binutils-gdb/gas/config/tc-h8300.c
Alan Modra 35a358074f * config/tc-h8300.c (constant_fits_width_p): Trim constant to 32 bits
and sign extend before range tests.
	(constant_fits_size_p): Similarly.
	(get_specific): Trim X_add_number to 32 bits.
	(fix_operand_size): Likewise, and use unsigned test for signed
	ranges.
2012-02-27 06:40:42 +00:00

2245 lines
54 KiB
C
Raw Blame History

This file contains invisible Unicode characters

This file contains invisible Unicode characters that are indistinguishable to humans but may be processed differently by a computer. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

/* tc-h8300.c -- Assemble code for the Renesas H8/300
Copyright 1991, 1992, 1993, 1994, 1995, 1996, 1997, 1998, 2000,
2001, 2002, 2003, 2004, 2005, 2006, 2007, 2008, 2009, 2012
Free Software Foundation, Inc.
This file is part of GAS, the GNU Assembler.
GAS 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, or (at your option)
any later version.
GAS 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 GAS; see the file COPYING. If not, write to the Free
Software Foundation, 51 Franklin Street - Fifth Floor, Boston, MA
02110-1301, USA. */
/* Written By Steve Chamberlain <sac@cygnus.com>. */
#include "as.h"
#include "subsegs.h"
#include "dwarf2dbg.h"
#define DEFINE_TABLE
#define h8_opcodes ops
#include "opcode/h8300.h"
#include "safe-ctype.h"
#ifdef OBJ_ELF
#include "elf/h8.h"
#endif
const char comment_chars[] = ";";
const char line_comment_chars[] = "#";
const char line_separator_chars[] = "";
static void sbranch (int);
static void h8300hmode (int);
static void h8300smode (int);
static void h8300hnmode (int);
static void h8300snmode (int);
static void h8300sxmode (int);
static void h8300sxnmode (int);
static void pint (int);
int Hmode;
int Smode;
int Nmode;
int SXmode;
#define PSIZE (Hmode && !Nmode ? L_32 : L_16)
static int bsize = L_8; /* Default branch displacement. */
struct h8_instruction
{
int length;
int noperands;
int idx;
int size;
const struct h8_opcode *opcode;
};
static struct h8_instruction *h8_instructions;
static void
h8300hmode (int arg ATTRIBUTE_UNUSED)
{
Hmode = 1;
Smode = 0;
if (!bfd_set_arch_mach (stdoutput, bfd_arch_h8300, bfd_mach_h8300h))
as_warn (_("could not set architecture and machine"));
}
static void
h8300smode (int arg ATTRIBUTE_UNUSED)
{
Smode = 1;
Hmode = 1;
if (!bfd_set_arch_mach (stdoutput, bfd_arch_h8300, bfd_mach_h8300s))
as_warn (_("could not set architecture and machine"));
}
static void
h8300hnmode (int arg ATTRIBUTE_UNUSED)
{
Hmode = 1;
Smode = 0;
Nmode = 1;
if (!bfd_set_arch_mach (stdoutput, bfd_arch_h8300, bfd_mach_h8300hn))
as_warn (_("could not set architecture and machine"));
}
static void
h8300snmode (int arg ATTRIBUTE_UNUSED)
{
Smode = 1;
Hmode = 1;
Nmode = 1;
if (!bfd_set_arch_mach (stdoutput, bfd_arch_h8300, bfd_mach_h8300sn))
as_warn (_("could not set architecture and machine"));
}
static void
h8300sxmode (int arg ATTRIBUTE_UNUSED)
{
Smode = 1;
Hmode = 1;
SXmode = 1;
if (!bfd_set_arch_mach (stdoutput, bfd_arch_h8300, bfd_mach_h8300sx))
as_warn (_("could not set architecture and machine"));
}
static void
h8300sxnmode (int arg ATTRIBUTE_UNUSED)
{
Smode = 1;
Hmode = 1;
SXmode = 1;
Nmode = 1;
if (!bfd_set_arch_mach (stdoutput, bfd_arch_h8300, bfd_mach_h8300sxn))
as_warn (_("could not set architecture and machine"));
}
static void
sbranch (int size)
{
bsize = size;
}
static void
pint (int arg ATTRIBUTE_UNUSED)
{
cons (Hmode ? 4 : 2);
}
/* Like obj_elf_section, but issues a warning for new
