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NetBSD/usr.bin/vi/common/term.c

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/*-
* Copyright (c) 1991, 1993, 1994
* The Regents of the University of California. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed by the University of
* California, Berkeley and its contributors.
* 4. Neither the name of the University nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
#ifndef lint
static const char sccsid[] = "@(#)term.c 8.80 (Berkeley) 8/17/94";
#endif /* not lint */
#include <sys/types.h>
#include <sys/queue.h>
#include <sys/time.h>
#include <bitstring.h>
#include <ctype.h>
#include <errno.h>
#include <limits.h>
#include <locale.h>
#include <signal.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <termios.h>
#include <unistd.h>
#include "compat.h"
/*
* XXX
* DON'T INCLUDE <curses.h> HERE, IT BREAKS OSF1 V2.0 WHERE IT
* CHANGES THE VALUES OF VERASE/VKILL/VWERASE TO INCORRECT ONES.
*/
#include <db.h>
#include <regex.h>
#include "vi.h"
static int keycmp __P((const void *, const void *));
static enum input term_key_queue __P((SCR *));
static void term_key_set __P((GS *, int, int));
/*
* If we're reading less than 20 characters, up the size of the tty buffer.
* This shouldn't ever happen, other than the first time through, but it's
* possible if a map is large enough.
*/
#define term_read_grow(sp, tty) \
(tty)->nelem - ((tty)->cnt + (tty)->next) >= 20 ? \
0 : __term_read_grow(sp, tty, 64)
static int __term_read_grow __P((SCR *, IBUF *, int));
/*
* !!!
* Historic vi always used:
*
* ^D: autoindent deletion
* ^H: last character deletion
* ^W: last word deletion
* ^Q: quote the next character (if not used in flow control).
* ^V: quote the next character
*
* regardless of the user's choices for these characters. The user's erase
* and kill characters worked in addition to these characters. Nvi wires
* down the above characters, but in addition permits the VEOF, VERASE, VKILL
* and VWERASE characters described by the user's termios structure.
*
* Ex was not consistent with this scheme, as it historically ran in tty
* cooked mode. This meant that the scroll command and autoindent erase
* characters were mapped to the user's EOF character, and the character
* and word deletion characters were the user's tty character and word
* deletion characters. This implementation makes it all consistent, as
* described above for vi.
*
* XXX
* THIS REQUIRES THAT ALL SCREENS SHARE A SPECIAL KEY SET.
*/
KEYLIST keylist[] = {
{K_CARAT, '^'}, /* ^ */
{K_CNTRLD, '\004'}, /* ^D */
{K_CNTRLR, '\022'}, /* ^R */
{K_CNTRLT, '\024'}, /* ^T */
{K_CNTRLZ, '\032'}, /* ^Z */
{K_COLON, ':'}, /* : */
{K_CR, '\r'}, /* \r */
{K_ESCAPE, '\033'}, /* ^[ */
{K_FORMFEED, '\f'}, /* \f */
{K_HEXCHAR, '\030'}, /* ^X */
{K_NL, '\n'}, /* \n */
{K_RIGHTBRACE, '}'}, /* } */
{K_RIGHTPAREN, ')'}, /* ) */
{K_TAB, '\t'}, /* \t */
{K_VERASE, '\b'}, /* \b */
{K_VKILL, '\025'}, /* ^U */
{K_VLNEXT, '\021'}, /* ^Q */
{K_VLNEXT, '\026'}, /* ^V */
{K_VWERASE, '\027'}, /* ^W */
{K_ZERO, '0'}, /* 0 */
{K_NOTUSED, 0}, /* VEOF, VERASE, VKILL, VWERASE */
{K_NOTUSED, 0},
{K_NOTUSED, 0},
{K_NOTUSED, 0},
};
static int nkeylist = (sizeof(keylist) / sizeof(keylist[0])) - 4;
/*
* term_init --
* Initialize the special key lookup table.
*/
int
term_init(sp)
SCR *sp;
{
GS *gp;
KEYLIST *kp;
int cnt;
/*
* XXX
* 8-bit only, for now. Recompilation should get you any
* 8-bit character set, as long as nul isn't a character.
