freebsd-skq/usr.bin/xlint/lint1/func.c
2011-12-30 11:02:40 +00:00

1289 lines
26 KiB
C

/* $NetBSD: func.c,v 1.16 2002/01/03 04:25:15 thorpej Exp $ */
/*
* 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: func.c,v 1.16 2002/01/03 04:25:15 thorpej Exp $");
#endif
__FBSDID("$FreeBSD$");
#include <stdlib.h>
#include <string.h>
#include "lint1.h"
#include "cgram.h"
/*
* Contains a pointer to the symbol table entry of the current function
* definition.
*/
sym_t *funcsym;
/* Is set as long as a statement can be reached. Must be set at level 0. */
int reached = 1;
/*
* Is set as long as NOTREACHED is in effect.
* Is reset everywhere where reached can become 0.
*/
int rchflg;
/*
* In conjunction with reached controls printing of "fallthrough on ..."
* warnings.
* Reset by each statement and set by FALLTHROUGH, switch (switch1())
* and case (label()).
*
* Control statements if, for, while and switch do not reset ftflg because
* this must be done by the controlled statement. At least for if this is
* important because ** FALLTHROUGH ** after "if (expr) stmnt" is evaluated
* before the following token, which causes reduction of above, is read.
* This means that ** FALLTHROUGH ** after "if ..." would always be ignored.
*/
int ftflg;
/* Top element of stack for control statements */
cstk_t *cstk;
/*
* Number of arguments which will be checked for usage in following
* function definition. -1 stands for all arguments.
*
* The position of the last ARGSUSED comment is stored in aupos.
*/
int nargusg = -1;
pos_t aupos;
/*
* Number of arguments of the following function definition whose types
* shall be checked by lint2. -1 stands for all arguments.
*
* The position of the last VARARGS comment is stored in vapos.
*/
int nvararg = -1;
pos_t vapos;
/*
* Both prflstr and scflstrg contain the number of the argument which
* shall be used to check the types of remaining arguments (for PRINTFLIKE
* and SCANFLIKE).
*
* prflpos and scflpos are the positions of the last PRINTFLIKE or
* SCANFLIKE comment.
*/
int prflstrg = -1;
int scflstrg = -1;
pos_t prflpos;
pos_t scflpos;
/*
* Are both plibflg and llibflg set, prototypes are written as function
* definitions to the output file.
*/
int plibflg;
/*
* Nonzero means that no warnings about constants in conditional
* context are printed.
*/
int ccflg;
/*
* llibflg is set if a lint library shall be created. The effect of
* llibflg is that all defined symbols are treated as used.
* (The LINTLIBRARY comment also resets vflag.)
*/
int llibflg;
/*
* Nonzero if warnings are suppressed by a LINTED directive
*/
int nowarn;
/*
* Nonzero if bitfield type errors are suppressed by a BITFIELDTYPE
* directive.
*/
int bitfieldtype_ok;
/*
* Nonzero if complaints about use of "long long" are suppressed in
* the next statement or declaration.
*/
int quadflg;
/*
* Puts a new element at the top of the stack used for control statements.
*/
void
pushctrl(int env)
{
cstk_t *ci;
if ((ci = calloc(1, sizeof (cstk_t))) == NULL)
nomem();
ci->c_env = env;
ci->c_nxt = cstk;
cstk = ci;
}
/*
* Removes the top element of the stack used for control statements.
*/
void
popctrl(int env)
{
cstk_t *ci;
clst_t *cl;
if (cstk == NULL || cstk->c_env != env)
lerror("popctrl() 1");
cstk = (ci = cstk)->c_nxt;
while ((cl = ci->c_clst) != NULL) {
ci->c_clst = cl->cl_nxt;
free(cl);
}
if (ci->c_swtype != NULL)
free(ci->c_swtype);
free(ci);
}
/*
* Prints a warning if a statement cannot be reached.
*/
void
chkreach(void)
{
if (!reached && !rchflg) {
/* statement not reached */
warning(193);
reached = 1;
}
}
/*
* Called after a function declaration which introduces a function definition
* and before an (optional) old style argument declaration list.
*
* Puts all symbols declared in the Prototype or in an old style argument
* list back to the symbol table.
