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gnu / bison / refs/heads/partialorder / . / src / symtab.c
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/* Symbol table manager for Bison.
Copyright (C) 1984, 1989, 2000-2002, 2004-2013 Free Software
Foundation, Inc.
This file is part of Bison, the GNU Compiler Compiler.
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>. */
#include <config.h>
#include "system.h"
#include <hash.h>
#include "complain.h"
#include "gram.h"
#include "symtab.h"
#include "symlist.h"
/*-------------------------------------------------------------------.
| Symbols sorted by tag. Allocated by the first invocation of |
| symbols_do, after which no more symbols should be created. |
`-------------------------------------------------------------------*/
static symbol **symbols_sorted = NULL;
static symbol **semantic_types_sorted = NULL;
/*------------------------.
| Distinguished symbols. |
`------------------------*/
symbol *errtoken = NULL;
symbol *undeftoken = NULL;
symbol *endtoken = NULL;
symbol *accept = NULL;
symbol *startsymbol = NULL;
location startsymbol_location;
/*---------------------------.
| Precedence relation graph. |
`---------------------------*/
static symgraph **prec_nodes;
/*-----------------------------------.
| Store which associativity is used. |
`-----------------------------------*/
bool *used_assoc = NULL;
/*-------------------------------------------------------------.
| The current precedence group of symbols. Used by the parser. |
`-------------------------------------------------------------*/
static symgroup *current_group = NULL;
/*-------------------------------------------------------.
| The list of symbols declared in the current statement. |
`-------------------------------------------------------*/
static symbol_list *current_prec_declaration = NULL;
/*-------------------------------------------------.
| A counter to distinguish precedence declarations |
`-------------------------------------------------*/
static int current_prec_level = 0;
/*-----------------------------.
| Constructor for a prec_link. |
`-----------------------------*/
static prec_link *
prec_link_new (prec_node *to, bool transitive)
{
prec_link *res = malloc (sizeof *res);
res->target = to;
res->transitive = transitive;
res->next = NULL;
return res;
}
/*-------------------------------------.
| Destructor for a simple symbol list. |
`-------------------------------------*/
static void
symbol_list_prec_free (symbol_list *l)
{
if (l)
{
symbol_list_prec_free (l->next);
free (l);
}
}
/*------------------------------------------------.
| Check if PARENT has a higher priority than SON. |
`------------------------------------------------*/
bool
is_prec_superior (prec_node *parent, prec_node *son)
{
prec_link *l;
for (l = parent->sons; l; l = l->next)
if (l->target == son)
return true;
return false;
}
/*-----------------------------------------.
| Check if S1 has the same priority as S2. |
`-----------------------------------------*/
bool
is_prec_equal (prec_node *s1, prec_node *s2)
{
prec_link *l;
if (s1 == s2)
return true;
for (l = s1->equals; l; l = l->next)
if (l->target == s2)
return true;
return false;
}
static inline void
complain_contradicting_prec (location *loc, uniqstr s1, uniqstr s2, char c1,
char c2)
{
complain (loc, Wprecedence, _("contradicting declaration: %s %c %s is in "
"conflict with the previous declaration: %s %c %s"), s1, c1, s2,
s1, c2, s2);
}
/*-----------------------------------------------------------------------.
| Compare LINK with TARGET, and return whether they are equal. |
| In case of equality, complain of the duplicate precedence declaration. |
`-----------------------------------------------------------------------*/
static inline bool
is_prec_target (prec_node *l, prec_node *target, uniqstr from, char c,
location loc)
{
if (l == target)
{
complain (&loc, Wprecedence, _("duplicate declaration of the precedence "
"relationship %s %c %s"), from, c,
target->symbol->tag);
return true;
}
return false;
}
/*-----------------------------------------.
| Add a precedence relationship FROM > TO. |
`-----------------------------------------*/
static void
add_prec_link (prec_node *from, prec_node *to, bool transitive, location loc)
{
if (is_prec_superior (to, from))
complain_contradicting_prec(&loc, from->symbol->tag, to->symbol->tag,
'>', '<');
else if (is_prec_equal (from, to))
complain_contradicting_prec(&loc, from->symbol->tag, to->symbol->tag,
'>', '=');
else
{
if (from->sons)
{
if (is_prec_target (from->sons->target, to, from->symbol->tag, '>',
loc))
return;
prec_link *son = from->sons;
for (; son->next; son = son->next)
if (is_prec_target (son->next->target, to, from->symbol->tag, '>',
loc))
return;
son->next = prec_link_new (to, transitive);
}
else
from->sons = prec_link_new (to, transitive);
}
}
/*-------------------------------------------------.
| Add a precedence relationship S1 == S2, one way. |
`-------------------------------------------------*/
static void
create_prec_equal_link (prec_node *s1, prec_node *s2, bool transitive,
location loc)
{
if (s1->equals)
{
if (is_prec_target (s1->equals->target, s2, s1->symbol->tag, '=',
loc))
return;
prec_link *eq = s1->equals;
for (; eq->next; eq = eq->next)
if (is_prec_target (eq->next->target, s2, s1->symbol->tag, '=',
loc))
return;
eq->next = prec_link_new (s2, transitive);
}
else
s1->equals = prec_link_new (s2, transitive);
}
/*---------------------------------------------------.
