/* YACC parser for D expressions, for GDB.
Copyright (C) 2014 Free Software Foundation, Inc.
This file is part of GDB.
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 . */
/* This file is derived from c-exp.y, jv-exp.y. */
/* Parse a D expression from text in a string,
and return the result as a struct expression pointer.
That structure contains arithmetic operations in reverse polish,
with constants represented by operations that are followed by special data.
See expression.h for the details of the format.
What is important here is that it can be built up sequentially
during the process of parsing; the lower levels of the tree always
come first in the result.
Note that malloc's and realloc's in this file are transformed to
xmalloc and xrealloc respectively by the same sed command in the
makefile that remaps any other malloc/realloc inserted by the parser
generator. Doing this with #defines and trying to control the interaction
with include files ( and for example) just became
too messy, particularly when such includes can be inserted at random
times by the parser generator. */
%{
#include "defs.h"
#include
#include
#include "expression.h"
#include "value.h"
#include "parser-defs.h"
#include "language.h"
#include "c-lang.h"
#include "d-lang.h"
#include "bfd.h" /* Required by objfiles.h. */
#include "symfile.h" /* Required by objfiles.h. */
#include "objfiles.h" /* For have_full_symbols and have_partial_symbols */
#include "charset.h"
#include "block.h"
#define parse_type(ps) builtin_type (parse_gdbarch (ps))
#define parse_d_type(ps) builtin_d_type (parse_gdbarch (ps))
/* Remap normal yacc parser interface names (yyparse, yylex, yyerror, etc),
as well as gratuitiously global symbol names, so we can have multiple
yacc generated parsers in gdb. Note that these are only the variables
produced by yacc. If other parser generators (bison, byacc, etc) produce
additional global names that conflict at link time, then those parser
generators need to be fixed instead of adding those names to this list. */
#define yymaxdepth d_maxdepth
#define yyparse d_parse_internal
#define yylex d_lex
#define yyerror d_error
#define yylval d_lval
#define yychar d_char
#define yydebug d_debug
#define yypact d_pact
#define yyr1 d_r1
#define yyr2 d_r2
#define yydef d_def
#define yychk d_chk
#define yypgo d_pgo
#define yyact d_act
#define yyexca d_exca
#define yyerrflag d_errflag
#define yynerrs d_nerrs
#define yyps d_ps
#define yypv d_pv
#define yys d_s
#define yy_yys d_yys
#define yystate d_state
#define yytmp d_tmp
#define yyv d_v
#define yy_yyv d_yyv
#define yyval d_val
#define yylloc d_lloc
#define yyreds d_reds /* With YYDEBUG defined */
#define yytoks d_toks /* With YYDEBUG defined */
#define yyname d_name /* With YYDEBUG defined */
#define yyrule d_rule /* With YYDEBUG defined */
#define yylhs d_yylhs
#define yylen d_yylen
#define yydefre d_yydefred
#define yydgoto d_yydgoto
#define yysindex d_yysindex
#define yyrindex d_yyrindex
#define yygindex d_yygindex
#define yytable d_yytable
#define yycheck d_yycheck
#define yyss d_yyss
#define yysslim d_yysslim
#define yyssp d_yyssp
#define yystacksize d_yystacksize
#define yyvs d_yyvs
#define yyvsp d_yyvsp
#ifndef YYDEBUG
#define YYDEBUG 1 /* Default to yydebug support */
#endif
#define YYFPRINTF parser_fprintf
/* The state of the parser, used internally when we are parsing the
expression. */
static struct parser_state *pstate = NULL;
int yyparse (void);
static int yylex (void);
void yyerror (char *);
%}
/* Although the yacc "value" of an expression is not used,
since the result is stored in the structure being created,
other node types do have values. */
%union
{
struct {
LONGEST val;
struct type *type;
} typed_val_int;
struct {
DOUBLEST dval;
struct type *type;
} typed_val_float;
struct symbol *sym;
struct type *tval;
struct typed_stoken tsval;
struct stoken sval;
struct ttype tsym;
struct symtoken ssym;
int ival;
struct block *bval;
enum exp_opcode opcode;
struct stoken_vector svec;
}
%{
/* YYSTYPE gets defined by %union */
static int parse_number (struct parser_state *, const char *,
int, int, YYSTYPE *);
static void push_expression_name (struct parser_state *, struct stoken);
%}
%token IDENTIFIER
%token TYPENAME
%token COMPLETE
/* A NAME_OR_INT is a symbol which is not known in the symbol table,
but which would parse as a valid number in the current input radix.
E.g. "c" when input_radix==16. Depending on the parse, it will be
turned into a name or into a number. */
%token NAME_OR_INT
%token INTEGER_LITERAL
%token FLOAT_LITERAL
%token CHARACTER_LITERAL
%token STRING_LITERAL
%type StringExp
%type BasicType TypeExp
%type IdentifierExp
%type ArrayLiteral
%token ENTRY
%token ERROR
/* Keywords that have a constant value. */
%token TRUE_KEYWORD FALSE_KEYWORD NULL_KEYWORD
/* Class 'super' accessor. */
%token SUPER_KEYWORD
/* Properties. */
%token CAST_KEYWORD SIZEOF_KEYWORD
%token TYPEOF_KEYWORD TYPEID_KEYWORD
%token INIT_KEYWORD
/* Comparison keywords. */
/* Type storage classes. */
%token IMMUTABLE_KEYWORD CONST_KEYWORD SHARED_KEYWORD
/* Non-scalar type keywords. */
%token STRUCT_KEYWORD UNION_KEYWORD
%token CLASS_KEYWORD INTERFACE_KEYWORD
%token ENUM_KEYWORD TEMPLATE_KEYWORD
%token DELEGATE_KEYWORD FUNCTION_KEYWORD
%token DOLLAR_VARIABLE
%token ASSIGN_MODIFY
%left ','
%right '=' ASSIGN_MODIFY
%right '?'
