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1 /* Generate information regarding function declarations and definitions based
2 on information stored in GCC's tree structure. This code implements the
3 -aux-info option.
4 Copyright (C) 1989, 1991, 1994, 1995, 1997, 1998,
5 1999, 2000, 2003, 2004, 2007 Free Software Foundation, Inc.
6 Contributed by Ron Guilmette (rfg@segfault.us.com).
8 This file is part of GCC.
10 GCC is free software; you can redistribute it and/or modify it under
11 the terms of the GNU General Public License as published by the Free
12 Software Foundation; either version 3, or (at your option) any later
13 version.
15 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
16 WARRANTY; without even the implied warranty of MERCHANTABILITY or
17 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
18 for more details.
20 You should have received a copy of the GNU General Public License
21 along with GCC; see the file COPYING3. If not see
22 <http://www.gnu.org/licenses/>. */
34 ansi,
35 k_and_r_names,
36 k_and_r_decls
37 };
48 \f
49 /* Given a string representing an entire type or an entire declaration
50 which only lacks the actual "data-type" specifier (at its left end),
51 affix the data-type specifier to the left end of the given type
52 specification or object declaration.
54 Because of C language weirdness, the data-type specifier (which normally
55 goes in at the very left end) may have to be slipped in just to the
56 right of any leading "const" or "volatile" qualifiers (there may be more
57 than one). Actually this may not be strictly necessary because it seems
58 that GCC (at least) accepts `<data-type> const foo;' and treats it the
59 same as `const <data-type> foo;' but people are accustomed to seeing
60 `const char *foo;' and *not* `char const *foo;' so we try to create types
61 that look as expected. */
65 {
71 /* Skip as many leading const's or volatile's as there are. */
74 {
76 {
79 }
81 {
84 }
86 }
88 /* p now points to the place where we can insert the data type. We have to
89 add a blank after the data-type of course. */
100 }
102 /* Given a tree node which represents some "function type", generate the
103 source code version of a formal parameter list (of some given style) for
104 this function type. Return the whole formal parameter list (including
105 a pair of surrounding parens) as a string. Note that if the style
106 we are currently aiming for is non-ansi, then we just return a pair
107 of empty parens here. */
111 {
113 tree formal_type;
120 {
127 formal_list
133 }
135 /* If we got to here, then we are trying to generate an ANSI style formal
136 parameters list.
138 New style prototyped ANSI formal parameter lists should in theory always
139 contain some stuff between the opening and closing parens, even if it is
140 only "void".
142 The brutal truth though is that there is lots of old K&R code out there
143 which contains declarations of "pointer-to-function" parameters and
144 these almost never have fully specified formal parameter lists associated
145 with them. That is, the pointer-to-function parameters are declared
146 with just empty parameter lists.
148 In cases such as these, protoize should really insert *something* into
149 the vacant parameter lists, but what? It has no basis on which to insert
150 anything in particular.
152 Here, we make life easy for protoize by trying to distinguish between
153 K&R empty parameter lists and new-style prototyped parameter lists
154 that actually contain "void". In the latter case we (obviously) want
155 to output the "void" verbatim, and that what we do. In the former case,
156 we do our best to give protoize something nice to insert.
158 This "something nice" should be something that is still valid (when
159 re-compiled) but something that can clearly indicate to the user that
160 more typing information (for the parameter list) should be added (by
161 hand) at some convenient moment.
163 The string chosen here is a comment with question marks in it. */
166 {
168 /* assert (TREE_VALUE (TYPE_ARG_TYPES (fntype)) == void_type_node); */
170 else
172 }
173 else
174 {
175 /* If there were at least some parameters, and if the formals-types-list
176 petered out to a NULL (i.e. without being terminated by a
177 void_type_node) then we need to tack on an ellipsis. */
180 }
183 }
185 /* Generate a parameter list for a function definition (in some given style).
187 Note that this routine has to be separate (and different) from the code that
188 generates the prototype parameter lists for function declarations, because
189 in the case of a function declaration, all we have to go on is a tree node
190 representing the function's own "function type". This can tell us the types
191 of all of the formal parameters for the function, but it cannot tell us the
192 actual *names* of each of the formal parameters. We need to output those
193 parameter names for each function definition.
195 This routine gets a pointer to a tree node which represents the actual
196 declaration of the given function, and this DECL node has a list of formal
197 parameter (variable) declarations attached to it. These formal parameter
198 (variable) declaration nodes give us the actual names of the formal
199 parameters for the given function definition.
201 This routine returns a string which is the source form for the entire
202 function formal parameter list. */
206 {
208 tree formal_decl;
212 {
220 else
223 }
225 {
230 }
234 }
236 /* Generate a string which is the source code form for a given type (t). This
237 routine is ugly and complex because the C syntax for declarations is ugly
238 and complex. This routine is straightforward so long as *no* pointer types,
239 array types, or function types are involved.
241 In the simple cases, this routine will return the (string) value which was
242 passed in as the "ret_val" argument. Usually, this starts out either as an
243 empty string, or as the name of the declared item (i.e. the formal function
244 parameter variable).
