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terminal.c
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terminal.c
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/*
* Terminal emulator.
*/
#include <stdio.h>
#include <stdlib.h>
#include <ctype.h>
#include <time.h>
#include <assert.h>
#include "putty.h"
#include "terminal.h"
#define poslt(p1,p2) ( (p1).y < (p2).y || ( (p1).y == (p2).y && (p1).x < (p2).x ) )
#define posle(p1,p2) ( (p1).y < (p2).y || ( (p1).y == (p2).y && (p1).x <= (p2).x ) )
#define poseq(p1,p2) ( (p1).y == (p2).y && (p1).x == (p2).x )
#define posdiff(p1,p2) ( ((p1).y - (p2).y) * (term->cols+1) + (p1).x - (p2).x )
/* Product-order comparisons for rectangular block selection. */
#define posPlt(p1,p2) ( (p1).y <= (p2).y && (p1).x < (p2).x )
#define posPle(p1,p2) ( (p1).y <= (p2).y && (p1).x <= (p2).x )
#define incpos(p) ( (p).x == term->cols ? ((p).x = 0, (p).y++, 1) : ((p).x++, 0) )
#define decpos(p) ( (p).x == 0 ? ((p).x = term->cols, (p).y--, 1) : ((p).x--, 0) )
#define VT52_PLUS
#define CL_ANSIMIN 0x0001 /* Codes in all ANSI like terminals. */
#define CL_VT100 0x0002 /* VT100 */
#define CL_VT100AVO 0x0004 /* VT100 +AVO; 132x24 (not 132x14) & attrs */
#define CL_VT102 0x0008 /* VT102 */
#define CL_VT220 0x0010 /* VT220 */
#define CL_VT320 0x0020 /* VT320 */
#define CL_VT420 0x0040 /* VT420 */
#define CL_VT510 0x0080 /* VT510, NB VT510 includes ANSI */
#define CL_VT340TEXT 0x0100 /* VT340 extensions that appear in the VT420 */
#define CL_SCOANSI 0x1000 /* SCOANSI not in ANSIMIN. */
#define CL_ANSI 0x2000 /* ANSI ECMA-48 not in the VT100..VT420 */
#define CL_OTHER 0x4000 /* Others, Xterm, linux, putty, dunno, etc */
#define TM_VT100 (CL_ANSIMIN|CL_VT100)
#define TM_VT100AVO (TM_VT100|CL_VT100AVO)
#define TM_VT102 (TM_VT100AVO|CL_VT102)
#define TM_VT220 (TM_VT102|CL_VT220)
#define TM_VTXXX (TM_VT220|CL_VT340TEXT|CL_VT510|CL_VT420|CL_VT320)
#define TM_SCOANSI (CL_ANSIMIN|CL_SCOANSI)
#define TM_PUTTY (0xFFFF)
#define UPDATE_DELAY ((TICKSPERSEC+49)/50)/* ticks to defer window update */
#define TBLINK_DELAY ((TICKSPERSEC*9+19)/20)/* ticks between text blinks*/
#define CBLINK_DELAY (CURSORBLINK) /* ticks between cursor blinks */
#define VBELL_DELAY (VBELL_TIMEOUT) /* visual bell timeout in ticks */
#define compatibility(x) \
if ( ((CL_##x)&term->compatibility_level) == 0 ) { \
term->termstate=TOPLEVEL; \
break; \
}
#define compatibility2(x,y) \
if ( ((CL_##x|CL_##y)&term->compatibility_level) == 0 ) { \
term->termstate=TOPLEVEL; \
break; \
}
#define has_compat(x) ( ((CL_##x)&term->compatibility_level) != 0 )
char *EMPTY_WINDOW_TITLE = "";
const char sco2ansicolour[] = { 0, 4, 2, 6, 1, 5, 3, 7 };
#define sel_nl_sz (sizeof(sel_nl)/sizeof(wchar_t))
const wchar_t sel_nl[] = SEL_NL;
/*
* Fetch the character at a particular position in a line array,
* for purposes of `wordtype'. The reason this isn't just a simple
* array reference is that if the character we find is UCSWIDE,
* then we must look one space further to the left.