*/
(void)setlocale(LC_ALL, "");
key_init(sp);
gp = sp->gp;
#ifdef VEOF
term_key_set(gp, VEOF, K_CNTRLD);
#endif
#ifdef VERASE
term_key_set(gp, VERASE, K_VERASE);
#endif
#ifdef VKILL
term_key_set(gp, VKILL, K_VKILL);
#endif
#ifdef VWERASE
term_key_set(gp, VWERASE, K_VWERASE);
#endif
/* Sort the special key list. */
qsort(keylist, nkeylist, sizeof(keylist[0]), keycmp);
/* Initialize the fast lookup table. */
for (gp->max_special = 0, kp = keylist, cnt = nkeylist; cnt--; ++kp) {
if (gp->max_special < kp->value)
gp->max_special = kp->value;
if (kp->ch <= MAX_FAST_KEY)
gp->special_key[kp->ch] = kp->value;
}
return (0);
}
/*
* term_key_set --
* Set keys found in the termios structure. VERASE and VKILL are required
* by POSIX 1003.1-1990, VWERASE is a 4.4BSD extension. We've left three
* open slots in the keylist table, if these values exist, put them into
* place. Note, they may reset (or duplicate) values already in the table,
* so we check for that first.
*/
static void
term_key_set(gp, name, val)
GS *gp;
int name, val;
{
KEYLIST *kp;
cc_t ch;
if (!F_ISSET(gp, G_TERMIOS_SET))
return;
if ((ch = gp->original_termios.c_cc[name]) == _POSIX_VDISABLE)
return;
/* Check for duplication. */
for (kp = keylist; kp->value != K_NOTUSED; ++kp)
if (kp->ch == ch) {
kp->value = val;
return;
}
/* Add a new entry. */
if (kp->value == K_NOTUSED) {
keylist[nkeylist].ch = ch;
keylist[nkeylist].value = val;
++nkeylist;
}
}
/*
* key_init --
* Build the fast-lookup key display array.
*/
void
key_init(sp)
SCR *sp;
{
CHAR_T ch;
for (ch = 0; ch <= MAX_FAST_KEY; ++ch) {
(void)__key_name(sp, ch);
(void)memmove(sp->gp->cname[ch].name, sp->cname, sp->clen);
sp->gp->cname[ch].len = sp->clen;
}
}
/*
* __key_len --
* Return the length of the string that will display the key.
* This routine is the backup for the KEY_LEN() macro.
*/
size_t
__key_len(sp, ch)
SCR *sp;
ARG_CHAR_T ch;
{
(void)__key_name(sp, ch);
return (sp->clen);
}
/*
* __key_name --
* Return the string that will display the key. This routine
* is the backup for the KEY_NAME() macro.
*/
CHAR_T *
__key_name(sp, ach)
SCR *sp;
ARG_CHAR_T ach;
{
static const CHAR_T hexdigit[] = "0123456789abcdef";
static const CHAR_T octdigit[] = "01234567";
CHAR_T ch, *chp, mask;
size_t len;
int cnt, shift;
/*
* Historical (ARPA standard) mappings. Printable characters are left
* alone. Control characters less than '\177' are represented as '^'
* followed by the character offset from the '@' character in the ASCII
* map. '\177' is represented as '^' followed by '?'.
*
* XXX
* The following code depends on the current locale being identical to
* the ASCII map from '\100' to '\076' (\076 since that's the largest
* character for which we can offset from '@' and get something that's
* a printable character in ASCII. I'm told that this is a reasonable
* assumption...
*
* XXX
* This code will only work with CHAR_T's that are multiples of 8-bit
* bytes.
*
* XXX
* NB: There's an assumption here that all printable characters take
* up a single column on the screen. This is not always correct.
*/
ch = ach;
if (isprint(ch)) {
sp->cname[0] = ch;
len = 1;
} else if (ch <= '\076' && iscntrl(ch)) {
sp->cname[0] = '^';
sp->cname[1] = ch == '\177' ? '?' : '@' + ch;
len = 2;
} else if (O_ISSET(sp, O_OCTAL)) {
#define BITS (sizeof(CHAR_T) * 8)
#define SHIFT (BITS - BITS % 3)
#define TOPMASK (BITS % 3 == 2 ? 3 : 1) << (BITS - BITS % 3)
sp->cname[0] = '\\';
sp->cname[1] = octdigit[(ch & TOPMASK) >> SHIFT];
shift = SHIFT - 3;
for (len = 2, mask = 7 << (SHIFT - 3),
cnt = BITS / 3; cnt-- > 0; mask >>= 3, shift -= 3)
sp->cname[len++] = octdigit[(ch & mask) >> shift];
} else {
sp->cname[0] = '0';
sp->cname[1] = 'x';
for (len = 2, chp = (u_int8_t *)&ch,
cnt = sizeof(CHAR_T); cnt-- > 0; ++chp) {
sp->cname[len++] = hexdigit[(*chp & 0xf0) >> 4];
sp->cname[len++] = hexdigit[*chp & 0x0f];
}
}
sp->cname[sp->clen = len] = '\0';
return (sp->cname);
}
/*
* term_push --
* Push keys onto the front of a buffer.
