e2d1595531
In an upcoming commit, I need to be able to set the prefix used to introduce hexadecimal literal constants using a command line flag. This is not currently possible, because the switch which determines this (LITERAL_PREFIXDOLLAR_HEX) is a macro set at build time. This change substitutes it for a variable to be set at start up. gas/ChangeLog: * expr.c (literal_prefix_dollar_hex): New variable. (operand)[case '$']: Use the new variable instead of the old macro. Also, move this instance of "case '$'" next to the other one, and enable it only in the complementary proprocessor case. * expr.h (literal_prefix_dollar_hex): Declare it. * config/tc-epiphany.c (md_begin): Assign literal_prefix_dollar_hex. * config/tc-ip2k.c: ditto * config/tc-mt.c: ditto * config/tc-epiphany.h (LITERAL_PREFIXDOLLAR_HEX): Remove macro definition. * config/tc-ip2k.h: ditto * config/tc-mt.h: ditto
192 lines
6.7 KiB
C
192 lines
6.7 KiB
C
/* expr.h -> header file for expr.c
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Copyright (C) 1987-2019 Free Software Foundation, Inc.
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This file is part of GAS, the GNU Assembler.
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GAS is free software; you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation; either version 3, or (at your option)
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any later version.
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GAS is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with GAS; see the file COPYING. If not, write to the Free
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Software Foundation, 51 Franklin Street - Fifth Floor, Boston, MA
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02110-1301, USA. */
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/*
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* By popular demand, we define a struct to represent an expression.
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* This will no doubt mutate as expressions become baroque.
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*
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* Currently, we support expressions like "foo OP bar + 42". In other
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* words we permit a (possibly undefined) symbol, a (possibly
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* undefined) symbol and the operation used to combine the symbols,
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* and an (absolute) augend. RMS says this is so we can have 1-pass
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* assembly for any compiler emissions, and a 'case' statement might
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* emit 'undefined1 - undefined2'.
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*
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* The type of an expression used to be stored as a segment. That got
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* confusing because it overloaded the concept of a segment. I added
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* an operator field, instead.
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*/
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/* This is the type of an expression. The operator types are also
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used while parsing an expression.
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NOTE: This enumeration must match the op_rank array in expr.c. */
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typedef enum {
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/* An illegal expression. */
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O_illegal,
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/* A nonexistent expression. */
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O_absent,
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/* X_add_number (a constant expression). */
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O_constant,
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/* X_add_symbol + X_add_number. */
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O_symbol,
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/* X_add_symbol + X_add_number - the base address of the image. */
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O_symbol_rva,
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/* A register (X_add_number is register number). */
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O_register,
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/* A big value. If X_add_number is negative or 0, the value is in
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generic_floating_point_number. Otherwise the value is in
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generic_bignum, and X_add_number is the number of LITTLENUMs in
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the value. */
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O_big,
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/* (- X_add_symbol) + X_add_number. */
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O_uminus,
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/* (~ X_add_symbol) + X_add_number. */
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O_bit_not,
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/* (! X_add_symbol) + X_add_number. */
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O_logical_not,
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/* (X_add_symbol * X_op_symbol) + X_add_number. */
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O_multiply,
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/* (X_add_symbol / X_op_symbol) + X_add_number. */
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O_divide,
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/* (X_add_symbol % X_op_symbol) + X_add_number. */
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O_modulus,
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/* (X_add_symbol << X_op_symbol) + X_add_number. */
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O_left_shift,
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/* (X_add_symbol >> X_op_symbol) + X_add_number. */
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O_right_shift,
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/* (X_add_symbol | X_op_symbol) + X_add_number. */
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O_bit_inclusive_or,
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/* (X_add_symbol |~ X_op_symbol) + X_add_number. */
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O_bit_or_not,
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/* (X_add_symbol ^ X_op_symbol) + X_add_number. */
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O_bit_exclusive_or,
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/* (X_add_symbol & X_op_symbol) + X_add_number. */
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O_bit_and,
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/* (X_add_symbol + X_op_symbol) + X_add_number. */
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O_add,
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/* (X_add_symbol - X_op_symbol) + X_add_number. */
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O_subtract,
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/* (X_add_symbol == X_op_symbol) + X_add_number. */
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O_eq,
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/* (X_add_symbol != X_op_symbol) + X_add_number. */
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O_ne,
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/* (X_add_symbol < X_op_symbol) + X_add_number. */