| Add a precedence relationship S1 == S2, both ways. |
`---------------------------------------------------*/
static void
add_prec_equal_link (prec_node *s1, prec_node *s2, bool transitive,
location loc)
{
if (is_prec_superior (s2, s1))
complain_contradicting_prec(&loc, s1->symbol->tag, s2->symbol->tag,
'=', '>');
else if (is_prec_superior (s1, s2))
complain_contradicting_prec(&loc, s1->symbol->tag, s2->symbol->tag,
'=', '<');
create_prec_equal_link (s1, s2, transitive, loc);
create_prec_equal_link (s2, s1, transitive, loc);
}
/* The function to use to register \a c type relations. */
typedef void (*add_link_t) (prec_node *, prec_node *, bool, location);
static add_link_t
add_link_function (prec_rel_comparator c)
{
switch (c)
{
case prec_superior_strict:
case prec_superior:
return &add_prec_link;
case prec_equal:
return &add_prec_equal_link;
}
abort ();
}
/*---------------------------------------------------------------------.
| Handle the precedence declaration between the elements of S1 and S2. |
`---------------------------------------------------------------------*/
void
declare_precedence_relation (symbol_list *s1, symbol_list *s2,
prec_rel_comparator c, location loc)
{
void (*functionPtr) (prec_node *, prec_node *, bool, location)
= add_link_function (c);
bool transitive = c != prec_superior_strict;
for (symbol_list *l1 = s1; l1; l1 = l1->next)
for (symbol_list *l2 = s2; l2; l2 = l2->next)
(*functionPtr)(l1->content.sym->content->prec_node,
l2->content.sym->content->prec_node, transitive, loc);
symbol_list_free (s1);
symbol_list_free (s2);
}
/*----------------------------------------------.
| Get the list of symbols contained in a group. |
`----------------------------------------------*/
symbol_list *
expand_symbol_group (symgroup *group, location loc)
{
symbol_list *l = NULL;
for (sym_content *s = group->symbol_list; s; s = s->group_next)
l = symbol_list_append (l, symbol_list_sym_new (s->symbol, loc));
return l;
}
/*------------------------------------------------------------------------.
| Add a symbol to the current declaration group, and declare the implicit |
| precedence links. SAME_LINE is true if the symbol was declared in the |
| same statement as the previous one (same precedence level). |
`------------------------------------------------------------------------*/
void
add_to_current_group (sym_content *s, bool same_line)
{
if (!same_line)
for (symbol_list *l = current_prec_declaration; l; l = l->next)
{
sym_content *symb = l->content.sym->content;
if (!current_group->symbol_list)
current_group->symbol_list = symb;
else
{
sym_content *sym = current_group->symbol_list;
while (sym->group_next)
sym = sym->group_next;
sym->group_next = symb;
}
}
if (current_group->symbol_list)
for (sym_content *sym = current_group->symbol_list; sym;
sym = sym->group_next)
add_prec_link (s->prec_node, sym->prec_node, true,
s->prec_node->prec_location);
if (!same_line)
{
symbol_list_prec_free (current_prec_declaration);
current_prec_declaration = malloc (sizeof *current_prec_declaration);
current_prec_declaration->content.sym = s->symbol;
current_prec_declaration->next = NULL;
}
else
{
symbol_list *l = current_prec_declaration;
for (; true; l = l->next)
{
add_prec_equal_link (s->prec_node, l->content.sym->content->prec_node,
true, s->prec_node->prec_location);
if (!l->next)
break;
}
l->next = malloc (sizeof *l->next);
l->next->content.sym = s->symbol;
l->next->next = NULL;
}
}
/*-----------------------------------------.
| Create a new prec_node for the symbol s. |
`-----------------------------------------*/
static prec_node *
prec_node_new (symbol * s)
{
prec_node * res = malloc (sizeof *res);
res->symbol = s;
res->assoc = undef_assoc;
res->sons = NULL;
res-> equals = NULL;
return res;
}
/*--------------------------.
| Create a new sym_content. |
`--------------------------*/
static sym_content *
sym_content_new (symbol *s)
{
sym_content *res = xmalloc (sizeof *res);
res->symbol = s;
res->type_name = NULL;
{
int i;
for (i = 0; i < CODE_PROPS_SIZE; ++i)
code_props_none_init (&res->props[i]);
}
res->number = NUMBER_UNDEFINED;
res->prec = 0;
res->user_token_number = USER_NUMBER_UNDEFINED;
res->class = unknown_sym;
res->status = undeclared;
res->group_next = NULL;
res->prec_node = prec_node_new (s);
return res;
}
/*---------------------------------.