*/
#define UCSGET(a, x) \
( (x)>0 && (a)[(x)].chr == UCSWIDE ? (a)[(x)-1].chr : (a)[(x)].chr )
/*
* Detect the various aliases of U+0020 SPACE.
*/
#define IS_SPACE_CHR(chr) \
((chr) == 0x20 || (DIRECT_CHAR(chr) && ((chr) & 0xFF) == 0x20))
/*
* Spot magic CSETs.
*/
#define CSET_OF(chr) (DIRECT_CHAR(chr)||DIRECT_FONT(chr) ? (chr)&CSET_MASK : 0)
/*
* Internal prototypes.
*/
static void resizeline(Terminal *, termline *, int);
static termline *lineptr(Terminal *, int, int, int);
static void unlineptr(termline *);
static void do_paint(Terminal *, Context, int);
static void erase_lots(Terminal *, int, int, int);
static int find_last_nonempty_line(Terminal *, tree234 *);
static void swap_screen(Terminal *, int, int, int);
static void update_sbar(Terminal *);
static void deselect(Terminal *);
static void term_print_finish(Terminal *);
static void scroll(Terminal *, int, int, int, int);
#ifdef OPTIMISE_SCROLL
static void scroll_display(Terminal *, int, int, int);
#endif /* OPTIMISE_SCROLL */
static termline *newline(Terminal *term, int cols, int bce)
{
termline *line;
int j;
line = snew(termline);
line->chars = snewn(cols, termchar);
for (j = 0; j < cols; j++)
line->chars[j] = (bce ? term->erase_char : term->basic_erase_char);
line->cols = line->size = cols;
line->lattr = LATTR_NORM;
line->temporary = FALSE;
line->cc_free = 0;
return line;
}
static void freeline(termline *line)
{
if (line) {
sfree(line->chars);
sfree(line);
}
}
static void unlineptr(termline *line)
{
if (line->temporary)
freeline(line);
}
#ifdef TERM_CC_DIAGS
/*
* Diagnostic function: verify that a termline has a correct
* combining character structure.
*
* This is a performance-intensive check, so it's no longer enabled
* by default.
*/
static void cc_check(termline *line)
{
unsigned char *flags;
int i, j;
assert(line->size >= line->cols);
flags = snewn(line->size, unsigned char);
for (i = 0; i < line->size; i++)
flags[i] = (i < line->cols);
for (i = 0; i < line->cols; i++) {
j = i;
while (line->chars[j].cc_next) {
j += line->chars[j].cc_next;
assert(j >= line->cols && j < line->size);
assert(!flags[j]);
flags[j] = TRUE;
}
}
j = line->cc_free;
if (j) {
while (1) {
assert(j >= line->cols && j < line->size);
assert(!flags[j]);
flags[j] = TRUE;
if (line->chars[j].cc_next)
j += line->chars[j].cc_next;
else
break;
}
}
j = 0;
for (i = 0; i < line->size; i++)
j += (flags[i] != 0);
assert(j == line->size);
sfree(flags);
}
#endif
/*
* Add a combining character to a character cell.
*/
static void add_cc(termline *line, int col, unsigned long chr)
{
int newcc;
assert(col >= 0 && col < line->cols);
/*
* Start by extending the cols array if the free list is empty.
*/
if (!line->cc_free) {
int n = line->size;
line->size += 16 + (line->size - line->cols) / 2;
line->chars = sresize(line->chars, line->size, termchar);
line->cc_free = n;
while (n < line->size) {
if (n+1 < line->size)
line->chars[n].cc_next = 1;
else
line->chars[n].cc_next = 0;
n++;
}
}
/*
* Now walk the cc list of the cell in question.
