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uemacs/display.c

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/* display.c -- implements display.h */
#include "display.h"
#define REVSTA 1 /* Status line appears in reverse video */
/* The functions in this file handle redisplay. There are two halves, the
ones that update the virtual display screen, and the ones that make the
physical display screen the same as the virtual display screen. These
functions use hints that are left in the windows by the commands.
Modified by Petri Kutvonen
*/
#include <errno.h>
#include <stdio.h>
#include <stdarg.h>
#include <string.h>
#include <unistd.h>
#include "buffer.h"
#include "estruct.h"
#include "input.h"
#include "line.h"
#include "termio.h"
#include "terminal.h"
#include "version.h"
#include "wrapper.h"
#include "utf8.h"
#include "window.h"
struct video {
int v_flag; /* Flags */
#if COLOR
int v_fcolor; /* current forground color */
int v_bcolor; /* current background color */
int v_rfcolor; /* requested forground color */
int v_rbcolor; /* requested background color */
#endif
unicode_t v_text[] ; /* Screen data. */
};
#define VFCHG 0x0001 /* Changed flag */
#define VFEXT 0x0002 /* extended (beyond column 80) */
#define VFREV 0x0004 /* reverse video status */
#define VFREQ 0x0008 /* reverse video request */
#define VFCOL 0x0010 /* color change requested */
static struct video **vscreen; /* Virtual screen. */
#if MEMMAP == 0 || SCROLLCODE
static struct video **pscreen; /* Physical screen. */
#endif
static int displaying = TRUE;
#if UNIX
#include <signal.h>
#endif
#ifdef SIGWINCH
#include <sys/ioctl.h>
/* for window size changes */
int chg_width, chg_height;
#endif
static int currow ; /* Cursor row */
static int curcol ; /* Cursor column */
static int vtrow = 0 ; /* Row location of SW cursor */
static int vtcol = 0 ; /* Column location of SW cursor */
static int lbound = 0 ; /* leftmost column of current line being displayed */
static int taboff = 0 ; /* tab offset for display */
int mpresf = FALSE ; /* TRUE if message in last line */
int scrollcount = 1 ; /* number of lines to scroll */
int discmd = TRUE ; /* display command flag */
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int disinp = TRUE ; /* display input characters (echo) */
static int reframe(struct window *wp);
static void updone(struct window *wp);
static void updall(struct window *wp);
static int scrolls(int inserts);
static void scrscroll(int from, int to, int count);
static int texttest(int vrow, int prow);
static int endofline(unicode_t *s, int n);
static void updext(void);
static int updateline(int row, struct video *vp1, struct video *vp2);
static void modeline(struct window *wp);
static void mlputi(int i, int r);
static void mlputli(long l, int r);
static void mlputf(int s);
static void mlputs( const char *s) ;
#if SIGWINCH
static int newscreensize(int h, int w);
#endif
/*
* Initialize the data structures used by the display code. The edge vectors
* used to access the screens are set up. The operating system's terminal I/O
* channel is set up. All the other things get initialized at compile time.
* The original window has "WFCHG" set, so that it will get completely
* redrawn on the first call to "update".
*/
void vtinit(void)
{
int i;
struct video *vp;
TTopen(); /* open the screen */
TTkopen(); /* open the keyboard */
TTrev(FALSE);
vscreen = xmalloc( term.t_maxrow * sizeof( struct video *)) ;
#if MEMMAP == 0 || SCROLLCODE
pscreen = xmalloc( term.t_maxrow * sizeof( struct video *)) ;
#endif
for( i = 0 ; i < term.t_maxrow ; ++i) {
vp = xmalloc( sizeof( struct video) + term.t_maxcol * sizeof( unicode_t)) ;
vp->v_flag = 0;
#if COLOR
vp->v_rfcolor = 7;
vp->v_rbcolor = 0;
#endif
vscreen[i] = vp;
#if MEMMAP == 0 || SCROLLCODE
vp = xmalloc( sizeof( struct video) + term.t_maxcol * sizeof( unicode_t)) ;
vp->v_flag = 0;
pscreen[i] = vp;
#endif
}
}
#if CLEAN
/* free up all the dynamically allocated video structures */
void vtfree(void)
{
int i;
for( i = 0 ; i < term.t_maxrow; ++i ) {
free(vscreen[i]);
#if MEMMAP == 0 || SCROLLCODE
free(pscreen[i]);
#endif
}
free(vscreen);
#if MEMMAP == 0 || SCROLLCODE
free(pscreen);
#endif
}
#endif
/*
* Clean up the virtual terminal system, in anticipation for a return to the
* operating system. Move down to the last line and clear it out (the next
* system prompt will be written in the line). Shut down the channel to the
* terminal.
*/
void vttidy(void)
{
mlerase() ; /* ends with movecursor( term.t_nrow, 0) and TTflush() */
TTclose();
TTkclose();
#ifdef PKCODE
{
int ret ;
ret = write( 1, "\r", 1) ;
if( ret != 1) {
/* some error handling here */
}
}
#endif
}
/*
* Set the virtual cursor to the specified row and column on the virtual
* screen. There is no checking for nonsense values; this might be a good
* idea during the early stages.
