Current Path : /usr/src/usr.bin/xlint/lint1/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //usr/src/usr.bin/xlint/lint1/decl.c |
/* $NetBSD: decl.c,v 1.29 2002/01/18 21:01:39 thorpej Exp $ */ /* * Copyright (c) 1996 Christopher G. Demetriou. All Rights Reserved. * Copyright (c) 1994, 1995 Jochen Pohl * All Rights Reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by Jochen Pohl for * The NetBSD Project. * 4. The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include <sys/cdefs.h> #if defined(__RCSID) && !defined(lint) __RCSID("$NetBSD: decl.c,v 1.29 2002/01/18 21:01:39 thorpej Exp $"); #endif __FBSDID("$FreeBSD: release/9.1.0/usr.bin/xlint/lint1/decl.c 223262 2011-06-18 13:56:33Z benl $"); #include <sys/param.h> #include <limits.h> #include <stdlib.h> #include <string.h> #include "lint1.h" const char *unnamed = "<unnamed>"; /* shared type structures for arithmtic types and void */ static type_t *typetab; /* value of next enumerator during declaration of enum types */ int enumval; /* * pointer to top element of a stack which contains informations local * to nested declarations */ dinfo_t *dcs; static type_t *tdeferr(type_t *, tspec_t); static void settdsym(type_t *, sym_t *); static tspec_t mrgtspec(tspec_t, tspec_t); static void align(int, int); static sym_t *newtag(sym_t *, scl_t, int, int); static int eqargs(type_t *, type_t *, int *); static int mnoarg(type_t *, int *); static int chkosdef(sym_t *, sym_t *); static int chkptdecl(sym_t *, sym_t *); static sym_t *nsfunc(sym_t *, sym_t *); static void osfunc(sym_t *, sym_t *); static void ledecl(sym_t *); static int chkinit(sym_t *); static void chkausg(int, sym_t *); static void chkvusg(int, sym_t *); static void chklusg(sym_t *); static void chktusg(sym_t *); static void chkglvar(sym_t *); static void glchksz(sym_t *); /* * initializes all global vars used in declarations */ void initdecl(void) { int i; /* declaration stack */ if ((dcs = calloc(1, sizeof (dinfo_t))) == NULL) nomem(); dcs->d_ctx = EXTERN; dcs->d_ldlsym = &dcs->d_dlsyms; /* type information and classification */ inittyp(); /* shared type structures */ if ((typetab = calloc(NTSPEC, sizeof (type_t))) == NULL) nomem(); for (i = 0; i < NTSPEC; i++) typetab[i].t_tspec = NOTSPEC; typetab[CHAR].t_tspec = CHAR; typetab[SCHAR].t_tspec = SCHAR; typetab[UCHAR].t_tspec = UCHAR; typetab[SHORT].t_tspec = SHORT; typetab[USHORT].t_tspec = USHORT; typetab[INT].t_tspec = INT; typetab[UINT].t_tspec = UINT; typetab[LONG].t_tspec = LONG; typetab[ULONG].t_tspec = ULONG; typetab[QUAD].t_tspec = QUAD; typetab[UQUAD].t_tspec = UQUAD; typetab[FLOAT].t_tspec = FLOAT; typetab[DOUBLE].t_tspec = DOUBLE; typetab[LDOUBLE].t_tspec = LDOUBLE; typetab[VOID].t_tspec = VOID; /* * Next two are not real types. They are only used by the parser * to return keywords "signed" and "unsigned" */ typetab[SIGNED].t_tspec = SIGNED; typetab[UNSIGN].t_tspec = UNSIGN; } /* * Returns a shared type structure vor arithmetic types and void. * * It's important do duplicate this structure (using duptyp() or tdupdyp()) * if it is to be modified (adding qualifiers or anything else). */ type_t * gettyp(tspec_t t) { return (&typetab[t]); } type_t * duptyp(const type_t *tp) { type_t *ntp; ntp = getblk(sizeof (type_t)); STRUCT_ASSIGN(*ntp, *tp); return (ntp); } /* * Use tduptyp() instead of duptyp() inside expressions (if the * allocated memory should be freed after the expr). */ type_t * tduptyp(const type_t *tp) { type_t *ntp; ntp = tgetblk(sizeof (type_t)); STRUCT_ASSIGN(*ntp, *tp); return (ntp); } /* * Returns 1 if the argument is void or an incomplete array, * struct, union or enum type. */ int incompl(type_t *tp) { tspec_t t; if ((t = tp->t_tspec) == VOID) { return (1); } else if (t == ARRAY) { return (tp->t_aincompl); } else if (t == STRUCT || t == UNION) { return (tp->t_str->sincompl); } else if (t == ENUM) { return (tp->t_enum->eincompl); } return (0); } /* * Set the flag for (in)complete array, struct, union or enum * types. */ void setcompl(type_t *tp, int ic) { tspec_t t; if ((t = tp->t_tspec) == ARRAY) { tp->t_aincompl = ic; } else if (t == STRUCT || t == UNION) { tp->t_str->sincompl = ic; } else { if (t != ENUM) lerror("setcompl() 1"); tp->t_enum->eincompl = ic; } } /* * Remember the storage class of the current declaration in dcs->d_scl * (the top element of the declaration stack) and detect multiple * storage classes. */ void addscl(scl_t sc) { if (sc == INLINE) { if (dcs->d_inline) /* duplicate '%s' */ warning(10, "inline"); dcs->d_inline = 1; return; } if (dcs->d_type != NULL || dcs->d_atyp != NOTSPEC || dcs->d_smod != NOTSPEC || dcs->d_lmod != NOTSPEC) { /* storage class after type is obsolescent */ warning(83); } if (dcs->d_scl == NOSCL) { dcs->d_scl = sc; } else { /* * multiple storage classes. An error will be reported in * deftyp(). */ dcs->d_mscl = 1; } } /* * Remember the type, modifier or typedef name returned by the parser * in *dcs (top element of decl stack). This information is used in * deftyp() to build the type used for all declarators in this * declaration. * * Is tp->t_typedef 1, the type comes from a previously defined typename. * Otherwise it comes from a type specifier (int, long, ...) or a * struct/union/enum tag. */ void addtype(type_t *tp) { tspec_t t; if (tp->t_typedef) { if (dcs->d_type != NULL || dcs->d_atyp != NOTSPEC || dcs->d_lmod != NOTSPEC || dcs->d_smod != NOTSPEC) { /* * something like "typedef int a; int a b;" * This should not happen with current grammar. */ lerror("addtype()"); } dcs->d_type = tp; return; } t = tp->t_tspec; if (t == STRUCT || t == UNION || t == ENUM) { /* * something like "int struct a ..." * struct/union/enum with anything else is not allowed */ if (dcs->d_type != NULL || dcs->d_atyp != NOTSPEC || dcs->d_lmod != NOTSPEC || dcs->d_smod != NOTSPEC) { /* * remember that an error must be reported in * deftyp(). */ dcs->d_terr = 1; dcs->d_atyp = dcs->d_lmod = dcs->d_smod = NOTSPEC; } dcs->d_type = tp; return; } if (dcs->d_type != NULL && !dcs->d_type->t_typedef) { /* * something like "struct a int" * struct/union/enum with anything else is not allowed */ dcs->d_terr = 1; return; } if (t == LONG && dcs->d_lmod == LONG) { /* "long long" or "long ... long" */ t = QUAD; dcs->d_lmod = NOTSPEC; if (!quadflg) /* %s C does not support 'long long' */ (void)gnuism(265, tflag ? "traditional" : "ANSI"); } if (dcs->d_type != NULL && dcs->d_type->t_typedef) { /* something like "typedef int a; a long ..." */ dcs->d_type = tdeferr(dcs->d_type, t); return; } /* now it can be only a combination of arithmetic types and void */ if (t == SIGNED || t == UNSIGN) { /* remeber specifiers "signed" and "unsigned" in dcs->d_smod */ if (dcs->d_smod != NOTSPEC) /* * more than one "signed" and/or "unsigned"; print * an error in deftyp() */ dcs->d_terr = 1; dcs->d_smod = t; } else if (t == SHORT || t == LONG || t == QUAD) { /* * remember specifiers "short", "long" and "long long" in * dcs->d_lmod */ if (dcs->d_lmod != NOTSPEC) /* more than one, print error in deftyp() */ dcs->d_terr = 1; dcs->d_lmod = t; } else { /* * remember specifiers "void", "char", "int", "float" or * "double" int dcs->d_atyp */ if (dcs->d_atyp != NOTSPEC) /* more than one, print error in deftyp() */ dcs->d_terr = 1; dcs->d_atyp = t; } } /* * called if a list of declaration specifiers contains a typedef name * and other specifiers (except struct, union, enum, typedef name) */ static type_t * tdeferr(type_t *td, tspec_t t) { tspec_t t2; t2 = td->t_tspec; switch (t) { case SIGNED: case UNSIGN: if (t2 == CHAR || t2 == SHORT || t2 == INT || t2 == LONG || t2 == QUAD) { if (!tflag) /* modifying typedef with ... */ warning(5, ttab[t].tt_name); td = duptyp(gettyp(mrgtspec(t2, t))); td->t_typedef = 1; return (td); } break; case SHORT: if (t2 == INT || t2 == UINT) { /* modifying typedef with ... */ warning(5, "short"); td = duptyp(gettyp(t2 == INT ? SHORT : USHORT)); td->t_typedef = 1; return (td); } break; case LONG: if (t2 == INT || t2 == UINT || t2 == LONG || t2 == ULONG || t2 == FLOAT || t2 == DOUBLE) { /* modifying typedef with ... */ warning(5, "long"); if (t2 == INT) { td = gettyp(LONG); } else if (t2 == UINT) { td = gettyp(ULONG); } else if (t2 == LONG) { td = gettyp(QUAD); } else if (t2 == ULONG) { td = gettyp(UQUAD); } else if (t2 == FLOAT) { td = gettyp(DOUBLE); } else if (t2 == DOUBLE) { td = gettyp(LDOUBLE); } td = duptyp(td); td->t_typedef = 1; return (td); } break; /* LINTED (enumeration values not handled in switch) */ case NOTSPEC: case USHORT: case UCHAR: case SCHAR: case CHAR: case FUNC: case ARRAY: case PTR: case ENUM: case UNION: case STRUCT: case VOID: case LDOUBLE: case DOUBLE: case FLOAT: case UQUAD: case QUAD: case ULONG: case UINT: case INT: break; } /* Anything other is not accepted. */ dcs->d_terr = 1; return (td); } /* * Remember the symbol of a typedef name (2nd arg) in a struct, union * or enum tag if the typedef name is the first defined for this tag. * * If the tag is unnamed, the typdef name is used for identification * of this tag in lint2. Although its possible that more than one typedef * name is defined for one tag, the first name defined should be unique * if the tag is unnamed. */ static void settdsym(type_t *tp, sym_t *sym) { tspec_t t; if ((t = tp->t_tspec) == STRUCT || t == UNION) { if (tp->t_str->stdef == NULL) tp->t_str->stdef = sym; } else if (t == ENUM) { if (tp->t_enum->etdef == NULL) tp->t_enum->etdef = sym; } } /* * Remember a qualifier which is part of the declaration specifiers * (and not the declarator) in the top element of the declaration stack. * Also detect multiple qualifiers of the same kind. * The remembered qualifier is used by deftyp() to construct the type * for all declarators. */ void addqual(tqual_t q) { if (q == CONST) { if (dcs->d_const) { /* duplicate "%s" */ warning(10, "const"); } dcs->d_const = 1; } else { if (q != VOLATILE) lerror("addqual() 1"); if (dcs->d_volatile) { /* duplicate "%s" */ warning(10, "volatile"); } dcs->d_volatile = 1; } } /* * Go to the next declaration level (structs, nested structs, blocks, * argument declaration lists ...) */ void pushdecl(scl_t sc) { dinfo_t *di; if (dflag) (void)printf("pushdecl(%d)\n", (int)sc); /* put a new element on the declaration stack */ if ((di = calloc(1, sizeof (dinfo_t))) == NULL) nomem(); di->d_nxt = dcs; dcs = di; di->d_ctx = sc; di->d_ldlsym = &di->d_dlsyms; } /* * Go back to previous declaration level */ void popdecl(void) { dinfo_t *di; if (dflag) (void)printf("popdecl(%d)\n", (int)dcs->d_ctx); if (dcs->d_nxt == NULL) lerror("popdecl() 1"); di = dcs; dcs = di->d_nxt; switch (di->d_ctx) { case EXTERN: /* there is nothing after external declarations */ lerror("popdecl() 2"); /* NOTREACHED */ case MOS: case MOU: case ENUMCON: /* * Symbols declared in (nested) structs or enums are * part of the next level (they are removed from the * symbol table if the symbols of the outher level are * removed) */ if ((*dcs->d_ldlsym = di->d_dlsyms) != NULL) dcs->d_ldlsym = di->d_ldlsym; break; case ARG: /* * All symbols in dcs->d_dlsyms are introduced in old style * argument declarations (it's not clean, but possible). * They are appended to the list of symbols declared in * an old style argument identifier list or a new style * parameter type list. */ if (di->d_dlsyms != NULL) { *di->d_ldlsym = dcs->d_fpsyms; dcs->d_fpsyms = di->d_dlsyms; } break; case ABSTRACT: /* * casts and sizeof * Append all symbols declared in the abstract declaration * to the list of symbols declared in the surounding decl. * or block. * XXX I'm not sure whether they should be removed from the * symbol table now or later. */ if ((*dcs->d_ldlsym = di->d_dlsyms) != NULL) dcs->d_ldlsym = di->d_ldlsym; break; case AUTO: /* check usage of local vars */ chkusage(di); /* FALLTHROUGH */ case PARG: /* usage of arguments will be checked by funcend() */ rmsyms(di->d_dlsyms); break; default: lerror("popdecl() 3"); } free(di); } /* * Set flag d_asm in all declaration stack elements up to the * outermost one. * * This is used to mark compound statements which have, possibly in * nested compound statements, asm statements. For these compound * statements no warnings about unused or unitialized variables are * printed. * * There is no need to clear d_asm in dinfo structs with context AUTO, * because these structs are freed at the end of the compound statement. * But it must be cleard in the outermost dinfo struct, which has * context EXTERN. This could be done in clrtyp() and would work for * C, but not for C++ (due to mixed statements and declarations). Thus * we clear it in glclup(), which is used to do some cleanup after * global declarations/definitions. */ void setasm(void) { dinfo_t *di; for (di = dcs; di != NULL; di = di->d_nxt) di->d_asm = 1; } /* * Clean all elements of the top element of declaration stack which * will be used by the next declaration */ void clrtyp(void) { dcs->d_atyp = dcs->d_smod = dcs->d_lmod = NOTSPEC; dcs->d_scl = NOSCL; dcs->d_type = NULL; dcs->d_const = dcs->d_volatile = 0; dcs->d_inline = 0; dcs->d_mscl = dcs->d_terr = 0; dcs->d_nedecl = 0; dcs->d_notyp = 0; } /* * Create a type structure from the informations gathered in * the declaration stack. * Complain about storage classes which are not possible in current * context. */ void deftyp(void) { tspec_t t, s, l; type_t *tp; scl_t scl; t = dcs->d_atyp; /* CHAR, INT, FLOAT, DOUBLE, VOID */ s = dcs->d_smod; /* SIGNED, UNSIGNED */ l = dcs->d_lmod; /* SHORT, LONG, QUAD */ tp = dcs->d_type; scl = dcs->d_scl; if (t == NOTSPEC && s == NOTSPEC && l == NOTSPEC && tp == NULL) dcs->d_notyp = 1; if (tp != NULL && (t != NOTSPEC || s != NOTSPEC || l != NOTSPEC)) { /* should never happen */ lerror("deftyp() 1"); } if (tp == NULL) { switch (t) { case NOTSPEC: t = INT; /* FALLTHROUGH */ case INT: if (s == NOTSPEC) s = SIGNED; break; case CHAR: if (l != NOTSPEC) { dcs->d_terr = 1; l = NOTSPEC; } break; case FLOAT: if (l == LONG) { l = NOTSPEC; t = DOUBLE; if (!tflag) /* use 'double' instead of ... */ warning(6); } break; case DOUBLE: if (l == LONG) { l = NOTSPEC; t = LDOUBLE; if (tflag) /* 'long double' is illegal in ... */ warning(266); } break; case VOID: break; default: lerror("deftyp() 2"); } if (t != INT && t != CHAR && (s != NOTSPEC || l != NOTSPEC)) { dcs->d_terr = 1; l = s = NOTSPEC; } if (l != NOTSPEC) t = l; dcs->d_type = gettyp(mrgtspec(t, s)); } if (dcs->d_mscl) { /* only one storage class allowed */ error(7); } if (dcs->d_terr) { /* illegal type combination */ error(4); } if (dcs->d_ctx == EXTERN) { if (scl == REG || scl == AUTO) { /* illegal storage class */ error(8); scl = NOSCL; } } else if (dcs->d_ctx == ARG || dcs->d_ctx == PARG) { if (scl != NOSCL && scl != REG) { /* only "register" valid ... */ error(9); scl = NOSCL; } } dcs->d_scl = scl; if (dcs->d_const && dcs->d_type->t_const) { if (!dcs->d_type->t_typedef) lerror("deftyp() 3"); /* typedef already qualified with "%s" */ warning(68, "const"); } if (dcs->d_volatile && dcs->d_type->t_volatile) { if (!dcs->d_type->t_typedef) lerror("deftyp() 4"); /* typedef already qualified with "%s" */ warning(68, "volatile"); } if (dcs->d_const || dcs->d_volatile) { dcs->d_type = duptyp(dcs->d_type); dcs->d_type->t_const |= dcs->d_const; dcs->d_type->t_volatile |= dcs->d_volatile; } } /* * Merge type specifiers (char, ..., long long, signed, unsigned). */ static tspec_t