*/
while (line->chars[col].cc_next)
col += line->chars[col].cc_next;
/*
* `col' now points at the last cc currently in this cell; so
* we simply add another one.
*/
newcc = line->cc_free;
if (line->chars[newcc].cc_next)
line->cc_free = newcc + line->chars[newcc].cc_next;
else
line->cc_free = 0;
line->chars[newcc].cc_next = 0;
line->chars[newcc].chr = chr;
line->chars[col].cc_next = newcc - col;
#ifdef TERM_CC_DIAGS
cc_check(line);
#endif
}
/*
* Clear the combining character list in a character cell.
*/
static void clear_cc(termline *line, int col)
{
int oldfree, origcol = col;
assert(col >= 0 && col < line->cols);
if (!line->chars[col].cc_next)
return; /* nothing needs doing */
oldfree = line->cc_free;
line->cc_free = col + line->chars[col].cc_next;
while (line->chars[col].cc_next)
col += line->chars[col].cc_next;
if (oldfree)
line->chars[col].cc_next = oldfree - col;
else
line->chars[col].cc_next = 0;
line->chars[origcol].cc_next = 0;
#ifdef TERM_CC_DIAGS
cc_check(line);
#endif
}
/*
* Compare two character cells for equality. Special case required
* in do_paint() where we override what we expect the chr and attr
* fields to be.
*/
static int termchars_equal_override(termchar *a, termchar *b,
unsigned long bchr, unsigned long battr)
{
/* FULL-TERMCHAR */
if (a->chr != bchr)
return FALSE;
if ((a->attr &~ DATTR_MASK) != (battr &~ DATTR_MASK))
return FALSE;
while (a->cc_next || b->cc_next) {
if (!a->cc_next || !b->cc_next)
return FALSE; /* one cc-list ends, other does not */
a += a->cc_next;
b += b->cc_next;
if (a->chr != b->chr)
return FALSE;
}
return TRUE;
}
static int termchars_equal(termchar *a, termchar *b)
{
return termchars_equal_override(a, b, b->chr, b->attr);
}
/*
* Copy a character cell. (Requires a pointer to the destination
* termline, so as to access its free list.)
*/
static void copy_termchar(termline *destline, int x, termchar *src)
{
clear_cc(destline, x);
destline->chars[x] = *src; /* copy everything except cc-list */
destline->chars[x].cc_next = 0; /* and make sure this is zero */
while (src->cc_next) {
src += src->cc_next;
add_cc(destline, x, src->chr);
}
#ifdef TERM_CC_DIAGS
cc_check(destline);
#endif
}
/*
* Move a character cell within its termline.
*/
static void move_termchar(termline *line, termchar *dest, termchar *src)
{
/* First clear the cc list from the original char, just in case. */
clear_cc(line, dest - line->chars);
/* Move the character cell and adjust its cc_next. */
*dest = *src; /* copy everything except cc-list */
if (src->cc_next)
dest->cc_next = src->cc_next - (dest-src);
/* Ensure the original cell doesn't have a cc list. */
src->cc_next = 0;
#ifdef TERM_CC_DIAGS
cc_check(line);
#endif
}
/*
* Compress and decompress a termline into an RLE-based format for
* storing in scrollback. (Since scrollback almost never needs to
* be modified and exists in huge quantities, this is a sensible
* tradeoff, particularly since it allows us to continue adding
* features to the main termchar structure without proportionally
* bloating the terminal emulator's memory footprint unless those
* features are in constant use.)
