mandoc/term.c - diff

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Diff for /mandoc/term.c between version 1.129 and 1.179

version 1.129, 2010/03/23 12:42:22

version 1.179, 2011/03/17 08:49:34

Line 1

/* $Id$ */

* Permission to use, copy, modify, and distribute this software for any

* purpose with or without fee is hereby granted, provided that the above

Line 22

Line 23

#include <assert.h>

#include <ctype.h>

#include <stdint.h>

#include <stdio.h>

#include <stdlib.h>

#include <string.h>

#include <time.h>

#include "mandoc.h"

#include "chars.h"

#include "out.h"

#include "term.h"

#include "man.h"

#include "mdoc.h"

#include "main.h"

static struct termp *term_alloc(enum termenc);

static void spec(struct termp *, enum roffdeco,

static void term_free(struct termp *);

const char *, size_t);

static void spec(struct termp *, const char *, size_t);

static void res(struct termp *, const char *, size_t);

static void buffera(struct termp *, const char *, size_t);

static void bufferc(struct termp *, char);

static void adjbuf(struct termp *p, size_t);

static void encode(struct termp *, const char *, size_t);

void *

void

ascii_alloc(void)

term_free(struct termp *p)

{

return(term_alloc(TERMENC_ASCII));

if (p->buf)

free(p->buf);

if (p->symtab)

chars_free(p->symtab);

free(p);

}

void

terminal_free(void *arg)

term_begin(struct termp *p, term_margin head,

term_margin foot, const void *arg)

{

term_free((struct termp *)arg);

p->headf = head;

p->footf = foot;

p->argf = arg;

(*p->begin)(p);

}

static void

void

term_free(struct termp *p)

term_end(struct termp *p)

{

if (p->buf)

(*p->end)(p);

free(p->buf);

if (p->symtab)

chars_free(p->symtab);

free(p);

}

static struct termp *

struct termp *

term_alloc(enum termenc enc)

{

struct termp *p;

p = calloc(1, sizeof(struct termp));

p = mandoc_calloc(1, sizeof(struct termp));

if (NULL == p) {

perror(NULL);

exit(EXIT_FAILURE);

}

p->enc = enc;

return(p);

}

Line 92 term_alloc(enum termenc enc)

Line 90 term_alloc(enum termenc enc)

* Flush a line of text. A "line" is loosely defined as being something

* that should be followed by a newline, regardless of whether it's

* broken apart by newlines getting there. A line can also be a

* fragment of a columnar list.

* fragment of a columnar list (`Bl -tag' or `Bl -column'), which does

* not have a trailing newline.

* Specifically, a line is whatever's in p->buf of length p->col, which

* The following flags may be specified:

* is zeroed after this function returns.

* The usage of termp:flags is as follows:

* - TERMP_NOLPAD: when beginning to write the line, don't left-pad the

* offset value. This is useful when doing columnar lists where the

* prior column has right-padded.

Line 131 term_flushln(struct termp *p)

Line 127 term_flushln(struct termp *p)

int i; /* current input position in p->buf */

size_t vis; /* current visual position on output */

size_t vbl; /* number of blanks to prepend to output */

size_t vsz; /* visual characters to write to output */

size_t vend; /* end of word visual position on output */

size_t bp; /* visual right border position */

int j; /* temporary loop index */

size_t dv; /* temporary for visual pos calculations */

size_t maxvis, mmax;

int j; /* temporary loop index for p->buf */

int jhy; /* last hyph before overflow w/r/t j */

size_t maxvis; /* output position of visible boundary */

size_t mmax; /* used in calculating bp */

* First, establish the maximum columns of "visible" content.