| Create a new symbol, named TAG. |
`---------------------------------*/
static symbol *
symbol_new (uniqstr tag, location loc)
{
symbol *res = xmalloc (sizeof *res);
uniqstr_assert (tag);
/* If the tag is not a string (starts with a double quote), check
that it is valid for Yacc. */
if (tag[0] != '\"' && tag[0] != '\'' && strchr (tag, '-'))
complain (&loc, Wyacc,
_("POSIX Yacc forbids dashes in symbol names: %s"), tag);
res->tag = tag;
res->location = loc;
res->alias = NULL;
res->content = sym_content_new (res);
res->is_alias = false;
if (nsyms == SYMBOL_NUMBER_MAXIMUM)
complain (NULL, fatal, _("too many symbols in input grammar (limit is %d)"),
SYMBOL_NUMBER_MAXIMUM);
nsyms++;
return res;
}
void
prec_link_free (prec_link * l)
{
if (l)
{
prec_link_free (l->next);
free (l);
}
}
/*--------------------.
| Free one prec_node. |
`--------------------*/
static void
prec_node_free (prec_node * n)
{
prec_link_free (n->sons);
prec_link_free (n->equals);
free (n);
}
/*--------------------.
| Free a sym_content. |
`--------------------*/
static void
sym_content_free (sym_content *sym)
{
prec_node_free (sym->prec_node);
free (sym);
}
/*---------------------------------------------------------.
| Free a symbol and its associated content if appropriate. |
`---------------------------------------------------------*/
static void
symbol_free (void *ptr)
{
symbol *sym = (symbol *)ptr;
if (!sym->is_alias)
sym_content_free (sym->content);
free (sym);
}
char const *
code_props_type_string (code_props_type kind)
{
switch (kind)
{
case destructor:
return "%destructor";
case printer:
return "%printer";
}
assert (0);
}
/*----------------------------------------.
| Create a new semantic type, named TAG. |
`----------------------------------------*/
static semantic_type *
semantic_type_new (uniqstr tag, const location *loc)
{
semantic_type *res = xmalloc (sizeof *res);
uniqstr_assert (tag);
res->tag = tag;
res->location = loc ? *loc : empty_location;
res->status = undeclared;
{
int i;
for (i = 0; i < CODE_PROPS_SIZE; ++i)
code_props_none_init (&res->props[i]);
}
return res;
}
/*-----------------.
| Print a symbol. |
`-----------------*/
#define SYMBOL_ATTR_PRINT(Attr) \
if (s->content->Attr) \
fprintf (f, " %s { %s }", #Attr, s->content->Attr)
#define SYMBOL_CODE_PRINT(Attr) \
if (s->content->props[Attr].code) \
fprintf (f, " %s { %s }", #Attr, s->content->props[Attr].code)
void
symbol_print (symbol const *s, FILE *f)
{
if (s)
{
fputs (s->tag, f);
SYMBOL_ATTR_PRINT (type_name);
SYMBOL_CODE_PRINT (destructor);
SYMBOL_CODE_PRINT (printer);
}
else
fputs ("<NULL>", f);
}
#undef SYMBOL_ATTR_PRINT
#undef SYMBOL_CODE_PRINT
/*----------------------------------.
| Whether S is a valid identifier. |
`----------------------------------*/
static bool
is_identifier (uniqstr s)
{
static char const alphanum[26 + 26 + 1 + 10] =
"abcdefghijklmnopqrstuvwxyz"
"ABCDEFGHIJKLMNOPQRSTUVWXYZ"
"_"
"0123456789";
if (!s || ! memchr (alphanum, *s, sizeof alphanum - 10))
return false;
for (++s; *s; ++s)
if (! memchr (alphanum, *s, sizeof alphanum))
return false;
return true;
}
/*-----------------------------------------------.
| Get the identifier associated to this symbol. |
`-----------------------------------------------*/
uniqstr
symbol_id_get (symbol const *sym)
{
aver (sym->content->user_token_number != USER_NUMBER_HAS_STRING_ALIAS);
if (sym->alias)
sym = sym->alias;
return is_identifier (sym->tag) ? sym->tag : 0;
}
/*------------------------------------------------------------------.
| Complain that S's WHAT is redeclared at SECOND, and was first set |
| at FIRST. |
`------------------------------------------------------------------*/
static void
symbol_redeclaration (symbol *s, const char *what, location first,
location second)
{
unsigned i = 0;
complain_indent (&second, complaint, &i,
_("%s redeclaration for %s"), what, s->tag);
i += SUB_INDENT;
complain_indent (&first, complaint, &i,
_("previous declaration"));
}
static void
semantic_type_redeclaration (semantic_type *s, const char *what, location first,
location second)
{
unsigned i = 0;
complain_indent (&second, complaint, &i,
_("%s redeclaration for <%s>"), what, s->tag);
i += SUB_INDENT;
complain_indent (&first, complaint, &i,
_("previous declaration"));
}
/*-----------------------------------------------------------------.
| Set the TYPE_NAME associated with SYM. Does nothing if passed 0 |
| as TYPE_NAME. |
`-----------------------------------------------------------------*/
void
symbol_type_set (symbol *sym, uniqstr type_name, location loc)
{
if (type_name)
{
if (sym->content->type_name)
symbol_redeclaration (sym, "%type", sym->content->type_location, loc);
else
{
uniqstr_assert (type_name);
sym->content->type_name = type_name;
sym->content->type_location = loc;
}
}
}
/*--------------------------------------------------------.