sections which do not have an attribute specification. */
static void
h8300_elf_section (int push)
{
static const char * known_data_sections [] = { ".rodata", ".tdata", ".tbss" };
static const char * known_data_prefixes [] = { ".debug", ".zdebug", ".gnu.warning" };
char * saved_ilp = input_line_pointer;
char * name;
name = obj_elf_section_name ();
if (name == NULL)
return;
if (* input_line_pointer != ','
&& bfd_get_section_by_name (stdoutput, name) == NULL)
{
signed int i;
/* Ignore this warning for well known data sections. */
for (i = ARRAY_SIZE (known_data_sections); i--;)
if (strcmp (name, known_data_sections[i]) == 0)
break;
if (i < 0)
for (i = ARRAY_SIZE (known_data_prefixes); i--;)
if (strncmp (name, known_data_prefixes[i],
strlen (known_data_prefixes[i])) == 0)
break;
if (i < 0)
as_warn (_("new section '%s' defined without attributes - this might cause problems"), name);
}
/* FIXME: We ought to free the memory allocated by obj_elf_section_name()
for 'name', but we do not know if it was taken from the obstack, via
demand_copy_C_string(), or xmalloc()ed. */
input_line_pointer = saved_ilp;
obj_elf_section (push);
}
/* This table describes all the machine specific pseudo-ops the assembler
has to support. The fields are:
pseudo-op name without dot
function to call to execute this pseudo-op
Integer arg to pass to the function. */
const pseudo_typeS md_pseudo_table[] =
{
{"h8300h", h8300hmode, 0},
{"h8300hn", h8300hnmode, 0},
{"h8300s", h8300smode, 0},
{"h8300sn", h8300snmode, 0},
{"h8300sx", h8300sxmode, 0},
{"h8300sxn", h8300sxnmode, 0},
{"sbranch", sbranch, L_8},
{"lbranch", sbranch, L_16},
{"int", pint, 0},
{"data.b", cons, 1},
{"data.w", cons, 2},
{"data.l", cons, 4},
{"form", listing_psize, 0},
{"heading", listing_title, 0},
{"import", s_ignore, 0},
{"page", listing_eject, 0},
{"program", s_ignore, 0},
#ifdef OBJ_ELF
{"section", h8300_elf_section, 0},
{"section.s", h8300_elf_section, 0},
{"sect", h8300_elf_section, 0},
{"sect.s", h8300_elf_section, 0},
#endif
{0, 0, 0}
};
const char EXP_CHARS[] = "eE";
/* Chars that mean this number is a floating point constant
As in 0f12.456
or 0d1.2345e12. */
const char FLT_CHARS[] = "rRsSfFdDxXpP";
static struct hash_control *opcode_hash_control; /* Opcode mnemonics. */
/* This function is called once, at assembler startup time. This
should set up all the tables, etc. that the MD part of the assembler
needs. */
void
md_begin (void)
{
unsigned int nopcodes;
struct h8_opcode *p, *p1;
struct h8_instruction *pi;
char prev_buffer[100];
int idx = 0;
if (!bfd_set_arch_mach (stdoutput, bfd_arch_h8300, bfd_mach_h8300))
as_warn (_("could not set architecture and machine"));
opcode_hash_control = hash_new ();
prev_buffer[0] = 0;
nopcodes = sizeof (h8_opcodes) / sizeof (struct h8_opcode);
h8_instructions = (struct h8_instruction *)
xmalloc (nopcodes * sizeof (struct h8_instruction));
pi = h8_instructions;
p1 = h8_opcodes;
/* We do a minimum amount of sorting on the opcode table; this is to
make it easy to describe the mova instructions without unnecessary
code duplication.
Sorting only takes place inside blocks of instructions of the form
X/Y, so for example mova/b, mova/w and mova/l can be intermixed. */
while (p1)
{
struct h8_opcode *first_skipped = 0;
int len, cmplen = 0;
char *src = p1->name;
char *dst, *buffer;
if (p1->name == 0)
break;
/* Strip off any . part when inserting the opcode and only enter
unique codes into the hash table. */
dst = buffer = malloc (strlen (src) + 1);
while (*src)
{
if (*src == '.')
