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Diffstat (limited to 'extensions/spellcheck/hunspell/src/affentry.cxx')
-rw-r--r-- | extensions/spellcheck/hunspell/src/affentry.cxx | 983 |
1 files changed, 983 insertions, 0 deletions
diff --git a/extensions/spellcheck/hunspell/src/affentry.cxx b/extensions/spellcheck/hunspell/src/affentry.cxx new file mode 100644 index 0000000000..2cf4f4671f --- /dev/null +++ b/extensions/spellcheck/hunspell/src/affentry.cxx @@ -0,0 +1,983 @@ +/* ***** BEGIN LICENSE BLOCK ***** + * Version: MPL 1.1/GPL 2.0/LGPL 2.1 + * + * Copyright (C) 2002-2022 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 <stdlib.h> +#include <string.h> +#include <stdio.h> +#include <ctype.h> + +#include "affentry.hxx" +#include "csutil.hxx" + +AffEntry::~AffEntry() { + if (opts & aeLONGCOND) + free(c.l.conds2); + if (morphcode && !(opts & aeALIASM)) + free(morphcode); + if (contclass && !(opts & aeALIASF)) + free(contclass); +} + +PfxEntry::PfxEntry(AffixMgr* pmgr) + // register affix manager + : pmyMgr(pmgr), + next(NULL), + nexteq(NULL), + nextne(NULL), + flgnxt(NULL) { +} + +// add prefix to this word assuming conditions hold +std::string PfxEntry::add(const char* word, size_t len) { + std::string result; + if ((len > strip.size() || (len == 0 && pmyMgr->get_fullstrip())) && + (len >= numconds) && test_condition(word) && + (!strip.size() || (strncmp(word, strip.c_str(), strip.size()) == 0))) { + /* we have a match so add prefix */ + result.assign(appnd); + result.append(word + strip.size()); + } + return result; +} + +inline char* PfxEntry::nextchar(char* p) { + if (p) { + p++; + if (opts & aeLONGCOND) { + // jump to the 2nd part of the condition + if (p == c.conds + MAXCONDLEN_1) + return c.l.conds2; + // end of the MAXCONDLEN length condition + } else if (p == c.conds + MAXCONDLEN) + return NULL; + return *p ? p : NULL; + } + return NULL; +} + +inline int PfxEntry::test_condition(const char* st) { + const char* pos = NULL; // group with pos input position + bool neg = false; // complementer + bool ingroup = false; // character in the group + if (numconds == 0) + return 1; + char* p = c.conds; + while (1) { + switch (*p) { + case '\0': + return 1; + case '[': { + neg = false; + ingroup = false; + p = nextchar(p); + pos = st; + break; + } + case '^': { + p = nextchar(p); + neg = true; + break; + } + case ']': { + if (bool(neg) == bool(ingroup)) + return 0; + pos = NULL; + p = nextchar(p); + // skip the next character + if (!ingroup && *st) + for (st++; (opts & aeUTF8) && (*st & 0xc0) == 0x80; st++) + ; + if (*st == '\0' && p) + return 0; // word <= condition + break; + } + case '.': + if (!pos) { // dots are not metacharacters in groups: [.] + p = nextchar(p); + // skip the next character + for (st++; (opts & aeUTF8) && (*st & 0xc0) == 0x80; st++) + ; + if (*st == '\0' && p) + return 0; // word <= condition + break; + } + /* FALLTHROUGH */ + default: { + if (*st == *p) { + st++; + p = nextchar(p); + if ((opts & aeUTF8) && (*(st - 1) & 0x80)) { // multibyte + while (p && (*p & 0xc0) == 0x80) { // character + if (*p != *st) { + if (!pos) + return 0; + st = pos; + break; + } + p = nextchar(p); + st++; + } + if (pos && st != pos) { + ingroup = true; + while (p && *p != ']' && ((p = nextchar(p)) != NULL)) { + } + } + } else if (pos) { + ingroup = true; + while (p && *p != ']' && ((p = nextchar(p)) != NULL)) { + } + } + } else if (pos) { // group + p = nextchar(p); + } else + return 0; + } + } + if (!p) + return 1; + } +} + +// check if this prefix entry matches +struct hentry* PfxEntry::checkword(const char* word, + int len, + char in_compound, + const FLAG needflag) { + struct hentry* he; // hash entry of root word or NULL + + // on entry prefix is 0 length or already matches the