*/
static void vtmove( int row, int col) {
vtrow = row;
vtcol = col;
}
/*
* Write a character to the virtual screen. The virtual row and
* column are updated. If we are not yet on left edge, don't print
* it yet. If the line is too long put a "$" in the last column.
*
* This routine only puts printing characters into the virtual
* terminal buffers. Only column overflow is checked.
*/
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static void sane_vtputc( unicode_t c) {
/* intended to be called by vtputc once sanity check has been done
** only normal printable char should be passed as parameter */
unicode_t *vcp = vscreen[ vtrow]->v_text ; /* ptr to line being updated */
if( vtcol >= term.t_ncol)
vcp[ term.t_ncol - 1] = '$' ;
else if( vtcol >= 0)
vcp[ vtcol] = c ;
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vtcol += 1 ;
}
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static void vtputc( unicode_t c) {
/* In case somebody passes us a signed char.. */
if( c > 0x10FFFF) /* Let's assume this is due to sign extension */
c &= 0xFF ;
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if( c == '\t')
do {
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sane_vtputc( ' ') ;
} while( ((vtcol + taboff) % tabwidth) != 0) ;
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else if( c < 0x20 || c == 0x7F) {
sane_vtputc( '^') ;
sane_vtputc( c ^ 0x40) ;
} else if( c >= 0x80 && c <= 0xA0) {
static const char hex[] = "0123456789abcdef";
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sane_vtputc( '\\') ;
sane_vtputc( hex[ c >> 4]) ;
sane_vtputc( hex[ c & 15]) ;
} else if( utf8_width( c) < 0) {
sane_vtputc( '\\') ; /* show as non printable */
sane_vtputc( 'u') ;
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} else
sane_vtputc( c) ;
}
static int vtputs( const char *s) {
int n = 0 ;
while( *s) {
unicode_t c ;
s += utf8_to_unicode( s, 0, 4, &c) ;
vtputc( c) ;
n += utf8_width( c) ; /* To Do: only works if all printable */
}
return n ;
}
/*
* Erase from the end of the software cursor to the end of the line on which
* the software cursor is located.
*/
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static void vteeol( void) {
unicode_t *vcp = vscreen[ vtrow]->v_text ;
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while( vtcol < term.t_ncol)
vcp[ vtcol++] = ' ' ;
}
/* upscreen:
* user routine to force a screen update
* always finishes complete update
*/
BINDABLE( upscreen) {
update( TRUE) ;
return TRUE ;
}
#if SCROLLCODE
static int scrflags;
#endif
/* Make sure that the display is right. This is a three part process.
First, scan through all of the windows looking for dirty ones. Check
the framing, and refresh the screen. Second, make sure that "currow"
and "curcol" are correct for the current window. Third, make the
virtual and physical screens the same.
boolean force_f ; force update past type ahead?
*/
int update( boolean force_f) {
struct window *wp;
#if TYPEAH && ! PKCODE
if( force_f == FALSE && typahead())
return TRUE;
#endif
#if VISMAC == 0
if( force_f == FALSE && kbdmode == PLAY)
return TRUE;
#endif
displaying = TRUE;
#if SCROLLCODE
/* first, propagate mode line changes to all instances of
a buffer displayed in more than one window */
wp = wheadp;
while (wp != NULL) {
if (wp->w_flag & WFMODE) {
if (wp->w_bufp->b_nwnd > 1) {
/* make sure all previous windows have this */
struct window *owp;
owp = wheadp;
while (owp != NULL) {
if (owp->w_bufp == wp->w_bufp)
owp->w_flag |= WFMODE;
owp = owp->w_wndp;
}
}
}
wp = wp->w_wndp;
}
#endif
/* update any windows that need refreshing */
wp = wheadp;
while (wp != NULL) {
if (wp->w_flag) {
/* if the window has changed, service it */
reframe(wp); /* check the framing */
#if SCROLLCODE
if (wp->w_flag & (WFKILLS | WFINS)) {
scrflags |=
(wp->w_flag & (WFINS | WFKILLS));
wp->w_flag &= ~(WFKILLS | WFINS);
}
#endif
if ((wp->w_flag & ~WFMODE) == WFEDIT)
updone(wp); /* update EDITed line */
else if (wp->w_flag & ~WFMOVE)
updall(wp); /* update all lines */
#if SCROLLCODE
if (scrflags || (wp->w_flag & WFMODE))
#else
if (wp->w_flag & WFMODE)
#endif
modeline(wp); /* update modeline */
wp->w_flag = 0;
wp->w_force = 0;
}