mrgtspec(tspec_t t, tspec_t s) { if (s == SIGNED || s == UNSIGN) { if (t == CHAR) { t = s == SIGNED ? SCHAR : UCHAR; } else if (t == SHORT) { t = s == SIGNED ? SHORT : USHORT; } else if (t == INT) { t = s == SIGNED ? INT : UINT; } else if (t == LONG) { t = s == SIGNED ? LONG : ULONG; } else if (t == QUAD) { t = s == SIGNED ? QUAD : UQUAD; } } return (t); } /* * Return the length of a type in bit. * * Printing a message if the outhermost dimension of an array is 0 must * be done by the caller. All other problems are reported by length() * if name is not NULL. */ int length(type_t *tp, const char *name) { int elem, elsz; elem = 1; while (tp && tp->t_tspec == ARRAY) { elem *= tp->t_dim; tp = tp->t_subt; } if (tp == NULL) return -1; switch (tp->t_tspec) { case FUNC: /* compiler takes size of function */ lerror("%s", msgs[12]); /* NOTREACHED */ case STRUCT: case UNION: if (incompl(tp) && name != NULL) { /* incomplete structure or union %s: %s */ error(31, tp->t_str->stag->s_name, name); } elsz = tp->t_str->size; break; case ENUM: if (incompl(tp) && name != NULL) { /* incomplete enum type: %s */ warning(13, name); } /* FALLTHROUGH */ default: elsz = size(tp->t_tspec); if (elsz <= 0) lerror("length()"); break; } return (elem * elsz); } /* * Get the alignment of the given Type in bits. */ int getbound(type_t *tp) { int a; tspec_t t; while (tp && tp->t_tspec == ARRAY) tp = tp->t_subt; if (tp == NULL) return -1; if ((t = tp->t_tspec) == STRUCT || t == UNION) { a = tp->t_str->align; } else if (t == FUNC) { /* compiler takes alignment of function */ error(14); a = LINT_ALIGN(1) * CHAR_BIT; } else { if ((a = size(t)) == 0) { a = CHAR_BIT; } else if (a > LINT_ALIGN(1) * CHAR_BIT) { a = LINT_ALIGN(1) * CHAR_BIT; } } if (a < CHAR_BIT || a > LINT_ALIGN(1) * CHAR_BIT) lerror("getbound() 1"); return (a); } /* * Concatenate two lists of symbols by s_nxt. Used by declarations of * struct/union/enum elements and parameters. */ sym_t * lnklst(sym_t *l1, sym_t *l2) { sym_t *l; if ((l = l1) == NULL) return (l2); while (l1->s_nxt != NULL) l1 = l1->s_nxt; l1->s_nxt = l2; return (l); } /* * Check if the type of the given symbol is valid and print an error * message if it is not. * * Invalid types are: * - arrays of incomlete types or functions * - functions returning arrays or functions * - void types other than type of function or pointer */ void chktyp(sym_t *sym) { tspec_t to, t; type_t **tpp, *tp; tpp = &sym->s_type; to = NOTSPEC; while ((tp = *tpp) != NULL) { t = tp->t_tspec; /* * If this is the type of an old style function definition, * a better warning is printed in funcdef(). */ if (t == FUNC && !tp->t_proto && !(to == NOTSPEC && sym->s_osdef)) { if (sflag && hflag) /* function declaration is not a prototype */ warning(287); } if (to == FUNC) { if (t == FUNC || t == ARRAY) { /* function returns illegal type */ error(15); if (t == FUNC) { *tpp = incref(*tpp, PTR); } else { *tpp = incref((*tpp)->t_subt, PTR); } return; } else if (tp->t_const || tp->t_volatile) { if (sflag) { /* XXX oder better !tflag ? */ /* function cannot return const... */ warning(228); } } } if (to == ARRAY) { if (t == FUNC) { /* array of function is illegal */ error(16); *tpp = gettyp(INT); return; } else if (t == ARRAY && tp->t_dim == 0) { /* null dimension */ error(17); return; } else if (t == VOID) { /* illegal use of void */ error(18); *tpp = gettyp(INT); #if 0 /* errors are produced by length() */ } else if (incompl(tp)) { /* array of incomplete type */ if (sflag) { error(301); } else { warning(301); } #endif } } else if (to == NOTSPEC && t == VOID) { if (dcs->d_ctx == PARG) { if (sym->s_scl != ABSTRACT) { if (sym->s_name == unnamed) lerror("chktyp()"); /* void param cannot have name: %s */ error(61, sym->s_name); *tpp = gettyp(INT); } } else if (dcs->d_ctx == ABSTRACT) { /* ok */ } else if (sym->s_scl != TYPEDEF) { /* void type for %s */ error(19, sym->s_name); *tpp = gettyp(INT); } } if (t == VOID && to != PTR) { if (tp->t_const || tp->t_volatile) { /* inappropriate qualifiers with "void" */ warning(69); tp->t_const = tp->t_volatile = 0; } } tpp = &tp->t_subt; to = t; } } /* * Process the declarator of a struct/union element. */ sym_t * decl1str(sym_t *dsym) { type_t *tp; tspec_t t; int sz, len; int o = 0; /* Appease gcc */ scl_t sc; if ((sc = dsym->s_scl) != MOS && sc != MOU) lerror("decl1str() 1"); if (dcs->d_rdcsym != NULL) { if ((sc = dcs->d_rdcsym->s_scl) != MOS && sc != MOU) /* should be ensured by storesym() */ lerror("decl1str() 2"); if (dsym->s_styp == dcs->d_rdcsym->s_styp) { /* duplicate member name: %s */ error(33, dsym->s_name); rmsym(dcs->d_rdcsym); } } chktyp(dsym); t = (tp = dsym->s_type)->t_tspec; if (dsym->s_field) { /* * bit field * * only unsigned und signed int are protable bit-field types *(at least in ANSI C, in traditional C only unsigned int) */ if (t == CHAR || t == UCHAR || t == SCHAR || t == SHORT || t == USHORT || t == ENUM) { if (bitfieldtype_ok == 0) { if (sflag) { /* * bit-field type '%s' invalid in * ANSI C */ warning(273, tyname(tp)); } else if (pflag) { /* nonportable bit-field type */ warning(34); } } } else if (t == INT && dcs->d_smod == NOTSPEC) { if (pflag && bitfieldtype_ok == 0) { /* nonportable bit-field type */ warning(34); } } else if (t != INT && t != UINT) { /* * Non-integer types are always illegal for * bitfields, regardless of BITFIELDTYPE. * Integer types not dealt with above are * okay only if BITFIELDTYPE is in effect. */ if (bitfieldtype_ok == 0 || isityp(t) == 0) { /* illegal bit-field type */ error(35); sz = tp->t_flen; dsym->s_type = tp = duptyp(gettyp(t = INT)); if ((tp->t_flen = sz) > size(t)) tp->t_flen = size(t); } } if ((len = tp->t_flen) < 0 || len > size(t)) { /* illegal bit-field size */ error(36); tp->t_flen = size(t); } else if (len == 0 && dsym->s_name != unnamed) { /* zero size bit-field */ error(37); tp->t_flen = size(t); } if (dsym->s_scl == MOU) { /* illegal use of bit-field */ error(41); dsym->s_type->t_isfield = 0; dsym->s_field = 0; } } else if (t == FUNC) { /* function illegal in structure or union */ error(38); dsym->s_type = tp = incref(tp, t = PTR); } /* * bit-fields of length 0 are not warned about because length() * does not return the length of the bit-field but the length * of the type the bit-field is packed in (its ok) */ if ((sz = length(dsym->s_type, dsym->s_name)) == 0) { if (t == ARRAY && dsym->s_type->t_dim == 0) { /* illegal zero sized structure member: %s */ warning(39, dsym->s_name); } } if (dcs->d_ctx == MOU) { o = dcs->d_offset; dcs->d_offset = 0; } if (dsym->s_field) { align(getbound(tp), tp->t_flen); dsym->s_value.v_quad = (dcs->d_offset / size(t)) * size(t); tp->t_foffs = dcs->d_offset - (int)dsym->s_value.v_quad; dcs->d_offset += tp->t_flen; } else { align(getbound(tp), 0); dsym->s_value.v_quad = dcs->d_offset; dcs->d_offset += sz; } if (dcs->d_ctx == MOU) { if (o > dcs->d_offset) dcs->d_offset = o; } chkfdef(dsym, 0); /* * Clear the BITFIELDTYPE indicator after processing each * structure element. */ bitfieldtype_ok = 0; return (dsym); } /* * Aligns next structure element as required. * * al contains the required alignment, len the length of a bit-field. */ static void align(int al, int len) { int no; /* * The alignment of the current element becomes the alignment of * the struct/union if it is larger than the current alignment * of the struct/union. */ if (al > dcs->d_stralign) dcs->d_stralign = al; no = (dcs->d_offset + (al - 1)) & ~(al - 1); if (len == 0 || dcs->d_offset + len > no) dcs->d_offset = no; } /* * Remember the width of the field in its type structure. */ sym_t * bitfield(sym_t *dsym, int len) { if (dsym == NULL) { dsym = getblk(sizeof (sym_t)); dsym->s_name = unnamed; dsym->s_kind = FMOS; dsym->s_scl = MOS; dsym->s_type = gettyp(UINT); dsym->s_blklev = -1; } dsym->s_type = duptyp(dsym->s_type); dsym->s_type->t_isfield = 1; dsym->s_type->t_flen = len; dsym->s_field = 1; return (dsym); } /* * Collect informations about a sequence of asterisks and qualifiers * in a list of type pqinf_t. * Qualifiers refer always to the left asterisk. The rightmost asterisk * will be at the top of the list. */ pqinf_t * mergepq(pqinf_t *p1, pqinf_t *p2) { pqinf_t *p; if (p2->p_pcnt != 0) { /* left '*' at the end of the list */ for (p = p2; p->p_nxt != NULL; p = p->p_nxt) continue; p->p_nxt = p1; return (p2); } else { if (p2->p_const) { if (p1->p_const) { /* duplicate %s */ warning(10, "const"); } p1->p_const = 1; } if (p2->p_volatile) { if (p1->p_volatile) { /* duplicate %s */ warning(10, "volatile"); } p1->p_volatile = 1; } free(p2); return (p1); } } /* * Followint 3 functions extend the type of a declarator with * pointer, function and array types. * * The current type is the Type built by deftyp() (dcs->d_type) and * pointer, function and array types already added for this * declarator. The new type extension is inserted between both. */ sym_t * addptr(sym_t *decl, pqinf_t *pi) { type_t **tpp, *tp; pqinf_t *npi; tpp = &decl->s_type; while (*tpp && *tpp != dcs->d_type) tpp = &(*tpp)->t_subt; if (*tpp == NULL) return decl; while (pi != NULL) { *tpp = tp = getblk(sizeof (type_t)); tp->t_tspec = PTR; tp->t_const = pi->p_const; tp->t_volatile = pi->p_volatile; *(tpp = &tp->t_subt) = dcs->d_type; npi = pi->p_nxt; free(pi); pi = npi; } return (decl); } /* * If a dimension was specified, dim is 1, otherwise 0 * n is the specified dimension */ sym_t * addarray(sym_t *decl, int dim, int n) { type_t **tpp, *tp; tpp = &decl->s_type; while (*tpp && *tpp != dcs->d_type) tpp = &(*tpp)->t_subt; if (*tpp == NULL) return decl; *tpp = tp = getblk(sizeof (type_t)); tp->t_tspec = ARRAY; tp->t_subt = dcs->d_type; tp->t_dim = n; if (n < 0) { /* zero or negative array dimension */ error(20); n = 0; } else if (n == 0 && dim) { /* zero or negative array dimension */ warning(20); } else if (n == 0 && !dim) { /* is incomplete type */ setcompl(tp, 1); } return (decl); } sym_t * addfunc(sym_t *decl, sym_t *args) { type_t **tpp, *tp; if (dcs->d_proto) { if (tflag) /* function prototypes are illegal in traditional C */ warning(270); args = nsfunc(decl, args); } else { osfunc(decl, args); } /* * The symbols are removed from the symbol table by popdecl() after * addfunc(). To be able to restore them if this is a function * definition, a pointer to the list of all symbols is stored in * dcs->d_nxt->d_fpsyms. Also a list of the arguments (concatenated * by s_nxt) is stored in dcs->d_nxt->d_fargs. * (dcs->d_nxt must be used because *dcs is the declaration stack * element created for the list of params and is removed after * addfunc()) */ if (dcs->d_nxt->d_ctx == EXTERN && decl->s_type == dcs->d_nxt->d_type) { dcs->d_nxt->d_fpsyms = dcs->d_dlsyms; dcs->d_nxt->d_fargs = args; } tpp = &decl->s_type; while (*tpp && *tpp != dcs->d_nxt->d_type) tpp = &(*tpp)->t_subt; if (*tpp == NULL) return decl; *tpp = tp = getblk(sizeof (type_t)); tp->t_tspec = FUNC; tp->t_subt = dcs->d_nxt->d_type; if ((tp->t_proto = dcs->d_proto) != 0) tp->t_args = args; tp->t_vararg = dcs->d_vararg; return (decl); } /* * Called for new style function declarations. */ /* ARGSUSED */ static sym_t * nsfunc(sym_t *decl, sym_t *args) { sym_t *arg, *sym; scl_t sc; int n; /* * Declarations of structs/unions/enums in param lists are legal, * but senseless. */ for (sym = dcs->d_dlsyms; sym != NULL; sym = sym->s_dlnxt) { sc = sym->s_scl; if (sc == STRTAG || sc == UNIONTAG || sc == ENUMTAG) { /* dubious tag declaration: %s %s */ warning(85, scltoa(sc), sym->s_name); } } n = 1; for (arg = args; arg != NULL; arg = arg->s_nxt) { if (arg->s_type->t_tspec == VOID) { if (n > 1 || arg->s_nxt != NULL) { /* "void" must be sole parameter */ error(60); arg->s_type = gettyp(INT); } } n++; } /* return NULL if first param is VOID */ return (args != NULL && args->s_type->t_tspec != VOID ? args : NULL); } /* * Called for old style function declarations. */ static void osfunc(sym_t *decl, sym_t *args) { /* * Remember list of params only if this is really seams to be * a function definition. */ if (dcs->d_nxt->d_ctx == EXTERN && decl->s_type == dcs->d_nxt->d_type) { /* * We assume that this becomes a function definition. If * we are wrong, its corrected in chkfdef(). */ if (args != NULL) { decl->s_osdef = 1; decl->s_args = args; } } else { if (args != NULL) /* function prototype parameters must have types */ warning(62); } } /* * Lists of Identifiers in functions declarations are allowed only if * its also a function definition. If this is not the case, print a * error message. */ void chkfdef(sym_t *sym, int msg) { if (sym->s_osdef) { if (msg) { /* incomplete or misplaced function definition */ error(22); } sym->s_osdef = 0; sym->s_args = NULL; } } /* * Process the name in a declarator. * If the symbol does already exists, a new one is created. * The symbol becomes one of the storage classes EXTERN, STATIC, AUTO or * TYPEDEF. * s_def and s_reg are valid after dname(). */ sym_t * dname(sym_t *sym) { scl_t sc = NOSCL; if (sym->s_scl == NOSCL) { dcs->d_rdcsym = NULL; } else if (sym->s_defarg) { sym->s_defarg = 0; dcs->d_rdcsym = NULL; } else { dcs->d_rdcsym = sym; sym = pushdown(sym); } switch (dcs->d_ctx) { case MOS: case MOU: /* Parent setzen */ sym->s_styp = dcs->d_tagtyp->t_str; sym->s_def = DEF; sym->s_value.v_tspec = INT; sc = dcs->d_ctx; break; case EXTERN: /* * static and external symbols without "extern" are * considered to be tentative defined, external * symbols with "extern" are declared, and typedef names * are defined. Tentative defined and declared symbols * may become defined if an initializer is present or * this is a function definition. */ if ((sc = dcs->d_scl) == NOSCL) { sc = EXTERN; sym->s_def = TDEF; } else if (sc == STATIC) { sym->s_def = TDEF; } else if (sc == TYPEDEF) { sym->s_def = DEF; } else if (sc == EXTERN) { sym->s_def = DECL; } else { lerror("dname() 1"); } break; case PARG: sym->s_arg = 1; /* FALLTHROUGH */ case ARG: if ((sc = dcs->d_scl) == NOSCL) { sc = AUTO; } else if (sc == REG) { sym->s_reg = 1; sc = AUTO; } else { lerror("dname() 2"); } sym->s_def = DEF; break; case AUTO: if ((sc = dcs->d_scl) == NOSCL) { /* * XXX somewhat ugly because we dont know whether * this is AUTO or EXTERN (functions). If we are * wrong it must be corrected in decl1loc(), where * we have the necessary type information. */ sc = AUTO; sym->s_def = DEF; } else if (sc == AUTO || sc == STATIC || sc == TYPEDEF) { sym->s_def = DEF; } else if (sc == REG) { sym->s_reg = 1; sc = AUTO; sym->s_def = DEF; } else if (sc == EXTERN) { sym->s_def = DECL; } else { lerror("dname() 3"); } break; default: lerror("dname() 4"); } sym->s_scl = sc; sym->s_type = dcs->d_type; dcs->d_fpsyms = NULL; return (sym); } /* * Process a name in the list of formal params in an old style function * definition. */ sym_t * iname(sym_t *sym) { if (sym->s_scl != NOSCL) { if (blklev == sym->s_blklev) { /* redeclaration of formal parameter %s */ error(21, sym->s_name); if (!sym->s_defarg) lerror("iname()"); } sym = pushdown(sym); } sym->s_type = gettyp(INT); sym->s_scl = AUTO; sym->s_def = DEF; sym->s_defarg = sym->s_arg = 1; return (sym); } /* * Create the type of a tag. * * tag points to the symbol table entry of the tag * kind is the kind of the tag (STRUCT/UNION/ENUM) * decl is 1 if the type of the tag will be completed in this declaration * (the following token is T_LBRACE) * semi is 1 if the following