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neovim/src/nvim/charset.c

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/// @file charset.c
///
/// Code related to character sets.
#include <string.h>
#include <wctype.h>
#include <wchar.h> // for towupper() and towlower()
#include "nvim/vim.h"
#include "nvim/charset.h"
#include "nvim/farsi.h"
#include "nvim/main.h"
#include "nvim/mbyte.h"
#include "nvim/memline.h"
#include "nvim/memory.h"
#include "nvim/misc1.h"
#include "nvim/misc2.h"
#include "nvim/garray.h"
#include "nvim/move.h"
#include "nvim/os_unix.h"
#include "nvim/strings.h"
#ifdef INCLUDE_GENERATED_DECLARATIONS
# include "charset.c.generated.h"
#endif
static int chartab_initialized = FALSE;
// b_chartab[] is an array of 32 bytes, each bit representing one of the
// characters 0-255.
#define SET_CHARTAB(buf, c) \
(buf)->b_chartab[(unsigned)(c) >> 3] |= (1 << ((c) & 0x7))
#define RESET_CHARTAB(buf, c) \
(buf)->b_chartab[(unsigned)(c) >> 3] &= ~(1 << ((c) & 0x7))
#define GET_CHARTAB(buf, c) \
((buf)->b_chartab[(unsigned)(c) >> 3] & (1 << ((c) & 0x7)))
/// Fill chartab[]. Also fills curbuf->b_chartab[] with flags for keyword
/// characters for current buffer.
///
/// Depends on the option settings 'iskeyword', 'isident', 'isfname',
/// 'isprint' and 'encoding'.
///
/// The index in chartab[] depends on 'encoding':
/// - For non-multi-byte index with the byte (same as the character).
/// - For DBCS index with the first byte.
/// - For UTF-8 index with the character (when first byte is up to 0x80 it is
/// the same as the character, if the first byte is 0x80 and above it depends
/// on further bytes).
///
/// The contents of chartab[]:
/// - The lower two bits, masked by CT_CELL_MASK, give the number of display
/// cells the character occupies (1 or 2). Not valid for UTF-8 above 0x80.
/// - CT_PRINT_CHAR bit is set when the character is printable (no need to
/// translate the character before displaying it). Note that only DBCS
/// characters can have 2 display cells and still be printable.
/// - CT_FNAME_CHAR bit is set when the character can be in a file name.
/// - CT_ID_CHAR bit is set when the character can be in an identifier.
///
/// @return FAIL if 'iskeyword', 'isident', 'isfname' or 'isprint' option has
/// an error, OK otherwise.
int init_chartab(void)
{
return buf_init_chartab(curbuf, TRUE);
}
/// Helper for init_chartab
///
/// @param global FALSE: only set buf->b_chartab[]
///
/// @return FAIL if 'iskeyword', 'isident', 'isfname' or 'isprint' option has
/// an error, OK otherwise.
int buf_init_chartab(buf_T *buf, int global)
{
int c;
int c2;
char_u *p;
int i;
int tilde;
int do_isalpha;
if (global) {
// Set the default size for printable characters:
// From <Space> to '~' is 1 (printable), others are 2 (not printable).
// This also inits all 'isident' and 'isfname' flags to FALSE.
//
// EBCDIC: all chars below ' ' are not printable, all others are
// printable.
c = 0;
while (c < ' ') {
chartab[c++] = (dy_flags & DY_UHEX) ? 4 : 2;
}
while (c <= '~') {
chartab[c++] = 1 + CT_PRINT_CHAR;
}
if (p_altkeymap) {
while (c < YE) {
chartab[c++] = 1 + CT_PRINT_CHAR;
}
}
while (c < 256) {
if (enc_utf8 && (c >= 0xa0)) {
// UTF-8: bytes 0xa0 - 0xff are printable (latin1)
chartab[c++] = CT_PRINT_CHAR + 1;
} else if ((enc_dbcs == DBCS_JPNU) && (c == 0x8e)) {
// euc-jp characters starting with 0x8e are single width
chartab[c++] = CT_PRINT_CHAR + 1;
} else if ((enc_dbcs != 0) && (MB_BYTE2LEN(c) == 2)) {
// other double-byte chars can be printable AND double-width
chartab[c++] = CT_PRINT_CHAR + 2;
} else {
// the rest is unprintable by default
chartab[c++] = (dy_flags & DY_UHEX) ? 4 : 2;
}
}
// Assume that every multi-byte char is a filename character.
for (c = 1; c < 256; ++c) {
if (((enc_dbcs != 0) && (MB_BYTE2LEN(c) > 1))
|| ((enc_dbcs == DBCS_JPNU) && (c == 0x8e))
|| (enc_utf8 && (c >= 0xa0))) {
chartab[c] |= CT_FNAME_CHAR;
}
}
}
// Init word char flags all to FALSE
memset(buf->b_chartab, 0, (size_t)32);
if (enc_dbcs != 0) {
for (c = 0; c < 256; ++c) {
// double-byte characters are probably word characters
if (MB_BYTE2LEN(c) == 2) {
SET_CHARTAB(buf, c);
}
}
}
// In lisp mode the '-' character is included in keywords.
if (buf->b_p_lisp) {
SET_CHARTAB(buf, '-');
}
// Walk through the 'isident', 'iskeyword', 'isfname' and 'isprint'
// options Each option is a list of characters, character numbers or
// ranges, separated by commas, e.g.: "200-210,x,#-178,-"
for (i = global ? 0 : 3; i <= 3; ++i) {
if (i == 0) {
// first round: 'isident'
p = p_isi;
} else if (i == 1) {
// second round: 'isprint'
p = p_isp;
} else if (i == 2) {
// third round: 'isfname'
p = p_isf;
} else { // i == 3
// fourth round: 'iskeyword'
p = buf->b_p_isk;
}
while (*p) {
tilde = FALSE;
do_isalpha = FALSE;
if ((*p == '^') && (p[1] != NUL)) {
tilde = TRUE;
++p;
}
if (VIM_ISDIGIT(*p)) {
c = getdigits(&p);
} else if (has_mbyte) {
c = mb_ptr2char_adv(&p);
} else {
c = *p++;
}
c2 = -1;
if ((*p == '-') && (p[1] != NUL)) {
++p;
if (VIM_ISDIGIT(*p)) {
c2 = getdigits(&p);
} else if (has_mbyte) {
c2 = mb_ptr2char_adv(&p);
} else {
c2 = *p++;
}
}
if ((c <= 0)
|| (c >= 256)
|| ((c2 < c) && (c2 != -1))
|| (c2 >= 256)
|| !((*p == NUL) || (*p == ','))) {
return FAIL;
}
if (c2 == -1) { // not a range
// A single '@' (not "@-@"):
// Decide on letters being ID/printable/keyword chars with
// standard function isalpha(). This takes care of locale for
// single-byte characters).