*
* There is a single input buffer in ex/vi. Characters are read onto the
* end of the buffer by the terminal input routines, and pushed onto the
* front of the buffer by various other functions in ex/vi. Each key has
* an associated flag value, which indicates if it has already been quoted,
* if it is the result of a mapping or an abbreviation, as well as a count
* of the number of times it has been mapped.
*/
int
term_push(sp, s, nchars, flags)
SCR *sp;
CHAR_T *s; /* Characters. */
size_t nchars; /* Number of chars. */
u_int flags; /* CH_* flags. */
{
IBUF *tty;
size_t total;
/* If we have room, stuff the keys into the buffer. */
tty = sp->gp->tty;
if (nchars <= tty->next ||
(tty->ch != NULL && tty->cnt == 0 && nchars <= tty->nelem)) {
if (tty->cnt != 0)
tty->next -= nchars;
tty->cnt += nchars;
MEMMOVE(tty->ch + tty->next, s, nchars);
MEMSET(tty->chf + tty->next, flags, nchars);
return (0);
}
/*
* If there are currently characters in the queue, shift them up,
* leaving some extra room. Get enough space plus a little extra.
*/
#define TERM_PUSH_SHIFT 30
total = tty->cnt + tty->next + nchars + TERM_PUSH_SHIFT;
if (total >= tty->nelem && __term_read_grow(sp, tty, MAX(total, 64)))
return (1);
if (tty->cnt) {
MEMMOVE(tty->ch + TERM_PUSH_SHIFT + nchars,
tty->ch + tty->next, tty->cnt);
MEMMOVE(tty->chf + TERM_PUSH_SHIFT + nchars,
tty->chf + tty->next, tty->cnt);
}
/* Put the new characters into the queue. */
tty->next = TERM_PUSH_SHIFT;
tty->cnt += nchars;
MEMMOVE(tty->ch + TERM_PUSH_SHIFT, s, nchars);
MEMSET(tty->chf + TERM_PUSH_SHIFT, flags, nchars);
return (0);
}
/*
* Remove characters from the queue, simultaneously clearing the flag
* and map counts.
*/
#define QREM_HEAD(q, len) { \
size_t __off = (q)->next; \
if (len == 1) \
tty->chf[__off] = 0; \
else \
MEMSET(tty->chf + __off, 0, len); \
if (((q)->cnt -= len) == 0) \
(q)->next = 0; \
else \
(q)->next += len; \
}
#define QREM_TAIL(q, len) { \
size_t __off = (q)->next + (q)->cnt - 1; \
if (len == 1) \
tty->chf[__off] = 0; \
else \
MEMSET(tty->chf + __off, 0, len); \
if (((q)->cnt -= len) == 0) \
(q)->next = 0; \
}
/*
* term_key --
* Get the next key.
*
* !!!
* The flag TXT_MAPNODIGIT probably needs some explanation. First, the idea
* of mapping keys is that one or more keystrokes act like a function key.
* What's going on is that vi is reading a number, and the character following
* the number may or may not be mapped (TXT_MAPCOMMAND). For example, if the
* user is entering the z command, a valid command is "z40+", and we don't want
* to map the '+', i.e. if '+' is mapped to "xxx", we don't want to change it
* into "z40xxx". However, if the user enters "35x", we want to put all of the
* characters through the mapping code.
*
* Historical practice is a bit muddled here. (Surprise!) It always permitted
* mapping digits as long as they weren't the first character of the map, e.g.
* ":map ^A1 xxx" was okay. It also permitted the mapping of the digits 1-9
* (the digit 0 was a special case as it doesn't indicate the start of a count)
* as the first character of the map, but then ignored those mappings. While
* it's probably stupid to map digits, vi isn't your mother.
*
* The way this works is that the TXT_MAPNODIGIT causes term_key to return the
* end-of-digit without "looking" at the next character, i.e. leaving it as the
* user entered it. Presumably, the next term_key call will tell us how the
* user wants it handled.
*
* There is one more complication. Users might map keys to digits, and, as
* it's described above, the commands "map g 1G|d2g" would return the keys
* "d2<end-of-digits>1G", when the user probably wanted "d21<end-of-digits>G".
* So, if a map starts off with a digit we continue as before, otherwise, we
* pretend that we haven't mapped the character and return <end-of-digits>.
*
* Now that that's out of the way, let's talk about Energizer Bunny macros.
* It's easy to create macros that expand to a loop, e.g. map x 3x. It's
* fairly easy to detect this example, because it's all internal to term_key.