{
src++;
break;
}
if (*src == '/')
cmplen = src - p1->name + 1;
*dst++ = *src++;
}
*dst = 0;
len = dst - buffer;
if (cmplen == 0)
cmplen = len;
hash_insert (opcode_hash_control, buffer, (char *) pi);
strcpy (prev_buffer, buffer);
idx++;
for (p = p1; p->name; p++)
{
/* A negative TIME is used to indicate that we've added this opcode
already. */
if (p->time == -1)
continue;
if (strncmp (p->name, buffer, cmplen) != 0
|| (p->name[cmplen] != '\0' && p->name[cmplen] != '.'
&& p->name[cmplen - 1] != '/'))
{
if (first_skipped == 0)
first_skipped = p;
break;
}
if (strncmp (p->name, buffer, len) != 0)
{
if (first_skipped == 0)
first_skipped = p;
continue;
}
p->time = -1;
pi->size = p->name[len] == '.' ? p->name[len + 1] : 0;
pi->idx = idx;
/* Find the number of operands. */
pi->noperands = 0;
while (pi->noperands < 3 && p->args.nib[pi->noperands] != (op_type) E)
pi->noperands++;
/* Find the length of the opcode in bytes. */
pi->length = 0;
while (p->data.nib[pi->length * 2] != (op_type) E)
pi->length++;
pi->opcode = p;
pi++;
}
p1 = first_skipped;
}
/* Add entry for the NULL vector terminator. */
pi->length = 0;
pi->noperands = 0;
pi->idx = 0;
pi->size = 0;
pi->opcode = 0;
linkrelax = 1;
}
struct h8_op
{
op_type mode;
unsigned reg;
expressionS exp;
};
static void clever_message (const struct h8_instruction *, struct h8_op *);
static void fix_operand_size (struct h8_op *, int);
static void build_bytes (const struct h8_instruction *, struct h8_op *);
static void do_a_fix_imm (int, int, struct h8_op *, int, const struct h8_instruction *);
static void check_operand (struct h8_op *, unsigned int, char *);
static const struct h8_instruction * get_specific (const struct h8_instruction *, struct h8_op *, int) ;
static char *get_operands (unsigned, char *, struct h8_op *);
static void get_operand (char **, struct h8_op *, int);
static int parse_reg (char *, op_type *, unsigned *, int);
static char *skip_colonthing (char *, int *);
static char *parse_exp (char *, struct h8_op *);
static int constant_fits_width_p (struct h8_op *, unsigned int);
static int constant_fits_size_p (struct h8_op *, int, int);
/*
parse operands
WREG r0,r1,r2,r3,r4,r5,r6,r7,fp,sp
r0l,r0h,..r7l,r7h
@WREG
@WREG+
@-WREG
#const
ccr
*/
/* Try to parse a reg name. Return the number of chars consumed. */
static int
parse_reg (char *src, op_type *mode, unsigned int *reg, int direction)
{
char *end;
int len;
/* Cribbed from get_symbol_end. */
if (!is_name_beginner (*src) || *src == '\001')
return 0;
end = src + 1;
while ((is_part_of_name (*end) && *end != '.') || *end == '\001')
end++;
len = end - src;
if (len == 2 && TOLOWER (src[0]) == 's' && TOLOWER (src[1]) == 'p')
{
*mode = PSIZE | REG | direction;
*reg = 7;
return len;
}
if (len == 3 &&
TOLOWER (src[0]) == 'c' &&
TOLOWER (src[1]) == 'c' &&
TOLOWER (src[2]) == 'r')
{
*mode = CCR;
*reg = 0;
return len;
}
if (len == 3 &&
TOLOWER (src[0]) == 'e' &&
TOLOWER (src[1]) == 'x' &&
TOLOWER (src[2]) == 'r')
{
*mode = EXR;
*reg = 1;
return len;
}
if (len == 3 &&
TOLOWER (src[0]) == 'v' &&
TOLOWER (src[1]) == 'b' &&
TOLOWER (src[2]) == 'r')
{
*mode = VBR;
*reg = 6;
return len;
}
if (len == 3 &&
TOLOWER (src[0]) == 's' &&
TOLOWER (src[1]) == 'b' &&
TOLOWER (src[2]) == 'r')
{
*mode = SBR;
*reg = 7;
return len;
}
if (len == 2 && TOLOWER (src[0]) == 'f' && TOLOWER (src[1]) == 'p')
{
*mode = PSIZE | REG | direction;
*reg = 6;
return len;
}
if (len == 3 && TOLOWER (src[0]) == 'e' && TOLOWER (src[1]) == 'r' &&
src[2] >= '0' && src[2] <= '7')
{
*mode = L_32 | REG | direction;
*reg = src[2] - '0';
if (!Hmode)
as_warn (_("Reg not valid for H8/300"));
return len;
}
if (len == 2 && TOLOWER (src[0]) == 'e' && src[1] >= '0' && src[1] <= '7')
{
*mode = L_16 | REG | direction;
*reg = src[1] - '0' + 8;
if (!Hmode)
as_warn (_("Reg not valid for H8/300"));
return len;
}
if (TOLOWER (src[0]) == 'r')
{
if (src[1] >= '0' && src[1] <= '7')
{
if (len == 3 && TOLOWER (src[2]) == 'l')
{
*mode = L_8 | REG | direction;
*reg = (src[1] - '0') + 8;
return len;
}
if (len == 3 && TOLOWER (src[2]) == 'h')
{
*mode = L_8 | REG | direction;
*reg = (src[1] - '0');
return len;
}
if (len == 2)
{
*mode = L_16 | REG | direction;
*reg = (src[1] - '0');
return len;
}
}
}
return 0;
}
/* Parse an immediate or address-related constant and store it in OP.
