xlint/lint1/lex.c

1.225    rillig /* $NetBSD: lex.c,v 1.225 2024/05/09 11:08:07 rillig Exp $ */
  1.1    rillig
  1.1    rillig /*
  1.1    rillig  * Copyright (c) 1996 Christopher G. Demetriou.  All Rights Reserved.
  1.1    rillig  * Copyright (c) 1994, 1995 Jochen Pohl
  1.1    rillig  * All Rights Reserved.
  1.1    rillig  *
  1.1    rillig  * Redistribution and use in source and binary forms, with or without
  1.1    rillig  * modification, are permitted provided that the following conditions
  1.1    rillig  * are met:
  1.1    rillig  * 1. Redistributions of source code must retain the above copyright
  1.1    rillig  *    notice, this list of conditions and the following disclaimer.
  1.1    rillig  * 2. Redistributions in binary form must reproduce the above copyright
  1.1    rillig  *    notice, this list of conditions and the following disclaimer in the
  1.1    rillig  *    documentation and/or other materials provided with the distribution.
  1.1    rillig  * 3. All advertising materials mentioning features or use of this software
  1.1    rillig  *    must display the following acknowledgement:
1.182    rillig  *	This product includes software developed by Jochen Pohl for
1.182    rillig  *	The NetBSD Project.
  1.1    rillig  * 4. The name of the author may not be used to endorse or promote products
  1.1    rillig  *    derived from this software without specific prior written permission.
  1.1    rillig  *
  1.1    rillig  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
  1.1    rillig  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
  1.1    rillig  * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
  1.1    rillig  * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
  1.1    rillig  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
  1.1    rillig  * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
  1.1    rillig  * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
  1.1    rillig  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
  1.1    rillig  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
  1.1    rillig  * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  1.1    rillig  */
  1.1    rillig
  1.4  christos #if HAVE_NBTOOL_CONFIG_H
  1.4  christos #include "nbtool_config.h"
  1.4  christos #endif
  1.4  christos
  1.1    rillig #include <sys/cdefs.h>
1.131    rillig #if defined(__RCSID)
1.225    rillig __RCSID("$NetBSD: lex.c,v 1.225 2024/05/09 11:08:07 rillig Exp $");
  1.1    rillig #endif
  1.1    rillig
  1.1    rillig #include <ctype.h>
  1.1    rillig #include <errno.h>
  1.1    rillig #include <float.h>
  1.1    rillig #include <limits.h>
  1.1    rillig #include <math.h>
  1.1    rillig #include <stdlib.h>
  1.1    rillig #include <string.h>
  1.1    rillig
  1.1    rillig #include "lint1.h"
  1.1    rillig #include "cgram.h"
  1.1    rillig
 1.72    rillig #define CHAR_MASK	((1U << CHAR_SIZE) - 1)
  1.1    rillig
  1.1    rillig
  1.1    rillig /* Current position (it's also updated when an included file is parsed) */
1.196    rillig pos_t curr_pos = { "", 1, 0 };
  1.1    rillig
  1.1    rillig /*
  1.1    rillig  * Current position in C source (not updated when an included file is
  1.1    rillig  * parsed).
  1.1    rillig  */
1.196    rillig pos_t csrc_pos = { "", 1, 0 };
  1.1    rillig
 1.94    rillig bool in_gcc_attribute;
 1.94    rillig bool in_system_header;
  1.1    rillig
1.125    rillig /*
1.224    rillig  * Define a keyword that cannot be overridden by identifiers.
1.224    rillig  *
1.184    rillig  * Valid values for 'since' are 78, 90, 99, 11, 23.
1.125    rillig  *
1.184    rillig  * The C11 keywords are all taken from the reserved namespace.  They are added
1.184    rillig  * in C99 mode as well, to make the parse error messages more useful.  For
1.184    rillig  * example, if the keyword '_Generic' were not defined, it would be interpreted
1.184    rillig  * as an implicit function call, leading to a parse error.
1.184    rillig  *
1.184    rillig  * The C23 keywords are not made available in earlier modes, as they may
1.184    rillig  * conflict with user-defined identifiers.
1.125    rillig  */
1.175    rillig #define kwdef(name, token, detail,	since, gcc, deco) \
1.184    rillig 	{ /* CONSTCOND */ \
1.175    rillig 		name, token, detail, \
1.122    rillig 		(since) == 90, \
1.184    rillig 		(since) == 99 || (since) == 11, \
1.184    rillig 		(since) == 23, \
1.133    rillig 		(gcc) > 0, \
 1.66    rillig 		((deco) & 1) != 0, ((deco) & 2) != 0, ((deco) & 4) != 0, \
 1.13    rillig 	}
1.122    rillig #define kwdef_token(name, token,		since, gcc, deco) \
1.175    rillig 	kwdef(name, token, {false},		since, gcc, deco)
1.122    rillig #define kwdef_sclass(name, sclass,		since, gcc, deco) \
1.175    rillig 	kwdef(name, T_SCLASS, .u.kw_scl = (sclass), since, gcc, deco)
1.132    rillig #define kwdef_type(name, tspec,			since) \
1.175    rillig 	kwdef(name, T_TYPE, .u.kw_tspec = (tspec), since, 0, 1)
1.122    rillig #define kwdef_tqual(name, tqual,		since, gcc, deco) \
1.185    rillig 	kwdef(name, T_QUAL, .u.kw_tqual = {.tqual = true}, since, gcc, deco)
1.225    rillig #define kwdef_const(name, named_constant,	since, gcc, deco) \
1.225    rillig 	kwdef(name, T_NAMED_CONSTANT, \
1.225    rillig 	    .u.kw_named_constant = (named_constant), since, gcc, deco)
 1.35    rillig #define kwdef_keyword(name, token) \
1.175    rillig 	kwdef(name, token, {false},		78, 0, 1)
 1.13    rillig
 1.94    rillig /* During initialization, these keywords are written to the symbol table. */
1.106    rillig static const struct keyword {
1.178    rillig 	const	char kw_name[20];
1.176    rillig 	int	kw_token;	/* token to be returned by yylex() */
1.175    rillig 	union {
1.175    rillig 		bool kw_dummy;
1.175    rillig 		scl_t kw_scl;		/* if kw_token is T_SCLASS */
1.175    rillig 		tspec_t kw_tspec;	/* if kw_token is T_TYPE or
1.175    rillig 					 * T_STRUCT_OR_UNION */
1.185    rillig 		type_qualifiers kw_tqual;	/* if kw_token is T_QUAL */
1.176    rillig 		function_specifier kw_fs;	/* if kw_token is
1.176    rillig 						 * T_FUNCTION_SPECIFIER */
1.225    rillig 		named_constant kw_named_constant;
1.175    rillig 	} u;
1.184    rillig 	bool	kw_added_in_c90:1;
1.184    rillig 	bool	kw_added_in_c99_or_c11:1;
1.184    rillig 	bool	kw_added_in_c23:1;
1.146    rillig 	bool	kw_gcc:1;	/* available in GCC mode */
 1.93    rillig 	bool	kw_plain:1;	/* 'name' */
 1.93    rillig 	bool	kw_leading:1;	/* '__name' */
 1.93    rillig 	bool	kw_both:1;	/* '__name__' */
 1.94    rillig } keywords[] = {
1.186    rillig 	// TODO: _Alignas is not available in C99.
 1.35    rillig 	kwdef_keyword(	"_Alignas",	T_ALIGNAS),
1.186    rillig 	// TODO: _Alignof is not available in C99.
 1.35    rillig 	kwdef_keyword(	"_Alignof",	T_ALIGNOF),
1.186    rillig 	// TODO: alignof is not available in C99.
1.130    rillig 	kwdef_token(	"alignof",	T_ALIGNOF,		78,0,6),
1.146    rillig 	kwdef_token(	"asm",		T_ASM,			78,1,7),
1.142    rillig 	kwdef_token(	"_Atomic",	T_ATOMIC,		11,0,1),
1.122    rillig 	kwdef_token(	"attribute",	T_ATTRIBUTE,		78,1,6),
1.122    rillig 	kwdef_sclass(	"auto",		AUTO,			78,0,1),
1.132    rillig 	kwdef_type(	"_Bool",	BOOL,			99),
1.224    rillig 	kwdef_type(	"bool",		BOOL,			23),
 1.35    rillig 	kwdef_keyword(	"break",	T_BREAK),
1.122    rillig 	kwdef_token(	"__builtin_offsetof", T_BUILTIN_OFFSETOF, 78,1,1),
 1.35    rillig 	kwdef_keyword(	"case",		T_CASE),
1.132    rillig 	kwdef_type(	"char",		CHAR,			78),
1.132    rillig 	kwdef_type(	"_Complex",	COMPLEX,		99),
1.185    rillig 	kwdef_tqual(	"const",	tq_const,		90,0,7),
 1.35    rillig 	kwdef_keyword(	"continue",	T_CONTINUE),
 1.35    rillig 	kwdef_keyword(	"default",	T_DEFAULT),
 1.35    rillig 	kwdef_keyword(	"do",		T_DO),
1.132    rillig 	kwdef_type(	"double",	DOUBLE,			78),
 1.35    rillig 	kwdef_keyword(	"else",		T_ELSE),
1.186    rillig 	// XXX: enum is not available in traditional C.