Line 142 term_flushln(struct termp *p)

Line 141 term_flushln(struct termp *p)

* an indentation, but can be, for tagged lists or columns, a

* small set of values.

assert (p->rmargin >= p->offset);

dv = p->rmargin - p->offset;

maxvis = (int)dv > p->overstep ? dv - (size_t)p->overstep : 0;

dv = p->maxrmargin - p->offset;

mmax = (int)dv > p->overstep ? dv - (size_t)p->overstep : 0;

assert(p->offset < p->rmargin);

maxvis = (int)(p->rmargin - p->offset) - p->overstep < 0 ?

/* LINTED */

0 : p->rmargin - p->offset - p->overstep;

mmax = (int)(p->maxrmargin - p->offset) - p->overstep < 0 ?

/* LINTED */

0 : p->maxrmargin - p->offset - p->overstep;

bp = TERMP_NOBREAK & p->flags ? mmax : maxvis;

* FIXME: if bp is zero, we still output the first word before

* breaking the line.

vis = 0;

* If in the standard case (left-justified), then begin with our

* Indent the first line of a paragraph.

* indentation, otherwise (columns, etc.) just start spitting

* out text.

vbl = p->flags & TERMP_NOLPAD ? (size_t)0 : p->offset;

if ( ! (p->flags & TERMP_NOLPAD))

vis = vend = 0;

/* LINTED */

i = 0;

for (j = 0; j < (int)p->offset; j++)

putchar(' ');

for (i = 0; i < (int)p->col; i++) {

while (i < (int)p->col) {

* Handle literal tab characters: collapse all

* subsequent tabs into a single huge set of spaces.

while (i < (int)p->col && '\t' == p->buf[i]) {

vend = (vis / p->tabwidth + 1) * p->tabwidth;

vbl += vend - vis;

vis = vend;

i++;

}

* Count up visible word characters. Control sequences

* (starting with the CSI) aren't counted. A space

* generates a non-printing word, which is valid (the

* space is printed according to regular spacing rules).

/* LINTED */

for (j = i, jhy = 0; j < (int)p->col; j++) {

for (j = i, vsz = 0; j < (int)p->col; j++) {

if ((j && ' ' == p->buf[j]) || '\t' == p->buf[j])

if (j && ' ' == p->buf[j])

break;

else if (8 == p->buf[j])

vsz--;

/* Back over the the last printed character. */

else

if (8 == p->buf[j]) {

vsz++;

assert(j);

vend -= (*p->width)(p, p->buf[j - 1]);

continue;

}

/* Regular word. */

/* Break at the hyphen point if we overrun. */

if (vend > vis && vend < bp &&

ASCII_HYPH == p->buf[j])

jhy = j;

vend += (*p->width)(p, p->buf[j]);

}

* Choose the number of blanks to prepend: no blank at the

* beginning of a line, one between words -- but do not

* actually write them yet.

vbl = (size_t)(0 == vis ? 0 : 1);

* Find out whether we would exceed the right margin.

* If so, break to the next line. (TODO: hyphenate)

* If so, break to the next line.

* Otherwise, write the chosen number of blanks now.

if (vis && vis + vbl + vsz > bp) {

if (vend > bp && 0 == jhy && vis > 0) {

putchar('\n');

vend -= vis;

(*p->endline)(p);

if (TERMP_NOBREAK & p->flags) {

for (j = 0; j < (int)p->rmargin; j++)

p->viscol = p->rmargin;

putchar(' ');

(*p->advance)(p, p->rmargin);

vis = p->rmargin - p->offset;

vend += p->rmargin - p->offset;

} else {

for (j = 0; j < (int)p->offset; j++)

p->viscol = 0;

putchar(' ');

vbl = p->offset;

vis = 0;

}

/* Remove the p->overstep width. */

bp += (int)/* LINTED */

p->overstep;

bp += (size_t)p->overstep;

p->overstep = 0;

} else {

for (j = 0; j < (int)vbl; j++)

putchar(' ');

vis += vbl;

}

/* Write out the [remaining] word. */

* Finally, write out the word.