*
* Does the usual checking of storage class, type (return value),
* redeclaration etc..
*/
void
funcdef(sym_t *fsym)
{
int n, warn;
sym_t *arg, *sym, *rdsym;
funcsym = fsym;
/*
* Put all symbols declared in the argument list back to the
* symbol table.
*/
for (sym = dcs->d_fpsyms; sym != NULL; sym = sym->s_dlnxt) {
if (sym->s_blklev != -1) {
if (sym->s_blklev != 1)
lerror("funcdef() 1");
inssym(1, sym);
}
}
/*
* In osfunc() we did not know whether it is an old style function
* definition or only an old style declaration, if there are no
* arguments inside the argument list ("f()").
*/
if (!fsym->s_type->t_proto && fsym->s_args == NULL)
fsym->s_osdef = 1;
chktyp(fsym);
/*
* chktyp() checks for almost all possible errors, but not for
* incomplete return values (these are allowed in declarations)
*/
if (fsym->s_type->t_subt->t_tspec != VOID &&
incompl(fsym->s_type->t_subt)) {
/* cannot return incomplete type */
error(67);
}
fsym->s_def = DEF;
if (fsym->s_scl == TYPEDEF) {
fsym->s_scl = EXTERN;
/* illegal storage class */
error(8);
}
if (dcs->d_inline)
fsym->s_inline = 1;
/*
* Arguments in new style function declarations need a name.
* (void is already removed from the list of arguments)
*/
n = 1;
for (arg = fsym->s_type->t_args; arg != NULL; arg = arg->s_nxt) {
if (arg->s_scl == ABSTRACT) {
if (arg->s_name != unnamed)
lerror("funcdef() 2");
/* formal parameter lacks name: param #%d */
error(59, n);
} else {
if (arg->s_name == unnamed)
lerror("funcdef() 3");
}
n++;
}
/*
* We must also remember the position. s_dpos is overwritten
* if this is an old style definition and we had already a
* prototype.
*/
STRUCT_ASSIGN(dcs->d_fdpos, fsym->s_dpos);
if ((rdsym = dcs->d_rdcsym) != NULL) {
if (!isredec(fsym, (warn = 0, &warn))) {
/*
* Print nothing if the newly defined function
* is defined in old style. A better warning will
* be printed in cluparg().
*/
if (warn && !fsym->s_osdef) {
/* redeclaration of %s */
(*(sflag ? error : warning))(27, fsym->s_name);
prevdecl(-1, rdsym);
}
/* copy usage information */
cpuinfo(fsym, rdsym);
/*
* If the old symbol was a prototype and the new
* one is none, overtake the position of the
* declaration of the prototype.
*/
if (fsym->s_osdef && rdsym->s_type->t_proto)
STRUCT_ASSIGN(fsym->s_dpos, rdsym->s_dpos);
/* complete the type */
compltyp(fsym, rdsym);
/* once a function is inline it remains inline */
if (rdsym->s_inline)
fsym->s_inline = 1;
}
/* remove the old symbol from the symbol table */
rmsym(rdsym);
}
if (fsym->s_osdef && !fsym->s_type->t_proto) {
if (sflag && hflag && strcmp(fsym->s_name, "main") != 0)
/* function definition is not a prototype */
warning(286);
}
if (dcs->d_notyp)
/* return value is implicitly declared to be int */
fsym->s_rimpl = 1;
reached = 1;
}
/*
* Called at the end of a function definition.
*/
void
funcend(void)
{
sym_t *arg;
int n;
if (reached) {
cstk->c_noretval = 1;
if (funcsym->s_type->t_subt->t_tspec != VOID &&
!funcsym->s_rimpl) {
/* func. %s falls off bottom without returning value */
warning(217, funcsym->s_name);
}
}
/*
* This warning is printed only if the return value was implicitly
* declared to be int. Otherwise the wrong return statement
* has already printed a warning.
*/
if (cstk->c_noretval && cstk->c_retval && funcsym->s_rimpl)
/* function %s has return (e); and return; */
warning(216, funcsym->s_name);
/* Print warnings for unused arguments */
arg = dcs->d_fargs;
n = 0;
while (arg != NULL && (nargusg == -1 || n < nargusg)) {
chkusg1(dcs->d_asm, arg);
arg = arg->s_nxt;
n++;
}
nargusg = -1;
/*
* write the information about the function definition to the
* output file
* inline functions explicitly declared extern are written as
* declarations only.