if (c == '@') {
do_isalpha = TRUE;
c = 1;
c2 = 255;
} else {
c2 = c;
}
}
while (c <= c2) {
// Use the MB_ functions here, because isalpha() doesn't
// work properly when 'encoding' is "latin1" and the locale is
// "C".
if (!do_isalpha
|| vim_islower(c)
|| vim_isupper(c)
|| (p_altkeymap && (F_isalpha(c) || F_isdigit(c)))) {
if (i == 0) {
// (re)set ID flag
if (tilde) {
chartab[c] &= ~CT_ID_CHAR;
} else {
chartab[c] |= CT_ID_CHAR;
}
} else if (i == 1) {
// (re)set printable
// For double-byte we keep the cell width, so
// that we can detect it from the first byte.
if (((c < ' ')
|| (c > '~')
|| (p_altkeymap && (F_isalpha(c) || F_isdigit(c))))
&& !(enc_dbcs && (MB_BYTE2LEN(c) == 2))) {
if (tilde) {
chartab[c] = (chartab[c] & ~CT_CELL_MASK)
+ ((dy_flags & DY_UHEX) ? 4 : 2);
chartab[c] &= ~CT_PRINT_CHAR;
} else {
chartab[c] = (chartab[c] & ~CT_CELL_MASK) + 1;
chartab[c] |= CT_PRINT_CHAR;
}
}
} else if (i == 2) {
// (re)set fname flag
if (tilde) {
chartab[c] &= ~CT_FNAME_CHAR;
} else {
chartab[c] |= CT_FNAME_CHAR;
}
} else { // i == 3
// (re)set keyword flag
if (tilde) {
RESET_CHARTAB(buf, c);
} else {
SET_CHARTAB(buf, c);
}
}
}
++c;
}
c = *p;
p = skip_to_option_part(p);
if ((c == ',') && (*p == NUL)) {
// Trailing comma is not allowed.
return FAIL;
}
}
}
chartab_initialized = TRUE;
return OK;
}
/// Translate any special characters in buf[bufsize] in-place.
///
/// The result is a string with only printable characters, but if there is not
/// enough room, not all characters will be translated.
///
/// @param buf
/// @param bufsize
void trans_characters(char_u *buf, int bufsize)
{
int len; // length of string needing translation
int room; // room in buffer after string
char_u *trs; // translated character
int trs_len; // length of trs[]
len = (int)STRLEN(buf);
room = bufsize - len;
while (*buf != 0) {
// Assume a multi-byte character doesn't need translation.
if (has_mbyte && ((trs_len = (*mb_ptr2len)(buf)) > 1)) {
len -= trs_len;
} else {
trs = transchar_byte(*buf);
trs_len = (int)STRLEN(trs);
if (trs_len > 1) {
room -= trs_len - 1;
if (room <= 0) {
return;
}
memmove(buf + trs_len, buf + 1, (size_t)len);
}
memmove(buf, trs, (size_t)trs_len);
--len;
}
buf += trs_len;
}
}
/// Translate a string into allocated memory, replacing special chars with
/// printable chars. Returns NULL when out of memory.
///
/// @param s
///
/// @return translated string
char_u *transstr(char_u *s)
{
char_u *res;
char_u *p;
int l, c;
char_u hexbuf[11];
if (has_mbyte) {
// Compute the length of the result, taking account of unprintable
// multi-byte characters.
size_t len = 0;
p = s;
while (*p != NUL) {
if ((l = (*mb_ptr2len)(p)) > 1) {
c = (*mb_ptr2char)(p);
p += l;
if (vim_isprintc(c)) {
len += l;
} else {
transchar_hex(hexbuf, c);
len += STRLEN(hexbuf);
}
} else {
l = byte2cells(*p++);
if (l > 0) {
len += l;
} else {
// illegal byte sequence
len += 4;
}
}
}
res = xmallocz(len);
} else {
res = xmallocz(vim_strsize(s));
}
*res = NUL;
p = s;
while (*p != NUL) {
if (has_mbyte && ((l = (*mb_ptr2len)(p)) > 1)) {
c = (*mb_ptr2char)(p);
if (vim_isprintc(c)) {
// append printable multi-byte char
STRNCAT(res, p, l);
} else {
transchar_hex(res + STRLEN(res), c);
}
p += l;
} else {
STRCAT(res, transchar_byte(*p++));
}
}
return res;
}
/// Convert the string "str[orglen]" to do ignore-case comparing. Uses the
/// current locale.
///
/// When "buf" is NULL returns an allocated string (NULL for out-of-memory).
/// Otherwise puts the result in "buf[buflen]".
///
/// @param str
/// @param orglen
/// @param buf
/// @param buflen
///
/// @return converted string.
char_u* str_foldcase(char_u *str, int orglen, char_u *buf, int buflen)
{
garray_T ga;
int i;
int len = orglen;
#define GA_CHAR(i) ((char_u *)ga.ga_data)[i]
#define GA_PTR(i) ((char_u *)ga.ga_data + i)
#define STR_CHAR(i) (buf == NULL ? GA_CHAR(i) : buf[i])
#define STR_PTR(i) (buf == NULL ? GA_PTR(i) : buf + i)
// Copy "str" into "buf" or allocated memory, unmodified.
if (buf == NULL) {
ga_init(&ga, 1, 10);
ga_grow(&ga, len + 1);
memmove(ga.ga_data, str, (size_t)len);
ga.ga_len = len;
} else {
if (len >= buflen) {
// Ugly!
len = buflen - 1;
}
memmove(buf, str, (size_t)len);
}
if (buf == NULL) {
GA_CHAR(len) = NUL;
} else {
buf[len] = NUL;
}
// Make each character lower case.
i = 0;
while (STR_CHAR(i) != NUL) {
if (enc_utf8 || (has_mbyte && (MB_BYTE2LEN(STR_CHAR(i)) > 1))) {
if (enc_utf8) {
int c = utf_ptr2char(STR_PTR(i));
int olen = utf_ptr2len(STR_PTR(i));
int lc = utf_tolower(c);
// Only replace the character when it is not an invalid
// sequence (ASCII character or more than one byte) and
// utf_tolower() doesn't return the original character.
if (((c < 0x80) || (olen > 1)) && (c != lc)) {
int nlen = utf_char2len(lc);
// If the byte length changes need to shift the following
// characters forward or backward.