*/
struct buf {
unsigned char *data;
int len, size;
};
static void add(struct buf *b, unsigned char c)
{
if (b->len >= b->size) {
b->size = (b->len * 3 / 2) + 512;
b->data = sresize(b->data, b->size, unsigned char);
}
b->data[b->len++] = c;
}
static int get(struct buf *b)
{
return b->data[b->len++];
}
static void makerle(struct buf *b, termline *ldata,
void (*makeliteral)(struct buf *b, termchar *c,
unsigned long *state))
{
int hdrpos, hdrsize, n, prevlen, prevpos, thislen, thispos, prev2;
termchar *c = ldata->chars;
unsigned long state = 0, oldstate;
n = ldata->cols;
hdrpos = b->len;
hdrsize = 0;
add(b, 0);
prevlen = prevpos = 0;
prev2 = FALSE;
while (n-- > 0) {
thispos = b->len;
makeliteral(b, c++, &state);
thislen = b->len - thispos;
if (thislen == prevlen &&
!memcmp(b->data + prevpos, b->data + thispos, thislen)) {
/*
* This literal precisely matches the previous one.
* Turn it into a run if it's worthwhile.
*
* With one-byte literals, it costs us two bytes to
* encode a run, plus another byte to write the header
* to resume normal output; so a three-element run is
* neutral, and anything beyond that is unconditionally
* worthwhile. With two-byte literals or more, even a
* 2-run is a win.
*/
if (thislen > 1 || prev2) {
int runpos, runlen;
/*
* It's worth encoding a run. Start at prevpos,
* unless hdrsize==0 in which case we can back up
* another one and start by overwriting hdrpos.
*/
hdrsize--; /* remove the literal at prevpos */
if (prev2) {
assert(hdrsize > 0);
hdrsize--;
prevpos -= prevlen;/* and possibly another one */
}
if (hdrsize == 0) {
assert(prevpos == hdrpos + 1);
runpos = hdrpos;
b->len = prevpos+prevlen;
} else {
memmove(b->data + prevpos+1, b->data + prevpos, prevlen);
runpos = prevpos;
b->len = prevpos+prevlen+1;
/*
* Terminate the previous run of ordinary
* literals.
*/
assert(hdrsize >= 1 && hdrsize <= 128);
b->data[hdrpos] = hdrsize - 1;
}
runlen = prev2 ? 3 : 2;
while (n > 0 && runlen < 129) {
int tmppos, tmplen;
tmppos = b->len;
oldstate = state;
makeliteral(b, c, &state);
tmplen = b->len - tmppos;
b->len = tmppos;
if (tmplen != thislen ||
memcmp(b->data + runpos+1, b->data + tmppos, tmplen)) {
state = oldstate;
break; /* run over */
}
n--, c++, runlen++;
}
assert(runlen >= 2 && runlen <= 129);
b->data[runpos] = runlen + 0x80 - 2;
hdrpos = b->len;
hdrsize = 0;
add(b, 0);
/* And ensure this run doesn't interfere with the next. */
prevlen = prevpos = 0;
prev2 = FALSE;
continue;
} else {
/*
* Just flag that the previous two literals were
* identical, in case we find a third identical one
* we want to turn into a run.
*/
prev2 = TRUE;
prevlen = thislen;
prevpos = thispos;
}
} else {
prev2 = FALSE;
prevlen = thislen;
prevpos = thispos;
}
/*
* This character isn't (yet) part of a run. Add it to
* hdrsize.
*/
hdrsize++;
if (hdrsize == 128) {
b->data[hdrpos] = hdrsize - 1;
hdrpos = b->len;
hdrsize = 0;
add(b, 0);
prevlen = prevpos = 0;
prev2 = FALSE;
}
}
/*
* Clean up.
*/
if (hdrsize > 0) {
assert(hdrsize <= 128);
b->data[hdrpos] = hdrsize - 1;
} else {
b->len = hdrpos;
}
}
static void makeliteral_chr(struct buf *b, termchar *c, unsigned long *state)
{
/*
* My encoding for characters is UTF-8-like, in that it stores
* 7-bit ASCII in one byte and uses high-bit-set bytes as
* introducers to indicate a longer sequence. However, it's
* unlike UTF-8 in that it doesn't need to be able to
* resynchronise, and therefore I don't want to waste two bits
* per byte on having recognisable continuation characters.