*/
if (dcs->d_scl == EXTERN && funcsym->s_inline) {
outsym(funcsym, funcsym->s_scl, DECL);
} else {
outfdef(funcsym, &dcs->d_fdpos, cstk->c_retval,
funcsym->s_osdef, dcs->d_fargs);
}
/*
* remove all symbols declared during argument declaration from
* the symbol table
*/
if (dcs->d_nxt != NULL || dcs->d_ctx != EXTERN)
lerror("funcend() 1");
rmsyms(dcs->d_fpsyms);
/* must be set on level 0 */
reached = 1;
}
/*
* Process a label.
*
* typ type of the label (T_NAME, T_DEFAULT or T_CASE).
* sym symbol table entry of label if typ == T_NAME
* tn expression if typ == T_CASE
*/
void
label(int typ, sym_t *sym, tnode_t *tn)
{
cstk_t *ci;
clst_t *cl;
val_t *v;
val_t nv;
tspec_t t;
switch (typ) {
case T_NAME:
if (sym->s_set) {
/* label %s redefined */
error(194, sym->s_name);
} else {
setsflg(sym);
}
break;
case T_CASE:
/* find the stack entry for the innermost switch statement */
for (ci = cstk; ci != NULL && !ci->c_switch; ci = ci->c_nxt)
continue;
if (ci == NULL) {
/* case not in switch */
error(195);
tn = NULL;
} else if (tn != NULL && tn->tn_op != CON) {
/* non-constant case expression */
error(197);
tn = NULL;
} else if (tn != NULL && !isityp(tn->tn_type->t_tspec)) {
/* non-integral case expression */
error(198);
tn = NULL;
}
if (tn != NULL) {
if (ci->c_swtype == NULL)
lerror("label() 1");
if (reached && !ftflg) {
if (hflag)
/* fallthrough on case statement */
warning(220);
}
t = tn->tn_type->t_tspec;
if (t == LONG || t == ULONG ||
t == QUAD || t == UQUAD) {
if (tflag)
/* case label must be of type ... */
warning(203);
}
/*
* get the value of the expression and convert it
* to the type of the switch expression
*/
v = constant(tn);
(void) memset(&nv, 0, sizeof nv);
cvtcon(CASE, 0, ci->c_swtype, &nv, v);
free(v);
/* look if we had this value already */
for (cl = ci->c_clst; cl != NULL; cl = cl->cl_nxt) {
if (cl->cl_val.v_quad == nv.v_quad)
break;
}
if (cl != NULL && isutyp(nv.v_tspec)) {
/* duplicate case in switch, %lu */
error(200, (u_long)nv.v_quad);
} else if (cl != NULL) {
/* duplicate case in switch, %ld */
error(199, (long)nv.v_quad);
} else {
/*
* append the value to the list of
* case values
*/
cl = xcalloc(1, sizeof (clst_t));
STRUCT_ASSIGN(cl->cl_val, nv);
cl->cl_nxt = ci->c_clst;
ci->c_clst = cl;
}
}
tfreeblk();
break;
case T_DEFAULT:
/* find the stack entry for the innermost switch statement */
for (ci = cstk; ci != NULL && !ci->c_switch; ci = ci->c_nxt)
continue;
if (ci == NULL) {
/* default outside switch */
error(201);
} else if (ci->c_default) {
/* duplicate default in switch */
error(202);
} else {
if (reached && !ftflg) {
if (hflag)
/* fallthrough on default statement */
warning(284);
}
ci->c_default = 1;
}
break;
};
reached = 1;
}
/*
* T_IF T_LPARN expr T_RPARN
*/
void
if1(tnode_t *tn)
{
if (tn != NULL)
tn = cconv(tn);
if (tn != NULL)
tn = promote(NOOP, 0, tn);
expr(tn, 0, 1);
pushctrl(T_IF);
}
/*
* if_without_else
* if_without_else T_ELSE
*/
void
if2(void)
{
cstk->c_rchif = reached ? 1 : 0;
reached = 1;
}
/*
* if_without_else
* if_without_else T_ELSE stmnt
*/
void
if3(int els)
{
if (els) {
reached |= cstk->c_rchif;
} else {
reached = 1;
}
popctrl(T_IF);
}
/*
* T_SWITCH T_LPARN expr T_RPARN
*/
void
switch1(tnode_t *tn)
{
tspec_t t;
type_t *tp;
if (tn != NULL)
tn = cconv(tn);
if (tn != NULL)
tn = promote(NOOP, 0, tn);
if (tn != NULL && !isityp(tn->tn_type->t_tspec)) {
/* switch expression must have integral type */
error(205);
tn = NULL;
}
if (tn != NULL && tflag) {
t = tn->tn_type->t_tspec;
if (t == LONG || t == ULONG || t == QUAD || t == UQUAD) {
/* switch expr. must be of type `int' in trad. C */
warning(271);
}
}
/*
* Remember the type of the expression. Because its possible
* that (*tp) is allocated on tree memory the type must be
* duplicated. This is not too complicated because it is
* only an integer type.