 1.35    rillig 	kwdef_keyword(	"enum",		T_ENUM),
1.122    rillig 	kwdef_token(	"__extension__",T_EXTENSION,		78,1,1),
1.122    rillig 	kwdef_sclass(	"extern",	EXTERN,			78,0,1),
1.224    rillig 	kwdef_const(	"false",	NC_FALSE,		23,0,1),
1.132    rillig 	kwdef_type(	"float",	FLOAT,			78),
 1.35    rillig 	kwdef_keyword(	"for",		T_FOR),
1.122    rillig 	kwdef_token(	"_Generic",	T_GENERIC,		11,0,1),
 1.35    rillig 	kwdef_keyword(	"goto",		T_GOTO),
 1.35    rillig 	kwdef_keyword(	"if",		T_IF),
1.122    rillig 	kwdef_token(	"__imag__",	T_IMAG,			78,1,1),
1.176    rillig 	kwdef("inline",	T_FUNCTION_SPECIFIER, .u.kw_fs = FS_INLINE, 99,0,7),
1.132    rillig 	kwdef_type(	"int",		INT,			78),
 1.56    rillig #ifdef INT128_SIZE
1.132    rillig 	kwdef_type(	"__int128_t",	INT128,			99),
 1.56    rillig #endif
1.132    rillig 	kwdef_type(	"long",		LONG,			78),
1.177    rillig 	kwdef("_Noreturn", T_FUNCTION_SPECIFIER, .u.kw_fs = FS_NORETURN, 11,0,1),
1.225    rillig 	kwdef_const(	"nullptr",	NC_NULLPTR,		23,0,1),
1.186    rillig 	// XXX: __packed is GCC-specific.
1.124    rillig 	kwdef_token(	"__packed",	T_PACKED,		78,0,1),
1.124    rillig 	kwdef_token(	"__real__",	T_REAL,			78,1,1),
1.124    rillig 	kwdef_sclass(	"register",	REG,			78,0,1),
1.185    rillig 	kwdef_tqual(	"restrict",	tq_restrict,		99,0,7),
1.124    rillig 	kwdef_keyword(	"return",	T_RETURN),
1.132    rillig 	kwdef_type(	"short",	SHORT,			78),
1.175    rillig 	kwdef(		"signed", T_TYPE, .u.kw_tspec = SIGNED,	90,0,3),
1.124    rillig 	kwdef_keyword(	"sizeof",	T_SIZEOF),
1.124    rillig 	kwdef_sclass(	"static",	STATIC,			78,0,1),
1.186    rillig 	// XXX: _Static_assert was added in C11.
1.124    rillig 	kwdef_keyword(	"_Static_assert",	T_STATIC_ASSERT),
1.175    rillig 	kwdef("struct",	T_STRUCT_OR_UNION, .u.kw_tspec = STRUCT, 78,0,1),
1.124    rillig 	kwdef_keyword(	"switch",	T_SWITCH),
1.124    rillig 	kwdef_token(	"__symbolrename",	T_SYMBOLRENAME,	78,0,1),
1.183    rillig 	kwdef_sclass(	"__thread",	THREAD_LOCAL,		78,1,1),
1.183    rillig 	kwdef_sclass(	"_Thread_local", THREAD_LOCAL,		11,0,1),
1.184    rillig 	kwdef_sclass(	"thread_local", THREAD_LOCAL,		23,0,1),
1.224    rillig 	kwdef_const(	"true",		NC_TRUE,		23,0,1),
1.124    rillig 	kwdef_sclass(	"typedef",	TYPEDEF,		78,0,1),
1.124    rillig 	kwdef_token(	"typeof",	T_TYPEOF,		78,1,7),
1.124    rillig #ifdef INT128_SIZE
1.132    rillig 	kwdef_type(	"__uint128_t",	UINT128,		99),
1.124    rillig #endif
1.175    rillig 	kwdef("union",	T_STRUCT_OR_UNION, .u.kw_tspec = UNION,	78,0,1),
1.132    rillig 	kwdef_type(	"unsigned",	UNSIGN,			78),
1.186    rillig 	// XXX: void is not available in traditional C.
1.132    rillig 	kwdef_type(	"void",		VOID,			78),
1.185    rillig 	kwdef_tqual(	"volatile",	tq_volatile,		90,0,7),
1.124    rillig 	kwdef_keyword(	"while",	T_WHILE),
 1.13    rillig #undef kwdef
 1.13    rillig #undef kwdef_token
 1.13    rillig #undef kwdef_sclass
 1.13    rillig #undef kwdef_type
 1.13    rillig #undef kwdef_tqual
 1.36    rillig #undef kwdef_keyword
  1.1    rillig };
  1.1    rillig
1.146    rillig /*
1.146    rillig  * The symbol table containing all keywords, identifiers and labels. The hash
1.146    rillig  * entries are linked via sym_t.s_symtab_next.
1.146    rillig  */
1.173    rillig static sym_t *symtab[503];
  1.1    rillig
1.146    rillig /*
1.146    rillig  * The kind of the next expected symbol, to distinguish the namespaces of
1.146    rillig  * members, labels, type tags and other identifiers.
1.146    rillig  */
1.200    rillig symbol_kind sym_kind;
  1.1    rillig
  1.1    rillig
1.104    rillig static unsigned int
1.104    rillig hash(const char *s)
1.104    rillig {
1.210    rillig 	unsigned int v = 0;
1.210    rillig 	for (const char *p = s; *p != '\0'; p++) {
1.104    rillig 		v = (v << 4) + (unsigned char)*p;
1.104    rillig 		v ^= v >> 28;
1.104    rillig 	}
1.173    rillig 	return v % (sizeof(symtab) / sizeof(symtab[0]));
1.104    rillig }
1.104    rillig
  1.1    rillig static void
 1.62    rillig symtab_add(sym_t *sym)
 1.60    rillig {
1.210    rillig 	unsigned int h = hash(sym->s_name);
1.102    rillig 	if ((sym->s_symtab_next = symtab[h]) != NULL)
1.102    rillig 		symtab[h]->s_symtab_ref = &sym->s_symtab_next;
1.102    rillig 	sym->s_symtab_ref = &symtab[h];
 1.60    rillig 	symtab[h] = sym;
 1.60    rillig }
 1.60    rillig
1.104    rillig static sym_t *
1.143    rillig symtab_search(const char *name)
1.104    rillig {
1.104    rillig
1.143    rillig 	unsigned int h = hash(name);
1.104    rillig 	for (sym_t *sym = symtab[h]; sym != NULL; sym = sym->s_symtab_next) {
1.143    rillig 		if (strcmp(sym->s_name, name) != 0)
1.104    rillig 			continue;
1.148    rillig 		if (sym->s_keyword != NULL ||
1.200    rillig 		    sym->s_kind == sym_kind ||
1.148    rillig 		    in_gcc_attribute)
1.104    rillig 			return sym;
1.104    rillig 	}
1.104    rillig
1.104    rillig 	return NULL;
1.104    rillig }
1.104    rillig
 1.60    rillig static void
 1.61    rillig symtab_remove(sym_t *sym)
 1.61    rillig {
 1.61    rillig
1.102    rillig 	if ((*sym->s_symtab_ref = sym->s_symtab_next) != NULL)
1.102    rillig 		sym->s_symtab_next->s_symtab_ref = sym->s_symtab_ref;
1.102    rillig 	sym->s_symtab_next = NULL;
 1.61    rillig }
 1.61    rillig
1.104    rillig static void
1.104    rillig symtab_remove_locals(void)
1.104    rillig {
1.104    rillig
1.173    rillig 	for (size_t i = 0; i < sizeof(symtab) / sizeof(symtab[0]); i++) {
1.104    rillig 		for (sym_t *sym = symtab[i]; sym != NULL; ) {
1.104    rillig 			sym_t *next = sym->s_symtab_next;
1.104    rillig 			if (sym->s_block_level >= 1)
1.104    rillig 				symtab_remove(sym);
1.104    rillig 			sym = next;
1.104    rillig 		}
1.104    rillig 	}
1.104    rillig }
 1.61    rillig
1.107    rillig #ifdef DEBUG
1.107    rillig static int
1.107    rillig sym_by_name(const void *va, const void *vb)
1.107    rillig {
1.107    rillig 	const sym_t *a = *(const sym_t *const *)va;
1.107    rillig 	const sym_t *b = *(const sym_t *const *)vb;
1.107    rillig
1.107    rillig 	return strcmp(a->s_name, b->s_name);
1.107    rillig }
1.107    rillig
1.107    rillig struct syms {
1.107    rillig 	const sym_t **items;
1.107    rillig 	size_t len;
1.107    rillig 	size_t cap;
1.107    rillig };
1.107    rillig
1.107    rillig static void
1.107    rillig syms_add(struct syms *syms, const sym_t *sym)
1.107    rillig {
1.146    rillig 	if (syms->len >= syms->cap) {
1.107    rillig 		syms->cap *= 2;
1.107    rillig 		syms->items = xrealloc(syms->items,
1.107    rillig 		    syms->cap * sizeof(syms->items[0]));
1.107    rillig 	}
1.107    rillig 	syms->items[syms->len++] = sym;
1.107    rillig }
1.107    rillig
1.107    rillig void
1.107    rillig debug_symtab(void)
1.107    rillig {
1.107    rillig 	struct syms syms = { xcalloc(64, sizeof(syms.items[0])), 0, 64 };
1.107    rillig
1.187    rillig 	debug_enter();
1.111    rillig 	for (int level = -1;; level++) {
1.107    rillig 		bool more = false;
1.107    rillig 		size_t n = sizeof(symtab) / sizeof(symtab[0]);
1.107    rillig
1.107    rillig 		syms.len = 0;
1.107    rillig 		for (size_t i = 0; i < n; i++) {
1.107    rillig 			for (sym_t *sym = symtab[i]; sym != NULL;) {
1.107    rillig 				if (sym->s_block_level == level &&
1.107    rillig 				    sym->s_keyword == NULL)
1.107    rillig 					syms_add(&syms, sym);
1.107    rillig 				if (sym->s_block_level > level)
1.107    rillig 					more = true;
1.107    rillig 				sym = sym->s_symtab_next;
1.107    rillig 			}
1.107    rillig 		}
1.107    rillig
1.111    rillig 		if (syms.len > 0) {
1.187    rillig 			debug_step("symbol table level %d", level);