* Also I don't want to rule out the possibility that I may one
* day use values 0x80000000-0xFFFFFFFF for interesting
* purposes, so unlike UTF-8 I need a full 32-bit range.
* Accordingly, here is my encoding:
*
* 00000000-0000007F: 0xxxxxxx (but see below)
* 00000080-00003FFF: 10xxxxxx xxxxxxxx
* 00004000-001FFFFF: 110xxxxx xxxxxxxx xxxxxxxx
* 00200000-0FFFFFFF: 1110xxxx xxxxxxxx xxxxxxxx xxxxxxxx
* 10000000-FFFFFFFF: 11110ZZZ xxxxxxxx xxxxxxxx xxxxxxxx xxxxxxxx
*
* (`Z' is like `x' but is always going to be zero since the
* values I'm encoding don't go above 2^32. In principle the
* five-byte form of the encoding could extend to 2^35, and
* there could be six-, seven-, eight- and nine-byte forms as
* well to allow up to 64-bit values to be encoded. But that's
* completely unnecessary for these purposes!)
*
* The encoding as written above would be very simple, except
* that 7-bit ASCII can occur in several different ways in the
* terminal data; sometimes it crops up in the D800 page
* (CSET_ASCII) but at other times it's in the 0000 page (real
* Unicode). Therefore, this encoding is actually _stateful_:
* the one-byte encoding of 00-7F actually indicates `reuse the
* upper three bytes of the last character', and to encode an
* absolute value of 00-7F you need to use the two-byte form
* instead.
*/
if ((c->chr & ~0x7F) == *state) {
add(b, (unsigned char)(c->chr & 0x7F));
} else if (c->chr < 0x4000) {
add(b, (unsigned char)(((c->chr >> 8) & 0x3F) | 0x80));
add(b, (unsigned char)(c->chr & 0xFF));
} else if (c->chr < 0x200000) {
add(b, (unsigned char)(((c->chr >> 16) & 0x1F) | 0xC0));
add(b, (unsigned char)((c->chr >> 8) & 0xFF));
add(b, (unsigned char)(c->chr & 0xFF));
} else if (c->chr < 0x10000000) {
add(b, (unsigned char)(((c->chr >> 24) & 0x0F) | 0xE0));
add(b, (unsigned char)((c->chr >> 16) & 0xFF));
add(b, (unsigned char)((c->chr >> 8) & 0xFF));
add(b, (unsigned char)(c->chr & 0xFF));
} else {
add(b, 0xF0);
add(b, (unsigned char)((c->chr >> 24) & 0xFF));
add(b, (unsigned char)((c->chr >> 16) & 0xFF));
add(b, (unsigned char)((c->chr >> 8) & 0xFF));
add(b, (unsigned char)(c->chr & 0xFF));
}
*state = c->chr & ~0xFF;
}
static void makeliteral_attr(struct buf *b, termchar *c, unsigned long *state)
{
/*
* My encoding for attributes is 16-bit-granular and assumes
* that the top bit of the word is never required. I either
* store a two-byte value with the top bit clear (indicating
* just that value), or a four-byte value with the top bit set
* (indicating the same value with its top bit clear).
*
* However, first I permute the bits of the attribute value, so
* that the eight bits of colour (four in each of fg and bg)
* which are never non-zero unless xterm 256-colour mode is in
* use are placed higher up the word than everything else. This
* ensures that attribute values remain 16-bit _unless_ the
* user uses extended colour.