%left OROR
%left ANDAND
%left '|'
%left '^'
%left '&'
%left EQUAL NOTEQUAL '<' '>' LEQ GEQ
%right LSH RSH
%left '+' '-'
%left '*' '/' '%'
%right HATHAT
%left IDENTITY NOTIDENTITY
%right INCREMENT DECREMENT
%right '.' '[' '('
%token DOTDOT
%%
start :
Expression
| TypeExp
;
/* Expressions, including the comma operator. */
Expression:
CommaExpression
;
CommaExpression:
AssignExpression
| AssignExpression ',' CommaExpression
{ write_exp_elt_opcode (pstate, BINOP_COMMA); }
;
AssignExpression:
ConditionalExpression
| ConditionalExpression '=' AssignExpression
{ write_exp_elt_opcode (pstate, BINOP_ASSIGN); }
| ConditionalExpression ASSIGN_MODIFY AssignExpression
{ write_exp_elt_opcode (pstate, BINOP_ASSIGN_MODIFY);
write_exp_elt_opcode (pstate, $2);
write_exp_elt_opcode (pstate, BINOP_ASSIGN_MODIFY); }
;
ConditionalExpression:
OrOrExpression
| OrOrExpression '?' Expression ':' ConditionalExpression
{ write_exp_elt_opcode (pstate, TERNOP_COND); }
;
OrOrExpression:
AndAndExpression
| OrOrExpression OROR AndAndExpression
{ write_exp_elt_opcode (pstate, BINOP_LOGICAL_OR); }
;
AndAndExpression:
OrExpression
| AndAndExpression ANDAND OrExpression
{ write_exp_elt_opcode (pstate, BINOP_LOGICAL_AND); }
;
OrExpression:
XorExpression
| OrExpression '|' XorExpression
{ write_exp_elt_opcode (pstate, BINOP_BITWISE_IOR); }
;
XorExpression:
AndExpression
| XorExpression '^' AndExpression
{ write_exp_elt_opcode (pstate, BINOP_BITWISE_XOR); }
;
AndExpression:
CmpExpression
| AndExpression '&' CmpExpression
{ write_exp_elt_opcode (pstate, BINOP_BITWISE_AND); }
;
CmpExpression:
ShiftExpression
| EqualExpression
| IdentityExpression
| RelExpression
;
EqualExpression:
ShiftExpression EQUAL ShiftExpression
{ write_exp_elt_opcode (pstate, BINOP_EQUAL); }
| ShiftExpression NOTEQUAL ShiftExpression
{ write_exp_elt_opcode (pstate, BINOP_NOTEQUAL); }
;
IdentityExpression:
ShiftExpression IDENTITY ShiftExpression
{ write_exp_elt_opcode (pstate, BINOP_EQUAL); }
| ShiftExpression NOTIDENTITY ShiftExpression
{ write_exp_elt_opcode (pstate, BINOP_NOTEQUAL); }
;
RelExpression:
ShiftExpression '<' ShiftExpression
{ write_exp_elt_opcode (pstate, BINOP_LESS); }
| ShiftExpression LEQ ShiftExpression
{ write_exp_elt_opcode (pstate, BINOP_LEQ); }
| ShiftExpression '>' ShiftExpression
{ write_exp_elt_opcode (pstate, BINOP_GTR); }
| ShiftExpression GEQ ShiftExpression
{ write_exp_elt_opcode (pstate, BINOP_GEQ); }
;
ShiftExpression:
AddExpression
| ShiftExpression LSH AddExpression
{ write_exp_elt_opcode (pstate, BINOP_LSH); }
| ShiftExpression RSH AddExpression
{ write_exp_elt_opcode (pstate, BINOP_RSH); }
;
AddExpression:
MulExpression
| AddExpression '+' MulExpression
{ write_exp_elt_opcode (pstate, BINOP_ADD); }
| AddExpression '-' MulExpression
{ write_exp_elt_opcode (pstate, BINOP_SUB); }
| AddExpression '~' MulExpression
{ write_exp_elt_opcode (pstate, BINOP_CONCAT); }
;
MulExpression:
UnaryExpression
| MulExpression '*' UnaryExpression
{ write_exp_elt_opcode (pstate, BINOP_MUL); }
| MulExpression '/' UnaryExpression
{ write_exp_elt_opcode (pstate, BINOP_DIV); }
| MulExpression '%' UnaryExpression
{ write_exp_elt_opcode (pstate, BINOP_REM); }
UnaryExpression:
'&' UnaryExpression
{ write_exp_elt_opcode (pstate, UNOP_ADDR); }
| INCREMENT UnaryExpression
{ write_exp_elt_opcode (pstate, UNOP_PREINCREMENT); }
| DECREMENT UnaryExpression
{ write_exp_elt_opcode (pstate, UNOP_PREDECREMENT); }
| '*' UnaryExpression
{ write_exp_elt_opcode (pstate, UNOP_IND); }
| '-' UnaryExpression
{ write_exp_elt_opcode (pstate, UNOP_NEG); }
| '+' UnaryExpression
{ write_exp_elt_opcode (pstate, UNOP_PLUS); }
| '!' UnaryExpression
{ write_exp_elt_opcode (pstate, UNOP_LOGICAL_NOT); }
| '~' UnaryExpression
{ write_exp_elt_opcode (pstate, UNOP_COMPLEMENT); }
| CastExpression
| PowExpression
;
CastExpression:
CAST_KEYWORD '(' TypeExp ')' UnaryExpression
{ write_exp_elt_opcode (pstate, UNOP_CAST);
write_exp_elt_type (pstate, $3);
write_exp_elt_opcode (pstate, UNOP_CAST); }
/* C style cast is illegal D, but is still recognised in