for ( ; i < (int)p->col; i++) {

if (' ' == p->buf[i])

if (vend > bp && jhy > 0 && i > jhy)

break;

if ('\t' == p->buf[i])

break;

if (' ' == p->buf[i]) {

j = i;

while (' ' == p->buf[i])

i++;

dv = (size_t)(i - j) * (*p->width)(p, ' ');

vbl += dv;

vend += dv;

break;

}

if (ASCII_NBRSP == p->buf[i]) {

vbl += (*p->width)(p, ' ');

continue;

}

/* The unit sep. is a non-breaking space. */

if (31 == p->buf[i])

* Now we definitely know there will be

putchar(' ');

* printable characters to output,

else

* so write preceding white space now.

putchar(p->buf[i]);

if (vbl) {

(*p->advance)(p, vbl);

p->viscol += vbl;

vbl = 0;

}

if (ASCII_HYPH == p->buf[i]) {

(*p->letter)(p, '-');

p->viscol += (*p->width)(p, '-');

} else {

(*p->letter)(p, p->buf[i]);

p->viscol += (*p->width)(p, p->buf[i]);

}

vis += vsz;

vis = vend;

}

* If there was trailing white space, it was not printed;

* so reset the cursor position accordingly.

vis -= vbl;

p->col = 0;

p->overstep = 0;

if ( ! (TERMP_NOBREAK & p->flags)) {

putchar('\n');

p->viscol = 0;

(*p->endline)(p);

return;

}

if (TERMP_HANG & p->flags) {

/* We need one blank after the tag. */

p->overstep = /* LINTED */

p->overstep = (int)(vis - maxvis + (*p->width)(p, ' '));

vis - maxvis + 1;

* Behave exactly the same way as groff:

Line 264 term_flushln(struct termp *p)

Line 291 term_flushln(struct termp *p)

if (p->overstep >= -1) {

assert((int)maxvis + p->overstep >= 0);

/* LINTED */

maxvis += (size_t)p->overstep;

maxvis += p->overstep;

} else

p->overstep = 0;

Line 273 term_flushln(struct termp *p)

Line 299 term_flushln(struct termp *p)

return;

/* Right-pad. */

if (maxvis > vis + /* LINTED */

if (maxvis > vis +

((TERMP_TWOSPACE & p->flags) ? 1 : 0))

((TERMP_TWOSPACE & p->flags) ? (*p->width)(p, ' ') : 0)) {

for ( ; vis < maxvis; vis++)

p->viscol += maxvis - vis;

putchar(' ');

(*p->advance)(p, maxvis - vis);

else { /* ...or newline break. */

vis += (maxvis - vis);

putchar('\n');

} else { /* ...or newline break. */

for (i = 0; i < (int)p->rmargin; i++)

(*p->endline)(p);

putchar(' ');

p->viscol = p->rmargin;

(*p->advance)(p, p->rmargin);

}

Line 295 term_newln(struct termp *p)

Line 322 term_newln(struct termp *p)

{

p->flags |= TERMP_NOSPACE;

if (0 == p->col) {

if (0 == p->col && 0 == p->viscol) {

p->flags &= ~TERMP_NOLPAD;

return;

}

Line 315 term_vspace(struct termp *p)

Line 342 term_vspace(struct termp *p)

{

term_newln(p);

putchar('\n');

p->viscol = 0;

(*p->endline)(p);

}

static void

spec(struct termp *p, const char *word, size_t len)

numbered(struct termp *p, const char *word, size_t len)

{

const char *rhs;

rhs = chars_num2char(word, len);

if (rhs)

encode(p, rhs, 1);

}

static void

spec(struct termp *p, enum roffdeco d, const char *word, size_t len)

{

const char *rhs;

size_t sz;

rhs = chars_a2ascii(p->symtab, word, len, &sz);

rhs = chars_spec2str(p->symtab, word, len, &sz);

if (rhs)

encode(p, rhs, sz);

else if (DECO_SSPECIAL == d)

encode(p, word, len);

}

Line 337 res(struct termp *p, const char *word, size_t len)