*/
unsigned attr, colourbits;
attr = c->attr;
assert(ATTR_BGSHIFT > ATTR_FGSHIFT);
colourbits = (attr >> (ATTR_BGSHIFT + 4)) & 0xF;
colourbits <<= 4;
colourbits |= (attr >> (ATTR_FGSHIFT + 4)) & 0xF;
attr = (((attr >> (ATTR_BGSHIFT + 8)) << (ATTR_BGSHIFT + 4)) |
(attr & ((1 << (ATTR_BGSHIFT + 4))-1)));
attr = (((attr >> (ATTR_FGSHIFT + 8)) << (ATTR_FGSHIFT + 4)) |
(attr & ((1 << (ATTR_FGSHIFT + 4))-1)));
attr |= (colourbits << (32-9));
if (attr < 0x8000) {
add(b, (unsigned char)((attr >> 8) & 0xFF));
add(b, (unsigned char)(attr & 0xFF));
} else {
add(b, (unsigned char)(((attr >> 24) & 0x7F) | 0x80));
add(b, (unsigned char)((attr >> 16) & 0xFF));
add(b, (unsigned char)((attr >> 8) & 0xFF));
add(b, (unsigned char)(attr & 0xFF));
}
}
static void makeliteral_cc(struct buf *b, termchar *c, unsigned long *state)
{
/*
* For combining characters, I just encode a bunch of ordinary
* chars using makeliteral_chr, and terminate with a \0
* character (which I know won't come up as a combining char
* itself).
*
* I don't use the stateful encoding in makeliteral_chr.
*/
unsigned long zstate;
termchar z;
while (c->cc_next) {
c += c->cc_next;
assert(c->chr != 0);
zstate = 0;
makeliteral_chr(b, c, &zstate);
}
z.chr = 0;
zstate = 0;
makeliteral_chr(b, &z, &zstate);
}
static termline *decompressline(unsigned char *data, int *bytes_used);
static unsigned char *compressline(termline *ldata)
{
struct buf buffer = { NULL, 0, 0 }, *b = &buffer;
/*
* First, store the column count, 7 bits at a time, least
* significant `digit' first, with the high bit set on all but
* the last.
*/
{
int n = ldata->cols;
while (n >= 128) {
add(b, (unsigned char)((n & 0x7F) | 0x80));
n >>= 7;
}
add(b, (unsigned char)(n));
}
/*
* Next store the lattrs; same principle.
*/
{
int n = ldata->lattr;
while (n >= 128) {
add(b, (unsigned char)((n & 0x7F) | 0x80));
n >>= 7;
}
add(b, (unsigned char)(n));
}
/*
* Now we store a sequence of separate run-length encoded
* fragments, each containing exactly as many symbols as there
* are columns in the ldata.
*
* All of these have a common basic format:
*
* - a byte 00-7F indicates that X+1 literals follow it
* - a byte 80-FF indicates that a single literal follows it
* and expects to be repeated (X-0x80)+2 times.
*
* The format of the `literals' varies between the fragments.
*/
makerle(b, ldata, makeliteral_chr);
makerle(b, ldata, makeliteral_attr);
makerle(b, ldata, makeliteral_cc);
/*
* Diagnostics: ensure that the compressed data really does
* decompress to the right thing.
*
* This is a bit performance-heavy for production code.
*/
#ifdef TERM_CC_DIAGS
#ifndef CHECK_SB_COMPRESSION
{
int dused;
termline *dcl;
int i;
#ifdef DIAGNOSTIC_SB_COMPRESSION
for (i = 0; i < b->len; i++) {
printf(" %02x ", b->data[i]);
}
printf("\n");
#endif
dcl = decompressline(b->data, &dused);
assert(b->len == dused);
assert(ldata->cols == dcl->cols);
assert(ldata->lattr == dcl->lattr);
for (i = 0; i < ldata->cols; i++)
assert(termchars_equal(&ldata->chars[i], &dcl->chars[i]));
#ifdef DIAGNOSTIC_SB_COMPRESSION
printf("%d cols (%d bytes) -> %d bytes (factor of %g)\n",
ldata->cols, 4 * ldata->cols, dused,
(double)dused / (4 * ldata->cols));
#endif
freeline(dcl);
}
#endif
#endif /* TERM_CC_DIAGS */
/*
* Trim the allocated memory so we don't waste any, and return.