| Set the DESTRUCTOR or PRINTER associated with the SYM. |
`--------------------------------------------------------*/
void
symbol_code_props_set (symbol *sym, code_props_type kind,
code_props const *code)
{
if (sym->content->props[kind].code)
symbol_redeclaration (sym, code_props_type_string (kind),
sym->content->props[kind].location,
code->location);
else
sym->content->props[kind] = *code;
}
/*-----------------------------------------------------.
| Set the DESTRUCTOR or PRINTER associated with TYPE. |
`-----------------------------------------------------*/
void
semantic_type_code_props_set (semantic_type *type,
code_props_type kind,
code_props const *code)
{
if (type->props[kind].code)
semantic_type_redeclaration (type, code_props_type_string (kind),
type->props[kind].location,
code->location);
else
type->props[kind] = *code;
}
/*---------------------------------------------------.
| Get the computed %destructor or %printer for SYM. |
`---------------------------------------------------*/
code_props *
symbol_code_props_get (symbol *sym, code_props_type kind)
{
/* Per-symbol code props. */
if (sym->content->props[kind].code)
return &sym->content->props[kind];
/* Per-type code props. */
if (sym->content->type_name)
{
code_props *code =
&semantic_type_get (sym->content->type_name, NULL)->props[kind];
if (code->code)
return code;
}
/* Apply default code props's only to user-defined symbols. */
if (sym->tag[0] != '$' && sym != errtoken)
{
code_props *code = &semantic_type_get (sym->content->type_name ? "*" : "",
NULL)->props[kind];
if (code->code)
return code;
}
return &code_props_none;
}
/*-----------------------------------------------------------------.
| Set the PRECEDENCE associated with SYM. Does nothing if invoked |
| with UNDEF_ASSOC as ASSOC. |
`-----------------------------------------------------------------*/
void
symbol_precedence_set (symbol *sym, int prec, assoc a, location loc)
{
sym_content *s = sym->content;
if (a != undef_assoc)
{
if (s->prec_node->assoc != undef_assoc)
symbol_redeclaration (sym, assoc_to_string (a),
s->prec_node->prec_location, loc);
else
{
s->prec = prec;
s->prec_node->assoc = a;
s->prec_node->prec_location = loc;
add_to_current_group (s, prec == current_prec_level);
current_prec_level = prec;
}
}
/* Only terminals have a precedence. */
symbol_class_set (sym, token_sym, loc, false);
}
/*------------------------------------.
| Set the CLASS associated with SYM. |
`------------------------------------*/
void
symbol_class_set (symbol *sym, symbol_class class, location loc, bool declaring)
{
bool warned = false;
if (sym->content->class != unknown_sym && sym->content->class != class)
{
complain (&loc, complaint, _("symbol %s redefined"), sym->tag);
/* Don't report both "redefined" and "redeclared". */
warned = true;
}
if (class == nterm_sym && sym->content->class != nterm_sym)
sym->content->number = nvars++;
else if (class == token_sym && sym->content->number == NUMBER_UNDEFINED)
sym->content->number = ntokens++;
sym->content->class = class;
if (declaring)
{
if (sym->content->status == declared && !warned)
complain (&loc, Wother, _("symbol %s redeclared"), sym->tag);
else
sym->content->status = declared;
}
}
/*------------------------------------------------.
| Set the USER_TOKEN_NUMBER associated with SYM. |
`------------------------------------------------*/
void
symbol_user_token_number_set (symbol *sym, int user_token_number, location loc)
{
int *user_token_numberp;
user_token_numberp = &sym->content->user_token_number;
if (*user_token_numberp != USER_NUMBER_UNDEFINED
&& *user_token_numberp != user_token_number)
complain (&loc, complaint, _("redefining user token number of %s"),
sym->tag);
*user_token_numberp = user_token_number;
/* User defined $end token? */
if (user_token_number == 0)
{
endtoken = sym->content->symbol;
/* It is always mapped to 0, so it was already counted in
NTOKENS. */
if (endtoken->content->number != NUMBER_UNDEFINED)
--ntokens;
endtoken->content->number = 0;
}
}
/*----------------------------------------------------------.