*/
if ((tp = calloc(1, sizeof (type_t))) == NULL)
nomem();
if (tn != NULL) {
tp->t_tspec = tn->tn_type->t_tspec;
if ((tp->t_isenum = tn->tn_type->t_isenum) != 0)
tp->t_enum = tn->tn_type->t_enum;
} else {
tp->t_tspec = INT;
}
expr(tn, 1, 0);
pushctrl(T_SWITCH);
cstk->c_switch = 1;
cstk->c_swtype = tp;
reached = rchflg = 0;
ftflg = 1;
}
/*
* switch_expr stmnt
*/
void
switch2(void)
{
int nenum = 0, nclab = 0;
sym_t *esym;
clst_t *cl;
if (cstk->c_swtype == NULL)
lerror("switch2() 1");
/*
* If the switch expression was of type enumeration, count the case
* labels and the number of enumerators. If both counts are not
* equal print a warning.
*/
if (cstk->c_swtype->t_isenum) {
nenum = nclab = 0;
if (cstk->c_swtype->t_enum == NULL)
lerror("switch2() 2");
for (esym = cstk->c_swtype->t_enum->elem;
esym != NULL; esym = esym->s_nxt) {
nenum++;
}
for (cl = cstk->c_clst; cl != NULL; cl = cl->cl_nxt)
nclab++;
if (hflag && eflag && nenum != nclab && !cstk->c_default) {
/* enumeration value(s) not handled in switch */
warning(206);
}
}
if (cstk->c_break) {
/*
* end of switch alway reached (c_break is only set if the
* break statement can be reached).
*/
reached = 1;
} else if (!cstk->c_default &&
(!hflag || !cstk->c_swtype->t_isenum || nenum != nclab)) {
/*
* there are possible values which are not handled in
* switch
*/
reached = 1;
} /*
* otherwise the end of the switch expression is reached
* if the end of the last statement inside it is reached.
*/
popctrl(T_SWITCH);
}
/*
* T_WHILE T_LPARN expr T_RPARN
*/
void
while1(tnode_t *tn)
{
if (!reached) {
/* loop not entered at top */
warning(207);
reached = 1;
}
if (tn != NULL)
tn = cconv(tn);
if (tn != NULL)
tn = promote(NOOP, 0, tn);
if (tn != NULL && !issclt(tn->tn_type->t_tspec)) {
/* controlling expressions must have scalar type */
error(204);
tn = NULL;
}
pushctrl(T_WHILE);
cstk->c_loop = 1;
if (tn != NULL && tn->tn_op == CON) {
if (isityp(tn->tn_type->t_tspec)) {
cstk->c_infinite = tn->tn_val->v_quad != 0;
} else {
cstk->c_infinite = tn->tn_val->v_ldbl != 0.0;
}
}
expr(tn, 0, 1);
}
/*
* while_expr stmnt
* while_expr error
*/
void
while2(void)
{
/*
* The end of the loop can be reached if it is no endless loop
* or there was a break statement which was reached.