if (olen != nlen) {
if (nlen > olen) {
if (buf == NULL) {
ga_grow(&ga, nlen - olen + 1);
} else {
if (len + nlen - olen >= buflen) {
// out of memory, keep old char
lc = c;
nlen = olen;
}
}
}
if (olen != nlen) {
if (buf == NULL) {
STRMOVE(GA_PTR(i) + nlen, GA_PTR(i) + olen);
ga.ga_len += nlen - olen;
} else {
STRMOVE(buf + i + nlen, buf + i + olen);
len += nlen - olen;
}
}
}
(void)utf_char2bytes(lc, STR_PTR(i));
}
}
// skip to next multi-byte char
i += (*mb_ptr2len)(STR_PTR(i));
} else {
if (buf == NULL) {
GA_CHAR(i) = TOLOWER_LOC(GA_CHAR(i));
} else {
buf[i] = TOLOWER_LOC(buf[i]);
}
++i;
}
}
if (buf == NULL) {
return (char_u *)ga.ga_data;
}
return buf;
}
// Catch 22: chartab[] can't be initialized before the options are
// initialized, and initializing options may cause transchar() to be called!
// When chartab_initialized == FALSE don't use chartab[].
// Does NOT work for multi-byte characters, c must be <= 255.
// Also doesn't work for the first byte of a multi-byte, "c" must be a
// character!
static char_u transchar_buf[7];
/// Translates a character
///
/// @param c
///
/// @return translated character.
char_u* transchar(int c)
{
int i = 0;
if (IS_SPECIAL(c)) {
// special key code, display as ~@ char
transchar_buf[0] = '~';
transchar_buf[1] = '@';
i = 2;
c = K_SECOND(c);
}
if ((!chartab_initialized && (((c >= ' ') && (c <= '~')) || F_ischar(c)))
|| ((c < 256) && vim_isprintc_strict(c))) {
// printable character
transchar_buf[i] = c;
transchar_buf[i + 1] = NUL;
} else {
transchar_nonprint(transchar_buf + i, c);
}
return transchar_buf;
}
/// Like transchar(), but called with a byte instead of a character. Checks
/// for an illegal UTF-8 byte.
///
/// @param c
///
/// @return pointer to translated character in transchar_buf.
char_u* transchar_byte(int c)
{
if (enc_utf8 && (c >= 0x80)) {
transchar_nonprint(transchar_buf, c);
return transchar_buf;
}
return transchar(c);
}
/// Convert non-printable character to two or more printable characters in
/// "buf[]". "buf" needs to be able to hold five bytes.
/// Does NOT work for multi-byte characters, c must be <= 255.
///
/// @param buf
/// @param c
void transchar_nonprint(char_u *buf, int c)
{
if (c == NL) {
// we use newline in place of a NUL
c = NUL;
} else if ((c == CAR) && (get_fileformat(curbuf) == EOL_MAC)) {
// we use CR in place of NL in this case
c = NL;
}
if (dy_flags & DY_UHEX) {
// 'display' has "uhex"
transchar_hex(buf, c);
} else if (c <= 0x7f) {
// 0x00 - 0x1f and 0x7f
buf[0] = '^';
// DEL displayed as ^?
buf[1] = c ^ 0x40;
buf[2] = NUL;
} else if (enc_utf8 && (c >= 0x80)) {
transchar_hex(buf, c);
} else if ((c >= ' ' + 0x80) && (c <= '~' + 0x80)) {
// 0xa0 - 0xfe
buf[0] = '|';
buf[1] = c - 0x80;
buf[2] = NUL;
} else {
// 0x80 - 0x9f and 0xff
// TODO: EBCDIC I don't know what to do with this chars, so I display
// them as '~?' for now
buf[0] = '~';
buf[1] = (c - 0x80) ^ 0x40;
// 0xff displayed as ~?
buf[2] = NUL;
}
}
/// Convert a non-printable character to hex.
///
/// @param buf
/// @param c
void transchar_hex(char_u *buf, int c)
{
int i = 0;
buf[0] = '<';
if (c > 255) {
buf[++i] = nr2hex((unsigned)c >> 12);
buf[++i] = nr2hex((unsigned)c >> 8);
}
buf[++i] = nr2hex((unsigned)c >> 4);
buf[++i] = nr2hex((unsigned)c);
buf[++i] = '>';
buf[++i] = NUL;
}
/// Convert the lower 4 bits of byte "c" to its hex character.
/// Lower case letters are used to avoid the confusion of <F1> being 0xf1 or
/// function key 1.
///
/// @param c
///
/// @return the hex character.
static unsigned nr2hex(unsigned c)
{
if ((c & 0xf) <= 9) {
return (c & 0xf) + '0';
}
return (c & 0xf) - 10 + 'a';
}
/// Return number of display cells occupied by byte "b".
///
/// Caller must make sure 0 <= b <= 255.
/// For multi-byte mode "b" must be the first byte of a character.
/// A TAB is counted as two cells: "^I".
/// For UTF-8 mode this will return 0 for bytes >= 0x80, because the number of
/// cells depends on further bytes.
///
/// @param b
///
/// @reeturn Number of display cells.
int byte2cells(int b)
{
if (enc_utf8 && (b >= 0x80)) {
return 0;
}
return chartab[b] & CT_CELL_MASK;
}
/// Return number of display cells occupied by character "c".
///
/// "c" can be a special key (negative number) in which case 3 or 4 is returned.
/// A TAB is counted as two cells: "^I" or four: "<09>".
///
/// @param c
///
/// @return Number of display cells.
int char2cells(int c)
{
if (IS_SPECIAL(c)) {
return char2cells(K_SECOND(c)) + 2;
}
if (c >= 0x80) {
// UTF-8: above 0x80 need to check the value
if (enc_utf8) {
return utf_char2cells(c);
}
// DBCS: double-byte means double-width, except for euc-jp with first
// byte 0x8e
if ((enc_dbcs != 0) && (c >= 0x100)) {
if ((enc_dbcs == DBCS_JPNU) && (((unsigned)c >> 8) == 0x8e)) {
return 1;
}
return 2;
}
}
return chartab[c & 0xff] & CT_CELL_MASK;
}
/// Return number of display cells occupied by character at "*p".
/// A TAB is counted as two cells: "^I" or four: "<09>".
///
/// @param p
///
/// @return number of display cells.
int ptr2cells(char_u *p)
{
// For UTF-8 we need to look at more bytes if the first byte is >= 0x80.
if (enc_utf8 && (*p >= 0x80)) {
return utf_ptr2cells(p);
}
// For DBCS we can tell the cell count from the first byte.
return chartab[*p] & CT_CELL_MASK;
}
/// Return the number of character cells string "s" will take on the screen,
/// counting TABs as two characters: "^I".