| If SYM is not defined, report an error, and consider it a |
| nonterminal. |
`----------------------------------------------------------*/
static inline bool
symbol_check_defined (symbol *sym)
{
sym_content *s = sym->content;
if (s->class == unknown_sym)
{
assert (s->status != declared);
complain (&sym->location,
s->status == needed ? complaint : Wother,
_("symbol %s is used, but is not defined as a token"
" and has no rules"),
sym->tag);
s->class = nterm_sym;
s->number = nvars++;
}
{
int i;
for (i = 0; i < 2; ++i)
symbol_code_props_get (sym, i)->is_used = true;
}
/* Set the semantic type status associated to the current symbol to
'declared' so that we could check semantic types unnecessary uses. */
if (s->type_name)
{
semantic_type *sem_type = semantic_type_get (s->type_name, NULL);
if (sem_type)
sem_type->status = declared;
}
return true;
}
static inline bool
semantic_type_check_defined (semantic_type *sem_type)
{
/* <*> and <> do not have to be "declared". */
if (sem_type->status == declared
|| !*sem_type->tag
|| STREQ (sem_type->tag, "*"))
{
int i;
for (i = 0; i < 2; ++i)
if (sem_type->props[i].kind != CODE_PROPS_NONE
&& ! sem_type->props[i].is_used)
complain (&sem_type->location, Wother,
_("useless %s for type <%s>"),
code_props_type_string (i), sem_type->tag);
}
else
complain (&sem_type->location, Wother,
_("type <%s> is used, but is not associated to any symbol"),
sem_type->tag);
return true;
}
static bool
symbol_check_defined_processor (void *sym, void *null ATTRIBUTE_UNUSED)
{
return symbol_check_defined (sym);
}
static bool
semantic_type_check_defined_processor (void *sem_type,
void *null ATTRIBUTE_UNUSED)
{
return semantic_type_check_defined (sem_type);
}
void
symbol_make_alias (symbol *sym, symbol *str, location loc)
{
if (str->alias)
complain (&loc, Wother,
_("symbol %s used more than once as a literal string"), str->tag);
else if (sym->alias)
complain (&loc, Wother,
_("symbol %s given more than one literal string"), sym->tag);
else
{
sym_content_free (str->content);
str->content = sym->content;
str->content->symbol = str;
str->is_alias = true;
str->alias = sym;
sym->alias = str;
}
}
/*-------------------------------------------------------------------.
| Assign a symbol number, and write the definition of the token name |
| into FDEFINES. Put in SYMBOLS. |
`-------------------------------------------------------------------*/
static inline bool
symbol_pack (symbol *this)
{
aver (this->content->number != NUMBER_UNDEFINED);
if (this->content->class == nterm_sym)
this->content->number += ntokens;
else if (this->content->user_token_number == USER_NUMBER_HAS_STRING_ALIAS)
return true;
symbols[this->content->number] = this->content->symbol;
return true;
}
static bool
symbol_pack_processor (void *this, void *null ATTRIBUTE_UNUSED)
{
return symbol_pack (this);
}
static void
user_token_number_redeclaration (int num, symbol *first, symbol *second)
{
unsigned i = 0;
/* User token numbers are not assigned during the parsing, but in a
second step, via a traversal of the symbol table sorted on tag.
However, error messages make more sense if we keep the first
declaration first. */
if (location_cmp (first->location, second->location) > 0)
{
symbol* tmp = first;
first = second;
second = tmp;
}
complain_indent (&second->location, complaint, &i,
_("user token number %d redeclaration for %s"),
num, second->tag);
i += SUB_INDENT;
complain_indent (&first->location, complaint, &i,
_("previous declaration for %s"),
first->tag);
}
/*--------------------------------------------------.
| Put THIS in TOKEN_TRANSLATIONS if it is a token. |
`--------------------------------------------------*/
static inline bool
symbol_translation (symbol *this)
{
/* Non-terminal? */
if (this->content->class == token_sym
&& !this->is_alias)
{
/* A token which translation has already been set?*/
if (token_translations[this->content->user_token_number]
!= undeftoken->content->number)
user_token_number_redeclaration
(this->content->user_token_number,
symbols[token_translations[this->content->user_token_number]], this);
else
token_translations[this->content->user_token_number]
= this->content->number;
}
return true;
}
static bool
symbol_translation_processor (void *this, void *null ATTRIBUTE_UNUSED)
{
return symbol_translation (this);
}
/*---------------------------------------.
| Symbol and semantic type hash tables. |
`---------------------------------------*/
/* Initial capacity of symbol and semantic type hash table. */
#define HT_INITIAL_CAPACITY 257
static struct hash_table *symbol_table = NULL;
static struct hash_table *semantic_type_table = NULL;
static inline bool
hash_compare_symbol (const symbol *m1, const symbol *m2)
{
/* Since tags are unique, we can compare the pointers themselves. */
return UNIQSTR_EQ (m1->tag, m2->tag);
}
static inline bool
hash_compare_semantic_type (const semantic_type *m1, const semantic_type *m2)
{
/* Since names are unique, we can compare the pointers themselves. */
return UNIQSTR_EQ (m1->tag, m2->tag);
}
static bool
hash_symbol_comparator (void const *m1, void const *m2)
{
return hash_compare_symbol (m1, m2);
}
static bool
hash_semantic_type_comparator (void const *m1, void const *m2)
{
return hash_compare_semantic_type (m1, m2);
}
static inline size_t
hash_symbol (const symbol *m, size_t tablesize)
{
/* Since tags are unique, we can hash the pointer itself. */
return ((uintptr_t) m->tag) % tablesize;
}
static inline size_t
hash_semantic_type (const semantic_type *m, size_t tablesize)
{
/* Since names are unique, we can hash the pointer itself. */
return ((uintptr_t) m->tag) % tablesize;
}
static size_t
hash_symbol_hasher (void const *m, size_t tablesize)
{
return hash_symbol (m, tablesize);
}
static size_t
hash_semantic_type_hasher (void const *m, size_t tablesize)
{
return hash_semantic_type (m, tablesize);
}
/*-------------------------------------.