If the user also specifies the operand's size, store that size
in OP->MODE, otherwise leave it for later code to decide. */
static char *
parse_exp (char *src, struct h8_op *op)
{
char *save;
save = input_line_pointer;
input_line_pointer = src;
expression (&op->exp);
if (op->exp.X_op == O_absent)
as_bad (_("missing operand"));
src = input_line_pointer;
input_line_pointer = save;
return skip_colonthing (src, &op->mode);
}
/* If SRC starts with an explicit operand size, skip it and store the size
in *MODE. Leave *MODE unchanged otherwise. */
static char *
skip_colonthing (char *src, int *mode)
{
if (*src == ':')
{
src++;
*mode &= ~SIZE;
if (src[0] == '8' && !ISDIGIT (src[1]))
*mode |= L_8;
else if (src[0] == '2' && !ISDIGIT (src[1]))
*mode |= L_2;
else if (src[0] == '3' && !ISDIGIT (src[1]))
*mode |= L_3;
else if (src[0] == '4' && !ISDIGIT (src[1]))
*mode |= L_4;
else if (src[0] == '5' && !ISDIGIT (src[1]))
*mode |= L_5;
else if (src[0] == '2' && src[1] == '4' && !ISDIGIT (src[2]))
*mode |= L_24;
else if (src[0] == '3' && src[1] == '2' && !ISDIGIT (src[2]))
*mode |= L_32;
else if (src[0] == '1' && src[1] == '6' && !ISDIGIT (src[2]))
*mode |= L_16;
else
as_bad (_("invalid operand size requested"));
while (ISDIGIT (*src))
src++;
}
return src;
}
/* The many forms of operand:
Rn Register direct
@Rn Register indirect
@(exp[:16], Rn) Register indirect with displacement
@Rn+
@-Rn
@aa:8 absolute 8 bit
@aa:16 absolute 16 bit
@aa absolute 16 bit
#xx[:size] immediate data
@(exp:[8], pc) pc rel
@@aa[:8] memory indirect. */
static int
constant_fits_width_p (struct h8_op *operand, unsigned int width)
{
offsetT num;
num = ((operand->exp.X_add_number & 0xffffffff) ^ 0x80000000) - 0x80000000;
return (num & ~width) == 0 || (num | width) == ~0;
}
static int
constant_fits_size_p (struct h8_op *operand, int size, int no_symbols)
{
offsetT num;
if (no_symbols
&& (operand->exp.X_add_symbol != 0 || operand->exp.X_op_symbol != 0))
return 0;
num = operand->exp.X_add_number & 0xffffffff;
switch (size)
{
case L_2:
return (num & ~3) == 0;
case L_3:
return (num & ~7) == 0;
case L_3NZ:
return num >= 1 && num < 8;
case L_4:
return (num & ~15) == 0;
case L_5:
return num >= 1 && num < 32;
case L_8:
num = (num ^ 0x80000000) - 0x80000000;
return (num & ~0xFF) == 0 || (num | 0x7F) == ~0;
case L_8U:
return (num & ~0xFF) == 0;
case L_16:
num = (num ^ 0x80000000) - 0x80000000;
return (num & ~0xFFFF) == 0 || (num | 0x7FFF) == ~0;
case L_16U:
return (num & ~0xFFFF) == 0;
case L_32:
return 1;
default:
abort ();
}
}
static void
get_operand (char **ptr, struct h8_op *op, int direction)
{
char *src = *ptr;
op_type mode;
unsigned int num;
unsigned int len;
op->mode = 0;
/* Check for '(' and ')' for instructions ldm and stm. */
if (src[0] == '(' && src[8] == ')')
++ src;
/* Gross. Gross. ldm and stm have a format not easily handled
by get_operand. We deal with it explicitly here. */
if (TOLOWER (src[0]) == 'e' && TOLOWER (src[1]) == 'r' &&
ISDIGIT (src[2]) && src[3] == '-' &&