*/
reached = !cstk->c_infinite || cstk->c_break;
rchflg = 0;
popctrl(T_WHILE);
}
/*
* T_DO
*/
void
do1(void)
{
if (!reached) {
/* loop not entered at top */
warning(207);
reached = 1;
}
pushctrl(T_DO);
cstk->c_loop = 1;
}
/*
* do stmnt do_while_expr
* do error
*/
void
do2(tnode_t *tn)
{
/*
* If there was a continue statement the expression controlling the
* loop is reached.
*/
if (cstk->c_cont)
reached = 1;
if (tn != NULL)
tn = cconv(tn);
if (tn != NULL)
tn = promote(NOOP, 0, tn);
if (tn != NULL && !issclt(tn->tn_type->t_tspec)) {
/* controlling expressions must have scalar type */
error(204);
tn = NULL;
}
if (tn != NULL && tn->tn_op == CON) {
if (isityp(tn->tn_type->t_tspec)) {
cstk->c_infinite = tn->tn_val->v_quad != 0;
} else {
cstk->c_infinite = tn->tn_val->v_ldbl != 0.0;
}
}
expr(tn, 0, 1);
/*
* The end of the loop is only reached if it is no endless loop
* or there was a break statement which could be reached.
*/
reached = !cstk->c_infinite || cstk->c_break;
rchflg = 0;
popctrl(T_DO);
}
/*
* T_FOR T_LPARN opt_expr T_SEMI opt_expr T_SEMI opt_expr T_RPARN
*/
void
for1(tnode_t *tn1, tnode_t *tn2, tnode_t *tn3)
{
/*
* If there is no initialisation expression it is possible that
* it is intended not to enter the loop at top.
*/
if (tn1 != NULL && !reached) {
/* loop not entered at top */
warning(207);
reached = 1;
}
pushctrl(T_FOR);
cstk->c_loop = 1;
/*
* Store the tree memory for the reinitialisation expression.
* Also remember this expression itself. We must check it at
* the end of the loop to get "used but not set" warnings correct.
*/
cstk->c_fexprm = tsave();
cstk->c_f3expr = tn3;
STRUCT_ASSIGN(cstk->c_fpos, curr_pos);
STRUCT_ASSIGN(cstk->c_cfpos, csrc_pos);
if (tn1 != NULL)
expr(tn1, 0, 0);
if (tn2 != NULL)
tn2 = cconv(tn2);
if (tn2 != NULL)
tn2 = promote(NOOP, 0, tn2);
if (tn2 != NULL && !issclt(tn2->tn_type->t_tspec)) {
/* controlling expressions must have scalar type */
error(204);
tn2 = NULL;
}
if (tn2 != NULL)
expr(tn2, 0, 1);
if (tn2 == NULL) {
cstk->c_infinite = 1;
} else if (tn2->tn_op == CON) {
if (isityp(tn2->tn_type->t_tspec)) {
cstk->c_infinite = tn2->tn_val->v_quad != 0;
} else {
cstk->c_infinite = tn2->tn_val->v_ldbl != 0.0;
}
}
/* Checking the reinitialisation expression is done in for2() */
reached = 1;
}
/*
* for_exprs stmnt
* for_exprs error
*/
void
for2(void)
{
pos_t cpos, cspos;
tnode_t *tn3;
if (cstk->c_cont)
reached = 1;
STRUCT_ASSIGN(cpos, curr_pos);
STRUCT_ASSIGN(cspos, csrc_pos);
/* Restore the tree memory for the reinitialisation expression */
trestor(cstk->c_fexprm);
tn3 = cstk->c_f3expr;
STRUCT_ASSIGN(curr_pos, cstk->c_fpos);
STRUCT_ASSIGN(csrc_pos, cstk->c_cfpos);
/* simply "statement not reached" would be confusing */
if (!reached && !rchflg) {
/* end-of-loop code not reached */
warning(223);
reached = 1;
}
if (tn3 != NULL) {
expr(tn3, 0, 0);
} else {
tfreeblk();
}
STRUCT_ASSIGN(curr_pos, cpos);
STRUCT_ASSIGN(csrc_pos, cspos);
/* An endless loop without break will never terminate */
reached = cstk->c_break || !cstk->c_infinite;