| Symbol precedence group hash table. |
`-------------------------------------*/
static struct hash_table *group_table = NULL;
static inline bool
hash_compare_group (const symgroup *m1, const symgroup *m2)
{
/* Since tags are unique, we can compare the pointers themselves. */
return UNIQSTR_EQ (m1->tag, m2->tag);
}
static bool
hash_group_comparator (void const *m1, void const *m2)
{
return hash_compare_group (m1, m2);
}
static inline size_t
hash_group (const symgroup *m, size_t tablesize)
{
/* Since tags are unique, we can hash the pointer itself. */
return ((uintptr_t) m->tag) % tablesize;
}
static size_t
hash_group_hasher (void const *m, size_t tablesize)
{
return hash_group (m, tablesize);
}
/*-------------------------------.
| Create the symbol hash table. |
`-------------------------------*/
void
symbols_new (void)
{
symbol_table = hash_initialize (HT_INITIAL_CAPACITY,
NULL,
hash_symbol_hasher,
hash_symbol_comparator,
symbol_free);
semantic_type_table = hash_initialize (HT_INITIAL_CAPACITY,
NULL,
hash_semantic_type_hasher,
hash_semantic_type_comparator,
free);
group_table = hash_initialize (HT_INITIAL_CAPACITY,
NULL,
hash_group_hasher,
hash_group_comparator,
free);
set_current_group (DEFAULT_GROUP_NAME, NULL);
}
/*----------------------------------------------------------------.
| Find the symbol named KEY, and return it. If it does not exist |
| yet, create it. |
`----------------------------------------------------------------*/
symbol *
symbol_from_uniqstr (const uniqstr key, location loc)
{
symbol probe;
symbol *entry;
probe.tag = key;
entry = hash_lookup (symbol_table, &probe);
if (!entry)
{
/* First insertion in the hash. */
aver (!symbols_sorted);
entry = symbol_new (key, loc);
if (!hash_insert (symbol_table, entry))
xalloc_die ();
}
return entry;
}
/*-----------------------------------------------------------------------.
| Find the semantic type named KEY, and return it. If it does not exist |
| yet, create it. |
`-----------------------------------------------------------------------*/
semantic_type *
semantic_type_from_uniqstr (const uniqstr key, const location *loc)
{
semantic_type probe;
semantic_type *entry;
probe.tag = key;
entry = hash_lookup (semantic_type_table, &probe);
if (!entry)
{
/* First insertion in the hash. */
entry = semantic_type_new (key, loc);
if (!hash_insert (semantic_type_table, entry))
xalloc_die ();
}
return entry;
}
/*----------------------------------------------------------------.
| Find the symbol named KEY, and return it. If it does not exist |
| yet, create it. |
`----------------------------------------------------------------*/
symbol *
symbol_get (const char *key, location loc)
{
return symbol_from_uniqstr (uniqstr_new (key), loc);
}
/*-----------------------------------------------------------------------.
| Find the semantic type named KEY, and return it. If it does not exist |
| yet, create it. |
`-----------------------------------------------------------------------*/
semantic_type *
semantic_type_get (const char *key, const location *loc)
{
return semantic_type_from_uniqstr (uniqstr_new (key), loc);
}
/*------------------------------------------------------------------.
| Generate a dummy nonterminal, whose name cannot conflict with the |
| user's names. |
`------------------------------------------------------------------*/
symbol *
dummy_symbol_get (location loc)
{
/* Incremented for each generated symbol. */
static int dummy_count = 0;
static char buf[256];
symbol *sym;
sprintf (buf, "$@%d", ++dummy_count);
sym = symbol_get (buf, loc);
sym->content->class = nterm_sym;
sym->content->number = nvars++;
return sym;
}
bool
symbol_is_dummy (const symbol *sym)
{
return sym->tag[0] == '@' || (sym->tag[0] == '$' && sym->tag[1] == '@');
}
/*-------------------.
| Free the symbols. |
`-------------------*/
void
symbols_free (void)
{
hash_free (symbol_table);
hash_free (semantic_type_table);
hash_free (group_table);
free (symbols);
free (symbols_sorted);
free (semantic_types_sorted);
symbol_list_prec_free (current_prec_declaration);
}
/*---------------------------------------------------------------.
| Look for undefined symbols, report an error, and consider them |
| terminals. |
`---------------------------------------------------------------*/
static int
symbols_cmp (symbol const *a, symbol const *b)
{
return strcmp (a->tag, b->tag);
}
static int
symbols_cmp_qsort (void const *a, void const *b)
{
return symbols_cmp (*(symbol * const *)a, *(symbol * const *)b);
}
static void
symbols_do (Hash_processor processor, void *processor_data,
struct hash_table *table, symbol ***sorted)
{
size_t count = hash_get_n_entries (table);
if (!*sorted)
{
*sorted = xnmalloc (count, sizeof **sorted);
hash_get_entries (table, (void**)*sorted, count);
qsort (*sorted, count, sizeof **sorted, symbols_cmp_qsort);
}
{
size_t i;
for (i = 0; i < count; ++i)
processor ((*sorted)[i], processor_data);
}
}
/*--------------------------------------------------------------.