/* on to the next window */
wp = wp->w_wndp;
}
/* recalc the current hardware cursor location */
updpos();
#if MEMMAP && ! SCROLLCODE
/* update the cursor and flush the buffers */
movecursor(currow, curcol - lbound);
#endif
/* check for lines to de-extend */
upddex();
/* if screen is garbage, re-plot it */
if (sgarbf != FALSE)
updgar();
/* update the virtual screen to the physical screen */
updupd( force_f) ;
/* update the cursor and flush the buffers */
movecursor(currow, curcol - lbound);
TTflush();
displaying = FALSE;
#if SIGWINCH
while (chg_width || chg_height)
newscreensize(chg_height, chg_width);
#endif
return TRUE;
}
/*
* reframe:
* check to see if the cursor is on in the window
* and re-frame it if needed or wanted
*/
static int reframe(struct window *wp)
{
struct line *lp, *lp0;
int i = 0;
/* if not a requested reframe, check for a needed one */
if ((wp->w_flag & WFFORCE) == 0) {
#if SCROLLCODE
/* loop from one line above the window to one line after */
lp = wp->w_linep;
lp0 = lback(lp);
if (lp0 == wp->w_bufp->b_linep)
i = 0;
else {
i = -1;
lp = lp0;
}
for (; i <= (int) (wp->w_ntrows); i++)
#else
lp = wp->w_linep;
for (i = 0; i < wp->w_ntrows; i++)
#endif
{
/* if the line is in the window, no reframe */
if (lp == wp->w_dotp) {
#if SCROLLCODE
/* if not _quite_ in, we'll reframe gently */
if (i < 0 || i == wp->w_ntrows) {
/* if the terminal can't help, then
we're simply outside */
if (term.t_scroll == NULL)
i = wp->w_force;
break;
}
#endif
return TRUE;
}
/* if we are at the end of the file, reframe */
if (lp == wp->w_bufp->b_linep)
break;
/* on to the next line */
lp = lforw(lp);
}
}
#if SCROLLCODE
if (i == -1) { /* we're just above the window */
i = scrollcount; /* put dot at first line */
scrflags |= WFINS;
} else if (i == wp->w_ntrows) { /* we're just below the window */
i = -scrollcount; /* put dot at last line */
scrflags |= WFKILLS;
} else /* put dot where requested */
#endif
i = wp->w_force; /* (is 0, unless reposition() was called) */
wp->w_flag |= WFMODE;
/* how far back to reframe? */
if (i > 0) { /* only one screen worth of lines max */
if (--i >= wp->w_ntrows)
i = wp->w_ntrows - 1;
} else if (i < 0) { /* negative update???? */
i += wp->w_ntrows;
if (i < 0)
i = 0;
} else
i = wp->w_ntrows / 2;
/* backup to new line at top of window */
lp = wp->w_dotp;
while (i != 0 && lback(lp) != wp->w_bufp->b_linep) {
--i;
lp = lback(lp);
}
/* and reset the current line at top of window */
wp->w_linep = lp;
wp->w_flag |= WFHARD;
wp->w_flag &= ~WFFORCE;
return TRUE;
}
static void show_line(struct line *lp)
{
int i = 0, len = llength(lp);
while (i < len) {
unicode_t c;
i += utf8_to_unicode(lp->l_text, i, len, &c);
vtputc(c);
}
}
/*
* updone:
* update the current line to the virtual screen
*
* struct window *wp; window to update current line in
*/
static void updone(struct window *wp)
{
struct line *lp; /* line to update */
int sline; /* physical screen line to update */
/* search down the line we want */
lp = wp->w_linep;
sline = wp->w_toprow;
while (lp != wp->w_dotp) {
++sline;
lp = lforw(lp);
}
/* and update the virtual line */
vscreen[sline]->v_flag |= VFCHG;
vscreen[sline]->v_flag &= ~VFREQ;
vtmove(sline, 0);
show_line(lp);
#if COLOR
vscreen[sline]->v_rfcolor = wp->w_fcolor;
vscreen[sline]->v_rbcolor = wp->w_bcolor;
#endif
vteeol();
}
/*
* updall:
* update all the lines in a window on the virtual screen
*
* struct window *wp; window to update lines in
*/
static void updall(struct window *wp)
{
struct line *lp; /* line to update */
int sline; /* physical screen line to update */
/* search down the lines, updating them */
lp = wp->w_linep;
sline = wp->w_toprow;
while (sline < wp->w_toprow + wp->w_ntrows) {
/* and update the virtual line */
vscreen[sline]->v_flag |= VFCHG;
vscreen[sline]->v_flag &= ~VFREQ;
vtmove(sline, 0);
if (lp != wp->w_bufp->b_linep) {
/* if we are not at the end */
show_line(lp);
lp = lforw(lp);
}
/* on to the next one */
#if COLOR
vscreen[sline]->v_rfcolor = wp->w_fcolor;
vscreen[sline]->v_rbcolor = wp->w_bcolor;
#endif
vteeol();
++sline;
}
}
/*
* updpos:
* update the position of the hardware cursor and handle extended
* lines. This is the only update for simple moves.