TOLOWER (src[4]) == 'e' && TOLOWER (src[5]) == 'r' && ISDIGIT (src[6]))
{
int low, high;
low = src[2] - '0';
high = src[6] - '0';
/* Check register pair's validity as per tech note TN-H8*-193A/E
from Renesas for H8S and H8SX hardware manual. */
if ( !(low == 0 && (high == 1 || high == 2 || high == 3))
&& !(low == 1 && (high == 2 || high == 3 || high == 4) && SXmode)
&& !(low == 2 && (high == 3 || ((high == 4 || high == 5) && SXmode)))
&& !(low == 3 && (high == 4 || high == 5 || high == 6) && SXmode)
&& !(low == 4 && (high == 5 || high == 6))
&& !(low == 4 && high == 7 && SXmode)
&& !(low == 5 && (high == 6 || high == 7) && SXmode)
&& !(low == 6 && high == 7 && SXmode))
as_bad (_("Invalid register list for ldm/stm\n"));
/* Even sicker. We encode two registers into op->reg. One
for the low register to save, the other for the high
register to save; we also set the high bit in op->reg
so we know this is "very special". */
op->reg = 0x80000000 | (high << 8) | low;
op->mode = REG;
if (src[7] == ')')
*ptr = src + 8;
else
*ptr = src + 7;
return;
}
len = parse_reg (src, &op->mode, &op->reg, direction);
if (len)
{
src += len;
if (*src == '.')
{
int size = op->mode & SIZE;
switch (src[1])
{
case 'l': case 'L':
if (size != L_32)
as_warn (_("mismatch between register and suffix"));
op->mode = (op->mode & ~MODE) | LOWREG;
break;
case 'w': case 'W':
if (size != L_32 && size != L_16)
as_warn (_("mismatch between register and suffix"));
op->mode = (op->mode & ~MODE) | LOWREG;
op->mode = (op->mode & ~SIZE) | L_16;
break;
case 'b': case 'B':
op->mode = (op->mode & ~MODE) | LOWREG;
if (size != L_32 && size != L_8)
as_warn (_("mismatch between register and suffix"));
op->mode = (op->mode & ~MODE) | LOWREG;
op->mode = (op->mode & ~SIZE) | L_8;
break;
default:
as_warn (_("invalid suffix after register."));
break;
}
src += 2;
}
*ptr = src;
return;
}
if (*src == '@')
{
src++;
if (*src == '@')
{
*ptr = parse_exp (src + 1, op);
if (op->exp.X_add_number >= 0x100)
{
int divisor = 1;
op->mode = VECIND;
/* FIXME : 2? or 4? */
if (op->exp.X_add_number >= 0x400)
as_bad (_("address too high for vector table jmp/jsr"));
else if (op->exp.X_add_number >= 0x200)
divisor = 4;
else
divisor = 2;
op->exp.X_add_number = op->exp.X_add_number / divisor - 0x80;
}
else
op->mode = MEMIND;
return;
}
if (*src == '-' || *src == '+')
{
len = parse_reg (src + 1, &mode, &num, direction);
if (len == 0)
{
/* Oops, not a reg after all, must be ordinary exp. */
op->mode = ABS | direction;
*ptr = parse_exp (src, op);
return;
}
if (((mode & SIZE) != PSIZE)
/* For Normal mode accept 16 bit and 32 bit pointer registers. */
&& (!Nmode || ((mode & SIZE) != L_32)))
as_bad (_("Wrong size pointer register for architecture."));
op->mode = src[0] == '-' ? RDPREDEC : RDPREINC;
op->reg = num;
*ptr = src + 1 + len;
return;
}
if (*src == '(')
{
src++;
/* See if this is @(ERn.x, PC). */
len = parse_reg (src, &mode, &op->reg, direction);
if (len != 0 && (mode & MODE) == REG && src[len] == '.')
