/* ***** BEGIN LICENSE BLOCK ***** * Version: MPL 1.1/GPL 2.0/LGPL 2.1 * * Copyright (C) 2002-2017 Németh László * * The contents of this file are subject to the Mozilla Public License Version * 1.1 (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.mozilla.org/MPL/ * * Software distributed under the License is distributed on an "AS IS" basis, * WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License * for the specific language governing rights and limitations under the * License. * * Hunspell is based on MySpell which is Copyright (C) 2002 Kevin Hendricks. * * Contributor(s): David Einstein, Davide Prina, Giuseppe Modugno, * Gianluca Turconi, Simon Brouwer, Noll János, Bíró Árpád, * Goldman Eleonóra, Sarlós Tamás, Bencsáth Boldizsár, Halácsy Péter, * Dvornik László, Gefferth András, Nagy Viktor, Varga Dániel, Chris Halls, * Rene Engelhard, Bram Moolenaar, Dafydd Jones, Harri Pitkänen * * Alternatively, the contents of this file may be used under the terms of * either the GNU General Public License Version 2 or later (the "GPL"), or * the GNU Lesser General Public License Version 2.1 or later (the "LGPL"), * in which case the provisions of the GPL or the LGPL are applicable instead * of those above. If you wish to allow use of your version of this file only * under the terms of either the GPL or the LGPL, and not to allow others to * use your version of this file under the terms of the MPL, indicate your * decision by deleting the provisions above and replace them with the notice * and other provisions required by the GPL or the LGPL. If you do not delete * the provisions above, a recipient may use your version of this file under * the terms of any one of the MPL, the GPL or the LGPL. * * ***** END LICENSE BLOCK ***** */ /* * Copyright 2002 Kevin B. Hendricks, Stratford, Ontario, Canada * And Contributors. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * 3. All modifications to the source code must be clearly marked as * such. Binary redistributions based on modified source code * must be clearly marked as modified versions in the documentation * and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY KEVIN B. HENDRICKS AND CONTRIBUTORS * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL * KEVIN B. HENDRICKS OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include #include #include #include #include #include #include #include #include #include "affixmgr.hxx" #include "affentry.hxx" #include "langnum.hxx" #include "csutil.hxx" AffixMgr::AffixMgr(const char* affpath, const std::vector& ptr, const char* key) : alldic(ptr) , pHMgr(ptr[0]) { // register hash manager and load affix data from aff file csconv = NULL; utf8 = 0; complexprefixes = 0; parsedmaptable = false; parsedbreaktable = false; iconvtable = NULL; oconvtable = NULL; // allow simplified compound forms (see 3rd field of CHECKCOMPOUNDPATTERN) simplifiedcpd = 0; parsedcheckcpd = false; parseddefcpd = false; phone = NULL; compoundflag = FLAG_NULL; // permits word in compound forms compoundbegin = FLAG_NULL; // may be first word in compound forms compoundmiddle = FLAG_NULL; // may be middle word in compound forms compoundend = FLAG_NULL; // may be last word in compound forms compoundroot = FLAG_NULL; // compound word signing flag compoundpermitflag = FLAG_NULL; // compound permitting flag for suffixed word compoundforbidflag = FLAG_NULL; // compound fordidden flag for suffixed word compoundmoresuffixes = 0; // allow more suffixes within compound words checkcompounddup = 0; // forbid double words in compounds checkcompoundrep = 0; // forbid bad compounds (may be non-compound word with // a REP substitution) checkcompoundcase = 0; // forbid upper and lowercase combinations at word bounds checkcompoundtriple = 0; // forbid compounds with triple letters simplifiedtriple = 0; // allow simplified triple letters in compounds // (Schiff+fahrt -> Schiffahrt) forbiddenword = FORBIDDENWORD; // forbidden word signing flag nosuggest = FLAG_NULL; // don't suggest words signed with NOSUGGEST flag nongramsuggest = FLAG_NULL; langnum = 0; // language code (see http://l10n.openoffice.org/languages.html) needaffix = FLAG_NULL; // forbidden root, allowed only with suffixes cpdwordmax = -1; // default: unlimited wordcount in compound words cpdmin = -1; // undefined cpdmaxsyllable = 0; // default: unlimited syllablecount in compound words pfxappnd = NULL; // previous prefix for counting syllables of the prefix BUG sfxappnd = NULL; // previous suffix for counting syllables of the suffix BUG sfxextra = 0; // modifier for syllable count of sfxappnd BUG checknum = 0; // checking numbers, and word with numbers havecontclass = 0; // flags of possible continuing classes (double affix) // LEMMA_PRESENT: not put root into the morphological output. Lemma presents // in morhological description in dictionary file. It's often combined with // PSEUDOROOT. lemma_present = FLAG_NULL; circumfix = FLAG_NULL; onlyincompound = FLAG_NULL; maxngramsugs = -1; // undefined maxdiff = -1; // undefined onlymaxdiff = 0; maxcpdsugs = -1; // undefined nosplitsugs = 0; sugswithdots = 0; keepcase = 0; forceucase = 0; warn = 0; forbidwarn = 0; checksharps = 0; substandard = FLAG_NULL; fullstrip = 0; sfx = NULL; pfx = NULL; for (int i = 0; i < SETSIZE; i++) { pStart[i] = NULL; sStart[i] = NULL; pFlag[i] = NULL; sFlag[i] = NULL; } for (int j = 0; j < CONTSIZE; j++) { contclasses[j] = 0; } if (parse_file(affpath, key)) { HUNSPELL_WARNING(stderr, "Failure loading aff file %s\n", affpath); } if (cpdmin == -1) cpdmin = MINCPDLEN; } AffixMgr::~AffixMgr() { // pass through linked prefix entries and clean up for (int i = 0; i < SETSIZE; i++) { pFlag[i] = NULL; PfxEntry* ptr = pStart[i]; PfxEntry* nptr = NULL; while (ptr) { nptr = ptr->getNext(); delete (ptr); ptr = nptr; nptr = NULL; } } // pass through linked suffix entries and clean up for (int j = 0; j < SETSIZE; j++) { sFlag[j] = NULL; SfxEntry* ptr = sStart[j]; SfxEntry* nptr = NULL; while (ptr) { nptr = ptr->getNext(); delete (ptr); ptr = nptr; nptr = NULL; } sStart[j] = NULL; } delete iconvtable; delete oconvtable; delete phone; FREE_FLAG(compoundflag); FREE_FLAG(compoundbegin); FREE_FLAG(compoundmiddle); FREE_FLAG(compoundend); FREE_FLAG(compoundpermitflag); FREE_FLAG(compoundforbidflag); FREE_FLAG(compoundroot); FREE_FLAG(forbiddenword); FREE_FLAG(nosuggest); FREE_FLAG(nongramsuggest); FREE_FLAG(needaffix); FREE_FLAG(lemma_present); FREE_FLAG(circumfix); FREE_FLAG(onlyincompound); cpdwordmax = 0; pHMgr = NULL; cpdmin = 0; cpdmaxsyllable = 0; free_utf_tbl(); checknum = 0; #ifdef MOZILLA_CLIENT delete[] csconv; #endif } void AffixMgr::finishFileMgr(FileMgr* afflst) { delete afflst; // convert affix trees to sorted list process_pfx_tree_to_list(); process_sfx_tree_to_list(); } // read in aff file and build up prefix and suffix entry objects int AffixMgr::parse_file(const char* affpath, const char* key) { // checking flag duplication char dupflags[CONTSIZE]; char dupflags_ini = 1; // first line indicator for removing byte order mark int firstline = 1; // open the affix file FileMgr* afflst = new FileMgr(affpath, key); if (!afflst) { HUNSPELL_WARNING( stderr, "error: could not open affix description file %s\n", affpath); return 1; } // step one is to parse the affix file building up the internal // affix data structures // read in each line ignoring any that do not // start with a known line type indicator std::string line; while (afflst->getline(line)) { mychomp(line); /* remove byte order mark */ if (firstline) { firstline = 0; // Affix file begins with byte order mark: possible incompatibility with // old Hunspell versions if (line.compare(0, 3, "\xEF\xBB\xBF", 3) == 0) { line.erase(0, 3); } } /* parse in the keyboard string */ if (line.compare(0, 3, "KEY", 3) == 0) { if (!parse_string(line, keystring, afflst->getlinenum())) { finishFileMgr(afflst); return 1; } } /* parse in the try string */ if (line.compare(0, 3, "TRY", 3) == 0) { if (!parse_string(line, trystring, afflst->getlinenum())) { finishFileMgr(afflst); return 1; } } /* parse in the name of the character set used by the .dict and .aff */ if (line.compare(0, 3, "SET", 3) == 0) { if (!parse_string(line, encoding, afflst->getlinenum())) { finishFileMgr(afflst); return 1; } if (encoding == "UTF-8") { utf8 = 1; #ifndef OPENOFFICEORG #ifndef MOZILLA_CLIENT initialize_utf_tbl(); #endif #endif } } /* parse COMPLEXPREFIXES for agglutinative languages with right-to-left * writing system */ if (line.compare(0, 15, "COMPLEXPREFIXES", 15) == 0) complexprefixes = 1; /* parse in the flag used by the controlled compound words */ if (line.compare(0, 12, "COMPOUNDFLAG", 12) == 0) { if (!parse_flag(line, &compoundflag, afflst)) { finishFileMgr(afflst); return 1; } } /* parse in the flag used by compound words */ if (line.compare(0, 13, "COMPOUNDBEGIN", 13) == 0) { if (complexprefixes) { if (!parse_flag(line, &compoundend, afflst)) { finishFileMgr(afflst); return 1; } } else { if (!parse_flag(line, &compoundbegin, afflst)) { finishFileMgr(afflst); return 1; } } } /* parse in the flag used by compound words */ if (line.compare(0, 14, "COMPOUNDMIDDLE", 14) == 0) { if (!parse_flag(line, &compoundmiddle, afflst)) { finishFileMgr(afflst); return 1; } } /* parse in the flag used by compound words */ if (line.compare(0, 11, "COMPOUNDEND", 11) == 0) { if (complexprefixes) { if (!parse_flag(line, &compoundbegin, afflst)) { finishFileMgr(afflst); return 1; } } else { if (!parse_flag(line, &compoundend, afflst)) { finishFileMgr(afflst); return 1; } } } /* parse in the data used by compound_check() method */ if (line.compare(0, 15, "COMPOUNDWORDMAX", 15) == 0) { if (!parse_num(line, &cpdwordmax, afflst)) { finishFileMgr(afflst); return 1; } } /* parse in the flag sign compounds in dictionary */ if (line.compare(0, 12, "COMPOUNDROOT", 12) == 0) { if (!parse_flag(line, &compoundroot, afflst)) { finishFileMgr(afflst); return 1; } } /* parse in the flag used by compound_check() method */ if (line.compare(0, 18, "COMPOUNDPERMITFLAG", 18) == 0) { if (!parse_flag(line, &compoundpermitflag, afflst)) { finishFileMgr(afflst); return 1; } } /* parse in the flag used by compound_check() method */ if (line.compare(0, 18, "COMPOUNDFORBIDFLAG", 18) == 0) { if (!parse_flag(line, &compoundforbidflag, afflst)) { finishFileMgr(afflst); return 1; } } if (line.compare(0, 20, "COMPOUNDMORESUFFIXES", 20) == 0) { compoundmoresuffixes = 1; } if (line.compare(0, 16, "CHECKCOMPOUNDDUP", 16) == 0) { checkcompounddup = 1; } if (line.compare(0, 16, "CHECKCOMPOUNDREP", 16) == 0) { checkcompoundrep = 1; } if (line.compare(0, 19, "CHECKCOMPOUNDTRIPLE", 19) == 0) { checkcompoundtriple = 1; } if (line.compare(0, 16, "SIMPLIFIEDTRIPLE", 16) == 0) { simplifiedtriple = 1; } if (line.compare(0, 17, "CHECKCOMPOUNDCASE", 17) == 0) { checkcompoundcase = 1; } if (line.compare(0, 9, "NOSUGGEST", 9) == 0) { if (!parse_flag(line, &nosuggest, afflst)) { finishFileMgr(afflst); return 1; } } if (line.compare(0, 14, "NONGRAMSUGGEST", 14) == 0) { if (!parse_flag(line, &nongramsuggest, afflst)) { finishFileMgr(afflst); return 1; } } /* parse in the flag used by forbidden words */ if (line.compare(0, 13, "FORBIDDENWORD", 13) == 0) { if (!parse_flag(line, &forbiddenword, afflst)) { finishFileMgr(afflst); return 1; } } /* parse in the flag used by forbidden words (is deprecated) */ if (line.compare(0, 13, "LEMMA_PRESENT", 13) == 0) { if (!parse_flag(line, &lemma_present, afflst)) { finishFileMgr(afflst); return 1; } } /* parse in the flag used by circumfixes */ if (line.compare(0, 9, "CIRCUMFIX", 9) == 0) { if (!parse_flag(line, &circumfix, afflst)) { finishFileMgr(afflst); return 1; } } /* parse in the flag used by fogemorphemes */ if (line.compare(0, 14, "ONLYINCOMPOUND", 14) == 0) { if (!parse_flag(line, &onlyincompound, afflst)) { finishFileMgr(afflst); return 1; } } /* parse in the flag used by `needaffixs' (is deprecated) */ if (line.compare(0, 10, "PSEUDOROOT", 10) == 0) { if (!parse_flag(line, &needaffix, afflst)) { finishFileMgr(afflst); return 1; } } /* parse in the flag used by `needaffixs' */ if (line.compare(0, 9, "NEEDAFFIX", 9) == 0) { if (!parse_flag(line, &needaffix, afflst)) { finishFileMgr(afflst); return 1; } } /* parse in the minimal length for words in compounds */ if (line.compare(0, 11, "COMPOUNDMIN", 11) == 0) { if (!parse_num(line, &cpdmin, afflst)) { finishFileMgr(afflst); return 1; } if (cpdmin < 1) cpdmin = 1; } /* parse in the max. words and syllables in compounds */ if (line.compare(0, 16, "COMPOUNDSYLLABLE", 16) == 0) { if (!parse_cpdsyllable(line, afflst)) { finishFileMgr(afflst); return 1; } } /* parse in the flag used by compound_check() method */ if (line.compare(0, 11, "SYLLABLENUM", 11) == 0) { if (!parse_string(line, cpdsyllablenum, afflst->getlinenum())) { finishFileMgr(afflst); return 1; } } /* parse in the flag used by the controlled compound words */ if (line.compare(0, 8, "CHECKNUM", 8) == 0) { checknum = 1; } /* parse in the extra word characters */ if (line.compare(0, 9, "WORDCHARS", 9) == 0) { if (!parse_array(line, wordchars, wordchars_utf16, utf8, afflst->getlinenum())) { finishFileMgr(afflst); return 1; } } /* parse in the ignored characters (for example, Arabic optional diacretics * charachters */ if (line.compare(0, 6, "IGNORE", 6) == 0) { if (!parse_array(line, ignorechars, ignorechars_utf16, utf8, afflst->getlinenum())) { finishFileMgr(afflst); return 1; } } /* parse in the input conversion table */ if (line.compare(0, 5, "ICONV", 5) == 0) { if (!parse_convtable(line, afflst, &iconvtable, "ICONV")) { finishFileMgr(afflst); return 1; } } /* parse in the output conversion table */ if (line.compare(0, 5, "OCONV", 5) == 0) { if (!parse_convtable(line, afflst, &oconvtable, "OCONV")) { finishFileMgr(afflst); return 1; } } /* parse in the phonetic translation table */ if (line.compare(0, 5, "PHONE", 5) == 0) { if (!parse_phonetable(line, afflst)) { finishFileMgr(afflst); return 1; } } /* parse in the checkcompoundpattern table */ if (line.compare(0, 20, "CHECKCOMPOUNDPATTERN", 20) == 0) { if (!parse_checkcpdtable(line, afflst)) { finishFileMgr(afflst); return 1; } } /* parse in the defcompound table */ if (line.compare(0, 12, "COMPOUNDRULE", 12) == 0) { if (!parse_defcpdtable(line, afflst)) { finishFileMgr(afflst); return 