///
/// 's' must be non-null.
///
/// @param s
///
/// @return number of character cells.
int vim_strsize(char_u *s)
{
return vim_strnsize(s, (int)MAXCOL);
}
/// Return the number of character cells string "s[len]" will take on the
/// screen, counting TABs as two characters: "^I".
///
/// 's' must be non-null.
///
/// @param s
/// @param len
///
/// @return Number of character cells.
int vim_strnsize(char_u *s, int len)
{
assert(s != NULL);
int size = 0;
while (*s != NUL && --len >= 0) {
if (has_mbyte) {
int l = (*mb_ptr2len)(s);
size += ptr2cells(s);
s += l;
len -= l - 1;
} else {
size += byte2cells(*s++);
}
}
return size;
}
/// Return the number of characters 'c' will take on the screen, taking
/// into account the size of a tab.
/// Use a define to make it fast, this is used very often!!!
/// Also see getvcol() below.
///
/// @param p
/// @param col
///
/// @return Number of characters.
#define RET_WIN_BUF_CHARTABSIZE(wp, buf, p, col) \
if (*(p) == TAB && (!(wp)->w_p_list || lcs_tab1)) { \
int ts; \
ts = (buf)->b_p_ts; \
return (int)(ts - (col % ts)); \
} else { \
return ptr2cells(p); \
}
int chartabsize(char_u *p, colnr_T col)
{
RET_WIN_BUF_CHARTABSIZE(curwin, curbuf, p, col)
}
static int win_chartabsize(win_T *wp, char_u *p, colnr_T col)
{
RET_WIN_BUF_CHARTABSIZE(wp, wp->w_buffer, p, col)
}
/// Return the number of characters the string 's' will take on the screen,
/// taking into account the size of a tab.
///
/// @param s
///
/// @return Number of characters the string will take on the screen.
int linetabsize(char_u *s)
{
return linetabsize_col(0, s);
}
/// Like linetabsize(), but starting at column "startcol".
///
/// @param startcol
/// @param s
///
/// @return Number of characters the string will take on the screen.
int linetabsize_col(int startcol, char_u *s)
{
colnr_T col = startcol;
while (*s != NUL) {
col += lbr_chartabsize_adv(&s, col);
}
return (int)col;
}
/// Like linetabsize(), but for a given window instead of the current one.
///
/// @param wp
/// @param p
/// @param len
///
/// @return Number of characters the string will take on the screen.
int win_linetabsize(win_T *wp, char_u *p, colnr_T len)
{
colnr_T col = 0;
char_u *s;
for (s = p; *s != NUL && (len == MAXCOL || s < p + len); mb_ptr_adv(s)) {
col += win_lbr_chartabsize(wp, s, col, NULL);
}
return (int)col;
}
/// Return TRUE if 'c' is a normal identifier character:
///
/// Letters and characters from the 'isident' option.
///
/// @param c
///
/// @return TRUE if 'c' is a normal identifier character.
int vim_isIDc(int c)
{
return c > 0 && c < 0x100 && (chartab[c] & CT_ID_CHAR);
}
/// return TRUE if 'c' is a keyword character: Letters and characters from
/// 'iskeyword' option for current buffer.
///
/// For multi-byte characters mb_get_class() is used (builtin rules).
///
/// @param c
///
/// @return TRUE if 'c' is a keyword character.
int vim_iswordc(int c)
{
return vim_iswordc_buf(c, curbuf);
}
int vim_iswordc_buf(int c, buf_T *buf)
{
if (c >= 0x100) {
if (enc_dbcs != 0) {
return dbcs_class((unsigned)c >> 8, (unsigned)(c & 0xff)) >= 2;
}
if (enc_utf8) {
return utf_class(c) >= 2;
}
}
return c > 0 && c < 0x100 && GET_CHARTAB(buf, c) != 0;
}
/// Just like vim_iswordc() but uses a pointer to the (multi-byte) character.
///
/// @param p
///
/// @return TRUE if 'p' points to a keyword character.
int vim_iswordp(char_u *p)
{
if (has_mbyte && (MB_BYTE2LEN(*p) > 1)) {
return mb_get_class(p) >= 2;
}
return GET_CHARTAB(curbuf, *p) != 0;
}
int vim_iswordp_buf(char_u *p, buf_T *buf)
{
if (has_mbyte && (MB_BYTE2LEN(*p) > 1)) {
return mb_get_class(p) >= 2;
}
return GET_CHARTAB(buf, *p) != 0;
}
/// return TRUE if 'c' is a valid file-name character
/// Assume characters above 0x100 are valid (multi-byte).
///
/// @param c
///
/// @return TRUE if 'c' is a valid file name character.
int vim_isfilec(int c)
{
return c >= 0x100 || (c > 0 && (chartab[c] & CT_FNAME_CHAR));
}
/// return TRUE if 'c' is a valid file-name character or a wildcard character
/// Assume characters above 0x100 are valid (multi-byte).
/// Explicitly interpret ']' as a wildcard character as mch_has_wildcard("]")
/// returns false.
///
/// @param c
///
/// @return TRUE if 'c' is a valid file-name character or wildcard character.
int vim_isfilec_or_wc(int c)
{
char_u buf[2];
buf[0] = (char_u)c;
buf[1] = NUL;
return vim_isfilec(c) || c == ']' || mch_has_wildcard(buf);
}
/// return TRUE if 'c' is a printable character
/// Assume characters above 0x100 are printable (multi-byte), except for
/// Unicode.
///
/// @param c
///
/// @return TRUE if 'c' a printable character.
int vim_isprintc(int c)
{
if (enc_utf8 && (c >= 0x100)) {
return utf_printable(c);
}
return c >= 0x100 || (c > 0 && (chartab[c] & CT_PRINT_CHAR));
}
/// Strict version of vim_isprintc(c), don't return TRUE if "c" is the head
/// byte of a double-byte character.
///
/// @param c
///
/// @return TRUE if 'c' is a printable character.
int vim_isprintc_strict(int c)
{
if ((enc_dbcs != 0) && (c < 0x100) && (MB_BYTE2LEN(c) > 1)) {
return FALSE;
}
if (enc_utf8 && (c >= 0x100)) {
return utf_printable(c);
}
return c >= 0x100 || (c > 0 && (chartab[c] & CT_PRINT_CHAR));
}
/// like chartabsize(), but also check for line breaks on the screen
///
/// @param s
/// @param col
///
/// @return The number of characters taken up on the screen.
int lbr_chartabsize(unsigned char *s, colnr_T col)
{
if (!curwin->w_p_lbr && (*p_sbr == NUL)) {
if (curwin->w_p_wrap) {
return win_nolbr_chartabsize(curwin, s, col, NULL);
}
RET_WIN_BUF_CHARTABSIZE(curwin, curbuf, s, col)
}
return win_lbr_chartabsize(curwin, s, col, NULL);
}
/// Call lbr_chartabsize() and advance the pointer.
