Mercurial > vim
view src/spell.c @ 34686:83875247fbc0 v9.1.0224
patch 9.1.0224: cursor may move too many lines over "right" & "below" virt text
Commit: https://github.com/vim/vim/commit/515f734e687f28f7199b2a8042197624d9f3ec15
Author: Dylan Thacker-Smith <dylan.ah.smith@gmail.com>
Date: Thu Mar 28 12:01:14 2024 +0100
patch 9.1.0224: cursor may move too many lines over "right" & "below" virt text
Problem: If a line has "right" & "below" virtual text properties,
where the "below" property may be stored first due to lack of
ordering between them, then the line height is calculated to
be 1 more and causes the cursor to far over the line.
Solution: Remove some unnecessary setting of a
`next_right_goes_below = TRUE` flag for "below" and "above"
text properties. (Dylan Thacker-Smith)
I modified a regression test I recently added to cover this case,
leveraging the fact that "after", "right" & "below" text properties are
being stored in the reverse of the order they are added in. The
previous version of this regression test was crafted to workaround this
issue so it can be addressed by this separate patch.
closes: #14317
Signed-off-by: Dylan Thacker-Smith <dylan.ah.smith@gmail.com>
Signed-off-by: Christian Brabandt <cb@256bit.org>
| author | Christian Brabandt <cb@256bit.org> |
|---|---|
| date | Thu, 28 Mar 2024 12:15:03 +0100 |
| parents | 9e093c96dff6 |
| children | ffa6ed03a9f2 |
line wrap: on
line source
/* vi:set ts=8 sts=4 sw=4 noet: * * VIM - Vi IMproved by Bram Moolenaar * * Do ":help uganda" in Vim to read copying and usage conditions. * Do ":help credits" in Vim to see a list of people who contributed. * See README.txt for an overview of the Vim source code. */ /* * spell.c: code for spell checking * * See spellfile.c for the Vim spell file format. * * The spell checking mechanism uses a tree (aka trie). Each node in the tree * has a list of bytes that can appear (siblings). For each byte there is a * pointer to the node with the byte that follows in the word (child). * * A NUL byte is used where the word may end. The bytes are sorted, so that * binary searching can be used and the NUL bytes are at the start. The * number of possible bytes is stored before the list of bytes. * * The tree uses two arrays: "byts" stores the characters, "idxs" stores * either the next index or flags. The tree starts at index 0. For example, * to lookup "vi" this sequence is followed: * i = 0 * len = byts[i] * n = where "v" appears in byts[i + 1] to byts[i + len] * i = idxs[n] * len = byts[i] * n = where "i" appears in byts[i + 1] to byts[i + len] * i = idxs[n] * len = byts[i] * find that byts[i + 1] is 0, idxs[i + 1] has flags for "vi". * * There are two word trees: one with case-folded words and one with words in * original case. The second one is only used for keep-case words and is * usually small. * * There is one additional tree for when not all prefixes are applied when * generating the .spl file. This tree stores all the possible prefixes, as * if they were words. At each word (prefix) end the prefix nr is stored, the * following word must support this prefix nr. And the condition nr is * stored, used to lookup the condition that the word must match with. * * Thanks to Olaf Seibert for providing an example implementation of this tree * and the compression mechanism. * LZ trie ideas: * http://www.irb.hr/hr/home/ristov/papers/RistovLZtrieRevision1.pdf * More papers: http://www-igm.univ-mlv.fr/~laporte/publi_en.html * * Matching involves checking the caps type: Onecap ALLCAP KeepCap. * * Why doesn't Vim use aspell/ispell/myspell/etc.? * See ":help develop-spell". */ #define IN_SPELL_C #include "vim.h" #if defined(FEAT_SPELL) || defined(PROTO) #ifndef UNIX // it's in os_unix.h for Unix # include <time.h> // for time_t #endif #define REGION_ALL 0xff // word valid in all regions // Result values. Lower number is accepted over higher one. #define SP_BANNED (-1) #define SP_OK 0 #define SP_RARE 1 #define SP_LOCAL 2 #define SP_BAD 3 /* * Structure to store info for word matching. */ typedef struct matchinf_S { langp_T *mi_lp; // info for language and region // pointers to original text to be checked char_u *mi_word; // start of word being checked char_u *mi_end; // end of matching word so far char_u *mi_fend; // next char to be added to mi_fword char_u *mi_cend; // char after what was used for // mi_capflags // case-folded text char_u mi_fword[MAXWLEN + 1]; // mi_word case-folded int mi_fwordlen; // nr of valid bytes in mi_fword // for when checking word after a prefix int mi_prefarridx; // index in sl_pidxs with list of // affixID/condition int mi_prefcnt; // number of entries at mi_prefarridx int mi_prefixlen; // byte length of prefix int mi_cprefixlen; // byte length of prefix in original // case // for when checking a compound word int mi_compoff; // start of following word offset char_u mi_compflags[MAXWLEN]; // flags for compound words used int mi_complen; // nr of compound words used int mi_compextra; // nr of COMPOUNDROOT words // others int mi_result; // result so far: SP_BAD, SP_OK, etc. int mi_capflags; // WF_ONECAP WF_ALLCAP WF_KEEPCAP win_T *mi_win; // buffer being checked // for NOBREAK int mi_result2; // "mi_result" without following word char_u *mi_end2; // "mi_end" without following word } matchinf_T; static int spell_mb_isword_class(int cl, win_T *wp); // mode values for find_word #define FIND_FOLDWORD 0 // find word case-folded #define FIND_KEEPWORD 1 // find keep-case word #define FIND_PREFIX 2 // find word after prefix #define FIND_COMPOUND 3 // find case-folded compound word #define FIND_KEEPCOMPOUND 4 // find keep-case compound word // type values for get_char_type #define CHAR_OTHER 0 #define CHAR_UPPER 1 #define CHAR_DIGIT 2 static void find_word(matchinf_T *mip, int mode); static void find_prefix(matchinf_T *mip, int mode); static int fold_more(matchinf_T *mip); static void spell_load_cb(char_u *fname, void *cookie); static int count_syllables(slang_T *slang, char_u *word); static void clear_midword(win_T *buf); static void use_midword(slang_T *lp, win_T *buf); static int find_region(char_u *rp, char_u *region); static void spell_soundfold_sofo(slang_T *slang, char_u *inword, char_u *res); static void spell_soundfold_sal(slang_T *slang, char_u *inword, char_u *res); static void spell_soundfold_wsal(slang_T *slang, char_u *inword, char_u *res); static void dump_word(slang_T *slang, char_u *word, char_u *pat, int *dir, int round, int flags, linenr_T lnum); static linenr_T dump_prefixes(slang_T *slang, char_u *word, char_u *pat, int *dir, int round, int flags, linenr_T startlnum); static char_u *advance_camelcase_word(char_u *p, win_T *wp, int *is_camel_case); /* * Main spell-checking function. * "ptr" points to a character that could be the start of a word. * "*attrp" is set to the highlight index for a badly spelled word. For a * non-word or when it's OK it remains unchanged. * This must only be called when 'spelllang' is not empty. * * "capcol" is used to check for a Capitalised word after the end of a * sentence. If it's zero then perform the check. Return the column where to * check next, or -1 when no sentence end was found. If it's NULL then don't * worry. * * Returns the length of the word in bytes, also when it's OK, so that the * caller can skip over the word. */ int spell_check( win_T *wp, // current window char_u *ptr, hlf_T *attrp, int *capcol, // column to check for Capital int docount) // count good words { matchinf_T mi; // Most things are put in "mi" so that it can // be passed to functions quickly. int nrlen = 0; // found a number first int c; int wrongcaplen = 0; int lpi; int count_word = docount; int use_camel_case = *wp->w_s->b_p_spo != NUL; int is_camel_case = FALSE; // A word never starts at a space or a control character. Return quickly // then, skipping over the character. if (*ptr <= ' ') return 1; // Return here when loading language files failed. if (wp->w_s->b_langp.ga_len == 0) return 1; CLEAR_FIELD(mi); // A number is always OK. Also skip hexadecimal numbers 0xFF99 and // 0X99FF. But always do check spelling to find "3GPP" and "11 // julifeest". if (*ptr >= '0' && *ptr <= '9') { if (*ptr == '0' && (ptr[1] == 'b' || ptr[1] == 'B')) mi.mi_end = skipbin(ptr + 2); else if (*ptr == '0' && (ptr[1] == 'x' || ptr[1] == 'X')) mi.mi_end = skiphex(ptr + 2); else mi.mi_end = skipdigits(ptr); nrlen = (int)(mi.mi_end - ptr); } // Find the normal end of the word (until the next non-word character). mi.mi_word = ptr; mi.mi_fend = ptr; if (spell_iswordp(mi.mi_fend, wp)) { if (use_camel_case) mi.mi_fend = advance_camelcase_word(ptr, wp, &is_camel_case); else { do { MB_PTR_ADV(mi.mi_fend); } while (*mi.mi_fend != NUL && spell_iswordp(mi.mi_fend, wp)); } if (capcol != NULL && *capcol == 0 && wp->w_s->b_cap_prog != NULL) { // Check word starting with capital letter. c = PTR2CHAR(ptr); if (!SPELL_ISUPPER(c)) wrongcaplen = (int)(mi.mi_fend - ptr); } } if (capcol != NULL) *capcol = -1; // We always use the characters up to the next non-word character, // also for bad words. mi.mi_end = mi.mi_fend; // Check caps type later. mi.mi_capflags = 0; mi.mi_cend = NULL; mi.mi_win = wp; // case-fold the word with one non-word character, so that we can check // for the word end. if (*mi.mi_fend != NUL) MB_PTR_ADV(mi.mi_fend); (void)spell_casefold(wp, ptr, (int)(mi.mi_fend - ptr), mi.mi_fword, MAXWLEN + 1); mi.mi_fwordlen = (int)STRLEN(mi.mi_fword); if (is_camel_case && mi.mi_fwordlen > 0) // Introduce a fake word end space into the folded word. mi.mi_fword[mi.mi_fwordlen - 1] = ' '; // The word is bad unless we recognize it. mi.mi_result = SP_BAD; mi.mi_result2 = SP_BAD; /* * Loop over the languages specified in 'spelllang'. * We check them all, because a word may be matched longer in another * language. */ for (lpi = 0; lpi < wp->w_s->b_langp.ga_len; ++lpi) { mi.mi_lp = LANGP_ENTRY(wp->w_s->b_langp, lpi); // If reloading fails the language is still in the list but everything // has been cleared. if (mi.mi_lp->lp_slang->sl_fidxs == NULL) continue; // Check for a matching word in case-folded words. find_word(&mi, FIND_FOLDWORD); // Check for a matching word in keep-case words. find_word(&mi, FIND_KEEPWORD); // Check for matching prefixes. find_prefix(&mi, FIND_FOLDWORD); // For a NOBREAK language, may want to use a word without a following // word as a backup. if (mi.mi_lp->lp_slang->sl_nobreak && mi.mi_result == SP_BAD && mi.mi_result2 != SP_BAD) { mi.mi_result = mi.mi_result2; mi.mi_end = mi.mi_end2; } // Count the word in the first language where it's found to be OK. if (count_word && mi.mi_result == SP_OK) { count_common_word(mi.mi_lp->lp_slang, ptr, (int)(mi.mi_end - ptr), 1); count_word = FALSE; } } if (mi.mi_result != SP_OK) { // If we found a number skip over it. Allows for "42nd". Do flag // rare and local words, e.g., "3GPP". if (nrlen > 0) { if (mi.mi_result == SP_BAD || mi.mi_result == SP_BANNED) return nrlen; } // When we are at a non-word character there is no error, just // skip over the character (try looking for a word after it). else if (!spell_iswordp_nmw(ptr, wp)) { if (capcol != NULL && wp->w_s->b_cap_prog != NULL) { regmatch_T regmatch; int r; // Check for end of sentence. regmatch.regprog = wp->w_s->b_cap_prog; regmatch.rm_ic = FALSE; r = vim_regexec(®match, ptr, 0); wp->w_s->b_cap_prog = regmatch.regprog; if (r) *capcol = (int)(regmatch.endp[0] - ptr); } if (has_mbyte) return (*mb_ptr2len)(ptr); return 1; } else if (mi.mi_end == ptr) // Always include at least one character. Required for when there // is a mixup in "midword". MB_PTR_ADV(mi.mi_end); else if (mi.mi_result == SP_BAD && LANGP_ENTRY(wp->w_s->b_langp, 0)->lp_slang->sl_nobreak) { char_u *p, *fp; int save_result = mi.mi_result; // First language in 'spelllang' is NOBREAK. Find first position // at which any word would be valid. mi.mi_lp = LANGP_ENTRY(wp->w_s->b_langp, 0); if (mi.mi_lp->lp_slang->sl_fidxs != NULL) { p = mi.mi_word; fp = mi.mi_fword; for (;;) { MB_PTR_ADV(p); MB_PTR_ADV(fp); if (p >= mi.mi_end) break; mi.mi_compoff = (int)(fp - mi.mi_fword); find_word(&mi, FIND_COMPOUND); if (mi.mi_result != SP_BAD) { mi.mi_end = p; break; } } mi.mi_result = save_result; } } if (mi.mi_result == SP_BAD || mi.mi_result == SP_BANNED) *attrp = HLF_SPB; else if (mi.mi_result == SP_RARE) *attrp = HLF_SPR; else *attrp = HLF_SPL; } if (wrongcaplen > 0 && (mi.mi_result == SP_OK || mi.mi_result == SP_RARE)) { // Report SpellCap only when the word isn't badly spelled. *attrp = HLF_SPC; return wrongcaplen; } return (int)(mi.mi_end - ptr); } /* * Determine the type of character 'c'. */ static int get_char_type(int c) { if (VIM_ISDIGIT(c)) return CHAR_DIGIT; if (SPELL_ISUPPER(c)) return CHAR_UPPER; return CHAR_OTHER; } /* * Returns a pointer to the end of the word starting at "str". * Supports camelCase words. */ static char_u * advance_camelcase_word(char_u *str, win_T *wp, int *is_camel_case) { int last_type, last_last_type, this_type; int c; char_u *end = str; *is_camel_case = FALSE; if (*str == NUL) return str; c = PTR2CHAR(end); MB_PTR_ADV(end); // We need at most the types of the type of the last two chars. last_last_type = -1; last_type = get_char_type(c); while (*end != NUL && spell_iswordp(end, wp)) { c = PTR2CHAR(end); this_type = get_char_type(c); if (last_last_type == CHAR_UPPER && last_type == CHAR_UPPER && this_type == CHAR_OTHER) { // Handle the following cases: // UpperUpperLower *is_camel_case = TRUE; // Back up by one char. MB_PTR_BACK(str, end); break; } else if ((this_type == CHAR_UPPER && last_type == CHAR_OTHER) || (this_type != last_type && (this_type == CHAR_DIGIT || last_type == CHAR_DIGIT))) { // Handle the following cases: // LowerUpper LowerDigit UpperDigit DigitUpper DigitLower *is_camel_case = TRUE; break; } last_last_type = last_type; last_type = this_type; MB_PTR_ADV(end); } return end; } /* * Check if the word at "mip->mi_word" is in the tree. * When "mode" is FIND_FOLDWORD check in fold-case word tree. * When "mode" is FIND_KEEPWORD check in keep-case word tree. * When "mode" is FIND_PREFIX check for word after prefix in fold-case word * tree. * * For a match mip->mi_result is updated. */ static void find_word(matchinf_T *mip, int mode) { idx_T arridx = 0; int endlen[MAXWLEN]; // length at possible word endings idx_T endidx[MAXWLEN]; // possible word endings int endidxcnt = 0; int len; int wlen = 0; int flen; int c; char_u *ptr; idx_T lo, hi, m; char_u *s; char_u *p; int res = SP_BAD; slang_T *slang = mip->mi_lp->lp_slang; unsigned flags; char_u *byts; idx_T *idxs; int word_ends; int prefix_found; int nobreak_result; if (mode == FIND_KEEPWORD || mode == FIND_KEEPCOMPOUND) { // Check for word with matching case in keep-case tree. ptr = mip->mi_word; flen = 9999; // no case folding, always enough bytes byts = slang->sl_kbyts; idxs = slang->sl_kidxs; if (mode == FIND_KEEPCOMPOUND) // Skip over the previously found word(s). wlen += mip->mi_compoff; } else { // Check for case-folded in case-folded tree. ptr = mip->mi_fword; flen = mip->mi_fwordlen; // available case-folded bytes byts = slang->sl_fbyts; idxs = slang->sl_fidxs; if (mode == FIND_PREFIX) { // Skip over the prefix. wlen = mip->mi_prefixlen; flen -= mip->mi_prefixlen; } else if (mode == FIND_COMPOUND) { // Skip over the previously found word(s). wlen = mip->mi_compoff; flen -= mip->mi_compoff; } } if (byts == NULL) return; // array is empty /* * Repeat advancing in the tree until: * - there is a byte that doesn't match, * - we reach the end of the tree, * - or we reach the end of the line. */ for (;;) { if (flen <= 0 && *mip->mi_fend != NUL) flen = fold_more(mip); len = byts[arridx++]; // If the first possible byte is a zero the word could end here. // Remember this index, we first check for the longest word. if (byts[arridx] == 0) { if (endidxcnt == MAXWLEN) { // Must be a corrupted spell file. emsg(_(e_format_error_in_spell_file)); return; } endlen[endidxcnt] = wlen; endidx[endidxcnt++] = arridx++; --len; // Skip over the zeros, there can be several flag/region // combinations. while (len > 0 && byts[arridx] == 0) { ++arridx; --len; } if (len == 0) break; // no children, word must end here } // Stop looking at end of the line. if (ptr[wlen] == NUL) break; // Perform a binary search in the list of accepted bytes. c = ptr[wlen]; if (c == TAB) // <Tab> is handled like <Space> c = ' '; lo = arridx; hi = arridx + len - 1; while (lo < hi) { m = (lo + hi) / 2; if (byts[m] > c) hi = m - 1; else if (byts[m] < c) lo = m + 1; else { lo = hi = m; break; } } // Stop if there is no matching byte. if (hi < lo || byts[lo] != c) break; // Continue at the child (if there is one). arridx = idxs[lo]; ++wlen; --flen; // One space in the good word may stand for several spaces in the // checked word. if (c == ' ') { for (;;) { if (flen <= 0 && *mip->mi_fend != NUL) flen = fold_more(mip); if (ptr[wlen] != ' ' && ptr[wlen] != TAB) break; ++wlen; --flen; } } } /* * Verify that one of the possible endings is valid. Try the longest * first. */ while (endidxcnt > 0) { --endidxcnt; arridx = endidx[endidxcnt]; wlen = endlen[endidxcnt]; if ((*mb_head_off)(ptr, ptr + wlen) > 0) continue; // not at first byte of character if (spell_iswordp(ptr + wlen, mip->mi_win)) { if (slang->sl_compprog == NULL && !slang->sl_nobreak) continue; // next char is a word character word_ends = FALSE; } else word_ends = TRUE; // The prefix flag is before compound flags. Once a valid prefix flag // has been found we try compound flags. prefix_found = FALSE; if (mode != FIND_KEEPWORD && has_mbyte) { // Compute byte length in original word, length may change // when folding case. This can be slow, take a shortcut when the // case-folded word is equal to the keep-case word. p = mip->mi_word; if (STRNCMP(ptr, p, wlen) != 0) { for (s = ptr; s < ptr + wlen; MB_PTR_ADV(s)) MB_PTR_ADV(p); wlen = (int)(p - mip->mi_word); } } // Check flags and region. For FIND_PREFIX check the condition and // prefix ID. // Repeat this if there are more flags/region alternatives until there // is a match. res = SP_BAD; for (len = byts[arridx - 1]; len > 0 && byts[arridx] == 0; --len, ++arridx) { flags = idxs[arridx]; // For the fold-case tree check that the case of the checked word // matches with what the word in the tree requires. // For keep-case tree the case is always right. For prefixes we // don't bother to check. if (mode == FIND_FOLDWORD) { if (mip->mi_cend != mip->mi_word + wlen) { // mi_capflags was set for a different word length, need // to do it again. mip->mi_cend = mip->mi_word + wlen; mip->mi_capflags = captype(mip->mi_word, mip->mi_cend); } if (mip->mi_capflags == WF_KEEPCAP || !spell_valid_case(mip->mi_capflags, flags)) continue; } // When mode is FIND_PREFIX the word must support the prefix: // check the prefix ID and the condition. Do that for the list at // mip->mi_prefarridx that find_prefix() filled. else if (mode == FIND_PREFIX && !prefix_found) { c = valid_word_prefix(mip->mi_prefcnt, mip->mi_prefarridx, flags, mip->mi_word + mip->mi_cprefixlen, slang, FALSE); if (c == 0) continue; // Use the WF_RARE flag for a rare prefix. if (c & WF_RAREPFX) flags |= WF_RARE; prefix_found = TRUE; } if (slang->sl_nobreak) { if ((mode == FIND_COMPOUND || mode == FIND_KEEPCOMPOUND) && (flags & WF_BANNED) == 0) { // NOBREAK: found a valid following word. That's all we // need to know, so return. mip->mi_result = SP_OK; break; } } else if ((mode == FIND_COMPOUND || mode == FIND_KEEPCOMPOUND || !word_ends)) { // If there is no compound flag or the word is shorter than // COMPOUNDMIN reject it quickly. // Makes you wonder why someone puts a compound flag on a word // that's too short... Myspell compatibility requires this // anyway. if (((unsigned)flags >> 24) == 0 || wlen - mip->mi_compoff < slang->sl_compminlen) continue; // For multi-byte chars check character length against // COMPOUNDMIN. if (has_mbyte && slang->sl_compminlen > 0 && mb_charlen_len(mip->mi_word + mip->mi_compoff, wlen - mip->mi_compoff) < slang->sl_compminlen) continue; // Limit the number of compound words to COMPOUNDWORDMAX if no // maximum for syllables is specified. if (!word_ends && mip->mi_complen + mip->mi_compextra + 2 > slang->sl_compmax && slang->sl_compsylmax == MAXWLEN) continue; // Don't allow compounding on a side where an affix was added, // unless COMPOUNDPERMITFLAG was used. if (mip->mi_complen > 0 && (flags & WF_NOCOMPBEF)) continue; if (!word_ends && (flags & WF_NOCOMPAFT)) continue; // Quickly check if compounding is possible with this flag. if (!byte_in_str(mip->mi_complen == 0 ? slang->sl_compstartflags : slang->sl_compallflags, ((unsigned)flags >> 24))) continue; // If there is a match with a CHECKCOMPOUNDPATTERN rule // discard the compound word. if (match_checkcompoundpattern(ptr, wlen, &slang->sl_comppat)) continue; if (mode == FIND_COMPOUND) { int capflags; // Need to check the caps type of the appended compound // word. if (has_mbyte && STRNCMP(ptr, mip->mi_word, mip->mi_compoff) != 0) { // case folding may have changed the length p = mip->mi_word; for (s = ptr; s < ptr + mip->mi_compoff; MB_PTR_ADV(s)) MB_PTR_ADV(p); } else p = mip->mi_word + mip->mi_compoff; capflags = captype(p, mip->mi_word + wlen); if (capflags == WF_KEEPCAP || (capflags == WF_ALLCAP && (flags & WF_FIXCAP) != 0)) continue; if (capflags != WF_ALLCAP) { // When the character before the word is a word // character we do not accept a Onecap word. We do // accept a no-caps word, even when the dictionary // word specifies ONECAP. MB_PTR_BACK(mip->mi_word, p); if (spell_iswordp_nmw(p, mip->mi_win) ? capflags == WF_ONECAP : (flags & WF_ONECAP) != 0 && capflags != WF_ONECAP) continue; } } // If the word ends the sequence of compound flags of the // words must match with one of the COMPOUNDRULE items and // the number of syllables must not be too large. mip->mi_compflags[mip->mi_complen] = ((unsigned)flags >> 24); mip->mi_compflags[mip->mi_complen + 1] = NUL; if (word_ends) { char_u fword[MAXWLEN]; if (slang->sl_compsylmax < MAXWLEN) { // "fword" is only needed for checking syllables. if (ptr == mip->mi_word) (void)spell_casefold(mip->mi_win, ptr, wlen, fword, MAXWLEN); else vim_strncpy(fword, ptr, endlen[endidxcnt]); } if (!can_compound(slang, fword, mip->mi_compflags)) continue; } else if (slang->sl_comprules != NULL && !match_compoundrule(slang, mip->mi_compflags)) // The compound flags collected so far do not match any // COMPOUNDRULE, discard the compounded word. continue; } // Check NEEDCOMPOUND: can't use word without compounding. else if (flags & WF_NEEDCOMP) continue; nobreak_result = SP_OK; if (!word_ends) { int save_result = mip->mi_result; char_u *save_end = mip->mi_end; langp_T *save_lp = mip->mi_lp; int lpi; // Check that a valid word follows. If there is one and we // are compounding, it will set "mi_result", thus we are // always finished here. For NOBREAK we only check that a // valid word follows. // Recursive! if (slang->sl_nobreak) mip->mi_result = SP_BAD; // Find following word in case-folded tree. mip->mi_compoff = endlen[endidxcnt]; if (has_mbyte && mode == FIND_KEEPWORD) { // Compute byte length in case-folded word from "wlen": // byte length in keep-case word. Length may change when // folding case. This can be slow, take a shortcut when // the case-folded word is equal to the keep-case word. p = mip->mi_fword; if (STRNCMP(ptr, p, wlen) != 0) { for (s = ptr; s < ptr + wlen; MB_PTR_ADV(s)) MB_PTR_ADV(p); mip->mi_compoff = (int)(p - mip->mi_fword); } } #if 0 // Disabled, see below c = mip->mi_compoff; #endif ++mip->mi_complen; if (flags & WF_COMPROOT) ++mip->mi_compextra; // For NOBREAK we need to try all NOBREAK languages, at least // to find the ".add" file(s). for (lpi = 0; lpi < mip->mi_win->w_s->b_langp.ga_len; ++lpi) { if (slang->sl_nobreak) { mip->mi_lp = LANGP_ENTRY(mip->mi_win->w_s->b_langp, lpi); if (mip->mi_lp->lp_slang->sl_fidxs == NULL || !mip->mi_lp->lp_slang->sl_nobreak) continue; } find_word(mip, FIND_COMPOUND); // When NOBREAK any word that matches is OK. Otherwise we // need to find the longest match, thus try with keep-case // and prefix too. if (!slang->sl_nobreak || mip->mi_result == SP_BAD) { // Find following word in keep-case tree. mip->mi_compoff = wlen; find_word(mip, FIND_KEEPCOMPOUND); #if 0 // Disabled, a prefix must not appear halfway a compound word, // unless the COMPOUNDPERMITFLAG is used and then it can't be a // postponed prefix. if (!slang->sl_nobreak || mip->mi_result == SP_BAD) { // Check for following word with prefix. mip->mi_compoff = c; find_prefix(mip, FIND_COMPOUND); } #endif } if (!slang->sl_nobreak) break; } --mip->mi_complen; if (flags & WF_COMPROOT) --mip->mi_compextra; mip->mi_lp = save_lp; if (slang->sl_nobreak) { nobreak_result = mip->mi_result; mip->mi_result = save_result; mip->mi_end = save_end; } else { if (mip->mi_result == SP_OK) break; continue; } } if (flags & WF_BANNED) res = SP_BANNED; else if (flags & WF_REGION) { // Check region. if ((mip->mi_lp->lp_region & (flags >> 16)) != 0) res = SP_OK; else res = SP_LOCAL; } else if (flags & WF_RARE) res = SP_RARE; else res = SP_OK; // Always use the longest match and the best result. For NOBREAK // we separately keep the longest match without a following good // word as a fall-back. if (nobreak_result == SP_BAD) { if (mip->mi_result2 > res) { mip->mi_result2 = res; mip->mi_end2 = mip->mi_word + wlen; } else if (mip->mi_result2 == res && mip->mi_end2 < mip->mi_word + wlen) mip->mi_end2 = mip->mi_word + wlen; } else if (mip->mi_result > res) { mip->mi_result = res; mip->mi_end = mip->mi_word + wlen; } else if (mip->mi_result == res && mip->mi_end < mip->mi_word + wlen) mip->mi_end = mip->mi_word + wlen; if (mip->mi_result == SP_OK) break; } if (mip->mi_result == SP_OK) break; } } /* * Return TRUE if there is a match between the word ptr[wlen] and * CHECKCOMPOUNDPATTERN rules, assuming that we will concatenate with another * word. * A match means that the first part of CHECKCOMPOUNDPATTERN matches at the * end of ptr[wlen] and the second part matches after it. */ int match_checkcompoundpattern( char_u *ptr, int wlen, garray_T *gap) // &sl_comppat { int i; char_u *p; int len; for (i = 0; i + 1 < gap->ga_len; i += 2) { p = ((char_u **)gap->ga_data)[i + 1]; if (STRNCMP(ptr + wlen, p, STRLEN(p)) == 0) { // Second part matches at start of following compound word, now // check if first part matches at end of previous word. p = ((char_u **)gap->ga_data)[i]; len = (int)STRLEN(p); if (len <= wlen && STRNCMP(ptr + wlen - len, p, len) == 0) return TRUE; } } return FALSE; } /* * Return TRUE if "flags" is a valid sequence of compound flags and "word" * does not have too many syllables. */ int can_compound(slang_T *slang, char_u *word, char_u *flags) { char_u uflags[MAXWLEN * 2]; int i; char_u *p; if (slang->sl_compprog == NULL) return FALSE; if (enc_utf8) { // Need to convert the single byte flags to utf8 characters. p = uflags; for (i = 0; flags[i] != NUL; ++i) p += utf_char2bytes(flags[i], p); *p = NUL; p = uflags; } else p = flags; if (!vim_regexec_prog(&slang->sl_compprog, FALSE, p, 0)) return FALSE; // Count the number of syllables. This may be slow, do it last. If there // are too many syllables AND the number of compound words is above // COMPOUNDWORDMAX then compounding is not allowed. if (slang->sl_compsylmax < MAXWLEN && count_syllables(slang, word) > slang->sl_compsylmax) return (int)STRLEN(flags) < slang->sl_compmax; return TRUE; } /* * Return TRUE if the compound flags in compflags[] match the start of any * compound rule. This is used to stop trying a compound if the flags * collected so far can't possibly match any compound rule. * Caller must check that slang->sl_comprules is not NULL. */ int match_compoundrule(slang_T *slang, char_u *compflags) { char_u *p; int i; int c; // loop over all the COMPOUNDRULE entries for (p = slang->sl_comprules; *p != NUL; ++p) { // loop over the flags in the compound word we have made, match // them against the current rule entry for (i = 0; ; ++i) { c = compflags[i]; if (c == NUL) // found a rule that matches for the flags we have so far return TRUE; if (*p == '/' || *p == NUL) break; // end of rule, it's too short if (*p == '[') { int match = FALSE; // compare against all the flags in [] ++p; while (*p != ']' && *p != NUL) if (*p++ == c) match = TRUE; if (!match) break; // none matches } else if (*p != c) break; // flag of word doesn't match flag in pattern ++p; } // Skip to the next "/", where the next pattern starts. p = vim_strchr(p, '/'); if (p == NULL) break; } // Checked all the rules and none of them match the flags, so there // can't possibly be a compound starting with these flags. return FALSE; } /* * Return non-zero if the prefix indicated by "arridx" matches with the prefix * ID in "flags" for the word "word". * The WF_RAREPFX flag is included in the return value for a rare prefix. */ int valid_word_prefix( int totprefcnt, // nr of prefix IDs int arridx, // idx in sl_pidxs[] int flags, char_u *word, slang_T *slang, int cond_req) // only use prefixes with a condition { int prefcnt; int pidx; regprog_T **rp; int prefid; prefid = (unsigned)flags >> 24; for (prefcnt = totprefcnt - 1; prefcnt >= 0; --prefcnt) { pidx = slang->sl_pidxs[arridx + prefcnt]; // Check the prefix ID. if (prefid != (pidx & 0xff)) continue; // Check if the prefix doesn't combine and the word already has a // suffix. if ((flags & WF_HAS_AFF) && (pidx & WF_PFX_NC)) continue; // Check the condition, if there is one. The condition index is // stored in the two bytes above the prefix ID byte. rp = &slang->sl_prefprog[((unsigned)pidx >> 8) & 0xffff]; if (*rp != NULL) { if (!vim_regexec_prog(rp, FALSE, word, 0)) continue; } else if (cond_req) continue; // It's a match! Return the WF_ flags. return pidx; } return 0; } /* * Check if the word at "mip->mi_word" has a matching prefix. * If it does, then check the following word. * * If "mode" is "FIND_COMPOUND" then do the same after another word, find a * prefix in a compound word. * * For a match mip->mi_result is updated. */ static void find_prefix(matchinf_T *mip, int mode) { idx_T arridx = 0; int len; int wlen = 0; int flen; int c; char_u *ptr; idx_T lo, hi, m; slang_T *slang = mip->mi_lp->lp_slang; char_u *byts; idx_T *idxs; byts = slang->sl_pbyts; if (byts == NULL) return; // array is empty // We use the case-folded word here, since prefixes are always // case-folded. ptr = mip->mi_fword; flen = mip->mi_fwordlen; // available case-folded bytes if (mode == FIND_COMPOUND) { // Skip over the previously found word(s). ptr += mip->mi_compoff; flen -= mip->mi_compoff; } idxs = slang->sl_pidxs; /* * Repeat advancing in the tree until: * - there is a byte that doesn't match, * - we reach the end of the tree, * - or we reach the end of the line. */ for (;;) { if (flen == 0 && *mip->mi_fend != NUL) flen = fold_more(mip); len = byts[arridx++]; // If the first possible byte is a zero the prefix could end here. // Check if the following word matches and supports the prefix. if (byts[arridx] == 0) { // There can be several prefixes with different conditions. We // try them all, since we don't know which one will give the // longest match. The word is the same each time, pass the list // of possible prefixes to find_word(). mip->mi_prefarridx = arridx; mip->mi_prefcnt = len; while (len > 0 && byts[arridx] == 0) { ++arridx; --len; } mip->mi_prefcnt -= len; // Find the word that comes after the prefix. mip->mi_prefixlen = wlen; if (mode == FIND_COMPOUND) // Skip over the previously found word(s). mip->mi_prefixlen += mip->mi_compoff; if (has_mbyte) { // Case-folded length may differ from original length. mip->mi_cprefixlen = nofold_len(mip->mi_fword, mip->mi_prefixlen, mip->mi_word); } else mip->mi_cprefixlen = mip->mi_prefixlen; find_word(mip, FIND_PREFIX); if (len == 0) break; // no children, word must end here } // Stop looking at end of the line. if (ptr[wlen] == NUL) break; // Perform a binary search in the list of accepted bytes. c = ptr[wlen]; lo = arridx; hi = arridx + len - 1; while (lo < hi) { m = (lo + hi) / 2; if (byts[m] > c) hi = m - 1; else if (byts[m] < c) lo = m + 1; else { lo = hi = m; break; } } // Stop if there is no matching byte. if (hi < lo || byts[lo] != c) break; // Continue at the child (if there is one). arridx = idxs[lo]; ++wlen; --flen; } } /* * Need to fold at least one more character. Do until next non-word character * for efficiency. Include the non-word character too. * Return the length of the folded chars in bytes. */ static int fold_more(matchinf_T *mip) { int flen; char_u *p; p = mip->mi_fend; do MB_PTR_ADV(mip->mi_fend); while (*mip->mi_fend != NUL && spell_iswordp(mip->mi_fend, mip->mi_win)); // Include the non-word character so that we can check for the word end. if (*mip->mi_fend != NUL) MB_PTR_ADV(mip->mi_fend); (void)spell_casefold(mip->mi_win, p, (int)(mip->mi_fend - p), mip->mi_fword + mip->mi_fwordlen, MAXWLEN - mip->mi_fwordlen); flen = (int)STRLEN(mip->mi_fword + mip->mi_fwordlen); mip->mi_fwordlen += flen; return flen; } /* * Check case flags for a word. Return TRUE if the word has the requested * case. */ int spell_valid_case( int wordflags, // flags for the checked word. int treeflags) // flags for the word in the spell tree { return ((wordflags == WF_ALLCAP && (treeflags & WF_FIXCAP) == 0) || ((treeflags & (WF_ALLCAP | WF_KEEPCAP)) == 0 && ((treeflags & WF_ONECAP) == 0 || (wordflags & WF_ONECAP) != 0))); } /* * Return TRUE if spell checking is enabled for "wp". */ int spell_check_window(win_T *wp) { return wp->w_p_spell && *wp->w_s->b_p_spl != NUL && wp->w_s->b_langp.ga_len > 0 && *(char **)(wp->w_s->b_langp.ga_data) != NULL; } /* * Return TRUE and give an error if spell checking is not enabled. */ static int no_spell_checking(win_T *wp) { if (spell_check_window(wp)) return FALSE; emsg(_(e_spell_checking_is_not_possible)); return TRUE; } /* * Move to next spell error. * "curline" is FALSE for "[s", "]s", "[S" and "]S". * "curline" is TRUE to find word under/after cursor in the same line. * For Insert mode completion "dir" is BACKWARD and "curline" is TRUE: move * to after badly spelled word before the cursor. * Return 0 if not found, length of the badly spelled word otherwise. */ int spell_move_to( win_T *wp, int dir, // FORWARD or BACKWARD int allwords, // TRUE for "[s"/"]s", FALSE for "[S"/"]S" int curline, hlf_T *attrp) // return: attributes of bad word or NULL // (only when "dir" is FORWARD) { linenr_T lnum; pos_T found_pos; int found_len = 0; char_u *line; char_u *p; char_u *endp; hlf_T attr = 0; int len; #ifdef FEAT_SYN_HL int has_syntax = syntax_present(wp); #endif int col; int can_spell; char_u *buf = NULL; int buflen = 0; int skip = 0; int capcol = -1; int found_one = FALSE; int wrapped = FALSE; if (no_spell_checking(wp)) return 0; /* * Start looking for bad word at the start of the line, because we can't * start halfway a word, we don't know where it starts or ends. * * When searching backwards, we continue in the line to find the last * bad word (in the cursor line: before the cursor). * * We concatenate the start of the next line, so that wrapped words work * (e.g. "et<line-break>cetera"). Doesn't work when searching backwards * though... */ lnum = wp->w_cursor.lnum; CLEAR_POS(&found_pos); while (!got_int) { int empty_line; line = ml_get_buf(wp->w_buffer, lnum, FALSE); len = ml_get_buf_len(wp->w_buffer, lnum); if (buflen < len + MAXWLEN + 2) { vim_free(buf); buflen = len + MAXWLEN + 2; buf = alloc(buflen); if (buf == NULL) break; } // In first line check first word for Capital. if (lnum == 1) capcol = 0; // For checking first word with a capital skip white space. if (capcol == 0) capcol = getwhitecols(line); else if (curline && wp == curwin) { // For spellbadword(): check if first word needs a capital. col = getwhitecols(line); if (check_need_cap(curwin, lnum, col)) capcol = col; // Need to get the line again, may have looked at the previous // one. line = ml_get_buf(wp->w_buffer, lnum, FALSE); } // Copy the line into "buf" and append the start of the next line if // possible. Note: this ml_get_buf() may make "line" invalid, check // for empty line first. empty_line = *skipwhite(line) == NUL; STRCPY(buf, line); if (lnum < wp->w_buffer->b_ml.ml_line_count) spell_cat_line(buf + STRLEN(buf), ml_get_buf(wp->w_buffer, lnum + 1, FALSE), MAXWLEN); p = buf + skip; endp = buf + len; while (p < endp) { // When searching backward don't search after the cursor. Unless // we wrapped around the end of the buffer. if (dir == BACKWARD && lnum == wp->w_cursor.lnum && !wrapped && (colnr_T)(p - buf) >= wp->w_cursor.col) break; // start of word attr = HLF_COUNT; len = spell_check(wp, p, &attr, &capcol, FALSE); if (attr != HLF_COUNT) { // We found a bad word. Check the attribute. if (allwords || attr == HLF_SPB) { // When searching forward only accept a bad word after // the cursor. if (dir == BACKWARD || lnum != wp->w_cursor.lnum || (wrapped || (colnr_T)(curline ? p - buf + len : p - buf) > wp->w_cursor.col)) { #ifdef FEAT_SYN_HL if (has_syntax) { col = (int)(p - buf); (void)syn_get_id(wp, lnum, (colnr_T)col, FALSE, &can_spell, FALSE); if (!can_spell) attr = HLF_COUNT; } else #endif can_spell = TRUE; if (can_spell) { found_one = TRUE; found_pos.lnum = lnum; found_pos.col = (int)(p - buf); found_pos.coladd = 0; if (dir == FORWARD) { // No need to search further. wp->w_cursor = found_pos; vim_free(buf); if (attrp != NULL) *attrp = attr; return len; } else if (curline) // Insert mode completion: put cursor after // the bad word. found_pos.col += len; found_len = len; } } else found_one = TRUE; } } // advance to character after the word p += len; capcol -= len; } if (dir == BACKWARD && found_pos.lnum != 0) { // Use the last match in the line (before the cursor). wp->w_cursor = found_pos; vim_free(buf); return found_len; } if (curline) break; // only check cursor line // If we are back at the starting line and searched it again there // is no match, give up. if (lnum == wp->w_cursor.lnum && wrapped) break; // Advance to next line. if (dir == BACKWARD) { if (lnum > 1) --lnum; else if (!p_ws) break; // at first line and 'nowrapscan' else { // Wrap around to the end of the buffer. May search the // starting line again and accept the last match. lnum = wp->w_buffer->b_ml.ml_line_count; wrapped = TRUE; if (!shortmess(SHM_SEARCH)) give_warning((char_u *)_(top_bot_msg), TRUE); } capcol = -1; } else { if (lnum < wp->w_buffer->b_ml.ml_line_count) ++lnum; else if (!p_ws) break; // at first line and 'nowrapscan' else { // Wrap around to the start of the buffer. May search the // starting line again and accept the first match. lnum = 1; wrapped = TRUE; if (!shortmess(SHM_SEARCH)) give_warning((char_u *)_(bot_top_msg), TRUE); } // If we are back at the starting line and there is no match then // give up. if (lnum == wp->w_cursor.lnum && !found_one) break; // Skip the characters at the start of the next line that were // included in a match crossing line boundaries. if (attr == HLF_COUNT) skip = (int)(p - endp); else skip = 0; // Capcol skips over the inserted space. --capcol; // But after empty line check first word in next line if (empty_line) capcol = 0; } line_breakcheck(); } vim_free(buf); return 0; } /* * For spell checking: concatenate the start of the following line "line" into * "buf", blanking-out special characters. Copy less than "maxlen" bytes. * Keep the blanks at the start of the next line, this is used in win_line() * to skip those bytes if the word was OK. */ void spell_cat_line(char_u *buf, char_u *line, int maxlen) { char_u *p; int n; p = skipwhite(line); while (vim_strchr((char_u *)"*#/\"\t", *p) != NULL) p = skipwhite(p + 1); if (*p == NUL) return; // Only worth concatenating if there is something else than spaces to // concatenate. n = (int)(p - line) + 1; if (n < maxlen - 1) { vim_memset(buf, ' ', n); vim_strncpy(buf + n, p, maxlen - 1 - n); } } /* * Structure used for the cookie argument of do_in_runtimepath(). */ typedef struct spelload_S { char_u sl_lang[MAXWLEN + 1]; // language name slang_T *sl_slang; // resulting slang_T struct int sl_nobreak; // NOBREAK language found } spelload_T; /* * Load word list(s) for "lang" from Vim spell file(s). * "lang" must be the language without the region: e.g., "en". */ static void spell_load_lang(char_u *lang) { char_u fname_enc[85]; int r; spelload_T sl; int round; // Copy the language name to pass it to spell_load_cb() as a cookie. // It's truncated when an error is detected. STRCPY(sl.sl_lang, lang); sl.sl_slang = NULL; sl.sl_nobreak = FALSE; // Disallow deleting the current buffer. Autocommands can do weird things // and cause "lang" to be freed. ++curbuf->b_locked; // We may retry when no spell file is found for the language, an // autocommand may load it then. for (round = 1; round <= 2; ++round) { /* * Find the first spell file for "lang" in 'runtimepath' and load it. */ vim_snprintf((char *)fname_enc, sizeof(fname_enc) - 5, #ifdef VMS "spell/%s_%s.spl", #else "spell/%s.%s.spl", #endif lang, spell_enc()); r = do_in_runtimepath(fname_enc, 0, spell_load_cb, &sl); if (r == FAIL && *sl.sl_lang != NUL) { // Try loading the ASCII version. vim_snprintf((char *)fname_enc, sizeof(fname_enc) - 5, #ifdef VMS "spell/%s_ascii.spl", #else "spell/%s.ascii.spl", #endif lang); r = do_in_runtimepath(fname_enc, 0, spell_load_cb, &sl); if (r == FAIL && *sl.sl_lang != NUL && round == 1 && apply_autocmds(EVENT_SPELLFILEMISSING, lang, curbuf->b_fname, FALSE, curbuf)) continue; break; } break; } if (r == FAIL) { smsg( #ifdef VMS _("Warning: Cannot find word list \"%s_%s.spl\" or \"%s_ascii.spl\""), #else _("Warning: Cannot find word list \"%s.%s.spl\" or \"%s.ascii.spl\""), #endif lang, spell_enc(), lang); } else if (sl.sl_slang != NULL) { // At least one file was loaded, now load ALL the additions. STRCPY(fname_enc + STRLEN(fname_enc) - 3, "add.spl"); do_in_runtimepath(fname_enc, DIP_ALL, spell_load_cb, &sl); } --curbuf->b_locked; } /* * Return the encoding used for spell checking: Use 'encoding', except that we * use "latin1" for "latin9". And limit to 60 characters (just in case). */ char_u * spell_enc(void) { if (STRLEN(p_enc) < 60 && STRCMP(p_enc, "iso-8859-15") != 0) return p_enc; return (char_u *)"latin1"; } /* * Get the name of the .spl file for the internal wordlist into * "fname[MAXPATHL]". */ static void int_wordlist_spl(char_u *fname) { vim_snprintf((char *)fname, MAXPATHL, SPL_FNAME_TMPL, int_wordlist, spell_enc()); } /* * Allocate a new slang_T for language "lang". "lang" can be NULL. * Caller must fill "sl_next". */ slang_T * slang_alloc(char_u *lang) { slang_T *lp; lp = ALLOC_CLEAR_ONE(slang_T); if (lp != NULL) { if (lang != NULL) lp->sl_name = vim_strsave(lang); ga_init2(&lp->sl_rep, sizeof(fromto_T), 10); ga_init2(&lp->sl_repsal, sizeof(fromto_T), 10); lp->sl_compmax = MAXWLEN; lp->sl_compsylmax = MAXWLEN; hash_init(&lp->sl_wordcount); } return lp; } /* * Free the contents of an slang_T and the structure itself. */ void slang_free(slang_T *lp) { vim_free(lp->sl_name); vim_free(lp->sl_fname); slang_clear(lp); vim_free(lp); } /* * Clear an slang_T so that the file can be reloaded. */ void slang_clear(slang_T *lp) { garray_T *gap; fromto_T *ftp; salitem_T *smp; int i; int round; VIM_CLEAR(lp->sl_fbyts); VIM_CLEAR(lp->sl_kbyts); VIM_CLEAR(lp->sl_pbyts); VIM_CLEAR(lp->sl_fidxs); VIM_CLEAR(lp->sl_kidxs); VIM_CLEAR(lp->sl_pidxs); for (round = 1; round <= 2; ++round) { gap = round == 1 ? &lp->sl_rep : &lp->sl_repsal; while (gap->ga_len > 0) { ftp = &((fromto_T *)gap->ga_data)[--gap->ga_len]; vim_free(ftp->ft_from); vim_free(ftp->ft_to); } ga_clear(gap); } gap = &lp->sl_sal; if (lp->sl_sofo) { // "ga_len" is set to 1 without adding an item for latin1 if (gap->ga_data != NULL) // SOFOFROM and SOFOTO items: free lists of wide characters. for (i = 0; i < gap->ga_len; ++i) vim_free(((int **)gap->ga_data)[i]); } else // SAL items: free salitem_T items while (gap->ga_len > 0) { smp = &((salitem_T *)gap->ga_data)[--gap->ga_len]; vim_free(smp->sm_lead); // Don't free sm_oneof and sm_rules, they point into sm_lead. vim_free(smp->sm_to); vim_free(smp->sm_lead_w); vim_free(smp->sm_oneof_w); vim_free(smp->sm_to_w); } ga_clear(gap); for (i = 0; i < lp->sl_prefixcnt; ++i) vim_regfree(lp->sl_prefprog[i]); lp->sl_prefixcnt = 0; VIM_CLEAR(lp->sl_prefprog); VIM_CLEAR(lp->sl_info); VIM_CLEAR(lp->sl_midword); vim_regfree(lp->sl_compprog); lp->sl_compprog = NULL; VIM_CLEAR(lp->sl_comprules); VIM_CLEAR(lp->sl_compstartflags); VIM_CLEAR(lp->sl_compallflags); VIM_CLEAR(lp->sl_syllable); ga_clear(&lp->sl_syl_items); ga_clear_strings(&lp->sl_comppat); hash_clear_all(&lp->sl_wordcount, WC_KEY_OFF); hash_init(&lp->sl_wordcount); hash_clear_all(&lp->sl_map_hash, 0); // Clear info from .sug file. slang_clear_sug(lp); lp->sl_compmax = MAXWLEN; lp->sl_compminlen = 0; lp->sl_compsylmax = MAXWLEN; lp->sl_regions[0] = NUL; } /* * Clear the info from the .sug file in "lp". */ void slang_clear_sug(slang_T *lp) { VIM_CLEAR(lp->sl_sbyts); VIM_CLEAR(lp->sl_sidxs); close_spellbuf(lp->sl_sugbuf); lp->sl_sugbuf = NULL; lp->sl_sugloaded = FALSE; lp->sl_sugtime = 0; } /* * Load one spell file and store the info into a slang_T. * Invoked through do_in_runtimepath(). */ static void spell_load_cb(char_u *fname, void *cookie) { spelload_T *slp = (spelload_T *)cookie; slang_T *slang; slang = spell_load_file(fname, slp->sl_lang, NULL, FALSE); if (slang == NULL) return; // When a previously loaded file has NOBREAK also use it for the // ".add" files. if (slp->sl_nobreak && slang->sl_add) slang->sl_nobreak = TRUE; else if (slang->sl_nobreak) slp->sl_nobreak = TRUE; slp->sl_slang = slang; } /* * Add a word to the hashtable of common words. * If it's already there then the counter is increased. */ void count_common_word( slang_T *lp, char_u *word, int len, // word length, -1 for up to NUL int count) // 1 to count once, 10 to init { hash_T hash; hashitem_T *hi; wordcount_T *wc; char_u buf[MAXWLEN]; char_u *p; if (len == -1) p = word; else if (len >= MAXWLEN) return; else { vim_strncpy(buf, word, len); p = buf; } hash = hash_hash(p); hi = hash_lookup(&lp->sl_wordcount, p, hash); if (HASHITEM_EMPTY(hi)) { wc = alloc(offsetof(wordcount_T, wc_word) + STRLEN(p) + 1); if (wc == NULL) return; STRCPY(wc->wc_word, p); wc->wc_count = count; hash_add_item(&lp->sl_wordcount, hi, wc->wc_word, hash); } else { wc = HI2WC(hi); if ((wc->wc_count += count) < (unsigned)count) // check for overflow wc->wc_count = MAXWORDCOUNT; } } /* * Return TRUE if byte "n" appears in "str". * Like strchr() but independent of locale. */ int byte_in_str(char_u *str, int n) { char_u *p; for (p = str; *p != NUL; ++p) if (*p == n) return TRUE; return FALSE; } #define SY_MAXLEN 30 typedef struct syl_item_S { char_u sy_chars[SY_MAXLEN]; // the sequence of chars int sy_len; } syl_item_T; /* * Truncate "slang->sl_syllable" at the first slash and put the following items * in "slang->sl_syl_items". */ int init_syl_tab(slang_T *slang) { char_u *p; char_u *s; int l; syl_item_T *syl; ga_init2(&slang->sl_syl_items, sizeof(syl_item_T), 4); p = vim_strchr(slang->sl_syllable, '/'); while (p != NULL) { *p++ = NUL; if (*p == NUL) // trailing slash break; s = p; p = vim_strchr(p, '/'); if (p == NULL) l = (int)STRLEN(s); else l = (int)(p - s); if (l >= SY_MAXLEN) return SP_FORMERROR; if (ga_grow(&slang->sl_syl_items, 1) == FAIL) return SP_OTHERERROR; syl = ((syl_item_T *)slang->sl_syl_items.ga_data) + slang->sl_syl_items.ga_len++; vim_strncpy(syl->sy_chars, s, l); syl->sy_len = l; } return OK; } /* * Count the number of syllables in "word". * When "word" contains spaces the syllables after the last space are counted. * Returns zero if syllables are not defines. */ static int count_syllables(slang_T *slang, char_u *word) { int cnt = 0; int skip = FALSE; char_u *p; int len; int i; syl_item_T *syl; int c; if (slang->sl_syllable == NULL) return 0; for (p = word; *p != NUL; p += len) { // When running into a space reset counter. if (*p == ' ') { len = 1; cnt = 0; continue; } // Find longest match of syllable items. len = 0; for (i = 0; i < slang->sl_syl_items.ga_len; ++i) { syl = ((syl_item_T *)slang->sl_syl_items.ga_data) + i; if (syl->sy_len > len && STRNCMP(p, syl->sy_chars, syl->sy_len) == 0) len = syl->sy_len; } if (len != 0) // found a match, count syllable { ++cnt; skip = FALSE; } else { // No recognized syllable item, at least a syllable char then? c = mb_ptr2char(p); len = (*mb_ptr2len)(p); if (vim_strchr(slang->sl_syllable, c) == NULL) skip = FALSE; // No, search for next syllable else if (!skip) { ++cnt; // Yes, count it skip = TRUE; // don't count following syllable chars } } } return cnt; } /* * Parse 'spelllang' and set w_s->b_langp accordingly. * Returns NULL if it's OK, an untranslated error message otherwise. */ char * parse_spelllang(win_T *wp) { garray_T ga; char_u *splp; char_u *region; char_u region_cp[3]; int filename; int region_mask; slang_T *slang; int c; char_u lang[MAXWLEN + 1]; char_u spf_name[MAXPATHL]; int len; char_u *p; int round; char_u *spf; char_u *use_region = NULL; int dont_use_region = FALSE; int nobreak = FALSE; int i, j; langp_T *lp, *lp2; static int recursive = FALSE; char *ret_msg = NULL; char_u *spl_copy; bufref_T bufref; set_bufref(&bufref, wp->w_buffer); // We don't want to do this recursively. May happen when a language is // not available and the SpellFileMissing autocommand opens a new buffer // in which 'spell' is set. if (recursive) return NULL; recursive = TRUE; ga_init2(&ga, sizeof(langp_T), 2); clear_midword(wp); // Make a copy of 'spelllang', the SpellFileMissing autocommands may change // it under our fingers. spl_copy = vim_strsave(wp->w_s->b_p_spl); if (spl_copy == NULL) goto theend; wp->w_s->b_cjk = 0; // Loop over comma separated language names. for (splp = spl_copy; *splp != NUL; ) { // Get one language name. copy_option_part(&splp, lang, MAXWLEN, ","); region = NULL; len = (int)STRLEN(lang); if (!valid_spelllang(lang)) continue; if (STRCMP(lang, "cjk") == 0) { wp->w_s->b_cjk = 1; continue; } // If the name ends in ".spl" use it as the name of the spell file. // If there is a region name let "region" point to it and remove it // from the name. if (len > 4 && fnamecmp(lang + len - 4, ".spl") == 0) { filename = TRUE; // Locate a region and remove it from the file name. p = vim_strchr(gettail(lang), '_'); if (p != NULL && ASCII_ISALPHA(p[1]) && ASCII_ISALPHA(p[2]) && !ASCII_ISALPHA(p[3])) { vim_strncpy(region_cp, p + 1, 2); mch_memmove(p, p + 3, len - (p - lang) - 2); region = region_cp; } else dont_use_region = TRUE; // Check if we loaded this language before. FOR_ALL_SPELL_LANGS(slang) if (fullpathcmp(lang, slang->sl_fname, FALSE, TRUE) == FPC_SAME) break; } else { filename = FALSE; if (len > 3 && lang[len - 3] == '_') { region = lang + len - 2; len -= 3; lang[len] = NUL; } else dont_use_region = TRUE; // Check if we loaded this language before. FOR_ALL_SPELL_LANGS(slang) if (STRICMP(lang, slang->sl_name) == 0) break; } if (region != NULL) { // If the region differs from what was used before then don't // use it for 'spellfile'. if (use_region != NULL && STRCMP(region, use_region) != 0) dont_use_region = TRUE; use_region = region; } // If not found try loading the language now. if (slang == NULL) { if (filename) (void)spell_load_file(lang, lang, NULL, FALSE); else { spell_load_lang(lang); // SpellFileMissing autocommands may do anything, including // destroying the buffer we are using or closing the window. if (!bufref_valid(&bufref) || !win_valid_any_tab(wp)) { ret_msg = N_(e_spellfilemising_autocommand_deleted_buffer); goto theend; } } } /* * Loop over the languages, there can be several files for "lang". */ FOR_ALL_SPELL_LANGS(slang) if (filename ? fullpathcmp(lang, slang->sl_fname, FALSE, TRUE) == FPC_SAME : STRICMP(lang, slang->sl_name) == 0) { region_mask = REGION_ALL; if (!filename && region != NULL) { // find region in sl_regions c = find_region(slang->sl_regions, region); if (c == REGION_ALL) { if (slang->sl_add) { if (*slang->sl_regions != NUL) // This addition file is for other regions. region_mask = 0; } else // This is probably an error. Give a warning and // accept the words anyway. smsg(_("Warning: region %s not supported"), region); } else region_mask = 1 << c; } if (region_mask != 0) { if (ga_grow(&ga, 1) == FAIL) { ga_clear(&ga); ret_msg = e_out_of_memory; goto theend; } LANGP_ENTRY(ga, ga.ga_len)->lp_slang = slang; LANGP_ENTRY(ga, ga.ga_len)->lp_region = region_mask; ++ga.ga_len; use_midword(slang, wp); if (slang->sl_nobreak) nobreak = TRUE; } } } // round 0: load int_wordlist, if possible. // round 1: load first name in 'spellfile'. // round 2: load second name in 'spellfile. // etc. spf = curwin->w_s->b_p_spf; for (round = 0; round == 0 || *spf != NUL; ++round) { if (round == 0) { // Internal wordlist, if there is one. if (int_wordlist == NULL) continue; int_wordlist_spl(spf_name); } else { // One entry in 'spellfile'. copy_option_part(&spf, spf_name, MAXPATHL - 5, ","); STRCAT(spf_name, ".spl"); // If it was already found above then skip it. for (c = 0; c < ga.ga_len; ++c) { p = LANGP_ENTRY(ga, c)->lp_slang->sl_fname; if (p != NULL && fullpathcmp(spf_name, p, FALSE, TRUE) == FPC_SAME) break; } if (c < ga.ga_len) continue; } // Check if it was loaded already. FOR_ALL_SPELL_LANGS(slang) if (fullpathcmp(spf_name, slang->sl_fname, FALSE, TRUE) == FPC_SAME) break; if (slang == NULL) { // Not loaded, try loading it now. The language name includes the // region name, the region is ignored otherwise. for int_wordlist // use an arbitrary name. if (round == 0) STRCPY(lang, "internal wordlist"); else { vim_strncpy(lang, gettail(spf_name), MAXWLEN); p = vim_strchr(lang, '.'); if (p != NULL) *p = NUL; // truncate at ".encoding.add" } slang = spell_load_file(spf_name, lang, NULL, TRUE); // If one of the languages has NOBREAK we assume the addition // files also have this. if (slang != NULL && nobreak) slang->sl_nobreak = TRUE; } if (slang != NULL && ga_grow(&ga, 1) == OK) { region_mask = REGION_ALL; if (use_region != NULL && !dont_use_region) { // find region in sl_regions c = find_region(slang->sl_regions, use_region); if (c != REGION_ALL) region_mask = 1 << c; else if (*slang->sl_regions != NUL) // This spell file is for other regions. region_mask = 0; } if (region_mask != 0) { LANGP_ENTRY(ga, ga.ga_len)->lp_slang = slang; LANGP_ENTRY(ga, ga.ga_len)->lp_sallang = NULL; LANGP_ENTRY(ga, ga.ga_len)->lp_replang = NULL; LANGP_ENTRY(ga, ga.ga_len)->lp_region = region_mask; ++ga.ga_len; use_midword(slang, wp); } } } // Everything is fine, store the new b_langp value. ga_clear(&wp->w_s->b_langp); wp->w_s->b_langp = ga; // For each language figure out what language to use for sound folding and // REP items. If the language doesn't support it itself use another one // with the same name. E.g. for "en-math" use "en". for (i = 0; i < ga.ga_len; ++i) { lp = LANGP_ENTRY(ga, i); // sound folding if (lp->lp_slang->sl_sal.ga_len > 0) // language does sound folding itself lp->lp_sallang = lp->lp_slang; else // find first similar language that does sound folding for (j = 0; j < ga.ga_len; ++j) { lp2 = LANGP_ENTRY(ga, j); if (lp2->lp_slang->sl_sal.ga_len > 0 && STRNCMP(lp->lp_slang->sl_name, lp2->lp_slang->sl_name, 2) == 0) { lp->lp_sallang = lp2->lp_slang; break; } } // REP items if (lp->lp_slang->sl_rep.ga_len > 0) // language has REP items itself lp->lp_replang = lp->lp_slang; else // find first similar language that has REP items for (j = 0; j < ga.ga_len; ++j) { lp2 = LANGP_ENTRY(ga, j); if (lp2->lp_slang->sl_rep.ga_len > 0 && STRNCMP(lp->lp_slang->sl_name, lp2->lp_slang->sl_name, 2) == 0) { lp->lp_replang = lp2->lp_slang; break; } } } redraw_win_later(wp, UPD_NOT_VALID); theend: vim_free(spl_copy); recursive = FALSE; return ret_msg; } /* * Clear the midword characters for buffer "buf". */ static void clear_midword(win_T *wp) { CLEAR_FIELD(wp->w_s->b_spell_ismw); VIM_CLEAR(wp->w_s->b_spell_ismw_mb); } /* * Use the "sl_midword" field of language "lp" for buffer "buf". * They add up to any currently used midword characters. */ static void use_midword(slang_T *lp, win_T *wp) { char_u *p; if (lp->sl_midword == NULL) // there aren't any return; for (p = lp->sl_midword; *p != NUL; ) if (has_mbyte) { int c, l, n; char_u *bp; c = mb_ptr2char(p); l = (*mb_ptr2len)(p); if (c < 256 && l <= 2) wp->w_s->b_spell_ismw[c] = TRUE; else if (wp->w_s->b_spell_ismw_mb == NULL) // First multi-byte char in "b_spell_ismw_mb". wp->w_s->b_spell_ismw_mb = vim_strnsave(p, l); else { // Append multi-byte chars to "b_spell_ismw_mb". n = (int)STRLEN(wp->w_s->b_spell_ismw_mb); bp = vim_strnsave(wp->w_s->b_spell_ismw_mb, n + l); if (bp != NULL) { vim_free(wp->w_s->b_spell_ismw_mb); wp->w_s->b_spell_ismw_mb = bp; vim_strncpy(bp + n, p, l); } } p += l; } else wp->w_s->b_spell_ismw[*p++] = TRUE; } /* * Find the region "region[2]" in "rp" (points to "sl_regions"). * Each region is simply stored as the two characters of its name. * Returns the index if found (first is 0), REGION_ALL if not found. */ static int find_region(char_u *rp, char_u *region) { int i; for (i = 0; ; i += 2) { if (rp[i] == NUL) return REGION_ALL; if (rp[i] == region[0] && rp[i + 1] == region[1]) break; } return i / 2; } /* * Return case type of word: * w word 0 * Word WF_ONECAP * W WORD WF_ALLCAP * WoRd wOrd WF_KEEPCAP */ int captype( char_u *word, char_u *end) // When NULL use up to NUL byte. { char_u *p; int c; int firstcap; int allcap; int past_second = FALSE; // past second word char // find first letter for (p = word; !spell_iswordp_nmw(p, curwin); MB_PTR_ADV(p)) if (end == NULL ? *p == NUL : p >= end) return 0; // only non-word characters, illegal word if (has_mbyte) c = mb_ptr2char_adv(&p); else c = *p++; firstcap = allcap = SPELL_ISUPPER(c); /* * Need to check all letters to find a word with mixed upper/lower. * But a word with an upper char only at start is a ONECAP. */ for ( ; end == NULL ? *p != NUL : p < end; MB_PTR_ADV(p)) if (spell_iswordp_nmw(p, curwin)) { c = PTR2CHAR(p); if (!SPELL_ISUPPER(c)) { // UUl -> KEEPCAP if (past_second && allcap) return WF_KEEPCAP; allcap = FALSE; } else if (!allcap) // UlU -> KEEPCAP return WF_KEEPCAP; past_second = TRUE; } if (allcap) return WF_ALLCAP; if (firstcap) return WF_ONECAP; return 0; } /* * Delete the internal wordlist and its .spl file. */ void spell_delete_wordlist(void) { char_u fname[MAXPATHL]; if (int_wordlist == NULL) return; mch_remove(int_wordlist); int_wordlist_spl(fname); mch_remove(fname); VIM_CLEAR(int_wordlist); } /* * Free all languages. */ void spell_free_all(void) { slang_T *slang; buf_T *buf; // Go through all buffers and handle 'spelllang'. <VN> FOR_ALL_BUFFERS(buf) ga_clear(&buf->b_s.b_langp); while (first_lang != NULL) { slang = first_lang; first_lang = slang->sl_next; slang_free(slang); } spell_delete_wordlist(); VIM_CLEAR(repl_to); VIM_CLEAR(repl_from); } /* * Clear all spelling tables and reload them. * Used after 'encoding' is set and when ":mkspell" was used. */ void spell_reload(void) { win_T *wp; // Initialize the table for spell_iswordp(). init_spell_chartab(); // Unload all allocated memory. spell_free_all(); // Go through all buffers and handle 'spelllang'. FOR_ALL_WINDOWS(wp) { // Only load the wordlists when 'spelllang' is set and there is a // window for this buffer in which 'spell' is set. if (*wp->w_s->b_p_spl != NUL) { if (wp->w_p_spell) { (void)parse_spelllang(wp); break; } } } } /* * Open a spell buffer. This is a nameless buffer that is not in the buffer * list and only contains text lines. Can use a swapfile to reduce memory * use. * Most other fields are invalid! Esp. watch out for string options being * NULL and there is no undo info. * Returns NULL when out of memory. */ buf_T * open_spellbuf(void) { buf_T *buf; buf = ALLOC_CLEAR_ONE(buf_T); if (buf == NULL) return NULL; buf->b_spell = TRUE; buf->b_p_swf = TRUE; // may create a swap file #ifdef FEAT_CRYPT buf->b_p_key = empty_option; #endif ml_open(buf); ml_open_file(buf); // create swap file now return buf; } /* * Close the buffer used for spell info. */ void close_spellbuf(buf_T *buf) { if (buf == NULL) return; ml_close(buf, TRUE); vim_free(buf); } /* * Init the chartab used for spelling for ASCII. */ void clear_spell_chartab(spelltab_T *sp) { int i; // Init everything to FALSE (zero). CLEAR_FIELD(sp->st_isw); CLEAR_FIELD(sp->st_isu); for (i = 0; i < 256; ++i) { sp->st_fold[i] = i; sp->st_upper[i] = i; } // We include digits. A word shouldn't start with a digit, but handling // that is done separately. for (i = '0'; i <= '9'; ++i) sp->st_isw[i] = TRUE; for (i = 'A'; i <= 'Z'; ++i) { sp->st_isw[i] = TRUE; sp->st_isu[i] = TRUE; sp->st_fold[i] = i + 0x20; } for (i = 'a'; i <= 'z'; ++i) { sp->st_isw[i] = TRUE; sp->st_upper[i] = i - 0x20; } } /* * Init the chartab used for spelling. Only depends on 'encoding'. * Called once while starting up and when 'encoding' changes. * The default is to use isalpha(), but the spell file should define the word * characters to make it possible that 'encoding' differs from the current * locale. For utf-8 we don't use isalpha() but our own functions. */ void init_spell_chartab(void) { int i; did_set_spelltab = FALSE; clear_spell_chartab(&spelltab); if (enc_dbcs) { // DBCS: assume double-wide characters are word characters. for (i = 128; i <= 255; ++i) if (MB_BYTE2LEN(i) == 2) spelltab.st_isw[i] = TRUE; } else if (enc_utf8) { for (i = 128; i < 256; ++i) { int f = utf_fold(i); int u = utf_toupper(i); spelltab.st_isu[i] = utf_isupper(i); spelltab.st_isw[i] = spelltab.st_isu[i] || utf_islower(i); // The folded/upper-cased value is different between latin1 and // utf8 for 0xb5, causing E763 for no good reason. Use the latin1 // value for utf-8 to avoid this. spelltab.st_fold[i] = (f < 256) ? f : i; spelltab.st_upper[i] = (u < 256) ? u : i; } } else { // Rough guess: use locale-dependent library functions. for (i = 128; i < 256; ++i) { if (MB_ISUPPER(i)) { spelltab.st_isw[i] = TRUE; spelltab.st_isu[i] = TRUE; spelltab.st_fold[i] = MB_TOLOWER(i); } else if (MB_ISLOWER(i)) { spelltab.st_isw[i] = TRUE; spelltab.st_upper[i] = MB_TOUPPER(i); } } } } /* * Return TRUE if "p" points to a word character. * As a special case we see "midword" characters as word character when it is * followed by a word character. This finds they'there but not 'they there'. * Thus this only works properly when past the first character of the word. */ int spell_iswordp( char_u *p, win_T *wp) // buffer used { char_u *s; int l; int c; if (has_mbyte) { l = mb_ptr2len(p); s = p; if (l == 1) { // be quick for ASCII if (wp->w_s->b_spell_ismw[*p]) s = p + 1; // skip a mid-word character } else { c = mb_ptr2char(p); if (c < 256 ? wp->w_s->b_spell_ismw[c] : (wp->w_s->b_spell_ismw_mb != NULL && vim_strchr(wp->w_s->b_spell_ismw_mb, c) != NULL)) s = p + l; } c = mb_ptr2char(s); if (c > 255) return spell_mb_isword_class(mb_get_class(s), wp); return spelltab.st_isw[c]; } return spelltab.st_isw[wp->w_s->b_spell_ismw[*p] ? p[1] : p[0]]; } /* * Return TRUE if "p" points to a word character. * Unlike spell_iswordp() this doesn't check for "midword" characters. */ int spell_iswordp_nmw(char_u *p, win_T *wp) { int c; if (has_mbyte) { c = mb_ptr2char(p); if (c > 255) return spell_mb_isword_class(mb_get_class(p), wp); return spelltab.st_isw[c]; } return spelltab.st_isw[*p]; } /* * Return TRUE if word class indicates a word character. * Only for characters above 255. * Unicode subscript and superscript are not considered word characters. * See also dbcs_class() and utf_class() in mbyte.c. */ static int spell_mb_isword_class(int cl, win_T *wp) { if (wp->w_s->b_cjk) // East Asian characters are not considered word characters. return cl == 2 || cl == 0x2800; return cl >= 2 && cl != 0x2070 && cl != 0x2080 && cl != 3; } /* * Return TRUE if "p" points to a word character. * Wide version of spell_iswordp(). */ static int spell_iswordp_w(int *p, win_T *wp) { int *s; if (*p < 256 ? wp->w_s->b_spell_ismw[*p] : (wp->w_s->b_spell_ismw_mb != NULL && vim_strchr(wp->w_s->b_spell_ismw_mb, *p) != NULL)) s = p + 1; else s = p; if (*s > 255) { if (enc_utf8) return spell_mb_isword_class(utf_class(*s), wp); if (enc_dbcs) return spell_mb_isword_class( dbcs_class((unsigned)*s >> 8, *s & 0xff), wp); return 0; } return spelltab.st_isw[*s]; } /* * Case-fold "str[len]" into "buf[buflen]". The result is NUL terminated. * Uses the character definitions from the .spl file. * When using a multi-byte 'encoding' the length may change! * Returns FAIL when something wrong. */ int spell_casefold( win_T *wp, char_u *str, int len, char_u *buf, int buflen) { int i; if (len >= buflen) { buf[0] = NUL; return FAIL; // result will not fit } if (has_mbyte) { int outi = 0; char_u *p; int c; // Fold one character at a time. for (p = str; p < str + len; ) { if (outi + MB_MAXBYTES > buflen) { buf[outi] = NUL; return FAIL; } c = mb_cptr2char_adv(&p); // Exception: greek capital sigma 0x03A3 folds to 0x03C3, except // when it is the last character in a word, then it folds to // 0x03C2. if (c == 0x03a3 || c == 0x03c2) { if (p == str + len || !spell_iswordp(p, wp)) c = 0x03c2; else c = 0x03c3; } else c = SPELL_TOFOLD(c); outi += mb_char2bytes(c, buf + outi); } buf[outi] = NUL; } else { // Be quick for non-multibyte encodings. for (i = 0; i < len; ++i) buf[i] = spelltab.st_fold[str[i]]; buf[i] = NUL; } return OK; } /* * Check if the word at line "lnum" column "col" is required to start with a * capital. This uses 'spellcapcheck' of the buffer in window "wp". */ int check_need_cap(win_T *wp, linenr_T lnum, colnr_T col) { if (wp->w_s->b_cap_prog == NULL) return FALSE; int need_cap = FALSE; char_u *line = col ? ml_get_buf(wp->w_buffer, lnum, FALSE) : NULL; char_u *line_copy = NULL; colnr_T endcol = 0; if (col == 0 || getwhitecols(line) >= col) { // At start of line, check if previous line is empty or sentence // ends there. if (lnum == 1) need_cap = TRUE; else { line = ml_get_buf(wp->w_buffer, lnum - 1, FALSE); if (*skipwhite(line) == NUL) need_cap = TRUE; else { // Append a space in place of the line break. line_copy = concat_str(line, (char_u *)" "); if (line_copy == NULL) return FALSE; line = line_copy; endcol = (colnr_T)STRLEN(line); } } } else endcol = col; if (endcol > 0) { // Check if sentence ends before the bad word. regmatch_T regmatch; regmatch.regprog = wp->w_s->b_cap_prog; regmatch.rm_ic = FALSE; char_u *p = line + endcol; for (;;) { MB_PTR_BACK(line, p); if (p == line || spell_iswordp_nmw(p, wp)) break; if (vim_regexec(®match, p, 0) && regmatch.endp[0] == line + endcol) { need_cap = TRUE; break; } } wp->w_s->b_cap_prog = regmatch.regprog; } vim_free(line_copy); return need_cap; } /* * ":spellrepall" */ void ex_spellrepall(exarg_T *eap UNUSED) { pos_T pos = curwin->w_cursor; char_u *frompat; char_u *line; char_u *p; int save_ws = p_ws; linenr_T prev_lnum = 0; if (repl_from == NULL || repl_to == NULL) { emsg(_(e_no_previous_spell_replacement)); return; } size_t repl_from_len = STRLEN(repl_from); size_t repl_to_len = STRLEN(repl_to); int addlen = (int)(repl_to_len - repl_from_len); frompat = alloc(repl_from_len + 7); if (frompat == NULL) return; sprintf((char *)frompat, "\\V\\<%s\\>", repl_from); p_ws = FALSE; sub_nsubs = 0; sub_nlines = 0; curwin->w_cursor.lnum = 0; while (!got_int) { if (do_search(NULL, '/', '/', frompat, 1L, SEARCH_KEEP, NULL) == 0 || u_save_cursor() == FAIL) break; // Only replace when the right word isn't there yet. This happens // when changing "etc" to "etc.". line = ml_get_curline(); if (addlen <= 0 || STRNCMP(line + curwin->w_cursor.col, repl_to, repl_to_len) != 0) { p = alloc(ml_get_curline_len() + addlen + 1); if (p == NULL) break; mch_memmove(p, line, curwin->w_cursor.col); STRCPY(p + curwin->w_cursor.col, repl_to); STRCAT(p, line + curwin->w_cursor.col + repl_from_len); ml_replace(curwin->w_cursor.lnum, p, FALSE); changed_bytes(curwin->w_cursor.lnum, curwin->w_cursor.col); #if defined(FEAT_PROP_POPUP) if (curbuf->b_has_textprop && addlen != 0) adjust_prop_columns(curwin->w_cursor.lnum, curwin->w_cursor.col, addlen, APC_SUBSTITUTE); #endif if (curwin->w_cursor.lnum != prev_lnum) { ++sub_nlines; prev_lnum = curwin->w_cursor.lnum; } ++sub_nsubs; } curwin->w_cursor.col += (colnr_T)repl_to_len; } p_ws = save_ws; curwin->w_cursor = pos; vim_free(frompat); if (sub_nsubs == 0) semsg(_(e_not_found_str), repl_from); else do_sub_msg(FALSE); } /* * Make a copy of "word", with the first letter upper or lower cased, to * "wcopy[MAXWLEN]". "word" must not be empty. * The result is NUL terminated. */ void onecap_copy( char_u *word, char_u *wcopy, int upper) // TRUE: first letter made upper case { char_u *p; int c; int l; p = word; if (has_mbyte) c = mb_cptr2char_adv(&p); else c = *p++; if (upper) c = SPELL_TOUPPER(c); else c = SPELL_TOFOLD(c); if (has_mbyte) l = mb_char2bytes(c, wcopy); else { l = 1; wcopy[0] = c; } vim_strncpy(wcopy + l, p, MAXWLEN - l - 1); } /* * Make a copy of "word" with all the letters upper cased into * "wcopy[MAXWLEN]". The result is NUL terminated. */ void allcap_copy(char_u *word, char_u *wcopy) { char_u *s; char_u *d; int c; d = wcopy; for (s = word; *s != NUL; ) { if (has_mbyte) c = mb_cptr2char_adv(&s); else c = *s++; // We only change 0xdf to SS when we are certain latin1 is used. It // would cause weird errors in other 8-bit encodings. if (enc_latin1like && c == 0xdf) { c = 'S'; if (d - wcopy >= MAXWLEN - 1) break; *d++ = c; } else c = SPELL_TOUPPER(c); if (has_mbyte) { if (d - wcopy >= MAXWLEN - MB_MAXBYTES) break; d += mb_char2bytes(c, d); } else { if (d - wcopy >= MAXWLEN - 1) break; *d++ = c; } } *d = NUL; } /* * Case-folding may change the number of bytes: Count nr of chars in * fword[flen] and return the byte length of that many chars in "word". */ int nofold_len(char_u *fword, int flen, char_u *word) { char_u *p; int i = 0; for (p = fword; p < fword + flen; MB_PTR_ADV(p)) ++i; for (p = word; i > 0; MB_PTR_ADV(p)) --i; return (int)(p - word); } /* * Copy "fword" to "cword", fixing case according to "flags". */ void make_case_word(char_u *fword, char_u *cword, int flags) { if (flags & WF_ALLCAP) // Make it all upper-case allcap_copy(fword, cword); else if (flags & WF_ONECAP) // Make the first letter upper-case onecap_copy(fword, cword, TRUE); else // Use goodword as-is. STRCPY(cword, fword); } #if defined(FEAT_EVAL) || defined(PROTO) /* * Soundfold a string, for soundfold(). * Result is in allocated memory, NULL for an error. */ char_u * eval_soundfold(char_u *word) { langp_T *lp; char_u sound[MAXWLEN]; int lpi; if (curwin->w_p_spell && *curwin->w_s->b_p_spl != NUL) // Use the sound-folding of the first language that supports it. for (lpi = 0; lpi < curwin->w_s->b_langp.ga_len; ++lpi) { lp = LANGP_ENTRY(curwin->w_s->b_langp, lpi); if (lp->lp_slang->sl_sal.ga_len > 0) { // soundfold the word spell_soundfold(lp->lp_slang, word, FALSE, sound); return vim_strsave(sound); } } // No language with sound folding, return word as-is. return vim_strsave(word); } #endif /* * Turn "inword" into its sound-a-like equivalent in "res[MAXWLEN]". * * There are many ways to turn a word into a sound-a-like representation. The * oldest is Soundex (1918!). A nice overview can be found in "Approximate * swedish name matching - survey and test of different algorithms" by Klas * Erikson. * * We support two methods: * 1. SOFOFROM/SOFOTO do a simple character mapping. * 2. SAL items define a more advanced sound-folding (and much slower). */ void spell_soundfold( slang_T *slang, char_u *inword, int folded, // "inword" is already case-folded char_u *res) { char_u fword[MAXWLEN]; char_u *word; if (slang->sl_sofo) // SOFOFROM and SOFOTO used spell_soundfold_sofo(slang, inword, res); else { // SAL items used. Requires the word to be case-folded. if (folded) word = inword; else { (void)spell_casefold(curwin, inword, (int)STRLEN(inword), fword, MAXWLEN); word = fword; } if (has_mbyte) spell_soundfold_wsal(slang, word, res); else spell_soundfold_sal(slang, word, res); } } /* * Perform sound folding of "inword" into "res" according to SOFOFROM and * SOFOTO lines. */ static void spell_soundfold_sofo(slang_T *slang, char_u *inword, char_u *res) { char_u *s; int ri = 0; int c; if (has_mbyte) { int prevc = 0; int *ip; // The sl_sal_first[] table contains the translation for chars up to // 255, sl_sal the rest. for (s = inword; *s != NUL; ) { c = mb_cptr2char_adv(&s); if (enc_utf8 ? utf_class(c) == 0 : VIM_ISWHITE(c)) c = ' '; else if (c < 256) c = slang->sl_sal_first[c]; else { ip = ((int **)slang->sl_sal.ga_data)[c & 0xff]; if (ip == NULL) // empty list, can't match c = NUL; else for (;;) // find "c" in the list { if (*ip == 0) // not found { c = NUL; break; } if (*ip == c) // match! { c = ip[1]; break; } ip += 2; } } if (c != NUL && c != prevc) { ri += mb_char2bytes(c, res + ri); if (ri + MB_MAXBYTES > MAXWLEN) break; prevc = c; } } } else { // The sl_sal_first[] table contains the translation. for (s = inword; (c = *s) != NUL; ++s) { if (VIM_ISWHITE(c)) c = ' '; else c = slang->sl_sal_first[c]; if (c != NUL && (ri == 0 || res[ri - 1] != c)) res[ri++] = c; } } res[ri] = NUL; } static void spell_soundfold_sal(slang_T *slang, char_u *inword, char_u *res) { salitem_T *smp; char_u word[MAXWLEN]; char_u *s = inword; char_u *t; char_u *pf; int i, j, z; int reslen; int n, k = 0; int z0; int k0; int n0; int c; int pri; int p0 = -333; int c0; // Remove accents, if wanted. We actually remove all non-word characters. // But keep white space. We need a copy, the word may be changed here. if (slang->sl_rem_accents) { t = word; while (*s != NUL) { if (VIM_ISWHITE(*s)) { *t++ = ' '; s = skipwhite(s); } else { if (spell_iswordp_nmw(s, curwin)) *t++ = *s; ++s; } } *t = NUL; } else vim_strncpy(word, s, MAXWLEN - 1); smp = (salitem_T *)slang->sl_sal.ga_data; /* * This comes from Aspell phonet.cpp. Converted from C++ to C. * Changed to keep spaces. */ i = reslen = z = 0; while ((c = word[i]) != NUL) { // Start with the first rule that has the character in the word. n = slang->sl_sal_first[c]; z0 = 0; if (n >= 0) { // check all rules for the same letter for (; (s = smp[n].sm_lead)[0] == c; ++n) { // Quickly skip entries that don't match the word. Most // entries are less than three chars, optimize for that. k = smp[n].sm_leadlen; if (k > 1) { if (word[i + 1] != s[1]) continue; if (k > 2) { for (j = 2; j < k; ++j) if (word[i + j] != s[j]) break; if (j < k) continue; } } if ((pf = smp[n].sm_oneof) != NULL) { // Check for match with one of the chars in "sm_oneof". while (*pf != NUL && *pf != word[i + k]) ++pf; if (*pf == NUL) continue; ++k; } s = smp[n].sm_rules; pri = 5; // default priority p0 = *s; k0 = k; while (*s == '-' && k > 1) { k--; s++; } if (*s == '<') s++; if (VIM_ISDIGIT(*s)) { // determine priority pri = *s - '0'; s++; } if (*s == '^' && *(s + 1) == '^') s++; if (*s == NUL || (*s == '^' && (i == 0 || !(word[i - 1] == ' ' || spell_iswordp(word + i - 1, curwin))) && (*(s + 1) != '$' || (!spell_iswordp(word + i + k0, curwin)))) || (*s == '$' && i > 0 && spell_iswordp(word + i - 1, curwin) && (!spell_iswordp(word + i + k0, curwin)))) { // search for followup rules, if: // followup and k > 1 and NO '-' in searchstring c0 = word[i + k - 1]; n0 = slang->sl_sal_first[c0]; if (slang->sl_followup && k > 1 && n0 >= 0 && p0 != '-' && word[i + k] != NUL) { // test follow-up rule for "word[i + k]" for ( ; (s = smp[n0].sm_lead)[0] == c0; ++n0) { // Quickly skip entries that don't match the word. // k0 = smp[n0].sm_leadlen; if (k0 > 1) { if (word[i + k] != s[1]) continue; if (k0 > 2) { pf = word + i + k + 1; for (j = 2; j < k0; ++j) if (*pf++ != s[j]) break; if (j < k0) continue; } } k0 += k - 1; if ((pf = smp[n0].sm_oneof) != NULL) { // Check for match with one of the chars in // "sm_oneof". while (*pf != NUL && *pf != word[i + k0]) ++pf; if (*pf == NUL) continue; ++k0; } p0 = 5; s = smp[n0].sm_rules; while (*s == '-') { // "k0" gets NOT reduced because // "if (k0 == k)" s++; } if (*s == '<') s++; if (VIM_ISDIGIT(*s)) { p0 = *s - '0'; s++; } if (*s == NUL // *s == '^' cuts || (*s == '$' && !spell_iswordp(word + i + k0, curwin))) { if (k0 == k) // this is just a piece of the string continue; if (p0 < pri) // priority too low continue; // rule fits; stop search break; } } if (p0 >= pri && smp[n0].sm_lead[0] == c0) continue; } // replace string s = smp[n].sm_to; if (s == NULL) s = (char_u *)""; pf = smp[n].sm_rules; p0 = (vim_strchr(pf, '<') != NULL) ? 1 : 0; if (p0 == 1 && z == 0) { // rule with '<' is used if (reslen > 0 && *s != NUL && (res[reslen - 1] == c || res[reslen - 1] == *s)) reslen--; z0 = 1; z = 1; k0 = 0; while (*s != NUL && word[i + k0] != NUL) { word[i + k0] = *s; k0++; s++; } if (k > k0) STRMOVE(word + i + k0, word + i + k); // new "actual letter" c = word[i]; } else { // no '<' rule used i += k - 1; z = 0; while (*s != NUL && s[1] != NUL && reslen < MAXWLEN) { if (reslen == 0 || res[reslen - 1] != *s) res[reslen++] = *s; s++; } // new "actual letter" c = *s; if (strstr((char *)pf, "^^") != NULL) { if (c != NUL) res[reslen++] = c; STRMOVE(word, word + i + 1); i = 0; z0 = 1; } } break; } } } else if (VIM_ISWHITE(c)) { c = ' '; k = 1; } if (z0 == 0) { if (k && !p0 && reslen < MAXWLEN && c != NUL && (!slang->sl_collapse || reslen == 0 || res[reslen - 1] != c)) // condense only double letters res[reslen++] = c; i++; z = 0; k = 0; } } res[reslen] = NUL; } /* * Turn "inword" into its sound-a-like equivalent in "res[MAXWLEN]". * Multi-byte version of spell_soundfold(). */ static void spell_soundfold_wsal(slang_T *slang, char_u *inword, char_u *res) { salitem_T *smp = (salitem_T *)slang->sl_sal.ga_data; int word[MAXWLEN]; int wres[MAXWLEN]; int l; char_u *s; int *ws; char_u *t; int *pf; int i, j, z; int reslen; int n, k = 0; int z0; int k0; int n0; int c; int pri; int p0 = -333; int c0; int did_white = FALSE; int wordlen; /* * Convert the multi-byte string to a wide-character string. * Remove accents, if wanted. We actually remove all non-word characters. * But keep white space. */ wordlen = 0; for (s = inword; *s != NUL; ) { t = s; c = mb_cptr2char_adv(&s); if (slang->sl_rem_accents) { if (enc_utf8 ? utf_class(c) == 0 : VIM_ISWHITE(c)) { if (did_white) continue; c = ' '; did_white = TRUE; } else { did_white = FALSE; if (!spell_iswordp_nmw(t, curwin)) continue; } } word[wordlen++] = c; } word[wordlen] = NUL; /* * This algorithm comes from Aspell phonet.cpp. * Converted from C++ to C. Added support for multi-byte chars. * Changed to keep spaces. */ i = reslen = z = 0; while ((c = word[i]) != NUL) { // Start with the first rule that has the character in the word. n = slang->sl_sal_first[c & 0xff]; z0 = 0; if (n >= 0) { // Check all rules for the same index byte. // If c is 0x300 need extra check for the end of the array, as // (c & 0xff) is NUL. for (; ((ws = smp[n].sm_lead_w)[0] & 0xff) == (c & 0xff) && ws[0] != NUL; ++n) { // Quickly skip entries that don't match the word. Most // entries are less than three chars, optimize for that. if (c != ws[0]) continue; k = smp[n].sm_leadlen; if (k > 1) { if (word[i + 1] != ws[1]) continue; if (k > 2) { for (j = 2; j < k; ++j) if (word[i + j] != ws[j]) break; if (j < k) continue; } } if ((pf = smp[n].sm_oneof_w) != NULL) { // Check for match with one of the chars in "sm_oneof". while (*pf != NUL && *pf != word[i + k]) ++pf; if (*pf == NUL) continue; ++k; } s = smp[n].sm_rules; pri = 5; // default priority p0 = *s; k0 = k; while (*s == '-' && k > 1) { k--; s++; } if (*s == '<') s++; if (VIM_ISDIGIT(*s)) { // determine priority pri = *s - '0'; s++; } if (*s == '^' && *(s + 1) == '^') s++; if (*s == NUL || (*s == '^' && (i == 0 || !(word[i - 1] == ' ' || spell_iswordp_w(word + i - 1, curwin))) && (*(s + 1) != '$' || (!spell_iswordp_w(word + i + k0, curwin)))) || (*s == '$' && i > 0 && spell_iswordp_w(word + i - 1, curwin) && (!spell_iswordp_w(word + i + k0, curwin)))) { // search for followup rules, if: // followup and k > 1 and NO '-' in searchstring c0 = word[i + k - 1]; n0 = slang->sl_sal_first[c0 & 0xff]; if (slang->sl_followup && k > 1 && n0 >= 0 && p0 != '-' && word[i + k] != NUL) { // Test follow-up rule for "word[i + k]"; loop over // all entries with the same index byte. for ( ; ((ws = smp[n0].sm_lead_w)[0] & 0xff) == (c0 & 0xff); ++n0) { // Quickly skip entries that don't match the word. if (c0 != ws[0]) continue; k0 = smp[n0].sm_leadlen; if (k0 > 1) { if (word[i + k] != ws[1]) continue; if (k0 > 2) { pf = word + i + k + 1; for (j = 2; j < k0; ++j) if (*pf++ != ws[j]) break; if (j < k0) continue; } } k0 += k - 1; if ((pf = smp[n0].sm_oneof_w) != NULL) { // Check for match with one of the chars in // "sm_oneof". while (*pf != NUL && *pf != word[i + k0]) ++pf; if (*pf == NUL) continue; ++k0; } p0 = 5; s = smp[n0].sm_rules; while (*s == '-') { // "k0" gets NOT reduced because // "if (k0 == k)" s++; } if (*s == '<') s++; if (VIM_ISDIGIT(*s)) { p0 = *s - '0'; s++; } if (*s == NUL // *s == '^' cuts || (*s == '$' && !spell_iswordp_w(word + i + k0, curwin))) { if (k0 == k) // this is just a piece of the string continue; if (p0 < pri) // priority too low continue; // rule fits; stop search break; } } if (p0 >= pri && (smp[n0].sm_lead_w[0] & 0xff) == (c0 & 0xff)) continue; } // replace string ws = smp[n].sm_to_w; s = smp[n].sm_rules; p0 = (vim_strchr(s, '<') != NULL) ? 1 : 0; if (p0 == 1 && z == 0) { // rule with '<' is used if (reslen > 0 && ws != NULL && *ws != NUL && (wres[reslen - 1] == c || wres[reslen - 1] == *ws)) reslen--; z0 = 1; z = 1; k0 = 0; if (ws != NULL) while (*ws != NUL && word[i + k0] != NUL) { word[i + k0] = *ws; k0++; ws++; } if (k > k0) mch_memmove(word + i + k0, word + i + k, sizeof(int) * (wordlen - (i + k) + 1)); // new "actual letter" c = word[i]; } else { // no '<' rule used i += k - 1; z = 0; if (ws != NULL) while (*ws != NUL && ws[1] != NUL && reslen < MAXWLEN) { if (reslen == 0 || wres[reslen - 1] != *ws) wres[reslen++] = *ws; ws++; } // new "actual letter" if (ws == NULL) c = NUL; else c = *ws; if (strstr((char *)s, "^^") != NULL) { if (c != NUL) wres[reslen++] = c; mch_memmove(word, word + i + 1, sizeof(int) * (wordlen - (i + 1) + 1)); i = 0; z0 = 1; } } break; } } } else if (VIM_ISWHITE(c)) { c = ' '; k = 1; } if (z0 == 0) { if (k && !p0 && reslen < MAXWLEN && c != NUL && (!slang->sl_collapse || reslen == 0 || wres[reslen - 1] != c)) // condense only double letters wres[reslen++] = c; i++; z = 0; k = 0; } } // Convert wide characters in "wres" to a multi-byte string in "res". l = 0; for (n = 0; n < reslen; ++n) { l += mb_char2bytes(wres[n], res + l); if (l + MB_MAXBYTES > MAXWLEN) break; } res[l] = NUL; } /* * ":spellinfo" */ void ex_spellinfo(exarg_T *eap UNUSED) { int lpi; langp_T *lp; char_u *p; if (no_spell_checking(curwin)) return; msg_start(); for (lpi = 0; lpi < curwin->w_s->b_langp.ga_len && !got_int; ++lpi) { lp = LANGP_ENTRY(curwin->w_s->b_langp, lpi); msg_puts("file: "); msg_puts((char *)lp->lp_slang->sl_fname); msg_putchar('\n'); p = lp->lp_slang->sl_info; if (p != NULL) { msg_puts((char *)p); msg_putchar('\n'); } } msg_end(); } #define DUMPFLAG_KEEPCASE 1 // round 2: keep-case tree #define DUMPFLAG_COUNT 2 // include word count #define DUMPFLAG_ICASE 4 // ignore case when finding matches #define DUMPFLAG_ONECAP 8 // pattern starts with capital #define DUMPFLAG_ALLCAP 16 // pattern is all capitals /* * ":spelldump" */ void ex_spelldump(exarg_T *eap) { char_u *spl; long dummy; if (no_spell_checking(curwin)) return; (void)get_option_value((char_u*)"spl", &dummy, &spl, NULL, OPT_LOCAL); // Create a new empty buffer in a new