*/
void updpos(void)
{
struct line *lp;
int i;
/* find the current row */
lp = curwp->w_linep;
currow = curwp->w_toprow;
while (lp != curwp->w_dotp) {
++currow;
lp = lforw(lp);
}
/* find the current column */
curcol = 0;
i = 0;
while (i < curwp->w_doto) {
unicode_t c;
i += utf8_to_unicode( lp->l_text, i, curwp->w_doto, &c) ;
if( c == '\t')
curcol += tabwidth - curcol % tabwidth ;
else if( c < 0x20 || c == 0x7F)
curcol += 2 ; /* displayed as ^c */
else if( c >= 0x80 && c <= 0xA0)
curcol += 3 ; /* displayed as \xx */
else {
int width = utf8_width( c) ;
curcol += (width < 0) ? 2 : width ; /* non printable are displayed as \u */
}
}
/* if extended, flag so and update the virtual line image */
if (curcol >= term.t_ncol - 1) {
vscreen[currow]->v_flag |= (VFEXT | VFCHG);
updext();
} else
lbound = 0;
}
/*
* upddex:
* de-extend any line that deserves it
*/
void upddex(void)
{
struct window *wp;
struct line *lp;
int i;
wp = wheadp;
while (wp != NULL) {
lp = wp->w_linep;
i = wp->w_toprow;
while (i < wp->w_toprow + wp->w_ntrows) {
if (vscreen[i]->v_flag & VFEXT) {
if ((wp != curwp) || (lp != wp->w_dotp) ||
(curcol < term.t_ncol - 1)) {
vtmove(i, 0);
show_line(lp);
vteeol();
/* this line no longer is extended */
vscreen[i]->v_flag &= ~VFEXT;
vscreen[i]->v_flag |= VFCHG;
}
}
lp = lforw(lp);
++i;
}
/* and onward to the next window */
wp = wp->w_wndp;
}
}
/*
* updgar:
* if the screen is garbage, clear the physical screen and
* the virtual screen and force a full update
*/
void updgar(void)
{
unicode_t *txt;
int i, j;
for (i = 0; i < term.t_nrow; ++i) {
vscreen[i]->v_flag |= VFCHG;
#if REVSTA
vscreen[i]->v_flag &= ~VFREV;
#endif
#if COLOR
vscreen[i]->v_fcolor = gfcolor;
vscreen[i]->v_bcolor = gbcolor;
#endif
#if MEMMAP == 0 || SCROLLCODE
txt = pscreen[i]->v_text;
for (j = 0; j < term.t_ncol; ++j)
txt[j] = ' ';
#endif
}
movecursor(0, 0); /* Erase the screen. */
(*term.t_eeop) ();
sgarbf = FALSE; /* Erase-page clears */
mpresf = FALSE; /* the message area. */
#if COLOR
mlerase(); /* needs to be cleared if colored */
#endif
}
/*
* updupd:
* update the physical screen from the virtual screen
*
* int force; forced update flag
*/
int updupd(int force)
{
struct video *vp1;
int i;
#if SCROLLCODE
if (scrflags & WFKILLS)
scrolls(FALSE);
if (scrflags & WFINS)
scrolls(TRUE);
scrflags = 0;
#endif
for (i = 0; i < term.t_nrow; ++i) {
vp1 = vscreen[i];
/* for each line that needs to be updated */
if ((vp1->v_flag & VFCHG) != 0) {
#if TYPEAH && ! PKCODE
if (force == FALSE && typahead())
return TRUE;
#endif
#if MEMMAP && ! SCROLLCODE
updateline(i, vp1);
#else
updateline(i, vp1, pscreen[i]);
#endif
}
}
return TRUE;
}
#if SCROLLCODE
/*
* optimize out scrolls (line breaks, and newlines)
* arg. chooses between looking for inserts or deletes
*/
static int scrolls(int inserts)
{ /* returns true if it does something */
struct video *vpv; /* virtual screen image */
struct video *vpp; /* physical screen image */
int i, j, k;
int rows, cols;
int first, match, count, target, end;
int longmatch, longcount;
int from, to;
if (!term.t_scroll) /* no way to scroll */
return FALSE;
rows = term.t_nrow;
cols = term.t_ncol;
first = -1;
for (i = 0; i < rows; i++) { /* find first wrong line */
if (!texttest(i, i)) {
first = i;
break;
}
}
if (first < 0)
return FALSE; /* no text changes */
vpv = vscreen[first];
vpp = pscreen[first];
if (inserts) {
/* determine types of potential scrolls */
end = endofline(vpv->v_text, cols);
if (end == 0)
target = first; /* newlines */
else if (memcmp(vpp->v_text, vpv->v_text, 4*end) == 0)
target = first + 1; /* broken line newlines */
else
target = first;
} else {
target = first + 1;