the grammar, so we keep this around for convenience. */
| '(' TypeExp ')' UnaryExpression
{ write_exp_elt_opcode (pstate, UNOP_CAST);
write_exp_elt_type (pstate, $2);
write_exp_elt_opcode (pstate, UNOP_CAST); }
;
PowExpression:
PostfixExpression
| PostfixExpression HATHAT UnaryExpression
{ write_exp_elt_opcode (pstate, BINOP_EXP); }
;
PostfixExpression:
PrimaryExpression
| PostfixExpression INCREMENT
{ write_exp_elt_opcode (pstate, UNOP_POSTINCREMENT); }
| PostfixExpression DECREMENT
{ write_exp_elt_opcode (pstate, UNOP_POSTDECREMENT); }
| CallExpression
| IndexExpression
| SliceExpression
;
ArgumentList:
AssignExpression
{ arglist_len = 1; }
| ArgumentList ',' AssignExpression
{ arglist_len++; }
;
ArgumentList_opt:
/* EMPTY */
{ arglist_len = 0; }
| ArgumentList
;
CallExpression:
PostfixExpression '('
{ start_arglist (); }
ArgumentList_opt ')'
{ write_exp_elt_opcode (pstate, OP_FUNCALL);
write_exp_elt_longcst (pstate, (LONGEST) end_arglist ());
write_exp_elt_opcode (pstate, OP_FUNCALL); }
;
IndexExpression:
PostfixExpression '[' ArgumentList ']'
{ if (arglist_len > 0)
{
write_exp_elt_opcode (pstate, MULTI_SUBSCRIPT);
write_exp_elt_longcst (pstate, (LONGEST) arglist_len);
write_exp_elt_opcode (pstate, MULTI_SUBSCRIPT);
}
else
write_exp_elt_opcode (pstate, BINOP_SUBSCRIPT);
}
;
SliceExpression:
PostfixExpression '[' ']'
{ /* Do nothing. */ }
| PostfixExpression '[' AssignExpression DOTDOT AssignExpression ']'
{ write_exp_elt_opcode (pstate, TERNOP_SLICE); }
;
PrimaryExpression:
'(' Expression ')'
{ /* Do nothing. */ }
| IdentifierExp
{ push_expression_name (pstate, $1); }
| IdentifierExp '.' COMPLETE
{ struct stoken s;
s.ptr = "";
s.length = 0;
push_expression_name (pstate, $1);
mark_struct_expression (pstate);
write_exp_elt_opcode (pstate, STRUCTOP_STRUCT);
write_exp_string (pstate, s);
write_exp_elt_opcode (pstate, STRUCTOP_STRUCT); }
| IdentifierExp '.' IDENTIFIER COMPLETE
{ push_expression_name (pstate, $1);
mark_struct_expression (pstate);
write_exp_elt_opcode (pstate, STRUCTOP_STRUCT);
write_exp_string (pstate, $3);
write_exp_elt_opcode (pstate, STRUCTOP_STRUCT); }
| DOLLAR_VARIABLE
{ write_dollar_variable (pstate, $1); }
| NAME_OR_INT
{ YYSTYPE val;
parse_number (pstate, $1.ptr, $1.length, 0, &val);
write_exp_elt_opcode (pstate, OP_LONG);
write_exp_elt_type (pstate, val.typed_val_int.type);
write_exp_elt_longcst (pstate,
(LONGEST) val.typed_val_int.val);
write_exp_elt_opcode (pstate, OP_LONG); }
| NULL_KEYWORD
{ struct type *type = parse_d_type (pstate)->builtin_void;
type = lookup_pointer_type (type);
write_exp_elt_opcode (pstate, OP_LONG);
write_exp_elt_type (pstate, type);
write_exp_elt_longcst (pstate, (LONGEST) 0);
write_exp_elt_opcode (pstate, OP_LONG); }
| TRUE_KEYWORD
{ write_exp_elt_opcode (pstate, OP_BOOL);
write_exp_elt_longcst (pstate, (LONGEST) 1);
write_exp_elt_opcode (pstate, OP_BOOL); }
| FALSE_KEYWORD
{ write_exp_elt_opcode (pstate, OP_BOOL);
write_exp_elt_longcst (pstate, (LONGEST) 0);
write_exp_elt_opcode (pstate, OP_BOOL); }
| INTEGER_LITERAL
{ write_exp_elt_opcode (pstate, OP_LONG);
write_exp_elt_type (pstate, $1.type);
write_exp_elt_longcst (pstate, (LONGEST)($1.val));
write_exp_elt_opcode (pstate, OP_LONG); }
| FLOAT_LITERAL
{ write_exp_elt_opcode (pstate, OP_DOUBLE);
write_exp_elt_type (pstate, $1.type);
write_exp_elt_dblcst (pstate, $1.dval);
write_exp_elt_opcode (pstate, OP_DOUBLE); }
| CHARACTER_LITERAL
{ struct stoken_vector vec;
vec.len = 1;
vec.tokens = &$1;
write_exp_string_vector (pstate, $1.type, &vec); }
| StringExp
{ int i;
write_exp_string_vector (pstate, 0, &$1);
for (i = 0; i < $1.len; ++i)
free ($1.tokens[i].ptr);
free ($1.tokens); }
| ArrayLiteral
{ write_exp_elt_opcode (pstate, OP_ARRAY);
write_exp_elt_longcst (pstate, (LONGEST) 0);
write_exp_elt_longcst (pstate, (LONGEST) $1 - 1);
write_exp_elt_opcode (pstate, OP_ARRAY); }
;
ArrayLiteral:
'[' ArgumentList_opt ']'
{ $$ = arglist_len; }
;
IdentifierExp:
IDENTIFIER
| IdentifierExp '.' IDENTIFIER
{ $$.length = $1.length + $3.length + 1;
if ($1.ptr + $1.length + 1 == $3.ptr
&& $1.ptr[$1.length] == '.')