beginning of the word. + // So if the remaining root word has positive length + // and if there are enough chars in root word and added back strip chars + // to meet the number of characters conditions, then test it + + int tmpl = len - appnd.size(); // length of tmpword + + if (tmpl > 0 || (tmpl == 0 && pmyMgr->get_fullstrip())) { + // generate new root word by removing prefix and adding + // back any characters that would have been stripped + + std::string tmpword(strip); + tmpword.append(word + appnd.size(), tmpl); + + // now make sure all of the conditions on characters + // are met. Please see the appendix at the end of + // this file for more info on exactly what is being + // tested + + // if all conditions are met then check if resulting + // root word in the dictionary + + if (test_condition(tmpword.c_str())) { + tmpl += strip.size(); + if ((he = pmyMgr->lookup(tmpword.c_str())) != NULL) { + do { + if (TESTAFF(he->astr, aflag, he->alen) && + // forbid single prefixes with needaffix flag + !TESTAFF(contclass, pmyMgr->get_needaffix(), contclasslen) && + // needflag + ((!needflag) || TESTAFF(he->astr, needflag, he->alen) || + (contclass && TESTAFF(contclass, needflag, contclasslen)))) + return he; + he = he->next_homonym; // check homonyms + } while (he); + } + + // prefix matched but no root word was found + // if aeXPRODUCT is allowed, try again but now + // ross checked combined with a suffix + + // if ((opts & aeXPRODUCT) && in_compound) { + if ((opts & aeXPRODUCT)) { + he = pmyMgr->suffix_check(tmpword.c_str(), tmpl, aeXPRODUCT, this, + FLAG_NULL, needflag, in_compound); + if (he) + return he; + } + } + } + return NULL; +} + +// check if this prefix entry matches +struct hentry* PfxEntry::check_twosfx(const char* word, + int len, + char in_compound, + const FLAG needflag) { + // on entry prefix is 0 length or already matches the beginning of the word. + // So if the remaining root word has positive length + // and if there are enough chars in root word and added back strip chars + // to meet the number of characters conditions, then test it + + int tmpl = len - appnd.size(); // length of tmpword + + if ((tmpl > 0 || (tmpl == 0 && pmyMgr->get_fullstrip())) && + (tmpl + strip.size() >= numconds)) { + // generate new root word by removing prefix and adding + // back any characters that would have been stripped + + std::string tmpword(strip); + tmpword.append(word + appnd.size()); + + // now make sure all of the conditions on characters + // are met. Please see the appendix at the end of + // this file for more info on exactly what is being + // tested + + // if all conditions are met then check if resulting + // root word in the dictionary + + if (test_condition(tmpword.c_str())) { + tmpl += strip.size(); + + // prefix matched but no root word was found + // if aeXPRODUCT is allowed, try again but now + // cross checked combined with a suffix + + if ((opts & aeXPRODUCT) && (in_compound != IN_CPD_BEGIN)) { + // hash entry of root word or NULL + struct hentry* he = pmyMgr->suffix_check_twosfx(tmpword.c_str(), tmpl, aeXPRODUCT, this, + needflag); + if (he) + return he; + } + } + } + return NULL; +} + +// check if this prefix entry matches +std::string PfxEntry::check_twosfx_morph(const char* word, + int len, + char in_compound, + const FLAG needflag) { + std::string result; + // on entry prefix is 0 length or already matches the beginning of the word. + // So if the remaining root word has positive length + // and if there are enough chars in root word and added back strip chars + // to meet the number of characters conditions, then test it + int tmpl = len - appnd.size(); // length of tmpword + + if ((tmpl > 0 || (tmpl == 0 && pmyMgr->get_fullstrip())) && + (tmpl + strip.size() >= numconds)) { + // generate