}
/* find the matching shifted area */
match = -1;
longmatch = -1;
longcount = 0;
from = target;
for (i = from + 1; i < rows - longcount /* P.K. */ ; i++) {
if (inserts ? texttest(i, from) : texttest(from, i)) {
match = i;
count = 1;
for (j = match + 1, k = from + 1;
j < rows && k < rows; j++, k++) {
if (inserts ? texttest(j, k) :
texttest(k, j))
count++;
else
break;
}
if (longcount < count) {
longcount = count;
longmatch = match;
}
}
}
match = longmatch;
count = longcount;
if (!inserts) {
/* full kill case? */
if (match > 0 && texttest(first, match - 1)) {
target--;
match--;
count++;
}
}
/* do the scroll */
if (match > 0 && count > 2) { /* got a scroll */
/* move the count lines starting at target to match */
if (inserts) {
from = target;
to = match;
} else {
from = match;
to = target;
}
if (2 * count < abs(from - to))
return FALSE;
scrscroll(from, to, count);
for (i = 0; i < count; i++) {
vpp = pscreen[to + i];
vpv = vscreen[to + i];
memcpy(vpp->v_text, vpv->v_text, 4*cols);
vpp->v_flag = vpv->v_flag; /* XXX */
if (vpp->v_flag & VFREV) {
vpp->v_flag &= ~VFREV;
vpp->v_flag |= ~VFREQ;
}
#if MEMMAP
vscreen[to + i]->v_flag &= ~VFCHG;
#endif
}
if (inserts) {
from = target;
to = match;
} else {
from = target + count;
to = match + count;
}
#if MEMMAP == 0
for (i = from; i < to; i++) {
unicode_t *txt;
txt = pscreen[i]->v_text;
for (j = 0; j < term.t_ncol; ++j)
txt[j] = ' ';
vscreen[i]->v_flag |= VFCHG;
}
#endif
return TRUE;
}
return FALSE;
}
/* move the "count" lines starting at "from" to "to" */
static void scrscroll(int from, int to, int count)
{
ttrow = ttcol = -1;
(*term.t_scroll) (from, to, count);
}
/*
* return TRUE on text match
*
* int vrow, prow; virtual, physical rows
*/
static int texttest(int vrow, int prow)
{
struct video *vpv = vscreen[vrow]; /* virtual screen image */
struct video *vpp = pscreen[prow]; /* physical screen image */
return !memcmp(vpv->v_text, vpp->v_text, 4*term.t_ncol);
}
/*
* return the index of the first blank of trailing whitespace
*/
static int endofline(unicode_t *s, int n)
{
int i;
for (i = n - 1; i >= 0; i--)
if (s[i] != ' ')
return i + 1;
return 0;
}
#endif /* SCROLLCODE */
/*
* updext:
* update the extended line which the cursor is currently
* on at a column greater than the terminal width. The line
* will be scrolled right or left to let the user see where
* the cursor is
*/
static void updext(void)
{
int rcursor; /* real cursor location */
struct line *lp; /* pointer to current line */
/* calculate what column the real cursor will end up in */
rcursor = ((curcol - term.t_ncol) % term.t_scrsiz) + term.t_margin;
taboff = lbound = curcol - rcursor + 1;
/* scan through the line outputing characters to the virtual screen */
/* once we reach the left edge */
vtmove(currow, -lbound); /* start scanning offscreen */
lp = curwp->w_dotp; /* line to output */
show_line(lp);
/* truncate the virtual line, restore tab offset */
vteeol();
taboff = 0;
/* and put a '$' in column 1 */
vscreen[currow]->v_text[0] = '$';
}
/*
* Update a single line. This does not know how to use insert or delete
* character sequences; we are using VT52 functionality. Update the physical
* row and column variables. It does try an exploit erase to end of line.
*/
#if MEMMAP
/* UPDATELINE specific code for the IBM-PC and other compatables */
static int updateline(int row, struct video *vp1, struct video *vp2)
{
#if SCROLLCODE
unicode_t *cp1;
unicode_t *cp2;
int nch;
cp1 = &vp1->v_text[0];
cp2 = &vp2->v_text[0];
nch = term.t_ncol;
do {
*cp2 = *cp1;
++cp2;
++cp1;
}
while (--nch);
#endif
#if COLOR
scwrite(row, vp1->v_text, vp1->v_rfcolor, vp1->v_rbcolor);