1; } } /* parse in the related character map table */ if (line.compare(0, 3, "MAP", 3) == 0) { if (!parse_maptable(line, afflst)) { finishFileMgr(afflst); return 1; } } /* parse in the word breakpoints table */ if (line.compare(0, 5, "BREAK", 5) == 0) { if (!parse_breaktable(line, afflst)) { finishFileMgr(afflst); return 1; } } /* parse in the language for language specific codes */ if (line.compare(0, 4, "LANG", 4) == 0) { if (!parse_string(line, lang, afflst->getlinenum())) { finishFileMgr(afflst); return 1; } langnum = get_lang_num(lang); } if (line.compare(0, 7, "VERSION", 7) == 0) { size_t startpos = line.find_first_not_of(" \t", 7); if (startpos != std::string::npos) { version = line.substr(startpos); } } if (line.compare(0, 12, "MAXNGRAMSUGS", 12) == 0) { if (!parse_num(line, &maxngramsugs, afflst)) { finishFileMgr(afflst); return 1; } } if (line.compare(0, 11, "ONLYMAXDIFF", 11) == 0) onlymaxdiff = 1; if (line.compare(0, 7, "MAXDIFF", 7) == 0) { if (!parse_num(line, &maxdiff, afflst)) { finishFileMgr(afflst); return 1; } } if (line.compare(0, 10, "MAXCPDSUGS", 10) == 0) { if (!parse_num(line, &maxcpdsugs, afflst)) { finishFileMgr(afflst); return 1; } } if (line.compare(0, 11, "NOSPLITSUGS", 11) == 0) { nosplitsugs = 1; } if (line.compare(0, 9, "FULLSTRIP", 9) == 0) { fullstrip = 1; } if (line.compare(0, 12, "SUGSWITHDOTS", 12) == 0) { sugswithdots = 1; } /* parse in the flag used by forbidden words */ if (line.compare(0, 8, "KEEPCASE", 8) == 0) { if (!parse_flag(line, &keepcase, afflst)) { finishFileMgr(afflst); return 1; } } /* parse in the flag used by `forceucase' */ if (line.compare(0, 10, "FORCEUCASE", 10) == 0) { if (!parse_flag(line, &forceucase, afflst)) { finishFileMgr(afflst); return 1; } } /* parse in the flag used by `warn' */ if (line.compare(0, 4, "WARN", 4) == 0) { if (!parse_flag(line, &warn, afflst)) { finishFileMgr(afflst); return 1; } } if (line.compare(0, 10, "FORBIDWARN", 10) == 0) { forbidwarn = 1; } /* parse in the flag used by the affix generator */ if (line.compare(0, 11, "SUBSTANDARD", 11) == 0) { if (!parse_flag(line, &substandard, afflst)) { finishFileMgr(afflst); return 1; } } if (line.compare(0, 11, "CHECKSHARPS", 11) == 0) { checksharps = 1; } /* parse this affix: P - prefix, S - suffix */ // affix type char ft = ' '; if (line.compare(0, 3, "PFX", 3) == 0) ft = complexprefixes ? 'S' : 'P'; if (line.compare(0, 3, "SFX", 3) == 0) ft = complexprefixes ? 'P' : 'S'; if (ft != ' ') { if (dupflags_ini) { memset(dupflags, 0, sizeof(dupflags)); dupflags_ini = 0; } if (!parse_affix(line, ft, afflst, dupflags)) { finishFileMgr(afflst); return 1; } } } finishFileMgr(afflst); // affix trees are sorted now // now we can speed up performance greatly taking advantage of the // relationship between the affixes and the idea of "subsets". // View each prefix as a potential leading subset of another and view // each suffix (reversed) as a potential trailing subset of another. // To illustrate this relationship if we know the prefix "ab" is found in the // word to examine, only prefixes that "ab" is a leading subset of need be // examined. // Furthermore is "ab" is not present then none of the prefixes that "ab" is // is a subset need be examined. // The same argument goes for suffix string that are reversed. // Then to top this off why not examine the first char of the word to quickly // limit the set of prefixes to examine (i.e. the prefixes to examine must // be leading supersets of the first character of the word (if they exist) // To take advantage of this "subset" relationship, we need to add two links // from entry. One to take next if the current prefix is found (call it // nexteq) // and one to take next if the current prefix is not found (call it nextne). // Since we have built ordered lists, all that remains is to properly // initialize // the nextne and nexteq pointers that relate them process_pfx_order(); process_sfx_order(); /* get encoding for CHECKCOMPOUNDCASE */ if (!utf8) { csconv = get_current_cs(get_encoding()); for (int i = 0; i <= 255; i++) { if ((csconv[i].cupper != csconv[i].clower) && (wordchars.find((char)i) == std::string::npos)) { wordchars.push_back((char)i); } } } // default BREAK definition if (!parsedbreaktable) { breaktable.push_back("-"); breaktable.push_back("^-"); breaktable.push_back("-$"); parsedbreaktable = true; } return 0; } // we want to be able to quickly access prefix information // both by prefix flag, and sorted by prefix string itself // so we need to set up two indexes int AffixMgr::build_pfxtree(PfxEntry* pfxptr) { PfxEntry* ptr; PfxEntry* pptr; PfxEntry* ep = pfxptr; // get the right starting points const char* key = ep->getKey(); const unsigned char flg = (unsigned char)(ep->getFlag() & 0x00FF); // first index by flag which must exist ptr = pFlag[flg]; ep->setFlgNxt(ptr); pFlag[flg] = ep; // handle the special case of null affix string if (strlen(key) == 0) { // always inset them at head of list at element 0 ptr = pStart[0]; ep->setNext(ptr); pStart[0] = ep; return 0; } // now handle the normal case ep->setNextEQ(NULL); ep->setNextNE(NULL); unsigned char sp = *((const unsigned char*)key); ptr = pStart[sp]; // handle the first insert if (!ptr) { pStart[sp] = ep; return 0; } // otherwise use binary tree insertion so that a sorted // list can easily be generated later pptr = NULL; for (;;) { pptr = ptr; if (strcmp(ep->getKey(), ptr->getKey()) <= 0) { ptr = ptr->getNextEQ(); if (!ptr) { pptr->setNextEQ(ep); break; } } else { ptr = ptr->getNextNE(); if (!ptr) { pptr->setNextNE(ep); break; } } } return 0; } // we want to be able to quickly access suffix information // both by suffix flag, and sorted by the reverse of the // suffix string itself; so we need to set up two indexes int AffixMgr::build_sfxtree(SfxEntry* sfxptr) { sfxptr->initReverseWord(); SfxEntry* ptr; SfxEntry* pptr; SfxEntry* ep = sfxptr; /* get the right starting point */ const char* key = ep->getKey(); const unsigned char flg = (unsigned char)(ep->getFlag() & 0x00FF); // first index by flag which must exist ptr = sFlag[flg]; ep->setFlgNxt(ptr); sFlag[flg] = ep; // next index by affix string // handle the special case of null affix string if (strlen(key) == 0) { // always inset them at head of list at element 0 ptr = sStart[0]; ep->setNext(ptr); sStart[0] = ep; return 0; } // now handle the normal case ep->setNextEQ(NULL); ep->setNextNE(NULL); unsigned char sp = *((const unsigned char*)key); ptr = sStart[sp]; // handle the first insert if (!ptr) { sStart[sp] = ep; return 0; } // otherwise use binary tree insertion so that a sorted // list can easily be generated later pptr = NULL; for (;;) { pptr = ptr; if (strcmp(ep->getKey(), ptr->getKey()) <= 0) { ptr = ptr->getNextEQ(); if (!ptr) { pptr->setNextEQ(ep); break; } } else { ptr = ptr->getNextNE(); if (!ptr) { pptr->setNextNE(ep); break; } } } return 0; } // convert from binary tree to sorted list int AffixMgr::process_pfx_tree_to_list() { for (int i = 1; i < SETSIZE; i++) { pStart[i] = process_pfx_in_order(pStart[i], NULL); } return 0; } PfxEntry* AffixMgr::process_pfx_in_order(PfxEntry* ptr, PfxEntry* nptr) { if (ptr) { nptr = process_pfx_in_order(ptr->getNextNE(), nptr); ptr->setNext(nptr); nptr = process_pfx_in_order(ptr->getNextEQ(), ptr); } return nptr; } // convert from binary tree to sorted list int AffixMgr::process_sfx_tree_to_list() { for (int i = 1; i < SETSIZE; i++) { sStart[i] = process_sfx_in_order(sStart[i], NULL); } return 0; } SfxEntry* AffixMgr::process_sfx_in_order(SfxEntry* ptr, SfxEntry* nptr) { if (ptr) { nptr = process_sfx_in_order(ptr->getNextNE(), nptr); ptr->setNext(nptr); nptr = process_sfx_in_order(ptr->getNextEQ(), ptr); } return nptr; } // reinitialize the PfxEntry links NextEQ and NextNE to speed searching // using the idea of leading subsets this time int AffixMgr::process_pfx_order() { PfxEntry* ptr; // loop through each prefix list starting point for (int i = 1; i < SETSIZE; i++) { ptr = pStart[i]; // look through the remainder of the list // and find next entry with affix that // the current one is not a subset of // mark that as destination for NextNE // use next in list that you are a subset // of as NextEQ for (; ptr != NULL; ptr = ptr->getNext()) { PfxEntry* nptr = ptr->getNext(); for (; nptr != NULL; nptr = nptr->getNext()) { if (!isSubset(ptr->getKey(), nptr->getKey())) break; } ptr->setNextNE(nptr); ptr->setNextEQ(NULL); if ((ptr->getNext()) && isSubset(ptr->getKey(), (ptr->getNext())->getKey())) ptr->setNextEQ(ptr->getNext()); } // now clean up by adding smart search termination strings: // if you are already a superset of the previous prefix // but not a subset of the next, search can end here // so set NextNE properly ptr = pStart[i]; for (; ptr != NULL; ptr = ptr->getNext()) { PfxEntry* nptr = ptr->getNext(); PfxEntry* mptr = NULL; for (; nptr != NULL; nptr = nptr->getNext()) { if (!isSubset(ptr->getKey(), nptr->getKey())) break; mptr = nptr; } if (mptr) mptr->setNextNE(NULL); } } return 0; } // initialize the SfxEntry links NextEQ and NextNE to speed searching // using the idea of leading subsets this time int AffixMgr::process_sfx_order() { SfxEntry* ptr; // loop through each prefix list starting point for (int i = 1; i < SETSIZE; i++) { ptr = sStart[i]; // look through the remainder of the list // and find next entry with affix that // the current one is not a subset of // mark that as destination for NextNE // use next in list that you are a subset // of as NextEQ for (; ptr != NULL; ptr = ptr->getNext()) { SfxEntry* nptr = ptr->getNext(); for (; nptr != NULL; nptr = nptr->getNext()) { if (!isSubset(ptr->getKey(), nptr->getKey())) break; } ptr->setNextNE(nptr); ptr->setNextEQ(NULL); if ((ptr->getNext()) && isSubset(ptr->getKey(), (ptr->getNext())->getKey())) ptr->setNextEQ(ptr->getNext()); } // now clean up by adding smart search termination strings: // if you are already a superset of the previous suffix // but not a subset of the next, search can end here // so set NextNE properly ptr = sStart[i]; for (; ptr != NULL; ptr = ptr->getNext()) { SfxEntry* nptr = ptr->getNext(); SfxEntry* mptr = NULL; for (; nptr != NULL; nptr = nptr->getNext()) { if (!isSubset(ptr->getKey(), nptr->getKey())) break; mptr = nptr; } if (mptr) mptr->setNextNE(NULL); } } return 0; } // add flags to the result for dictionary debugging std::string& AffixMgr::debugflag(std::string& result, unsigned short flag) { char* st = encode_flag(flag); result.push_back(MSEP_FLD); result.append(MORPH_FLAG); if (st) { result.append(st); free(st); } return result; } // calculate the character length of the condition int AffixMgr::condlen(const char* st) { int l = 0; bool group = false; for (; *st; st++) { if (*st == '[') { group = true; l++; } else if (*st == ']') group = false; else if (!group && (!utf8 || (!(*st & 0x80) || ((*st & 0xc0) == 0x80)))) l++; } return l; } int AffixMgr::encodeit(AffEntry& entry, const char* cs) { if (strcmp(cs, ".") != 0) { entry.numconds = (char)condlen(cs); const size_t cslen = strlen(cs); const size_t short_part = std::min(MAXCONDLEN, cslen); memcpy(entry.c.conds, cs, short_part); if (short_part < MAXCONDLEN) { //blank out the remaining space memset(entry.c.conds + short_part, 0, MAXCONDLEN - short_part); } else if (cs[MAXCONDLEN]) { //there is more conditions than fit in fixed space, so its //a long condition entry.opts += aeLONGCOND; entry.c.l.conds2 = mystrdup(cs + MAXCONDLEN_1); if (!entry.c.l.conds2) return 1; } } else { entry.numconds = 0; entry.c.conds[0] = '\0'; } return 0; } // return 1 if s1 is a leading subset of s2 (dots are for infixes) inline int AffixMgr::isSubset(const char* s1, const char* s2) { while (((*s1 == *s2) || (*s1 == '.')) && (*s1 != '\0')) { s1++; s2++; } return (*s1 == '\0'); } // check word for prefixes struct hentry* AffixMgr::prefix_check(const char* word, int len, char in_compound, const FLAG needflag) { struct hentry* rv = NULL; pfx = NULL; pfxappnd = NULL; sfxappnd = NULL; sfxextra = 0; // first handle the special case of 0 length prefixes PfxEntry* pe = pStart[0]; while (pe) { if ( // fogemorpheme ((in_compound != IN_CPD_NOT) || !(pe->getCont() && (TESTAFF(pe->getCont(), onlyincompound, pe->getContLen())))) && // permit prefixes in compounds ((in_compound != IN_CPD_END) || (pe->getCont() && (TESTAFF(pe->getCont(), compoundpermitflag, pe->getContLen()))))) { // check prefix rv = pe->checkword(word, len, in_compound, needflag); if (rv) { pfx = pe; // BUG: pfx not stateless return rv; } } pe = pe->getNext(); } // now handle the general case unsigned char sp = *((const unsigned char*)word); PfxEntry* pptr = pStart[sp]; while (pptr) { if (isSubset(pptr->getKey(), word)) { if ( // fogemorpheme ((in_compound != IN_CPD_NOT) || !(pptr->getCont() && (TESTAFF(pptr->getCont(), onlyincompound, pptr->getContLen())))) && // permit prefixes in compounds ((in_compound != IN_CPD_END) || (pptr->getCont() && (TESTAFF(pptr->getCont(), compoundpermitflag, pptr->getContLen()))))) { // check prefix rv = pptr->checkword(word, len, in_compound, needflag); if (rv) { pfx = pptr; // BUG: pfx not stateless return rv; } } pptr = pptr->getNextEQ(); } else { pptr = pptr->getNextNE(); } } return NULL; } // check word for prefixes and two-level suffixes struct hentry* AffixMgr::prefix_check_twosfx(const char* word, int len, char in_compound, const FLAG needflag) { struct hentry* rv = NULL; pfx = NULL; sfxappnd = NULL; sfxextra = 0; // first handle the special case of 0 length prefixes PfxEntry* pe = pStart[0]; while (pe) { rv = pe->check_twosfx(word, len, in_compound, needflag); if (rv) return rv; pe = pe->getNext(); } // now handle the general case unsigned char sp = *((const unsigned char*)word); PfxEntry* pptr = pStart[sp]; while (pptr) { if (isSubset(pptr->getKey(), word)) { rv = pptr->check_twosfx(word, len, in_compound, needflag); if (rv) { pfx = pptr; return rv; } pptr = pptr->getNextEQ(); } else { pptr = pptr->getNextNE(); } } return NULL; } // check word for prefixes and morph std::string AffixMgr::prefix_check_morph(const char* word, int len, char in_compound, const FLAG needflag) { std::string result; pfx = NULL; sfxappnd = NULL; sfxextra = 0; // first handle the special case of 0 length prefixes PfxEntry* pe = pStart[0]; while (pe) { std::string st = pe->check_morph(word, len, in_compound, needflag); if (!st.empty()) { result.append(st); } pe = pe->getNext(); } // now handle the general case unsigned char sp = *((const unsigned char*)word); PfxEntry* pptr = pStart[sp]; while (pptr) { if (isSubset(pptr->getKey(), word)) { std::string st = pptr->check_morph(word, len, in_compound, needflag); if (!st.empty()) { // fogemorpheme if ((in_compound != IN_CPD_NOT) || !