new root word by removing prefix and adding + // back any characters that would have been stripped + + std::string tmpword(strip); + tmpword.append(word + appnd.size()); + + // now make sure all of the conditions on characters + // are met. Please see the appendix at the end of + // this file for more info on exactly what is being + // tested + + // if all conditions are met then check if resulting + // root word in the dictionary + + if (test_condition(tmpword.c_str())) { + tmpl += strip.size(); + + // prefix matched but no root word was found + // if aeXPRODUCT is allowed, try again but now + // ross checked combined with a suffix + + if ((opts & aeXPRODUCT) && (in_compound != IN_CPD_BEGIN)) { + result = pmyMgr->suffix_check_twosfx_morph(tmpword.c_str(), tmpl, + aeXPRODUCT, + this, needflag); + } + } + } + return result; +} + +// check if this prefix entry matches +std::string PfxEntry::check_morph(const char* word, + int len, + char in_compound, + const FLAG needflag) { + std::string result; + + // on entry prefix is 0 length or already matches the beginning of the word. + // So if the remaining root word has positive length + // and if there are enough chars in root word and added back strip chars + // to meet the number of characters conditions, then test it + + int tmpl = len - appnd.size(); // length of tmpword + + if ((tmpl > 0 || (tmpl == 0 && pmyMgr->get_fullstrip())) && + (tmpl + strip.size() >= numconds)) { + // generate new root word by removing prefix and adding + // back any characters that would have been stripped + + std::string tmpword(strip); + tmpword.append(word + appnd.size()); + + // now make sure all of the conditions on characters + // are met. Please see the appendix at the end of + // this file for more info on exactly what is being + // tested + + // if all conditions are met then check if resulting + // root word in the dictionary + + if (test_condition(tmpword.c_str())) { + tmpl += strip.size(); + struct hentry* he; // hash entry of root word or NULL + if ((he = pmyMgr->lookup(tmpword.c_str())) != NULL) { + do { + if (TESTAFF(he->astr, aflag, he->alen) && + // forbid single prefixes with needaffix flag + !TESTAFF(contclass, pmyMgr->get_needaffix(), contclasslen) && + // needflag + ((!needflag) || TESTAFF(he->astr, needflag, he->alen) || + (contclass && TESTAFF(contclass, needflag, contclasslen)))) { + if (morphcode) { + result.push_back(MSEP_FLD); + result.append(morphcode); + } else + result.append(getKey()); + if (!HENTRY_FIND(he, MORPH_STEM)) { + result.push_back(MSEP_FLD); + result.append(MORPH_STEM); + result.append(HENTRY_WORD(he)); + } + // store the pointer of the hash entry + if (HENTRY_DATA(he)) { + result.push_back(MSEP_FLD); + result.append(HENTRY_DATA2(he)); + } else { + // return with debug information + char* flag = pmyMgr->encode_flag(getFlag()); + result.push_back(MSEP_FLD); + result.append(MORPH_FLAG); + result.append(flag); + free(flag); + } + result.push_back(MSEP_REC); + } + he = he->next_homonym; + } while (he); + } + + // prefix matched but no root word was found + // if aeXPRODUCT is allowed, try again but now + // ross checked combined with a suffix + + if ((opts & aeXPRODUCT) && (in_compound != IN_CPD_BEGIN)) { + std::string st = pmyMgr->suffix_check_morph(tmpword.c_str(), tmpl, aeXPRODUCT, this, + FLAG_NULL, needflag); + if (!st.empty()) { + result.append(st); + } + } + } + } + + return result; +} + +SfxEntry::SfxEntry(AffixMgr* pmgr) + : pmyMgr(pmgr) // register affix manager + , + next(NULL), + nexteq(NULL), + nextne(NULL), + flgnxt(NULL), + l_morph(NULL), + r_morph(NULL), + eq_morph(NULL) { +} + +// add suffix to this word assuming conditions hold +std::string SfxEntry::add(const char* word, size_t len) { + std::string