token is T_SEMI */ type_t * mktag(sym_t *tag, tspec_t kind, int decl, int semi) { scl_t scl = NOSCL; type_t *tp; if (kind == STRUCT) { scl = STRTAG; } else if (kind == UNION) { scl = UNIONTAG; } else if (kind == ENUM) { scl = ENUMTAG; } else { lerror("mktag()"); } if (tag != NULL) { if (tag->s_scl != NOSCL) { tag = newtag(tag, scl, decl, semi); } else { /* a new tag, no empty declaration */ dcs->d_nxt->d_nedecl = 1; if (scl == ENUMTAG && !decl) { if (!tflag && (sflag || pflag)) /* forward reference to enum type */ warning(42); } } if (tag->s_scl == NOSCL) { tag->s_scl = scl; tag->s_type = tp = getblk(sizeof (type_t)); } else { tp = tag->s_type; } } else { tag = getblk(sizeof (sym_t)); tag->s_name = unnamed; UNIQUE_CURR_POS(tag->s_dpos); tag->s_kind = FTAG; tag->s_scl = scl; tag->s_blklev = -1; tag->s_type = tp = getblk(sizeof (type_t)); dcs->d_nxt->d_nedecl = 1; } if (tp->t_tspec == NOTSPEC) { tp->t_tspec = kind; if (kind != ENUM) { tp->t_str = getblk(sizeof (str_t)); tp->t_str->align = CHAR_BIT; tp->t_str->stag = tag; } else { tp->t_isenum = 1; tp->t_enum = getblk(sizeof (enum_t)); tp->t_enum->etag = tag; } /* ist unvollstaendiger Typ */ setcompl(tp, 1); } return (tp); } /* * Checks all possible cases of tag redeclarations. * decl is 1 if T_LBRACE follows * semi is 1 if T_SEMI follows */ static sym_t * newtag(sym_t *tag, scl_t scl, int decl, int semi) { if (tag->s_blklev < blklev) { if (semi) { /* "struct a;" */ if (!tflag) { if (!sflag) /* decl. introduces new type ... */ warning(44, scltoa(scl), tag->s_name); tag = pushdown(tag); } else if (tag->s_scl != scl) { /* base type is really "%s %s" */ warning(45, scltoa(tag->s_scl), tag->s_name); } dcs->d_nxt->d_nedecl = 1; } else if (decl) { /* "struct a { ... } " */ if (hflag) /* redefinition hides earlier one: %s */ warning(43, tag->s_name); tag = pushdown(tag); dcs->d_nxt->d_nedecl = 1; } else if (tag->s_scl != scl) { /* base type is really "%s %s" */ warning(45, scltoa(tag->s_scl), tag->s_name); /* declaration introduces new type in ANSI C: %s %s */ if (!sflag) warning(44, scltoa(scl), tag->s_name); tag = pushdown(tag); dcs->d_nxt->d_nedecl = 1; } } else { if (tag->s_scl != scl) { /* (%s) tag redeclared */ error(46, scltoa(tag->s_scl)); prevdecl(-1, tag); tag = pushdown(tag); dcs->d_nxt->d_nedecl = 1; } else if (decl && !incompl(tag->s_type)) { /* (%s) tag redeclared */ error(46, scltoa(tag->s_scl)); prevdecl(-1, tag); tag = pushdown(tag); dcs->d_nxt->d_nedecl = 1; } else if (semi || decl) { dcs->d_nxt->d_nedecl = 1; } } return (tag); } const char * scltoa(scl_t sc) { const char *s; switch (sc) { case EXTERN: s = "extern"; break; case STATIC: s = "static"; break; case AUTO: s = "auto"; break; case REG: s = "register"; break; case TYPEDEF: s = "typedef"; break; case STRTAG: s = "struct"; break; case UNIONTAG: s = "union"; break; case ENUMTAG: s = "enum"; break; default: lerror("tagttoa()"); } return (s); } /* * Completes the type of a tag in a struct/union/enum declaration. * tp points to the type of the, tag, fmem to the list of members/enums. */ type_t * compltag(type_t *tp, sym_t *fmem) { tspec_t t; str_t *sp; int n; sym_t *mem; /* from now a complete type */ setcompl(tp, 0); if ((t = tp->t_tspec) != ENUM) { align(dcs->d_stralign, 0); sp = tp->t_str; sp->align = dcs->d_stralign; sp->size = dcs->d_offset; sp->memb = fmem; if (sp->size == 0) { /* zero sized %s */ (void)gnuism(47, ttab[t].tt_name); } else { n = 0; for (mem = fmem; mem != NULL; mem = mem->s_nxt) { if (mem->s_name != unnamed) n++; } if (n == 0) { /* %s has no named members */ warning(65, t == STRUCT ? "structure" : "union"); } } } else { tp->t_enum->elem = fmem; } return (tp); } /* * Processes the name of an enumerator in en enum declaration. * * sym points to the enumerator * val is the value of the enumerator * impl is 1 if the value of the enumerator was not explicit specified. */ sym_t * ename(sym_t *sym, int val, int impl) { if (sym->s_scl) { if (sym->s_blklev == blklev) { /* no hflag, because this is illegal!!! */ if (sym->s_arg) { /* enumeration constant hides parameter: %s */ warning(57, sym->s_name); } else { /* redeclaration of %s */ error(27, sym->s_name); /* * inside blocks it should not too complicated * to find the position of the previous * declaration */ if (blklev == 0) prevdecl(-1, sym); } } else { if (hflag) /* redefinition hides earlier one: %s */ warning(43, sym->s_name); } sym = pushdown(sym); } sym->s_scl = ENUMCON; sym->s_type = dcs->d_tagtyp; sym->s_value.v_tspec = INT; sym->s_value.v_quad = val; if (impl && val - 1 == INT_MAX) { /* overflow in enumeration values: %s */ warning(48, sym->s_name); } enumval = val + 1; return (sym); } /* * Process a single external declarator. */ void decl1ext(sym_t *dsym, int initflg) { int warn, rval, redec; sym_t *rdsym; chkfdef(dsym, 1); chktyp(dsym); if (initflg && !(initerr = chkinit(dsym))) dsym->s_def = DEF; /* * Declarations of functions are marked as "tentative" in dname(). * This is wrong because there are no tentative function * definitions. */ if (dsym->s_type->t_tspec == FUNC && dsym->s_def == TDEF) dsym->s_def = DECL; if (dcs->d_inline) { if (dsym->s_type->t_tspec == FUNC) { dsym->s_inline = 1; } else { /* variable declared inline: %s */ warning(268, dsym->s_name); } } /* Write the declaration into the output file */ if (plibflg && llibflg && dsym->s_type->t_tspec == FUNC && dsym->s_type->t_proto) { /* * With both LINTLIBRARY and PROTOLIB the prototyp is * written as a function definition to the output file. */ rval = dsym->s_type->t_subt->t_tspec != VOID; outfdef(dsym, &dsym->s_dpos, rval, 0, NULL); } else { outsym(dsym, dsym->s_scl, dsym->s_def); } if ((rdsym = dcs->d_rdcsym) != NULL) { /* * If the old symbol stems from an old style function definition * we have remembered the params in rdsmy->s_args and compare * them with the params of the prototype. */ if (rdsym->s_osdef && dsym->s_type->t_proto) { redec = chkosdef(rdsym, dsym); } else { redec = 0; } if (!redec && !isredec(dsym, (warn = 0, &warn))) { if (warn) { /* redeclaration of %s */ (*(sflag ? error : warning))(27, dsym->s_name); prevdecl(-1, rdsym); } /* * Overtake the rememberd params if the new symbol * is not a prototype. */ if (rdsym->s_osdef && !dsym->s_type->t_proto) { dsym->s_osdef = rdsym->s_osdef; dsym->s_args = rdsym->s_args; STRUCT_ASSIGN(dsym->s_dpos, rdsym->s_dpos); } /* * Remember the position of the declaration if the * old symbol was a prototype and the new is not. * Also remember the position if the old symbol * was defined and the new is not. */ if (rdsym->s_type->t_proto && !dsym->s_type->t_proto) { STRUCT_ASSIGN(dsym->s_dpos, rdsym->s_dpos); } else if (rdsym->s_def == DEF && dsym->s_def != DEF) { STRUCT_ASSIGN(dsym->s_dpos, rdsym->s_dpos); } /* * Copy informations about usage of the name into * the new symbol. */ cpuinfo(dsym, rdsym); /* Once a name is defined, it remains defined. */ if (rdsym->s_def == DEF) dsym->s_def = DEF; /* once a function is inline, it remains inline */ if (rdsym->s_inline) dsym->s_inline = 1; compltyp(dsym, rdsym); } rmsym(rdsym); } if (dsym->s_scl == TYPEDEF) { dsym->s_type = duptyp(dsym->s_type); dsym->s_type->t_typedef = 1; settdsym(dsym->s_type, dsym); } } /* * Copies informations about usage into a new symbol table entry of * the same symbol. */ void cpuinfo(sym_t *sym, sym_t *rdsym) { sym->s_spos = rdsym->s_spos; sym->s_upos = rdsym->s_upos; sym->s_set = rdsym->s_set; sym->s_used = rdsym->s_used; } /* * Prints an error and returns 1 if a symbol is redeclared/redefined. * Otherwise returns 0 and, in some cases of minor problems, prints * a warning. */ int isredec(sym_t *dsym, int *warn) { sym_t *rsym; if ((rsym = dcs->d_rdcsym)->s_scl == ENUMCON) { /* redeclaration of %s */ error(27, dsym->s_name); prevdecl(-1, rsym); return (1); } if (rsym->s_scl == TYPEDEF) { /* typedef redeclared: %s */ error(89, dsym->s_name); prevdecl(-1, rsym); return (1); } if (dsym->s_scl == TYPEDEF) { /* redeclaration of %s */ error(27, dsym->s_name); prevdecl(-1, rsym); return (1); } if (rsym->s_def == DEF && dsym->s_def == DEF) { /* redefinition of %s */ error(28, dsym->s_name); prevdecl(-1, rsym); return(1); } if (!eqtype(rsym->s_type, dsym->s_type, 0, 0, warn)) { /* redeclaration of %s */ error(27, dsym->s_name); prevdecl(-1, rsym); return(1); } if (rsym->s_scl == EXTERN && dsym->s_scl == EXTERN) return(0); if (rsym->s_scl == STATIC && dsym->s_scl == STATIC) return(0); if (rsym->s_scl == STATIC && dsym->s_def == DECL) return(0); if (rsym->s_scl == EXTERN && rsym->s_def == DEF) { /* * All cases except "int a = 1; static int a;" are catched * above with or without a warning */ /* redeclaration of %s */ error(27, dsym->s_name); prevdecl(-1, rsym); return(1); } if (rsym->s_scl == EXTERN) { /* previously declared extern, becomes static: %s */ warning(29, dsym->s_name); prevdecl(-1, rsym); return(0); } /* * Now its on of: * "static a; int a;", "static a; int a = 1;", "static a = 1; int a;" */ /* redeclaration of %s; ANSI C requires "static" */ if (sflag) { warning(30, dsym->s_name); prevdecl(-1, rsym); } dsym->s_scl = STATIC; return (0); } /* * Checks if two types are compatible. Returns 0 if not, otherwise 1. * * ignqual ignore qualifiers of type; used for function params * promot promote left type; used for comparison of params of * old style function definitions with params of prototypes. * *warn set to 1 if an old style function declaration is not * compatible with a prototype */ int eqtype(type_t *tp1, type_t *tp2, int ignqual, int promot, int *warn) { tspec_t t; while (tp1 != NULL && tp2 != NULL) { t = tp1->t_tspec; if (promot) { if (t == FLOAT) { t = DOUBLE; } else if (t == CHAR || t == SCHAR) { t = INT; } else if (t == UCHAR) { t = tflag ? UINT : INT; } else if (t == SHORT) { t = INT; } else if (t == USHORT) { /* CONSTCOND */ t = INT_MAX < USHRT_MAX || tflag ? UINT : INT; } } if (t != tp2->t_tspec) return (0); if (tp1->t_const != tp2->t_const && !ignqual && !tflag) return (0); if (tp1->t_volatile != tp2->t_volatile && !ignqual && !tflag) return (0); if (t == STRUCT || t == UNION) return (tp1->t_str == tp2->t_str); if (t == ARRAY && tp1->t_dim != tp2->t_dim) { if (tp1->t_dim != 0 && tp2->t_dim != 0) return (0); } /* dont check prototypes for traditional */ if (t == FUNC && !tflag) { if (tp1->t_proto && tp2->t_proto) { if (!eqargs(tp1, tp2, warn)) return (0); } else if (tp1->t_proto) { if (!mnoarg(tp1, warn)) return (0); } else if (tp2->t_proto) { if (!mnoarg(tp2, warn)) return (0); } } tp1 = tp1->t_subt; tp2 = tp2->t_subt; ignqual = promot = 0; } return (tp1 == tp2); } /* * Compares the parameter types of two prototypes. */ static int eqargs(type_t *tp1, type_t *tp2, int *warn) { sym_t *a1, *a2; if (tp1->t_vararg != tp2->t_vararg) return (0); a1 = tp1->t_args; a2 = tp2->t_args; while (a1 != NULL && a2 != NULL) { if (eqtype(a1->s_type, a2->s_type, 1, 0, warn) == 0) return (0); a1 = a1->s_nxt; a2 = a2->s_nxt; } return (a1 == a2); } /* * mnoarg() (matches functions with no argument type information) * returns 1 if all parameters of a prototype are compatible with * and old style function declaration. * This is the case if following conditions are met: * 1. the prototype must have a fixed number of parameters * 2. no parameter is of type float * 3. no parameter is converted to another type if integer promotion * is applied on it */ static int mnoarg(type_t *tp, int *warn) { sym_t *arg; tspec_t t; if (tp->t_vararg) { if (warn != NULL) *warn = 1; } for (arg = tp->t_args; arg != NULL; arg = arg->s_nxt) { if ((t = arg->s_type->t_tspec) == FLOAT || t == CHAR || t == SCHAR || t == UCHAR || t == SHORT || t == USHORT) { if (warn != NULL) *warn = 1; } } return (1); } /* * Compares a prototype declaration with the remembered arguments of * a previous old style function definition. */ static int chkosdef(sym_t *rdsym, sym_t *dsym) { sym_t *args, *pargs, *arg, *parg; int narg, nparg, n; int warn, msg; args = rdsym->s_args; pargs = dsym->s_type->t_args; msg = 0; narg = nparg = 0; for (arg = args; arg != NULL; arg = arg->s_nxt) narg++; for (parg = pargs; parg != NULL; parg = parg->s_nxt) nparg++; if (narg != nparg) { /* prototype does not match old-style definition */ error(63); msg = 1; goto end; } arg = args; parg = pargs; n = 1; while (narg--) { warn = 0; /* * If it does not match due to promotion and sflag is * not set we print only a warning. */ if (!eqtype(arg->s_type, parg->s_type, 1, 1, &warn) || warn) { /* prototype does not match old-style def., arg #%d */ error(299, n); msg = 1; } arg = arg->s_nxt; parg = parg->s_nxt; n++; } end: if (msg) /* old style definition */ prevdecl(300, rdsym); return (msg); } /* * Complets a type by copying the dimension and prototype information * from a second compatible type. * * Following lines are legal: * "typedef a[]; a b; a b[10]; a c; a c[20];" * "typedef ft(); ft f; f(int); ft g; g(long);" * This means that, if a type is completed, the type structure must * be duplicated. */ void compltyp(sym_t *dsym, sym_t *ssym) { type_t **dstp, *src; type_t *dst; dstp = &dsym->s_type; src = ssym->s_type; while ((dst = *dstp) != NULL) { if (src == NULL || dst->t_tspec != src->t_tspec) lerror("compltyp() 1"); if (dst->t_tspec == ARRAY) { if (dst->t_dim == 0 && src->t_dim != 0) { *dstp = dst = duptyp(dst); dst->t_dim = src->t_dim; /* now a complete Typ */ setcompl(dst, 0); } } else if (dst->t_tspec == FUNC) { if (!dst->t_proto && src->t_proto) { *dstp = dst = duptyp(dst); dst->t_proto = 1; dst->t_args = src->t_args; } } dstp = &dst->t_subt; src = src->t_subt; } } /* * Completes the declaration of a single argument. */ sym_t * decl1arg(sym_t *sym, int initflg) { tspec_t t; chkfdef(sym, 1); chktyp(sym); if (dcs->d_rdcsym != NULL && dcs->d_rdcsym->s_blklev == blklev) { /* redeclaration of formal parameter %s */ error(237, sym->s_name); rmsym(dcs->d_rdcsym); sym->s_arg = 1; } if (!sym->s_arg) { /* declared argument %s is missing */ error(53, sym->s_name); sym->s_arg = 1; } if (initflg) { /* cannot initialize parameter: %s */ error(52, sym->s_name); initerr = 1; } if ((t = sym->s_type->t_tspec) == ARRAY) { sym->s_type = incref(sym->s_type->t_subt, PTR); } else if (t == FUNC) { if (tflag) /* a function is declared as an argument: %s */ warning(50, sym->s_name); sym->s_type = incref(sym->s_type, PTR); } else if (t == FLOAT) { if (tflag) sym->s_type = gettyp(DOUBLE); } if (dcs->d_inline) /* argument declared inline: %s */ warning(269, sym->s_name); /* * Arguments must have complete types. lengths() prints the needed * error messages (null dimension is impossible because arrays are * converted to pointers). */ if (sym->s_type->t_tspec != VOID) (void)length(sym->s_type, sym->s_name); setsflg(sym); return (sym); } /* * Does some checks for lint directives which apply to functions. * Processes arguments in old style function definitions which default * to int. * Checks compatiblility of old style function definition with previous * prototype. */ void cluparg(void) { sym_t *args, *arg, *pargs, *parg; int narg, nparg, n, msg; tspec_t t; args = funcsym->s_args; pargs = funcsym->s_type->t_args; /* check for illegal combinations of lint directives */ if (prflstrg != -1 && scflstrg != -1) { /* can't be used together: ** PRINTFLIKE ** ** SCANFLIKE ** */ warning(289); prflstrg = scflstrg = -1; } if (nvararg != -1 && (prflstrg != -1 || scflstrg != -1)) { /* dubious