$$.ptr = $1.ptr; /* Optimization. */
else
{
char *buf = malloc ($$.length + 1);
make_cleanup (free, buf);
sprintf (buf, "%.*s.%.*s",
$1.length, $1.ptr, $3.length, $3.ptr);
$$.ptr = buf;
}
}
;
StringExp:
STRING_LITERAL
{ /* We copy the string here, and not in the
lexer, to guarantee that we do not leak a
string. Note that we follow the
NUL-termination convention of the
lexer. */
struct typed_stoken *vec = XNEW (struct typed_stoken);
$$.len = 1;
$$.tokens = vec;
vec->type = $1.type;
vec->length = $1.length;
vec->ptr = malloc ($1.length + 1);
memcpy (vec->ptr, $1.ptr, $1.length + 1);
}
| StringExp STRING_LITERAL
{ /* Note that we NUL-terminate here, but just
for convenience. */
char *p;
++$$.len;
$$.tokens = realloc ($$.tokens,
$$.len * sizeof (struct typed_stoken));
p = malloc ($2.length + 1);
memcpy (p, $2.ptr, $2.length + 1);
$$.tokens[$$.len - 1].type = $2.type;
$$.tokens[$$.len - 1].length = $2.length;
$$.tokens[$$.len - 1].ptr = p;
}
;
TypeExp:
BasicType
{ write_exp_elt_opcode (pstate, OP_TYPE);
write_exp_elt_type (pstate, $1);
write_exp_elt_opcode (pstate, OP_TYPE); }
| BasicType BasicType2
{ $$ = follow_types ($1);
write_exp_elt_opcode (pstate, OP_TYPE);
write_exp_elt_type (pstate, $$);
write_exp_elt_opcode (pstate, OP_TYPE);
}
;
BasicType2:
'*'
{ push_type (tp_pointer); }
| '*' BasicType2
{ push_type (tp_pointer); }
| '[' INTEGER_LITERAL ']'
{ push_type_int ($2.val);
push_type (tp_array); }
| '[' INTEGER_LITERAL ']' BasicType2
{ push_type_int ($2.val);
push_type (tp_array); }
;
BasicType:
TYPENAME
{ $$ = $1.type; }
| CLASS_KEYWORD IdentifierExp
{ $$ = lookup_struct (copy_name ($2),
expression_context_block); }
| CLASS_KEYWORD COMPLETE
{ mark_completion_tag (TYPE_CODE_CLASS, "", 0);
$$ = NULL; }
| CLASS_KEYWORD IdentifierExp COMPLETE
{ mark_completion_tag (TYPE_CODE_CLASS, $2.ptr, $2.length);
$$ = NULL; }
| STRUCT_KEYWORD IdentifierExp
{ $$ = lookup_struct (copy_name ($2),
expression_context_block); }
| STRUCT_KEYWORD COMPLETE
{ mark_completion_tag (TYPE_CODE_STRUCT, "", 0);
$$ = NULL; }
| STRUCT_KEYWORD IdentifierExp COMPLETE
{ mark_completion_tag (TYPE_CODE_STRUCT, $2.ptr, $2.length);
$$ = NULL; }
| UNION_KEYWORD IdentifierExp
{ $$ = lookup_union (copy_name ($2),
expression_context_block); }
| UNION_KEYWORD COMPLETE
{ mark_completion_tag (TYPE_CODE_UNION, "", 0);
$$ = NULL; }
| UNION_KEYWORD IdentifierExp COMPLETE
{ mark_completion_tag (TYPE_CODE_UNION, $2.ptr, $2.length);
$$ = NULL; }
| ENUM_KEYWORD IdentifierExp
{ $$ = lookup_enum (copy_name ($2),
expression_context_block); }
| ENUM_KEYWORD COMPLETE
{ mark_completion_tag (TYPE_CODE_ENUM, "", 0);
$$ = NULL; }
| ENUM_KEYWORD IdentifierExp COMPLETE
{ mark_completion_tag (TYPE_CODE_ENUM, $2.ptr, $2.length);
$$ = NULL; }
;
%%
/* Take care of parsing a number (anything that starts with a digit).
Set yylval and return the token type; update lexptr.
LEN is the number of characters in it. */
/*** Needs some error checking for the float case ***/
static int
parse_number (struct parser_state *ps, const char *p,
int len, int parsed_float, YYSTYPE *putithere)
{
ULONGEST n = 0;
ULONGEST prevn = 0;
ULONGEST un;
int i = 0;
int c;
int base = input_radix;
int unsigned_p = 0;
int long_p = 0;
/* We have found a "L" or "U" suffix. */
int found_suffix = 0;
ULONGEST high_bit;
struct type *signed_type;
struct type *unsigned_type;
if (parsed_float)
{
const struct builtin_d_type *builtin_d_types;
const char *suffix;
int suffix_len;
char *s, *sp;
/* Strip out all embedded '_' before passing to parse_float. */
s = (char *) alloca (len + 1);
sp = s;
while (len-- > 0)
{
if (*p != '_')
*sp++ = *p;
p++;
}
*sp = '\0';
len = strlen (s);
if (! parse_float (s, len, &putithere->typed_val_float.dval, &suffix))
return ERROR;
suffix_len = s + len - suffix;
if (suffix_len == 0)
{
putithere->typed_val_float.type
= parse_d_type (ps)->builtin_double;
}
else if (suffix_len == 1)
{
/* Check suffix for `f', `l', or `i' (float, real, or idouble). */
if (tolower (*suffix) == 'f')
{
putithere->typed_val_float.type
= parse_d_type (ps)->builtin_float;
}
else if (tolower (*suffix) == 'l')
{
putithere->typed_val_float.type
= parse_d_type (ps)->builtin_real;
}
else if (tolower (*suffix) == 'i')
{
putithere->typed_val_float.type
= parse_d_type (ps)->builtin_idouble;
}
else
return ERROR;
}
else if (suffix_len == 2)
{
/* Check suffix for `fi' or `li' (ifloat or ireal). */
if (tolower (suffix[0]) == 'f' && tolower (suffix[1] == 'i'))
{
putithere->typed_val_float.type
= parse_d_type (ps)->builtin_ifloat;
}
else if (tolower (suffix[0]) == 'l' && tolower (suffix[1] == 'i'))
{
putithere->typed_val_float.type
= parse_d_type (ps)->builtin_ireal;
}
else
return ERROR;
}
else
return ERROR;
return FLOAT_LITERAL;
}
/* Handle base-switching prefixes 0x, 0b, 0 */
if (p[0] == '0')
switch (p[1])
{
case 'x':
case 'X':
if (len >= 3)
{
p += 2;
base = 16;
len -= 2;
}
break;
case 'b':
case 'B':
if (len >= 3)
{
p += 2;
base = 2;
len -= 2;
}
break;
default:
base = 8;
break;
}
while (len-- > 0)
{
c = *p++;
if (c == '_')
continue; /* Ignore embedded '_'. */
if (c >= 'A' && c <= 'Z')
c += 'a' - 'A';
if (c != 'l' && c != 'u')
n *= base;
if (c >= '0' && c <= '9')
{
if (found_suffix)
return ERROR;
n += i = c - '0';
}
else
{
if (base > 10 && c >= 'a' && c <= 'f')
{
if (found_suffix)
return ERROR;
n += i = c - 'a' + 10;
}
else if (c == 'l' && long_p == 0)
{
long_p = 1;
found_suffix = 1;
}
else if (c == 'u' && unsigned_p == 0)
{
unsigned_p = 1;
found_suffix = 1;
}
else
return ERROR; /* Char not a digit */
}
if (i >= base)
return ERROR; /* Invalid digit in this base. */
/* Portably test for integer overflow. */
if (c != 'l' && c != 'u')
{
ULONGEST n2 = prevn * base;
if ((n2 / base != prevn) || (n2 + i < prevn))
error (_("Numeric constant too large."));
}
prevn = n;
}
/* An integer constant is an int or a long. An L suffix forces it to
be long, and a U suffix forces it to be unsigned. To figure out
whether it fits, we shift it right and see whether anything remains.