result; + /* make sure all conditions match */ + if ((len > strip.size() || (len == 0 && pmyMgr->get_fullstrip())) && + (len >= numconds) && test_condition(word + len, word) && + (!strip.size() || + (strcmp(word + len - strip.size(), strip.c_str()) == 0))) { + result.assign(word); + /* we have a match so add suffix */ + result.replace(len - strip.size(), std::string::npos, appnd); + } + return result; +} + +inline char* SfxEntry::nextchar(char* p) { + if (p) { + p++; + if (opts & aeLONGCOND) { + // jump to the 2nd part of the condition + if (p == c.l.conds1 + MAXCONDLEN_1) + return c.l.conds2; + // end of the MAXCONDLEN length condition + } else if (p == c.conds + MAXCONDLEN) + return NULL; + return *p ? p : NULL; + } + return NULL; +} + +inline int SfxEntry::test_condition(const char* st, const char* beg) { + const char* pos = NULL; // group with pos input position + bool neg = false; // complementer + bool ingroup = false; // character in the group + if (numconds == 0) + return 1; + char* p = c.conds; + st--; + int i = 1; + while (1) { + switch (*p) { + case '\0': + return 1; + case '[': + p = nextchar(p); + pos = st; + break; + case '^': + p = nextchar(p); + neg = true; + break; + case ']': + if (!neg && !ingroup) + return 0; + i++; + // skip the next character + if (!ingroup) { + for (; (opts & aeUTF8) && (st >= beg) && (*st & 0xc0) == 0x80; st--) + ; + st--; + } + pos = NULL; + neg = false; + ingroup = false; + p = nextchar(p); + if (st < beg && p) + return 0; // word <= condition + break; + case '.': + if (!pos) { + // dots are not metacharacters in groups: [.] + p = nextchar(p); + // skip the next character + for (st--; (opts & aeUTF8) && (st >= beg) && (*st & 0xc0) == 0x80; + st--) + ; + if (st < beg) { // word <= condition + if (p) + return 0; + else + return 1; + } + if ((opts & aeUTF8) && (*st & 0x80)) { // head of the UTF-8 character + st--; + if (st < beg) { // word <= condition + if (p) + return 0; + else + return 1; + } + } + break; + } + /* FALLTHROUGH */ + default: { + if (*st == *p) { + p = nextchar(p); + if ((opts & aeUTF8) && (*st & 0x80)) { + st--; + while (p && (st >= beg)) { + if (*p != *st) { + if (!pos) + return 0; + st = pos; + break; + } + // first byte of the UTF-8 multibyte character + if ((*p & 0xc0) != 0x80) + break; + p = nextchar(p); + st--; + } + if (pos && st != pos) { + if (neg) + return 0; + else if (i == numconds) + return 1; + ingroup = true; + while (p && *p != ']' && ((p = nextchar(p)) != NULL)) { + } + st--; + } + if (p && *p != ']') + p = nextchar(p); + } else if (pos) { + if (neg) + return 0; + else if (i == numconds) + return 1; + ingroup = true; + while (p && *p != ']' && ((p = nextchar(p)) != NULL)) { + } + // if (p && *p != ']') p = nextchar(p); + st--; + } + if (!pos) { + i++; + st--; + } + if (st < beg && p && *p != ']') + return 0; // word <= condition + } else if (pos) { // group + p = nextchar(p); + } else + return 0; + } + } + if (!p) + return 1; + } +} + +// see if this suffix is present in the word +struct hentry* SfxEntry::checkword(const char* word, + int len, + int optflags, + PfxEntry* ppfx, + const FLAG cclass, + const FLAG needflag, + const FLAG badflag) { + struct hentry* he; // hash entry pointer + PfxEntry* ep = ppfx; + + // if this suffix is being cross checked with a prefix + // but it does not support cross products skip it + + if (((optflags & aeXPRODUCT) != 0) && ((opts & aeXPRODUCT) == 0)) + return NULL; + + // upon entry suffix is 0 length or already matches the end of the word. + // So if the remaining root word has positive length + // and if there are enough chars in root word and added back strip chars + // to meet the number of characters conditions, then test it + + int tmpl = len - appnd.size(); // length of tmpword + // the