use of ** VARARGS ** with ** %s ** */ warning(288, prflstrg != -1 ? "PRINTFLIKE" : "SCANFLIKE"); nvararg = -1; } /* * check if the argument of a lint directive is compatible with the * number of arguments. */ narg = 0; for (arg = dcs->d_fargs; arg != NULL; arg = arg->s_nxt) narg++; if (nargusg > narg) { /* argument number mismatch with directive: ** %s ** */ warning(283, "ARGSUSED"); nargusg = 0; } if (nvararg > narg) { /* argument number mismatch with directive: ** %s ** */ warning(283, "VARARGS"); nvararg = 0; } if (prflstrg > narg) { /* argument number mismatch with directive: ** %s ** */ warning(283, "PRINTFLIKE"); prflstrg = -1; } else if (prflstrg == 0) { prflstrg = -1; } if (scflstrg > narg) { /* argument number mismatch with directive: ** %s ** */ warning(283, "SCANFLIKE"); scflstrg = -1; } else if (scflstrg == 0) { scflstrg = -1; } if (prflstrg != -1 || scflstrg != -1) { narg = prflstrg != -1 ? prflstrg : scflstrg; arg = dcs->d_fargs; for (n = 1; n < narg; n++) arg = arg->s_nxt; if (arg->s_type->t_tspec != PTR || ((t = arg->s_type->t_subt->t_tspec) != CHAR && t != UCHAR && t != SCHAR)) { /* arg. %d must be 'char *' for PRINTFLIKE/SCANFLIKE */ warning(293, narg); prflstrg = scflstrg = -1; } } /* * print a warning for each argument off an old style function * definition which defaults to int */ for (arg = args; arg != NULL; arg = arg->s_nxt) { if (arg->s_defarg) { /* argument type defaults to int: %s */ warning(32, arg->s_name); arg->s_defarg = 0; setsflg(arg); } } /* * If this is an old style function definition and a prototyp * exists, compare the types of arguments. */ if (funcsym->s_osdef && funcsym->s_type->t_proto) { /* * If the number of arguments does not macht, we need not * continue. */ narg = nparg = 0; msg = 0; for (parg = pargs; parg != NULL; parg = parg->s_nxt) nparg++; for (arg = args; arg != NULL; arg = arg->s_nxt) narg++; if (narg != nparg) { /* parameter mismatch: %d declared, %d defined */ error(51, nparg, narg); msg = 1; } else { parg = pargs; arg = args; while (narg--) { msg |= chkptdecl(arg, parg); parg = parg->s_nxt; arg = arg->s_nxt; } } if (msg) /* prototype declaration */ prevdecl(285, dcs->d_rdcsym); /* from now the prototype is valid */ funcsym->s_osdef = 0; funcsym->s_args = NULL; } } /* * Checks compatibility of an old style function definition with a previous * prototype declaration. * Returns 1 if the position of the previous declaration should be reported. */ static int chkptdecl(sym_t *arg, sym_t *parg) { type_t *tp, *ptp; int warn, msg; tp = arg->s_type; ptp = parg->s_type; msg = 0; warn = 0; if (!eqtype(tp, ptp, 1, 1, &warn)) { if (eqtype(tp, ptp, 1, 0, &warn)) { /* type does not match prototype: %s */ msg = gnuism(58, arg->s_name); } else { /* type does not match prototype: %s */ error(58, arg->s_name); msg = 1; } } else if (warn) { /* type does not match prototype: %s */ (*(sflag ? error : warning))(58, arg->s_name); msg = 1; } return (msg); } /* * Completes a single local declaration/definition. */ void decl1loc(sym_t *dsym, int initflg) { /* Correct a mistake done in dname(). */ if (dsym->s_type->t_tspec == FUNC) { dsym->s_def = DECL; if (dcs->d_scl == NOSCL) dsym->s_scl = EXTERN; } if (dsym->s_type->t_tspec == FUNC) { if (dsym->s_scl == STATIC) { /* dubious static function at block level: %s */ warning(93, dsym->s_name); dsym->s_scl = EXTERN; } else if (dsym->s_scl != EXTERN && dsym->s_scl != TYPEDEF) { /* function has illegal storage class: %s */ error(94, dsym->s_name); dsym->s_scl = EXTERN; } } /* * functions may be declared inline at local scope, although * this has no effect for a later definition of the same * function. * XXX it should have an effect if tflag is set. this would * also be the way gcc behaves. */ if (dcs->d_inline) { if (dsym->s_type->t_tspec == FUNC) { dsym->s_inline = 1; } else { /* variable declared inline: %s */ warning(268, dsym->s_name); } } chkfdef(dsym, 1); chktyp(dsym); if (dcs->d_rdcsym != NULL && dsym->s_scl == EXTERN) ledecl(dsym); if (dsym->s_scl == EXTERN) { /* * XXX wenn die statische Variable auf Ebene 0 erst * spaeter definiert wird, haben wir die Brille auf. */ if (dsym->s_xsym == NULL) { outsym(dsym, EXTERN, dsym->s_def); } else { outsym(dsym, dsym->s_xsym->s_scl, dsym->s_def); } } if (dcs->d_rdcsym != NULL) { if (dcs->d_rdcsym->s_blklev == 0) { switch (dsym->s_scl) { case AUTO: /* automatic hides external declaration: %s */ if (hflag) warning(86, dsym->s_name); break; case STATIC: /* static hides external declaration: %s */ if (hflag) warning(87, dsym->s_name); break; case TYPEDEF: /* typedef hides external declaration: %s */ if (hflag) warning(88, dsym->s_name); break; case EXTERN: /* * Warnings and errors are printed in ledecl() */ break; default: lerror("decl1loc() 1"); } } else if (dcs->d_rdcsym->s_blklev == blklev) { /* no hflag, because its illegal! */ if (dcs->d_rdcsym->s_arg) { /* * if !tflag, a "redeclaration of %s" error * is produced below */ if (tflag) { if (hflag) /* decl. hides parameter: %s */ warning(91, dsym->s_name); rmsym(dcs->d_rdcsym); } } } else if (dcs->d_rdcsym->s_blklev < blklev) { if (hflag) /* declaration hides earlier one: %s */ warning(95, dsym->s_name); } if (dcs->d_rdcsym->s_blklev == blklev) { /* redeclaration of %s */ error(27, dsym->s_name); rmsym(dcs->d_rdcsym); } } if (initflg && !(initerr = chkinit(dsym))) { dsym->s_def = DEF; setsflg(dsym); } if (dsym->s_scl == TYPEDEF) { dsym->s_type = duptyp(dsym->s_type); dsym->s_type->t_typedef = 1; settdsym(dsym->s_type, dsym); } /* * Before we can check the size we must wait for an initialisation * which may follow. */ } /* * Processes (re)declarations of external Symbols inside blocks. */ static void ledecl(sym_t *dsym) { int eqt, warn; sym_t *esym; /* look for a symbol with the same name */ esym = dcs->d_rdcsym; while (esym != NULL && esym->s_blklev != 0) { while ((esym = esym->s_link) != NULL) { if (esym->s_kind != FVFT) continue; if (strcmp(dsym->s_name, esym->s_name) == 0) break; } } if (esym == NULL) return; if (esym->s_scl != EXTERN && esym->s_scl != STATIC) { /* gcc accepts this without a warning, pcc prints an error. */ /* redeclaration of %s */ warning(27, dsym->s_name); prevdecl(-1, esym); return; } warn = 0; eqt = eqtype(esym->s_type, dsym->s_type, 0, 0, &warn); if (!eqt || warn) { if (esym->s_scl == EXTERN) { /* inconsistent redeclaration of extern: %s */ warning(90, dsym->s_name); prevdecl(-1, esym); } else { /* inconsistent redeclaration of static: %s */ warning(92, dsym->s_name); prevdecl(-1, esym); } } if (eqt) { /* * Remember the external symbol so we can update usage * information at the end of the block. */ dsym->s_xsym = esym; } } /* * Print an error or a warning if the symbol cant be initialized due * to type/storage class. Returnvalue is 1 if an error has been * detected. */ static int chkinit(sym_t *sym) { int err; err = 0; if (sym->s_type->t_tspec == FUNC) { /* cannot initialize function: %s */ error(24, sym->s_name); err = 1; } else if (sym->s_scl == TYPEDEF) { /* cannot initialize typedef: %s */ error(25, sym->s_name); err = 1; } else if (sym->s_scl == EXTERN && sym->s_def == DECL) { /* cannot initialize "extern" declaration: %s */ if (dcs->d_ctx == EXTERN) { warning(26, sym->s_name); } else { error(26, sym->s_name); err = 1; } } return (err); } /* * Create a symbole for an abstract declaration. */ sym_t * aname(void) { sym_t *sym; if (dcs->d_ctx != ABSTRACT && dcs->d_ctx != PARG) lerror("aname()"); sym = getblk(sizeof (sym_t)); sym->s_name = unnamed; sym->s_def = DEF; sym->s_scl = ABSTRACT; sym->s_blklev = -1; if (dcs->d_ctx == PARG) sym->s_arg = 1; sym->s_type = dcs->d_type; dcs->d_rdcsym = NULL; dcs->d_vararg = 