rchflg = 0;
popctrl(T_FOR);
}
/*
* T_GOTO identifier T_SEMI
* T_GOTO error T_SEMI
*/
void
dogoto(sym_t *lab)
{
setuflg(lab, 0, 0);
chkreach();
reached = rchflg = 0;
}
/*
* T_BREAK T_SEMI
*/
void
dobreak(void)
{
cstk_t *ci;
ci = cstk;
while (ci != NULL && !ci->c_loop && !ci->c_switch)
ci = ci->c_nxt;
if (ci == NULL) {
/* break outside loop or switch */
error(208);
} else {
if (reached)
ci->c_break = 1;
}
if (bflag)
chkreach();
reached = rchflg = 0;
}
/*
* T_CONTINUE T_SEMI
*/
void
docont(void)
{
cstk_t *ci;
for (ci = cstk; ci != NULL && !ci->c_loop; ci = ci->c_nxt)
continue;
if (ci == NULL) {
/* continue outside loop */
error(209);
} else {
ci->c_cont = 1;
}
chkreach();
reached = rchflg = 0;
}
/*
* T_RETURN T_SEMI
* T_RETURN expr T_SEMI
*/
void
doreturn(tnode_t *tn)
{
tnode_t *ln, *rn;
cstk_t *ci;
op_t op;
for (ci = cstk; ci->c_nxt != NULL; ci = ci->c_nxt)
continue;
if (tn != NULL) {
ci->c_retval = 1;
} else {
ci->c_noretval = 1;
}
if (tn != NULL && funcsym->s_type->t_subt->t_tspec == VOID) {
/* void function %s cannot return value */
error(213, funcsym->s_name);
tfreeblk();
tn = NULL;
} else if (tn == NULL && funcsym->s_type->t_subt->t_tspec != VOID) {
/*
* Assume that the function has a return value only if it
* is explicitly declared.
*/
if (!funcsym->s_rimpl)
/* function %s expects to return value */
warning(214, funcsym->s_name);
}
if (tn != NULL) {
/* Create a temporary node for the left side */
ln = tgetblk(sizeof (tnode_t));
ln->tn_op = NAME;
ln->tn_type = tduptyp(funcsym->s_type->t_subt);
ln->tn_type->t_const = 0;
ln->tn_lvalue = 1;
ln->tn_sym = funcsym; /* better than nothing */
tn = build(RETURN, ln, tn);
if (tn != NULL) {
rn = tn->tn_right;
while ((op = rn->tn_op) == CVT || op == PLUS)
rn = rn->tn_left;
if (rn->tn_op == AMPER && rn->tn_left->tn_op == NAME &&
rn->tn_left->tn_sym->s_scl == AUTO) {
/* %s returns pointer to automatic object */
warning(302, funcsym->s_name);
}
}
expr(tn, 1, 0);
} else {
chkreach();
}
reached = rchflg = 0;
}
/*
* Do some cleanup after a global declaration or definition.
* Especially remove informations about unused lint comments.
*/
void
glclup(int silent)
{
pos_t cpos;
STRUCT_ASSIGN(cpos, curr_pos);
if (nargusg != -1) {
if (!silent) {
STRUCT_ASSIGN(curr_pos, aupos);
/* must precede function definition: %s */
warning(282, "ARGSUSED");
}
nargusg = -1;
}
if (nvararg != -1) {
if (!silent) {
STRUCT_ASSIGN(curr_pos, vapos);
/* must precede function definition: %s */
warning(282, "VARARGS");
}
nvararg = -1;
}
if (prflstrg != -1) {
if (!silent) {
STRUCT_ASSIGN(curr_pos, prflpos);
/* must precede function definition: %s */
warning(282, "PRINTFLIKE");
}
prflstrg = -1;
}
if (scflstrg != -1) {
if (!silent) {
STRUCT_ASSIGN(curr_pos, scflpos);
/* must precede function definition: %s */
warning(282, "SCANFLIKE");
}
scflstrg = -1;
}
STRUCT_ASSIGN(curr_pos, cpos);
dcs->d_asm = 0;
}
/*
* ARGSUSED comment
*
* Only the first n arguments of the following function are checked
* for usage. A missing argument is taken to be 0.