///
/// @param s
/// @param col
///
/// @return The number of characters take up on the screen.
int lbr_chartabsize_adv(char_u **s, colnr_T col)
{
int retval;
retval = lbr_chartabsize(*s, col);
mb_ptr_adv(*s);
return retval;
}
/// This function is used very often, keep it fast!!!!
///
/// If "headp" not NULL, set *headp to the size of what we for 'showbreak'
/// string at start of line. Warning: *headp is only set if it's a non-zero
/// value, init to 0 before calling.
///
/// @param wp
/// @param s
/// @param col
/// @param headp
///
/// @return The number of characters taken up on the screen.
int win_lbr_chartabsize(win_T *wp, char_u *s, colnr_T col, int *headp)
{
colnr_T col2;
colnr_T colmax;
int added;
int mb_added = 0;
int numberextra;
char_u *ps;
int tab_corr = (*s == TAB);
int n;
// No 'linebreak' and 'showbreak': return quickly.
if (!wp->w_p_lbr && (*p_sbr == NUL)) {
if (wp->w_p_wrap) {
return win_nolbr_chartabsize(wp, s, col, headp);
}
RET_WIN_BUF_CHARTABSIZE(wp, wp->w_buffer, s, col)
}
// First get normal size, without 'linebreak'
int size = win_chartabsize(wp, s, col);
int c = *s;
// If 'linebreak' set check at a blank before a non-blank if the line
// needs a break here
if (wp->w_p_lbr
&& vim_isbreak(c)
&& !vim_isbreak(s[1])
&& !wp->w_p_list
&& wp->w_p_wrap
&& (wp->w_width != 0)) {
// Count all characters from first non-blank after a blank up to next
// non-blank after a blank.
numberextra = win_col_off(wp);
col2 = col;
colmax = (colnr_T)(wp->w_width - numberextra);
if (col >= colmax) {
n = colmax + win_col_off2(wp);
if (n > 0) {
colmax += (((col - colmax) / n) + 1) * n;
}
}
for (;;) {
ps = s;
mb_ptr_adv(s);
c = *s;
if (!((c != NUL)
&& (vim_isbreak(c)
|| (!vim_isbreak(c)
&& ((col2 == col) || !vim_isbreak(*ps)))))) {
break;
}
col2 += win_chartabsize(wp, s, col2);
if (col2 >= colmax) { /* doesn't fit */
size = colmax - col;
tab_corr = FALSE;
break;
}
}
} else if (has_mbyte
&& (size == 2)
&& (MB_BYTE2LEN(*s) > 1)
&& wp->w_p_wrap
&& in_win_border(wp, col)) {
// Count the ">" in the last column.
++size;
mb_added = 1;
}
// May have to add something for 'showbreak' string at start of line
// Set *headp to the size of what we add.
added = 0;
if ((*p_sbr != NUL) && wp->w_p_wrap && (col != 0)) {
numberextra = win_col_off(wp);
col += numberextra + mb_added;
if (col >= (colnr_T)wp->w_width) {
col -= wp->w_width;
numberextra = wp->w_width - (numberextra - win_col_off2(wp));
if (numberextra > 0) {
col = col % numberextra;
}
}
if ((col == 0) || (col + size > (colnr_T)wp->w_width)) {
added = vim_strsize(p_sbr);
if (tab_corr) {
size += (added / wp->w_buffer->b_p_ts) * wp->w_buffer->b_p_ts;
} else {
size += added;
}
if (col != 0) {
added = 0;
}
}
}
if (headp != NULL) {
*headp = added + mb_added;
}
return size;
}
/// Like win_lbr_chartabsize(), except that we know 'linebreak' is off and
/// 'wrap' is on. This means we need to check for a double-byte character that
/// doesn't fit at the end of the screen line.
///
/// @param wp
/// @param s
/// @param col
/// @param headp
///
/// @return The number of characters take up on the screen.
static int win_nolbr_chartabsize(win_T *wp, char_u *s, colnr_T col, int *headp)
{
int n;
if ((*s == TAB) && (!wp->w_p_list || lcs_tab1)) {
n = wp->w_buffer->b_p_ts;
return (int)(n - (col % n));
}
n = ptr2cells(s);
// Add one cell for a double-width character in the last column of the
// window, displayed with a ">".
if ((n == 2) && (MB_BYTE2LEN(*s) > 1) && in_win_border(wp, col)) {
if (headp != NULL) {
*headp = 1;
}
return 3;
}
return n;
}
/// Return TRUE if virtual column "vcol" is in the rightmost column of window
/// "wp".
///
/// @param wp
/// @param vcol
///
/// @return TRUE if the virtual column is in the rightmost column.
int in_win_border(win_T *wp, colnr_T vcol)
{
int width1; // width of first line (after line number)
int width2; // width of further lines
if (wp->w_width == 0) {
// there is no border
return FALSE;
}
width1 = wp->w_width - win_col_off(wp);
if ((int)vcol < width1 - 1) {
return FALSE;
}
if ((int)vcol == width1 - 1) {
return TRUE;
}
width2 = width1 + win_col_off2(wp);
if (width2 <= 0) {
return FALSE;
}
return (vcol - width1) % width2 == width2 - 1;
}
/// Get virtual column number of pos.
/// start: on the first position of this character (TAB, ctrl)
/// cursor: where the cursor is on this character (first char, except for TAB)
/// end: on the last position of this character (TAB, ctrl)
///
/// This is used very often, keep it fast!
///
/// @param wp
/// @param pos
/// @param start
/// @param cursor
/// @param end
void getvcol(win_T *wp, pos_T *pos, colnr_T *start, colnr_T *cursor,
colnr_T *end)
{
colnr_T vcol;
char_u *ptr; // points to current char
char_u *posptr; // points to char at pos->col
int incr;
int head;
int ts = wp->w_buffer->b_p_ts;
int c;
vcol = 0;
ptr = ml_get_buf(wp->w_buffer, pos->lnum, FALSE);
if (pos->col == MAXCOL) {
// continue until the NUL
posptr = NULL;
} else {
posptr = ptr + pos->col;
}
// This function is used very often, do some speed optimizations.
// When 'list', 'linebreak' and 'showbreak' are not set use a simple loop.