0; return (sym); } /* * Removes anything which has nothing to do on global level. */ void globclup(void) { while (dcs->d_nxt != NULL) popdecl(); cleanup(); blklev = 0; mblklev = 0; /* * remove all informations about pending lint directives without * warnings. */ glclup(1); } /* * Process an abstract type declaration */ sym_t * decl1abs(sym_t *sym) { chkfdef(sym, 1); chktyp(sym); return (sym); } /* * Checks size after declarations of variables and their initialisation. */ void chksz(sym_t *dsym) { /* * check size only for symbols which are defined and no function and * not typedef name */ if (dsym->s_def != DEF) return; if (dsym->s_scl == TYPEDEF) return; if (dsym->s_type->t_tspec == FUNC) return; if (length(dsym->s_type, dsym->s_name) == 0 && dsym->s_type->t_tspec == ARRAY && dsym->s_type->t_dim == 0) { /* empty array declaration: %s */ if (tflag) { warning(190, dsym->s_name); } else { error(190, dsym->s_name); } } } /* * Mark an object as set if it is not already */ void setsflg(sym_t *sym) { if (!sym->s_set) { sym->s_set = 1; UNIQUE_CURR_POS(sym->s_spos); } } /* * Mark an object as used if it is not already */ void setuflg(sym_t *sym, int fcall, int szof) { if (!sym->s_used) { sym->s_used = 1; UNIQUE_CURR_POS(sym->s_upos); } /* * for function calls another record is written * * XXX Should symbols used in sizeof() treated as used or not? * Probably not, because there is no sense to declare an * external variable only to get their size. */ if (!fcall && !szof && sym->s_kind == FVFT && sym->s_scl == EXTERN) outusg(sym); } /* * Prints warnings for a list of variables and labels (concatenated * with s_dlnxt) if these are not used or only set. */ void chkusage(dinfo_t *di) { sym_t *sym; int mknowarn; /* for this warnings LINTED has no effect */ mknowarn = nowarn; nowarn = 0; for (sym = di->d_dlsyms; sym != NULL; sym = sym->s_dlnxt) chkusg1(di->d_asm, sym); nowarn = mknowarn; } /* * Prints a warning for a single variable or label if it is not used or * only set. */ void chkusg1(int novar, sym_t *sym) { pos_t cpos; if (sym->s_blklev == -1) return; STRUCT_ASSIGN(cpos, curr_pos); if (sym->s_kind == FVFT) { if (sym->s_arg) { chkausg(novar, sym); } else { chkvusg(novar, sym); } } else if (sym->s_kind == FLAB) { chklusg(sym); } else if (sym->s_kind == FTAG) { chktusg(sym); } STRUCT_ASSIGN(curr_pos, cpos); } static void chkausg(int novar, sym_t *arg) { if (!arg->s_set) lerror("chkausg() 1"); if (novar) return; if (!arg->s_used && vflag) { STRUCT_ASSIGN(curr_pos, arg->s_dpos); /* argument %s unused in function %s */ warning(231, arg->s_name, funcsym->s_name); } } static void chkvusg(int novar, sym_t *sym) { scl_t sc; sym_t *xsym; if (blklev == 0 || sym->s_blklev == 0) lerror("chkvusg() 1"); /* errors in expressions easily cause lots of these warnings */ if (nerr != 0) return; /* * XXX Only variables are checkd, although types should * probably also be checked */ if ((sc = sym->s_scl) != EXTERN && sc != STATIC && sc != AUTO && sc != REG) { return; } if (novar) return; if (sc == EXTERN) { if (!sym->s_used && !sym->s_set) { STRUCT_ASSIGN(curr_pos, sym->s_dpos); /* %s unused in function %s */ warning(192, sym->s_name, funcsym->s_name); } } else { if (sym->s_set && !sym->s_used) { STRUCT_ASSIGN(curr_pos, sym->s_spos); /* %s set but not used in function %s */ warning(191, sym->s_name, funcsym->s_name); } else if (!sym->s_used) { STRUCT_ASSIGN(curr_pos, sym->s_dpos); /* %s unused in function %s */ warning(192, sym->s_name, funcsym->s_name); } } if (sc == EXTERN) { /* * information about usage is taken over into the symbol * tabel entry at level 0 if the symbol was locally declared * as an external symbol. * * XXX This is wrong for symbols declared static at level 0 * if the usage information stems from sizeof(). This is * because symbols at level 0 only used in sizeof() are * considered to not be used. */ if ((xsym = sym->s_xsym) != NULL) { if (sym->s_used && !xsym->s_used) { xsym->s_used = 1; STRUCT_ASSIGN(xsym->s_upos, sym->s_upos); } if (sym->s_set && !xsym->s_set) { xsym->s_set = 1; STRUCT_ASSIGN(xsym->s_spos, sym->s_spos); } } } } static void chklusg(sym_t *lab) { if (blklev != 1 || lab->s_blklev != 1) lerror("chklusg() 1"); if (lab->s_set && !lab->s_used) { STRUCT_ASSIGN(curr_pos, lab->s_spos); /* label %s unused in function %s */ warning(192, lab->s_name, funcsym->s_name); } else if (!lab->s_set) { STRUCT_ASSIGN(curr_pos, lab->s_upos); /* undefined label %s */ warning(23, lab->s_name); } } static void chktusg(sym_t *sym) { if (!incompl(sym->s_type)) return; /* complain alwasy about incomplet tags declared inside blocks */ if (!zflag || dcs->d_ctx != EXTERN) return; STRUCT_ASSIGN(curr_pos, sym->s_dpos); switch (sym->s_type->t_tspec) { case STRUCT: /* struct %s never defined */ warning(233, sym->s_name); break; case UNION: /* union %s never defined */ warning(234, sym->s_name); break; case ENUM: /* enum %s never defined */ warning(235, sym->s_name); break; default: lerror("chktusg() 1"); } } /* * Called after the entire translation unit has been parsed. * Changes tentative definitions in definitions. * Performs some tests on global Symbols. Detected Problems are: * - defined variables of incomplete type * - constant variables which are not initialized * - static symbols which are never used */ void chkglsyms(void) { sym_t *sym; pos_t cpos; if (blklev != 0 || dcs->d_nxt != NULL) norecover(); STRUCT_ASSIGN(cpos, curr_pos); for (sym = dcs->d_dlsyms; sym != NULL; sym = sym->s_dlnxt) { if (sym->s_blklev == -1) continue; if (sym->s_kind == FVFT) { chkglvar(sym); } else if (sym->s_kind == FTAG) { chktusg(sym); } else { if (sym->s_kind != FMOS) lerror("chkglsyms() 1"); } } STRUCT_ASSIGN(curr_pos, cpos); } static void chkglvar(sym_t *sym) { if (sym->s_scl == TYPEDEF || sym->s_scl == ENUMCON) return; if (sym->s_scl != EXTERN && sym->s_scl != STATIC) lerror("chkglvar() 1"); glchksz(sym); if (sym->s_scl == STATIC) { if (sym->s_type->t_tspec == FUNC) { if (sym->s_used && sym->s_def != DEF) { STRUCT_ASSIGN(curr_pos, sym->s_upos); /* static func. called but not def.. */ error(225, sym->s_name); } } if (!sym->s_used) { STRUCT_ASSIGN(curr_pos, sym->s_dpos); if (sym->s_type->t_tspec == FUNC) { if (sym->s_def == DEF) { if (!sym->s_inline) /* static function %s unused */ warning(236, sym->s_name); } else { /* static function %s decl. but ... */ warning(290, sym->s_name); } } else if (!sym->s_set) { /* static variable %s unused */ warning(226, sym->s_name); } else { /* static variable %s set but not used */ warning(307, sym->s_name); } } if (!tflag && sym->s_def == TDEF && sym->s_type->t_const) { STRUCT_ASSIGN(curr_pos, sym->s_dpos); /* const object %s should have initializer */ warning(227, sym->s_name); } } } static void glchksz(sym_t *sym) { if (sym->s_def == TDEF) { if (sym->s_type->t_tspec == FUNC) /* * this can happen if a syntax error occurred * after a function declaration */ return; STRUCT_ASSIGN(curr_pos, sym->s_dpos); if (length(sym->s_type, sym->s_name) == 0 && sym->s_type->t_tspec == ARRAY && sym->s_type->t_dim == 0) { /* empty array declaration: %s */ if (tflag || (sym->s_scl == EXTERN && !sflag)) { warning(190, sym->s_name); } else { error(190, sym->s_name); } } } } /* * Prints information about location of previous definition/declaration. */ void prevdecl(int msg, sym_t *psym) { pos_t cpos; if (!rflag) return; STRUCT_ASSIGN(cpos, curr_pos); STRUCT_ASSIGN(curr_pos, psym->s_dpos); if (msg != -1) { message(msg, psym->s_name); } else if (psym->s_def == DEF || psym->s_def == TDEF) { /* previous definition of %s */ message(261, psym->s_name); } else { /* previous declaration of %s */ message(260, psym->s_name); } STRUCT_ASSIGN(curr_pos, cpos); }