((pptr->getCont() && (TESTAFF(pptr->getCont(), onlyincompound, pptr->getContLen()))))) { result.append(st); pfx = pptr; } } pptr = pptr->getNextEQ(); } else { pptr = pptr->getNextNE(); } } return result; } // check word for prefixes and morph and two-level suffixes std::string AffixMgr::prefix_check_twosfx_morph(const char* word, int len, char in_compound, const FLAG needflag) { std::string result; pfx = NULL; sfxappnd = NULL; sfxextra = 0; // first handle the special case of 0 length prefixes PfxEntry* pe = pStart[0]; while (pe) { std::string st = pe->check_twosfx_morph(word, len, in_compound, needflag); if (!st.empty()) { result.append(st); } pe = pe->getNext(); } // now handle the general case unsigned char sp = *((const unsigned char*)word); PfxEntry* pptr = pStart[sp]; while (pptr) { if (isSubset(pptr->getKey(), word)) { std::string st = pptr->check_twosfx_morph(word, len, in_compound, needflag); if (!st.empty()) { result.append(st); pfx = pptr; } pptr = pptr->getNextEQ(); } else { pptr = pptr->getNextNE(); } } return result; } // Is word a non-compound with a REP substitution (see checkcompoundrep)? int AffixMgr::cpdrep_check(const char* word, int wl) { if ((wl < 2) || get_reptable().empty()) return 0; for (size_t i = 0; i < get_reptable().size(); ++i) { // use only available mid patterns if (!get_reptable()[i].outstrings[0].empty()) { const char* r = word; const size_t lenp = get_reptable()[i].pattern.size(); // search every occurence of the pattern in the word while ((r = strstr(r, get_reptable()[i].pattern.c_str())) != NULL) { std::string candidate(word); candidate.replace(r - word, lenp, get_reptable()[i].outstrings[0]); if (candidate_check(candidate.c_str(), candidate.size())) return 1; ++r; // search for the next letter } } } return 0; } // forbid compound words, if they are in the dictionary as a // word pair separated by space int AffixMgr::cpdwordpair_check(const char * word, int wl) { if (wl > 2) { std::string candidate(word); for (size_t i = 1; i < candidate.size(); i++) { // go to end of the UTF-8 character if (utf8 && ((word[i] & 0xc0) == 0x80)) continue; candidate.insert(i, 1, ' '); if (candidate_check(candidate.c_str(), candidate.size())) return 1; candidate.erase(i, 1); } } return 0; } // forbid compoundings when there are special patterns at word bound int AffixMgr::cpdpat_check(const char* word, int pos, hentry* r1, hentry* r2, const char /*affixed*/) { for (size_t i = 0; i < checkcpdtable.size(); ++i) { size_t len; if (isSubset(checkcpdtable[i].pattern2.c_str(), word + pos) && (!r1 || !checkcpdtable[i].cond || (r1->astr && TESTAFF(r1->astr, checkcpdtable[i].cond, r1->alen))) && (!r2 || !checkcpdtable[i].cond2 || (r2->astr && TESTAFF(r2->astr, checkcpdtable[i].cond2, r2->alen))) && // zero length pattern => only TESTAFF // zero pattern (0/flag) => unmodified stem (zero affixes allowed) (checkcpdtable[i].pattern.empty() || ((checkcpdtable[i].pattern[0] == '0' && r1->blen <= pos && strncmp(word + pos - r1->blen, r1->word, r1->blen) == 0) || (checkcpdtable[i].pattern[0] != '0' && ((len = checkcpdtable[i].pattern.size()) != 0) && strncmp(word + pos - len, checkcpdtable[i].pattern.c_str(), len) == 0)))) { return 1; } } return 0; } // forbid compounding with neighbouring upper and lower case characters at word // bounds int AffixMgr::cpdcase_check(const char* word, int pos) { if (utf8) { const char* p; for (p = word + pos - 1; (*p & 0xc0) == 0x80; p--) ; std::string pair(p); std::vector pair_u; u8_u16(pair_u, pair); unsigned short a = pair_u.size() > 1 ? ((pair_u[1].h << 8) + pair_u[1].l) : 0; unsigned short b = !pair_u.empty() ? ((pair_u[0].h << 8) + pair_u[0].l) : 0; if (((unicodetoupper(a, langnum) == a) || (unicodetoupper(b, langnum) == b)) && (a != '-') && (b != '-')) return 1; } else { unsigned char a = *(word + pos - 1); unsigned char b = *(word + pos); if ((csconv[a].ccase || csconv[b].ccase) && (a != '-') && (b != '-')) return 1; } return 0; } struct metachar_data { signed short btpp; // metacharacter (*, ?) position for backtracking signed short btwp; // word position for metacharacters int btnum; // number of matched characters in metacharacter }; // check compound patterns int AffixMgr::defcpd_check(hentry*** words, short wnum, hentry* rv, hentry** def, char all) { int w = 0; if (!*words) { w = 1; *words = def; } if (!*words) { return 0; } std::vector btinfo(1); short bt = 0; (*words)[wnum] = rv; // has the last word COMPOUNDRULE flag? if (rv->alen == 0) { (*words)[wnum] = NULL; if (w) *words = NULL; return 0; } int ok = 0; for (size_t i = 0; i < defcpdtable.size(); ++i) { for (size_t j = 0; j < defcpdtable[i].size(); ++j) { if (defcpdtable[i][j] != '*' && defcpdtable[i][j] != '?' && TESTAFF(rv->astr, defcpdtable[i][j], rv->alen)) { ok = 1; break; } } } if (ok == 0) { (*words)[wnum] = NULL; if (w) *words = NULL; return 0; } for (size_t i = 0; i < defcpdtable.size(); ++i) { size_t pp = 0; // pattern position signed short wp = 0; // "words" position int ok2; ok = 1; ok2 = 1; do { while ((pp < defcpdtable[i].size()) && (wp <= wnum)) { if (((pp + 1) < defcpdtable[i].size()) && ((defcpdtable[i][pp + 1] == '*') || (defcpdtable[i][pp + 1] == '?'))) { int wend = (defcpdtable[i][pp + 1] == '?') ? wp : wnum; ok2 = 1; pp += 2; btinfo[bt].btpp = pp; btinfo[bt].btwp = wp; while (wp <= wend) { if (!(*words)[wp]->alen || !TESTAFF((*words)[wp]->astr, defcpdtable[i][pp - 2], (*words)[wp]->alen)) { ok2 = 0; break; } wp++; } if (wp <= wnum) ok2 = 0; btinfo[bt].btnum = wp - btinfo[bt].btwp; if (btinfo[bt].btnum > 0) { ++bt; btinfo.resize(bt+1); } if (ok2) break; } else { ok2 = 1; if (!(*words)[wp] || !(*words)[wp]->alen || !TESTAFF((*words)[wp]->astr, defcpdtable[i][pp], (*words)[wp]->alen)) { ok = 0; break; } pp++; wp++; if ((defcpdtable[i].size() == pp) && !(wp > wnum)) ok = 0; } } if (ok && ok2) { size_t r = pp; while ((defcpdtable[i].size() > r) && ((r + 1) < defcpdtable[i].size()) && ((defcpdtable[i][r + 1] == '*') || (defcpdtable[i][r + 1] == '?'))) r += 2; if (defcpdtable[i].size() <= r) return 1; } // backtrack if (bt) do { ok = 1; btinfo[bt - 1].btnum--; pp = btinfo[bt - 1].btpp; wp = btinfo[bt - 1].btwp + (signed short)btinfo[bt - 1].btnum; } while ((btinfo[bt - 1].btnum < 0) && --bt); } while (bt); if (ok && ok2 && (!all || (defcpdtable[i].size() <= pp))) return 1; // check zero ending while (ok && ok2 && (defcpdtable[i].size() > pp) && ((pp + 1) < defcpdtable[i].size()) && ((defcpdtable[i][pp + 1] == '*') || (defcpdtable[i][pp + 1] == '?'))) pp += 2; if (ok && ok2 && (defcpdtable[i].size() <= pp)) return 1; } (*words)[wnum] = NULL; if (w) *words = NULL; return 0; } inline int AffixMgr::candidate_check(const char* word, int len) { struct hentry* rv = lookup(word); if (rv) return 1; // rv = prefix_check(word,len,1); // if (rv) return 1; rv = affix_check(word, len); if (rv) return 1; return 0; } // calculate number of syllable for compound-checking short AffixMgr::get_syllable(const std::string& word) { if (cpdmaxsyllable == 0) return 0; short num = 0; if (!utf8) { for (size_t i = 0; i < word.size(); ++i) { if (std::binary_search(cpdvowels.begin(), cpdvowels.end(), word[i])) { ++num; } } } else if (!cpdvowels_utf16.empty()) { std::vector w; u8_u16(w, word); for (size_t i = 0; i < w.size(); ++i) { if (std::binary_search(cpdvowels_utf16.begin(), cpdvowels_utf16.end(), w[i])) { ++num; } } } return num; } void AffixMgr::setcminmax(int* cmin, int* cmax, const char* word, int len) { if (utf8) { int i; for (*cmin = 0, i = 0; (i < cpdmin) && *cmin < len; i++) { for ((*cmin)++; *cmin < len && (word[*cmin] & 0xc0) == 0x80; (*cmin)++) ; } for (*cmax = len, i = 0; (i < (cpdmin - 1)) && *cmax >= 0; i++) { for ((*cmax)--; *cmax >= 0 && (word[*cmax] & 0xc0) == 0x80; (*cmax)--) ; } } else { *cmin = cpdmin; *cmax = len - cpdmin + 1; } } // check if compound word is correctly spelled // hu_mov_rule = spec. Hungarian rule (XXX) struct hentry* AffixMgr::compound_check(const std::string& word, short wordnum, short numsyllable, short maxwordnum, short wnum, hentry** words = NULL, hentry** rwords = NULL, char hu_mov_rule = 0, char is_sug = 0, int* info = NULL) { int i; short oldnumsyllable, oldnumsyllable2, oldwordnum, oldwordnum2; struct hentry* rv = NULL; struct hentry* rv_first; std::string st; char ch = '\0'; int cmin; int cmax; int striple = 0; size_t scpd = 0; int soldi = 0; int oldcmin = 0; int oldcmax = 0; int oldlen = 0; int checkedstriple = 0; char affixed = 0; hentry** oldwords = words; size_t len = word.size(); int checked_prefix; // add a time limit to handle possible // combinatorical explosion of the overlapping words HUNSPELL_THREAD_LOCAL clock_t timelimit; if (wordnum == 0) timelimit = clock(); else if (timelimit != 0 && (clock() > timelimit + TIMELIMIT)) { timelimit = 0; } setcminmax(&cmin, &cmax, word.c_str(), len); st.assign(word); for (i = cmin; i < cmax; i++) { // go to end of the UTF-8 character if (utf8) { for (; (st[i] & 0xc0) == 0x80; i++) ; if (i >= cmax) return NULL; } words = oldwords; int onlycpdrule = (words) ? 1 : 0; do { // onlycpdrule loop oldnumsyllable = numsyllable; oldwordnum = wordnum; checked_prefix = 0; do { // simplified checkcompoundpattern loop if (timelimit == 0) return 0; if (scpd > 0) { for (; scpd <= checkcpdtable.size() && (checkcpdtable[scpd - 1].pattern3.empty() || strncmp(word.c_str() + i, checkcpdtable[scpd - 1].pattern3.c_str(), checkcpdtable[scpd - 1].pattern3.size()) != 0); scpd++) ; if (scpd > checkcpdtable.size()) break; // break simplified checkcompoundpattern loop st.replace(i, std::string::npos, checkcpdtable[scpd - 1].pattern); soldi = i; i += checkcpdtable[scpd - 1].pattern.size(); st.replace(i, std::string::npos, checkcpdtable[scpd - 1].pattern2); st.replace(i + checkcpdtable[scpd - 1].pattern2.size(), std::string::npos, word.substr(soldi + checkcpdtable[scpd - 1].pattern3.size())); oldlen = len; len += checkcpdtable[scpd - 1].pattern.size() + checkcpdtable[scpd - 1].pattern2.size() - checkcpdtable[scpd - 1].pattern3.size(); oldcmin = cmin; oldcmax = cmax; setcminmax(&cmin, &cmax, st.c_str(), len); cmax = len - cpdmin + 1; } ch = st[i]; st[i] = '\0'; sfx = NULL; pfx = NULL; // FIRST WORD affixed = 1; rv = lookup(st.c_str()); // perhaps without prefix // forbid dictionary stems with COMPOUNDFORBIDFLAG in // compound words, overriding the effect of COMPOUNDPERMITFLAG if ((rv) && compoundforbidflag && TESTAFF(rv->astr, compoundforbidflag, rv->alen) && !hu_mov_rule) continue; // search homonym with compound flag while ((rv) && !hu_mov_rule && ((needaffix && TESTAFF(rv->astr, needaffix, rv->alen)) || !((compoundflag && !words && !onlycpdrule && TESTAFF(rv->astr, compoundflag, rv->alen)) || (compoundbegin && !wordnum && !onlycpdrule && TESTAFF(rv->astr, compoundbegin, rv->alen)) || (compoundmiddle && wordnum && !words && !onlycpdrule && TESTAFF(rv->astr, compoundmiddle, rv->alen)) || (!defcpdtable.empty() && onlycpdrule && ((!words && !wordnum && defcpd_check(&words, wnum, rv, rwords, 0)) || (words && defcpd_check(&words, wnum, rv, rwords, 0))))) || (scpd != 0 && checkcpdtable[scpd - 1].cond != FLAG_NULL && !TESTAFF(rv->astr, checkcpdtable[scpd - 1].cond, rv->alen)))) { rv = rv->next_homonym; } if (rv) affixed = 0; if (!rv) { if (onlycpdrule) break; if (compoundflag && !(rv = prefix_check(st.c_str(), i, hu_mov_rule ? IN_CPD_OTHER : IN_CPD_BEGIN, compoundflag))) { if (((rv = suffix_check( st.c_str(), i, 0, NULL, FLAG_NULL, compoundflag, hu_mov_rule ? IN_CPD_OTHER : IN_CPD_BEGIN)) || (compoundmoresuffixes && (rv = suffix_check_twosfx(st.c_str(), i, 0, NULL, compoundflag)))) && !hu_mov_rule && sfx->getCont() && ((compoundforbidflag && TESTAFF(sfx->getCont(), compoundforbidflag, sfx->getContLen())) || (compoundend && TESTAFF(sfx->getCont(), compoundend, sfx->getContLen())))) { rv = NULL; } } if (rv || (((wordnum == 0) && compoundbegin && ((rv = suffix_check( st.c_str(), i, 0, NULL, FLAG_NULL, compoundbegin, hu_mov_rule ? IN_CPD_OTHER : IN_CPD_BEGIN)) || (compoundmoresuffixes && (rv = suffix_check_twosfx( st.c_str(), i, 0, NULL, compoundbegin))) || // twofold suffixes + compound (rv = prefix_check(st.c_str(), i, hu_mov_rule ? IN_CPD_OTHER : IN_CPD_BEGIN, compoundbegin)))) || ((wordnum > 0) && compoundmiddle && ((rv = suffix_check( st.c_str(), i, 0, NULL, FLAG_NULL, compoundmiddle, hu_mov_rule ? IN_CPD_OTHER : IN_CPD_BEGIN)) || (compoundmoresuffixes && (rv = suffix_check_twosfx( st.c_str(), i, 0, NULL, compoundmiddle))) || // twofold suffixes + compound (rv = prefix_check(st.c_str(), i, hu_mov_rule ? IN_CPD_OTHER : IN_CPD_BEGIN, compoundmiddle)))))) checked_prefix = 1; // else check forbiddenwords and needaffix } else if (rv->astr && (TESTAFF(rv->astr, forbiddenword, rv->alen) || TESTAFF(rv->astr, needaffix, rv->alen) || TESTAFF(rv->astr, ONLYUPCASEFLAG, rv->alen) || (is_sug && nosuggest && TESTAFF(rv->astr, nosuggest, rv->alen)))) { st[i] = ch; // continue; break; } // check non_compound flag in suffix and prefix if ((rv) && !hu_mov_rule && ((pfx && pfx->getCont() && TESTAFF(pfx->getCont(), compoundforbidflag, pfx->getContLen())) || (sfx && sfx->getCont() && TESTAFF(sfx->getCont(), compoundforbidflag, sfx->getContLen())))) { rv = NULL; } // check compoundend flag in suffix and prefix if ((rv) && !checked_prefix && compoundend && !hu_mov_rule && ((pfx && pfx->getCont() && TESTAFF(pfx->getCont(), compoundend, pfx->getContLen())) || (sfx && sfx->getCont() && TESTAFF(sfx->getCont(), compoundend, sfx->getContLen())))) { rv = NULL; } // check compoundmiddle flag in suffix and prefix if ((rv) && !checked_prefix && (wordnum == 0) && compoundmiddle && !hu_mov_rule && ((pfx && pfx->getCont() && TESTAFF(pfx->getCont(), compoundmiddle, pfx->getContLen())) || (sfx && sfx->getCont() && TESTAFF(sfx->getCont(), compoundmiddle, sfx->getContLen())))) { rv = NULL; } // check forbiddenwords if ((rv) && (rv->astr) && (TESTAFF(rv->astr, forbiddenword, rv->alen) || TESTAFF(rv->astr, ONLYUPCASEFLAG, rv->alen) || (is_sug && nosuggest && TESTAFF(rv->astr, nosuggest, rv->alen)))) { return NULL; } // increment word number, if the second root has a compoundroot flag if ((rv) && compoundroot && (TESTAFF(rv->astr, compoundroot, rv->alen))) { wordnum++; } // first word is acceptable in compound words? if (((rv) && (checked_prefix || (words && words[wnum]) || (compoundflag && TESTAFF(rv->astr, compoundflag, rv->alen)) || ((oldwordnum == 0) && compoundbegin && TESTAFF(rv->astr, compoundbegin, rv->alen)) || ((oldwordnum > 0) && compoundmiddle && TESTAFF(rv->astr, compoundmiddle, rv->alen)) // LANG_hu section: spec. Hungarian rule || ((langnum == LANG_hu) && hu_mov_rule && (TESTAFF( rv->astr, 'F', rv->alen) || // XXX hardwired Hungarian dictionary codes TESTAFF(rv->astr, 'G', rv->alen) || TESTAFF(rv->astr, 'H', rv->alen))) // END of LANG_hu section ) && ( // test CHECKCOMPOUNDPATTERN conditions scpd == 0 || checkcpdtable[scpd - 1].cond == FLAG_NULL || TESTAFF(rv->astr, checkcpdtable[scpd - 1].cond, rv->alen)) && !