{
switch (TOLOWER (src[len + 1]))
{
case 'b':
mode = PCIDXB | direction;
break;
case 'w':
mode = PCIDXW | direction;
break;
case 'l':
mode = PCIDXL | direction;
break;
default:
mode = 0;
break;
}
if (mode
&& src[len + 2] == ','
&& TOLOWER (src[len + 3]) != 'p'
&& TOLOWER (src[len + 4]) != 'c'
&& src[len + 5] != ')')
{
*ptr = src + len + 6;
op->mode |= mode;
return;
}
/* Fall through into disp case - the grammar is somewhat
ambiguous, so we should try whether it's a DISP operand
after all ("ER3.L" might be a poorly named label...). */
}
/* Disp. */
/* Start off assuming a 16 bit offset. */
src = parse_exp (src, op);
if (*src == ')')
{
op->mode |= ABS | direction;
*ptr = src + 1;
return;
}
if (*src != ',')
{
as_bad (_("expected @(exp, reg16)"));
return;
}
src++;
len = parse_reg (src, &mode, &op->reg, direction);
if (len == 0 || (mode & MODE) != REG)
{
as_bad (_("expected @(exp, reg16)"));
return;
}
src += len;
if (src[0] == '.')
{
switch (TOLOWER (src[1]))
{
case 'b':
op->mode |= INDEXB | direction;
break;
case 'w':
op->mode |= INDEXW | direction;
break;
case 'l':
op->mode |= INDEXL | direction;
break;
default:
as_bad (_("expected .L, .W or .B for register in indexed addressing mode"));
}
src += 2;
op->reg &= 7;
}
else
op->mode |= DISP | direction;
src = skip_colonthing (src, &op->mode);
if (*src != ')' && '(')
{
as_bad (_("expected @(exp, reg16)"));
return;
}
*ptr = src + 1;
return;
}
len = parse_reg (src, &mode, &num, direction);
if (len)
{
src += len;
if (*src == '+' || *src == '-')
{
if (((mode & SIZE) != PSIZE)
/* For Normal mode accept 16 bit and 32 bit pointer registers. */
&& (!Nmode || ((mode & SIZE) != L_32)))
as_bad (_("Wrong size pointer register for architecture."));
op->mode = *src == '+' ? RSPOSTINC : RSPOSTDEC;
op->reg = num;
src++;
*ptr = src;
return;
}
if (((mode & SIZE) != PSIZE)
/* For Normal mode accept 16 bit and 32 bit pointer registers. */
&& (!Nmode || ((mode & SIZE) != L_32)))
as_bad (_("Wrong size pointer register for architecture."));
op->mode = direction | IND | PSIZE;
op->reg = num;
*ptr = src;
return;
}
else
{
/* must be a symbol */
op->mode = ABS | direction;
*ptr = parse_exp (src, op);
return;
}
}
if (*src == '#')
{
op->mode = IMM;
*ptr = parse_exp (src + 1, op);
return;
}
else if (strncmp (src, "mach", 4) == 0 ||
strncmp (src, "macl", 4) == 0 ||
strncmp (src, "MACH", 4) == 0 ||
strncmp (src, "MACL", 4) == 0)
{
op->reg = TOLOWER (src[3]) == 'l';
op->mode = MACREG;
*ptr = src + 4;
return;
}
else
{
op->mode = PCREL;
*ptr = parse_exp (src, op);
}
}
static char *
get_operands (unsigned int noperands, char *op_end, struct h8_op *operand)
{
char *ptr = op_end;
switch (noperands)
{
case 0:
break;
case 1:
ptr++;
get_operand (&ptr, operand + 0, SRC);
if (*ptr == ',')
{
ptr++;
get_operand (&ptr, operand + 1, DST);
}
break;
case 2:
ptr++;
get_operand (&ptr, operand + 0, SRC);
if (*ptr == ',')
ptr++;
get_operand (&ptr, operand + 1, DST);
break;
case 3:
ptr++;
get_operand (&ptr, operand + 0, SRC);
if (*ptr == ',')
ptr++;
get_operand (&ptr, operand + 1, DST);
if (*ptr == ',')
ptr++;
get_operand (&ptr, operand + 2, OP3);
break;
default:
abort ();
}
return ptr;
}
/* MOVA has special requirements. Rather than adding twice the amount of
addressing modes, we simply special case it a bit. */
static void
get_mova_operands (char *op_end, struct h8_op *operand)
{
char *ptr = op_end;
if (ptr[1] != '@' || ptr[2] != '(')
goto error;
ptr += 3;
operand[0].mode = 0;
ptr = parse_exp (ptr, &operand[0]);
if (*ptr !=',')
goto error;
ptr++;
get_operand (&ptr, operand + 1, DST);
if (*ptr =='.')