second condition is not enough for UTF-8 strings + // it checked in test_condition() + + if ((tmpl > 0 || (tmpl == 0 && pmyMgr->get_fullstrip())) && + (tmpl + strip.size() >= numconds)) { + // generate new root word by removing suffix and adding + // back any characters that would have been stripped or + // or null terminating the shorter string + + std::string tmpstring(word, tmpl); + if (strip.size()) { + tmpstring.append(strip); + } + + const char* tmpword = tmpstring.c_str(); + const char* endword = tmpword + tmpstring.size(); + + // now make sure all of the conditions on characters + // are met. Please see the appendix at the end of + // this file for more info on exactly what is being + // tested + + // if all conditions are met then check if resulting + // root word in the dictionary + + if (test_condition(endword, tmpword)) { +#ifdef SZOSZABLYA_POSSIBLE_ROOTS + fprintf(stdout, "%s %s %c\n", word, tmpword, aflag); +#endif + if ((he = pmyMgr->lookup(tmpword)) != NULL) { + do { + // check conditional suffix (enabled by prefix) + if ((TESTAFF(he->astr, aflag, he->alen) || + (ep && ep->getCont() && + TESTAFF(ep->getCont(), aflag, ep->getContLen()))) && + (((optflags & aeXPRODUCT) == 0) || + (ep && TESTAFF(he->astr, ep->getFlag(), he->alen)) || + // enabled by prefix + ((contclass) && + (ep && TESTAFF(contclass, ep->getFlag(), contclasslen)))) && + // handle cont. class + ((!cclass) || + ((contclass) && TESTAFF(contclass, cclass, contclasslen))) && + // check only in compound homonyms (bad flags) + (!badflag || !TESTAFF(he->astr, badflag, he->alen)) && + // handle required flag + ((!needflag) || + (TESTAFF(he->astr, needflag, he->alen) || + ((contclass) && TESTAFF(contclass, needflag, contclasslen))))) + return he; + he = he->next_homonym; // check homonyms + } while (he); + } + } + } + return NULL; +} + +// see if two-level suffix is present in the word +struct hentry* SfxEntry::check_twosfx(const char* word, + int len, + int optflags, + PfxEntry* ppfx, + const FLAG needflag) { + PfxEntry* ep = ppfx; + + // if this suffix is being cross checked with a prefix + // but it does not support cross products skip it + + if ((optflags & aeXPRODUCT) != 0 && (opts & aeXPRODUCT) == 0) + return NULL; + + // upon entry suffix is 0 length or already matches the end of the word. + // So if the remaining root word has positive length + // and if there are enough chars in root word and added back strip chars + // to meet the number of characters conditions, then test it + + int tmpl = len - appnd.size(); // length of tmpword + + if ((tmpl > 0 || (tmpl == 0 && pmyMgr->get_fullstrip())) && + (tmpl + strip.size() >= numconds)) { + // generate new root word by removing suffix and adding + // back any characters that would have been stripped or + // or null terminating the shorter string + + std::string tmpword(word); + tmpword.resize(tmpl); + tmpword.append(strip); + tmpl += strip.size(); + + const char* beg = tmpword.c_str(); + const char* end = beg + tmpl; + + // now make sure all of the conditions on characters + // are met. Please see the appendix at the end of + // this file for more info on exactly what is being + // tested + + // if all conditions are met then recall suffix_check + + if (test_condition(end, beg)) { + struct hentry* he; // hash entry pointer + if (ppfx) { + // handle conditional suffix + if ((contclass) && TESTAFF(contclass, ep->getFlag(), contclasslen)) + he = pmyMgr->suffix_check(tmpword.c_str(), tmpl, 0, NULL, + (FLAG)aflag, needflag, IN_CPD_NOT); + else + he = pmyMgr->suffix_check(tmpword.c_str(), tmpl, optflags, ppfx, + (FLAG)aflag, needflag, IN_CPD_NOT); + } else { + he = pmyMgr->suffix_check(tmpword.c_str(), tmpl, 0, NULL, + (FLAG)aflag, needflag, IN_CPD_NOT); + } + if (he) + return