mandoc/macro.c - diff

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Diff for /mandoc/Attic/macro.c between version 1.43 and 1.45

version 1.43, 2009/01/19 17:51:32

version 1.45, 2009/01/20 13:05:28

Line 25

#include <time.h>

#endif

* This has scanning/parsing routines, each of which extract a macro and

* its arguments and parameters, then know how to progress to the next

* macro. Macros are parsed according as follows:

* ELEMENT: TEXT | epsilon

* BLOCK: HEAD PUNCT BODY PUNCT BLOCK_TAIL PUNCT

* BLOCK_TAIL: TAIL | epsilon

* HEAD: ELEMENT | TEXT | BLOCK | epsilon

* BODY: ELEMENT | TEXT | BLOCK | epsilon

* TAIL: TEXT | epsilon

* PUNCT: TEXT (delimiters) | epsilon

* These are arranged into a parse tree, an example of which follows:

* ROOT

* BLOCK (.Sh)

* HEAD

* TEXT (`NAME')

* BODY

* ELEMENT (.Nm)

* TEXT (`mdocml')

* ELEMENT (.Nd)

* TEXT (`mdoc macro compiler')

* BLOCK (.Op)

* HEAD

* ELEMENT (.Fl)

* TEXT (`v')

* BLOCK (.Op)

* HEAD

* ELEMENT (.Fl)

* TEXT (`v')

* ELEMENT (.Fl)

* TEXT (`W')

* ELEMENT (.Ns)

* ELEMENT (.Ar)

* TEXT (`err...')

* These types are always per-line except for block bodies, which may

* span multiple lines. Macros are assigned a parsing routine, which

* corresponds to the type, in the mdoc_macros table.

* Note that types are general: there can be several parsing routines

* corresponding to a single type. The macro_text function, for

* example, parses an ELEMENT type (see the function definition for

* details) that may be interrupted by further macros; the

* macro_constant function, on the other hand, parses an ELEMENT type

* spanning a single line.

#include "private.h"

/* FIXME: maxlineargs should be per LINE, no per TOKEN. */

static int rewind_alt(int);

static int rewind_dohalt(int, enum mdoc_type,

const struct mdoc_node *);

#define REWIND_REWIND (1 << 0)

#define REWIND_NOHALT (1 << 1)

#define REWIND_HALT (1 << 2)

static int rewind_dohalt(int, enum mdoc_type,

const struct mdoc_node *);

static int rewind_alt(int);

static int rewind_dobreak(int, const struct mdoc_node *);

static int rewind_elem(struct mdoc *, int);

static int rewind_impblock(struct mdoc *, int, int, int);

static int rewind_expblock(struct mdoc *, int, int, int);

Line 158 rewind_dohalt(int tok, enum mdoc_type type, const stru

Line 204 rewind_dohalt(int tok, enum mdoc_type type, const stru

case (MDOC_Qq):

/* FALLTHROUGH */

case (MDOC_Sq):

assert(MDOC_BODY != type);

assert(MDOC_HEAD != type);

assert(MDOC_TAIL != type);

if (type == p->type && tok == p->tok)

return(REWIND_REWIND);

Line 412 append_delims(struct mdoc *mdoc, int line, int *pos, c

Line 458 append_delims(struct mdoc *mdoc, int line, int *pos, c

}

* Close out an explicit scope. This optionally parses a TAIL type with

* a set number of TEXT children.

int

macro_scoped_close(MACRO_PROT_ARGS)

{

Line 497 macro_scoped_close(MACRO_PROT_ARGS)

Line 547 macro_scoped_close(MACRO_PROT_ARGS)

}

* A general text macro. This is a complex case because of punctuation.

* If a text macro is followed by words, then punctuation, the macro is

* "stopped" and "reopened" following the punctuation. Thus, the

* following arises:

* .Fl a ; b

* ELEMENT (.Fl)

* TEXT (`a')

* TEXT (`;')

* ELEMENT (.Fl)

* TEXT (`b')

* This must handle the following situations:

* .Fl Ar b ; ;

* ELEMENT (.Fl)

* ELEMENT (.Ar)

* TEXT (`b')

* TEXT (`;')

int

macro_text(MACRO_PROT_ARGS)

{

int la, lastpunct, c, fl, argc;

int la, lastpunct, c, w, fl, argc;

struct mdoc_arg argv[MDOC_LINEARG_MAX];

char *p;

Line 543 macro_text(MACRO_PROT_ARGS)