// Also use this when 'list' is set but tabs take their normal size.
if ((!wp->w_p_list || (lcs_tab1 != NUL))
&& !wp->w_p_lbr
&& (*p_sbr == NUL)) {
for (;;) {
head = 0;
c = *ptr;
// make sure we don't go past the end of the line
if (c == NUL) {
// NUL at end of line only takes one column
incr = 1;
break;
}
// A tab gets expanded, depending on the current column
if (c == TAB) {
incr = ts - (vcol % ts);
} else {
if (has_mbyte) {
// For utf-8, if the byte is >= 0x80, need to look at
// further bytes to find the cell width.
if (enc_utf8 && (c >= 0x80)) {
incr = utf_ptr2cells(ptr);
} else {
incr = CHARSIZE(c);
}
// If a double-cell char doesn't fit at the end of a line
// it wraps to the next line, it's like this char is three
// cells wide.
if ((incr == 2)
&& wp->w_p_wrap
&& (MB_BYTE2LEN(*ptr) > 1)
&& in_win_border(wp, vcol)) {
++incr;
head = 1;
}
} else {
incr = CHARSIZE(c);
}
}
if ((posptr != NULL) && (ptr >= posptr)) {
// character at pos->col
break;
}
vcol += incr;
mb_ptr_adv(ptr);
}
} else {
for (;;) {
// A tab gets expanded, depending on the current column
head = 0;
incr = win_lbr_chartabsize(wp, ptr, vcol, &head);
// make sure we don't go past the end of the line
if (*ptr == NUL) {
// NUL at end of line only takes one column
incr = 1;
break;
}
if ((posptr != NULL) && (ptr >= posptr)) {
// character at pos->col
break;
}
vcol += incr;
mb_ptr_adv(ptr);
}
}
if (start != NULL) {
*start = vcol + head;
}
if (end != NULL) {
*end = vcol + incr - 1;
}
if (cursor != NULL) {
if ((*ptr == TAB)
&& (State & NORMAL)
&& !wp->w_p_list
&& !virtual_active()
&& !(VIsual_active && ((*p_sel == 'e') || ltoreq(*pos, VIsual)))) {
// cursor at end
*cursor = vcol + incr - 1;
} else {
// cursor at start
*cursor = vcol + head;
}
}
}
/// Get virtual cursor column in the current window, pretending 'list' is off.
///
/// @param posp
///
/// @retujrn The virtual cursor column.
colnr_T getvcol_nolist(pos_T *posp)
{
int list_save = curwin->w_p_list;
colnr_T vcol;
curwin->w_p_list = FALSE;
getvcol(curwin, posp, NULL, &vcol, NULL);
curwin->w_p_list = list_save;
return vcol;
}
/// Get virtual column in virtual mode.
///
/// @param wp
/// @param pos
/// @param start
/// @param cursor
/// @param end
void getvvcol(win_T *wp, pos_T *pos, colnr_T *start, colnr_T *cursor,
colnr_T *end)
{
colnr_T col;
colnr_T coladd;
colnr_T endadd;
char_u *ptr;
if (virtual_active()) {
// For virtual mode, only want one value
getvcol(wp, pos, &col, NULL, NULL);
coladd = pos->coladd;
endadd = 0;
// Cannot put the cursor on part of a wide character.
ptr = ml_get_buf(wp->w_buffer, pos->lnum, FALSE);
if (pos->col < (colnr_T)STRLEN(ptr)) {
int c = (*mb_ptr2char)(ptr + pos->col);
if ((c != TAB) && vim_isprintc(c)) {
endadd = (colnr_T)(char2cells(c) - 1);
if (coladd > endadd) {
// past end of line
endadd = 0;
} else {
coladd = 0;
}
}
}
col += coladd;
if (start != NULL) {
*start = col;
}
if (cursor != NULL) {
*cursor = col;
}
if (end != NULL) {
*end = col + endadd;
}
} else {
getvcol(wp, pos, start, cursor, end);
}
}
/// Get the leftmost and rightmost virtual column of pos1 and pos2.
/// Used for Visual block mode.
///
/// @param wp
/// @param pos1
/// @param pos2
/// @param left
/// @param right
void getvcols(win_T *wp, pos_T *pos1, pos_T *pos2, colnr_T *left,
colnr_T *right)
{
colnr_T from1;
colnr_T from2;
colnr_T to1;
colnr_T to2;
if (ltp(pos1, pos2)) {
getvvcol(wp, pos1, &from1, NULL, &to1);
getvvcol(wp, pos2, &from2, NULL, &to2);
} else {
getvvcol(wp, pos2, &from1, NULL, &to1);
getvvcol(wp, pos1, &from2, NULL, &to2);
}
if (from2 < from1) {
*left = from2;
} else {
*left = from1;
}
if (to2 > to1) {
if ((*p_sel == 'e') && (from2 - 1 >= to1)) {
*right = from2 - 1;
} else {
*right = to2;
}
} else {
*right = to1;
}
}
/// skipwhite: skip over ' ' and '\t'.
///
/// @param q
///
/// @return Pointer to character after the skipped whitespace.
char_u* skipwhite(char_u *q)
{
char_u *p = q;
while (vim_iswhite(*p)) {
// skip to next non-white
p++;
}
return p;
}
/// skip over digits
///
/// @param q
///
/// @return Pointer to the character after the skipped digits.
char_u* skipdigits(char_u *q)
{
char_u *p = q;
while (VIM_ISDIGIT(*p)) {
// skip to next non-digit
p++;
}
return p;
}
/// skip over digits and hex characters
///
/// @param q
///
/// @return Pointer to the character after the skipped digits and hex
/// characters.
char_u* skiphex(char_u *q)
{
char_u *p = q;
while (vim_isxdigit(*p)) {
// skip to next non-digit
p++;
}
return p;
}
/// skip to digit (or NUL after the string)
///
/// @param q
///
/// @return Pointer to the digit or (NUL after the string).
char_u* skiptodigit(char_u *q)
{
char_u *p = q;
while (*p != NUL && !VIM_ISDIGIT(*p)) {
// skip to next digit
p++;
}
return p;
}
/// skip to hex character (or NUL after the string)
///
/// @param q
///
/// @return Pointer to the hex character or (NUL after the string).
char_u* skiptohex(char_u *q)
{
char_u *p = q;
while (*p != NUL && !vim_isxdigit(*p)) {
// skip to next digit
p++;
}
return p;
}
/// Variant of isdigit() that can handle characters > 0x100.
/// We don't use isdigit() here, because on some systems it also considers
/// superscript 1 to be a digit.
/// Use the VIM_ISDIGIT() macro for simple arguments.