1.111    rillig 			debug_indent_inc();
1.111    rillig 			qsort(syms.items, syms.len, sizeof(syms.items[0]),
1.111    rillig 			    sym_by_name);
1.111    rillig 			for (size_t i = 0; i < syms.len; i++)
1.114    rillig 				debug_sym("", syms.items[i], "\n");
1.111    rillig 			debug_indent_dec();
1.111    rillig
1.111    rillig 			lint_assert(level != -1);
1.111    rillig 		}
1.107    rillig
1.107    rillig 		if (!more)
1.107    rillig 			break;
1.107    rillig 	}
1.187    rillig 	debug_leave();
1.107    rillig
1.107    rillig 	free(syms.items);
1.107    rillig }
1.107    rillig #endif
1.107    rillig
 1.61    rillig static void
1.210    rillig register_keyword(const struct keyword *kw, bool leading, bool trailing)
  1.1    rillig {
1.146    rillig
  1.1    rillig 	const char *name;
 1.66    rillig 	if (!leading && !trailing) {
  1.1    rillig 		name = kw->kw_name;
 1.66    rillig 	} else {
1.146    rillig 		char buf[256];
 1.73    rillig 		(void)snprintf(buf, sizeof(buf), "%s%s%s",
 1.66    rillig 		    leading ? "__" : "", kw->kw_name, trailing ? "__" : "");
 1.66    rillig 		name = xstrdup(buf);
  1.1    rillig 	}
  1.1    rillig
1.188    rillig 	sym_t *sym = block_zero_alloc(sizeof(*sym), "sym");
  1.1    rillig 	sym->s_name = name;
  1.1    rillig 	sym->s_keyword = kw;
1.146    rillig 	int tok = kw->kw_token;
1.146    rillig 	sym->u.s_keyword.sk_token = tok;
1.146    rillig 	if (tok == T_TYPE || tok == T_STRUCT_OR_UNION)
1.176    rillig 		sym->u.s_keyword.u.sk_tspec = kw->u.kw_tspec;
1.146    rillig 	if (tok == T_SCLASS)
1.175    rillig 		sym->s_scl = kw->u.kw_scl;
1.146    rillig 	if (tok == T_QUAL)
1.185    rillig 		sym->u.s_keyword.u.sk_type_qualifier = kw->u.kw_tqual;
1.176    rillig 	if (tok == T_FUNCTION_SPECIFIER)
1.176    rillig 		sym->u.s_keyword.u.function_specifier = kw->u.kw_fs;
1.225    rillig 	if (tok == T_NAMED_CONSTANT)
1.225    rillig 		sym->u.s_keyword.u.named_constant = kw->u.kw_named_constant;
 1.60    rillig
 1.60    rillig 	symtab_add(sym);
  1.1    rillig }
  1.1    rillig
1.126    rillig static bool
1.126    rillig is_keyword_known(const struct keyword *kw)
1.126    rillig {
1.126    rillig
1.184    rillig 	if (kw->kw_added_in_c23 && !allow_c23)
1.184    rillig 		return false;
1.184    rillig 	if ((kw->kw_added_in_c90 || kw->kw_added_in_c99_or_c11) && !allow_c90)
1.126    rillig 		return false;
1.126    rillig
1.126    rillig 	/*
1.126    rillig 	 * In the 1990s, GCC defined several keywords that were later
1.126    rillig 	 * incorporated into C99, therefore in GCC mode, all C99 keywords are
1.126    rillig 	 * made available.  The C11 keywords are made available as well, but
1.126    rillig 	 * there are so few that they don't matter practically.
1.126    rillig 	 */
1.126    rillig 	if (allow_gcc)
1.126    rillig 		return true;
1.126    rillig 	if (kw->kw_gcc)
1.126    rillig 		return false;
1.126    rillig
1.184    rillig 	if (kw->kw_added_in_c99_or_c11 && !allow_c99)
1.126    rillig 		return false;
1.126    rillig 	return true;
1.126    rillig }
1.126    rillig
1.146    rillig /* Write all keywords to the symbol table. */
  1.1    rillig void
1.210    rillig init_lex(void)
  1.1    rillig {
  1.1    rillig
1.146    rillig 	size_t n = sizeof(keywords) / sizeof(keywords[0]);
1.146    rillig 	for (size_t i = 0; i < n; i++) {
1.146    rillig 		const struct keyword *kw = keywords + i;
1.126    rillig 		if (!is_keyword_known(kw))
  1.1    rillig 			continue;
 1.66    rillig 		if (kw->kw_plain)
1.210    rillig 			register_keyword(kw, false, false);
 1.66    rillig 		if (kw->kw_leading)
1.210    rillig 			register_keyword(kw, true, false);
 1.66    rillig 		if (kw->kw_both)
1.210    rillig 			register_keyword(kw, true, true);
  1.1    rillig 	}
  1.1    rillig }
  1.1    rillig
  1.1    rillig /*
1.135    rillig  * When scanning the remainder of a long token (see lex_input), read a byte
1.135    rillig  * and return it as an unsigned char or as EOF.
1.135    rillig  *
1.135    rillig  * Increment the line counts if necessary.
  1.1    rillig  */
  1.1    rillig static int
1.135    rillig read_byte(void)
  1.1    rillig {
1.215    rillig 	int c = lex_input();
  1.1    rillig
 1.41    rillig 	if (c == '\n')
  1.6    rillig 		lex_next_line();
1.215    rillig 	return c == '\0' ? EOF : c;	/* lex returns 0 on EOF. */
  1.1    rillig }
  1.1    rillig
1.105    rillig static int
1.105    rillig lex_keyword(sym_t *sym)
1.105    rillig {
1.144    rillig 	int tok = sym->u.s_keyword.sk_token;
1.105    rillig
1.144    rillig 	if (tok == T_SCLASS)
1.105    rillig 		yylval.y_scl = sym->s_scl;
1.144    rillig 	if (tok == T_TYPE || tok == T_STRUCT_OR_UNION)
1.176    rillig 		yylval.y_tspec = sym->u.s_keyword.u.sk_tspec;
1.144    rillig 	if (tok == T_QUAL)
1.185    rillig 		yylval.y_type_qualifiers =
1.185    rillig 		    sym->u.s_keyword.u.sk_type_qualifier;
1.176    rillig 	if (tok == T_FUNCTION_SPECIFIER)
1.176    rillig 		yylval.y_function_specifier =
1.176    rillig 		    sym->u.s_keyword.u.function_specifier;
1.225    rillig 	if (tok == T_NAMED_CONSTANT)
1.225    rillig 		yylval.y_named_constant = sym->u.s_keyword.u.named_constant;
1.144    rillig 	return tok;
1.105    rillig }
1.105    rillig
  1.1    rillig /*
1.146    rillig  * Look up the definition of a name in the symbol table. This symbol must
1.200    rillig  * either be a keyword or a symbol of the type required by sym_kind (label,
1.146    rillig  * member, tag, ...).
  1.1    rillig  */
  1.1    rillig extern int
  1.1    rillig lex_name(const char *yytext, size_t yyleng)
  1.1    rillig {
  1.1    rillig
1.143    rillig 	sym_t *sym = symtab_search(yytext);
1.143    rillig 	if (sym != NULL && sym->s_keyword != NULL)
1.105    rillig 		return lex_keyword(sym);
  1.1    rillig
1.143    rillig 	sbuf_t *sb = xmalloc(sizeof(*sb));
1.143    rillig 	sb->sb_len = yyleng;
  1.1    rillig 	sb->sb_sym = sym;
1.143    rillig 	yylval.y_name = sb;
  1.1    rillig
  1.1    rillig 	if (sym != NULL) {
 1.12    rillig 		lint_assert(block_level >= sym->s_block_level);
  1.1    rillig 		sb->sb_name = sym->s_name;
1.143    rillig 		return sym->s_scl == TYPEDEF ? T_TYPENAME : T_NAME;
  1.1    rillig 	}
  1.1    rillig
1.188    rillig 	char *name = block_zero_alloc(yyleng + 1, "string");
1.144    rillig 	(void)memcpy(name, yytext, yyleng + 1);
1.144    rillig 	sb->sb_name = name;
1.143    rillig 	return T_NAME;
  1.1    rillig }
  1.1    rillig
1.202    rillig static tspec_t
1.218    rillig integer_constant_type_signed(unsigned ls, uint64_t ui, int base, bool warned)
1.202    rillig {
1.218    rillig 	if (ls == 0 && ui <= TARG_INT_MAX)
1.218    rillig 		return INT;
1.218    rillig 	if (ls == 0 && ui <= TARG_UINT_MAX && base != 10 && allow_c90)
1.218    rillig 		return UINT;
1.218    rillig 	if (ls == 0 && ui <= TARG_LONG_MAX)
1.218    rillig 		return LONG;
1.218    rillig
1.218    rillig 	if (ls <= 1 && ui <= TARG_LONG_MAX)
1.218    rillig 		return LONG;
1.218    rillig 	if (ls <= 1 && ui <= TARG_ULONG_MAX && base != 10)
1.218    rillig 		return allow_c90 ? ULONG : LONG;
1.218    rillig 	if (ls <= 1 && !allow_c99) {
1.203    rillig 		if (!warned)
1.203    rillig 			/* integer constant out of range */
1.203    rillig 			warning(252);
1.218    rillig 		return allow_c90 ? ULONG : LONG;
1.218    rillig 	}
1.218    rillig
1.218    rillig 	if (ui <= TARG_LLONG_MAX)
1.218    rillig 		return LLONG;
1.218    rillig 	if (ui <= TARG_ULLONG_MAX && base != 10)
1.214    rillig 		return allow_c90 ? ULLONG : LLONG;
1.218    rillig 	if (!warned)
1.218    rillig 		/* integer constant out of range */
1.218    rillig 		warning(252);
1.218    rillig 	return allow_c90 ? ULLONG : LLONG;
