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gerrit.omnirom.org / android_external_vim / refs/heads/android-16 / . / src / spell.c
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/* 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(&regmatch, 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
smt_T behaviour, // Behaviour of the function
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 (behaviour == SMT_ALL
|| (behaviour == SMT_BAD && attr == HLF_SPB)
|| (behaviour == SMT_RARE && attr == HLF_SPR))
{
// 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 - 4, ",");
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(&regmatch, 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;
size_t frompatlen;
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;
frompatlen = vim_snprintf((char *)frompat, repl_from_len + 7, "\\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, frompatlen, 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 && reslen < MAXWLEN)
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, 0) == 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 spf_name[MAXPATHL];
char_u *spf;
char_u *s;
int l;
spf = val;
while (*spf != NUL)
{
l = copy_option_part(&spf, spf_name, MAXPATHL, ",");
if (l >= MAXPATHL - 4 || l < 4
|| STRCMP(spf_name + l - 4, ".add") != 0)
return FALSE;
for (s = spf_name; *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(void)
{
char *errmsg = NULL;
win_T *wp;
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