*/
return sresize(b->data, b->len, unsigned char);
}
static void readrle(struct buf *b, termline *ldata,
void (*readliteral)(struct buf *b, termchar *c,
termline *ldata, unsigned long *state))
{
int n = 0;
unsigned long state = 0;
while (n < ldata->cols) {
int hdr = get(b);
if (hdr >= 0x80) {
/* A run. */
int pos = b->len, count = hdr + 2 - 0x80;
while (count--) {
assert(n < ldata->cols);
b->len = pos;
readliteral(b, ldata->chars + n, ldata, &state);
n++;
}
} else {
/* Just a sequence of consecutive literals. */
int count = hdr + 1;
while (count--) {
assert(n < ldata->cols);
readliteral(b, ldata->chars + n, ldata, &state);
n++;
}
}
}
assert(n == ldata->cols);
}
static void readliteral_chr(struct buf *b, termchar *c, termline *ldata,
unsigned long *state)
{
int byte;
/*
* 00000000-0000007F: 0xxxxxxx
* 00000080-00003FFF: 10xxxxxx xxxxxxxx
* 00004000-001FFFFF: 110xxxxx xxxxxxxx xxxxxxxx
* 00200000-0FFFFFFF: 1110xxxx xxxxxxxx xxxxxxxx xxxxxxxx
* 10000000-FFFFFFFF: 11110ZZZ xxxxxxxx xxxxxxxx xxxxxxxx xxxxxxxx
*/
byte = get(b);
if (byte < 0x80) {
c->chr = byte | *state;
} else if (byte < 0xC0) {
c->chr = (byte &~ 0xC0) << 8;
c->chr |= get(b);
} else if (byte < 0xE0) {
c->chr = (byte &~ 0xE0) << 16;
c->chr |= get(b) << 8;
c->chr |= get(b);
} else if (byte < 0xF0) {
c->chr = (byte &~ 0xF0) << 24;
c->chr |= get(b) << 16;
c->chr |= get(b) << 8;
c->chr |= get(b);
} else {
assert(byte == 0xF0);
c->chr = get(b) << 24;
c->chr |= get(b) << 16;
c->chr |= get(b) << 8;
c->chr |= get(b);
}
*state = c->chr & ~0xFF;
}
static void readliteral_attr(struct buf *b, termchar *c, termline *ldata,
unsigned long *state)
{
unsigned val, attr, colourbits;
val = get(b) << 8;
val |= get(b);
if (val >= 0x8000) {
val &= ~0x8000;
val <<= 16;
val |= get(b) << 8;
val |= get(b);
}
colourbits = (val >> (32-9)) & 0xFF;
attr = (val & ((1<<(32-9))-1));
attr = (((attr >> (ATTR_FGSHIFT + 4)) << (ATTR_FGSHIFT + 8)) |
(attr & ((1 << (ATTR_FGSHIFT + 4))-1)));
attr = (((attr >> (ATTR_BGSHIFT + 4)) << (ATTR_BGSHIFT + 8)) |
(attr & ((1 << (ATTR_BGSHIFT + 4))-1)));
attr |= (colourbits >> 4) << (ATTR_BGSHIFT + 4);
attr |= (colourbits & 0xF) << (ATTR_FGSHIFT + 4);
c->attr = attr;
}
static void readliteral_cc(struct buf *b, termchar *c, termline *ldata,
unsigned long *state)
{
termchar n;
unsigned long zstate;
int x = c - ldata->chars;
c->cc_next = 0;
while (1) {
zstate = 0;
readliteral_chr(b, &n, ldata, &zstate);
if (!n.chr)
break;
add_cc(ldata, x, n.chr);
}
}
static termline *decompressline(unsigned char *data, int *bytes_used)
{
int ncols, byte, shift;
struct buf buffer, *b = &buffer;
termline *ldata;
b->data = data;
b->len = 0;
/*
* First read in the column count.