he; + } + } + return NULL; +} + +// see if two-level suffix is present in the word +std::string SfxEntry::check_twosfx_morph(const char* word, + int len, + int optflags, + PfxEntry* ppfx, + const FLAG needflag) { + PfxEntry* ep = ppfx; + + std::string result; + + // if this suffix is being cross checked with a prefix + // but it does not support cross products skip it + + if ((optflags & aeXPRODUCT) != 0 && (opts & aeXPRODUCT) == 0) + return result; + + // upon entry suffix is 0 length or already matches the end of the word. + // So if the remaining root word has positive length + // and if there are enough chars in root word and added back strip chars + // to meet the number of characters conditions, then test it + + int tmpl = len - appnd.size(); // length of tmpword + + if ((tmpl > 0 || (tmpl == 0 && pmyMgr->get_fullstrip())) && + (tmpl + strip.size() >= numconds)) { + // generate new root word by removing suffix and adding + // back any characters that would have been stripped or + // or null terminating the shorter string + + std::string tmpword(word); + tmpword.resize(tmpl); + tmpword.append(strip); + tmpl += strip.size(); + + const char* beg = tmpword.c_str(); + const char* end = beg + tmpl; + + // now make sure all of the conditions on characters + // are met. Please see the appendix at the end of + // this file for more info on exactly what is being + // tested + + // if all conditions are met then recall suffix_check + + if (test_condition(end, beg)) { + if (ppfx) { + // handle conditional suffix + if ((contclass) && TESTAFF(contclass, ep->getFlag(), contclasslen)) { + std::string st = pmyMgr->suffix_check_morph(tmpword.c_str(), tmpl, 0, NULL, aflag, + needflag); + if (!st.empty()) { + if (ppfx->getMorph()) { + result.append(ppfx->getMorph()); + result.push_back(MSEP_FLD); + } + result.append(st); + mychomp(result); + } + } else { + std::string st = pmyMgr->suffix_check_morph(tmpword.c_str(), tmpl, optflags, ppfx, aflag, + needflag); + if (!st.empty()) { + result.append(st); + mychomp(result); + } + } + } else { + std::string st = pmyMgr->suffix_check_morph(tmpword.c_str(), tmpl, 0, NULL, aflag, needflag); + if (!st.empty()) { + result.append(st); + mychomp(result); + } + } + } + } + return result; +} + +// get next homonym with same affix +struct hentry* SfxEntry::get_next_homonym(struct hentry* he, + int optflags, + PfxEntry* ppfx, + const FLAG cclass, + const FLAG needflag) { + PfxEntry* ep = ppfx; + FLAG eFlag = ep ? ep->getFlag() : FLAG_NULL; + + while (he->next_homonym) { + he = he->next_homonym; + if ((TESTAFF(he->astr, aflag, he->alen) || + (ep && ep->getCont() && + TESTAFF(ep->getCont(), aflag, ep->getContLen()))) && + ((optflags & aeXPRODUCT) == 0 || TESTAFF(he->astr, eFlag, he->alen) || + // handle conditional suffix + ((contclass) && TESTAFF(contclass, eFlag, contclasslen))) && + // handle cont. class + ((!cclass) || + ((contclass) && TESTAFF(contclass, cclass, contclasslen))) && + // handle required flag + ((!needflag) || + (TESTAFF(he->astr, needflag, he->alen) || + ((contclass) && TESTAFF(contclass, needflag, contclasslen))))) + return he; + } + return NULL; +} + +void SfxEntry::initReverseWord() { + rappnd = appnd; + reverseword(rappnd); +} + +#if 0 + +Appendix: Understanding Affix Code + + +An affix is either a prefix or a suffix attached to root words to make +other words. + +Basically a Prefix or a Suffix is set of AffEntry objects +which store information about the prefix or suffix along +with supporting routines to check if a word has a particular +prefix or suffix or a combination. + +The structure affentry is defined as follows: + +struct affentry +{ + unsigned short aflag; // ID used to represent the affix + std::string strip; // string to strip before adding