| Check that all the symbols are defined. Report any undefined |
| symbols and consider them nonterminals. |
`--------------------------------------------------------------*/
void
symbols_check_defined (void)
{
symbols_do (symbol_check_defined_processor, NULL,
symbol_table, &symbols_sorted);
symbols_do (semantic_type_check_defined_processor, NULL,
semantic_type_table, &semantic_types_sorted);
}
/*------------------------------------------------------------------.
| Set TOKEN_TRANSLATIONS. Check that no two symbols share the same |
| number. |
`------------------------------------------------------------------*/
static void
symbols_token_translations_init (void)
{
bool num_256_available_p = true;
int i;
/* Find the highest user token number, and whether 256, the POSIX
preferred user token number for the error token, is used. */
max_user_token_number = 0;
for (i = 0; i < ntokens; ++i)
{
sym_content *this = symbols[i]->content;
if (this->user_token_number != USER_NUMBER_UNDEFINED)
{
if (this->user_token_number > max_user_token_number)
max_user_token_number = this->user_token_number;
if (this->user_token_number == 256)
num_256_available_p = false;
}
}
/* If 256 is not used, assign it to error, to follow POSIX. */
if (num_256_available_p
&& errtoken->content->user_token_number == USER_NUMBER_UNDEFINED)
errtoken->content->user_token_number = 256;
/* Set the missing user numbers. */
if (max_user_token_number < 256)
max_user_token_number = 256;
for (i = 0; i < ntokens; ++i)
{
sym_content *this = symbols[i]->content;
if (this->user_token_number == USER_NUMBER_UNDEFINED)
this->user_token_number = ++max_user_token_number;
if (this->user_token_number > max_user_token_number)
max_user_token_number = this->user_token_number;
}
token_translations = xnmalloc (max_user_token_number + 1,
sizeof *token_translations);
/* Initialize all entries for literal tokens to the internal token
number for $undefined, which represents all invalid inputs. */
for (i = 0; i < max_user_token_number + 1; i++)
token_translations[i] = undeftoken->content->number;
symbols_do (symbol_translation_processor, NULL,
symbol_table, &symbols_sorted);
}
/*----------------------------------------------------------------.
| Assign symbol numbers, and write definition of token names into |
| FDEFINES. Set up vectors SYMBOL_TABLE, TAGS of symbols. |
`----------------------------------------------------------------*/
void
symbols_pack (void)
{
symbols = xcalloc (nsyms, sizeof *symbols);
symbols_do (symbol_pack_processor, NULL, symbol_table, &symbols_sorted);
/* Aliases leave empty slots in symbols, so remove them. */
{
int writei;
int readi;
int nsyms_old = nsyms;
for (writei = 0, readi = 0; readi < nsyms_old; readi += 1)
{
if (symbols[readi] == NULL)
{
nsyms -= 1;
ntokens -= 1;
}
else
{
symbols[writei] = symbols[readi];
symbols[writei]->content->number = writei;
writei += 1;
}
}
}
symbols = xnrealloc (symbols, nsyms, sizeof *symbols);
symbols_token_translations_init ();
if (startsymbol->content->class == unknown_sym)
complain (&startsymbol_location, fatal,
_("the start symbol %s is undefined"),
startsymbol->tag);
else if (startsymbol->content->class == token_sym)
complain (&startsymbol_location, fatal,
_("the start symbol %s is a token"),
startsymbol->tag);
}
/*---------------------------------.
| Initialize relation graph nodes. |
`---------------------------------*/
static void
init_prec_nodes (void)
{
int i;
prec_nodes = xcalloc (nsyms, sizeof *prec_nodes);
for (i = 0; i < nsyms; ++i)
{
prec_nodes[i] = xmalloc (sizeof *prec_nodes[i]);
symgraph *s = prec_nodes[i];
s->id = i;
s->succ = 0;
s->pred = 0;
}
}
/*----------------.
| Create a link. |
`----------------*/
static symgraphlink *
symgraphlink_new (graphid id, symgraphlink *next)
{
symgraphlink *l = xmalloc (sizeof *l);
l->id = id;
l->next = next;
return l;
}
/*------------------------------------------------------------------.
| Register the second symbol of the precedence relation, and return |
| whether this relation is new. Use only in register_precedence. |
`------------------------------------------------------------------*/
static bool
register_precedence_second_symbol (symgraphlink **first, graphid sym)
{
if (!*first || sym < (*first)->id)
*first = symgraphlink_new (sym, *first);
else
{
symgraphlink *slist = *first;
while (slist->next && slist->next->id <= sym)
slist = slist->next;
if (slist->id == sym)
/* Relation already present. */
return false;
slist->next = symgraphlink_new (sym, slist->next);
}
return true;
}
/*------------------------------------------------------------------.
| Register a new relation between symbols as used. The first symbol |
| has a greater precedence than the second one. |
`------------------------------------------------------------------*/
void
register_precedence (graphid first, graphid snd)
{
if (!prec_nodes)
init_prec_nodes ();
register_precedence_second_symbol (&(prec_nodes[first]->succ), snd);
register_precedence_second_symbol (&(prec_nodes[snd]->pred), first);
}
/*---------------------------------------.