*/
ncols = shift = 0;
do {
byte = get(b);
ncols |= (byte & 0x7F) << shift;
shift += 7;
} while (byte & 0x80);
/*
* Now create the output termline.
*/
ldata = snew(termline);
ldata->chars = snewn(ncols, termchar);
ldata->cols = ldata->size = ncols;
ldata->temporary = TRUE;
ldata->cc_free = 0;
/*
* We must set all the cc pointers in ldata->chars to 0 right
* now, so that cc diagnostics that verify the integrity of the
* whole line will make sense while we're in the middle of
* building it up.
*/
{
int i;
for (i = 0; i < ldata->cols; i++)
ldata->chars[i].cc_next = 0;
}
/*
* Now read in the lattr.
*/
ldata->lattr = shift = 0;
do {
byte = get(b);
ldata->lattr |= (byte & 0x7F) << shift;
shift += 7;
} while (byte & 0x80);
/*
* Now we read in each of the RLE streams in turn.
*/
readrle(b, ldata, readliteral_chr);
readrle(b, ldata, readliteral_attr);
readrle(b, ldata, readliteral_cc);
/* Return the number of bytes read, for diagnostic purposes. */
if (bytes_used)
*bytes_used = b->len;
return ldata;
}
/*
* Resize a line to make it `cols' columns wide.
*/
static void resizeline(Terminal *term, termline *line, int cols)
{
int i, oldcols;
if (line->cols != cols) {
oldcols = line->cols;
/*
* This line is the wrong length, which probably means it
* hasn't been accessed since a resize. Resize it now.
*
* First, go through all the characters that will be thrown
* out in the resize (if we're shrinking the line) and
* return their cc lists to the cc free list.
*/
for (i = cols; i < oldcols; i++)
clear_cc(line, i);
/*
* If we're shrinking the line, we now bodily move the
* entire cc section from where it started to where it now
* needs to be. (We have to do this before the resize, so
* that the data we're copying is still there. However, if
* we're expanding, we have to wait until _after_ the
* resize so that the space we're copying into is there.)
*/
if (cols < oldcols)
memmove(line->chars + cols, line->chars + oldcols,
(line->size - line->cols) * TSIZE);
/*
* Now do the actual resize, leaving the _same_ amount of
* cc space as there was to begin with.
*/
line->size += cols - oldcols;
line->chars = sresize(line->chars, line->size, TTYPE);
line->cols = cols;
/*
* If we're expanding the line, _now_ we move the cc
* section.
*/
if (cols > oldcols)
memmove(line->chars + cols, line->chars + oldcols,
(line->size - line->cols) * TSIZE);
/*
* Go through what's left of the original line, and adjust
* the first cc_next pointer in each list. (All the
* subsequent ones are still valid because they are
* relative offsets within the cc block.) Also do the same
* to the head of the cc_free list.
*/
for (i = 0; i < oldcols && i < cols; i++)
if (line->chars[i].cc_next)
line->chars[i].cc_next += cols - oldcols;
if (line->cc_free)
line->cc_free += cols - oldcols;
/*
* And finally fill in the new space with erase chars. (We
* don't have to worry about cc lists here, because we
* _know_ the erase char doesn't have one.)
*/
for (i = oldcols; i < cols; i++)
line->chars[i] = term->basic_erase_char;
#ifdef TERM_CC_DIAGS
cc_check(line);
#endif
}
}
/*
* Get the number of lines in the scrollback.
*/
static int sblines(Terminal *term)
{
int sblines = count234(term->scrollback);
if (term->cfg.erase_to_scrollback &&
term->alt_which && term->alt_screen) {
sblines += term->alt_sblines;
}
return sblines;
}
/*
* Retrieve a line of the screen or of the scrollback, according to