/* ***** 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 "affixmgr.hxx" #include "hunspell.hxx" #include "suggestmgr.hxx" #include "hunspell.h" #include "csutil.hxx" #include #include #define MAXWORDUTF8LEN (MAXWORDLEN * 3) class HunspellImpl { public: HunspellImpl(const char* affpath, const char* dpath, const char* key); ~HunspellImpl(); int add_dic(const char* dpath, const char* key); std::vector suffix_suggest(const std::string& root_word); std::vector generate(const std::string& word, const std::vector& pl); std::vector generate(const std::string& word, const std::string& pattern); std::vector stem(const std::string& word); std::vector stem(const std::vector& morph); std::vector analyze(const std::string& word); bool input_conv(const std::string& word, std::string& dest); bool spell(const std::string& word, int* info = NULL, std::string* root = NULL); std::vector suggest(const std::string& word); const std::string& get_wordchars() const; const std::vector& get_wordchars_utf16() const; const std::string& get_dict_encoding() const; int add(const std::string& word); int add_with_affix(const std::string& word, const std::string& example); int remove(const std::string& word); struct cs_info* get_csconv(); std::vector dic_encoding_vec; int get_langnum() const { return langnum; } const char* get_try_string() const { return pAMgr->get_try_string(); } const std::string& get_version() const { return pAMgr->get_version(); } private: AffixMgr* pAMgr; std::vector m_HMgrs; SuggestMgr* pSMgr; char* affixpath; std::string encoding; struct cs_info* csconv; int langnum; int utf8; int complexprefixes; std::vector wordbreak; private: void cleanword(std::string& dest, const std::string&, int* pcaptype, int* pabbrev); size_t cleanword2(std::string& dest, std::vector& dest_u, const std::string& src, int* pcaptype, size_t* pabbrev); void mkinitcap(std::string& u8); int mkinitcap2(std::string& u8, std::vector& u16); int mkinitsmall2(std::string& u8, std::vector& u16); void mkallcap(std::string& u8); int mkallsmall2(std::string& u8, std::vector& u16); struct hentry* checkword(const std::string& source, int* info, std::string* root); std::string sharps_u8_l1(const std::string& source); hentry* spellsharps(std::string& base, size_t start_pos, int, int, int* info, std::string* root); int is_keepcase(const hentry* rv); void insert_sug(std::vector& slst, const std::string& word); void cat_result(std::string& result, const std::string& st); std::vector spellml(const std::string& word); std::string get_xml_par(const char* par); const char* get_xml_pos(const char* s, const char* attr); std::vector get_xml_list(const char* list, const char* tag); int check_xml_par(const char* q, const char* attr, const char* value); private: HunspellImpl(const HunspellImpl&); HunspellImpl& operator=(const HunspellImpl&); }; Hunspell::Hunspell(const char* affpath, const char* dpath, const char* key) : m_Impl(new HunspellImpl(affpath, dpath, key)) { } HunspellImpl::HunspellImpl(const char* affpath, const char* dpath, const char* key) { csconv = NULL; utf8 = 0; complexprefixes = 0; affixpath = mystrdup(affpath); /* first set up the hash manager */ m_HMgrs.push_back(new HashMgr(dpath, affpath, key)); /* next set up the affix manager */ /* it needs access to the hash manager lookup methods */ pAMgr = new AffixMgr(affpath, m_HMgrs, key); /* get the preferred try string and the dictionary */ /* encoding from the Affix Manager for that dictionary */ char* try_string = pAMgr->get_try_string(); encoding = pAMgr->get_encoding(); langnum = pAMgr->get_langnum(); utf8 = pAMgr->get_utf8(); if (!utf8) csconv = get_current_cs(encoding); complexprefixes = pAMgr->get_complexprefixes(); wordbreak = pAMgr->get_breaktable(); dic_encoding_vec.resize(encoding.size()+1); strcpy(&dic_encoding_vec[0], encoding.c_str()); /* and finally set up the suggestion manager */ pSMgr = new SuggestMgr(try_string, MAXSUGGESTION, pAMgr); if (try_string) free(try_string); } Hunspell::~Hunspell() { delete m_Impl; } HunspellImpl::~HunspellImpl() { delete pSMgr; delete pAMgr; for (size_t i = 0; i < m_HMgrs.size(); ++i) delete m_HMgrs[i]; pSMgr = NULL; pAMgr = NULL; #ifdef MOZILLA_CLIENT delete[] csconv; #endif csconv = NULL; if (affixpath) free(affixpath); affixpath = NULL; } // load extra dictionaries int Hunspell::add_dic(const char* dpath, const char* key) { return m_Impl->add_dic(dpath, key); } // load extra dictionaries int HunspellImpl::add_dic(const char* dpath, const char* key) { if (!affixpath) return 1; m_HMgrs.push_back(new HashMgr(dpath, affixpath, key)); return 0; } // make a copy of src at destination while removing all leading // blanks and removing any trailing periods after recording // their presence with the abbreviation flag // also since already going through character by character, // set the capitalization type // return the length of the "cleaned" (and UTF-8 encoded) word size_t HunspellImpl::cleanword2(std::string& dest, std::vector& dest_utf, const std::string& src, int* pcaptype, size_t* pabbrev) { dest.clear(); dest_utf.clear(); const char* q = src.c_str(); // first skip over any leading blanks while (*q == ' ') ++q; // now strip off any trailing periods (recording their presence) *pabbrev = 0; int nl = strlen(q); while ((nl > 0) && (*(q + nl - 1) == '.')) { nl--; (*pabbrev)++; } // if no characters are left it can't be capitalized if (nl <= 0) { *pcaptype = NOCAP; return 0; } dest.append(q, nl); nl = dest.size(); if (utf8) { u8_u16(dest_utf, dest); *pcaptype = get_captype_utf8(dest_utf, langnum); } else { *pcaptype = get_captype(dest, csconv); } return nl; } void HunspellImpl::cleanword(std::string& dest, const std::string& src, int* pcaptype, int* pabbrev) { dest.clear(); const unsigned char* q = (const unsigned char*)src.c_str(); int firstcap = 0; // first skip over any leading blanks while (*q == ' ') ++q; // now strip off any trailing periods (recording their presence) *pabbrev = 0; int nl = strlen((const char*)q); while ((nl > 0) && (*(q + nl - 1) == '.')) { nl--; (*pabbrev)++; } // if no characters are left it can't be capitalized if (nl <= 0) { *pcaptype = NOCAP; return; } // now determine the capitalization type of the first nl letters int ncap = 0; int nneutral = 0; int nc = 0; if (!utf8) { while (nl > 0) { nc++; if (csconv[(*q)].ccase) ncap++; if (csconv[(*q)].cupper == csconv[(*q)].clower) nneutral++; dest.push_back(*q++); nl--; } // remember to terminate the destination string firstcap = csconv[static_cast(dest[0])].ccase; } else { std::vector t; u8_u16(t, src); for (size_t i = 0; i < t.size(); ++i) { unsigned short idx = (t[i].h << 8) + t[i].l; unsigned short low = unicodetolower(idx, langnum); if (idx != low) ncap++; if (unicodetoupper(idx, langnum) == low) nneutral++; } u16_u8(dest, t); if (ncap) { unsigned short idx = (t[0].h << 8) + t[0].l; firstcap = (idx != unicodetolower(idx, langnum)); } } // now finally set the captype if (ncap == 0) { *pcaptype = NOCAP; } else if ((ncap == 1) && firstcap) { *pcaptype = INITCAP; } else if ((ncap == nc) || ((ncap + nneutral) == nc)) { *pcaptype = ALLCAP; } else if ((ncap > 1) && firstcap) { *pcaptype = HUHINITCAP; } else { *pcaptype = HUHCAP; } } void HunspellImpl::mkallcap(std::string& u8) { if (utf8) { std::vector u16; u8_u16(u16, u8); ::mkallcap_utf(u16, langnum); u16_u8(u8, u16); } else { ::mkallcap(u8, csconv); } } int HunspellImpl::mkallsmall2(std::string& u8, std::vector& u16) { if (utf8) { ::mkallsmall_utf(u16, langnum); u16_u8(u8, u16); } else { ::mkallsmall(u8, csconv); } return u8.size(); } // convert UTF-8 sharp S codes to latin 1 std::string HunspellImpl::sharps_u8_l1(const std::string& source) { std::string dest(source); mystrrep(dest, "\xC3\x9F", "\xDF"); return dest; } // recursive search for right ss - sharp s permutations hentry* HunspellImpl::spellsharps(std::string& base, size_t n_pos, int n, int repnum, int* info, std::string* root) { size_t pos = base.find("ss", n_pos); if (pos != std::string::npos && (n < MAXSHARPS)) { base[pos] = '\xC3'; base[pos + 1] = '\x9F'; hentry* h = spellsharps(base, pos + 2, n + 1, repnum + 1, info, root); if (h) return h; base[pos] = 's'; base[pos + 1] = 's'; h = spellsharps(base, pos + 2, n + 1, repnum, info, root); if (h) return h; } else if (repnum > 0) { if (utf8) return checkword(base, info, root); std::string tmp(sharps_u8_l1(base)); return checkword(tmp, info, root); } return NULL; } int HunspellImpl::is_keepcase(const hentry* rv) { return pAMgr && rv->astr && pAMgr->get_keepcase() && TESTAFF(rv->astr, pAMgr->get_keepcase(), rv->alen); } /* insert a word to the beginning of the suggestion array */ void HunspellImpl::insert_sug(std::vector& slst, const std::string& word) { slst.insert(slst.begin(), word); } bool Hunspell::spell(const std::string& word, int* info, std::string* root) { return m_Impl->spell(word, info, root); } bool HunspellImpl::spell(const std::string& word, int* info, std::string* root) { struct hentry* rv = NULL; int info2 = 0; if (!info) info = &info2; else *info = 0; // Hunspell supports XML input of the simplified API (see manual) if (word == SPELL_XML) return true; if (utf8) { if (word.size() >= MAXWORDUTF8LEN) return false; } else { if (word.size() >= MAXWORDLEN) return false; } int captype = NOCAP; size_t abbv = 0; size_t wl = 0; std::string scw; std::vector sunicw; // input conversion RepList* rl = pAMgr ? pAMgr->get_iconvtable() : NULL; { std::string wspace; bool convstatus = rl ? rl->conv(word, wspace) : false; if (convstatus) wl = cleanword2(scw, sunicw, wspace, &captype, &abbv); else wl = cleanword2(scw, sunicw, word, &captype, &abbv); } #ifdef MOZILLA_CLIENT // accept the abbreviated words without dots // workaround for the incomplete tokenization of Mozilla abbv = 1; #endif if (wl == 0 || m_HMgrs.empty()) return true; if (root) root->clear(); // allow numbers with dots, dashes and commas (but forbid double separators: // "..", "--" etc.) enum { NBEGIN, NNUM, NSEP }; int nstate = NBEGIN; size_t i; for (i = 0; (i < wl); i++) { if ((scw[i] <= '9') && (scw[i] >= '0')) { nstate = NNUM; } else if ((scw[i] == ',') || (scw[i] == '.') || (scw[i] == '-')) { if ((nstate == NSEP) || (i == 0)) break; nstate = NSEP; } else break; } if ((i == wl) && (nstate == NNUM)) return true; switch (captype) { case HUHCAP: /* FALLTHROUGH */ case HUHINITCAP: *info += SPELL_ORIGCAP; /* FALLTHROUGH */ case NOCAP: rv = checkword(scw, info, root); if ((abbv) && !