* If we're expanding a macro and it gets big enough, at some point we can
* assume it's looping and kill it. The examples that are tough are the ones
* where the parser is involved, e.g. map x "ayyx"byy. We do an expansion
* on 'x', and get "ayyx"byy. We then return the first 4 characters, and then
* find the looping macro again. There is no way that we can detect this
* without doing a full parse of the command, because the character that might
* cause the loop (in this case 'x') may be a literal character, e.g. the map
* map x "ayy"xyy"byy is perfectly legal and won't cause a loop.
*
* Historic vi tried to detect looping macros by disallowing obvious cases in
* the map command, maps that that ended with the same letter as they started
* (which wrongly disallowed "map x 'x"), and detecting macros that expanded
* too many times before keys were returned to the command parser. It didn't
* get many (most?) of the tricky cases right, however, and it was certainly
* possible to create macros that ran forever. And, even if it did figure out
* what was going on, the user was usually tossed into ex mode. Finally, any
* changes made before vi realized that the macro was recursing were left in
* place. We recover gracefully, but the only recourse the user has in an
* infinite macro loop is to interrupt.
*
* !!!
* It is historic practice that mapping characters to themselves as the first
* part of the mapped string was legal, and did not cause infinite loops, i.e.
* ":map! { {^M^T" and ":map n nz." were known to work. The initial, matching
* characters were returned instead of being remapped.
*
* XXX
* The final issue is recovery. It would be possible to undo all of the work
* that was done by the macro if we entered a record into the log so that we
* knew when the macro started, and, in fact, this might be worth doing at some
* point. Given that this might make the log grow unacceptably (consider that
* cursor keys are done with maps), for now we leave any changes made in place.
*/
enum input
term_key(sp, chp, flags)
SCR *sp;
CH *chp;
u_int flags;
{
enum input rval;
struct timeval t, *tp;
CHAR_T ch;
GS *gp;
IBUF *tty;
SEQ *qp;
int init_nomap, ispartial, nr;
/* If we've been interrupted, return an error. */
if (INTERRUPTED(sp))
return (INP_INTR);
gp = sp->gp;
tty = gp->tty;
/*
* If the queue is empty, read more keys in. Since no timeout is
* requested, s_key_read will either return an error or will read
* some number of characters.
*/
loop: if (tty->cnt == 0) {
if (term_read_grow(sp, tty))
return (INP_ERR);
if ((rval = sp->s_key_read(sp, &nr, NULL)) != INP_OK)
return (rval);
/*
* If there's something on the mode line that we wanted
* the user to see, they just entered a character so we
* can presume they saw it.
*/
if (F_ISSET(sp, S_UPDATE_MODE))
F_CLR(sp, S_UPDATE_MODE);
}
/* If the key is mappable and should be mapped, look it up. */
if (!(tty->chf[tty->next] & CH_NOMAP) &&
LF_ISSET(TXT_MAPCOMMAND | TXT_MAPINPUT)) {
/* Set up timeout value. */
if (O_ISSET(sp, O_TIMEOUT)) {
tp = &t;
t.tv_sec = O_VAL(sp, O_KEYTIME) / 10;
t.tv_usec = (O_VAL(sp, O_KEYTIME) % 10) * 100000L;
} else
tp = NULL;
/* Get the next key. */
newmap: ch = tty->ch[tty->next];
if (ch < MAX_BIT_SEQ && !bit_test(gp->seqb, ch))
goto nomap;
/* Search the map. */
remap: qp = seq_find(sp, NULL, &tty->ch[tty->next], tty->cnt,
LF_ISSET(TXT_MAPCOMMAND) ? SEQ_COMMAND : SEQ_INPUT,
&ispartial);
/* If we've been interrupted, return an error. */
if (INTERRUPTED(sp))
return (INP_INTR);
/*
* If get a partial match, read more characters and retry
* the map. If no characters read, return the characters
* unmapped.
*/
if (ispartial) {
if (term_read_grow(sp, tty))
return (INP_ERR);
if ((rval = sp->s_key_read(sp, &nr, tp)) != INP_OK)
return (rval);
if (nr)
goto remap;
goto nomap;
}
/* If no map, return the character. */
if (qp == NULL)
goto nomap;
/*
* If looking for the end of a digit string, and the first
* character of the map is it, pretend we haven't seen the
* character.