*/
void
argsused(int n)
{
if (n == -1)
n = 0;
if (dcs->d_ctx != EXTERN) {
/* must be outside function: ** %s ** */
warning(280, "ARGSUSED");
return;
}
if (nargusg != -1) {
/* duplicate use of ** %s ** */
warning(281, "ARGSUSED");
}
nargusg = n;
STRUCT_ASSIGN(aupos, curr_pos);
}
/*
* VARARGS comment
*
* Makes that lint2 checks only the first n arguments for compatibility
* to the function definition. A missing argument is taken to be 0.
*/
void
varargs(int n)
{
if (n == -1)
n = 0;
if (dcs->d_ctx != EXTERN) {
/* must be outside function: ** %s ** */
warning(280, "VARARGS");
return;
}
if (nvararg != -1) {
/* duplicate use of ** %s ** */
warning(281, "VARARGS");
}
nvararg = n;
STRUCT_ASSIGN(vapos, curr_pos);
}
/*
* PRINTFLIKE comment
*
* Check all arguments until the (n-1)-th as usual. The n-th argument is
* used the check the types of remaining arguments.
*/
void
printflike(int n)
{
if (n == -1)
n = 0;
if (dcs->d_ctx != EXTERN) {
/* must be outside function: ** %s ** */
warning(280, "PRINTFLIKE");
return;
}
if (prflstrg != -1) {
/* duplicate use of ** %s ** */
warning(281, "PRINTFLIKE");
}
prflstrg = n;
STRUCT_ASSIGN(prflpos, curr_pos);
}
/*
* SCANFLIKE comment
*
* Check all arguments until the (n-1)-th as usual. The n-th argument is
* used the check the types of remaining arguments.
*/
void
scanflike(int n)
{
if (n == -1)
n = 0;
if (dcs->d_ctx != EXTERN) {
/* must be outside function: ** %s ** */
warning(280, "SCANFLIKE");
return;
}
if (scflstrg != -1) {
/* duplicate use of ** %s ** */
warning(281, "SCANFLIKE");
}
scflstrg = n;
STRUCT_ASSIGN(scflpos, curr_pos);
}
/*
* Set the linenumber for a CONSTCOND comment. At this and the following
* line no warnings about constants in conditional contexts are printed.
*/
/* ARGSUSED */
void
constcond(int n)
{
ccflg = 1;
}
/*
* Suppress printing of "fallthrough on ..." warnings until next
* statement.
*/
/* ARGSUSED */
void
fallthru(int n)
{
ftflg = 1;
}
/*
* Stop warnings about statements which cannot be reached. Also tells lint
* that the following statements cannot be reached (e.g. after exit()).
*/
/* ARGSUSED */
void
notreach(int n)
{
reached = 0;
rchflg = 1;
}
/* ARGSUSED */
void
lintlib(int n)
{
if (dcs->d_ctx != EXTERN) {
/* must be outside function: ** %s ** */
warning(280, "LINTLIBRARY");
return;
}
llibflg = 1;
vflag = 0;
}
/*
* Suppress most warnings at the current and the following line.
*/
/* ARGSUSED */
void
linted(int n)
{
#ifdef DEBUG
printf("%s, %d: nowarn = 1\n", curr_pos.p_file, curr_pos.p_line);
#endif
nowarn = 1;
}
/*
* Suppress bitfield type errors on the current line.
*/
/* ARGSUSED */
void
bitfieldtype(int n)
{
#ifdef DEBUG
printf("%s, %d: bitfieldtype_ok = 1\n", curr_pos.p_file,
curr_pos.p_line);
#endif
bitfieldtype_ok = 1;
}
/*
* PROTOTLIB in conjunction with LINTLIBRARY can be used to handle
* prototypes like function definitions. This is done if the argument
* to PROTOLIB is nonzero. Otherwise prototypes are handled normaly.
*/
void
protolib(int n)
{
if (dcs->d_ctx != EXTERN) {
/* must be outside function: ** %s ** */
warning(280, "PROTOLIB");
return;
}
plibflg = n == 0 ? 0 : 1;
}
/*
* Set quadflg to nonzero which means that the next statement/declaration
* may use "long long" without an error or warning.
*/
/* ARGSUSED */
void
longlong(int n)
{
quadflg = 1;
}