window. do_cmdline_cmd((char_u *)"new"); // enable spelling locally in the new window set_option_value_give_err((char_u*)"spell", TRUE, (char_u*)"", OPT_LOCAL); set_option_value_give_err((char_u*)"spl", dummy, spl, OPT_LOCAL); vim_free(spl); if (!BUFEMPTY()) return; spell_dump_compl(NULL, 0, NULL, eap->forceit ? DUMPFLAG_COUNT : 0); // Delete the empty line that we started with. if (curbuf->b_ml.ml_line_count > 1) ml_delete(curbuf->b_ml.ml_line_count); redraw_later(UPD_NOT_VALID); } /* * Go through all possible words and: * 1. When "pat" is NULL: dump a list of all words in the current buffer. * "ic" and "dir" are not used. * 2. When "pat" is not NULL: add matching words to insert mode completion. */ void spell_dump_compl( char_u *pat, // leading part of the word int ic, // ignore case int *dir, // direction for adding matches int dumpflags_arg) // DUMPFLAG_* { langp_T *lp; slang_T *slang; idx_T arridx[MAXWLEN]; int curi[MAXWLEN]; char_u word[MAXWLEN]; int c; char_u *byts; idx_T *idxs; linenr_T lnum = 0; int round; int depth; int n; int flags; char_u *region_names = NULL; // region names being used int do_region = TRUE; // dump region names and numbers char_u *p; int lpi; int dumpflags = dumpflags_arg; int patlen; // When ignoring case or when the pattern starts with capital pass this on // to dump_word(). if (pat != NULL) { if (ic) dumpflags |= DUMPFLAG_ICASE; else { n = captype(pat, NULL); if (n == WF_ONECAP) dumpflags |= DUMPFLAG_ONECAP; else if (n == WF_ALLCAP && (int)STRLEN(pat) > mb_ptr2len(pat)) dumpflags |= DUMPFLAG_ALLCAP; } } // Find out if we can support regions: All languages must support the same // regions or none at all. for (lpi = 0; lpi < curwin->w_s->b_langp.ga_len; ++lpi) { lp = LANGP_ENTRY(curwin->w_s->b_langp, lpi); p = lp->lp_slang->sl_regions; if (p[0] != 0) { if (region_names == NULL) // first language with regions region_names = p; else if (STRCMP(region_names, p) != 0) { do_region = FALSE; // region names are different break; } } } if (do_region && region_names != NULL && pat == NULL) { vim_snprintf((char *)IObuff, IOSIZE, "/regions=%s", region_names); ml_append(lnum++, IObuff, (colnr_T)0, FALSE); } else do_region = FALSE; /* * Loop over all files loaded for the entries in 'spelllang'. */ for (lpi = 0; lpi < curwin->w_s->b_langp.ga_len; ++lpi) { lp = LANGP_ENTRY(curwin->w_s->b_langp, lpi); slang = lp->lp_slang; if (slang->sl_fbyts == NULL) // reloading failed continue; if (pat == NULL) { vim_snprintf((char *)IObuff, IOSIZE, "# file: %s", slang->sl_fname); ml_append(lnum++, IObuff, (colnr_T)0, FALSE); } // When matching with a pattern and there are no prefixes only use // parts of the tree that match "pat". if (pat != NULL && slang->sl_pbyts == NULL) patlen = (int)STRLEN(pat); else patlen = -1; // round 1: case-folded tree // round 2: keep-case tree for (round = 1; round <= 2; ++round) { if (round == 1) { dumpflags &= ~DUMPFLAG_KEEPCASE; byts = slang->sl_fbyts; idxs = slang->sl_fidxs; } else { dumpflags |= DUMPFLAG_KEEPCASE; byts = slang->sl_kbyts; idxs = slang->sl_kidxs; } if (byts == NULL) continue; // array is empty depth = 0; arridx[0] = 0; curi[0] = 1; while (depth >= 0 && !got_int && (pat == NULL || !ins_compl_interrupted())) { if (curi[depth] > byts[arridx[depth]]) { // Done all bytes at this node, go up one level. --depth; line_breakcheck(); ins_compl_check_keys(50, FALSE); } else { // Do one more byte at this node. n = arridx[depth] + curi[depth]; ++curi[depth]; c = byts[n]; if (c == 0 || depth >= MAXWLEN - 1) { // End of word or reached maximum length, deal with the // word. // Don't use keep-case words in the fold-case tree, // they will appear in the keep-case tree. // Only use the word when the region matches. flags = (int)idxs[n]; if ((round == 2 || (flags & WF_KEEPCAP) == 0) && (flags & WF_NEEDCOMP) == 0 && (do_region || (flags & WF_REGION) == 0 || (((unsigned)flags >> 16) & lp->lp_region) != 0)) { word[depth] = NUL; if (!do_region) flags &= ~WF_REGION; // Dump the basic word if there is no prefix or // when it's the first one. c = (unsigned)flags >> 24; if (c == 0 || curi[depth] == 2) { dump_word(slang, word, pat, dir, dumpflags, flags, lnum); if (pat == NULL) ++lnum; } // Apply the prefix, if there is one. if (c != 0) lnum = dump_prefixes(slang, word, pat, dir, dumpflags, flags, lnum); } } else { // Normal char, go one level deeper. word[depth++] = c; arridx[depth] = idxs[n]; curi[depth] = 1; // Check if this character matches with the pattern. // If not skip the whole tree below it. // Always ignore case here, dump_word() will check // proper case later. This isn't exactly right when // length changes for multi-byte characters with // ignore case... if (depth <= patlen && MB_STRNICMP(word, pat, depth) != 0) --depth; } } } } } } /* * Dump one word: apply case modifications and append a line to the buffer. * When "lnum" is zero add insert mode completion. */ static void dump_word( slang_T *slang, char_u *word, char_u *pat, int *dir, int dumpflags, int wordflags, linenr_T lnum) { int keepcap = FALSE; char_u *p; char_u *tw; char_u cword[MAXWLEN]; char_u badword[MAXWLEN + 10]; int i; int flags = wordflags; if (dumpflags & DUMPFLAG_ONECAP) flags |= WF_ONECAP; if (dumpflags & DUMPFLAG_ALLCAP) flags |= WF_ALLCAP; if ((dumpflags & DUMPFLAG_KEEPCASE) == 0 && (flags & WF_CAPMASK) != 0) { // Need to fix case according to "flags". make_case_word(word, cword, flags); p = cword; } else { p = word; if ((dumpflags & DUMPFLAG_KEEPCASE) && ((captype(word, NULL) & WF_KEEPCAP) == 0 || (flags & WF_FIXCAP) != 0)) keepcap = TRUE; } tw = p; if (pat == NULL) { // Add flags and regions after a slash. if ((flags & (WF_BANNED | WF_RARE | WF_REGION)) || keepcap) { STRCPY(badword, p); STRCAT(badword, "/"); if (keepcap) STRCAT(badword, "="); if (flags & WF_BANNED) STRCAT(badword, "!"); else if (flags & WF_RARE) STRCAT(badword, "?"); if (flags & WF_REGION) for (i = 0; i < 7; ++i) if (flags & (0x10000 << i)) sprintf((char *)badword + STRLEN(badword), "%d", i + 1); p = badword; } if (dumpflags & DUMPFLAG_COUNT) { hashitem_T *hi; // Include the word count for ":spelldump!". hi = hash_find(&slang->sl_wordcount, tw); if (!HASHITEM_EMPTY(hi)) { vim_snprintf((char *)IObuff, IOSIZE, "%s\t%d", tw, HI2WC(hi)->wc_count); p = IObuff; } } ml_append(lnum, p, (colnr_T)0, FALSE); } else if (((dumpflags & DUMPFLAG_ICASE) ? MB_STRNICMP(p, pat, STRLEN(pat)) == 0 : STRNCMP(p, pat, STRLEN(pat)) == 0) && ins_compl_add_infercase(p, (int)STRLEN(p), p_ic, NULL, *dir, FALSE) == OK) // if dir was BACKWARD then honor it just once *dir = FORWARD; } /* * For ":spelldump": Find matching prefixes for "word". Prepend each to * "word" and append a line to the buffer. * When "lnum" is zero add insert mode completion. * Return the updated line number. */ static linenr_T dump_prefixes( slang_T *slang, char_u *word, // case-folded word char_u *pat, int *dir, int dumpflags, int flags, // flags with prefix ID linenr_T startlnum) { idx_T arridx[MAXWLEN]; int curi[MAXWLEN]; char_u prefix[MAXWLEN]; char_u word_up[MAXWLEN]; int has_word_up = FALSE; int c; char_u *byts; idx_T *idxs; linenr_T lnum = startlnum; int depth; int n; int len; int i; // If the word starts with a lower-case letter make the word with an // upper-case letter in word_up[]. c = PTR2CHAR(word); if (SPELL_TOUPPER(c) != c) { onecap_copy(word, word_up, TRUE); has_word_up = TRUE; } byts = slang->sl_pbyts; idxs = slang->sl_pidxs; if (byts != NULL) // array not is empty { /* * Loop over all prefixes, building them byte-by-byte in prefix[]. * When at the end of a prefix check that it supports "flags". */ depth = 0; arridx[0] = 0; curi[0] = 1; while (depth >= 0 && !got_int) { n = arridx[depth]; len = byts[n]; if (curi[depth] > len) { // Done all bytes at this node, go up one level. --depth; line_breakcheck(); } else { // Do one more byte at this node. n += curi[depth]; ++curi[depth]; c = byts[n]; if (c == 0) { // End of prefix, find out how many IDs there are. for (i = 1; i < len; ++i) if (byts[n + i] != 0) break; curi[depth] += i - 1; c = valid_word_prefix(i, n, flags, word, slang, FALSE); if (c != 0) { vim_strncpy(prefix + depth, word, MAXWLEN - depth - 1); dump_word(slang, prefix, pat, dir, dumpflags, (c & WF_RAREPFX) ? (flags | WF_RARE) : flags, lnum); if (lnum != 0) ++lnum; } // Check for prefix that matches the word when the // first letter is upper-case, but only if the prefix has // a condition. if (has_word_up) { c = valid_word_prefix(i, n, flags, word_up, slang, TRUE); if (c != 0) { vim_strncpy(prefix + depth, word_up, MAXWLEN - depth - 1); dump_word(slang, prefix, pat, dir, dumpflags, (c & WF_RAREPFX) ? (flags | WF_RARE) : flags, lnum); if (lnum != 0) ++lnum; } } } else { // Normal char, go one level deeper. prefix[depth++] = c; arridx[depth] = idxs[n]; curi[depth] = 1; } } } } return lnum; } /* * Move "p" to the end of word "start". * Uses the spell-checking word characters. */ char_u * spell_to_word_end(char_u *start, win_T *win) { char_u *p = start; while (*p != NUL && spell_iswordp(p, win)) MB_PTR_ADV(p); return p; } /* * For Insert mode completion CTRL-X s: * Find start of the word in front of column "startcol". * We don't check if it is badly spelled, with completion we can only change * the word in front of the cursor. * Returns the column number of the word. */ int spell_word_start(int startcol) { char_u *line; char_u *p; int col = 0; if (no_spell_checking(curwin)) return startcol; // Find a word character before "startcol". line = ml_get_curline(); for (p = line + startcol; p > line; ) { MB_PTR_BACK(line, p); if (spell_iswordp_nmw(p, curwin)) break; } // Go back to start of the word. while (p > line) { col = (int)(p - line); MB_PTR_BACK(line, p); if (!spell_iswordp(p, curwin)) break; col = 0; } return col; } /* * Need to check for 'spellcapcheck' now, the word is removed before * expand_spelling() is called. Therefore the ugly global variable. */ static int spell_expand_need_cap; void spell_expand_check_cap(colnr_T col) { spell_expand_need_cap = check_need_cap(curwin, curwin->w_cursor.lnum, col); } /* * Get list of spelling suggestions. * Used for Insert mode completion CTRL-X ?. * Returns the number of matches. The matches are in "matchp[]", array of * allocated strings. */ int expand_spelling( linenr_T lnum UNUSED, char_u *pat, char_u ***matchp) { garray_T ga; spell_suggest_list(&ga, pat, 100, spell_expand_need_cap, TRUE); *matchp = ga.ga_data; return ga.ga_len; } /* * Return TRUE if "val" is a valid 'spelllang' value. */ int valid_spelllang(char_u *val) { return valid_name(val, ".-_,@"); } /* * Return TRUE if "val" is a valid 'spellfile' value. */ int valid_spellfile(char_u *val) { char_u *s; for (s = val; *s != NUL; ++s) if (!vim_is_fname_char(*s)) return FALSE; return TRUE; } /* * Handle side effects of setting 'spell' or 'spellfile' * Return an error message or NULL for success. */ char * did_set_spell_option(int is_spellfile) { char *errmsg = NULL; win_T *wp; int l; if (is_spellfile) { l = (int)STRLEN(curwin->w_s->b_p_spf); if (l > 0 && (l < 4 || STRCMP(curwin->w_s->b_p_spf + l - 4, ".add") != 0)) errmsg = e_invalid_argument; } if (errmsg != NULL) return errmsg; FOR_ALL_WINDOWS(wp) if (wp->w_buffer == curbuf && wp->w_p_spell) { errmsg = parse_spelllang(wp); break; } return errmsg; } /* * Set curbuf->b_cap_prog to the regexp program for 'spellcapcheck'. * Return error message when failed, NULL when OK. */ char * compile_cap_prog(synblock_T *synblock) { regprog_T *rp = synblock->b_cap_prog; char_u *re; if (synblock->b_p_spc == NULL || *synblock->b_p_spc == NUL) synblock->b_cap_prog = NULL; else { // Prepend a ^ so that we only match at one column re = concat_str((char_u *)"^", synblock->b_p_spc); if (re != NULL) { synblock->b_cap_prog = vim_regcomp(re, RE_MAGIC); vim_free(re); if (synblock->b_cap_prog == NULL) { synblock->b_cap_prog = rp; // restore the previous program return e_invalid_argument; } } } vim_regfree(rp); return NULL; } #endif // FEAT_SPELL