Line 617 macro_text(MACRO_PROT_ARGS)

lastpunct = 0;

for (;;) {

la = *pos;

c = mdoc_args(mdoc, line, pos, buf, fl, &p);

w = mdoc_args(mdoc, line, pos, buf, fl, &p);

if (ARGS_ERROR == c) {

if (ARGS_ERROR == w) {

mdoc_argv_free(argc, argv);

return(0);

}

if (ARGS_EOLN == c)

if (ARGS_EOLN == w)

break;

if (ARGS_PUNCT == c)

if (ARGS_PUNCT == w)

break;

if (-1 == (c = lookup(mdoc, line, la, tok, p)))

c = ARGS_QWORD == w ? MDOC_MAX :

return(0);

lookup(mdoc, line, la, tok, p);

else if (MDOC_MAX != c) {

if (MDOC_MAX != c && -1 != c) {

if (0 == lastpunct && ! rewind_elem(mdoc, tok)) {

mdoc_argv_free(argc, argv);

return(0);

}

mdoc_argv_free(argc, argv);

c = mdoc_macro(mdoc, c, line, la, pos, buf);

if (0 == c)

return(0);

if (ppos > 1)

return(1);

return(append_delims(mdoc, line, pos, buf));

} else if (-1 == c) {

mdoc_argv_free(argc, argv);

return(0);

}

if (mdoc_isdelim(p)) {

if (ARGS_QWORD != w && mdoc_isdelim(p)) {

if (0 == lastpunct && ! rewind_elem(mdoc, tok)) {

mdoc_argv_free(argc, argv);

return(0);

Line 603 macro_text(MACRO_PROT_ARGS)

Line 680 macro_text(MACRO_PROT_ARGS)

}

* Handle explicit-scope (having a different closure token) and implicit

* scope (closing out prior scopes when re-invoked) macros. These

* constitute the BLOCK type and usually span multiple lines. These

* always have HEAD and sometimes have BODY types. In the multi-line

* case:

* .Bd -ragged

* Text.

* .Fl macro

* Another.

* .Ed

* BLOCK (.Bd)

* HEAD

* BODY

* TEXT (`Text.')

* ELEMENT (.Fl)

* TEXT (`macro')

* TEXT (`Another.')

* Note that the `.It' macro, possibly the most difficult (as it has

* embedded scope, etc.) is handled by this routine.

int

macro_scoped(MACRO_PROT_ARGS)

{

Line 704 macro_scoped(MACRO_PROT_ARGS)

Line 805 macro_scoped(MACRO_PROT_ARGS)

}

* This handles a case of implicitly-scoped macro (BLOCK) limited to a

* single line. Instead of being closed out by a subsequent call to

* another macro, the scope is closed at the end of line. These don't

* have BODY or TAIL types. Notice that the punctuation falls outside

* of the HEAD type.

* .Qq a Fl b Ar d ; ;

* BLOCK (Qq)

* HEAD

* TEXT (`a')

* ELEMENT (.Fl)

* TEXT (`b')

* ELEMENT (.Ar)

* TEXT (`d')

* TEXT (`;')

int

macro_scoped_line(MACRO_PROT_ARGS)

{

Line 716 macro_scoped_line(MACRO_PROT_ARGS)

Line 836 macro_scoped_line(MACRO_PROT_ARGS)

if ( ! mdoc_head_alloc(mdoc, line, ppos, tok))

return(0);

mdoc->next = MDOC_NEXT_SIBLING;

if ( ! mdoc_body_alloc(mdoc, line, ppos, tok))

return(0);

mdoc->next = MDOC_NEXT_CHILD;

/* XXX - no known argument macros. */

Line 747 macro_scoped_line(MACRO_PROT_ARGS)

Line 870 macro_scoped_line(MACRO_PROT_ARGS)

}

if (1 == ppos) {

if ( ! rewind_subblock(MDOC_HEAD, mdoc, tok, line, ppos))

if ( ! rewind_subblock(MDOC_BODY, mdoc, tok, line, ppos))

return(0);

if ( ! append_delims(mdoc, line, pos, buf))

return(0);

} else if ( ! rewind_subblock(MDOC_HEAD, mdoc, tok, line, ppos))

} else if ( ! rewind_subblock(MDOC_BODY, mdoc, tok, line, ppos))

return(0);

return(rewind_impblock(mdoc, tok, line, ppos));

}

* A constant-scoped macro is like a simple-scoped macro (mdoc_scoped)

* except that it doesn't handle implicit scopes and explicit ones have

* a fixed number of TEXT children to the BODY.