(rv)) { std::string u8buffer(scw); u8buffer.push_back('.'); rv = checkword(u8buffer, info, root); } break; case ALLCAP: { *info += SPELL_ORIGCAP; rv = checkword(scw, info, root); if (rv) break; if (abbv) { std::string u8buffer(scw); u8buffer.push_back('.'); rv = checkword(u8buffer, info, root); if (rv) break; } // Spec. prefix handling for Catalan, French, Italian: // prefixes separated by apostrophe (SANT'ELIA -> Sant'+Elia). size_t apos = pAMgr ? scw.find('\'') : std::string::npos; if (apos != std::string::npos) { mkallsmall2(scw, sunicw); //conversion may result in string with different len to pre-mkallsmall2 //so re-scan if (apos != std::string::npos && apos < scw.size() - 1) { std::string part1 = scw.substr(0, apos+1); std::string part2 = scw.substr(apos+1); if (utf8) { std::vector part1u, part2u; u8_u16(part1u, part1); u8_u16(part2u, part2); mkinitcap2(part2, part2u); scw = part1 + part2; sunicw = part1u; sunicw.insert(sunicw.end(), part2u.begin(), part2u.end()); rv = checkword(scw, info, root); if (rv) break; } else { mkinitcap2(part2, sunicw); scw = part1 + part2; rv = checkword(scw, info, root); if (rv) break; } mkinitcap2(scw, sunicw); rv = checkword(scw, info, root); if (rv) break; } } if (pAMgr && pAMgr->get_checksharps() && scw.find("SS") != std::string::npos) { mkallsmall2(scw, sunicw); std::string u8buffer(scw); rv = spellsharps(u8buffer, 0, 0, 0, info, root); if (!rv) { mkinitcap2(scw, sunicw); rv = spellsharps(scw, 0, 0, 0, info, root); } if ((abbv) && !(rv)) { u8buffer.push_back('.'); rv = spellsharps(u8buffer, 0, 0, 0, info, root); if (!rv) { u8buffer = std::string(scw); u8buffer.push_back('.'); rv = spellsharps(u8buffer, 0, 0, 0, info, root); } } if (rv) break; } } case INITCAP: { *info += SPELL_ORIGCAP; mkallsmall2(scw, sunicw); std::string u8buffer(scw); mkinitcap2(scw, sunicw); if (captype == INITCAP) *info += SPELL_INITCAP; rv = checkword(scw, info, root); if (captype == INITCAP) *info -= SPELL_INITCAP; // forbid bad capitalization // (for example, ijs -> Ijs instead of IJs in Dutch) // use explicit forms in dic: Ijs/F (F = FORBIDDENWORD flag) if (*info & SPELL_FORBIDDEN) { rv = NULL; break; } if (rv && is_keepcase(rv) && (captype == ALLCAP)) rv = NULL; if (rv) break; rv = checkword(u8buffer, info, root); if (abbv && !rv) { u8buffer.push_back('.'); rv = checkword(u8buffer, info, root); if (!rv) { u8buffer = scw; u8buffer.push_back('.'); if (captype == INITCAP) *info += SPELL_INITCAP; rv = checkword(u8buffer, info, root); if (captype == INITCAP) *info -= SPELL_INITCAP; if (rv && is_keepcase(rv) && (captype == ALLCAP)) rv = NULL; break; } } if (rv && is_keepcase(rv) && ((captype == ALLCAP) || // if CHECKSHARPS: KEEPCASE words with \xDF are allowed // in INITCAP form, too. !(pAMgr->get_checksharps() && ((utf8 && u8buffer.find("\xC3\x9F") != std::string::npos) || (!utf8 && u8buffer.find('\xDF') != std::string::npos))))) rv = NULL; break; } } if (rv) { if (pAMgr && pAMgr->get_warn() && rv->astr && TESTAFF(rv->astr, pAMgr->get_warn(), rv->alen)) { *info += SPELL_WARN; if (pAMgr->get_forbidwarn()) return false; return true; } return true; } // recursive breaking at break points if (!wordbreak.empty()) { int nbr = 0; wl = scw.size(); // calculate break points for recursion limit for (size_t j = 0; j < wordbreak.size(); ++j) { size_t pos = 0; while ((pos = scw.find(wordbreak[j], pos)) != std::string::npos) { ++nbr; pos += wordbreak[j].size(); } } if (nbr >= 10) return false; // check boundary patterns (^begin and end$) for (size_t j = 0; j < wordbreak.size(); ++j) { size_t plen = wordbreak[j].size(); if (plen == 1 || plen > wl) continue; if (wordbreak[j][0] == '^' && scw.compare(0, plen - 1, wordbreak[j], 1, plen -1) == 0 && spell(scw.substr(plen - 1))) return true; if (wordbreak[j][plen - 1] == '$' && scw.compare(wl - plen + 1, plen - 1, wordbreak[j], 0, plen - 1) == 0) { std::string suffix(scw.substr(wl - plen + 1)); scw.resize(wl - plen + 1); if (spell(scw)) return true; scw.append(suffix); } } // other patterns for (size_t j = 0; j < wordbreak.size(); ++j) { size_t plen = wordbreak[j].size(); size_t found = scw.find(wordbreak[j]); if ((found > 0) && (found < wl - plen)) { if (!spell(scw.substr(found + plen))) continue; std::string suffix(scw.substr(found)); scw.resize(found); // examine 2 sides of the break point if (spell(scw)) return true; scw.append(suffix); // LANG_hu: spec. dash rule if (langnum == LANG_hu && wordbreak[j] == "-") { suffix = scw.substr(found + 1); scw.resize(found + 1); if (spell(scw)) return true; // check the first part with dash scw.append(suffix); } // end of LANG specific region } } } return false; } struct hentry* HunspellImpl::checkword(const std::string& w, int* info, std::string* root) { bool usebuffer = false; std::string w2; const char* word; int len; const char* ignoredchars = pAMgr ? pAMgr->get_ignore() : NULL; if (ignoredchars != NULL) { w2.assign(w); if (utf8) { const std::vector& ignoredchars_utf16 = pAMgr->get_ignore_utf16(); remove_ignored_chars_utf(w2, ignoredchars_utf16); } else { remove_ignored_chars(w2, ignoredchars); } word = w2.c_str(); len = w2.size(); usebuffer = true; } else { word = w.c_str(); len = w.size(); } if (!len) return NULL; // word reversing wrapper for complex prefixes if (complexprefixes) { if (!usebuffer) { w2.assign(word); usebuffer = true; } if (utf8) reverseword_utf(w2); else reverseword(w2); } if (usebuffer) { word = w2.c_str(); } // look word in hash table struct hentry* he = NULL; for (size_t i = 0; (i < m_HMgrs.size()) && !he; ++i) { he = m_HMgrs[i]->lookup(word); // check forbidden and onlyincompound words if ((he) && (he->astr) && (pAMgr) && TESTAFF(he->astr, pAMgr->get_forbiddenword(), he->alen)) { if (info) *info += SPELL_FORBIDDEN; // LANG_hu section: set dash information for suggestions if (langnum == LANG_hu) { if (pAMgr->get_compoundflag() && TESTAFF(he->astr, pAMgr->get_compoundflag(), he->alen)) { if (info) *info += SPELL_COMPOUND; } } return NULL; } // he = next not needaffix, onlyincompound homonym or onlyupcase word while (he && (he->astr) && pAMgr && ((pAMgr->get_needaffix() && TESTAFF(he->astr, pAMgr->get_needaffix(), he->alen)) || (pAMgr->get_onlyincompound() && TESTAFF(he->astr, pAMgr->get_onlyincompound(), he->alen)) || (info && (*info & SPELL_INITCAP) && TESTAFF(he->astr, ONLYUPCASEFLAG, he->alen)))) he = he->next_homonym; } // check with affixes if (!he && pAMgr) { // try stripping off affixes */ he = pAMgr->affix_check(word, len, 0); // check compound restriction and onlyupcase if (he && he->astr && ((pAMgr->get_onlyincompound() && TESTAFF(he->astr, pAMgr->get_onlyincompound(), he->alen)) || (info && (*info & SPELL_INITCAP) && TESTAFF(he->astr, ONLYUPCASEFLAG, he->alen)))) { he = NULL; } if (he) { if ((he->astr) && (pAMgr) && TESTAFF(he->astr, pAMgr->get_forbiddenword(), he->alen)) { if (info) *info += SPELL_FORBIDDEN; return NULL; } if (root) { root->assign(he->word); if (complexprefixes) { if (utf8) reverseword_utf(*root); else reverseword(*root); } } // try check compound word } else if (pAMgr->get_compound()) { struct hentry* rwords[100]; // buffer for COMPOUND pattern checking he = pAMgr->compound_check(word, 0, 0, 100, 0, NULL, (hentry**)&rwords, 0, 0, info); // LANG_hu section: `moving rule' with last dash if ((!he) && (langnum == LANG_hu) && (word[len - 1] == '-')) { std::string dup(word, len - 1); he = pAMgr->compound_check(dup, -5, 0, 100, 0, NULL, (hentry**)&rwords, 1, 0, info); } // end of LANG specific region if (he) { if (root) { root->assign(he->word); if (complexprefixes) { if (utf8) reverseword_utf(*root); else reverseword(*root); } } if (info) *info += SPELL_COMPOUND; } } } return he; } std::vector Hunspell::suggest(const std::string& word) { return m_Impl->suggest(word); } std::vector HunspellImpl::suggest(const std::string& word) { std::vector slst; int onlycmpdsug = 0; if (!pSMgr || m_HMgrs.empty()) return slst; // process XML input of the simplified API (see manual) if (word.compare(0, sizeof(SPELL_XML) - 3, SPELL_XML, sizeof(SPELL_XML) - 3) == 0) { return spellml(word); } if (utf8) { if (word.size() >= MAXWORDUTF8LEN) return slst; } else { if (word.size() >= MAXWORDLEN) return slst; } int captype = NOCAP; size_t abbv = 0; size_t wl = 0; std::string scw; std::vector sunicw; // input conversion RepList* rl = (pAMgr) ? pAMgr->get_iconvtable() : NULL; { std::string wspace; bool convstatus = rl ? rl->conv(word, wspace) : false; if (convstatus) wl = cleanword2(scw, sunicw, wspace, &captype, &abbv); else wl = cleanword2(scw, sunicw, word, &captype, &abbv); if (wl == 0) return slst; } int capwords = 0; // check capitalized form for FORCEUCASE if (pAMgr && captype == NOCAP && pAMgr->get_forceucase()) { int info = SPELL_ORIGCAP; if (checkword(scw, &info, NULL)) { std::string form(scw); mkinitcap(form); slst.push_back(form); return slst; } } switch (captype) { case NOCAP: { pSMgr->suggest(slst, scw.c_str(), &onlycmpdsug); break; } case INITCAP: { capwords = 1; pSMgr->suggest(slst, scw.c_str(), &onlycmpdsug); std::string wspace(scw); mkallsmall2(wspace, sunicw); pSMgr->suggest(slst, wspace.c_str(), &onlycmpdsug); break; } case HUHINITCAP: capwords = 1; case HUHCAP: { pSMgr->suggest(slst, scw.c_str(), &onlycmpdsug); // something.The -> something. The size_t dot_pos = scw.find('.'); if (dot_pos != std::string::npos) { std::string postdot = scw.substr(dot_pos + 1); int captype_; if (utf8) { std::vector postdotu; u8_u16(postdotu, postdot); captype_ = get_captype_utf8(postdotu, langnum); } else { captype_ = get_captype(postdot, csconv); } if (captype_ == INITCAP) { std::string str(scw); str.insert(dot_pos + 1, 1, ' '); insert_sug(slst, str); } } std::string wspace; if (captype == HUHINITCAP) { // TheOpenOffice.org -> The OpenOffice.org wspace = scw; mkinitsmall2(wspace, sunicw); pSMgr->suggest(slst, wspace.c_str(), &onlycmpdsug); } wspace = scw; mkallsmall2(wspace, sunicw); if (spell(wspace.c_str())) insert_sug(slst, wspace); size_t prevns = slst.size(); pSMgr->suggest(slst, wspace.c_str(), &onlycmpdsug); if (captype == HUHINITCAP) { mkinitcap2(wspace, sunicw); if (spell(wspace.c_str())) insert_sug(slst, wspace); pSMgr->suggest(slst, wspace.c_str(), &onlycmpdsug); } // aNew -> "a New" (instead of "a new") for (size_t j = prevns; j < slst.size(); ++j) { const char* space = strchr(slst[j].c_str(), ' '); if (space) { size_t slen = strlen(space + 1); // different case after space (need capitalisation) if ((slen < wl) && strcmp(scw.c_str() + wl - slen, space + 1)) { std::string first(slst[j].c_str(), space + 1); std::string second(space + 1); std::vector w; if (utf8) u8_u16(w, second); mkinitcap2(second, w); // set as first suggestion slst.erase(slst.begin() + j); slst.insert(slst.begin(), first + second); } } } break; } case ALLCAP: { std::string wspace(scw); mkallsmall2(wspace, sunicw); pSMgr->suggest(slst, wspace.c_str(), &onlycmpdsug); if (pAMgr && pAMgr->get_keepcase() && spell(wspace.c_str())) insert_sug(slst, wspace); mkinitcap2(wspace, sunicw); pSMgr->suggest(slst, wspace.c_str(), &onlycmpdsug); for (size_t j = 0; j < slst.size(); ++j) { mkallcap(slst[j]); if (pAMgr && pAMgr->get_checksharps()) { if (utf8) { mystrrep(slst[j], "\xC3\x9F", "SS"); } else { mystrrep(slst[j], "\xDF", "SS"); } } } break; } } // LANG_hu section: replace '-' with ' ' in Hungarian if (langnum == LANG_hu) { for (size_t j = 0; j < slst.size(); ++j) { size_t pos = slst[j].find('-'); if (pos != std::string::npos) { int info; std::string w(slst[j].substr(0, pos)); w.append(slst[j].substr(pos + 1)); (void)spell(w, &info, NULL); if ((info & SPELL_COMPOUND) && (info & SPELL_FORBIDDEN)) { slst[j][pos] = ' '; } else slst[j][pos] = '-'; } } } // END OF LANG_hu section // try ngram approach since found nothing or only compound words if (pAMgr && (slst.empty() || onlycmpdsug) && (pAMgr->get_maxngramsugs() != 