d,%d,%d,%d,%g,%g,%g,%g,%g,%g %s %d %d %d %s\t# %s\n", this->id_to_unichar(id), properties, min_bottom, max_bottom, min_top, max_top, width, width_sd, bearing, bearing_sd, advance, advance_sd, this->get_script_from_script_id(this->get_script(id)), this->get_other_case(id), this->get_direction(id), this->get_mirror(id), this->get_normed_unichar(id), this->debug_str(id).string()); } *str += buffer; } return true; } // TODO(rays) Replace with TFile everywhere. class InMemoryFilePointer { public: InMemoryFilePointer(const char *memory, int mem_size) : memory_(memory), fgets_ptr_(memory), mem_size_(mem_size) { } char *fgets(char *orig_dst, int size) { const char *src_end = memory_ + mem_size_; char *dst_end = orig_dst + size - 1; if (size < 1) { return fgets_ptr_ < src_end ? orig_dst : NULL; } char *dst = orig_dst; char ch = '^'; while (fgets_ptr_ < src_end && dst < dst_end && ch != '\n') { ch = *dst++ = *fgets_ptr_++; } *dst = 0; return (dst == orig_dst) ? NULL : orig_dst; } private: const char *memory_; const char *fgets_ptr_; const int mem_size_; }; bool UNICHARSET::load_from_inmemory_file( const char *memory, int mem_size, bool skip_fragments) { InMemoryFilePointer mem_fp(memory, mem_size); TessResultCallback2 *fgets_cb = NewPermanentTessCallback(&mem_fp, &InMemoryFilePointer::fgets); bool success = load_via_fgets(fgets_cb, skip_fragments); delete fgets_cb; return success; } class LocalFilePointer { public: LocalFilePointer(FILE *stream) : fp_(stream) {} char *fgets(char *dst, int size) { return ::fgets(dst, size, fp_); } private: FILE *fp_; }; bool UNICHARSET::load_from_file(FILE *file, bool skip_fragments) { LocalFilePointer lfp(file); TessResultCallback2 *fgets_cb = NewPermanentTessCallback(&lfp, &LocalFilePointer::fgets); bool success = load_via_fgets(fgets_cb, skip_fragments); delete fgets_cb; return success; } bool UNICHARSET::load_from_file(tesseract::TFile *file, bool skip_fragments) { TessResultCallback2 *fgets_cb = NewPermanentTessCallback(file, &tesseract::TFile::FGets); bool success = load_via_fgets(fgets_cb, skip_fragments); delete fgets_cb; return success; } bool UNICHARSET::load_via_fgets( TessResultCallback2 *fgets_cb, bool skip_fragments) { int unicharset_size; char buffer[256]; this->clear(); if (fgets_cb->Run(buffer, sizeof(buffer)) == NULL || sscanf(buffer, "%d", &unicharset_size) != 1) { return false; } this->reserve(unicharset_size); for (UNICHAR_ID id = 0; id < unicharset_size; ++id) { char unichar[256]; unsigned int properties; char script[64]; strcpy(script, null_script); int min_bottom = 0; int max_bottom = MAX_UINT8; int min_top = 0; int max_top = MAX_UINT8; float width = 0.0f; float width_sd = 0.0f; float bearing = 0.0f; float bearing_sd = 0.0f; float advance = 0.0f; float advance_sd = 0.0f; // TODO(eger): check that this default it ok // after enabling BiDi iterator for Arabic+Cube. int direction = UNICHARSET::U_LEFT_TO_RIGHT; UNICHAR_ID other_case = id; UNICHAR_ID mirror = id; char normed[64]; int v = -1; if (fgets_cb->Run(buffer, sizeof (buffer)) == NULL || ((v = sscanf(buffer, "%s %x %d,%d,%d,%d,%g,%g,%g,%g,%g,%g %63s %d %d %d %63s", unichar, &properties, &min_bottom, &max_bottom, &min_top, &max_top, &width, &width_sd, &bearing, &bearing_sd, &advance, &advance_sd, script, &other_case, &direction, &mirror, normed)) != 17 && (v = sscanf(buffer, "%s %x %d,%d,%d,%d,%g,%g,%g,%g,%g,%g %63s %d %d %d", unichar, &properties, &min_bottom, &max_bottom, &min_top, &max_top, &width, &width_sd, &bearing, &bearing_sd, &advance, &advance_sd, script, &other_case, &direction, &mirror)) != 16 && (v = sscanf(buffer, "%s %x %d,%d,%d,%d %63s %d %d %d", unichar, &properties, &min_bottom, &max_bottom, &min_top, &max_top, script, &other_case, &direction, &mirror)) != 10 && (v = sscanf(buffer, "%s %x %d,%d,%d,%d %63s %d", unichar, &properties, &min_bottom, &max_bottom, &min_top, &max_top, script, &other_case)) != 8 && (v = sscanf(buffer, "%s %x %63s %d", unichar, &properties, script, &other_case)) != 4 && (v = sscanf(buffer, "%s %x %63s", unichar, &properties, script)) != 3 && (v = sscanf(buffer, "%s %x", unichar, &properties)) != 2)) { return false; } // Skip fragments if needed. CHAR_FRAGMENT *frag = NULL; if (skip_fragments && (frag = CHAR_FRAGMENT::parse_from_string(unichar))) { int num_pieces = frag->get_total(); delete