{
ptr++;
switch (*ptr++)
{
case 'b': case 'B':
operand[0].mode = (operand[0].mode & ~MODE) | INDEXB;
break;
case 'w': case 'W':
operand[0].mode = (operand[0].mode & ~MODE) | INDEXW;
break;
case 'l': case 'L':
operand[0].mode = (operand[0].mode & ~MODE) | INDEXL;
break;
default:
goto error;
}
}
else if ((operand[1].mode & MODE) == LOWREG)
{
switch (operand[1].mode & SIZE)
{
case L_8:
operand[0].mode = (operand[0].mode & ~MODE) | INDEXB;
break;
case L_16:
operand[0].mode = (operand[0].mode & ~MODE) | INDEXW;
break;
case L_32:
operand[0].mode = (operand[0].mode & ~MODE) | INDEXL;
break;
default:
goto error;
}
}
else
goto error;
if (*ptr++ != ')' || *ptr++ != ',')
goto error;
get_operand (&ptr, operand + 2, OP3);
/* See if we can use the short form of MOVA. */
if (((operand[1].mode & MODE) == REG || (operand[1].mode & MODE) == LOWREG)
&& (operand[2].mode & MODE) == REG
&& (operand[1].reg & 7) == (operand[2].reg & 7))
{
operand[1].mode = operand[2].mode = 0;
operand[0].reg = operand[2].reg & 7;
}
return;
error:
as_bad (_("expected valid addressing mode for mova: \"@(disp, ea.sz),ERn\""));
}
static void
get_rtsl_operands (char *ptr, struct h8_op *operand)
{
int mode, len, type = 0;
unsigned int num, num2;
ptr++;
if (*ptr == '(')
{
ptr++;
type = 1;
}
len = parse_reg (ptr, &mode, &num, SRC);
if (len == 0 || (mode & MODE) != REG)
{
as_bad (_("expected register"));
return;
}
ptr += len;
if (*ptr == '-')
{
len = parse_reg (++ptr, &mode, &num2, SRC);
if (len == 0 || (mode & MODE) != REG)
{
as_bad (_("expected register"));
return;
}
ptr += len;
/* CONST_xxx are used as placeholders in the opcode table. */
num = num2 - num;
if (num > 3)
{
as_bad (_("invalid register list"));
return;
}
}
else
num2 = num, num = 0;
if (type == 1 && *ptr++ != ')')
{
as_bad (_("expected closing paren"));
return;
}
operand[0].mode = RS32;
operand[1].mode = RD32;
operand[0].reg = num;
operand[1].reg = num2;
}
/* Passed a pointer to a list of opcodes which use different
addressing modes, return the opcode which matches the opcodes
provided. */
static const struct h8_instruction *
get_specific (const struct h8_instruction *instruction,
struct h8_op *operands, int size)
{
const struct h8_instruction *this_try = instruction;
const struct h8_instruction *found_other = 0, *found_mismatched = 0;
int found = 0;
int this_index = instruction->idx;
int noperands = 0;
/* There's only one ldm/stm and it's easier to just
get out quick for them. */
if (OP_KIND (instruction->opcode->how) == O_LDM
|| OP_KIND (instruction->opcode->how) == O_STM)
return this_try;
while (noperands < 3 && operands[noperands].mode != 0)
noperands++;
while (this_index == instruction->idx && !found)
{
int this_size;
found = 1;
this_try = instruction++;
this_size = this_try->opcode->how & SN;
if (this_try->noperands != noperands)
found = 0;
else if (this_try->noperands > 0)
{
int i;
for (i = 0; i < this_try->noperands && found; i++)
{
op_type op = this_try->opcode->args.nib[i];
int op_mode = op & MODE;
int op_size = op & SIZE;
int x = operands[i].mode;
int x_mode = x & MODE;
int x_size = x & SIZE;
if (op_mode == LOWREG && (x_mode == REG || x_mode == LOWREG))
{
if ((x_size == L_8 && (operands[i].reg & 8) == 0)
|| (x_size == L_16 && (operands[i].reg & 8) == 8))
as_warn (_("can't use high part of register in operand %d"), i);