Line 378 res(struct termp *p, const char *word, size_t len)

const char *rhs;

size_t sz;

rhs = chars_a2res(p->symtab, word, len, &sz);

rhs = chars_res2str(p->symtab, word, len, &sz);

if (rhs)

encode(p, rhs, sz);

}

Line 417 void

Line 458 void

term_word(struct termp *p, const char *word)

{

const char *sv, *seq;

int sz;

size_t ssz;

enum roffdeco deco;

Line 440 term_word(struct termp *p, const char *word)

Line 480 term_word(struct termp *p, const char *word)

case(')'):

/* FALLTHROUGH */

case(']'):

/* FALLTHROUGH */

case('}'):

if ( ! (TERMP_IGNDELIM & p->flags))

p->flags |= TERMP_NOSPACE;

break;

Line 449 term_word(struct termp *p, const char *word)

Line 487 term_word(struct termp *p, const char *word)

break;

}

if ( ! (TERMP_NOSPACE & p->flags))

if ( ! (TERMP_NOSPACE & p->flags)) {

bufferc(p, ' ');

if ( ! (TERMP_KEEP & p->flags)) {

if (TERMP_PREKEEP & p->flags)

p->flags |= TERMP_KEEP;

bufferc(p, ' ');

if (TERMP_SENTENCE & p->flags)

bufferc(p, ' ');

} else

bufferc(p, ASCII_NBRSP);

}

if ( ! (p->flags & TERMP_NONOSPACE))

p->flags &= ~TERMP_NOSPACE;

else

p->flags |= TERMP_NOSPACE;

/* FIXME: use strcspn. */

p->flags &= ~(TERMP_SENTENCE | TERMP_IGNDELIM);

while (*word) {

if ('\\' != *word) {

if ((ssz = strcspn(word, "\\")) > 0)

encode(p, word, 1);

encode(p, word, ssz);

word++;

word += (int)ssz;

if ('\\' != *word)

continue;

}

seq = ++word;

sz = a2roffdeco(&deco, &seq, &ssz);

word += a2roffdeco(&deco, &seq, &ssz);

switch (deco) {

case (DECO_NUMBERED):

numbered(p, seq, ssz);

break;

case (DECO_RESERVED):

res(p, seq, ssz);

break;

case (DECO_SPECIAL):

spec(p, seq, ssz);

/* FALLTHROUGH */

case (DECO_SSPECIAL):

spec(p, deco, seq, ssz);

break;

case (DECO_BOLD):

term_fontrepl(p, TERMFONT_BOLD);

Line 490 term_word(struct termp *p, const char *word)

Line 544 term_word(struct termp *p, const char *word)

break;

}

word += sz;

if (DECO_NOSPACE == deco && '\0' == *word)

p->flags |= TERMP_NOSPACE;

}

if (sv[0] && 0 == sv[1])

* Note that we don't process the pipe: the parser sees it as

* punctuation, but we don't in terms of typography.

if (sv[0] && '\0' == sv[1])

switch (sv[0]) {

case('('):

/* FALLTHROUGH */

case('['):

/* FALLTHROUGH */

case('{'):

p->flags |= TERMP_NOSPACE;

break;

default:

Line 519 adjbuf(struct termp *p, size_t sz)

Line 574 adjbuf(struct termp *p, size_t sz)

while (sz >= p->maxcols)

p->maxcols <<= 2;

p->buf = realloc(p->buf, p->maxcols);

p->buf = mandoc_realloc(p->buf, p->maxcols);

if (NULL == p->buf) {

perror(NULL);

exit(EXIT_FAILURE);

}

static void

buffera(struct termp *p, const char *word, size_t sz)

{

if (p->col + sz >= p->maxcols)

adjbuf(p, p->col + sz);

memcpy(&p->buf[(int)p->col], word, sz);

p->col += sz;

}

static void

bufferc(struct termp *p, char c)