((checkcompoundtriple && scpd == 0 && !words && // test triple letters (word[i - 1] == word[i]) && (((i > 1) && (word[i - 1] == word[i - 2])) || ((word[i - 1] == word[i + 1])) // may be word[i+1] == '\0' )) || (checkcompoundcase && scpd == 0 && !words && cpdcase_check(word.c_str(), i)))) // LANG_hu section: spec. Hungarian rule || ((!rv) && (langnum == LANG_hu) && hu_mov_rule && (rv = affix_check(st.c_str(), i)) && (sfx && sfx->getCont() && ( // XXX hardwired Hungarian dic. codes TESTAFF(sfx->getCont(), (unsigned short)'x', sfx->getContLen()) || TESTAFF( sfx->getCont(), (unsigned short)'%', sfx->getContLen()))))) { // first word is ok condition // LANG_hu section: spec. Hungarian rule if (langnum == LANG_hu) { // calculate syllable number of the word numsyllable += get_syllable(st.substr(0, i)); // + 1 word, if syllable number of the prefix > 1 (hungarian // convention) if (pfx && (get_syllable(pfx->getKey()) > 1)) wordnum++; } // END of LANG_hu section // NEXT WORD(S) rv_first = rv; st[i] = ch; do { // striple loop // check simplifiedtriple if (simplifiedtriple) { if (striple) { checkedstriple = 1; i--; // check "fahrt" instead of "ahrt" in "Schiffahrt" } else if (i > 2 && word[i - 1] == word[i - 2]) striple = 1; } rv = lookup(st.c_str() + i); // perhaps without prefix // search homonym with compound flag while ((rv) && ((needaffix && TESTAFF(rv->astr, needaffix, rv->alen)) || !((compoundflag && !words && TESTAFF(rv->astr, compoundflag, rv->alen)) || (compoundend && !words && TESTAFF(rv->astr, compoundend, rv->alen)) || (!defcpdtable.empty() && words && defcpd_check(&words, wnum + 1, rv, NULL, 1))) || (scpd != 0 && checkcpdtable[scpd - 1].cond2 != FLAG_NULL && !TESTAFF(rv->astr, checkcpdtable[scpd - 1].cond2, rv->alen)))) { rv = rv->next_homonym; } // check FORCEUCASE if (rv && forceucase && (rv) && (TESTAFF(rv->astr, forceucase, rv->alen)) && !(info && *info & SPELL_ORIGCAP)) rv = NULL; if (rv && words && words[wnum + 1]) return rv_first; oldnumsyllable2 = numsyllable; oldwordnum2 = wordnum; // LANG_hu section: spec. Hungarian rule, XXX hardwired dictionary // code if ((rv) && (langnum == LANG_hu) && (TESTAFF(rv->astr, 'I', rv->alen)) && !(TESTAFF(rv->astr, 'J', rv->alen))) { numsyllable--; } // END of LANG_hu section // increment word number, if the second root has a compoundroot flag if ((rv) && (compoundroot) && (TESTAFF(rv->astr, compoundroot, rv->alen))) { wordnum++; } // check forbiddenwords if ((rv) && (rv->astr) && (TESTAFF(rv->astr, forbiddenword, rv->alen) || TESTAFF(rv->astr, ONLYUPCASEFLAG, rv->alen) || (is_sug && nosuggest && TESTAFF(rv->astr, nosuggest, rv->alen)))) return NULL; // second word is acceptable, as a root? // hungarian conventions: compounding is acceptable, // when compound forms consist of 2 words, or if more, // then the syllable number of root words must be 6, or lesser. if ((rv) && ((compoundflag && TESTAFF(rv->astr, compoundflag, rv->alen)) || (compoundend && TESTAFF(rv->astr, compoundend, rv->alen))) && (((cpdwordmax == -1) || (wordnum + 1 < cpdwordmax)) || ((cpdmaxsyllable != 0) && (numsyllable + get_syllable(std::string(HENTRY_WORD(rv), rv->blen)) <= cpdmaxsyllable))) && ( // test CHECKCOMPOUNDPATTERN checkcpdtable.empty() || scpd != 0 || !cpdpat_check(word.c_str(), i, rv_first, rv, 0)) && ((!checkcompounddup || (rv != rv_first))) // test CHECKCOMPOUNDPATTERN conditions && (scpd == 0 || checkcpdtable[scpd - 1].cond2 == FLAG_NULL || TESTAFF(rv->astr, checkcpdtable[scpd - 1].cond2, rv->alen))) { // forbid compound word, if it is a non-compound word with typical // fault if ((checkcompoundrep && cpdrep_check(word.c_str(), len)) || cpdwordpair_check(word.c_str(), len)) return NULL; return rv_first; } numsyllable = oldnumsyllable2; wordnum = oldwordnum2; // perhaps second word has prefix or/and suffix sfx = NULL; sfxflag = FLAG_NULL; rv = (compoundflag && !onlycpdrule) ? affix_check((word.c_str() + i), strlen(word.c_str() + i), compoundflag, IN_CPD_END) : NULL; if (!rv && compoundend && !onlycpdrule) { sfx = NULL; pfx = NULL; rv = affix_check((word.c_str() + i), strlen(word.c_str() + i), compoundend, IN_CPD_END); } if (!rv && !defcpdtable.empty() && words) { rv = affix_check((word.c_str() + i), strlen(word.c_str() + i), 0, IN_CPD_END); if (rv && defcpd_check(&words, wnum + 1, rv, NULL, 1)) return rv_first; rv = NULL; } // test CHECKCOMPOUNDPATTERN conditions (allowed forms) if (rv && !(scpd == 0 || checkcpdtable[scpd - 1].cond2 == FLAG_NULL || TESTAFF(rv->astr, checkcpdtable[scpd - 1].cond2, rv->alen))) rv = NULL; // test CHECKCOMPOUNDPATTERN conditions (forbidden compounds) if (rv && !checkcpdtable.empty() && scpd == 0 && cpdpat_check(word.c_str(), i, rv_first, rv, affixed)) rv = NULL; // check non_compound flag in suffix and prefix if ((rv) && ((pfx && pfx->getCont() && TESTAFF(pfx->getCont(), compoundforbidflag, pfx->getContLen())) || (sfx && sfx->getCont() && TESTAFF(sfx->getCont(), compoundforbidflag, sfx->getContLen())))) { rv = NULL; } // check FORCEUCASE if (rv && forceucase && (rv) && (TESTAFF(rv->astr, forceucase, rv->alen)) && !(info && *info & SPELL_ORIGCAP)) rv = NULL; // check forbiddenwords if ((rv) && (rv->astr) && (TESTAFF(rv->astr, forbiddenword, rv->alen) || TESTAFF(rv->astr, ONLYUPCASEFLAG, rv->alen) || (is_sug && nosuggest && TESTAFF(rv->astr, nosuggest, rv->alen)))) return NULL; // pfxappnd = prefix of word+i, or NULL // calculate syllable number of prefix. // hungarian convention: when syllable number of prefix is more, // than 1, the prefix+word counts as two words. if (langnum == LANG_hu) { // calculate syllable number of the word numsyllable += get_syllable(word.c_str() + i); // - affix syllable num. // XXX only second suffix (inflections, not derivations) if (sfxappnd) { std::string tmp(sfxappnd); reverseword(tmp); numsyllable -= short(get_syllable(tmp) + sfxextra); } else { numsyllable -= short(sfxextra); } // + 1 word, if syllable number of the prefix > 1 (hungarian // convention) if (pfx && (get_syllable(pfx->getKey()) > 1)) wordnum++; // increment syllable num, if last word has a SYLLABLENUM flag // and the suffix is beginning `s' if (!cpdsyllablenum.empty()) { switch (sfxflag) { case 'c': { numsyllable += 2; break; } case 'J': { numsyllable += 1; break; } case 'I': { if (rv && TESTAFF(rv->astr, 'J', rv->alen)) numsyllable += 1; break; } } } } // increment word number, if the second word has a compoundroot flag if ((rv) && (compoundroot) && (TESTAFF(rv->astr, compoundroot, rv->alen))) { wordnum++; } // second word is acceptable, as a word with prefix or/and suffix? // hungarian conventions: compounding is acceptable, // when compound forms consist 2 word, otherwise // the syllable number of root words is 6, or lesser. if ((rv) && (((cpdwordmax == -1) || (wordnum + 1 < cpdwordmax)) || ((cpdmaxsyllable != 0) && (numsyllable <= cpdmaxsyllable))) && ((!checkcompounddup || (rv != rv_first)))) { // forbid compound word, if it is a non-compound word with typical // fault if ((checkcompoundrep && cpdrep_check(word.c_str(), len)) || cpdwordpair_check(word.c_str(), len)) return NULL; return rv_first; } numsyllable = oldnumsyllable2; wordnum = oldwordnum2; // perhaps second word is a compound word (recursive call) if (wordnum + 2 < maxwordnum) { rv = compound_check(st.substr(i), wordnum + 1, numsyllable, maxwordnum, wnum + 1, words, rwords, 0, is_sug, info); if (rv && !checkcpdtable.empty() && ((scpd == 0 && cpdpat_check(word.c_str(), i, rv_first, rv, affixed)) || (scpd != 0 && !cpdpat_check(word.c_str(), i, rv_first, rv, affixed)))) rv = NULL; } else { rv = NULL; } if (rv) { // forbid compound word, if it is a non-compound word with typical // fault, or a dictionary word pair if (cpdwordpair_check(word.c_str(), len)) return NULL; if (checkcompoundrep || forbiddenword) { if (checkcompoundrep && cpdrep_check(word.c_str(), len)) return NULL; // check first part if (strncmp(rv->word, word.c_str() + i, rv->blen) == 0) { char r = st[i + rv->blen]; st[i + rv->blen] = '\0'; if ((checkcompoundrep && cpdrep_check(st.c_str(), i + rv->blen)) || cpdwordpair_check(st.c_str(), i + rv->blen)) { st[ + i + rv->blen] = r; continue; } if (forbiddenword) { struct hentry* rv2 = lookup(word.c_str()); if (!rv2) rv2 = affix_check(word.c_str(), len); if (rv2 && rv2->astr && TESTAFF(rv2->astr, forbiddenword, rv2->alen) && (strncmp(rv2->word, st.c_str(), i + rv->blen) == 0)) { return NULL; } } st[i + rv->blen] = r; } } return rv_first; } } while (striple && !checkedstriple); // end of striple loop if (checkedstriple) { i++; checkedstriple = 0; striple = 0; } } // first word is ok condition if (soldi != 0) { i = soldi; soldi = 0; len = oldlen; cmin = oldcmin; cmax = oldcmax; } scpd++; } while (!onlycpdrule && simplifiedcpd && scpd <= checkcpdtable.size()); // end of simplifiedcpd loop scpd = 0; wordnum = oldwordnum; numsyllable = oldnumsyllable; if (soldi != 0) { i = soldi; st.assign(word); // XXX add more optim. soldi = 0; } else st[i] = ch; } while (!defcpdtable.empty() && oldwordnum == 0 && onlycpdrule++ < 1); // end of onlycpd loop } return NULL; } // check if compound word is correctly spelled // hu_mov_rule = spec. Hungarian rule (XXX) int AffixMgr::compound_check_morph(const char* word, int len, short wordnum, short numsyllable, short maxwordnum, short wnum, hentry** words, hentry** rwords, char hu_mov_rule, std::string& result, const std::string* partresult) { int i; short oldnumsyllable, oldnumsyllable2, oldwordnum, oldwordnum2; int ok = 0; struct hentry* rv = NULL; struct hentry* rv_first; std::string st; char ch; int checked_prefix; std::string presult; int cmin; int cmax; char affixed = 0; hentry** oldwords = words; // add a time limit to handle possible // combinatorical explosion of the overlapping words HUNSPELL_THREAD_LOCAL clock_t timelimit; if (wordnum == 0) timelimit = clock(); else if (timelimit != 0 && (clock() > timelimit + TIMELIMIT)) { timelimit = 0; } setcminmax(&cmin, &cmax, word, len); st.assign(word); for (i = cmin; i < cmax; i++) { // go to end of the UTF-8 character if (utf8) { for (; (st[i] & 0xc0) == 0x80; i++) ; if (i >= cmax) return 0; } words = oldwords; int onlycpdrule = (words) ? 1 : 0; do { // onlycpdrule loop if (timelimit == 0) return 0; oldnumsyllable = numsyllable; oldwordnum = wordnum; checked_prefix = 0; ch = st[i]; st[i] = '\0'; sfx = NULL; // FIRST WORD affixed = 1; presult.clear(); if (partresult) presult.append(*partresult); rv = lookup(st.c_str()); // perhaps without prefix // forbid dictionary stems with COMPOUNDFORBIDFLAG in // compound words, overriding the effect of COMPOUNDPERMITFLAG if ((rv) && compoundforbidflag && TESTAFF(rv->astr, compoundforbidflag, rv->alen) && !hu_mov_rule) continue; // search homonym with compound flag while ((rv) && !hu_mov_rule && ((needaffix && TESTAFF(rv->astr, needaffix, rv->alen)) || !((compoundflag && !words && !onlycpdrule && TESTAFF(rv->astr, compoundflag, rv->alen)) || (compoundbegin && !wordnum && !onlycpdrule && TESTAFF(rv->astr, compoundbegin, rv->alen)) || (compoundmiddle && wordnum && !words && !onlycpdrule && TESTAFF(rv->astr, compoundmiddle, rv->alen)) || (!defcpdtable.empty() && onlycpdrule && ((!words && !wordnum && defcpd_check(&words, wnum, rv, rwords, 0)) || (words && defcpd_check(&words, wnum, rv, rwords, 0))))))) { rv = rv->next_homonym; } if (timelimit == 0) return 0; if (rv) affixed = 0; if (rv) { presult.push_back(MSEP_FLD); presult.append(MORPH_PART); presult.append(st.c_str()); if (!HENTRY_FIND(rv, MORPH_STEM)) { presult.push_back(MSEP_FLD); presult.append(MORPH_STEM); presult.append(st.c_str()); } if (HENTRY_DATA(rv)) { presult.push_back(MSEP_FLD); presult.append(HENTRY_DATA2(rv)); } } if (!rv) { if (compoundflag && !