0)) { switch (captype) { case NOCAP: { pSMgr->ngsuggest(slst, scw.c_str(), m_HMgrs); break; } case HUHINITCAP: capwords = 1; case HUHCAP: { std::string wspace(scw); mkallsmall2(wspace, sunicw); pSMgr->ngsuggest(slst, wspace.c_str(), m_HMgrs); break; } case INITCAP: { capwords = 1; std::string wspace(scw); mkallsmall2(wspace, sunicw); pSMgr->ngsuggest(slst, wspace.c_str(), m_HMgrs); break; } case ALLCAP: { std::string wspace(scw); mkallsmall2(wspace, sunicw); size_t oldns = slst.size(); pSMgr->ngsuggest(slst, wspace.c_str(), m_HMgrs); for (size_t j = oldns; j < slst.size(); ++j) { mkallcap(slst[j]); } break; } } } // try dash suggestion (Afo-American -> Afro-American) size_t dash_pos = scw.find('-'); if (dash_pos != std::string::npos) { int nodashsug = 1; for (size_t j = 0; j < slst.size() && nodashsug == 1; ++j) { if (slst[j].find('-') != std::string::npos) nodashsug = 0; } size_t prev_pos = 0; bool last = false; while (nodashsug && !last) { if (dash_pos == scw.size()) last = 1; std::string chunk = scw.substr(prev_pos, dash_pos - prev_pos); if (!spell(chunk.c_str())) { std::vector nlst = suggest(chunk.c_str()); for (std::vector::reverse_iterator j = nlst.rbegin(); j != nlst.rend(); ++j) { std::string wspace = scw.substr(0, prev_pos); wspace.append(*j); if (!last) { wspace.append("-"); wspace.append(scw.substr(dash_pos + 1)); } insert_sug(slst, wspace); } nodashsug = 0; } if (!last) { prev_pos = dash_pos + 1; dash_pos = scw.find('-', prev_pos); } if (dash_pos == std::string::npos) dash_pos = scw.size(); } } // word reversing wrapper for complex prefixes if (complexprefixes) { for (size_t j = 0; j < slst.size(); ++j) { if (utf8) reverseword_utf(slst[j]); else reverseword(slst[j]); } } // capitalize if (capwords) for (size_t j = 0; j < slst.size(); ++j) { mkinitcap(slst[j]); } // expand suggestions with dot(s) if (abbv && pAMgr && pAMgr->get_sugswithdots()) { for (size_t j = 0; j < slst.size(); ++j) { slst[j].append(word.substr(word.size() - abbv)); } } // remove bad capitalized and forbidden forms if (pAMgr && (pAMgr->get_keepcase() || pAMgr->get_forbiddenword())) { switch (captype) { case INITCAP: case ALLCAP: { size_t l = 0; for (size_t j = 0; j < slst.size(); ++j) { if (slst[j].find(' ') == std::string::npos && !spell(slst[j])) { std::string s; std::vector w; if (utf8) { u8_u16(w, slst[j]); } else { s = slst[j]; } mkallsmall2(s, w); if (spell(s)) { slst[l] = s; ++l; } else { mkinitcap2(s, w); if (spell(s)) { slst[l] = s; ++l; } } } else { slst[l] = slst[j]; ++l; } } slst.resize(l); } } } // remove duplications size_t l = 0; for (size_t j = 0; j < slst.size(); ++j) { slst[l] = slst[j]; for (size_t k = 0; k < l; ++k) { if (slst[k] == slst[j]) { --l; break; } } ++l; } slst.resize(l); // output conversion rl = (pAMgr) ? pAMgr->get_oconvtable() : NULL; for (size_t j = 0; rl && j < slst.size(); ++j) { std::string wspace; if (rl->conv(slst[j], wspace)) { slst[j] = wspace; } } return slst; } const std::string& Hunspell::get_dict_encoding() const { return m_Impl->get_dict_encoding(); } const std::string& HunspellImpl::get_dict_encoding() const { return encoding; } std::vector Hunspell::stem(const std::vector& desc) { return m_Impl->stem(desc); } std::vector HunspellImpl::stem(const std::vector& desc) { std::vector slst; std::string result2; if (desc.empty()) return slst; for (size_t i = 0; i < desc.size(); ++i) { std::string result; // add compound word parts (except the last one) const char* s = desc[i].c_str(); const char* part = strstr(s, MORPH_PART); if (part) { const char* nextpart = strstr(part + 1, MORPH_PART); while (nextpart) { std::string field; copy_field(field, part, MORPH_PART); result.append(field); part = nextpart; nextpart = strstr(part + 1, MORPH_PART); } s = part; } std::string tok(s); size_t alt = 0; while ((alt = tok.find(" | ", alt)) != std::string::npos) { tok[alt + 1] = MSEP_ALT; } std::vector pl = line_tok(tok, MSEP_ALT); for (size_t k = 0; k < pl.size(); ++k) { // add derivational suffixes if (pl[k].find(MORPH_DERI_SFX) != std::string::npos) { // remove inflectional suffixes const size_t is = pl[k].find(MORPH_INFL_SFX); if (is != std::string::npos) pl[k].resize(is); std::vector singlepl; singlepl.push_back(pl[k]); std::string sg = pSMgr->suggest_gen(singlepl, pl[k]); if (!sg.empty()) { std::vector gen = line_tok(sg, MSEP_REC); for (size_t j = 0; j < gen.size(); ++j) { result2.push_back(MSEP_REC); result2.append(result); result2.append(gen[j]); } } } else { result2.push_back(MSEP_REC); result2.append(result); if (pl[k].find(MORPH_SURF_PFX) != std::string::npos) { std::string field; copy_field(field, pl[k], MORPH_SURF_PFX); result2.append(field); } std::string field; copy_field(field, pl[k], MORPH_STEM); result2.append(field); } } } slst = line_tok(result2, MSEP_REC); uniqlist(slst); return slst; } std::vector Hunspell::stem(const std::string& word) { return m_Impl->stem(word); } std::vector HunspellImpl::stem(const std::string& word) { return stem(analyze(word)); } const char* Hunspell::get_wordchars() const { return m_Impl->get_wordchars().c_str(); } const std::string& Hunspell::get_wordchars_cpp() const { return m_Impl->get_wordchars(); } const std::string& HunspellImpl::get_wordchars() const { return pAMgr->get_wordchars(); } const std::vector& Hunspell::get_wordchars_utf16() const { return m_Impl->get_wordchars_utf16(); } const std::vector& HunspellImpl::get_wordchars_utf16() const { return pAMgr->get_wordchars_utf16(); } void HunspellImpl::mkinitcap(std::string& u8) { if (utf8) { std::vector u16; u8_u16(u16, u8); ::mkinitcap_utf(u16, langnum); u16_u8(u8, u16); } else { ::mkinitcap(u8, csconv); } } int HunspellImpl::mkinitcap2(std::string& u8, std::vector& u16) { if (utf8) { ::mkinitcap_utf(u16, langnum); u16_u8(u8, u16); } else { ::mkinitcap(u8, csconv); } return u8.size(); } int HunspellImpl::mkinitsmall2(std::string& u8, std::vector& u16) { if (utf8) { ::mkinitsmall_utf(u16, langnum); u16_u8(u8, u16); } else { ::mkinitsmall(u8, csconv); } return u8.size(); } int Hunspell::add(const std::string& word) { return m_Impl->add(word); } int HunspellImpl::add(const std::string& word) { if (!m_HMgrs.empty()) return m_HMgrs[0]->add(word); return 0; } int Hunspell::add_with_affix(const std::string& word, const std::string& example) { return m_Impl->add_with_affix(word, example); } int HunspellImpl::add_with_affix(const std::string& word, const std::string& example) { if (!m_HMgrs.empty()) return m_HMgrs[0]->add_with_affix(word, example); return 0; } int Hunspell::remove(const std::string& word) { return m_Impl->remove(word); } int HunspellImpl::remove(const std::string& word) { if (!m_HMgrs.empty()) return m_HMgrs[0]->remove(word); return 0; } const char* Hunspell::get_version() const { return m_Impl->get_version().c_str(); } const std::string& Hunspell::get_version_cpp() const { return m_Impl->get_version(); } const char* Hunspell::get_try_string() const { return m_Impl->get_try_string(); } struct cs_info* HunspellImpl::get_csconv() { return csconv; } struct cs_info* Hunspell::get_csconv() { return m_Impl->get_csconv(); } void HunspellImpl::cat_result(std::string& result, const std::string& st) { if (!st.empty()) { if (!result.empty()) result.append("\n"); result.append(st); } } std::vector Hunspell::analyze(const std::string& word) { return m_Impl->analyze(word); } std::vector HunspellImpl::analyze(const std::string& word) { std::vector slst; if (!pSMgr || m_HMgrs.empty()) return slst; if (utf8) { if (word.size() >= MAXWORDUTF8LEN) return slst; } else { if (word.size() >= MAXWORDLEN) return slst; } int captype = NOCAP; size_t abbv = 0; size_t wl = 0; std::string scw; std::vector sunicw; // input conversion RepList* rl = (pAMgr) ? pAMgr->get_iconvtable() : NULL; { std::string wspace; bool convstatus = rl ? rl->conv(word, wspace) : false; if (convstatus) wl = cleanword2(scw, sunicw, wspace, &captype, &abbv); else wl = cleanword2(scw, sunicw, word, &captype, &abbv); } if (wl == 0) { if (abbv) { scw.clear(); for (wl = 0; wl < abbv; wl++) scw.push_back('.'); abbv = 0; } else return slst; } std::string result; size_t n = 0; // test numbers // LANG_hu section: set dash information for suggestions if (langnum == LANG_hu) { size_t n2 = 0; size_t n3 = 0; while ((n < wl) && (((scw[n] <= '9') && (scw[n] >= '0')) || (((scw[n] == '.') || (scw[n] == ',')) && (n > 0)))) { n++; if ((scw[n] == '.') || (scw[n] == ',')) { if (((n2 == 0) && (n > 3)) || ((n2 > 0) && ((scw[n - 1] == '.') || (scw[n - 1] == ',')))) break; n2++; n3 = n; } } if ((n == wl) && (n3 > 0) && (n - n3 > 3)) return slst; if ((n == wl) || ((n > 0) && ((scw[n] == '%') || (scw[n] == '\xB0')) && checkword(scw.substr(n), NULL, NULL))) { result.append(scw); result.resize(n - 1); if (n == wl) cat_result(result, pSMgr->suggest_morph(scw.substr(n - 1))); else { std::string chunk = scw.substr(n - 1, 1); cat_result(result, pSMgr->suggest_morph(chunk)); result.push_back('+'); // XXX SPEC. MORPHCODE cat_result(result, pSMgr->suggest_morph(scw.substr(n))); } return line_tok(result, MSEP_REC); } } // END OF LANG_hu section switch (captype) { case HUHCAP: case HUHINITCAP: case NOCAP: { cat_result(result, pSMgr->suggest_morph(scw)); if (abbv) { std::string u8buffer(scw); u8buffer.push_back('.'); cat_result(result, pSMgr->suggest_morph(u8buffer)); } break; } case INITCAP: { mkallsmall2(scw, sunicw); std::string u8buffer(scw); mkinitcap2(scw, sunicw); cat_result(result, pSMgr->suggest_morph(u8buffer)); cat_result(result, pSMgr->suggest_morph(scw)); if (abbv) { u8buffer.push_back('.'); cat_result(result, pSMgr->suggest_morph(u8buffer)); u8buffer = scw; u8buffer.push_back('.'); cat_result(result, pSMgr->suggest_morph(u8buffer)); } break; } case ALLCAP: { cat_result(result, pSMgr->suggest_morph(scw)); if (abbv) { std::string u8buffer(scw); u8buffer.push_back('.'); cat_result(result, pSMgr->suggest_morph(u8buffer)); } mkallsmall2(scw, sunicw); std::string u8buffer(scw); mkinitcap2(scw, sunicw); cat_result(result, pSMgr->suggest_morph(u8buffer)); cat_result(result, pSMgr->suggest_morph(scw)); if (abbv) { u8buffer.push_back('.'); cat_result(result, pSMgr->suggest_morph(u8buffer)); u8buffer = scw; u8buffer.push_back('.'); cat_result(result, pSMgr->suggest_morph(u8buffer)); } break; } } if (!result.empty()) { // word reversing wrapper for complex prefixes if (complexprefixes) { if (utf8) reverseword_utf(result); else reverseword(result); } return line_tok(result, MSEP_REC); } // compound word with dash (HU) I18n // LANG_hu section: set dash information for suggestions size_t dash_pos = langnum == LANG_hu ? scw.find('-') : std::string::npos; if (dash_pos != std::string::npos) { int nresult = 0; std::string part1 = scw.substr(0, dash_pos); std::string part2 = scw.substr(dash_pos+1); // examine 2 sides of the dash if (part2.empty()) { // base word ending with dash if (spell(part1)) { std::string p = pSMgr->suggest_morph(part1); if (!p.empty()) { slst = line_tok(p, MSEP_REC); return slst; } } } else if (part2.size() == 1 && part2[0] == 'e') { // XXX (HU) -e hat. if (spell(part1) && (spell("-e"))) { std::string st = pSMgr->suggest_morph(part1); if (!st.empty()) { result.append(st); } result.push_back('+'); // XXX spec. separator in MORPHCODE st = pSMgr->suggest_morph("-e"); if (!st.empty()) { result.append(st); } return line_tok(result, MSEP_REC); } } else { // first word ending with dash: word- XXX ??? part1.push_back(' '); nresult = spell(part1); part1.erase(part1.size() - 1); if (nresult && spell(part2) && ((part2.size() > 1) || ((part2[0] > '0') && (part2[0] < '9')))) { std::string st = pSMgr->suggest_morph(part1); if (!st.empty()) { result.append(st); result.push_back('+'); // XXX spec. separator in MORPHCODE } st = pSMgr->suggest_morph(part2); if (!st.empty()) { result.append(st); } return line_tok(result, MSEP_REC); } } // affixed number in correct word if (nresult && (dash_pos > 0) && (((scw[dash_pos - 1] <= '9') && (scw[dash_pos - 1] >= '0')) || (scw[dash_pos - 1] == '.'))) { n = 1; if (scw[dash_pos - n] == '.') n++; // search first not a number character to left from dash while ((dash_pos >= n) && ((scw[dash_pos - n] == '0') || (n < 3)) && (n < 6)) { n++; } if (dash_pos < n) n--; // numbers: valami1000000-hoz // examine 100000-hoz, 10000-hoz 1000-hoz, 10-hoz, // 56-hoz, 6-hoz for (; n >= 1; n--) { if (scw[dash_pos - n] < '0' || scw[dash_pos - n] > '9') { continue; } std::string chunk = scw.substr(dash_pos - n); if (checkword(chunk, NULL, NULL)) { result.append(chunk); std::string st = pSMgr->suggest_morph(chunk); if (!st.empty()) { result.append(st); } return line_tok(result, MSEP_REC); } } } } return slst; } std::vector Hunspell::generate(const std::string& word, const std::vector& pl) { return m_Impl->generate(word, pl); } std::vector HunspellImpl::generate(const std::string& word, const std::vector& pl) { std::vector slst; if (!pSMgr || pl.empty()) return slst; std::vector pl2 = analyze(word); int captype = NOCAP; int abbv = 0; std::string cw; cleanword(cw, word, &captype, &abbv); std::string result; for (size_t i = 0; i < pl.size(); ++i) { cat_result(result, pSMgr->suggest_gen(pl2, pl[i])); } if (!result.empty()) { // allcap if (captype == ALLCAP) mkallcap(result); // line split slst = line_tok(result, MSEP_REC); // capitalize if (captype == INITCAP || captype == HUHINITCAP) { for (size_t j = 0; j < slst.size(); ++j) { mkinitcap(slst[j]); } } // temporary filtering of prefix related errors (eg. // generate("undrinkable", "eats") --> "undrinkables" and "*undrinks") std::vector::iterator it = slst.begin(); while (it != slst.end()) { if (!spell(*it)) { it = slst.erase(it); } else { ++it; } } } return slst; } std::vector Hunspell::generate(const std::string& word, const std::string& pattern) { return m_Impl->generate(word, pattern); } std::vector HunspellImpl::generate(const std::string& word, const std::string& pattern) { std::vector pl = analyze(pattern); std::vector slst = generate(word, pl); uniqlist(slst); return slst; } // minimal XML parser functions std::string HunspellImpl::get_xml_par(const char* par) { std::string dest; if (!par) return dest; char end = *par; if (end == '>') end = '<'; else if (end != '\'' && end != '"') return dest; // bad XML for (par++; *par != '\0' && *par != end; ++par) { dest.push_back(*par); } mystrrep(dest, "<", "<"); mystrrep(dest, "&", "&"); return dest; } int Hunspell::get_langnum() const { return m_Impl->get_langnum(); } bool Hunspell::input_conv(const std::string& word, std::string& dest) { return m_Impl->input_conv(word, dest); } int Hunspell::input_conv(const char* word, char* dest, size_t destsize) { std::string d; bool ret = input_conv(word, d); if (ret && d.size() < destsize) { strncpy(dest, d.c_str(), destsize); return 1; } return 0; } bool HunspellImpl::input_conv(const std::string& word, std::string& dest) { RepList* rl = pAMgr ? pAMgr->get_iconvtable() : NULL; if (rl) { return rl->conv(word, dest); } dest.assign(word); return false; } // return the beginning of the element (attr == NULL) or the attribute const char* HunspellImpl::get_xml_pos(const char* s, const char* attr) { const char* end = strchr(s, '>'); if (attr == NULL) return end; const char* p = s; while (1) { p = strstr(p, attr); if (!p || p >= end) return 0; if (*(p - 1) == ' ' || *(p - 1) == '\n') break; p += strlen(attr); } return p + strlen(attr); } int HunspellImpl::check_xml_par(const char* q, const char* attr, const char* value) { std::string cw = get_xml_par(get_xml_pos(q, attr)); if (cw == value) return 1; return 0; } std::vector HunspellImpl::get_xml_list(const char* list, const char* tag) { std::vector slst; if (!list) return slst; const char* p = list; for (size_t n = 0; ((p = strstr(p, tag)) != NULL); ++p, ++n) { std::string cw = get_xml_par(p + strlen(tag) - 1); if (cw.empty()) { break; } slst.push_back(cw); } return slst; } std::vector HunspellImpl::spellml(const std::string& in_word) { std::vector slst; const char* word = in_word.c_str(); const char* q = strstr(word, "'); if (!q2) return slst; // bad XML input q2 = strstr(q2, "')); if (!cw.empty()) slst = analyze(cw); if (slst.empty()) return slst; // convert the result to ana1ana2 format std::string r; r.append(""); for (size_t i = 0; i < slst.size(); ++i) { r.append(""); std::string entry(slst[i]); mystrrep(entry, "\t", " "); mystrrep(entry, "&", "&"); mystrrep(entry, "<", "<"); r.append(entry); r.append(""); } r.append(""); slst.clear(); slst.push_back(r); return slst; } else if (check_xml_par(q, "type=", "stem")) { std::string cw = get_xml_par(strchr(q2, '>')); if (!cw.empty()) return stem(cw); } else if (check_xml_par(q, "type=", "generate")) { std::string cw = get_xml_par(strchr(q2, '>')); if (cw.empty()) return slst; const char* q3 = strstr(q2 + 1, "')); if (!cw2.empty()) { return generate(cw, cw2); } } else { if ((q2 = strstr(q2 + 1, " slst2 = get_xml_list(strchr(q2, '>'), ""); if (!slst2.empty()) { slst = generate(cw, slst2); uniqlist(slst); return slst; } } } } return slst; } int Hunspell::spell(const char* word, int* info, char** root) { std::string sroot; bool ret = m_Impl->spell(word, info, root ? &sroot : NULL); if (root) { if (sroot.empty()) { *root = NULL; } else { *root = mystrdup(sroot.c_str()); } } return ret; } namespace { int munge_vector(char*** slst, const std::vector& items) { if (items.empty()) { *slst = NULL; return 0; } else { *slst = (char**)malloc(sizeof(char*) * items.size()); if (!