frag; // Skip multi-element fragments, but keep singles like UNICHAR_BROKEN in. if (num_pieces > 1) continue; } // Insert unichar into unicharset and set its properties. if (strcmp(unichar, "NULL") == 0) this->unichar_insert(" "); else this->unichar_insert(unichar); this->set_isalpha(id, properties & ISALPHA_MASK); this->set_islower(id, properties & ISLOWER_MASK); this->set_isupper(id, properties & ISUPPER_MASK); this->set_isdigit(id, properties & ISDIGIT_MASK); this->set_ispunctuation(id, properties & ISPUNCTUATION_MASK); this->set_isngram(id, false); this->set_script(id, script); this->unichars[id].properties.enabled = true; this->set_top_bottom(id, min_bottom, max_bottom, min_top, max_top); this->set_width_stats(id, width, width_sd); this->set_bearing_stats(id, bearing, bearing_sd); this->set_advance_stats(id, advance, advance_sd); this->set_direction(id, static_cast(direction)); ASSERT_HOST(other_case < unicharset_size); this->set_other_case(id, (v>3) ? other_case : id); ASSERT_HOST(mirror < unicharset_size); this->set_mirror(id, (v>8) ? mirror : id); this->set_normed(id, (v>16) ? normed : unichar); } post_load_setup(); return true; } // Sets up internal data after loading the file, based on the char // properties. Called from load_from_file, but also needs to be run // during set_unicharset_properties. void UNICHARSET::post_load_setup() { // Number of alpha chars with the case property minus those without, // in order to determine that half the alpha chars have case. int net_case_alphas = 0; int x_height_alphas = 0; int cap_height_alphas = 0; top_bottom_set_ = false; for (UNICHAR_ID id = 0; id < size_used; ++id) { int min_bottom = 0; int max_bottom = MAX_UINT8; int min_top = 0; int max_top = MAX_UINT8; get_top_bottom(id, &min_bottom, &max_bottom, &min_top, &max_top); if (min_top > 0) top_bottom_set_ = true; if (get_isalpha(id)) { if (get_islower(id) || get_isupper(id)) ++net_case_alphas; else --net_case_alphas; if (min_top < kMeanlineThreshold && max_top < kMeanlineThreshold) ++x_height_alphas; else if (min_top > kMeanlineThreshold && max_top > kMeanlineThreshold) ++cap_height_alphas; } set_normed_ids(id); } script_has_upper_lower_ = net_case_alphas > 0; script_has_xheight_ = script_has_upper_lower_ || (x_height_alphas > cap_height_alphas * kMinXHeightFraction && cap_height_alphas > x_height_alphas * kMinCapHeightFraction); null_sid_ = get_script_id_from_name(null_script); ASSERT_HOST(null_sid_ == 0); common_sid_ = get_script_id_from_name("Common"); latin_sid_ = get_script_id_from_name("Latin"); cyrillic_sid_ = get_script_id_from_name("Cyrillic"); greek_sid_ = get_script_id_from_name("Greek"); han_sid_ = get_script_id_from_name("Han"); hiragana_sid_ = get_script_id_from_name("Hiragana"); katakana_sid_ = get_script_id_from_name("Katakana"); // Compute default script. Use the highest-counting alpha script, that is // not the common script, as that still contains some "alphas". int* script_counts = new int[script_table_size_used]; memset(script_counts, 0, sizeof(*script_counts) * script_table_size_used); for (int id = 0; id < size_used; ++id) { if (get_isalpha(id)) { ++script_counts[get_script(id)]; } } default_sid_ = 0; for (int s = 1; s < script_table_size_used; ++s) { if (script_counts[s] > script_counts[default_sid_] && s != common_sid_) default_sid_ = s; } delete [] script_counts; } // Returns true if right_to_left scripts are significant in the unicharset, // but without being so sensitive that "universal" unicharsets containing // characters from many scripts, like orientation and script detection, // look like they are right_to_left. bool UNICHARSET::major_right_to_left() const { int ltr_count = 0; int rtl_count = 0; for (int id = 0; id < size_used; ++id) { int dir = get_direction(id); if (dir == UNICHARSET::U_LEFT_TO_RIGHT) ltr_count++; if (dir == UNICHARSET::U_RIGHT_TO_LEFT || dir == UNICHARSET::U_RIGHT_TO_LEFT_ARABIC || dir == UNICHARSET::U_ARABIC_NUMBER) rtl_count++; } return rtl_count > ltr_count; } // Set a whitelist and/or blacklist of characters to recognize. // An empty or NULL whitelist enables everything (minus any blacklist). // An empty or NULL blacklist disables nothing. // An empty or NULL blacklist has no effect. void UNICHARSET::set_black_and_whitelist(const char* blacklist, const char* whitelist, const