(rv = prefix_check(st.c_str(), i, hu_mov_rule ? IN_CPD_OTHER : IN_CPD_BEGIN, compoundflag))) { if (((rv = suffix_check(st.c_str(), i, 0, NULL, FLAG_NULL, compoundflag, hu_mov_rule ? IN_CPD_OTHER : IN_CPD_BEGIN)) || (compoundmoresuffixes && (rv = suffix_check_twosfx(st.c_str(), i, 0, NULL, compoundflag)))) && !hu_mov_rule && sfx->getCont() && ((compoundforbidflag && TESTAFF(sfx->getCont(), compoundforbidflag, sfx->getContLen())) || (compoundend && TESTAFF(sfx->getCont(), compoundend, sfx->getContLen())))) { rv = NULL; } } if (rv || (((wordnum == 0) && compoundbegin && ((rv = suffix_check(st.c_str(), i, 0, NULL, FLAG_NULL, compoundbegin, hu_mov_rule ? IN_CPD_OTHER : IN_CPD_BEGIN)) || (compoundmoresuffixes && (rv = suffix_check_twosfx( st.c_str(), i, 0, NULL, compoundbegin))) || // twofold suffix+compound (rv = prefix_check(st.c_str(), i, hu_mov_rule ? IN_CPD_OTHER : IN_CPD_BEGIN, compoundbegin)))) || ((wordnum > 0) && compoundmiddle && ((rv = suffix_check(st.c_str(), i, 0, NULL, FLAG_NULL, compoundmiddle, hu_mov_rule ? IN_CPD_OTHER : IN_CPD_BEGIN)) || (compoundmoresuffixes && (rv = suffix_check_twosfx( st.c_str(), i, 0, NULL, compoundmiddle))) || // twofold suffix+compound (rv = prefix_check(st.c_str(), i, hu_mov_rule ? IN_CPD_OTHER : IN_CPD_BEGIN, compoundmiddle)))))) { std::string p; if (compoundflag) p = affix_check_morph(st.c_str(), i, compoundflag); if (p.empty()) { if ((wordnum == 0) && compoundbegin) { p = affix_check_morph(st.c_str(), i, compoundbegin); } else if ((wordnum > 0) && compoundmiddle) { p = affix_check_morph(st.c_str(), i, compoundmiddle); } } if (!p.empty()) { presult.push_back(MSEP_FLD); presult.append(MORPH_PART); presult.append(st.c_str()); line_uniq_app(p, MSEP_REC); presult.append(p); } checked_prefix = 1; } // else check forbiddenwords } else if (rv->astr && (TESTAFF(rv->astr, forbiddenword, rv->alen) || TESTAFF(rv->astr, ONLYUPCASEFLAG, rv->alen) || TESTAFF(rv->astr, needaffix, rv->alen))) { st[i] = ch; continue; } // check non_compound flag in suffix and prefix if ((rv) && !hu_mov_rule && ((pfx && pfx->getCont() && TESTAFF(pfx->getCont(), compoundforbidflag, pfx->getContLen())) || (sfx && sfx->getCont() && TESTAFF(sfx->getCont(), compoundforbidflag, sfx->getContLen())))) { continue; } // check compoundend flag in suffix and prefix if ((rv) && !checked_prefix && compoundend && !hu_mov_rule && ((pfx && pfx->getCont() && TESTAFF(pfx->getCont(), compoundend, pfx->getContLen())) || (sfx && sfx->getCont() && TESTAFF(sfx->getCont(), compoundend, sfx->getContLen())))) { continue; } // check compoundmiddle flag in suffix and prefix if ((rv) && !checked_prefix && (wordnum == 0) && compoundmiddle && !hu_mov_rule && ((pfx && pfx->getCont() && TESTAFF(pfx->getCont(), compoundmiddle, pfx->getContLen())) || (sfx && sfx->getCont() && TESTAFF(sfx->getCont(), compoundmiddle, sfx->getContLen())))) { rv = NULL; } // check forbiddenwords if ((rv) && (rv->astr) && (TESTAFF(rv->astr, forbiddenword, rv->alen) || TESTAFF(rv->astr, ONLYUPCASEFLAG, rv->alen))) continue; // increment word number, if the second root has a compoundroot flag if ((rv) && (compoundroot) && (TESTAFF(rv->astr, compoundroot, rv->alen))) { wordnum++; } // first word is acceptable in compound words? if (((rv) && (checked_prefix || (words && words[wnum]) || (compoundflag && TESTAFF(rv->astr, compoundflag, rv->alen)) || ((oldwordnum == 0) && compoundbegin && TESTAFF(rv->astr, compoundbegin, rv->alen)) || ((oldwordnum > 0) && compoundmiddle && TESTAFF(rv->astr, compoundmiddle, rv->alen)) // LANG_hu section: spec. Hungarian rule || ((langnum == LANG_hu) && // hu_mov_rule hu_mov_rule && (TESTAFF(rv->astr, 'F', rv->alen) || TESTAFF(rv->astr, 'G', rv->alen) || TESTAFF(rv->astr, 'H', rv->alen))) // END of LANG_hu section ) && !((checkcompoundtriple && !words && // test triple letters (word[i - 1] == word[i]) && (((i > 1) && (word[i - 1] == word[i - 2])) || ((word[i - 1] == word[i + 1])) // may be word[i+1] == '\0' )) || ( // test CHECKCOMPOUNDPATTERN !checkcpdtable.empty() && !words && cpdpat_check(word, i, rv, NULL, affixed)) || (checkcompoundcase && !words && cpdcase_check(word, i)))) // LANG_hu section: spec. Hungarian rule || ((!rv) && (langnum == LANG_hu) && hu_mov_rule && (rv = affix_check(st.c_str(), i)) && (sfx && sfx->getCont() && (TESTAFF(sfx->getCont(), (unsigned short)'x', sfx->getContLen()) || TESTAFF(sfx->getCont(), (unsigned short)'%', sfx->getContLen())))) // END of LANG_hu section ) { // LANG_hu section: spec. Hungarian rule if (langnum == LANG_hu) { // calculate syllable number of the word numsyllable += get_syllable(st.substr(0, i)); // + 1 word, if syllable number of the prefix > 1 (hungarian // convention) if (pfx && (get_syllable(pfx->getKey()) > 1)) wordnum++; } // END of LANG_hu section // NEXT WORD(S) rv_first = rv; rv = lookup((word + i)); // perhaps without prefix // search homonym with compound flag while ((rv) && ((needaffix && TESTAFF(rv->astr, needaffix, rv->alen)) || !((compoundflag && !words && TESTAFF(rv->astr, compoundflag, rv->alen)) || (compoundend && !words && TESTAFF(rv->astr, compoundend, rv->alen)) || (!defcpdtable.empty() && words && defcpd_check(&words, wnum + 1, rv, NULL, 1))))) { rv = rv->next_homonym; } if (rv && words && words[wnum + 1]) { result.append(presult); result.push_back(MSEP_FLD); result.append(MORPH_PART); result.append(word + i); if (complexprefixes && HENTRY_DATA(rv)) result.append(HENTRY_DATA2(rv)); if (!HENTRY_FIND(rv, MORPH_STEM)) { result.push_back(MSEP_FLD); result.append(MORPH_STEM); result.append(HENTRY_WORD(rv)); } // store the pointer of the hash entry if (!complexprefixes && HENTRY_DATA(rv)) { result.push_back(MSEP_FLD); result.append(HENTRY_DATA2(rv)); } result.push_back(MSEP_REC); return 0; } oldnumsyllable2 = numsyllable; oldwordnum2 = wordnum; // LANG_hu section: spec. Hungarian rule if ((rv) && (langnum == LANG_hu) && (TESTAFF(rv->astr, 'I', rv->alen)) && !(TESTAFF(rv->astr, 'J', rv->alen))) { numsyllable--; } // END of LANG_hu section // increment word number, if the second root has a compoundroot flag if ((rv) && (compoundroot) && (TESTAFF(rv->astr, compoundroot, rv->alen))) { wordnum++; } // check forbiddenwords if ((rv) && (rv->astr) && (TESTAFF(rv->astr, forbiddenword, rv->alen) || TESTAFF(rv->astr, ONLYUPCASEFLAG, rv->alen))) { st[i] = ch; continue; } // second word is acceptable, as a root? // hungarian conventions: compounding is acceptable, // when compound forms consist of 2 words, or if more, // then the syllable number of root words must be 6, or lesser. if ((rv) && ((compoundflag && TESTAFF(rv->astr, compoundflag, rv->alen)) || (compoundend && TESTAFF(rv->astr, compoundend, rv->alen))) && (((cpdwordmax == -1) || (wordnum + 1 < cpdwordmax)) || ((cpdmaxsyllable != 0) && (numsyllable + get_syllable(std::string(HENTRY_WORD(rv), rv->blen)) <= cpdmaxsyllable))) && ((!checkcompounddup || (rv != rv_first)))) { // bad compound word result.append(presult); result.push_back(MSEP_FLD); result.append(MORPH_PART); result.append(word + i); if (HENTRY_DATA(rv)) { if (complexprefixes) result.append(HENTRY_DATA2(rv)); if (!HENTRY_FIND(rv, MORPH_STEM)) { result.push_back(MSEP_FLD); result.append(MORPH_STEM); result.append(HENTRY_WORD(rv)); } // store the pointer of the hash entry if (!complexprefixes) { result.push_back(MSEP_FLD); result.append(HENTRY_DATA2(rv)); } } result.push_back(MSEP_REC); ok = 1; } numsyllable = oldnumsyllable2; wordnum = oldwordnum2; // perhaps second word has prefix or/and suffix sfx = NULL; sfxflag = FLAG_NULL; if (compoundflag && !onlycpdrule) rv = affix_check((word + i), strlen(word + i), compoundflag); else rv = NULL; if (!rv && compoundend && !onlycpdrule) { sfx = NULL; pfx = NULL; rv = affix_check((word + i), strlen(word + i), compoundend); } if (!rv && !defcpdtable.empty() && words) { rv = affix_check((word + i), strlen(word + i), 0, IN_CPD_END); if (rv && words && defcpd_check(&words, wnum + 1, rv, NULL, 1)) { std::string m; if (compoundflag) m = affix_check_morph((word + i), strlen(word + i), compoundflag); if (m.empty() && compoundend) { m = affix_check_morph((word + i), strlen(word + i), compoundend); } result.append(presult); if (!m.empty()) { result.push_back(MSEP_FLD); result.append(MORPH_PART); result.append(word + i); line_uniq_app(m, MSEP_REC); result.append(m); } result.push_back(MSEP_REC); ok = 1; } } // check non_compound flag in suffix and prefix if ((rv) && ((pfx && pfx->getCont() && TESTAFF(pfx->getCont(), compoundforbidflag, pfx->getContLen())) || (sfx && sfx->getCont() && TESTAFF(sfx->getCont(), compoundforbidflag, sfx->getContLen())))) { rv = NULL; } // check forbiddenwords if ((rv) && (rv->astr) && (TESTAFF(rv->astr, forbiddenword, rv->alen) || TESTAFF(rv->astr, ONLYUPCASEFLAG, rv->alen)) && (!TESTAFF(rv->astr, needaffix, rv->alen))) { st[i] = ch; continue; } if (langnum == LANG_hu) { // calculate syllable number of the word numsyllable += get_syllable(word + i); // - affix syllable num. // XXX only second suffix (inflections, not derivations) if (sfxappnd) { std::string tmp(sfxappnd); reverseword(tmp); numsyllable -= short(get_syllable(tmp) + sfxextra); } else { numsyllable -= short(sfxextra); } // + 1 word, if syllable number of the prefix > 1 (hungarian // convention) if (pfx && (get_syllable(pfx->getKey()) > 1)) wordnum++; // increment syllable num, if last word has a SYLLABLENUM flag // and the suffix is beginning `s' if (!cpdsyllablenum.empty()) { switch (sfxflag) { case 'c': { numsyllable += 2; break; } case 'J': { numsyllable += 1; break; } case 'I': { if (rv && TESTAFF(rv->astr, 'J', rv->alen)) numsyllable += 1; break; } } } } // increment word number, if the second word has a compoundroot flag if ((rv) && (compoundroot) && (TESTAFF(rv->astr, compoundroot, rv->alen))) { wordnum++; } // second word is acceptable, as a word with prefix or/and suffix? // hungarian conventions: compounding is acceptable, // when compound forms consist 2 word, otherwise // the syllable number of root words is 6, or lesser. if ((rv) && (((cpdwordmax == -1) || (wordnum + 1 < cpdwordmax)) || ((cpdmaxsyllable != 0) && (numsyllable <= cpdmaxsyllable))) && ((!checkcompounddup || (rv != rv_first)))) { std::string m; if (compoundflag) m = affix_check_morph((word + i), strlen(word + i), compoundflag); if (m.empty() && compoundend) { m = affix_check_morph((word + i), strlen(word + i), compoundend); } result.append(presult); if (!m.empty()) { result.push_back(MSEP_FLD); result.append(MORPH_PART); result.append(word + i); line_uniq_app(m, MSEP_REC); result.push_back(MSEP_FLD); result.append(m); } result.push_back(MSEP_REC); ok = 1; } numsyllable = oldnumsyllable2; wordnum = oldwordnum2; // perhaps second word is a compound word (recursive call) if ((wordnum + 2 < maxwordnum) && (ok == 0)) { compound_check_morph((word + i), strlen(word + i), wordnum + 1, numsyllable, maxwordnum, wnum + 1, words, rwords, 0, result, &presult); } else { rv = NULL; } } st[i] = ch; wordnum = oldwordnum; numsyllable = oldnumsyllable; } while (!defcpdtable.empty() && oldwordnum == 0 && onlycpdrule++ < 1); // end of onlycpd loop } return 0; } inline int AffixMgr::isRevSubset(const char* s1, const char* end_of_s2, int len) { while ((len > 0) && (*s1 != '\0') && ((*s1 == *end_of_s2) || (*s1 == '.'))) { s1++; end_of_s2--; len--; } return (*s1 == '\0'); } // check word for suffixes struct hentry* AffixMgr::suffix_check(const char* word, int len, int sfxopts, PfxEntry* ppfx, const FLAG cclass, const FLAG needflag, char in_compound) { struct hentry* rv = NULL; PfxEntry* ep = ppfx; // first handle the special case of 0 length suffixes SfxEntry* se = sStart[0]; while (se) { if (!cclass || se->getCont()) { // suffixes are not allowed in beginning of compounds if ((((in_compound != IN_CPD_BEGIN)) || // && !cclass // except when signed with compoundpermitflag flag (se->getCont() && compoundpermitflag && TESTAFF(se->getCont(), compoundpermitflag, se->getContLen()))) && (!circumfix || // no circumfix flag in prefix and suffix ((!ppfx || !(ep->getCont()) || !TESTAFF(ep->getCont(), circumfix, ep->getContLen())) && (!se->getCont() || !(TESTAFF(se->getCont(), circumfix, se->getContLen())))) || // circumfix flag in prefix AND suffix ((ppfx && (ep->getCont()) && TESTAFF(ep->getCont(), circumfix, ep->getContLen())) && (se->getCont() && (TESTAFF(se->getCont(), circumfix, se->getContLen()))))) && // fogemorpheme (in_compound || !(se->getCont() && (TESTAFF(se->getCont(), onlyincompound, se->getContLen())))) && // needaffix on prefix or first suffix (cclass || !(se->getCont() && TESTAFF(se->getCont(), needaffix, se->getContLen())) || (ppfx && !((ep->getCont()) && TESTAFF(ep->getCont(), needaffix, ep->getContLen()))))) { rv = se->checkword(word, len, sfxopts, ppfx, (FLAG)cclass, needflag, (in_compound ? 0 : onlyincompound)); if (rv) { sfx = se; // BUG: sfx not stateless return rv; } } } se = se->getNext(); } // now handle the general case if (len == 0) return NULL; // FULLSTRIP unsigned char sp = *((const unsigned char*)(word + len - 1)); SfxEntry* sptr = sStart[sp]; while (sptr) { if (isRevSubset(sptr->getKey(), word + len - 1, len)) { // suffixes are not allowed in beginning of compounds if ((((in_compound != IN_CPD_BEGIN)) || // && !cclass // except when signed with compoundpermitflag flag (sptr->getCont() && compoundpermitflag && TESTAFF(sptr->getCont(), compoundpermitflag, sptr->getContLen()))) && (!circumfix || // no circumfix flag in prefix and suffix ((!ppfx || !(ep->getCont()) || !TESTAFF(ep->getCont(), circumfix, ep->getContLen())) && (!sptr->getCont() || !(TESTAFF(sptr->getCont(), circumfix, sptr->getContLen())))) || // circumfix flag in prefix AND suffix ((ppfx && (ep->getCont()) && TESTAFF(ep->getCont(), circumfix, ep->getContLen())) && (sptr->getCont() && (TESTAFF(sptr->getCont(), circumfix, sptr->getContLen()))))) && // fogemorpheme (in_compound || !((sptr->getCont() && (TESTAFF(sptr->getCont(), onlyincompound, sptr->getContLen()))))) && // needaffix on prefix or first suffix (cclass || !(sptr->getCont() && TESTAFF(sptr->getCont(), needaffix, sptr->getContLen())) || (ppfx && !((ep->getCont()) && TESTAFF(ep->getCont(), needaffix, ep->getContLen()))))) if (in_compound != IN_CPD_END || ppfx || !(sptr->getCont() && TESTAFF(sptr->getCont(), onlyincompound, sptr->getContLen()))) { rv = sptr->checkword(word, len, sfxopts, ppfx, cclass, needflag, (in_compound ? 