*slst) return 0; for (size_t i = 0; i < items.size(); ++i) (*slst)[i] = mystrdup(items[i].c_str()); } return items.size(); } } void Hunspell::free_list(char*** slst, int n) { Hunspell_free_list((Hunhandle*)(this), slst, n); } int Hunspell::suggest(char*** slst, const char* word) { return Hunspell_suggest((Hunhandle*)(this), slst, word); } int Hunspell::suffix_suggest(char*** slst, const char* root_word) { std::vector stems = m_Impl->suffix_suggest(root_word); return munge_vector(slst, stems); } char* Hunspell::get_dic_encoding() { return &(m_Impl->dic_encoding_vec[0]); } int Hunspell::stem(char*** slst, char** desc, int n) { return Hunspell_stem2((Hunhandle*)(this), slst, desc, n); } int Hunspell::stem(char*** slst, const char* word) { return Hunspell_stem((Hunhandle*)(this), slst, word); } int Hunspell::analyze(char*** slst, const char* word) { return Hunspell_analyze((Hunhandle*)(this), slst, word); } int Hunspell::generate(char*** slst, const char* word, char** pl, int pln) { return Hunspell_generate2((Hunhandle*)(this), slst, word, pl, pln); } int Hunspell::generate(char*** slst, const char* word, const char* pattern) { return Hunspell_generate((Hunhandle*)(this), slst, word, pattern); } Hunhandle* Hunspell_create(const char* affpath, const char* dpath) { return (Hunhandle*)(new Hunspell(affpath, dpath)); } Hunhandle* Hunspell_create_key(const char* affpath, const char* dpath, const char* key) { return reinterpret_cast(new Hunspell(affpath, dpath, key)); } void Hunspell_destroy(Hunhandle* pHunspell) { delete reinterpret_cast(pHunspell); } int Hunspell_add_dic(Hunhandle* pHunspell, const char* dpath) { return reinterpret_cast(pHunspell)->add_dic(dpath); } int Hunspell_spell(Hunhandle* pHunspell, const char* word) { return reinterpret_cast(pHunspell)->spell(std::string(word)); } char* Hunspell_get_dic_encoding(Hunhandle* pHunspell) { return reinterpret_cast(pHunspell)->get_dic_encoding(); } int Hunspell_suggest(Hunhandle* pHunspell, char*** slst, const char* word) { std::vector suggests = reinterpret_cast(pHunspell)->suggest(word); return munge_vector(slst, suggests); } int Hunspell_analyze(Hunhandle* pHunspell, char*** slst, const char* word) { std::vector stems = reinterpret_cast(pHunspell)->analyze(word); return munge_vector(slst, stems); } int Hunspell_stem(Hunhandle* pHunspell, char*** slst, const char* word) { std::vector stems = reinterpret_cast(pHunspell)->stem(word); return munge_vector(slst, stems); } int Hunspell_stem2(Hunhandle* pHunspell, char*** slst, char** desc, int n) { std::vector morph; for (int i = 0; i < n; ++i) morph.push_back(desc[i]); std::vector stems = reinterpret_cast(pHunspell)->stem(morph); return munge_vector(slst, stems); } int Hunspell_generate(Hunhandle* pHunspell, char*** slst, const char* word, const char* pattern) { std::vector stems = reinterpret_cast(pHunspell)->generate(word, pattern); return munge_vector(slst, stems); } int Hunspell_generate2(Hunhandle* pHunspell, char*** slst, const char* word, char** desc, int n) { std::vector morph; for (int i = 0; i < n; ++i) morph.push_back(desc[i]); std::vector stems = reinterpret_cast(pHunspell)->generate(word, morph); return munge_vector(slst, stems); } /* functions for run-time modification of the dictionary */ /* add word to the run-time dictionary */ int Hunspell_add(Hunhandle* pHunspell, const char* word) { return reinterpret_cast(pHunspell)->add(word); } /* add word to the run-time dictionary with affix flags of * the example (a dictionary word): Hunspell will recognize * affixed forms of the new word, too. */ int Hunspell_add_with_affix(Hunhandle* pHunspell, const char* word, const char* example) { return reinterpret_cast(pHunspell)->add_with_affix(word, example); } /* remove word from the run-time dictionary */ int Hunspell_remove(Hunhandle* pHunspell, const char* word) { return reinterpret_cast(pHunspell)->remove(word); } void Hunspell_free_list(Hunhandle*, char*** list, int n) { if (list && *list) { for (int i = 0; i < n; i++) free((*list)[i]); free(*list); *list = NULL; } } std::vector Hunspell::suffix_suggest(const std::string& root_word) { return m_Impl->suffix_suggest(root_word); } std::vector HunspellImpl::suffix_suggest(const std::string& root_word) { std::vector slst; struct hentry* he = NULL; int len; std::string w2; const char* word; const char* ignoredchars = pAMgr->get_ignore(); if (ignoredchars != NULL) { w2.assign(root_word); if (utf8) { const std::vector& ignoredchars_utf16 = pAMgr->get_ignore_utf16(); remove_ignored_chars_utf(w2, ignoredchars_utf16); } else { remove_ignored_chars(w2, ignoredchars); } word = w2.c_str(); } else word = root_word.c_str(); len = strlen(word); if (!len) return slst; for (size_t i = 0; (i < m_HMgrs.size()) && !he; ++i) { he = m_HMgrs[i]->lookup(word); } if (he) { slst = pAMgr->get_suffix_words(he->astr, he->alen, root_word.c_str()); } return slst; }