vp1->v_fcolor = vp1->v_rfcolor;
vp1->v_bcolor = vp1->v_rbcolor;
#else
if (vp1->v_flag & VFREQ)
scwrite(row, vp1->v_text, 0, 7);
else
scwrite(row, vp1->v_text, 7, 0);
#endif
vp1->v_flag &= ~(VFCHG | VFCOL); /* flag this line as changed */
}
#else
/*
* updateline()
*
* int row; row of screen to update
* struct video *vp1; virtual screen image
* struct video *vp2; physical screen image
*/
static int updateline(int row, struct video *vp1, struct video *vp2)
{
/* UPDATELINE code for all other versions */
unicode_t *cp1;
unicode_t *cp2;
unicode_t *cp3;
unicode_t *cp4;
unicode_t *cp5;
int nbflag; /* non-blanks to the right flag? */
#if REVSTA
int rev; /* reverse video flag */
#endif
int req = FALSE ; /* reverse video request flag */
/* set up pointers to virtual and physical lines */
cp1 = &vp1->v_text[0];
cp2 = &vp2->v_text[0];
#if COLOR
TTforg(vp1->v_rfcolor);
TTbacg(vp1->v_rbcolor);
#endif
#if REVSTA | COLOR
/* do a re-write of the entire line if it is reverse or there
** is a request to change the reverse status */
rev = (vp1->v_flag & VFREV) == VFREV;
req = (vp1->v_flag & VFREQ) == VFREQ;
if( req || (req != rev)
#if COLOR
|| (vp1->v_fcolor != vp1->v_rfcolor)
|| (vp1->v_bcolor != vp1->v_rbcolor)
#endif
) {
movecursor(row, 0); /* Go to start of line. */
TTrev( req) ; /* set needed rev video state */
/* scan through the line and dump it to the screen and
the virtual screen array */
while( ttcol < term.t_ncol) {
/* TODO: handle double width unicode char at last screen col */
unicode_t c = *cp1++ ;
TTputc( c) ;
ttcol += utf8_width( c) ;
*cp2++ = c ;
}
TTrev( FALSE) ; /* turn rev video off */
/* update the needed flags */
vp1->v_flag &= ~VFCHG;
if (req)
vp1->v_flag |= VFREV;
else
vp1->v_flag &= ~VFREV;
#if COLOR
vp1->v_fcolor = vp1->v_rfcolor;
vp1->v_bcolor = vp1->v_rbcolor;
#endif
return TRUE;
}
#endif
/* advance past any common chars at the left */
while (cp1 != &vp1->v_text[term.t_ncol] && cp1[0] == cp2[0]) {
++cp1;
++cp2;
}
/* This can still happen, even though we only call this routine on changed
* lines. A hard update is always done when a line splits, a massive
* change is done, or a buffer is displayed twice. This optimizes out most
* of the excess updating. A lot of computes are used, but these tend to
* be hard operations that do a lot of update, so I don't really care.
*/
/* if both lines are the same, no update needs to be done */
if (cp1 == &vp1->v_text[term.t_ncol]) {
vp1->v_flag &= ~VFCHG; /* flag this line is changed */
return TRUE;
}
/* find out if there is a match on the right */
nbflag = FALSE;
cp3 = &vp1->v_text[term.t_ncol];
cp4 = &vp2->v_text[term.t_ncol];
while (cp3[-1] == cp4[-1]) {
--cp3;
--cp4;
if (cp3[0] != ' ') /* Note if any nonblank */
nbflag = TRUE; /* in right match. */
}
cp5 = cp3;
/* Erase to EOL ? */
if (nbflag == FALSE && eolexist == TRUE && (req != TRUE)) {
while (cp5 != cp1 && cp5[-1] == ' ')
--cp5;
if (cp3 - cp5 <= 3) /* Use only if erase is */
cp5 = cp3; /* fewer characters. */
}
movecursor(row, cp1 - &vp1->v_text[0]); /* Go to start of line. */
#if REVSTA
TTrev(rev);
#endif
while (cp1 != cp5) { /* Ordinary. */
unicode_t c = *cp1++ ;
TTputc( c) ;
ttcol += utf8_width( c) ;
*cp2++ = c ;
}
if (cp5 != cp3) { /* Erase. */
TTeeol();
while (cp1 != cp3)
*cp2++ = *cp1++;
}
#if REVSTA
TTrev(FALSE);
#endif
vp1->v_flag &= ~VFCHG; /* flag this line as updated */
return TRUE;
}
#endif
/*
* Redisplay the mode line for the window pointed to by the "wp". This is the
* only routine that has any idea of how the modeline is formatted. You can
* change the modeline format by hacking at this routine. Called by "update"
* any time there is a dirty window.