Note that we can't shift sizeof (LONGEST) * HOST_CHAR_BIT bits or
more in one operation, because many compilers will warn about such a
shift (which always produces a zero result). To deal with the case
where it is we just always shift the value more than once, with fewer
bits each time. */
un = (ULONGEST) n >> 2;
if (long_p == 0 && (un >> 30) == 0)
{
high_bit = ((ULONGEST) 1) << 31;
signed_type = parse_d_type (ps)->builtin_int;
/* For decimal notation, keep the sign of the worked out type. */
if (base == 10 && !unsigned_p)
unsigned_type = parse_d_type (ps)->builtin_long;
else
unsigned_type = parse_d_type (ps)->builtin_uint;
}
else
{
int shift;
if (sizeof (ULONGEST) * HOST_CHAR_BIT < 64)
/* A long long does not fit in a LONGEST. */
shift = (sizeof (ULONGEST) * HOST_CHAR_BIT - 1);
else
shift = 63;
high_bit = (ULONGEST) 1 << shift;
signed_type = parse_d_type (ps)->builtin_long;
unsigned_type = parse_d_type (ps)->builtin_ulong;
}
putithere->typed_val_int.val = n;
/* If the high bit of the worked out type is set then this number
has to be unsigned_type. */
if (unsigned_p || (n & high_bit))
putithere->typed_val_int.type = unsigned_type;
else
putithere->typed_val_int.type = signed_type;
return INTEGER_LITERAL;
}
/* Temporary obstack used for holding strings. */
static struct obstack tempbuf;
static int tempbuf_init;
/* Parse a string or character literal from TOKPTR. The string or
character may be wide or unicode. *OUTPTR is set to just after the
end of the literal in the input string. The resulting token is
stored in VALUE. This returns a token value, either STRING or
CHAR, depending on what was parsed. *HOST_CHARS is set to the
number of host characters in the literal. */
static int
parse_string_or_char (const char *tokptr, const char **outptr,
struct typed_stoken *value, int *host_chars)
{
int quote;
/* Build the gdb internal form of the input string in tempbuf. Note
that the buffer is null byte terminated *only* for the
convenience of debugging gdb itself and printing the buffer
contents when the buffer contains no embedded nulls. Gdb does
not depend upon the buffer being null byte terminated, it uses
the length string instead. This allows gdb to handle C strings
(as well as strings in other languages) with embedded null
bytes */
if (!tempbuf_init)
tempbuf_init = 1;
else
obstack_free (&tempbuf, NULL);
obstack_init (&tempbuf);
/* Skip the quote. */
quote = *tokptr;
++tokptr;
*host_chars = 0;
while (*tokptr)
{
char c = *tokptr;
if (c == '\\')
{
++tokptr;
*host_chars += c_parse_escape (&tokptr, &tempbuf);
}
else if (c == quote)
break;
else
{
obstack_1grow (&tempbuf, c);
++tokptr;
/* FIXME: this does the wrong thing with multi-byte host
characters. We could use mbrlen here, but that would
make "set host-charset" a bit less useful. */
++*host_chars;
}
}
if (*tokptr != quote)
{
if (quote == '"' || quote == '`')
error (_("Unterminated string in expression."));
else
error (_("Unmatched single quote."));
}
++tokptr;
/* FIXME: should instead use own language string_type enum
and handle D-specific string suffixes here. */
if (quote == '\'')
value->type = C_CHAR;
else
value->type = C_STRING;
value->ptr = obstack_base (&tempbuf);
value->length = obstack_object_size (&tempbuf);
*outptr = tokptr;
return quote == '\'' ? CHARACTER_LITERAL : STRING_LITERAL;
}
struct token
{
char *operator;
int token;
enum exp_opcode opcode;
};
static const struct token tokentab3[] =
{
{"^^=", ASSIGN_MODIFY, BINOP_EXP},
{"<<=", ASSIGN_MODIFY, BINOP_LSH},
{">>=", ASSIGN_MODIFY, BINOP_RSH},
};
static const struct token tokentab2[] =
{
{"+=", ASSIGN_MODIFY, BINOP_ADD},
{"-=", ASSIGN_MODIFY, BINOP_SUB},
{"*=", ASSIGN_MODIFY, BINOP_MUL},
{"/=", ASSIGN_MODIFY, BINOP_DIV},
{"%=", ASSIGN_MODIFY, BINOP_REM},
{"|=", ASSIGN_MODIFY, BINOP_BITWISE_IOR},
{"&=", ASSIGN_MODIFY, BINOP_BITWISE_AND},
{"^=", ASSIGN_MODIFY, BINOP_BITWISE_XOR},
{"++", INCREMENT, BINOP_END},
{"--", DECREMENT, BINOP_END},
{"&&", ANDAND, BINOP_END},
{"||", OROR, BINOP_END},
{"^^", HATHAT, BINOP_END},
{"<<", LSH, BINOP_END},
{">>", RSH, BINOP_END},