0 : onlyincompound)); if (rv) { sfx = sptr; // BUG: sfx not stateless sfxflag = sptr->getFlag(); // BUG: sfxflag not stateless if (!sptr->getCont()) sfxappnd = sptr->getKey(); // BUG: sfxappnd not stateless // LANG_hu section: spec. Hungarian rule else if (langnum == LANG_hu && sptr->getKeyLen() && sptr->getKey()[0] == 'i' && sptr->getKey()[1] != 'y' && sptr->getKey()[1] != 't') { sfxextra = 1; } // END of LANG_hu section return rv; } } sptr = sptr->getNextEQ(); } else { sptr = sptr->getNextNE(); } } return NULL; } // check word for two-level suffixes struct hentry* AffixMgr::suffix_check_twosfx(const char* word, int len, int sfxopts, PfxEntry* ppfx, const FLAG needflag) { struct hentry* rv = NULL; // first handle the special case of 0 length suffixes SfxEntry* se = sStart[0]; while (se) { if (contclasses[se->getFlag()]) { rv = se->check_twosfx(word, len, sfxopts, ppfx, needflag); if (rv) return rv; } se = se->getNext(); } // now handle the general case if (len == 0) return NULL; // FULLSTRIP unsigned char sp = *((const unsigned char*)(word + len - 1)); SfxEntry* sptr = sStart[sp]; while (sptr) { if (isRevSubset(sptr->getKey(), word + len - 1, len)) { if (contclasses[sptr->getFlag()]) { rv = sptr->check_twosfx(word, len, sfxopts, ppfx, needflag); if (rv) { sfxflag = sptr->getFlag(); // BUG: sfxflag not stateless if (!sptr->getCont()) sfxappnd = sptr->getKey(); // BUG: sfxappnd not stateless return rv; } } sptr = sptr->getNextEQ(); } else { sptr = sptr->getNextNE(); } } return NULL; } // check word for two-level suffixes and morph std::string AffixMgr::suffix_check_twosfx_morph(const char* word, int len, int sfxopts, PfxEntry* ppfx, const FLAG needflag) { std::string result; std::string result2; std::string result3; // first handle the special case of 0 length suffixes SfxEntry* se = sStart[0]; while (se) { if (contclasses[se->getFlag()]) { std::string st = se->check_twosfx_morph(word, len, sfxopts, ppfx, needflag); if (!st.empty()) { if (ppfx) { if (ppfx->getMorph()) { result.append(ppfx->getMorph()); result.push_back(MSEP_FLD); } else debugflag(result, ppfx->getFlag()); } result.append(st); if (se->getMorph()) { result.push_back(MSEP_FLD); result.append(se->getMorph()); } else debugflag(result, se->getFlag()); result.push_back(MSEP_REC); } } se = se->getNext(); } // now handle the general case if (len == 0) return std::string(); // FULLSTRIP unsigned char sp = *((const unsigned char*)(word + len - 1)); SfxEntry* sptr = sStart[sp]; while (sptr) { if (isRevSubset(sptr->getKey(), word + len - 1, len)) { if (contclasses[sptr->getFlag()]) { std::string st = sptr->check_twosfx_morph(word, len, sfxopts, ppfx, needflag); if (!st.empty()) { sfxflag = sptr->getFlag(); // BUG: sfxflag not stateless if (!sptr->getCont()) sfxappnd = sptr->getKey(); // BUG: sfxappnd not stateless result2.assign(st); result3.clear(); if (sptr->getMorph()) { result3.push_back(MSEP_FLD); result3.append(sptr->getMorph()); } else debugflag(result3, sptr->getFlag()); strlinecat(result2, result3); result2.push_back(MSEP_REC); result.append(result2); } } sptr = sptr->getNextEQ(); } else { sptr = sptr->getNextNE(); } } return result; } std::string AffixMgr::suffix_check_morph(const char* word, int len, int sfxopts, PfxEntry* ppfx, const FLAG cclass, const FLAG needflag, char in_compound) { std::string result; struct hentry* rv = NULL; PfxEntry* ep = ppfx; // first handle the special case of 0 length suffixes SfxEntry* se = sStart[0]; while (se) { if (!cclass || se->getCont()) { // suffixes are not allowed in beginning of compounds if (((((in_compound != IN_CPD_BEGIN)) || // && !cclass // except when signed with compoundpermitflag flag (se->getCont() && compoundpermitflag && TESTAFF(se->getCont(), compoundpermitflag, se->getContLen()))) && (!circumfix || // no circumfix flag in prefix and suffix ((!ppfx || !(ep->getCont()) || !TESTAFF(ep->getCont(), circumfix, ep->getContLen())) && (!se->getCont() || !(TESTAFF(se->getCont(), circumfix, se->getContLen())))) || // circumfix flag in prefix AND suffix ((ppfx && (ep->getCont()) && TESTAFF(ep->getCont(), circumfix, ep->getContLen())) && (se->getCont() && (TESTAFF(se->getCont(), circumfix, se->getContLen()))))) && // fogemorpheme (in_compound || !((se->getCont() && (TESTAFF(se->getCont(), onlyincompound, se->getContLen()))))) && // needaffix on prefix or first suffix (cclass || !(se->getCont() && TESTAFF(se->getCont(), needaffix, se->getContLen())) || (ppfx && !((ep->getCont()) && TESTAFF(ep->getCont(), needaffix, ep->getContLen())))))) rv = se->checkword(word, len, sfxopts, ppfx, cclass, needflag, FLAG_NULL); while (rv) { if (ppfx) { if (ppfx->getMorph()) { result.append(ppfx->getMorph()); result.push_back(MSEP_FLD); } else debugflag(result, ppfx->getFlag()); } if (complexprefixes && HENTRY_DATA(rv)) result.append(HENTRY_DATA2(rv)); if (!HENTRY_FIND(rv, MORPH_STEM)) { result.push_back(MSEP_FLD); result.append(MORPH_STEM); result.append(HENTRY_WORD(rv)); } if (!complexprefixes && HENTRY_DATA(rv)) { result.push_back(MSEP_FLD); result.append(HENTRY_DATA2(rv)); } if (se->getMorph()) { result.push_back(MSEP_FLD); result.append(se->getMorph()); } else debugflag(result, se->getFlag()); result.push_back(MSEP_REC); rv = se->get_next_homonym(rv, sfxopts, ppfx, cclass, needflag); } } se = se->getNext(); } // now handle the general case if (len == 0) return std::string(); // FULLSTRIP unsigned char sp = *((const unsigned char*)(word + len - 1)); SfxEntry* sptr = sStart[sp]; while (sptr) { if (isRevSubset(sptr->getKey(), word + len - 1, len)) { // suffixes are not allowed in beginning of compounds if (((((in_compound != IN_CPD_BEGIN)) || // && !cclass // except when signed with compoundpermitflag flag (sptr->getCont() && compoundpermitflag && TESTAFF(sptr->getCont(), compoundpermitflag, sptr->getContLen()))) && (!circumfix || // no circumfix flag in prefix and suffix ((!ppfx || !(ep->getCont()) || !TESTAFF(ep->getCont(), circumfix, ep->getContLen())) && (!sptr->getCont() || !(TESTAFF(sptr->getCont(), circumfix, sptr->getContLen())))) || // circumfix flag in prefix AND suffix ((ppfx && (ep->getCont()) && TESTAFF(ep->getCont(), circumfix, ep->getContLen())) && (sptr->getCont() && (TESTAFF(sptr->getCont(), circumfix, sptr->getContLen()))))) && // fogemorpheme (in_compound || !((sptr->getCont() && (TESTAFF(sptr->getCont(), onlyincompound, sptr->getContLen()))))) && // needaffix on first suffix (cclass || !(sptr->getCont() && TESTAFF(sptr->getCont(), needaffix, sptr->getContLen()))))) rv = sptr->checkword(word, len, sfxopts, ppfx, cclass, needflag, FLAG_NULL); while (rv) { if (ppfx) { if (ppfx->getMorph()) { result.append(ppfx->getMorph()); result.push_back(MSEP_FLD); } else debugflag(result, ppfx->getFlag()); } if (complexprefixes && HENTRY_DATA(rv)) result.append(HENTRY_DATA2(rv)); if (!HENTRY_FIND(rv, MORPH_STEM)) { result.push_back(MSEP_FLD); result.append(MORPH_STEM); result.append(HENTRY_WORD(rv)); } if (!complexprefixes && HENTRY_DATA(rv)) { result.push_back(MSEP_FLD); result.append(HENTRY_DATA2(rv)); } if (sptr->getMorph()) { result.push_back(MSEP_FLD); result.append(sptr->getMorph()); } else debugflag(result, sptr->getFlag()); result.push_back(MSEP_REC); rv = sptr->get_next_homonym(rv, sfxopts, ppfx, cclass, needflag); } sptr = sptr->getNextEQ(); } else { sptr = sptr->getNextNE(); } } return result; } // check if word with affixes is correctly spelled struct hentry* AffixMgr::affix_check(const char* word, int len, const FLAG needflag, char in_compound) { // check all prefixes (also crossed with suffixes if allowed) struct hentry* rv = prefix_check(word, len, in_compound, needflag); if (rv) return rv; // if still not found check all suffixes rv = suffix_check(word, len, 0, NULL, FLAG_NULL, needflag, in_compound); if (havecontclass) { sfx = NULL; pfx = NULL; if (rv) return rv; // if still not found check all two-level suffixes rv = suffix_check_twosfx(word, len, 0, NULL, needflag); if (rv) return rv; // if still not found check all two-level suffixes rv = prefix_check_twosfx(word, len, IN_CPD_NOT, needflag); } return rv; } // check if word with affixes is correctly spelled std::string AffixMgr::affix_check_morph(const char* word, int len, const FLAG needflag, char in_compound) { std::string result; // check all prefixes (also crossed with suffixes if allowed) std::string st = prefix_check_morph(word, len, in_compound); if (!st.empty()) { result.append(st); } // if still not found check all suffixes st = suffix_check_morph(word, len, 0, NULL, '\0', needflag, in_compound); if (!st.empty()) { result.append(st); } if (havecontclass) { sfx = NULL; pfx = NULL; // if still not found check all two-level suffixes st = suffix_check_twosfx_morph(word, len, 0, NULL, needflag); if (!st.empty()) { result.append(st); } // if still not found check all two-level suffixes st = prefix_check_twosfx_morph(word, len, IN_CPD_NOT, needflag); if (!st.empty()) { result.append(st); } } return result; } // morphcmp(): compare MORPH_DERI_SFX, MORPH_INFL_SFX and MORPH_TERM_SFX fields // in the first line of the inputs // return 0, if inputs equal // return 1, if inputs may equal with a secondary suffix // otherwise return -1 static int morphcmp(const char* s, const char* t) { int se = 0; int te = 0; const char* sl; const char* tl; const char* olds; const char* oldt; if (!s || !t) return 1; olds = s; sl = strchr(s, '\n'); s = strstr(s, MORPH_DERI_SFX); if (!s || (sl && sl < s)) s = strstr(olds, MORPH_INFL_SFX); if (!s || (sl && sl < s)) { s = strstr(olds, MORPH_TERM_SFX); olds = NULL; } oldt = t; tl = strchr(t, '\n'); t = strstr(t, MORPH_DERI_SFX); if (!t || (tl && tl < t)) t = strstr(oldt, MORPH_INFL_SFX); if (!t || (tl && tl < t)) { t = strstr(oldt, MORPH_TERM_SFX); oldt = NULL; } while (s && t && (!sl || sl > s) && (!tl || tl > t)) { s += MORPH_TAG_LEN; t += MORPH_TAG_LEN; se = 0; te = 0; while ((*s == *t) && !se && !te) { s++; t++; switch (*s) { case ' ': case '\n': case '\t': case '\0': se = 1; } switch (*t) { case ' ': case '\n': case '\t': case '\0': te = 1; } } if (!se || !te) { // not terminal suffix difference if (olds) return -1; return 1; } olds = s; s = strstr(s, MORPH_DERI_SFX); if (!s || (sl && sl < s)) s = strstr(olds, MORPH_INFL_SFX); if (!s || (sl && sl < s)) { s = strstr(olds, MORPH_TERM_SFX); olds = NULL; } oldt = t; t = strstr(t, MORPH_DERI_SFX); if (!t || (tl && tl < t)) t = strstr(oldt, MORPH_INFL_SFX); if (!t || (tl && tl < t)) { t = strstr(oldt, MORPH_TERM_SFX); oldt = NULL; } } if (!s && !t && se && te) return 0; return 1; } std::string AffixMgr::morphgen(const char* ts, int wl, const unsigned short* ap, unsigned short al, const char* morph, const char* targetmorph, int level) { // handle suffixes if (!morph) return std::string(); // check substandard flag if (TESTAFF(ap, substandard, al)) return std::string(); if (morphcmp(morph, targetmorph) == 0) return ts; size_t stemmorphcatpos; std::string mymorph; // use input suffix fields, if exist if (strstr(morph, MORPH_INFL_SFX) || strstr(morph, MORPH_DERI_SFX)) { mymorph.assign(morph); mymorph.push_back(MSEP_FLD); stemmorphcatpos = mymorph.size(); } else { stemmorphcatpos = std::string::npos; } for (int i = 0; i < al; i++) { const unsigned char c = (unsigned char)(ap[i] & 0x00FF); SfxEntry* sptr = sFlag[c]; while (sptr) { if (sptr->getFlag() == ap[i] && sptr->getMorph() && ((sptr->getContLen() == 0) || // don't generate forms with substandard affixes !TESTAFF(sptr->getCont(), substandard, sptr->getContLen()))) { const char* stemmorph; if (stemmorphcatpos != std::string::npos) { mymorph.replace(stemmorphcatpos, std::string::npos, sptr->getMorph()); stemmorph = mymorph.c_str(); } else { stemmorph = sptr->getMorph(); } int cmp = morphcmp(stemmorph, targetmorph); if (cmp == 0) { std::string newword = sptr->add(ts, wl); if (!newword.empty()) { hentry* check = pHMgr->lookup(newword.c_str()); // XXX extra dic if (!check || !check->astr || !(TESTAFF(check->astr, forbiddenword, check->alen) || TESTAFF(check->astr, ONLYUPCASEFLAG, check->alen))) { return newword; } } } // recursive call for secondary suffixes if ((level == 0) && (cmp == 1) && (sptr->getContLen() > 0) && !TESTAFF(sptr->getCont(), substandard, sptr->getContLen())) { std::string newword = sptr->add(ts, wl); if (!newword.empty()) { std::string newword2 = morphgen(newword.c_str(), newword.size(), sptr->getCont(), sptr->getContLen(), stemmorph, targetmorph, 1); if (!newword2.empty()) { return newword2; } } } } sptr = sptr->getFlgNxt(); } } return std::string(); } int AffixMgr::expand_rootword(struct guessword* wlst, int maxn, const char* ts, int wl, const unsigned short* ap, unsigned short al, const char* bad, int badl, const char* phon) { int nh = 0; // first add root word to list if ((nh < maxn) && !(al && ((needaffix && TESTAFF(ap, needaffix, al)) || (onlyincompound && TESTAFF(ap, onlyincompound, al))))) { wlst[nh].word = mystrdup(ts); if (!wlst[nh].word) return 0; wlst[nh].allow = false; wlst[nh].orig = NULL; nh++; // add special phonetic version if (phon && (nh < maxn)) { wlst[nh].word = mystrdup(phon); if (!wlst[nh].word) return nh - 1; wlst[nh].allow = false; wlst[nh].orig = mystrdup(ts); if (!wlst[nh].orig) return nh - 1; nh++; } } // handle suffixes for (int i = 0; i < al; i++) { const unsigned char c = (unsigned char)(ap[i] & 0x00FF); SfxEntry* sptr = sFlag[c]; while (sptr) { if ((sptr->getFlag() == ap[i]) && (!sptr->getKeyLen() || ((badl > sptr->getKeyLen()) && (strcmp(sptr->getAffix(), bad + badl - sptr->getKeyLen()) == 0))) && // check needaffix flag !(sptr->getCont() && ((needaffix && TESTAFF(sptr->getCont(), needaffix, sptr->getContLen())) || (circumfix && TESTAFF(sptr->getCont(), circumfix, sptr->getContLen())) || (onlyincompound && TESTAFF(sptr->getCont(), onlyincompound, sptr->getContLen()))))) { std::string newword = sptr->add(ts, wl); if (!newword.empty()) { if (nh < maxn) { wlst[nh].word = mystrdup(newword.c_str()); wlst[nh].allow = sptr->allowCross(); wlst[nh].orig = NULL; nh++; // add special phonetic version if (phon && (nh < maxn)) { std::string prefix(phon); std::string key(sptr->getKey()); reverseword(key); prefix.append(key); wlst[nh].word = mystrdup(prefix.c_str()); if (!wlst[nh].word) return nh - 1; wlst[nh].allow = false; wlst[nh].orig = mystrdup(newword.c_str()); if (!wlst[nh].orig) return nh - 1; nh++; } } } } sptr = sptr->getFlgNxt(); } } int n = nh; // handle cross products of prefixes and suffixes for (int j = 1; j < n; j++) if (wlst[j].allow) { for (int k = 0; k < al; k++) { const unsigned char c = (unsigned char)(ap[k] & 0x00FF); PfxEntry* cptr = pFlag[c]; while (cptr) { if ((cptr->getFlag() == ap[k]) && cptr->allowCross() && (!cptr->getKeyLen() || ((badl > cptr->getKeyLen()) && (strncmp(cptr->getKey(), bad, cptr->getKeyLen()) == 0)))) { int l1 = strlen(wlst[j].word); std::string newword = cptr->add(wlst[j].word, l1); if (!newword.empty()) { if (nh < maxn) { wlst[nh].word = mystrdup(newword.c_str()); wlst[nh].allow = cptr->allowCross(); wlst[nh].orig = NULL; nh++; } } } cptr = cptr->getFlgNxt(); } } } // now handle pure prefixes for (int m = 0; m < al; m++) { const unsigned char c = (unsigned char)(ap[m] & 0x00FF); PfxEntry* ptr = pFlag[c]; while (ptr) { if ((ptr->getFlag() == ap[m]) && (!ptr->getKeyLen() || ((badl > ptr->getKeyLen()) && (strncmp(ptr->getKey(), bad, ptr->getKeyLen()) == 0))) && // check needaffix flag !