*/
static void modeline(struct window *wp)
{
int n; /* cursor position count */
struct buffer *bp;
int i; /* loop index */
int lchar; /* character to draw line in buffer with */
int firstm; /* is this the first mode? */
n = wp->w_toprow + wp->w_ntrows; /* Location. */
vscreen[n]->v_flag |= VFCHG | VFREQ | VFCOL; /* Redraw next time. */
#if COLOR
vscreen[n]->v_rfcolor = 0; /* black on */
vscreen[n]->v_rbcolor = 7; /* white..... */
#endif
vtmove(n, 0); /* Seek to right line. */
if (wp == curwp) /* mark the current buffer */
#if PKCODE && REVSTA
lchar = '-';
#else
lchar = '=';
#endif
else
#if REVSTA
if (revexist)
lchar = ' ';
else
#endif
lchar = '-';
bp = wp->w_bufp;
vtputc( ((bp->b_flag & BFTRUNC) != 0) ? '#' : lchar) ; /* truncated? */
vtputc( ((bp->b_flag & BFCHG) != 0) ? '*' : lchar) ; /* changed? */
vtputc( ' ') ;
if( n == term.t_nrow - 1)
n = 3 + vtputs( PROGRAM_NAME_UTF8 " " VERSION ": ") ;
else
n = 3 ;
n += vtputs( bp->b_bname) ;
n += vtputs( " (") ;
/* display the modes */
if ((bp->b_flag & BFTRUNC) != 0) {
firstm = FALSE;
n += vtputs( "Truncated") ;
} else
firstm = TRUE ;
for (i = 0; i < NUMMODES; i++) /* add in the mode flags */
if (wp->w_bufp->b_mode & (1 << i)) {
if (firstm != TRUE)
n += vtputs( " ") ;
else
firstm = FALSE ;
n += vtputs( modename[ i]) ;
}
n += vtputs( ") ") ;
#if PKCODE
if (bp->b_fname[0] != 0 && strcmp(bp->b_bname, bp->b_fname) != 0) {
#else
if (bp->b_fname[0] != 0) { /* File name. */
n += vtputs( "File: ") ;
#endif
n += vtputs( bp->b_fname) ;
vtputc(' ');
++n;
}
while (n < term.t_ncol) { /* Pad to full width. */
vtputc(lchar);
++n;
}
{ /* determine if top line, bottom line, or both are visible */
struct line *lp = wp->w_linep;
int rows = wp->w_ntrows;
char *msg = NULL;
char tline[ 6] ; /* buffer for part of mode line */
vtcol -= 7 ; /* strlen(" top ") plus a couple */
while (rows--) {
lp = lforw(lp);
if (lp == wp->w_bufp->b_linep) {
msg = " Bot ";
break;
}
}
if (lback(wp->w_linep) == wp->w_bufp->b_linep) {
if (msg) {
if (wp->w_linep == wp->w_bufp->b_linep)
msg = " Emp ";
else
msg = " All ";
} else {
msg = " Top ";
}
}
if (!msg) {
struct line *lp;
int numlines, predlines ;
lp = lforw(bp->b_linep);
numlines = 0;
predlines = 0;
while (lp != bp->b_linep) {
if (lp == wp->w_linep) {
predlines = numlines;
}
++numlines;
lp = lforw(lp);
}
if (wp->w_dotp == bp->b_linep) {
msg = " Bot ";
} else {
int ratio = 0 ;
if (numlines != 0)
ratio =
(100L * predlines) / numlines;
if (ratio > 99)
ratio = 99;
tline[ 0] = ' ' ;
tline[ 1] = ratio / 10 + '0' ;
tline[ 2] = ratio % 10 + '0' ;
tline[ 3] = '%' ;
tline[ 4] = ' ' ;
tline[ 5] = 0 ;
if( tline[ 1] == '0')
tline[ 1] = ' ' ;
msg = tline;
}
}
n += vtputs( msg) ;
}
}
void upmode(void)
{ /* update all the mode lines */
struct window *wp;
wp = wheadp;
while (wp != NULL) {
wp->w_flag |= WFMODE;
wp = wp->w_wndp;
}
}
/*
* Send a command to the terminal to move the hardware cursor to row "row"
* and column "col". The row and column arguments are origin 0. Optimize out
* random calls. Update "ttrow" and "ttcol".
*/
void movecursor(int row, int col)
{
if (row != ttrow || col != ttcol) {
ttrow = row;
ttcol = col;
TTmove(row, col);
}
}
/*
* Erase the message line. This is a special routine because the message line
* is not considered to be part of the virtual screen. It always works
* immediately; the terminal buffer is flushed via a call to the flusher.
*/
void mlerase( void) {
movecursor( term.t_nrow, 0) ;
if( discmd != FALSE) {
#if COLOR
TTforg( 7) ;
TTbacg( 0) ;
#endif
if( eolexist == TRUE)
TTeeol() ;
else {
for( ttcol = 0 ; ttcol < term.t_ncol ; ttcol++)
TTputc( ' ') ;
movecursor( term.t_nrow, 0) ;
}
mpresf = FALSE ;
}
TTflush() ;
}
static void mlputc( unicode_t c) {
if( ttcol < term.t_ncol) {
TTputc( c) ;
ttcol += utf8_width( c) ;
}
}
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/*
* output a string of output characters
*
* char *s; string to output
*/
void ostring( const char *s) {
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if( discmd)
mlputs( s) ;
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}
/*
* Write a message into the message line. Keep track of the physical cursor
* position. A small class of printf like format items is handled. Assumes the
* stack grows down; this assumption is made by the "++" in the argument scan
* loop. Set the "message line" flag TRUE.