{"==", EQUAL, BINOP_END},
{"!=", NOTEQUAL, BINOP_END},
{"<=", LEQ, BINOP_END},
{">=", GEQ, BINOP_END},
{"..", DOTDOT, BINOP_END},
};
/* Identifier-like tokens. */
static const struct token ident_tokens[] =
{
{"is", IDENTITY, BINOP_END},
{"!is", NOTIDENTITY, BINOP_END},
{"cast", CAST_KEYWORD, OP_NULL},
{"const", CONST_KEYWORD, OP_NULL},
{"immutable", IMMUTABLE_KEYWORD, OP_NULL},
{"shared", SHARED_KEYWORD, OP_NULL},
{"super", SUPER_KEYWORD, OP_NULL},
{"null", NULL_KEYWORD, OP_NULL},
{"true", TRUE_KEYWORD, OP_NULL},
{"false", FALSE_KEYWORD, OP_NULL},
{"init", INIT_KEYWORD, OP_NULL},
{"sizeof", SIZEOF_KEYWORD, OP_NULL},
{"typeof", TYPEOF_KEYWORD, OP_NULL},
{"typeid", TYPEID_KEYWORD, OP_NULL},
{"delegate", DELEGATE_KEYWORD, OP_NULL},
{"function", FUNCTION_KEYWORD, OP_NULL},
{"struct", STRUCT_KEYWORD, OP_NULL},
{"union", UNION_KEYWORD, OP_NULL},
{"class", CLASS_KEYWORD, OP_NULL},
{"interface", INTERFACE_KEYWORD, OP_NULL},
{"enum", ENUM_KEYWORD, OP_NULL},
{"template", TEMPLATE_KEYWORD, OP_NULL},
};
/* If NAME is a type name in this scope, return it. */
static struct type *
d_type_from_name (struct stoken name)
{
struct symbol *sym;
char *copy = copy_name (name);
sym = lookup_symbol (copy, expression_context_block,
STRUCT_DOMAIN, NULL);
if (sym != NULL)
return SYMBOL_TYPE (sym);
return NULL;
}
/* If NAME is a module name in this scope, return it. */
static struct type *
d_module_from_name (struct stoken name)
{
struct symbol *sym;
char *copy = copy_name (name);
sym = lookup_symbol (copy, expression_context_block,
MODULE_DOMAIN, NULL);
if (sym != NULL)
return SYMBOL_TYPE (sym);
return NULL;
}
/* If NAME is a valid variable name in this scope, push it and return 1.
Otherwise, return 0. */
static int
push_variable (struct parser_state *ps, struct stoken name)
{
char *copy = copy_name (name);
struct field_of_this_result is_a_field_of_this;
struct symbol *sym;
sym = lookup_symbol (copy, expression_context_block, VAR_DOMAIN,
&is_a_field_of_this);
if (sym && SYMBOL_CLASS (sym) != LOC_TYPEDEF)
{
if (symbol_read_needs_frame (sym))
{
if (innermost_block == 0 ||
contained_in (block_found, innermost_block))
innermost_block = block_found;
}
write_exp_elt_opcode (ps, OP_VAR_VALUE);
/* We want to use the selected frame, not another more inner frame
which happens to be in the same block. */
write_exp_elt_block (ps, NULL);
write_exp_elt_sym (ps, sym);
write_exp_elt_opcode (ps, OP_VAR_VALUE);
return 1;
}
if (is_a_field_of_this.type != NULL)
{
/* It hangs off of `this'. Must not inadvertently convert from a
method call to data ref. */
if (innermost_block == 0 ||
contained_in (block_found, innermost_block))
innermost_block = block_found;
write_exp_elt_opcode (ps, OP_THIS);
write_exp_elt_opcode (ps, OP_THIS);
write_exp_elt_opcode (ps, STRUCTOP_PTR);
write_exp_string (ps, name);
write_exp_elt_opcode (ps, STRUCTOP_PTR);
return 1;
}
return 0;
}
/* Assuming a reference expression has been pushed, emit the
STRUCTOP_PTR ops to access the field named NAME. If NAME is a
qualified name (has '.'), generate a field access for each part. */
static void
push_fieldnames (struct parser_state *ps, struct stoken name)
{
int i;
struct stoken token;
token.ptr = name.ptr;
for (i = 0; ; i++)
{
if (i == name.length || name.ptr[i] == '.')
{
/* token.ptr is start of current field name. */
token.length = &name.ptr[i] - token.ptr;
write_exp_elt_opcode (ps, STRUCTOP_PTR);
write_exp_string (ps, token);
write_exp_elt_opcode (ps, STRUCTOP_PTR);
token.ptr += token.length + 1;
}
if (i >= name.length)
break;
}
}
/* Helper routine for push_expression_name. Handle a TYPE symbol,
where DOT_INDEX is the index of the first '.' if NAME is part of
a qualified type. */
static void
push_type_name (struct parser_state *ps, struct type *type,
struct stoken name, int dot_index)
{
if (dot_index == name.length)
{
write_exp_elt_opcode (ps, OP_TYPE);
write_exp_elt_type (ps, type);
write_exp_elt_opcode (ps, OP_TYPE);
}
else
{
struct stoken token;
token.ptr = name.ptr;
token.length = dot_index;
dot_index = 0;
while (dot_index < name.length && name.ptr[dot_index] != '.')