///
/// @param c
///
/// @return TRUE if the character is a digit.
int vim_isdigit(int c)
{
return c >= '0' && c <= '9';
}
/// Variant of isxdigit() that can handle characters > 0x100.
/// We don't use isxdigit() here, because on some systems it also considers
/// superscript 1 to be a digit.
///
/// @param c
///
/// @return TRUE if the character is a digit.
int vim_isxdigit(int c)
{
return (c >= '0' && c <= '9')
|| (c >= 'a' && c <= 'f')
|| (c >= 'A' && c <= 'F');
}
// Vim's own character class functions. These exist because many library
// islower()/toupper() etc. do not work properly: they crash when used with
// invalid values or can't handle latin1 when the locale is C.
// Speed is most important here.
#define LATIN1LOWER 'l'
#define LATIN1UPPER 'U'
static char_u latin1flags[257] =
" "
" UUUUUUUUUUUUUUUUUUUUUUUUUU llllllllllllllllllllllllll "
" "
"UUUUUUUUUUUUUUUUUUUUUUU UUUUUUUllllllllllllllllllllllll llllllll";
static char_u latin1upper[257] =
" !\"#$%&'()*+,-./0123456789:;<=>"
"?@ABCDEFGHIJKLMNOPQRSTUVWXYZ[\\]^_`ABCDEFGHIJKLMNOPQRSTUVWXYZ{|}~"
"\x7f\x80\x81\x82\x83\x84\x85\x86\x87\x88\x89\x8a\x8b\x8c\x8d\x8e"
"\x8f\x90\x91\x92\x93\x94\x95\x96\x97\x98\x99\x9a\x9b\x9c\x9d\x9e"
"\x9f\xa0\xa1\xa2\xa3\xa4\xa5\xa6\xa7\xa8\xa9\xaa\xab\xac\xad\xae"
"\xaf\xb0\xb1\xb2\xb3\xb4\xb5\xb6\xb7\xb8\xb9\xba\xbb\xbc\xbd\xbe"
"\xbf\xc0\xc1\xc2\xc3\xc4\xc5\xc6\xc7\xc8\xc9\xca\xcb\xcc\xcd\xce"
"\xcf\xd0\xd1\xd2\xd3\xd4\xd5\xd6\xd7\xd8\xd9\xda\xdb\xdc\xdd\xde"
"\xdf\xc0\xc1\xc2\xc3\xc4\xc5\xc6\xc7\xc8\xc9\xca\xcb\xcc\xcd\xce"
"\xcf\xd0\xd1\xd2\xd3\xd4\xd5\xd6\xf7\xd8\xd9\xda\xdb\xdc\xdd\xde\xff";
static char_u latin1lower[257] =
" !\"#$%&'()*+,-./0123456789:;<=>"
"?@abcdefghijklmnopqrstuvwxyz[\\]^_`abcdefghijklmnopqrstuvwxyz{|}~"
"\x7f\x80\x81\x82\x83\x84\x85\x86\x87\x88\x89\x8a\x8b\x8c\x8d\x8e"
"\x8f\x90\x91\x92\x93\x94\x95\x96\x97\x98\x99\x9a\x9b\x9c\x9d\x9e"
"\x9f\xa0\xa1\xa2\xa3\xa4\xa5\xa6\xa7\xa8\xa9\xaa\xab\xac\xad\xae"
"\xaf\xb0\xb1\xb2\xb3\xb4\xb5\xb6\xb7\xb8\xb9\xba\xbb\xbc\xbd\xbe"
"\xbf\xe0\xe1\xe2\xe3\xe4\xe5\xe6\xe7\xe8\xe9\xea\xeb\xec\xed\xee"
"\xef\xf0\xf1\xf2\xf3\xf4\xf5\xf6\xd7\xf8\xf9\xfa\xfb\xfc\xfd\xfe"
"\xdf\xe0\xe1\xe2\xe3\xe4\xe5\xe6\xe7\xe8\xe9\xea\xeb\xec\xed\xee"
"\xef\xf0\xf1\xf2\xf3\xf4\xf5\xf6\xf7\xf8\xf9\xfa\xfb\xfc\xfd\xfe\xff";
int vim_islower(int c)
{
if (c <= '@') {
return FALSE;
}
if (c >= 0x80) {
if (enc_utf8) {
return utf_islower(c);
}
if (c >= 0x100) {
if (has_mbyte) {
return iswlower(c);
}
// islower() can't handle these chars and may crash
return FALSE;
}
if (enc_latin1like) {
return (latin1flags[c] & LATIN1LOWER) == LATIN1LOWER;
}
}
return islower(c);
}
int vim_isupper(int c)
{
if (c <= '@') {
return FALSE;
}
if (c >= 0x80) {
if (enc_utf8) {
return utf_isupper(c);
}
if (c >= 0x100) {
if (has_mbyte) {
return iswupper(c);
}
// islower() can't handle these chars and may crash
return FALSE;
}
if (enc_latin1like) {
return (latin1flags[c] & LATIN1UPPER) == LATIN1UPPER;
}
}
return isupper(c);
}
int vim_toupper(int c)
{
if (c <= '@') {
return c;
}
if (c >= 0x80) {
if (enc_utf8) {
return utf_toupper(c);
}
if (c >= 0x100) {
if (has_mbyte) {
return towupper(c);
}
// toupper() can't handle these chars and may crash
return c;
}
if (enc_latin1like) {
return latin1upper[c];
}
}
return TOUPPER_LOC(c);
}
int vim_tolower(int c)
{
if (c <= '@') {
return c;
}
if (c >= 0x80) {
if (enc_utf8) {
return utf_tolower(c);
}
if (c >= 0x100) {
if (has_mbyte) {
return towlower(c);
}
// tolower() can't handle these chars and may crash
return c;
}
if (enc_latin1like) {
return latin1lower[c];
}
}
return TOLOWER_LOC(c);
}
/// skiptowhite: skip over text until ' ' or '\t' or NUL.
///
/// @param p
///
/// @return Pointer to the next whitespace or NUL character.
char_u* skiptowhite(char_u *p)
{
while (*p != ' ' && *p != '\t' && *p != NUL) {
p++;
}
return p;
}
/// skiptowhite_esc: Like skiptowhite(), but also skip escaped chars
///
/// @param p
///
/// @return Pointer to the next whitespace character.
char_u* skiptowhite_esc(char_u *p) {
while (*p != ' ' && *p != '\t' && *p != NUL) {
if (((*p == '\\') || (*p == Ctrl_V)) && (*(p + 1) != NUL)) {
++p;
}
++p;
}
return p;
}
/// Getdigits: Get a number from a string and skip over it.