*/
if (LF_ISSET(TXT_MAPNODIGIT) &&
qp->output != NULL && !isdigit(qp->output[0]))
goto not_digit_ch;
/* Find out if the initial segments are identical. */
init_nomap = !memcmp(&tty->ch[tty->next], qp->output, qp->ilen);
/* Delete the mapped characters from the queue. */
QREM_HEAD(tty, qp->ilen);
/* If keys mapped to nothing, go get more. */
if (qp->output == NULL)
goto loop;
/* If remapping characters, push the character on the queue. */
if (O_ISSET(sp, O_REMAP)) {
if (init_nomap) {
if (term_push(sp, qp->output + qp->ilen,
qp->olen - qp->ilen, CH_MAPPED))
return (INP_ERR);
if (term_push(sp,
qp->output, qp->ilen, CH_NOMAP | CH_MAPPED))
return (INP_ERR);
goto nomap;
} else
if (term_push(sp,
qp->output, qp->olen, CH_MAPPED))
return (INP_ERR);
goto newmap;
}
/* Else, push the characters on the queue and return one. */
if (term_push(sp, qp->output, qp->olen, CH_MAPPED | CH_NOMAP))
return (INP_ERR);
}
nomap: ch = tty->ch[tty->next];
if (LF_ISSET(TXT_MAPNODIGIT) && !isdigit(ch)) {
not_digit_ch: chp->ch = CH_NOT_DIGIT;
chp->value = 0;
chp->flags = 0;
return (INP_OK);
}
/* Fill in the return information. */
chp->ch = ch;
chp->flags = tty->chf[tty->next];
chp->value = KEY_VAL(sp, ch);
/* Delete the character from the queue. */
QREM_HEAD(tty, 1);
return (INP_OK);
}
/*
* term_flush --
* Flush any flagged keys.
*/
void
term_flush(sp, msg, flags)
SCR *sp;
char *msg;
u_int flags;
{
IBUF *tty;
tty = sp->gp->tty;
if (!tty->cnt || !(tty->chf[tty->next] & flags))
return;
do {
QREM_HEAD(tty, 1);
} while (tty->cnt && tty->chf[tty->next] & flags);
msgq(sp, M_ERR, "%s: keys flushed", msg);
}
/*
* term_user_key --
* Get the next key, but require the user enter one.
*/
enum input
term_user_key(sp, chp)
SCR *sp;
CH *chp;
{
enum input rval;
IBUF *tty;
int nr;
/*
* Read any keys the user has waiting. Make the race
* condition as short as possible.
*/
if ((rval = term_key_queue(sp)) != INP_OK)
return (rval);
/* Wait and read another key. */
if ((rval = sp->s_key_read(sp, &nr, NULL)) != INP_OK)
return (rval);
/* Fill in the return information. */
tty = sp->gp->tty;
chp->ch = tty->ch[tty->next + (tty->cnt - 1)];
chp->flags = 0;
chp->value = KEY_VAL(sp, chp->ch);
QREM_TAIL(tty, 1);
return (INP_OK);
}
/*
* term_key_queue --
* Read the keys off of the terminal queue until it's empty.
*/
static enum input
term_key_queue(sp)
SCR *sp;
{
enum input rval;
struct timeval t;
IBUF *tty;
int nr;
t.tv_sec = 0;
t.tv_usec = 0;
for (tty = sp->gp->tty;;) {
if (term_read_grow(sp, tty))
return (INP_ERR);
if ((rval = sp->s_key_read(sp, &nr, &t)) != INP_OK)
return (rval);
if (nr == 0)
break;
}
return (INP_OK);
}
/*
* __key_val --
* Fill in the value for a key. This routine is the backup
* for the KEY_VAL() macro.
*/
int
__key_val(sp, ch)
SCR *sp;
ARG_CHAR_T ch;
{
KEYLIST k, *kp;
k.ch = ch;
kp = bsearch(&k, keylist, nkeylist, sizeof(keylist[0]), keycmp);
return (kp == NULL ? K_NOTUSED : kp->value);
}
/*
* __term_read_grow --
* Grow the terminal queue. This routine is the backup for
* the term_read_grow() macro.
*/
static int
__term_read_grow(sp, tty, add)
SCR *sp;
IBUF *tty;
int add;
{
size_t new_nelem, olen;
new_nelem = tty->nelem + add;
olen = tty->nelem * sizeof(tty->ch[0]);
BINC_RET(sp, tty->ch, olen, new_nelem * sizeof(tty->ch[0]));
olen = tty->nelem * sizeof(tty->chf[0]);
BINC_RET(sp, tty->chf, olen, new_nelem * sizeof(tty->chf[0]));
tty->nelem = olen / sizeof(tty->chf[0]);
return (0);
}
static int
keycmp(ap, bp)
const void *ap, *bp;
{
return (((KEYLIST *)ap)->ch - ((KEYLIST *)bp)->ch);
}
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