1.218    rillig }
1.218    rillig
1.218    rillig static tspec_t
1.218    rillig integer_constant_type_unsigned(unsigned l, uint64_t ui, bool warned)
1.218    rillig {
1.218    rillig 	if (l == 0 && ui <= TARG_UINT_MAX)
1.218    rillig 		return UINT;
1.218    rillig
1.218    rillig 	if (l <= 1 && ui <= TARG_ULONG_MAX)
1.218    rillig 		return ULONG;
1.218    rillig 	if (l <= 1 && !allow_c99) {
1.203    rillig 		if (!warned)
1.203    rillig 			/* integer constant out of range */
1.203    rillig 			warning(252);
1.218    rillig 		return ULONG;
1.218    rillig 	}
1.218    rillig
1.218    rillig 	if (ui <= TARG_ULLONG_MAX)
1.203    rillig 		return ULLONG;
1.218    rillig 	if (!warned)
1.218    rillig 		/* integer constant out of range */
1.218    rillig 		warning(252);
1.218    rillig 	return ULLONG;
1.202    rillig }
1.202    rillig
  1.1    rillig int
  1.6    rillig lex_integer_constant(const char *yytext, size_t yyleng, int base)
  1.1    rillig {
1.151    rillig 	const char *cp = yytext;
1.151    rillig 	size_t len = yyleng;
  1.1    rillig
  1.1    rillig 	/* skip 0[xX] or 0[bB] */
  1.1    rillig 	if (base == 16 || base == 2) {
  1.1    rillig 		cp += 2;
  1.1    rillig 		len -= 2;
  1.1    rillig 	}
  1.1    rillig
  1.1    rillig 	/* read suffixes */
1.151    rillig 	unsigned l_suffix = 0, u_suffix = 0;
1.143    rillig 	for (;; len--) {
1.151    rillig 		char c = cp[len - 1];
1.151    rillig 		if (c == 'l' || c == 'L')
  1.1    rillig 			l_suffix++;
1.143    rillig 		else if (c == 'u' || c == 'U')
  1.1    rillig 			u_suffix++;
1.143    rillig 		else
  1.1    rillig 			break;
  1.1    rillig 	}
  1.1    rillig 	if (l_suffix > 2 || u_suffix > 1) {
  1.1    rillig 		/* malformed integer constant */
  1.1    rillig 		warning(251);
  1.1    rillig 		if (l_suffix > 2)
  1.1    rillig 			l_suffix = 2;
  1.1    rillig 		if (u_suffix > 1)
  1.1    rillig 			u_suffix = 1;
  1.1    rillig 	}
1.216    rillig 	if (!allow_c90 && u_suffix > 0)
1.171    rillig 		/* suffix 'U' is illegal in traditional C */
  1.1    rillig 		warning(97);
  1.1    rillig
1.151    rillig 	bool warned = false;
  1.1    rillig 	errno = 0;
1.151    rillig 	char *eptr;
1.166    rillig 	uint64_t ui = (uint64_t)strtoull(cp, &eptr, base);
  1.1    rillig 	lint_assert(eptr == cp + len);
 1.11    rillig 	if (errno != 0) {
  1.1    rillig 		/* integer constant out of range */
  1.1    rillig 		warning(252);
 1.11    rillig 		warned = true;
 1.11    rillig 	}
  1.1    rillig
1.216    rillig 	if (any_query_enabled && base == 8 && ui != 0)
1.155    rillig 		/* octal number '%.*s' */
1.155    rillig 		query_message(8, (int)len, cp);
1.155    rillig
1.218    rillig 	bool unsigned_since_c90 = allow_trad && allow_c90 && u_suffix == 0
1.223    rillig 	    && ui > TARG_INT_MAX
1.223    rillig 	    && ((l_suffix == 0 && base != 10 && ui <= TARG_UINT_MAX)
1.223    rillig 		|| (l_suffix <= 1 && ui > TARG_LONG_MAX));
  1.1    rillig
1.219    rillig 	tspec_t t = u_suffix > 0
1.218    rillig 	    ? integer_constant_type_unsigned(l_suffix, ui, warned)
1.218    rillig 	    : integer_constant_type_signed(l_suffix, ui, base, warned);
1.223    rillig 	ui = (uint64_t)convert_integer((int64_t)ui, t, size_in_bits(t));
  1.1    rillig
 1.22    rillig 	yylval.y_val = xcalloc(1, sizeof(*yylval.y_val));
1.202    rillig 	yylval.y_val->v_tspec = t;
1.218    rillig 	yylval.y_val->v_unsigned_since_c90 = unsigned_since_c90;
1.166    rillig 	yylval.y_val->u.integer = (int64_t)ui;
  1.1    rillig
  1.1    rillig 	return T_CON;
  1.1    rillig }
  1.1    rillig
1.223    rillig /* Extend or truncate si to match t.  If t is signed, sign-extend. */
  1.1    rillig int64_t
1.223    rillig convert_integer(int64_t si, tspec_t t, unsigned int bits)
  1.1    rillig {
  1.1    rillig
1.223    rillig 	uint64_t vbits = value_bits(bits);
1.172    rillig 	uint64_t ui = (uint64_t)si;
1.223    rillig 	return t == PTR || is_uinteger(t) || ((ui & bit(bits - 1)) == 0)
1.172    rillig 	    ? (int64_t)(ui & vbits)
1.172    rillig 	    : (int64_t)(ui | ~vbits);
  1.1    rillig }
  1.1    rillig
  1.1    rillig int
  1.6    rillig lex_floating_constant(const char *yytext, size_t yyleng)
  1.1    rillig {
1.151    rillig 	const char *cp = yytext;
1.151    rillig 	size_t len = yyleng;
  1.1    rillig
1.158    rillig 	bool imaginary = cp[len - 1] == 'i';
1.158    rillig 	if (imaginary)
1.158    rillig 		len--;
 1.81    rillig
1.151    rillig 	char c = cp[len - 1];
1.215    rillig 	tspec_t t;
1.151    rillig 	if (c == 'f' || c == 'F') {
1.215    rillig 		t = imaginary ? FCOMPLEX : FLOAT;
  1.1    rillig 		len--;
  1.1    rillig 	} else if (c == 'l' || c == 'L') {
1.215    rillig 		t = imaginary ? LCOMPLEX : LDOUBLE;
  1.1    rillig 		len--;
1.152    rillig 	} else
1.215    rillig 		t = imaginary ? DCOMPLEX : DOUBLE;
  1.1    rillig
1.216    rillig 	if (!allow_c90 && t != DOUBLE)
1.171    rillig 		/* suffixes 'F' and 'L' are illegal in traditional C */
  1.1    rillig 		warning(98);
  1.1    rillig
  1.1    rillig 	errno = 0;
1.151    rillig 	char *eptr;
1.150    rillig 	long double ld = strtold(cp, &eptr);
1.149    rillig 	lint_assert(eptr == cp + len);
1.216    rillig 	if (errno != 0)
  1.1    rillig 		/* floating-point constant out of range */
  1.1    rillig 		warning(248);
1.216    rillig 	else if (t == FLOAT) {
1.150    rillig 		ld = (float)ld;
1.150    rillig 		if (isfinite(ld) == 0) {
  1.1    rillig 			/* floating-point constant out of range */
  1.1    rillig 			warning(248);
1.150    rillig 			ld = ld > 0 ? FLT_MAX : -FLT_MAX;
1.150    rillig 		}
1.215    rillig 	} else if (t == DOUBLE
1.194    rillig 	    || /* CONSTCOND */ LDOUBLE_SIZE == DOUBLE_SIZE) {
1.150    rillig 		ld = (double)ld;
1.150    rillig 		if (isfinite(ld) == 0) {
1.150    rillig 			/* floating-point constant out of range */
1.150    rillig 			warning(248);
1.150    rillig 			ld = ld > 0 ? DBL_MAX : -DBL_MAX;
  1.1    rillig 		}
  1.1    rillig 	}
  1.1    rillig
 1.22    rillig 	yylval.y_val = xcalloc(1, sizeof(*yylval.y_val));
1.215    rillig 	yylval.y_val->v_tspec = t;
1.166    rillig 	yylval.y_val->u.floating = ld;
  1.1    rillig
  1.1    rillig 	return T_CON;
  1.1    rillig }
  1.1    rillig
  1.1    rillig int
  1.1    rillig lex_operator(int t, op_t o)
  1.1    rillig {
  1.1    rillig
  1.1    rillig 	yylval.y_op = o;
  1.1    rillig 	return t;
  1.1    rillig }
  1.1    rillig
1.212    rillig static buffer *
1.217    rillig read_quoted(bool *complete, char delim, bool wide)
1.136    rillig {
1.212    rillig 	buffer *buf = xcalloc(1, sizeof(*buf));
1.212    rillig 	buf_init(buf);
1.212    rillig 	if (wide)
1.212    rillig 		buf_add_char(buf, 'L');
1.212    rillig 	buf_add_char(buf, delim);
1.212    rillig
1.212    rillig 	for (;;) {
1.212    rillig 		int c = read_byte();
1.212    rillig 		if (c <= 0)
1.212    rillig 			break;
1.212    rillig 		buf_add_char(buf, (char)c);
1.212    rillig 		if (c == '\n')
1.212    rillig 			break;
1.212    rillig 		if (c == delim) {
1.212    rillig 			*complete = true;
1.212    rillig 			return buf;
1.212    rillig 		}
1.212    rillig 		if (c == '\\') {
1.212    rillig 			c = read_byte();
1.212    rillig 			buf_add_char(buf, (char)(c <= 0 ? ' ' : c));
1.212    rillig 			if (c <= 0)
1.212    rillig 				break;
1.136    rillig 		}
1.136    rillig 	}
1.212    rillig 	*complete = false;
1.212    rillig 	buf_add_char(buf, delim);
1.212    rillig 	return buf;
1.136    rillig }
1.136    rillig
1.222    rillig /*
1.222    rillig  * Analyze the lexical representation of the next character in the string
1.222    rillig  * literal list. At the end, only update the position information.