246 This routine will also return with the global variable "data_type" set to
247 some string value which is the "basic" data-type of the given complete type.
248 This "data_type" string can be concatenated onto the front of the returned
249 string after this routine returns to its caller.
251 In complicated cases involving pointer types, array types, or function
252 types, the C declaration syntax requires an "inside out" approach, i.e. if
253 you have a type which is a "pointer-to-function" type, you need to handle
254 the "pointer" part first, but it also has to be "innermost" (relative to
255 the declaration stuff for the "function" type). Thus, is this case, you
256 must prepend a "(*" and append a ")" to the name of the item (i.e. formal
257 variable). Then you must append and prepend the other info for the
258 "function type" part of the overall type.
260 To handle the "innermost precedence" rules of complicated C declarators, we
261 do the following (in this routine). The input parameter called "ret_val"
262 is treated as a "seed". Each time gen_type is called (perhaps recursively)
263 some additional strings may be appended or prepended (or both) to the "seed"
264 string. If yet another (lower) level of the GCC tree exists for the given
265 type (as in the case of a pointer type, an array type, or a function type)
266 then the (wrapped) seed is passed to a (recursive) invocation of gen_type()
267 this recursive invocation may again "wrap" the (new) seed with yet more
268 declarator stuff, by appending, prepending (or both). By the time the
269 recursion bottoms out, the "seed value" at that point will have a value
270 which is (almost) the complete source version of the declarator (except
271 for the data_type info). Thus, this deepest "seed" value is simply passed
272 back up through all of the recursive calls until it is given (as the return
273 value) to the initial caller of the gen_type() routine. All that remains
274 to do at this point is for the initial caller to prepend the "data_type"
275 string onto the returned "seed". */
279 {
280 tree chain_p;
282 /* If there is a typedef name for this type, use it. */
285 else
286 {
288 {
311 else
312 {
318 }
324 NULL),
332 /* The following three cases are complicated by the fact that a
333 user may do something really stupid, like creating a brand new
334 "anonymous" type specification in a formal argument list (or as
335 part of a function return type specification). For example:
337 int f (enum { red, green, blue } color);
339 In such cases, we have no name that we can put into the prototype
340 to represent the (anonymous) type. Thus, we have to generate the
341 whole darn type specification. Yuck! */
346 else
347 {
351 {
353 NULL);
356 }
358 }
365 else
366 {
370 {
372 NULL);
375 }
377 }
384 else
385 {
389 {
395 }
397 }
408 /* Normally, `unsigned' is part of the deal. Not so if it comes
409 with a type qualifier. */
428 }
429 }
437 }
439 /* Generate a string (source) representation of an entire entity declaration
440 (using some particular style for function types).
442 The given entity may be either a variable or a function.
444 If the "is_func_definition" parameter is nonzero, assume that the thing
445 we are generating a declaration for is a FUNCTION_DECL node which is
446 associated with a function definition. In this case, we can assume that
447 an attached list of DECL nodes for function formal arguments is present. */
451 {
456 else
459 /* If we are just generating a list of names of formal parameters, we can
460 simply return the formal parameter name (with no typing information
461 attached to it) now. */
466 /* Note that for the declaration of some entity (either a function or a
467 data object, like for instance a parameter) if the entity itself was
468 declared as either const or volatile, then const and volatile properties
469 are associated with just the declaration of the entity, and *not* with
470 the `type' of the entity. Thus, for such declared entities, we have to
471 generate the qualifiers here. */
480 /* For FUNCTION_DECL nodes, there are two possible cases here. First, if
481 this FUNCTION_DECL node was generated from a function "definition", then
482 we will have a list of DECL_NODE's, one for each of the function's formal
483 parameters. In this case, we can print out not only the types of each
484 formal, but also each formal's name. In the second case, this
485 FUNCTION_DECL node came from an actual function declaration (and *not*
486 a definition). In this case, we do nothing here because the formal
487 argument type-list will be output later, when the "type" of the function
488 is added to the string we are building. Note that the ANSI-style formal
489 parameter list is considered to be a (suffix) part of the "type" of the
490 function. */
493 {
495 NULL);
497 /* Since we have already added in the formals list stuff, here we don't
498 add the whole "type" of the function we are considering (which
499 would include its parameter-list info), rather, we only add in
500 the "type" of the "type" of the function, which is really just
501 the return-type of the function (and does not include the parameter
502 list info). */
505 }
506 else
519 }
523 /* Generate and write a new line of info to the aux-info (.X) file. This
524 routine is called once for each function declaration, and once for each
525 function definition (even the implicit ones). */
527 void
530 {
532 {
536 /* Each output .X file must have a header line. Write one now if we
537 have not yet done so. */
540 {
541 /* The first line tells which directory file names are relative to.
542 Currently, -aux-info works only for files in the working
543 directory, so just use a `.' as a placeholder for now. */
545 }
547 /* Write the actual line of auxiliary info. */
555 /* If this is an explicit function declaration, we need to also write
556 out an old-style (i.e. K&R) function header, just in case the user
557 wants to run unprotoize. */
560 {
564 }
567 }
568 }