///
/// Note: the argument is a pointer to a char_u pointer!
///
/// @param pp
///
/// @return Number from the string.
long getdigits(char_u **pp)
{
char_u *p = *pp;
long retval = atol((char *)p);
if (*p == '-') {
// skip negative sign
++p;
}
// skip to next non-digit
p = skipdigits(p);
*pp = p;
return retval;
}
/// Return TRUE if "lbuf" is empty or only contains blanks.
///
/// @param lbuf
///
/// @return TRUE if `lbuf` is empty or only contains blanks.
int vim_isblankline(char_u *lbuf)
{
char_u *p = skipwhite(lbuf);
return *p == NUL || *p == '\r' || *p == '\n';
}
/// Convert a string into a long and/or unsigned long, taking care of
/// hexadecimal and octal numbers. Accepts a '-' sign.
/// If "hexp" is not NULL, returns a flag to indicate the type of the number:
/// 0 decimal
/// '0' octal
/// 'X' hex
/// 'x' hex
/// If "len" is not NULL, the length of the number in characters is returned.
/// If "nptr" is not NULL, the signed result is returned in it.
/// If "unptr" is not NULL, the unsigned result is returned in it.
/// If "dooct" is non-zero recognize octal numbers, when > 1 always assume
/// octal number.
/// If "dohex" is non-zero recognize hex numbers, when > 1 always assume
/// hex number.
///
/// @param start
/// @param hexp Returns type of number 0 = decimal, 'x' or 'X' is hex,
// '0' = octal
/// @param len Returns the detected length of number.
/// @param dooct recognize octal number
/// @param dohex recognize hex number
/// @param nptr Returns the signed result.
/// @param unptr Returns the unsigned result.
void vim_str2nr(char_u *start, int *hexp, int *len, int dooct, int dohex,
long *nptr, unsigned long *unptr)
{
char_u *ptr = start;
int hex = 0; // default is decimal
int negative = FALSE;
unsigned long un = 0;
int n;
if (ptr[0] == '-') {
negative = TRUE;
++ptr;
}
// Recognize hex and octal.
if ((ptr[0] == '0') && (ptr[1] != '8') && (ptr[1] != '9')) {
hex = ptr[1];
if (dohex
&& ((hex == 'X') || (hex == 'x'))
&& vim_isxdigit(ptr[2])) {
// hexadecimal
ptr += 2;
} else {
// default is decimal
hex = 0;
if (dooct) {
// Don't interpret "0", "08" or "0129" as octal.
for (n = 1; VIM_ISDIGIT(ptr[n]); ++n) {
if (ptr[n] > '7') {
// can't be octal
hex = 0;
break;
}
if (ptr[n] >= '0') {
// assume octal
hex = '0';
}
}
}
}
}
// Do the string-to-numeric conversion "manually" to avoid sscanf quirks.
if ((hex == '0') || (dooct > 1)) {
// octal
while ('0' <= *ptr && *ptr <= '7') {
un = 8 * un + (unsigned long)(*ptr - '0');
ptr++;
}
} else if ((hex != 0) || (dohex > 1)) {
// hex
while (vim_isxdigit(*ptr)) {
un = 16 * un + (unsigned long)hex2nr(*ptr);
ptr++;
}
} else {
// decimal
while (VIM_ISDIGIT(*ptr)) {
un = 10 * un + (unsigned long)(*ptr - '0');
ptr++;
}
}
if (hexp != NULL) {
*hexp = hex;
}
if (len != NULL) {
*len = (int)(ptr - start);
}
if (nptr != NULL) {
if (negative) {
// account for leading '-' for decimal numbers
*nptr = -(long)un;
} else {
*nptr = (long)un;
}
}
if (unptr != NULL) {
*unptr = un;
}
}
/// Return the value of a single hex character.
/// Only valid when the argument is '0' - '9', 'A' - 'F' or 'a' - 'f'.
///
/// @param c
///
/// @return The value of the hex character.
int hex2nr(int c)
{
if ((c >= 'a') && (c <= 'f')) {
return c - 'a' + 10;
}
if ((c >= 'A') && (c <= 'F')) {
return c - 'A' + 10;
}
return c - '0';
}
#if defined(FEAT_TERMRESPONSE) || defined(FEAT_GUI_GTK) || defined(PROTO)
/// Convert two hex characters to a byte.
/// Return -1 if one of the characters is not hex.
///
/// @param p
///
/// @return The two hex characters converted to a byte or -1 if one of the
/// character is not hex.
int hexhex2nr(char_u *p)
{
if (!vim_isxdigit(p[0]) || !vim_isxdigit(p[1])) {
return -1;
}
return (hex2nr(p[0]) << 4) + hex2nr(p[1]);
}
#endif // if defined(FEAT_TERMRESPONSE) || defined(FEAT_GUI_GTK)
// || defined(PROTO)
/// Return TRUE if "str" starts with a backslash that should be removed.
/// For WIN32 this is only done when the character after the
/// backslash is not a normal file name character.
/// '$' is a valid file name character, we don't remove the backslash before
/// it. This means it is not possible to use an environment variable after a
/// backslash. "C:\$VIM\doc" is taken literally, only "$VIM\doc" works.
/// Although "\ name" is valid, the backslash in "Program\ files" must be
/// removed. Assume a file name doesn't start with a space.
/// For multi-byte names, never remove a backslash before a non-ascii
/// character, assume that all multi-byte characters are valid file name
/// characters.
///
/// @param str
///
/// @return TRUE if `str` starts with a backslash that should be removed.
int rem_backslash(char_u *str)
{
#ifdef BACKSLASH_IN_FILENAME
return str[0] == '\\'
&& str[1] < 0x80
&& (str[1] == ' '
|| (str[1] != NUL
&& str[1] != '*'
&& str[1] != '?'
&& !vim_isfilec(str[1])));
#else // ifdef BACKSLASH_IN_FILENAME
return str[0] == '\\' && str[1] != NUL;
#endif // ifdef BACKSLASH_IN_FILENAME
}
/// Halve the number of backslashes in a file name argument.
///
/// @param p
void backslash_halve(char_u *p)
{
for (; *p; ++p) {
if (rem_backslash(p)) {
STRMOVE(p, p + 1);
}
}
}
/// backslash_halve() plus save the result in allocated memory.
///
/// @param p
///
/// @return String with the number of backslashes halved.
char_u* backslash_halve_save(char_u *p)
{
// TODO(philix): simplify and improve backslash_halve_save algorithm
char_u *res = vim_strsave(p);
backslash_halve(res);
return res;
}
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