1.222    rillig  */
1.212    rillig bool
1.212    rillig quoted_next(const buffer *lit, quoted_iterator *it)
1.137    rillig {
1.212    rillig 	const char *s = lit->data;
1.212    rillig
1.222    rillig 	*it = (quoted_iterator){ .start = it->end };
1.212    rillig
1.212    rillig 	char delim = s[s[0] == 'L' ? 1 : 0];
1.212    rillig
1.222    rillig 	bool in_the_middle = it->start > 0;
1.222    rillig 	if (!in_the_middle) {
1.212    rillig 		it->start = s[0] == 'L' ? 2 : 1;
1.222    rillig 		it->end = it->start;
1.212    rillig 	}
1.212    rillig
1.222    rillig 	while (s[it->start] == delim) {
1.222    rillig 		if (it->start + 1 == lit->len) {
1.222    rillig 			it->end = it->start;
1.212    rillig 			return false;
1.222    rillig 		}
1.212    rillig 		it->next_literal = in_the_middle;
1.212    rillig 		it->start += 2;
1.212    rillig 	}
1.222    rillig 	it->end = it->start;
1.137    rillig
1.212    rillig again:
1.222    rillig 	switch (s[it->end]) {
1.137    rillig 	case '\\':
1.222    rillig 		it->end++;
1.212    rillig 		goto backslash;
1.212    rillig 	case '\n':
1.212    rillig 		it->unescaped_newline = true;
1.212    rillig 		return false;
1.212    rillig 	default:
1.222    rillig 		it->value = (unsigned char)s[it->end++];
1.212    rillig 		return true;
1.212    rillig 	}
1.212    rillig
1.212    rillig backslash:
1.212    rillig 	it->escaped = true;
1.222    rillig 	if ('0' <= s[it->end] && s[it->end] <= '7')
1.212    rillig 		goto octal_escape;
1.222    rillig 	switch (s[it->end++]) {
1.212    rillig 	case '\n':
1.212    rillig 		goto again;
1.137    rillig 	case 'a':
1.212    rillig 		it->named_escape = true;
1.212    rillig 		it->value = '\a';
1.212    rillig 		it->invalid_escape = !allow_c90;
1.212    rillig 		return true;
1.137    rillig 	case 'b':
1.212    rillig 		it->named_escape = true;
1.212    rillig 		it->value = '\b';
1.212    rillig 		return true;
1.199    rillig 	case 'e':
1.212    rillig 		it->named_escape = true;
1.212    rillig 		it->value = '\033';
1.212    rillig 		it->invalid_escape = !allow_gcc;
1.212    rillig 		return true;
1.137    rillig 	case 'f':
1.212    rillig 		it->named_escape = true;
1.212    rillig 		it->value = '\f';
1.212    rillig 		return true;
1.137    rillig 	case 'n':
1.212    rillig 		it->named_escape = true;
1.212    rillig 		it->value = '\n';
1.212    rillig 		return true;
1.137    rillig 	case 'r':
1.212    rillig 		it->named_escape = true;
1.212    rillig 		it->value = '\r';
1.212    rillig 		return true;
1.137    rillig 	case 't':
1.212    rillig 		it->named_escape = true;
1.212    rillig 		it->value = '\t';
1.212    rillig 		return true;
1.137    rillig 	case 'v':
1.212    rillig 		it->named_escape = true;
1.212    rillig 		it->value = '\v';
1.212    rillig 		it->invalid_escape = !allow_c90;
1.212    rillig 		return true;
1.137    rillig 	case 'x':
1.212    rillig 		goto hex_escape;
1.212    rillig 	case '"':
1.212    rillig 		it->literal_escape = true;
1.212    rillig 		it->value = '"';
1.212    rillig 		it->invalid_escape = !allow_c90 && delim == '\'';
1.212    rillig 		return true;
1.212    rillig 	case '?':
1.212    rillig 		it->literal_escape = true;
1.212    rillig 		it->value = '?';
1.212    rillig 		it->invalid_escape = !allow_c90;
1.212    rillig 		return true;
1.137    rillig 	default:
1.212    rillig 		it->invalid_escape = true;
1.212    rillig 		/* FALLTHROUGH */
1.212    rillig 	case '\'':
1.212    rillig 	case '\\':
1.212    rillig 		it->literal_escape = true;
1.222    rillig 		it->value = (unsigned char)s[it->end - 1];
1.212    rillig 		return true;
1.137    rillig 	}
1.212    rillig
1.212    rillig octal_escape:
1.212    rillig 	it->octal_digits++;
1.222    rillig 	it->value = s[it->end++] - '0';
1.222    rillig 	if ('0' <= s[it->end] && s[it->end] <= '7') {
1.212    rillig 		it->octal_digits++;
1.222    rillig 		it->value = 8 * it->value + (s[it->end++] - '0');
1.222    rillig 		if ('0' <= s[it->end] && s[it->end] <= '7') {
1.212    rillig 			it->octal_digits++;
1.222    rillig 			it->value = 8 * it->value + (s[it->end++] - '0');
1.212    rillig 			it->overflow = it->value > TARG_UCHAR_MAX
1.212    rillig 			    && s[0] != 'L';
1.212    rillig 		}
1.212    rillig 	}
1.212    rillig 	return true;
1.212    rillig
1.212    rillig hex_escape:
1.212    rillig 	for (;;) {
1.222    rillig 		char ch = s[it->end];
1.212    rillig 		unsigned digit_value;
1.212    rillig 		if ('0' <= ch && ch <= '9')
1.212    rillig 			digit_value = ch - '0';
1.212    rillig 		else if ('A' <= ch && ch <= 'F')
1.212    rillig 			digit_value = 10 + (ch - 'A');
1.212    rillig 		else if ('a' <= ch && ch <= 'f')
1.212    rillig 			digit_value = 10 + (ch - 'a');
1.212    rillig 		else
1.212    rillig 			break;
1.212    rillig
1.222    rillig 		it->end++;
1.212    rillig 		it->value = 16 * it->value + digit_value;
1.212    rillig 		uint64_t limit = s[0] == 'L' ? TARG_UINT_MAX : TARG_UCHAR_MAX;
1.212    rillig 		if (it->value > limit)
1.212    rillig 			it->overflow = true;
1.212    rillig 		if (it->hex_digits < 3)
1.212    rillig 			it->hex_digits++;
1.212    rillig 	}
1.212    rillig 	it->missing_hex_digits = it->hex_digits == 0;
1.212    rillig 	return true;
1.137    rillig }
1.137    rillig
1.212    rillig static void
1.212    rillig check_quoted(const buffer *buf, bool complete, char delim)
1.138    rillig {
1.222    rillig 	quoted_iterator it = { .end = 0 }, prev = it;
1.213    rillig 	for (; quoted_next(buf, &it); prev = it) {
1.212    rillig 		if (it.missing_hex_digits)
1.212    rillig 			/* no hex digits follow \x */
1.212    rillig 			error(74);
1.212    rillig 		if (it.hex_digits > 0 && !allow_c90)
1.212    rillig 			/* \x undefined in traditional C */
1.212    rillig 			warning(82);
1.212    rillig 		else if (!it.invalid_escape)
1.212    rillig 			;
1.212    rillig 		else if (it.value == '8' || it.value == '9')
1.212    rillig 			/* bad octal digit '%c' */
1.212    rillig 			warning(77, (int)it.value);
1.212    rillig 		else if (it.literal_escape && it.value == '?')
1.212    rillig 			/* \? undefined in traditional C */
1.212    rillig 			warning(263);
1.212    rillig 		else if (it.literal_escape && it.value == '"')
1.212    rillig 			/* \" inside character constants undefined in ... */
1.212    rillig 			warning(262);
1.212    rillig 		else if (it.named_escape && it.value == '\a')
1.212    rillig 			/* \a undefined in traditional C */
1.212    rillig 			warning(81);
1.212    rillig 		else if (it.named_escape && it.value == '\v')
1.212    rillig 			/* \v undefined in traditional C */
1.212    rillig 			warning(264);
1.212    rillig 		else {
1.222    rillig 			unsigned char ch = buf->data[it.end - 1];
1.212    rillig 			if (isprint(ch))
1.212    rillig 				/* dubious escape \%c */
1.212    rillig 				warning(79, ch);
1.212    rillig 			else
1.212    rillig 				/* dubious escape \%o */
1.212    rillig 				warning(80, ch);
1.212    rillig 		}
1.212    rillig 		if (it.overflow && it.hex_digits > 0)
1.212    rillig 			/* overflow in hex escape */
1.212    rillig 			warning(75);
1.212    rillig 		if (it.overflow && it.octal_digits > 0)
1.212    rillig 			/* character escape does not fit in character */
1.212    rillig 			warning(76);
1.212    rillig 		if (it.value < ' ' && !it.escaped && complete)
1.197    rillig 			/* invisible character U+%04X in %s */
1.212    rillig 			query_message(17, (unsigned)it.value, delim == '"'
1.197    rillig 			    ? "string literal" : "character constant");
1.213    rillig 		if (prev.octal_digits > 0 && prev.octal_digits < 3
1.213    rillig 		    && !it.escaped && it.value >= '8' && it.value <= '9')
1.213    rillig 			/* short octal escape '%.*s' followed by digit '%c' */
1.222    rillig 			warning(356, (int)(prev.end - prev.start),
1.213    rillig 			    buf->data + prev.start, buf->data[it.start]);
1.138    rillig 	}
1.212    rillig 	if (it.unescaped_newline)
1.212    rillig 		/* newline in string or char constant */
1.212    rillig 		error(254);
1.212    rillig 	if (!complete && delim == '"')
1.212    rillig 		/* unterminated string constant */
1.212    rillig 		error(258);
1.212    rillig 	if (!complete && delim == '\'')
1.212    rillig 		/* unterminated character constant */
1.212    rillig 		error(253);
1.212    rillig }
1.212    rillig
1.212    rillig static buffer *
1.212    rillig lex_quoted(char delim, bool wide)
1.212    rillig {
1.212    rillig 	bool complete;
1.217    rillig 	buffer *buf = read_quoted(&complete, delim, wide);
1.212    rillig 	check_quoted(buf, complete, delim);
1.212    rillig 	return buf;
1.138    rillig }
1.138    rillig
1.113    rillig /* Called if lex found a leading "'". */
  1.1    rillig int
  1.6    rillig lex_character_constant(void)
  1.1    rillig {
1.212    rillig 	buffer *buf = lex_quoted('\'', false);
  1.1    rillig
1.211    rillig 	size_t n = 0;
1.212    rillig 	uint64_t val = 0;
1.222    rillig 	quoted_iterator it = { .end = 0 };
1.212    rillig 	while (quoted_next(buf, &it)) {
1.212    rillig 		val = (val << CHAR_SIZE) + it.value;
  1.1    rillig 		n++;
  1.1    rillig 	}
1.212    rillig 	if (n > sizeof(int) || (n > 1 && (pflag || hflag))) {
1.145    rillig 		/*
1.145    rillig 		 * XXX: ^^ should rather be sizeof(TARG_INT). Luckily,
1.145    rillig 		 * sizeof(int) is the same on all supported platforms.