| Deep clear a linked / adjacency list). |
`---------------------------------------*/
static void
linkedlist_free (symgraphlink *node)
{
if (node)
{
while (node->next)
{
symgraphlink *tmp = node->next;
free (node);
node = tmp;
}
free (node);
}
}
/*----------------------------------------------.
| Clear and destroy association tracking table. |
`----------------------------------------------*/
static void
assoc_free (void)
{
int i;
for (i = 0; i < nsyms; ++i)
{
linkedlist_free (prec_nodes[i]->pred);
linkedlist_free (prec_nodes[i]->succ);
free (prec_nodes[i]);
}
free (prec_nodes);
}
/*---------------------------------------.
| Initialize association tracking table. |
`---------------------------------------*/
static void
init_assoc (void)
{
graphid i;
used_assoc = xcalloc (nsyms, sizeof *used_assoc);
for (i = 0; i < nsyms; ++i)
used_assoc[i] = false;
}
/*------------------------------------------------------------------.
| Test if the associativity for the symbols is defined and useless. |
`------------------------------------------------------------------*/
static inline bool
is_assoc_useless (symbol *s)
{
return s
&& s->content->prec_node->assoc != undef_assoc
&& s->content->prec_node->assoc != precedence_assoc
&& !used_assoc[s->content->number];
}
/*-------------------------------.
| Register a used associativity. |
`-------------------------------*/
void
register_assoc (graphid i, graphid j)
{
if (!used_assoc)
init_assoc ();
used_assoc[i] = true;
used_assoc[j] = true;
}
/*--------------------------------------------------.
| Print a warning for unused precedence relations. |
`--------------------------------------------------*/
void
print_precedence_warnings (void)
{
int i;
if (!prec_nodes)
init_prec_nodes ();
if (!used_assoc)
init_assoc ();
for (i = 0; i < nsyms; ++i)
{
symbol *s = symbols[i];
if (s
&& !prec_nodes[i]->pred
&& !prec_nodes[i]->succ)
{
if (is_assoc_useless (s))
complain (&s->content->prec_node->prec_location, Wprecedence,
_("useless precedence and associativity for %s"), s->tag);
else if (s->content->prec_node->assoc == precedence_assoc)
complain (&s->content->prec_node->prec_location, Wprecedence,
_("useless precedence for %s"), s->tag);
}
else if (is_assoc_useless (s))
complain (&s->content->prec_node->prec_location, Wprecedence,
_("useless associativity for %s, use %%precedence"), s->tag);
}
free (used_assoc);
assoc_free ();
}
/*------------------------------------------------.
| Counter to create unique anonymous group names. |
`------------------------------------------------*/
static unsigned int anon_group_counter = 0;
/*-------------------------------------------------.
| Return a new unique name for an anonymous group. |
`-------------------------------------------------*/
uniqstr new_anonymous_group_name (void)
{
char buff[20];
snprintf (buff, 20, "__anon%u__", anon_group_counter++);
return uniqstr_new (buff);
}
/*-------------------------------------------.
| Constructor for a symbol precedence group. |
`-------------------------------------------*/
symgroup *
symgroup_new (const uniqstr tag, location loc)
{
symgroup *group = xmalloc (sizeof (*group));
group->tag = tag;
group->symbol_list = NULL;
group->location = loc;
return group;
}
/*----------------------------------------.
| Check if there is a group by that name. |
`----------------------------------------*/
bool
is_prec_group (const uniqstr key)
{
symgroup probe;
symgroup *entry;
probe.tag = key;
entry = hash_lookup (group_table, &probe);
return entry != NULL;
}
/*--------------------------------------------------------------------------.
| Get the symbol precedence group by that name. If not present, a new group |
| is created and inserted in the table, with the location information |
| provided, if any. |
`--------------------------------------------------------------------------*/
symgroup *
symgroup_from_uniqstr (const uniqstr key, location *loc)
{
bool null_loc = loc == NULL;
if (null_loc)
{
loc = malloc (sizeof *loc);
boundary_set (&loc->start, uniqstr_new (""), 1, 1);
boundary_set (&loc->end, uniqstr_new (""), 1, 1);
}
symgroup probe;
symgroup *entry;
probe.tag = key;
entry = hash_lookup (group_table, &probe);
if (!entry)
{
/* First insertion in the hash. */
entry = symgroup_new (key, *loc);
if (!hash_insert (group_table, entry))
xalloc_die ();
}
if (null_loc)
free (loc);
return entry;
}
/*--------------------------------------------------------------------------.
| Change the current group to the one designated by the name, and create it |
| if necessary. The location information is used for creation if available. |
`--------------------------------------------------------------------------*/
void set_current_group (const uniqstr tag, location *loc)
{
for (symbol_list *l = current_prec_declaration; l; l = l->next)
{
sym_content *symb = l->content.sym->content;
if (!current_group->symbol_list)
current_group->symbol_list = symb;
else
{
sym_content *sym = current_group->symbol_list;
for (; sym->group_next; sym = sym->group_next)
{}
sym->group_next = symb;
}
}
symbol_list_prec_free (current_prec_declaration);
current_prec_declaration = NULL;
current_group = symgroup_from_uniqstr (tag, loc);
}