*
* char *fmt; format string for output
* char *arg; pointer to first argument to print
*/
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void vmlwrite( const char *fmt, va_list ap) {
/* if we are not currently echoing on the command line, abort this */
if (discmd == FALSE) {
movecursor(term.t_nrow, 0);
return;
}
#if COLOR
/* set up the proper colors for the command line */
TTforg(7);
TTbacg(0);
#endif
/* if we can not erase to end-of-line, do it manually */
if( eolexist == FALSE)
mlerase() ; /* ends with movecursor( term.t_nrow, 0) and TTflush() */
else
movecursor( term.t_nrow, 0) ;
mpresf = *fmt ? TRUE : FALSE ; /* flag if line has content or not */
while( *fmt) {
unicode_t c ;
fmt += utf8_to_unicode( fmt, 0, 4, &c) ;
if( c != '%')
mlputc( c) ;
else if( *fmt == 0) {
mlputc( '%') ;
break ;
} else {
fmt += utf8_to_unicode( fmt, 0, 4, &c) ;
switch( c) {
case 'd':
mlputi(va_arg(ap, int), 10);
break;
case 'o':
mlputi(va_arg(ap, int), 8);
break;
case 'x':
mlputi(va_arg(ap, int), 16);
break;
case 'D':
mlputli(va_arg(ap, long), 10);
break;
case 's':
mlputs( (char *) va_arg( ap, char *)) ;
break;
case 'f':
mlputf(va_arg(ap, int));
break;
case 'B': /* ring a bell */
TTbeep() ;
break ;
default:
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mlputc( '%') ;
/* fallthrough */
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case '%':
mlputc( c) ;
}
}
}
/* if we can, erase to the end of screen */
if( eolexist == TRUE && ttcol < term.t_ncol)
TTeeol() ;
TTflush();
}
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void mlwrite( const char *fmt, ...) {
va_list ap ;
va_start( ap, fmt) ;
vmlwrite( fmt, ap) ;
va_end( ap) ;
}
/*
* Write out a string. Update the physical cursor position. This assumes that
* the characters in the string all have width "1"; if this is not the case
* things will get screwed up a little.
*/
static void mlputs( const char *s) {
while( *s && (ttcol < term.t_ncol)) {
unicode_t uc ;
s += utf8_to_unicode( (char *) s, 0, 4, &uc) ;
if( uc == '\t') /* Don't render tabulation */
uc = ' ' ;
TTputc( uc) ;
ttcol += utf8_width( uc) ;
}
}
/*
* Write out an integer, in the specified radix. Update the physical cursor
* position.
*/
static void mlputi( int i, int r) {
int q ;
unsigned u ;
static char hexdigits[] = "0123456789ABCDEF" ;
if( r == 16 || i >= 0)
u = i ;
else {
u = -i ;
mlputc( '-') ;
}
q = u / r ;
if( q != 0)
mlputi( q, r) ;
mlputc( hexdigits[ u % r]) ;
}
/*
* do the same except as a long integer.
*/
static void mlputli( long l, int r) {
long q ;
if( l < 0) {
l = -l ;
mlputc( '-') ;
}
q = l / r ;
if( q != 0)
mlputli( q, r) ;
mlputc( (int) (l % r) + '0') ;
}
/*
* write out a scaled integer with two decimal places
*
* int s; scaled integer to output
*/
static void mlputf( int s) {
int i ; /* integer portion of number */
int f ; /* fractional portion of number */
/* break it up */
i = s / 100 ;
f = s % 100 ;
/* send out the integer portion */
mlputi( i, 10) ;
mlputc('.') ;
mlputc((f / 10) + '0') ;
mlputc((f % 10) + '0') ;
}
/* Get terminal size from system.
Store number of lines into *heightp and width into *widthp.
If zero or a negative number is stored, the value is not valid. */
void getscreensize(int *widthp, int *heightp)
{
#ifdef TIOCGWINSZ
struct winsize size;
*widthp = 0;
*heightp = 0;
if (ioctl(0, TIOCGWINSZ, &size) < 0)
return;
*widthp = size.ws_col;
*heightp = size.ws_row;
#else
*widthp = 0;
*heightp = 0;
#endif
}
#ifdef SIGWINCH
void sizesignal(int signr)
{
int w, h;
int old_errno = errno;
getscreensize(&w, &h);
if( h > 0 && w > 0) {
term.t_mrow = h = h < term.t_maxrow ? h : term.t_maxrow ;
term.t_mcol = w = w < term.t_maxcol ? w : term.t_maxcol ;
if( h - 1 != term.t_nrow || w != term.t_ncol)
newscreensize( h, w) ;
}
signal(SIGWINCH, sizesignal);
errno = old_errno;
}
static int newscreensize(int h, int w)
{
/* do the change later */
if (displaying) {
chg_width = w;
chg_height = h;
return FALSE;
}
chg_width = chg_height = 0;
if( h <= term.t_mrow)
newsize(TRUE, h);
if( w <= term.t_mcol)
newwidth(TRUE, w);
update(TRUE);
return TRUE;
}
#endif
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/*
* output a character when echo is enabled
*
* char c ; character to output
*/
void echoc( unicode_t c) {
if( disinp) {
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TTputc( c) ;
ttcol += 1 ;
}
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}
/*
* output a string of characters when display input is enabled
*
* char *s; string to output
*/
void echos( const char *s) {
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unicode_t c ;
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if( disinp)
while( (c = *s++)) {
TTputc( c) ;
ttcol += 1 ;
}
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}
void rubout( void) {
if( disinp) {
TTputc( '\b') ;
TTputc( ' ') ;
TTputc( '\b') ;
ttcol -= 1 ;
}
}
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/* end of display.c */