dot_index++;
token.ptr = name.ptr;
token.length = dot_index;
write_exp_elt_opcode (ps, OP_SCOPE);
write_exp_elt_type (ps, type);
write_exp_string (ps, token);
write_exp_elt_opcode (ps, OP_SCOPE);
if (dot_index < name.length)
{
dot_index++;
name.ptr += dot_index;
name.length -= dot_index;
push_fieldnames (ps, name);
}
}
}
/* Helper routine for push_expression_name. Like push_type_name,
but used when TYPE is a module. Returns 1 on pushing the symbol. */
static int
push_module_name (struct parser_state *ps, struct type *module,
struct stoken name, int dot_index)
{
if (dot_index == name.length)
{
write_exp_elt_opcode (ps, OP_TYPE);
write_exp_elt_type (ps, module);
write_exp_elt_opcode (ps, OP_TYPE);
return 1;
}
else
{
struct symbol *sym;
char *copy;
copy = copy_name (name);
sym = lookup_symbol_static (copy, expression_context_block,
VAR_DOMAIN);
if (sym != NULL)
sym = lookup_symbol_global (copy, expression_context_block,
VAR_DOMAIN);
if (sym != NULL)
{
if (SYMBOL_CLASS (sym) != LOC_TYPEDEF)
{
write_exp_elt_opcode (ps, OP_VAR_VALUE);
write_exp_elt_block (ps, NULL);
write_exp_elt_sym (ps, sym);
write_exp_elt_opcode (ps, OP_VAR_VALUE);
}
else
{
write_exp_elt_opcode (ps, OP_TYPE);
write_exp_elt_type (ps, SYMBOL_TYPE (sym));
write_exp_elt_opcode (ps, OP_TYPE);
}
return 1;
}
}
return 0;
}
/* Handle NAME in an expression (or LHS), which could be a
variable, type, or module. */
static void
push_expression_name (struct parser_state *ps, struct stoken name)
{
struct stoken token;
struct type *typ;
struct bound_minimal_symbol msymbol;
char *copy;
int doti;
/* Handle VAR, which could be local or global. */
if (push_variable (ps, name) != 0)
return;
/* Handle MODULE. */
typ = d_module_from_name (name);
if (typ != NULL)
{
if (push_module_name (ps, typ, name, name.length) != 0)
return;
}
/* Handle TYPE. */
typ = d_type_from_name (name);
if (typ != NULL)
{
push_type_name (ps, typ, name, name.length);
return;
}
/* Handle VAR.FIELD1..FIELDN. */
for (doti = 0; doti < name.length; doti++)
{
if (name.ptr[doti] == '.')
{
token.ptr = name.ptr;
token.length = doti;
if (push_variable (ps, token) != 0)
{
token.ptr = name.ptr + doti + 1;
token.length = name.length - doti - 1;
push_fieldnames (ps, token);
return;
}
break;
}
}
/* Continue looking if we found a '.' in the name. */
if (doti < name.length)
{
token.ptr = name.ptr;
for (;;)
{
token.length = doti;
/* Handle PACKAGE.MODULE. */
typ = d_module_from_name (token);
if (typ != NULL)
{
if (push_module_name (ps, typ, name, doti) != 0)
return;
}
/* Handle TYPE.FIELD1..FIELDN. */
typ = d_type_from_name (token);
if (typ != NULL)
{
push_type_name (ps, typ, name, doti);
return;
}
if (doti >= name.length)
break;
doti++; /* Skip '.' */
while (doti < name.length && name.ptr[doti] != '.')
doti++;
}
}
/* Lookup foreign name in global static symbols. */
copy = copy_name (name);
msymbol = lookup_bound_minimal_symbol (copy);
if (msymbol.minsym != NULL)
write_exp_msymbol (ps, msymbol);
else if (!have_full_symbols () && !have_partial_symbols ())
error (_("No symbol table is loaded. Use the \"file\" command"));
else
error (_("No symbol \"%s\" in current context."), copy);
}
/* This is set if a NAME token appeared at the very end of the input
string, with no whitespace separating the name from the EOF. This
is used only when parsing to do field name completion. */
static int saw_name_at_eof;
/* This is set if the previously-returned token was a structure operator.
This is used only when parsing to do field name completion. */
static int last_was_structop;
/* Read one token, getting characters through lexptr. */
static int
yylex (void)
{
int c;
int namelen;
unsigned int i;
const char *tokstart;
int saw_structop = last_was_structop;
char *copy;
last_was_structop = 0;
retry:
prev_lexptr = lexptr;
tokstart = lexptr;
/* See if it is a special token of length 3. */
for (i = 0; i < sizeof tokentab3 / sizeof tokentab3[0]; i++)
if (strncmp (tokstart, tokentab3[i].operator, 3) == 0)
{
lexptr += 3;
yylval.opcode = tokentab3[i].opcode;
return tokentab3[i].token;
}
/* See if it is a special token of length 2. */
for (i = 0; i < sizeof tokentab2 / sizeof tokentab2[0]; i++)
if (strncmp (tokstart, tokentab2[i].operator, 2) == 0)
{
lexptr += 2;
yylval.opcode = tokentab2[i].opcode;
return tokentab2[i].token;
}
switch (c = *tokstart)
{
case 0:
/* If we're parsing for field name completion, and the previous
token allows such completion, return a COMPLETE token.
Otherwise, we were already scanning the original text, and
we're really done. */
if (saw_name_at_eof)
{
saw_name_at_eof = 0;
return COMPLETE;
}
else if (saw_structop)
return COMPLETE;
else
return 0;
case ' ':
case '\t':
case '\n':
lexptr++;
goto retry;
case '[':
case '(':
paren_depth++;
lexptr++;
return c;
case ']':
case ')':
if (paren_depth == 0)
return 0;
paren_depth--;
lexptr++;
return c;
case ',':
if (comma_terminates && paren_depth == 0)
return 0;
lexptr++;
return c;
case '.':
/* Might be a floating point number. */
if (lexptr[1] < '0' || lexptr[1] > '9')
{
if (parse_completion)
last_was_structop = 1;
goto symbol; /* Nope, must be a symbol. */
}
/* FALL THRU into number case. */
case '0':
case '1':
case '2':
case '3':
case '4':
case '5':
case '6':
case '7':
case '8':
case '9':
{
/* It's a number. */
int got_dot = 0, got_e = 0, toktype;
const char *p = tokstart;
int hex = input_radix > 10;
if (c == '0' && (p[1] == 'x' || p[1] == 'X'))
{
p += 2;
hex = 1;
}
for (;; ++p)
{
/* Hex exponents start with 'p', because 'e' is a valid hex
digit and thus does not indicate a floating point number
when the radix is hex. */
if ((!hex && !got_e && tolower (p[0]) == 'e')
|| (hex && !got_e && tolower (p[0] == 'p')))
got_dot = got_e = 1;
/* A '.' always indicates a decimal floating point number
regardless of the radix. If we have a '..' then its the
end of the number and the beginning of a slice. */
else if (!got_dot && (p[0] == '.' && p[1] != '.'))