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O_lt,
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/* (X_add_symbol <= X_op_symbol) + X_add_number. */
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O_le,
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/* (X_add_symbol >= X_op_symbol) + X_add_number. */
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O_ge,
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/* (X_add_symbol > X_op_symbol) + X_add_number. */
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O_gt,
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/* (X_add_symbol && X_op_symbol) + X_add_number. */
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O_logical_and,
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/* (X_add_symbol || X_op_symbol) + X_add_number. */
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O_logical_or,
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/* X_op_symbol [ X_add_symbol ] */
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O_index,
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/* machine dependent operators */
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O_md1, O_md2, O_md3, O_md4, O_md5, O_md6, O_md7, O_md8,
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O_md9, O_md10, O_md11, O_md12, O_md13, O_md14, O_md15, O_md16,
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O_md17, O_md18, O_md19, O_md20, O_md21, O_md22, O_md23, O_md24,
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O_md25, O_md26, O_md27, O_md28, O_md29, O_md30, O_md31, O_md32,
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/* this must be the largest value */
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O_max
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} operatorT;
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typedef struct expressionS {
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/* The main symbol. */
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symbolS *X_add_symbol;
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/* The second symbol, if needed. */
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symbolS *X_op_symbol;
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/* A number to add. */
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offsetT X_add_number;
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/* The type of the expression. We can't assume that an arbitrary
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compiler can handle a bitfield of enum type. FIXME: We could
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check this using autoconf. */
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#ifdef __GNUC__
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operatorT X_op : 8;
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#else
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unsigned char X_op;
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#endif
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/* Non-zero if X_add_number should be regarded as unsigned. This is
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only valid for O_constant expressions. It is only used when an
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O_constant must be extended into a bignum (i.e., it is not used
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when performing arithmetic on these values).
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FIXME: This field is not set very reliably. */
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unsigned int X_unsigned : 1;
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/* This is used to implement "word size + 1 bit" arithmetic, so that e.g.
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expressions used with .sleb128 directives can use the full range available
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for an unsigned word, but can also properly represent all values of a
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signed word. */
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unsigned int X_extrabit : 1;
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/* 7 additional bits can be defined if needed. */
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/* Machine dependent field */
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unsigned short X_md;
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} expressionS;
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enum expr_mode
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{
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expr_evaluate,
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expr_normal,
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expr_defer
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};
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/* "result" should be type (expressionS *). */
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#define expression(result) expr (0, result, expr_normal)
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#define expression_and_evaluate(result) expr (0, result, expr_evaluate)
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#define deferred_expression(result) expr (0, result, expr_defer)
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/* If an expression is O_big, look here for its value. These common
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data may be clobbered whenever expr() is called. */
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/* Flonums returned here. Big enough to hold most precise flonum. */
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extern FLONUM_TYPE generic_floating_point_number;
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/* Bignums returned here. */
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extern LITTLENUM_TYPE generic_bignum[];
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/* Number of littlenums in above. */
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#define SIZE_OF_LARGE_NUMBER (20)
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typedef char operator_rankT;
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extern char get_symbol_name (char **);
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extern char restore_line_pointer (char);
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extern void expr_begin (void);
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extern void expr_set_precedence (void);
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extern void expr_set_rank (operatorT, operator_rankT);
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extern void add_to_result (expressionS *, offsetT, int);
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extern void subtract_from_result (expressionS *, offsetT, int);
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extern segT expr (int, expressionS *, enum expr_mode);
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extern unsigned int get_single_number (void);
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extern symbolS *make_expr_symbol (expressionS * expressionP);
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extern int expr_symbol_where (symbolS *, const char **, unsigned int *);
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extern void current_location (expressionS *);
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extern symbolS *expr_build_uconstant (offsetT);
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extern symbolS *expr_build_dot (void);
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int resolve_expression (expressionS *);
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extern bfd_boolean literal_prefix_dollar_hex;
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