1.145    rillig 		 */
 1.43    rillig 		/* too many characters in character constant */
 1.43    rillig 		error(71);
1.216    rillig 	} else if (n > 1)
 1.43    rillig 		/* multi-character character constant */
 1.43    rillig 		warning(294);
1.216    rillig 	else if (n == 0 && !it.unescaped_newline)
 1.43    rillig 		/* empty character constant */
 1.43    rillig 		error(73);
1.212    rillig
1.212    rillig 	int64_t cval = n == 1
1.212    rillig 	    ? convert_integer((int64_t)val, CHAR, CHAR_SIZE)
1.212    rillig 	    : (int64_t)val;
  1.1    rillig
 1.22    rillig 	yylval.y_val = xcalloc(1, sizeof(*yylval.y_val));
  1.1    rillig 	yylval.y_val->v_tspec = INT;
1.161    rillig 	yylval.y_val->v_char_constant = true;
1.212    rillig 	yylval.y_val->u.integer = cval;
  1.1    rillig
  1.1    rillig 	return T_CON;
  1.1    rillig }
  1.1    rillig
1.223    rillig /* Called if lex found a leading "L'". */
  1.1    rillig int
  1.6    rillig lex_wide_character_constant(void)
  1.1    rillig {
1.212    rillig 	buffer *buf = lex_quoted('\'', true);
1.212    rillig
1.212    rillig 	static char wbuf[MB_LEN_MAX + 1];
1.212    rillig 	size_t n = 0, nmax = MB_CUR_MAX;
  1.1    rillig
1.222    rillig 	quoted_iterator it = { .end = 0 };
1.212    rillig 	while (quoted_next(buf, &it)) {
 1.44    rillig 		if (n < nmax)
1.212    rillig 			wbuf[n] = (char)it.value;
 1.44    rillig 		n++;
  1.1    rillig 	}
  1.1    rillig
1.211    rillig 	wchar_t wc = 0;
1.216    rillig 	if (n == 0)
  1.1    rillig 		/* empty character constant */
  1.1    rillig 		error(73);
1.216    rillig 	else if (n > nmax) {
 1.44    rillig 		n = nmax;
 1.43    rillig 		/* too many characters in character constant */
 1.43    rillig 		error(71);
  1.1    rillig 	} else {
1.212    rillig 		wbuf[n] = '\0';
 1.43    rillig 		(void)mbtowc(NULL, NULL, 0);
1.212    rillig 		if (mbtowc(&wc, wbuf, nmax) < 0)
 1.43    rillig 			/* invalid multibyte character */
 1.43    rillig 			error(291);
  1.1    rillig 	}
  1.1    rillig
 1.22    rillig 	yylval.y_val = xcalloc(1, sizeof(*yylval.y_val));
1.173    rillig 	yylval.y_val->v_tspec = WCHAR_TSPEC;
1.161    rillig 	yylval.y_val->v_char_constant = true;
1.166    rillig 	yylval.y_val->u.integer = wc;
  1.1    rillig
  1.1    rillig 	return T_CON;
  1.1    rillig }
  1.1    rillig
  1.1    rillig /* See https://gcc.gnu.org/onlinedocs/cpp/Preprocessor-Output.html */
  1.1    rillig static void
 1.25    rillig parse_line_directive_flags(const char *p,
 1.25    rillig 			   bool *is_begin, bool *is_end, bool *is_system)
  1.1    rillig {
  1.1    rillig
 1.25    rillig 	*is_begin = false;
 1.25    rillig 	*is_end = false;
 1.25    rillig 	*is_system = false;
  1.1    rillig
  1.8    rillig 	while (*p != '\0') {
1.221    rillig 		while (isspace((unsigned char)*p))
  1.1    rillig 			p++;
  1.8    rillig
1.157    rillig 		const char *word = p;
1.221    rillig 		while (*p != '\0' && !isspace((unsigned char)*p))
  1.8    rillig 			p++;
1.157    rillig 		size_t len = (size_t)(p - word);
  1.8    rillig
1.157    rillig 		if (len == 1 && word[0] == '1')
 1.25    rillig 			*is_begin = true;
1.157    rillig 		if (len == 1 && word[0] == '2')
 1.25    rillig 			*is_end = true;
1.157    rillig 		if (len == 1 && word[0] == '3')
 1.25    rillig 			*is_system = true;
 1.94    rillig 		/* Flag '4' is only interesting for C++. */
  1.1    rillig 	}
  1.1    rillig }
  1.1    rillig
  1.1    rillig /*
1.191    rillig  * The first directive of the preprocessed translation unit provides the name
1.191    rillig  * of the C source file as specified at the command line.
1.191    rillig  */
1.191    rillig static void
1.191    rillig set_csrc_pos(void)
1.191    rillig {
1.191    rillig 	static bool done;
1.191    rillig
1.191    rillig 	if (done)
1.191    rillig 		return;
1.191    rillig 	done = true;
1.191    rillig 	csrc_pos.p_file = curr_pos.p_file;
1.191    rillig 	outsrc(transform_filename(curr_pos.p_file, strlen(curr_pos.p_file)));
1.191    rillig }
1.191    rillig
1.191    rillig /*
  1.1    rillig  * Called for preprocessor directives. Currently implemented are:
 1.94    rillig  *	# pragma [argument...]
  1.1    rillig  *	# lineno
1.191    rillig  *	# lineno "filename" [GCC-flag...]
  1.1    rillig  */
  1.1    rillig void
  1.1    rillig lex_directive(const char *yytext)
  1.1    rillig {
1.191    rillig 	const char *p = yytext + 1;	/* skip '#' */
 1.25    rillig
1.191    rillig 	while (*p == ' ' || *p == '\t')
1.191    rillig 		p++;
  1.1    rillig
1.221    rillig 	if (!isdigit((unsigned char)*p)) {
1.221    rillig 		if (strncmp(p, "pragma", 6) == 0
1.221    rillig 		    && isspace((unsigned char)p[6]))
  1.1    rillig 			return;
1.191    rillig 		goto error;
  1.1    rillig 	}
1.191    rillig
1.191    rillig 	char *end;
1.191    rillig 	long ln = strtol(--p, &end, 10);
1.191    rillig 	if (end == p)
  1.1    rillig 		goto error;
1.191    rillig 	p = end;
1.191    rillig
1.191    rillig 	if (*p != ' ' && *p != '\t' && *p != '\0')
  1.1    rillig 		goto error;
1.191    rillig 	while (*p == ' ' || *p == '\t')
1.191    rillig 		p++;
1.191    rillig
1.191    rillig 	if (*p != '\0') {
1.191    rillig 		if (*p != '"')
  1.1    rillig 			goto error;
1.191    rillig 		const char *fn = ++p;
1.191    rillig 		while (*p != '"' && *p != '\0')
1.191    rillig 			p++;
1.191    rillig 		if (*p != '"')
  1.1    rillig 			goto error;
1.191    rillig 		size_t fn_len = p++ - fn;
1.191    rillig 		if (fn_len > PATH_MAX)
  1.1    rillig 			goto error;
1.191    rillig 		if (fn_len == 0) {
  1.1    rillig 			fn = "{standard input}";
1.191    rillig 			fn_len = strlen(fn);
  1.1    rillig 		}
1.191    rillig 		curr_pos.p_file = record_filename(fn, fn_len);
1.191    rillig 		set_csrc_pos();
 1.25    rillig
1.191    rillig 		bool is_begin, is_end, is_system;
1.191    rillig 		parse_line_directive_flags(p, &is_begin, &is_end, &is_system);
 1.26    rillig 		update_location(curr_pos.p_file, (int)ln, is_begin, is_end);
 1.26    rillig 		in_system_header = is_system;
  1.1    rillig 	}
  1.1    rillig 	curr_pos.p_line = (int)ln - 1;
  1.1    rillig 	curr_pos.p_uniq = 0;
  1.1    rillig 	if (curr_pos.p_file == csrc_pos.p_file) {
  1.1    rillig 		csrc_pos.p_line = (int)ln - 1;
  1.1    rillig 		csrc_pos.p_uniq = 0;
  1.1    rillig 	}
1.191    rillig 	return;
1.191    rillig
1.191    rillig error:
1.191    rillig 	/* undefined or invalid '#' directive */
1.191    rillig 	warning(255);
  1.1    rillig }
  1.1    rillig
1.180    rillig /* Handle lint comments such as ARGSUSED. */
  1.1    rillig void
  1.1    rillig lex_comment(void)
  1.1    rillig {
1.146    rillig 	int c;
  1.1    rillig 	static const struct {
1.180    rillig 		const	char name[18];
  1.3    rillig 		bool	arg;
1.180    rillig 		lint_comment comment;
  1.1    rillig 	} keywtab[] = {
1.180    rillig 		{ "ARGSUSED",		true,	LC_ARGSUSED	},
1.180    rillig 		{ "BITFIELDTYPE",	false,	LC_BITFIELDTYPE	},
1.180    rillig 		{ "CONSTCOND",		false,	LC_CONSTCOND	},
1.180    rillig 		{ "CONSTANTCOND",	false,	LC_CONSTCOND	},
1.180    rillig 		{ "CONSTANTCONDITION",	false,	LC_CONSTCOND	},
1.180    rillig 		{ "FALLTHRU",		false,	LC_FALLTHROUGH	},