got_dot = 1;
/* This is the sign of the exponent, not the end of the number. */
else if (got_e && (tolower (p[-1]) == 'e' || tolower (p[-1]) == 'p')
&& (*p == '-' || *p == '+'))
continue;
/* We will take any letters or digits, ignoring any embedded '_'.
parse_number will complain if past the radix, or if L or U are
not final. */
else if ((*p < '0' || *p > '9') && (*p != '_') &&
((*p < 'a' || *p > 'z') && (*p < 'A' || *p > 'Z')))
break;
}
toktype = parse_number (pstate, tokstart, p - tokstart,
got_dot|got_e, &yylval);
if (toktype == ERROR)
{
char *err_copy = (char *) alloca (p - tokstart + 1);
memcpy (err_copy, tokstart, p - tokstart);
err_copy[p - tokstart] = 0;
error (_("Invalid number \"%s\"."), err_copy);
}
lexptr = p;
return toktype;
}
case '@':
{
const char *p = &tokstart[1];
size_t len = strlen ("entry");
while (isspace (*p))
p++;
if (strncmp (p, "entry", len) == 0 && !isalnum (p[len])
&& p[len] != '_')
{
lexptr = &p[len];
return ENTRY;
}
}
/* FALLTHRU */
case '+':
case '-':
case '*':
case '/':
case '%':
case '|':
case '&':
case '^':
case '~':
case '!':
case '<':
case '>':
case '?':
case ':':
case '=':
case '{':
case '}':
symbol:
lexptr++;
return c;
case '\'':
case '"':
case '`':
{
int host_len;
int result = parse_string_or_char (tokstart, &lexptr, &yylval.tsval,
&host_len);
if (result == CHARACTER_LITERAL)
{
if (host_len == 0)
error (_("Empty character constant."));
else if (host_len > 2 && c == '\'')
{
++tokstart;
namelen = lexptr - tokstart - 1;
goto tryname;
}
else if (host_len > 1)
error (_("Invalid character constant."));
}
return result;
}
}
if (!(c == '_' || c == '$'
|| (c >= 'a' && c <= 'z') || (c >= 'A' && c <= 'Z')))
/* We must have come across a bad character (e.g. ';'). */
error (_("Invalid character '%c' in expression"), c);
/* It's a name. See how long it is. */
namelen = 0;
for (c = tokstart[namelen];
(c == '_' || c == '$' || (c >= '0' && c <= '9')
|| (c >= 'a' && c <= 'z') || (c >= 'A' && c <= 'Z'));)
c = tokstart[++namelen];
/* The token "if" terminates the expression and is NOT
removed from the input stream. */
if (namelen == 2 && tokstart[0] == 'i' && tokstart[1] == 'f')
return 0;
/* For the same reason (breakpoint conditions), "thread N"
terminates the expression. "thread" could be an identifier, but
an identifier is never followed by a number without intervening
punctuation. "task" is similar. Handle abbreviations of these,
similarly to breakpoint.c:find_condition_and_thread. */
if (namelen >= 1
&& (strncmp (tokstart, "thread", namelen) == 0
|| strncmp (tokstart, "task", namelen) == 0)
&& (tokstart[namelen] == ' ' || tokstart[namelen] == '\t'))
{
const char *p = tokstart + namelen + 1;
while (*p == ' ' || *p == '\t')
p++;
if (*p >= '0' && *p <= '9')
return 0;
}
lexptr += namelen;
tryname:
yylval.sval.ptr = tokstart;
yylval.sval.length = namelen;
/* Catch specific keywords. */
copy = copy_name (yylval.sval);
for (i = 0; i < sizeof ident_tokens / sizeof ident_tokens[0]; i++)
if (strcmp (copy, ident_tokens[i].operator) == 0)
{
/* It is ok to always set this, even though we don't always
strictly need to. */
yylval.opcode = ident_tokens[i].opcode;
return ident_tokens[i].token;
}
if (*tokstart == '$')
return DOLLAR_VARIABLE;
yylval.tsym.type
= language_lookup_primitive_type_by_name (parse_language (pstate),
parse_gdbarch (pstate), copy);
if (yylval.tsym.type != NULL)
return TYPENAME;
/* Input names that aren't symbols but ARE valid hex numbers,
when the input radix permits them, can be names or numbers
depending on the parse. Note we support radixes > 16 here. */
if ((tokstart[0] >= 'a' && tokstart[0] < 'a' + input_radix - 10)
|| (tokstart[0] >= 'A' && tokstart[0] < 'A' + input_radix - 10))
{
YYSTYPE newlval; /* Its value is ignored. */
int hextype = parse_number (pstate, tokstart, namelen, 0, &newlval);
if (hextype == INTEGER_LITERAL)
return NAME_OR_INT;
}
if (parse_completion && *lexptr == '\0')
saw_name_at_eof = 1;
return IDENTIFIER;
}
int
d_parse (struct parser_state *par_state)
{
int result;
struct cleanup *back_to;
/* Setting up the parser state. */
gdb_assert (par_state != NULL);
pstate = par_state;
back_to = make_cleanup (null_cleanup, NULL);
make_cleanup_restore_integer (&yydebug);
make_cleanup_clear_parser_state (&pstate);
yydebug = parser_debug;
/* Initialize some state used by the lexer. */
last_was_structop = 0;
saw_name_at_eof = 0;
result = yyparse ();
do_cleanups (back_to);
return result;
}
void
yyerror (char *msg)
{
if (prev_lexptr)
lexptr = prev_lexptr;
error (_("A %s in expression, near `%s'."), (msg ? msg : "error"), lexptr);
}