{

Line 563 encode(struct termp *p, const char *word, size_t sz)

Line 602 encode(struct termp *p, const char *word, size_t sz)

if (TERMFONT_NONE == (f = term_fonttop(p))) {

buffera(p, word, sz);

if (p->col + sz >= p->maxcols)

adjbuf(p, p->col + sz);

memcpy(&p->buf[(int)p->col], word, sz);

p->col += sz;

return;

}

/* Pre-buffer, assuming worst-case. */

if (p->col + 1 + (sz * 3) >= p->maxcols)

adjbuf(p, p->col + 1 + (sz * 3));

for (i = 0; i < (int)sz; i++) {

if ( ! isgraph((u_char)word[i])) {

bufferc(p, word[i]);

p->buf[(int)p->col++] = word[i];

continue;

}

if (TERMFONT_UNDER == f)

bufferc(p, '_');

p->buf[(int)p->col++] = '_';

else

bufferc(p, word[i]);

p->buf[(int)p->col++] = word[i];

bufferc(p, 8);

p->buf[(int)p->col++] = 8;

bufferc(p, word[i]);

p->buf[(int)p->col++] = word[i];

}

size_t

term_vspan(const struct roffsu *su)

term_len(const struct termp *p, size_t sz)

{

return((*p->width)(p, ' ') * sz);

}

size_t

term_strlen(const struct termp *p, const char *cp)

{

size_t sz, ssz, rsz, i;

enum roffdeco d;

const char *seq, *rhs;

for (sz = 0; '\0' != *cp; )

* Account for escaped sequences within string length

* calculations. This follows the logic in term_word()

* as we must calculate the width of produced strings.

if ('\\' == *cp) {

seq = ++cp;

cp += a2roffdeco(&d, &seq, &ssz);

switch (d) {

case (DECO_RESERVED):

rhs = chars_res2str

(p->symtab, seq, ssz, &rsz);

break;

case (DECO_SPECIAL):

/* FALLTHROUGH */

case (DECO_SSPECIAL):

rhs = chars_spec2str

(p->symtab, seq, ssz, &rsz);

/* Allow for one-char escapes. */

if (DECO_SSPECIAL != d || rhs)

break;

rhs = seq;

rsz = ssz;

break;

default:

rhs = NULL;

break;

}

if (rhs)

for (i = 0; i < rsz; i++)

sz += (*p->width)(p, *rhs++);

} else if (ASCII_NBRSP == *cp) {

sz += (*p->width)(p, ' ');

cp++;

} else if (ASCII_HYPH == *cp) {

sz += (*p->width)(p, '-');

cp++;

} else

sz += (*p->width)(p, *cp++);

return(sz);

}

/* ARGSUSED */

size_t

term_vspan(const struct termp *p, const struct roffsu *su)

{

double r;

switch (su->unit) {

Line 621 term_vspan(const struct roffsu *su)

Line 733 term_vspan(const struct roffsu *su)

size_t

term_hspan(const struct roffsu *su)

term_hspan(const struct termp *p, const struct roffsu *su)

{

double r;

double v;

/* XXX: CM, IN, and PT are approximations. */

v = ((*p->hspan)(p, su));

if (v < 0.0)

switch (su->unit) {

v = 0.0;

case (SCALE_CM):

return((size_t) /* LINTED */

r = 4 * su->scale;

v);

break;

case (SCALE_IN):

/* XXX: this is an approximation. */

r = 10 * su->scale;

break;

case (SCALE_PC):

r = (10 * su->scale) / 6;

break;

case (SCALE_PT):

r = (10 * su->scale) / 72;

break;

case (SCALE_MM):

r = su->scale / 1000; /* FIXME: double-check. */

break;

case (SCALE_VS):

r = su->scale * 2 - 1; /* FIXME: double-check. */

break;

default:

r = su->scale;

break;

}

if (r < 0.0)

r = 0.0;

return((size_t)/* LINTED */

r);

}

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