char* unblacklist) { bool def_enabled = whitelist == NULL || whitelist[0] == '\0'; // Set everything to default for (int ch = 0; ch < size_used; ++ch) unichars[ch].properties.enabled = def_enabled; if (!def_enabled) { // Enable the whitelist. GenericVector encoding; encode_string(whitelist, false, &encoding, NULL, NULL); for (int i = 0; i < encoding.size(); ++i) { if (encoding[i] != INVALID_UNICHAR_ID) unichars[encoding[i]].properties.enabled = true; } } if (blacklist != NULL && blacklist[0] != '\0') { // Disable the blacklist. GenericVector encoding; encode_string(blacklist, false, &encoding, NULL, NULL); for (int i = 0; i < encoding.size(); ++i) { if (encoding[i] != INVALID_UNICHAR_ID) unichars[encoding[i]].properties.enabled = false; } } if (unblacklist != NULL && unblacklist[0] != '\0') { // Re-enable the unblacklist. GenericVector encoding; encode_string(unblacklist, false, &encoding, NULL, NULL); for (int i = 0; i < encoding.size(); ++i) { if (encoding[i] != INVALID_UNICHAR_ID) unichars[encoding[i]].properties.enabled = true; } } } // Returns true if there are any repeated unicodes in the normalized // text of any unichar-id in the unicharset. bool UNICHARSET::AnyRepeatedUnicodes() const { int start_id = 0; if (has_special_codes()) start_id = SPECIAL_UNICHAR_CODES_COUNT; for (int id = start_id; id < size_used; ++id) { // Convert to unicodes. GenericVector unicodes; if (UNICHAR::UTF8ToUnicode(get_normed_unichar(id), &unicodes) && unicodes.size() > 1) { for (int u = 1; u < unicodes.size(); ++u) { if (unicodes[u - 1] == unicodes[u]) return true; } } } return false; } int UNICHARSET::add_script(const char* script) { for (int i = 0; i < script_table_size_used; ++i) { if (strcmp(script, script_table[i]) == 0) return i; } if (script_table_size_reserved == 0) { script_table_size_reserved = 8; script_table = new char*[script_table_size_reserved]; } if (script_table_size_used + 1 >= script_table_size_reserved) { char** new_script_table = new char*[script_table_size_reserved * 2]; memcpy(new_script_table, script_table, script_table_size_reserved * sizeof(char*)); delete[] script_table; script_table = new_script_table; script_table_size_reserved = 2 * script_table_size_reserved; } script_table[script_table_size_used] = new char[strlen(script) + 1]; strcpy(script_table[script_table_size_used], script); return script_table_size_used++; } // Returns the string that represents a fragment // with the given unichar, pos and total. STRING CHAR_FRAGMENT::to_string(const char *unichar, int pos, int total, bool natural) { if (total == 1) return STRING(unichar); STRING result = ""; result += kSeparator; result += unichar; char buffer[kMaxLen]; snprintf(buffer, kMaxLen, "%c%d%c%d", kSeparator, pos, natural ? kNaturalFlag : kSeparator, total); result += buffer; return result; } CHAR_FRAGMENT *CHAR_FRAGMENT::parse_from_string(const char *string) { const char *ptr = string; int len = strlen(string); if (len < kMinLen || *ptr != kSeparator) { return NULL; // this string can not represent a fragment } ptr++; // move to the next character int step = 0; while ((ptr + step) < (string + len) && *(ptr + step) != kSeparator) { step += UNICHAR::utf8_step(ptr + step); } if (step == 0 || step > UNICHAR_LEN) { return NULL; // no character for unichar or the character is too long } char unichar[UNICHAR_LEN + 1]; strncpy(unichar, ptr, step); unichar[step] = '\0'; // null terminate unichar ptr += step; // move to the next fragment separator int pos = 0; int total = 0; bool natural = false; char *end_ptr = NULL; for (int i = 0; i < 2; i++) { if (ptr > string + len || *ptr != kSeparator) { if (i == 1 && *ptr == kNaturalFlag) natural = true; else return NULL; // Failed to parse fragment representation. } ptr++; // move to the next character i == 0 ? pos = static_cast(strtol(ptr, &end_ptr, 10)) : total = static_cast(strtol(ptr, &end_ptr, 10)); ptr = end_ptr; } if (ptr != string + len) { return NULL; // malformed fragment representation } CHAR_FRAGMENT *fragment = new CHAR_FRAGMENT(); fragment->set_all(unichar, pos, total, natural); return fragment; } int UNICHARSET::get_script_id_from_name(const char* script_name) const { for (int i = 0; i < script_table_size_used; ++i) { if (strcmp(script_name, script_table[i]) == 0) return i; } return 0; // 0 is always the null_script }