1.180    rillig 		{ "FALLTHROUGH",	false,	LC_FALLTHROUGH	},
1.180    rillig 		{ "FALL THROUGH",	false,	LC_FALLTHROUGH	},
1.180    rillig 		{ "fallthrough",	false,	LC_FALLTHROUGH	},
1.180    rillig 		{ "LINTLIBRARY",	false,	LC_LINTLIBRARY	},
1.180    rillig 		{ "LINTED",		true,	LC_LINTED	},
1.180    rillig 		{ "LONGLONG",		false,	LC_LONGLONG	},
1.180    rillig 		{ "NOSTRICT",		true,	LC_LINTED	},
1.180    rillig 		{ "NOTREACHED",		false,	LC_NOTREACHED	},
1.180    rillig 		{ "PRINTFLIKE",		true,	LC_PRINTFLIKE	},
1.180    rillig 		{ "PROTOLIB",		true,	LC_PROTOLIB	},
1.180    rillig 		{ "SCANFLIKE",		true,	LC_SCANFLIKE	},
1.180    rillig 		{ "VARARGS",		true,	LC_VARARGS	},
  1.1    rillig 	};
1.159    rillig 	char keywd[32];
  1.1    rillig
1.146    rillig 	bool seen_end_of_comment = false;
  1.1    rillig
1.135    rillig 	while (c = read_byte(), isspace(c))
  1.1    rillig 		continue;
  1.1    rillig
  1.1    rillig 	/* Read the potential keyword to keywd */
1.223    rillig 	size_t l = 0;
 1.79    rillig 	while (c != EOF && l < sizeof(keywd) - 1 &&
 1.80    rillig 	    (isalpha(c) || isspace(c))) {
1.221    rillig 		if (islower(c) && l > 0 && isupper((unsigned char)keywd[0]))
 1.80    rillig 			break;
  1.1    rillig 		keywd[l++] = (char)c;
1.135    rillig 		c = read_byte();
  1.1    rillig 	}
1.221    rillig 	while (l > 0 && isspace((unsigned char)keywd[l - 1]))
 1.79    rillig 		l--;
  1.1    rillig 	keywd[l] = '\0';
  1.1    rillig
  1.1    rillig 	/* look for the keyword */
1.223    rillig 	size_t i;
1.181    rillig 	for (i = 0; i < sizeof(keywtab) / sizeof(keywtab[0]); i++)
1.180    rillig 		if (strcmp(keywtab[i].name, keywd) == 0)
1.181    rillig 			goto found_keyword;
1.181    rillig 	goto skip_rest;
  1.1    rillig
1.181    rillig found_keyword:
 1.94    rillig 	while (isspace(c))
1.135    rillig 		c = read_byte();
  1.1    rillig
  1.1    rillig 	/* read the argument, if the keyword accepts one and there is one */
1.223    rillig 	char arg[32];
  1.1    rillig 	l = 0;
  1.1    rillig 	if (keywtab[i].arg) {
 1.94    rillig 		while (isdigit(c) && l < sizeof(arg) - 1) {
  1.1    rillig 			arg[l++] = (char)c;
1.135    rillig 			c = read_byte();
  1.1    rillig 		}
  1.1    rillig 	}
  1.1    rillig 	arg[l] = '\0';
1.223    rillig 	int a = l != 0 ? atoi(arg) : -1;
  1.1    rillig
 1.94    rillig 	while (isspace(c))
1.135    rillig 		c = read_byte();
  1.1    rillig
1.146    rillig 	seen_end_of_comment = c == '*' && (c = read_byte()) == '/';
1.180    rillig 	if (!seen_end_of_comment && keywtab[i].comment != LC_LINTED)
1.146    rillig 		/* extra characters in lint comment */
1.146    rillig 		warning(257);
  1.1    rillig
1.180    rillig 	handle_lint_comment(keywtab[i].comment, a);
  1.1    rillig
  1.1    rillig skip_rest:
1.146    rillig 	while (!seen_end_of_comment) {
1.146    rillig 		int lc = c;
1.135    rillig 		if ((c = read_byte()) == EOF) {
  1.1    rillig 			/* unterminated comment */
  1.1    rillig 			error(256);
  1.1    rillig 			break;
  1.1    rillig 		}
  1.1    rillig 		if (lc == '*' && c == '/')
1.146    rillig 			seen_end_of_comment = true;
  1.1    rillig 	}
  1.1    rillig }
  1.1    rillig
  1.1    rillig void
  1.6    rillig lex_slash_slash_comment(void)
  1.1    rillig {
  1.1    rillig
1.121    rillig 	if (!allow_c99 && !allow_gcc)
1.170    rillig 		/* %s does not support '//' comments */
1.121    rillig 		gnuism(312, allow_c90 ? "C90" : "traditional C");
  1.1    rillig
1.223    rillig 	for (int c; c = read_byte(), c != EOF && c != '\n';)
  1.1    rillig 		continue;
  1.1    rillig }
  1.1    rillig
  1.1    rillig void
1.223    rillig reset_suppressions(void)
  1.1    rillig {
  1.1    rillig
  1.1    rillig 	lwarn = LWARN_ALL;
1.179    rillig 	suppress_longlong = false;
1.179    rillig 	suppress_constcond = false;
  1.1    rillig }
  1.1    rillig
  1.1    rillig int
  1.1    rillig lex_string(void)
  1.1    rillig {
1.212    rillig 	yylval.y_string = lex_quoted('"', false);
  1.1    rillig 	return T_STRING;
  1.1    rillig }
  1.1    rillig
1.209    rillig static size_t
1.209    rillig wide_length(const buffer *buf)
1.209    rillig {
1.209    rillig
1.209    rillig 	(void)mblen(NULL, 0);
1.209    rillig 	size_t len = 0, i = 0;
1.209    rillig 	while (i < buf->len) {
1.209    rillig 		int n = mblen(buf->data + i, MB_CUR_MAX);
1.209    rillig 		if (n == -1) {
1.209    rillig 			/* invalid multibyte character */
1.209    rillig 			error(291);
1.209    rillig 			break;
1.209    rillig 		}
1.209    rillig 		i += n > 1 ? n : 1;
1.209    rillig 		len++;
1.209    rillig 	}
1.209    rillig 	return len;
1.209    rillig }
1.209    rillig
  1.1    rillig int
  1.6    rillig lex_wide_string(void)
  1.1    rillig {
1.212    rillig 	buffer *buf = lex_quoted('"', true);
  1.1    rillig
1.212    rillig 	buffer str;
1.212    rillig 	buf_init(&str);
1.222    rillig 	quoted_iterator it = { .end = 0 };
1.212    rillig 	while (quoted_next(buf, &it))
1.212    rillig 		buf_add_char(&str, (char)it.value);
  1.1    rillig
1.212    rillig 	free(buf->data);
1.212    rillig 	*buf = (buffer) { .len = wide_length(&str) };
  1.1    rillig
1.212    rillig 	yylval.y_string = buf;
  1.1    rillig 	return T_STRING;
  1.1    rillig }
  1.1    rillig
1.105    rillig void
1.105    rillig lex_next_line(void)
1.105    rillig {
1.105    rillig 	curr_pos.p_line++;
1.105    rillig 	curr_pos.p_uniq = 0;
1.189    rillig 	debug_skip_indent();
1.187    rillig 	debug_printf("parsing %s:%d\n", curr_pos.p_file, curr_pos.p_line);
1.105    rillig 	if (curr_pos.p_file == csrc_pos.p_file) {
1.105    rillig 		csrc_pos.p_line++;
1.105    rillig 		csrc_pos.p_uniq = 0;
1.105    rillig 	}
1.105    rillig }
1.105    rillig
1.105    rillig void
1.105    rillig lex_unknown_character(int c)
1.105    rillig {
1.105    rillig
1.105    rillig 	/* unknown character \%o */
1.105    rillig 	error(250, c);
1.105    rillig }
1.105    rillig
  1.1    rillig /*
1.113    rillig  * The scanner does not create new symbol table entries for symbols it cannot
1.113    rillig  * find in the symbol table. This is to avoid putting undeclared symbols into
1.113    rillig  * the symbol table if a syntax error occurs.
  1.1    rillig  *
1.113    rillig  * getsym is called as soon as it is probably ok to put the symbol in the
 1.53    rillig  * symbol table. It is still possible that symbols are put in the symbol
 1.53    rillig  * table that are not completely declared due to syntax errors. To avoid too
1.113    rillig  * many problems in this case, symbols get type 'int' in getsym.
  1.1    rillig  *
1.113    rillig  * XXX calls to getsym should be delayed until declare_1_* is called.
  1.1    rillig  */
  1.1    rillig sym_t *
  1.1    rillig getsym(sbuf_t *sb)
  1.1    rillig {
  1.1    rillig
1.143    rillig 	sym_t *sym = sb->sb_sym;
  1.1    rillig
  1.1    rillig 	/*
1.195    rillig 	 * During member declaration it is possible that name() looked for
1.200    rillig 	 * symbols of type SK_VCFT, although it should have looked for symbols
1.200    rillig 	 * of type SK_TAG. Same can happen for labels. Both cases are
1.200    rillig 	 * compensated here.