(ptr->getCont() && ((needaffix && TESTAFF(ptr->getCont(), needaffix, ptr->getContLen())) || (circumfix && TESTAFF(ptr->getCont(), circumfix, ptr->getContLen())) || (onlyincompound && TESTAFF(ptr->getCont(), onlyincompound, ptr->getContLen()))))) { std::string newword = ptr->add(ts, wl); if (!newword.empty()) { if (nh < maxn) { wlst[nh].word = mystrdup(newword.c_str()); wlst[nh].allow = ptr->allowCross(); wlst[nh].orig = NULL; nh++; } } } ptr = ptr->getFlgNxt(); } } return nh; } // return replacing table const std::vector& AffixMgr::get_reptable() const { return pHMgr->get_reptable(); } // return iconv table RepList* AffixMgr::get_iconvtable() const { if (!iconvtable) return NULL; return iconvtable; } // return oconv table RepList* AffixMgr::get_oconvtable() const { if (!oconvtable) return NULL; return oconvtable; } // return replacing table struct phonetable* AffixMgr::get_phonetable() const { if (!phone) return NULL; return phone; } // return character map table const std::vector& AffixMgr::get_maptable() const { return maptable; } // return character map table const std::vector& AffixMgr::get_breaktable() const { return breaktable; } // return text encoding of dictionary const std::string& AffixMgr::get_encoding() { if (encoding.empty()) encoding = SPELL_ENCODING; return encoding; } // return text encoding of dictionary int AffixMgr::get_langnum() const { return langnum; } // return double prefix option int AffixMgr::get_complexprefixes() const { return complexprefixes; } // return FULLSTRIP option int AffixMgr::get_fullstrip() const { return fullstrip; } FLAG AffixMgr::get_keepcase() const { return keepcase; } FLAG AffixMgr::get_forceucase() const { return forceucase; } FLAG AffixMgr::get_warn() const { return warn; } int AffixMgr::get_forbidwarn() const { return forbidwarn; } int AffixMgr::get_checksharps() const { return checksharps; } char* AffixMgr::encode_flag(unsigned short aflag) const { return pHMgr->encode_flag(aflag); } // return the preferred ignore string for suggestions const char* AffixMgr::get_ignore() const { if (ignorechars.empty()) return NULL; return ignorechars.c_str(); } // return the preferred ignore string for suggestions const std::vector& AffixMgr::get_ignore_utf16() const { return ignorechars_utf16; } // return the keyboard string for suggestions char* AffixMgr::get_key_string() { if (keystring.empty()) keystring = SPELL_KEYSTRING; return mystrdup(keystring.c_str()); } // return the preferred try string for suggestions char* AffixMgr::get_try_string() const { if (trystring.empty()) return NULL; return mystrdup(trystring.c_str()); } // return the preferred try string for suggestions const std::string& AffixMgr::get_wordchars() const { return wordchars; } const std::vector& AffixMgr::get_wordchars_utf16() const { return wordchars_utf16; } // is there compounding? int AffixMgr::get_compound() const { return compoundflag || compoundbegin || !defcpdtable.empty(); } // return the compound words control flag FLAG AffixMgr::get_compoundflag() const { return compoundflag; } // return the forbidden words control flag FLAG AffixMgr::get_forbiddenword() const { return forbiddenword; } // return the forbidden words control flag FLAG AffixMgr::get_nosuggest() const { return nosuggest; } // return the forbidden words control flag FLAG AffixMgr::get_nongramsuggest() const { return nongramsuggest; } // return the substandard root/affix control flag FLAG AffixMgr::get_substandard() const { return substandard; } // return the forbidden words flag modify flag FLAG AffixMgr::get_needaffix() const { return needaffix; } // return the onlyincompound flag FLAG AffixMgr::get_onlyincompound() const { return onlyincompound; } // return the value of suffix const std::string& AffixMgr::get_version() const { return version; } // utility method to look up root words in hash table struct hentry* AffixMgr::lookup(const char* word) { struct hentry* he = NULL; for (size_t i = 0; i < alldic.size() && !he; ++i) { he = alldic[i]->lookup(word); } return he; } // return the value of suffix int AffixMgr::have_contclass() const { return havecontclass; } // return utf8 int AffixMgr::get_utf8() const { return utf8; } int AffixMgr::get_maxngramsugs(void) const { return maxngramsugs; } int AffixMgr::get_maxcpdsugs(void) const { return maxcpdsugs; } int AffixMgr::get_maxdiff(void) const { return maxdiff; } int AffixMgr::get_onlymaxdiff(void) const { return onlymaxdiff; } // return nosplitsugs int AffixMgr::get_nosplitsugs(void) const { return nosplitsugs; } // return sugswithdots int AffixMgr::get_sugswithdots(void) const { return sugswithdots; } /* parse flag */ bool AffixMgr::parse_flag(const std::string& line, unsigned short* out, FileMgr* af) { if (*out != FLAG_NULL && !(*out >= DEFAULTFLAGS)) { HUNSPELL_WARNING( stderr, "error: line %d: multiple definitions of an affix file parameter\n", af->getlinenum()); return false; } std::string s; if (!parse_string(line, s, af->getlinenum())) return false; *out = pHMgr->decode_flag(s.c_str()); return true; } /* parse num */ bool AffixMgr::parse_num(const std::string& line, int* out, FileMgr* af) { if (*out != -1) { HUNSPELL_WARNING( stderr, "error: line %d: multiple definitions of an affix file parameter\n", af->getlinenum()); return false; } std::string s; if (!parse_string(line, s, af->getlinenum())) return false; *out = atoi(s.c_str()); return true; } /* parse in the max syllablecount of compound words and */ bool AffixMgr::parse_cpdsyllable(const std::string& line, FileMgr* af) { int i = 0; int np = 0; std::string::const_iterator iter = line.begin(); std::string::const_iterator start_piece = mystrsep(line, iter); while (start_piece != line.end()) { switch (i) { case 0: { np++; break; } case 1: { cpdmaxsyllable = atoi(std::string(start_piece, iter).c_str()); np++; break; } case 2: { if (!utf8) { cpdvowels.assign(start_piece, iter); std::sort(cpdvowels.begin(), cpdvowels.end()); } else { std::string piece(start_piece, iter); u8_u16(cpdvowels_utf16, piece); std::sort(cpdvowels_utf16.begin(), cpdvowels_utf16.end()); } np++; break; } default: break; } ++i; start_piece = mystrsep(line, iter); } if (np < 2) { HUNSPELL_WARNING(stderr, "error: line %d: missing compoundsyllable information\n", af->getlinenum()); return false; } if (np == 2) cpdvowels = "AEIOUaeiou"; return true; } bool AffixMgr::parse_convtable(const std::string& line, FileMgr* af, RepList** rl, const std::string& keyword) { if (*rl) { HUNSPELL_WARNING(stderr, "error: line %d: multiple table definitions\n", af->getlinenum()); return false; } int i = 0; int np = 0; int numrl = 0; std::string::const_iterator iter = line.begin(); std::string::const_iterator start_piece = mystrsep(line, iter); while (start_piece != line.end()) { switch (i) { case 0: { np++; break; } case 1: { numrl = atoi(std::string(start_piece, iter).c_str()); if (numrl < 1) { HUNSPELL_WARNING(stderr, "error: line %d: incorrect entry number\n", af->getlinenum()); return false; } *rl = new RepList(numrl); if (!*rl) return false; np++; break; } default: break; } ++i; start_piece = mystrsep(line, iter); } if (np != 2) { HUNSPELL_WARNING(stderr, "error: line %d: missing data\n", af->getlinenum()); return false; } /* now parse the num lines to read in the remainder of the table */ for (int j = 0; j < numrl; j++) { std::string nl; if (!af->getline(nl)) return false; mychomp(nl); i = 0; std::string pattern; std::string pattern2; iter = nl.begin(); start_piece = mystrsep(nl, iter); while (start_piece != nl.end()) { { switch (i) { case 0: { if (nl.compare(start_piece - nl.begin(), keyword.size(), keyword, 0, keyword.size()) != 0) { HUNSPELL_WARNING(stderr, "error: line %d: table is corrupt\n", af->getlinenum()); delete *rl; *rl = NULL; return false; } break; } case 1: { pattern.assign(start_piece, iter); break; } case 2: { pattern2.assign(start_piece, iter); break; } default: break; } ++i; } start_piece = mystrsep(nl, iter); } if (pattern.empty() || pattern2.empty()) { HUNSPELL_WARNING(stderr, "error: line %d: table is corrupt\n", af->getlinenum()); return false; } (*rl)->add(pattern, pattern2); } return true; } /* parse in the typical fault correcting table */ bool AffixMgr::parse_phonetable(const std::string& line, FileMgr* af) { if (phone) { HUNSPELL_WARNING(stderr, "error: line %d: multiple table definitions\n", af->getlinenum()); return false; } int num = -1; int i = 0; int np = 0; std::string::const_iterator iter = line.begin(); std::string::const_iterator start_piece = mystrsep(line, iter); while (start_piece != line.end()) { switch (i) { case 0: { np++; break; } case 1: { num = atoi(std::string(start_piece, iter).c_str()); if (num < 1) { HUNSPELL_WARNING(stderr, "error: line %d: bad entry number\n", af->getlinenum()); return false; } phone = new phonetable; phone->utf8 = (char)utf8; np++; break; } default: break; } ++i; start_piece = mystrsep(line, iter); } if (np != 2) { HUNSPELL_WARNING(stderr, "error: line %d: missing data\n", af->getlinenum()); return false; } /* now parse the phone->num lines to read in the remainder of the table */ for (int j = 0; j < num; ++j) { std::string nl; if (!af->getline(nl)) return false; mychomp(nl); i = 0; const size_t old_size = phone->rules.size(); iter = nl.begin(); start_piece = mystrsep(nl, iter); while (start_piece != nl.end()) { { switch (i) { case 0: { if (nl.compare(start_piece - nl.begin(), 5, "PHONE", 5) != 0) { HUNSPELL_WARNING(stderr, "error: line %d: table is corrupt\n", af->getlinenum()); return false; } break; } case 1: { phone->rules.push_back(std::string(start_piece, iter)); break; } case 2: { phone->rules.push_back(std::string(start_piece, iter)); mystrrep(phone->rules.back(), "_", ""); break; } default: break; } ++i; } start_piece = mystrsep(nl, iter); } if (phone->rules.size() != old_size + 2) { HUNSPELL_WARNING(stderr, "error: line %d: table is corrupt\n", af->getlinenum()); phone->rules.clear(); return false; } } phone->rules.push_back(""); phone->rules.push_back(""); init_phonet_hash(*phone); return true; } /* parse in the checkcompoundpattern table */ bool AffixMgr::parse_checkcpdtable(const std::string& line, FileMgr* af) { if (parsedcheckcpd) { HUNSPELL_WARNING(stderr, "error: line %d: multiple table definitions\n", af->getlinenum()); return false; } parsedcheckcpd = true; int numcheckcpd = -1; int i = 0; int np = 0; std::string::const_iterator iter = line.begin(); std::string::const_iterator start_piece = mystrsep(line, iter); while (start_piece != line.end()) { switch (i) { case 0: { np++; break; } case 1: { numcheckcpd = atoi(std::string(start_piece, iter).c_str()); if (numcheckcpd < 1) { HUNSPELL_WARNING(stderr, "error: line %d: bad entry number\n", af->getlinenum()); return false; } checkcpdtable.reserve(numcheckcpd); np++; break; } default: break; } ++i; start_piece = mystrsep(line, iter); } if (np != 2) { HUNSPELL_WARNING(stderr, "error: line %d: missing data\n", af->getlinenum()); return false; } /* now parse the numcheckcpd lines to read in the remainder of the table */ for (int j = 0; j < numcheckcpd; ++j) { std::string nl; if (!af->getline(nl)) return false; mychomp(nl); i = 0; checkcpdtable.push_back(patentry()); iter = nl.begin(); start_piece = mystrsep(nl, iter); while (start_piece != nl.end()) { switch (i) { case 0: { if (nl.compare(start_piece - nl.begin(), 20, "CHECKCOMPOUNDPATTERN", 20) != 0) { HUNSPELL_WARNING(stderr, "error: line %d: table is corrupt\n", af->getlinenum()); return false; } break; } case 1: { checkcpdtable.back().pattern.assign(start_piece, iter); size_t slash_pos = checkcpdtable.back().pattern.find('/'); if (slash_pos != std::string::npos) { std::string chunk(checkcpdtable.back().pattern, slash_pos + 1); checkcpdtable.back().pattern.resize(slash_pos); checkcpdtable.back().cond = pHMgr->decode_flag(chunk.c_str()); } break; } case 2: { checkcpdtable.back().pattern2.assign(start_piece, iter); size_t slash_pos = checkcpdtable.back().pattern2.find('/'); if (slash_pos != std::string::npos) { std::string chunk(checkcpdtable.back().pattern2, slash_pos + 1); checkcpdtable.back().pattern2.resize(slash_pos); checkcpdtable.back().cond2 = pHMgr->decode_flag(chunk.c_str()); } break; } case 3: { checkcpdtable.back().pattern3.assign(start_piece, iter); simplifiedcpd = 1; break; } default: break; } i++; start_piece = mystrsep(nl, iter); } } return true; } /* parse in the compound rule table */ bool AffixMgr::parse_defcpdtable(const std::string& line, FileMgr* af) { if (parseddefcpd) { HUNSPELL_WARNING(stderr, "error: line %d: multiple table definitions\n", af->getlinenum()); return false; } parseddefcpd = true; int numdefcpd = -1; int i = 0; int np = 0; std::string::const_iterator iter = line.begin(); std::string::const_iterator start_piece = mystrsep(line, iter); while (start_piece != line.end()) { switch (i) { case 0: { np++; break; } case 1: { numdefcpd = atoi(std::string(start_piece, iter).c_str()); if (numdefcpd < 1) { HUNSPELL_WARNING(stderr, "error: line %d: bad entry number\n", af->getlinenum()); return false; } defcpdtable.reserve(numdefcpd); np++; break; } default: break; } ++i; start_piece = mystrsep(line, iter); } if (np != 2) { HUNSPELL_WARNING(stderr, "error: line %d: missing data\n", af->getlinenum()); return false; } /* now parse the numdefcpd lines to read in the remainder of the table */ for (int j = 0; j < numdefcpd; ++j) { std::string nl; if (!af->getline(nl)) return false; mychomp(nl); i = 0; defcpdtable.push_back(flagentry()); iter = nl.begin(); start_piece = mystrsep(nl, iter); while (start_piece != nl.end()) { switch (i) { case 0: { if (nl.compare(start_piece - nl.begin(), 12, "COMPOUNDRULE", 12) != 0) { HUNSPELL_WARNING(stderr, "error: line %d: table is corrupt\n", af->getlinenum()); numdefcpd = 0; return false; } break; } case 1: { // handle parenthesized flags if (std::find(start_piece, iter, '(') != iter) { for (std::string::const_iterator k = start_piece; k != iter; ++k) { std::string::const_iterator chb = k; std::string::const_iterator che = k + 1; if (*k == '(') { std::string::const_iterator parpos = std::find(k, iter, ')'); if (parpos != iter) { chb = k + 1; che = parpos; k = parpos; } } if (*chb == '*' || *chb == '?') { defcpdtable.back().push_back((FLAG)*chb); } else { pHMgr->decode_flags(defcpdtable.back(), std::string(chb, che), af); } } } else { pHMgr->decode_flags(defcpdtable.back(), std::string(start_piece, iter), af); } break; } default: break; } ++i; start_piece = mystrsep(nl, iter); } if (defcpdtable.back().empty()) { HUNSPELL_WARNING(stderr, "error: line %d: table is corrupt\n", af->getlinenum()); return false; } } return true; } /* parse in the character map table */ bool AffixMgr::parse_maptable(const std::string& line, FileMgr* af) { if (parsedmaptable) { HUNSPELL_WARNING(stderr, "error: line %d: multiple table definitions\n", af->getlinenum()); return false; } parsedmaptable = true; int nummap = -1; int i = 0; int np = 0; std::string::const_iterator iter = line.begin(); std::string::const_iterator start_piece = mystrsep(line, iter); while (start_piece != line.end()) { switch (i) { case 0: { np++; break; } case 1: { nummap = atoi(std::string(start_piece, iter).c_str()); if (nummap < 1) { HUNSPELL_WARNING(stderr, "error: line %d: bad entry number\n", af->getlinenum()); return false; } maptable.reserve(nummap); np++; break; } default: break; } ++i; start_piece = mystrsep(line, iter); } if (np != 2) { HUNSPELL_WARNING(stderr, "error: line %d: missing data\n", af->getlinenum()); return false; } /* now parse the nummap lines to read in the remainder of the table */ for (int j = 0; j < nummap; ++j) { std::string nl; if (!af->getline(nl)) return false; mychomp(nl); i = 0; maptable.push_back(mapentry()); iter = nl.begin(); start_piece = mystrsep(nl, iter); while (start_piece != nl.end()) { switch (i) { case 0: { if (nl.compare(start_piece - nl.begin(), 3, "MAP", 3) != 0) { HUNSPELL_WARNING(stderr, "error: line %d: table is corrupt\n", af->getlinenum()); nummap = 0; return false; } break; } case 1: { for (std::string::const_iterator k = start_piece; k != iter; ++k) { std::string::const_iterator chb = k; std::string::const_iterator che = k + 1; if (*k == '(') { std::string::const_iterator parpos = std::find(k, iter, ')'); if (parpos != iter) { chb = k + 1; che = parpos; k = parpos; } } else { if (utf8 && (*k & 0xc0) == 0xc0) { ++k; while (k != iter && (*k & 0xc0) == 0x80) ++k; che = k; --k; } } maptable.back().push_back(std::string(chb, che)); } break; } default: break; } ++i; start_piece = mystrsep(nl, iter); } if (maptable.back().empty()) { HUNSPELL_WARNING(stderr, "error: line %d: table is corrupt\n", af->getlinenum()); return false; } } return true; } /* parse in the word breakpoint table */ bool AffixMgr::parse_breaktable(const std::string& line, FileMgr* af) { if (parsedbreaktable) { HUNSPELL_WARNING(stderr, "error: line %d: multiple table definitions\n", af->getlinenum()); return false; } parsedbreaktable = true; int numbreak = -1; int i = 0; int np = 0; std::string::const_iterator iter = line.begin(); std::string::const_iterator start_piece = mystrsep(line, iter); while (start_piece != line.end()) { switch (i) { case 0: { np++; break; } case 1: { numbreak = atoi(std::string(start_piece, iter).c_str()); if (numbreak < 0) { HUNSPELL_WARNING(stderr, "error: line %d: bad entry number\n", af->getlinenum()); return false; } if (numbreak == 0) return true; breaktable.reserve(numbreak); np++; break; } default: break; } ++i; start_piece = mystrsep(line, iter); } if (np != 2) { HUNSPELL_WARNING(stderr, "error: line %d: missing data\n", af->getlinenum()); return false; } /* now parse the numbreak lines to read in the remainder of the table */ for (int j = 0; j < numbreak; ++j) { std::string nl; if (!af->getline(nl)) return false; mychomp(nl); i = 0; iter = nl.begin(); start_piece = mystrsep(nl, iter); while (start_piece != nl.end()) { switch (i) { case 0: { if (nl.compare(start_piece - nl.begin(), 5, "BREAK", 5) != 0) { HUNSPELL_WARNING(stderr, "error: line %d: table is corrupt\n", af->getlinenum()); numbreak = 0; return false; } break; } case 1: { breaktable.push_back(std::string(start_piece, iter)); break; } default: break; } ++i; start_piece = mystrsep(nl, iter); } } if (breaktable.size() != static_cast(numbreak)) { HUNSPELL_WARNING(stderr, "error: line %d: table is corrupt\n", af->getlinenum()); return false; } return true; } void AffixMgr::reverse_condition(std::string& piece) { if (piece.empty()) return; int neg = 0; for (std::string::reverse_iterator k = piece.rbegin(); k != piece.rend(); ++k) { switch (*k) { case '[': { if (neg) *(k - 1) = '['; else *k = ']'; break; } case ']': { *k = '['; if (neg) *(k - 1) = '^'; neg = 0; break; } case '^': { if (*(k - 1) == ']') neg = 1; else *(k - 1) = *k; break; } default: { if (neg) *(k - 1) = *k; } } } } class entries_container { std::vector entries; AffixMgr* m_mgr; char m_at; public: entries_container(char at, AffixMgr* mgr) : m_mgr(mgr) , m_at(at) { } void release() { entries.clear(); } void initialize(int numents, char opts, unsigned short aflag) { entries.reserve(numents); if (m_at == 'P') { entries.push_back(new PfxEntry(m_mgr)); } else { entries.push_back(new SfxEntry(m_mgr)); } entries.back()->opts = opts; entries.back()->aflag = aflag; } AffEntry* add_entry(char opts) { if (m_at == 'P') { entries.push_back(new PfxEntry(m_mgr)); } else { entries.push_back(new SfxEntry(m_mgr)); } AffEntry* ret = entries.back(); ret->opts = entries[0]->opts & opts; return ret; } AffEntry* first_entry() { return entries.empty() ? NULL : entries[0]; } ~entries_container() { for (size_t i = 0; i < entries.size(); ++i) { delete entries[i]; } } std::vector::iterator begin() { return entries.begin(); } std::vector::iterator end() { return entries.end(); } }; bool AffixMgr::parse_affix(const std::string& line, const char at, FileMgr* af, char* dupflags) { int numents = 0; // number of AffEntry structures to parse unsigned short aflag = 0; // affix char identifier char ff = 0; entries_container affentries(at, this); int i = 0; // checking lines with bad syntax #ifdef DEBUG int basefieldnum = 0; #endif // split affix header line into pieces int np = 0; std::string::const_iterator iter = line.begin(); std::string::const_iterator start_piece = mystrsep(line, iter); while (start_piece != line.end()) { switch (i) { // piece 1 - is type of affix case 0: { np++; break; } // piece 2 - is affix char case 1: { np++; aflag = pHMgr->decode_flag(std::string(start_piece, iter).c_str()); if (((at == 'S') && (dupflags[aflag] & dupSFX)) || ((at == 'P') && (dupflags[aflag] & dupPFX))) { HUNSPELL_WARNING( stderr, "error: line %d: multiple definitions of an affix flag\n", af->getlinenum()); } dupflags[aflag] += (char)((at == 'S') ? dupSFX : dupPFX); break; } // piece 3 - is cross product indicator case 2: { np++; if (*start_piece == 'Y') ff = aeXPRODUCT; break; } // piece 4 - is number of affentries case 3: { np++; numents = atoi(std::string(start_piece, iter).c_str()); if ((numents <= 0) || ((std::numeric_limits::max() / sizeof(AffEntry)) < static_cast(numents))) { char* err = pHMgr->encode_flag(aflag); if (err) { HUNSPELL_WARNING(stderr, "error: line %d: bad entry number\n", af->getlinenum()); free(err); } return false; } char opts = ff; if (utf8) opts += aeUTF8; if (pHMgr->is_aliasf()) opts += aeALIASF; if (pHMgr->is_aliasm()) opts += aeALIASM; affentries.initialize(numents, opts, aflag); } default: break; } ++i; start_piece = mystrsep(line, iter); } // check to make sure we parsed enough pieces if (np != 4) { char* err = pHMgr->encode_flag(aflag); if (err) { HUNSPELL_WARNING(stderr, "error: line %d: missing data\n", af->getlinenum()); free(err); } return false; } // now parse numents affentries for this affix AffEntry* entry = affentries.first_entry(); for (int ent = 0; ent < numents; ++ent) { std::string nl; if (!af->getline(nl)) return false; mychomp(nl); iter = nl.begin(); i = 0; np = 0; // split line into pieces start_piece = mystrsep(nl, iter); while (start_piece != nl.end()) { switch (i) { // piece 1 - is type case 0: { np++; if (ent != 0) entry = affentries.add_entry((char)(aeXPRODUCT + aeUTF8 + aeALIASF + aeALIASM)); break; } // piece 2 - is affix char case 1: { np++; std::string chunk(start_piece, iter); if (pHMgr->decode_flag(chunk.c_str()) != aflag) { char* err = pHMgr->encode_flag(aflag); if (err) { HUNSPELL_WARNING(stderr, "error: line %d: affix %s is corrupt\n", af->getlinenum(), err); free(err); } return false; } if (ent != 0) { AffEntry* start_entry = affentries.first_entry(); entry->aflag = start_entry->aflag; } break; } // piece 3 - is string to strip or 0 for null case 2: { np++; entry->strip = std::string(start_piece, iter); if (complexprefixes) { if (utf8) reverseword_utf(entry->strip); else reverseword(entry->strip); } if (entry->strip.compare("0") == 0) { entry->strip.clear(); } break; } // piece 4 - is affix string or 0 for null case 3: { entry->morphcode = NULL; entry->contclass = NULL; entry->contclasslen = 0; np++; std::string::const_iterator dash = std::find(start_piece, iter, '/'); if (dash != iter) { entry->appnd = std::string(start_piece, dash); std::string dash_str(dash + 1, iter); if (!ignorechars.empty() && !has_no_ignored_chars(entry->appnd, ignorechars)) { if (utf8) { remove_ignored_chars_utf(entry->appnd, ignorechars_utf16); } else { remove_ignored_chars(entry->appnd, ignorechars); } } if (complexprefixes) { if (utf8) reverseword_utf(entry->appnd); else reverseword(entry->appnd); } if (pHMgr->is_aliasf()) { int index = atoi(dash_str.c_str()); entry->contclasslen = (unsigned short)pHMgr->get_aliasf( index, &(entry->contclass), af); if (!entry->contclasslen) HUNSPELL_WARNING(stderr, "error: bad affix flag alias: \"%s\"\n", dash_str.c_str()); } else { entry->contclasslen = (unsigned short)pHMgr->decode_flags( &(entry->contclass), dash_str.c_str(), af); std::sort(entry->contclass, entry->contclass + entry->contclasslen); } havecontclass = 1; for (unsigned short _i = 0; _i < entry->contclasslen; _i++) { contclasses[(entry->contclass)[_i]] = 1; } } else { entry->appnd = std::string(start_piece, iter); if (!ignorechars.empty() && !has_no_ignored_chars(entry->appnd, ignorechars)) { if (utf8) { remove_ignored_chars_utf(entry->appnd, ignorechars_utf16); } else { remove_ignored_chars(entry->appnd, ignorechars); } } if (complexprefixes) { if (utf8) reverseword_utf(entry->appnd); else reverseword(entry->appnd); } } if (entry->appnd.compare("0") == 0) { entry->appnd.clear(); } break; } // piece 5 - is the conditions descriptions case 4: { std::string chunk(start_piece, iter); np++; if (complexprefixes) { if (utf8) reverseword_utf(chunk); else reverseword(chunk); reverse_condition(chunk); } if (!entry->strip.empty() && chunk != "." && redundant_condition(at, entry->strip.c_str(), entry->strip.size(), chunk.c_str(), af->getlinenum())) chunk = "."; if (at == 'S') { reverseword(chunk); reverse_condition(chunk); } if (encodeit(*entry, chunk.c_str())) return false; break; } case 5: { std::string chunk(start_piece, iter); np++; if (pHMgr->is_aliasm()) { int index = atoi(chunk.c_str()); entry->morphcode = pHMgr->get_aliasm(index); } else { if (complexprefixes) { // XXX - fix me for morph. gen. if (utf8) reverseword_utf(chunk); else reverseword(chunk); } // add the remaining of the line std::string::const_iterator end = nl.end(); if (iter != end) { chunk.append(iter, end); } entry->morphcode = mystrdup(chunk.c_str()); if (!entry->morphcode) return false; } break; } default: break; } i++; start_piece = mystrsep(nl, iter); } // check to make sure we parsed enough pieces if (np < 4) { char* err = pHMgr->encode_flag(aflag); if (err) { HUNSPELL_WARNING(stderr, "error: line %d: affix %s is corrupt\n", af->getlinenum(), err); free(err); } return false; } #ifdef DEBUG // detect unnecessary fields, excepting comments if (basefieldnum) { int fieldnum = !(entry->morphcode) ? 5 : ((*(entry->morphcode) == '#') ? 5 : 6); if (fieldnum != basefieldnum) HUNSPELL_WARNING(stderr, "warning: line %d: bad field number\n", af->getlinenum()); } else { basefieldnum = !(entry->morphcode) ? 5 : ((*(entry->morphcode) == '#') ? 5 : 6); } #endif } // now create SfxEntry or PfxEntry objects and use links to // build an ordered (sorted by affix string) list std::vector::iterator start = affentries.begin(); std::vector::iterator end = affentries.end(); for (std::vector::iterator affentry = start; affentry != end; ++affentry) { if (at == 'P') { build_pfxtree(static_cast(*affentry)); } else { build_sfxtree(static_cast(*affentry)); } } //contents belong to AffixMgr now affentries.release(); return true; } int AffixMgr::redundant_condition(char ft, const char* strip, int stripl, const char* cond, int linenum) { int condl = strlen(cond); int i; int j; int neg; int in; if (ft == 'P') { // prefix if (strncmp(strip, cond, condl) == 0) return 1; if (utf8) { } else { for (i = 0, j = 0; (i < stripl) && (j < condl); i++, j++) { if (cond[j] != '[') { if (cond[j] != strip[i]) { HUNSPELL_WARNING(stderr, "warning: line %d: incompatible stripping " "characters and condition\n", linenum); return 0; } } else { neg = (cond[j + 1] == '^') ? 1 : 0; in = 0; do { j++; if (strip[i] == cond[j]) in = 1; } while ((j < (condl - 1)) && (cond[j] != ']')); if (j == (condl - 1) && (cond[j] != ']')) { HUNSPELL_WARNING(stderr, "error: line %d: missing ] in condition:\n%s\n", linenum, cond); return 0; } if ((!neg && !in) || (neg && in)) { HUNSPELL_WARNING(stderr, "warning: line %d: incompatible stripping " "characters and condition\n", linenum); return 0; } } } if (j >= condl) return 1; } } else { // suffix if ((stripl >= condl) && strcmp(strip + stripl - condl, cond) == 0) return 1; if (utf8) { } else { for (i = stripl - 1, j = condl - 1; (i >= 0) && (j >= 0); i--, j--) { if (cond[j] != ']') { if (cond[j] != strip[i]) { HUNSPELL_WARNING(stderr, "warning: line %d: incompatible stripping " "characters and condition\n", linenum); return 0; } } else { in = 0; do { j--; if (strip[i] == cond[j]) in = 1; } while ((j > 0) && (cond[j] != '[')); if ((j == 0) && (cond[j] != '[')) { HUNSPELL_WARNING(stderr, "error: line: %d: missing ] in condition:\n%s\n", linenum, cond); return 0; } neg = (cond[j + 1] == '^') ? 1 : 0; if ((!neg && !in) || (neg && in)) { HUNSPELL_WARNING(stderr, "warning: line %d: incompatible stripping " "characters and condition\n", linenum); return 0; } } } if (j < 0) return 1; } } return 0; } std::vector AffixMgr::get_suffix_words(short unsigned* suff, int len, const char* root_word) { std::vector slst; short unsigned* start_ptr = suff; for (int j = 0; j < SETSIZE; j++) { SfxEntry* ptr = sStart[j]; while (ptr) { suff = start_ptr; for (int i = 0; i < len; i++) { if ((*suff) == ptr->getFlag()) { std::string nw(root_word); nw.append(ptr->getAffix()); hentry* ht = ptr->checkword(nw.c_str(), nw.size(), 0, NULL, 0, 0, 0); if (ht) { slst.push_back(nw); } } suff++; } ptr = ptr->getNext(); } } return slst; }