* .Fl a So b Sc ;

* ELEMENT (.Fl)

* TEXT (`a')

* BLOCK (.So)

* HEAD

* BODY

* TEXT (`b')

* TEXT (';')

int

macro_constant_scoped(MACRO_PROT_ARGS)

{

Line 856 macro_constant_scoped(MACRO_PROT_ARGS)

Line 994 macro_constant_scoped(MACRO_PROT_ARGS)

}

* A delimited constant is very similar to the macros parsed by

* macro_text except that, in the event of punctuation, the macro isn't

* "re-opened" as it is in macro_text. Also, these macros have a fixed

* number of parameters.

* .Fl a No b

* ELEMENT (.Fl)

* TEXT (`a')

* ELEMENT (.No)

* TEXT (`b')

int

macro_constant_delimited(MACRO_PROT_ARGS)

{

Line 958 macro_constant_delimited(MACRO_PROT_ARGS)

Line 1109 macro_constant_delimited(MACRO_PROT_ARGS)

}

* A constant macro is the simplest classification. It spans an entire

* line.

int

macro_constant(MACRO_PROT_ARGS)

{

int c, lastarg, argc, fl;

int c, w, la, argc, fl;

struct mdoc_arg argv[MDOC_LINEARG_MAX];

char *p;

struct mdoc_node *n;

fl = 0;

assert( ! (MDOC_CALLABLE & mdoc_macros[tok].flags));

if (MDOC_QUOTABLE & mdoc_macros[tok].flags)

fl = ARGS_QUOTED;

for (argc = 0; argc < MDOC_LINEARG_MAX; argc++) {

lastarg = *pos;

la = *pos;

c = mdoc_argv(mdoc, line, tok, &argv[argc], pos, buf);

if (ARGV_EOLN == c)

break;

if (ARGV_WORD == c) {

*pos = lastarg;

*pos = la;

break;

} else if (ARGV_ARG == c)

continue;

Line 998 macro_constant(MACRO_PROT_ARGS)

Line 1150 macro_constant(MACRO_PROT_ARGS)

mdoc->next = MDOC_NEXT_CHILD;

fl = 0;

if (MDOC_QUOTABLE & mdoc_macros[tok].flags)

fl = ARGS_QUOTED;

for (;;) {

lastarg = *pos;

la = *pos;

c = mdoc_args(mdoc, line, pos, buf, fl, &p);

w = mdoc_args(mdoc, line, pos, buf, fl, &p);

if (ARGS_ERROR == c)

if (ARGS_ERROR == w)

return(0);

if (ARGS_EOLN == c)

if (ARGS_EOLN == w)

break;

if (-1 == (c = lookup(mdoc, line, lastarg, tok, p)))

c = ARGS_QWORD == w ? MDOC_MAX :

return(0);

lookup(mdoc, line, la, tok, p);

else if (MDOC_MAX != c) {

if (MDOC_MAX != c && -1 != c) {

if ( ! rewind_elem(mdoc, tok))

return(0);

return(mdoc_macro(mdoc, c, line,

return(mdoc_macro(mdoc, c, line, la, pos, buf));

lastarg, pos, buf));

} else if (-1 == c)

}

return(0);

if ( ! mdoc_word_alloc(mdoc, line, lastarg, p))

if ( ! mdoc_word_alloc(mdoc, line, la, p))

return(0);

mdoc->next = MDOC_NEXT_SIBLING;

}

if ( ! rewind_elem(mdoc, tok))

return(rewind_elem(mdoc, tok));

return(0);

if ( ! (MDOC_NOKEEP & mdoc_macros[tok].flags))

return(1);

assert(mdoc->last->tok == tok);

if (mdoc->last->parent->child == mdoc->last)

mdoc->last->parent->child = mdoc->last->prev;

if (mdoc->last->prev)

mdoc->last->prev->next = NULL;

n = mdoc->last;

assert(NULL == mdoc->last->next);

if (mdoc->last->prev) {

mdoc->last = mdoc->last->prev;

mdoc->next = MDOC_NEXT_SIBLING;

} else {

mdoc->last = mdoc->last->parent;

mdoc->next = MDOC_NEXT_CHILD;

}

mdoc_node_freelist(n);

return(1);

}

Line 1057 macro_obsolete(MACRO_PROT_ARGS)

Line 1190 macro_obsolete(MACRO_PROT_ARGS)

}

* This is called at the end of parsing. It must traverse up the tree,

* closing out open [implicit] scopes. Obviously, open explicit scopes

* are errors.

int

macro_end(struct mdoc *mdoc)

{

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