  1.1    rillig 	 */
1.200    rillig 	if (sym_kind == SK_MEMBER || sym_kind == SK_LABEL) {
1.200    rillig 		if (sym == NULL || sym->s_kind == SK_VCFT)
1.143    rillig 			sym = symtab_search(sb->sb_name);
  1.1    rillig 	}
  1.1    rillig
  1.1    rillig 	if (sym != NULL) {
1.200    rillig 		lint_assert(sym->s_kind == sym_kind);
1.200    rillig 		set_sym_kind(SK_VCFT);
1.100    rillig 		free(sb);
  1.1    rillig 		return sym;
  1.1    rillig 	}
  1.1    rillig
  1.1    rillig 	/* create a new symbol table entry */
  1.1    rillig
1.164    rillig 	decl_level *dl;
1.200    rillig 	if (sym_kind == SK_LABEL) {
1.188    rillig 		sym = level_zero_alloc(1, sizeof(*sym), "sym");
1.188    rillig 		char *s = level_zero_alloc(1, sb->sb_len + 1, "string");
  1.1    rillig 		(void)memcpy(s, sb->sb_name, sb->sb_len + 1);
  1.1    rillig 		sym->s_name = s;
 1.12    rillig 		sym->s_block_level = 1;
1.164    rillig 		dl = dcs;
1.164    rillig 		while (dl->d_enclosing != NULL &&
1.164    rillig 		    dl->d_enclosing->d_enclosing != NULL)
1.164    rillig 			dl = dl->d_enclosing;
1.164    rillig 		lint_assert(dl->d_kind == DLK_AUTO);
  1.1    rillig 	} else {
1.188    rillig 		sym = block_zero_alloc(sizeof(*sym), "sym");
  1.1    rillig 		sym->s_name = sb->sb_name;
 1.12    rillig 		sym->s_block_level = block_level;
1.164    rillig 		dl = dcs;
  1.1    rillig 	}
  1.1    rillig
1.163    rillig 	sym->s_def_pos = unique_curr_pos();
1.200    rillig 	if ((sym->s_kind = sym_kind) != SK_LABEL)
  1.1    rillig 		sym->s_type = gettyp(INT);
  1.1    rillig
1.200    rillig 	set_sym_kind(SK_VCFT);
  1.1    rillig
1.133    rillig 	if (!in_gcc_attribute) {
1.190    rillig 		debug_printf("%s: symtab_add ", __func__);
1.190    rillig 		debug_sym("", sym, "\n");
1.133    rillig 		symtab_add(sym);
  1.1    rillig
1.164    rillig 		*dl->d_last_dlsym = sym;
1.164    rillig 		dl->d_last_dlsym = &sym->s_level_next;
1.133    rillig 	}
  1.1    rillig
1.100    rillig 	free(sb);
  1.1    rillig 	return sym;
  1.1    rillig }
  1.1    rillig
  1.1    rillig /*
1.146    rillig  * Construct a temporary symbol. The symbol name starts with a digit to avoid
1.146    rillig  * name clashes with other identifiers.
  1.1    rillig  */
  1.1    rillig sym_t *
1.112    rillig mktempsym(type_t *tp)
  1.1    rillig {
1.112    rillig 	static unsigned n = 0;
1.188    rillig 	char *s = level_zero_alloc((size_t)block_level, 64, "string");
1.188    rillig 	sym_t *sym = block_zero_alloc(sizeof(*sym), "sym");
 1.28    rillig 	scl_t scl;
  1.1    rillig
1.112    rillig 	(void)snprintf(s, 64, "%.8u_tmp", n++);
  1.1    rillig
 1.28    rillig 	scl = dcs->d_scl;
1.193    rillig 	if (scl == NO_SCL)
 1.28    rillig 		scl = block_level > 0 ? AUTO : EXTERN;
 1.28    rillig
  1.1    rillig 	sym->s_name = s;
1.112    rillig 	sym->s_type = tp;
 1.12    rillig 	sym->s_block_level = block_level;
 1.28    rillig 	sym->s_scl = scl;
1.200    rillig 	sym->s_kind = SK_VCFT;
  1.1    rillig 	sym->s_used = true;
  1.1    rillig 	sym->s_set = true;
  1.1    rillig
 1.60    rillig 	symtab_add(sym);
  1.1    rillig
1.162    rillig 	*dcs->d_last_dlsym = sym;
1.162    rillig 	dcs->d_last_dlsym = &sym->s_level_next;
  1.1    rillig
  1.1    rillig 	return sym;
  1.1    rillig }
  1.1    rillig
  1.1    rillig void
1.223    rillig symtab_remove_forever(sym_t *sym)
  1.1    rillig {
  1.1    rillig
1.223    rillig 	debug_step("%s '%s' %s '%s'", __func__,
1.200    rillig 	    sym->s_name, symbol_kind_name(sym->s_kind),
1.200    rillig 	    type_name(sym->s_type));
 1.61    rillig 	symtab_remove(sym);
 1.61    rillig
 1.61    rillig 	/* avoid that the symbol will later be put back to the symbol table */
 1.12    rillig 	sym->s_block_level = -1;
  1.1    rillig }
  1.1    rillig
  1.1    rillig /*
1.113    rillig  * Remove all symbols from the symbol table that have the same level as the
1.113    rillig  * given symbol.
  1.1    rillig  */
  1.1    rillig void
1.165    rillig symtab_remove_level(sym_t *syms)
  1.1    rillig {
  1.1    rillig
1.187    rillig 	if (syms != NULL)
1.187    rillig 		debug_step("%s %d", __func__, syms->s_block_level);
1.187    rillig
1.113    rillig 	/* Note the use of s_level_next instead of s_symtab_next. */
1.165    rillig 	for (sym_t *sym = syms; sym != NULL; sym = sym->s_level_next) {
 1.12    rillig 		if (sym->s_block_level != -1) {
1.187    rillig 			debug_step("%s '%s' %s '%s' %d", __func__,
1.200    rillig 			    sym->s_name, symbol_kind_name(sym->s_kind),
1.200    rillig 			    type_name(sym->s_type), sym->s_block_level);
 1.61    rillig 			symtab_remove(sym);
1.102    rillig 			sym->s_symtab_ref = NULL;
  1.1    rillig 		}
  1.1    rillig 	}
  1.1    rillig }
  1.1    rillig
1.146    rillig /* Put a symbol into the symbol table. */
  1.1    rillig void
1.113    rillig inssym(int level, sym_t *sym)
  1.1    rillig {
  1.1    rillig
1.187    rillig 	debug_step("%s '%s' %s '%s' %d", __func__,
1.200    rillig 	    sym->s_name, symbol_kind_name(sym->s_kind),
1.200    rillig 	    type_name(sym->s_type), level);
1.187    rillig 	sym->s_block_level = level;
 1.60    rillig 	symtab_add(sym);
1.113    rillig
1.146    rillig 	const sym_t *next = sym->s_symtab_next;
1.146    rillig 	if (next != NULL)
1.146    rillig 		lint_assert(sym->s_block_level >= next->s_block_level);
  1.1    rillig }
  1.1    rillig
1.146    rillig /* Called at level 0 after syntax errors. */
  1.1    rillig void
1.109    rillig clean_up_after_error(void)
  1.1    rillig {
  1.1    rillig
1.104    rillig 	symtab_remove_locals();
  1.1    rillig
1.143    rillig 	while (mem_block_level > 0)
1.143    rillig 		level_free_all(mem_block_level--);
  1.1    rillig }
  1.1    rillig
1.113    rillig /* Create a new symbol with the same name as an existing symbol. */
  1.1    rillig sym_t *
 1.21    rillig pushdown(const sym_t *sym)
  1.1    rillig {
  1.1    rillig
 1.98    rillig 	debug_step("pushdown '%s' %s '%s'",
1.200    rillig 	    sym->s_name, symbol_kind_name(sym->s_kind),
1.200    rillig 	    type_name(sym->s_type));
1.223    rillig
1.223    rillig 	sym_t *nsym = block_zero_alloc(sizeof(*nsym), "sym");
 1.12    rillig 	lint_assert(sym->s_block_level <= block_level);
  1.1    rillig 	nsym->s_name = sym->s_name;
1.163    rillig 	nsym->s_def_pos = unique_curr_pos();
  1.1    rillig 	nsym->s_kind = sym->s_kind;
 1.12    rillig 	nsym->s_block_level = block_level;
  1.1    rillig
 1.60    rillig 	symtab_add(nsym);
  1.1    rillig
1.162    rillig 	*dcs->d_last_dlsym = nsym;
1.162    rillig 	dcs->d_last_dlsym = &nsym->s_level_next;
  1.1    rillig
  1.1    rillig 	return nsym;
  1.1    rillig }
  1.1    rillig
  1.1    rillig /*
  1.1    rillig  * Free any dynamically allocated memory referenced by
  1.1    rillig  * the value stack or yylval.
  1.1    rillig  * The type of information in yylval is described by tok.
  1.1    rillig  */
  1.1    rillig void
  1.1    rillig freeyyv(void *sp, int tok)
  1.1    rillig {
  1.1    rillig 	if (tok == T_NAME || tok == T_TYPENAME) {
  1.1    rillig 		sbuf_t *sb = *(sbuf_t **)sp;
1.100    rillig 		free(sb);
  1.1    rillig 	} else if (tok == T_CON) {
  1.1    rillig 		val_t *val = *(val_t **)sp;
  1.1    rillig 		free(val);
  1.1    rillig 	} else if (tok == T_STRING) {
1.205    rillig 		buffer *str = *(buffer **)sp;
1.205    rillig 		free(str->data);
1.205    rillig 		free(str);
  1.1    rillig 	}
  1.1    rillig }