affix + std::string appnd; // the affix string to add + char numconds; // the number of conditions that must be met + char opts; // flag: aeXPRODUCT- combine both prefix and suffix + char conds[SETSIZE]; // array which encodes the conditions to be met +}; + + +Here is a suffix borrowed from the en_US.aff file. This file +is whitespace delimited. + +SFX D Y 4 +SFX D 0 e d +SFX D y ied [^aeiou]y +SFX D 0 ed [^ey] +SFX D 0 ed [aeiou]y + +This information can be interpreted as follows: + +In the first line has 4 fields + +Field +----- +1 SFX - indicates this is a suffix +2 D - is the name of the character flag which represents this suffix +3 Y - indicates it can be combined with prefixes (cross product) +4 4 - indicates that sequence of 4 affentry structures are needed to + properly store the affix information + +The remaining lines describe the unique information for the 4 SfxEntry +objects that make up this affix. Each line can be interpreted +as follows: (note fields 1 and 2 are as a check against line 1 info) + +Field +----- +1 SFX - indicates this is a suffix +2 D - is the name of the character flag for this affix +3 y - the string of chars to strip off before adding affix + (a 0 here indicates the NULL string) +4 ied - the string of affix characters to add +5 [^aeiou]y - the conditions which must be met before the affix + can be applied + +Field 5 is interesting. Since this is a suffix, field 5 tells us that +there are 2 conditions that must be met. The first condition is that +the next to the last character in the word must *NOT* be any of the +following "a", "e", "i", "o" or "u". The second condition is that +the last character of the word must end in "y". + +So how can we encode this information concisely and be able to +test for both conditions in a fast manner? The answer is found +but studying the wonderful ispell code of Geoff Kuenning, et.al. +(now available under a normal BSD license). + +If we set up a conds array of 256 bytes indexed (0 to 255) and access it +using a character (cast to an unsigned char) of a string, we have 8 bits +of information we can store about that character. Specifically we +could use each bit to say if that character is allowed in any of the +last (or first for prefixes) 8 characters of the word. + +Basically, each character at one end of the word (up to the number +of conditions) is used to index into the conds array and the resulting +value found there says whether the that character is valid for a +specific character position in the word. + +For prefixes, it does this by setting bit 0 if that char is valid +in the first position, bit 1 if valid in the second position, and so on. + +If a bit is not set, then that char is not valid for that postion in the +word. + +If working with suffixes bit 0 is used for the character closest +to the front, bit 1 for the next character towards the end, ..., +with bit numconds-1 representing the last char at the end of the string. + +Note: since entries in the conds[] are 8 bits, only 8 conditions +(read that only 8 character positions) can be examined at one +end of a word (the beginning for prefixes and the end for suffixes. + +So to make this clearer, lets encode the conds array values for the +first two affentries for the suffix D described earlier. + + + For the first affentry: + numconds = 1 (only examine the last character) + + conds['e'] = (1 << 0) (the word must end in an E) + all others are all 0 + + For the second affentry: + numconds = 2 (only examine the last two characters) + + conds[X] = conds[X] | (1 << 0) (aeiou are not allowed) + where X is all characters *but* a, e, i, o, or u + + + conds['y'] = (1 << 1) (the last char must be a y) + all other bits for all other entries in the conds array are zero + +#endif |