if (x_size != op_size)
found = 0;
}
else if (op_mode == REG)
{
if (x_mode == LOWREG)
x_mode = REG;
if (x_mode != REG)
found = 0;
if (x_size == L_P)
x_size = (Hmode ? L_32 : L_16);
if (op_size == L_P)
op_size = (Hmode ? L_32 : L_16);
/* The size of the reg is v important. */
if (op_size != x_size)
found = 0;
}
else if (op_mode & CTRL) /* control register */
{
if (!(x_mode & CTRL))
found = 0;
switch (x_mode)
{
case CCR:
if (op_mode != CCR &&
op_mode != CCR_EXR &&
op_mode != CC_EX_VB_SB)
found = 0;
break;
case EXR:
if (op_mode != EXR &&
op_mode != CCR_EXR &&
op_mode != CC_EX_VB_SB)
found = 0;
break;
case MACH:
if (op_mode != MACH &&
op_mode != MACREG)
found = 0;
break;
case MACL:
if (op_mode != MACL &&
op_mode != MACREG)
found = 0;
break;
case VBR:
if (op_mode != VBR &&
op_mode != VBR_SBR &&
op_mode != CC_EX_VB_SB)
found = 0;
break;
case SBR:
if (op_mode != SBR &&
op_mode != VBR_SBR &&
op_mode != CC_EX_VB_SB)
found = 0;
break;
}
}
else if ((op & ABSJMP) && (x_mode == ABS || x_mode == PCREL))
{
operands[i].mode &= ~MODE;
operands[i].mode |= ABSJMP;
/* But it may not be 24 bits long. */
if (x_mode == ABS && !Hmode)
{
operands[i].mode &= ~SIZE;
operands[i].mode |= L_16;
}
if ((operands[i].mode & SIZE) == L_32
&& (op_mode & SIZE) != L_32)
found = 0;
}
else if (x_mode == IMM && op_mode != IMM)
{
offsetT num = operands[i].exp.X_add_number & 0xffffffff;
if (op_mode == KBIT || op_mode == DBIT)
/* This is ok if the immediate value is sensible. */;
else if (op_mode == CONST_2)
found = num == 2;
else if (op_mode == CONST_4)
found = num == 4;
else if (op_mode == CONST_8)
found = num == 8;
else if (op_mode == CONST_16)
found = num == 16;
else
found = 0;
}
else if (op_mode == PCREL && op_mode == x_mode)
{
/* movsd, bsr/bc and bsr/bs only come in PCREL16 flavour:
If x_size is L_8, promote it. */
if (OP_KIND (this_try->opcode->how) == O_MOVSD
|| OP_KIND (this_try->opcode->how) == O_BSRBC
|| OP_KIND (this_try->opcode->how) == O_BSRBS)
if (x_size == L_8)
x_size = L_16;
/* The size of the displacement is important. */
if (op_size != x_size)
found = 0;
}
else if ((op_mode == DISP || op_mode == IMM || op_mode == ABS
|| op_mode == INDEXB || op_mode == INDEXW
|| op_mode == INDEXL)
&& op_mode == x_mode)
{
/* Promote a L_24 to L_32 if it makes us match. */
if (x_size == L_24 && op_size == L_32)
{
x &= ~SIZE;
x |= x_size = L_32;
}
if (((x_size == L_16 && op_size == L_16U)
|| (x_size == L_8 && op_size == L_8U)
|| (x_size == L_3 && op_size == L_3NZ))
/* We're deliberately more permissive for ABS modes. */
&& (op_mode == ABS
|| constant_fits_size_p (operands + i, op_size,
op & NO_SYMBOLS)))
x_size = op_size;
if (x_size != 0 && op_size != x_size)
found = 0;
else if (x_size == 0
&& ! constant_fits_size_p (operands + i, op_size,
op & NO_SYMBOLS))
found = 0;
}
else if (op_mode != x_mode)
{
found = 0;
}
}
}
if (found)
{
if ((this_try->opcode->available == AV_H8SX && ! SXmode)
|| (this_try->opcode->available == AV_H8S && ! Smode)
|| (this_try->opcode->available == AV_H8H && ! Hmode))
found = 0, found_other = this_try;
else if (this_size != size && (this_size != SN && size != SN))
found_mismatched = this_try, found = 0;
}
}
if (found)
return this_try;
if (found_other)
{
as_warn (_("Opcode `%s' with these operand types not available in %s mode"),
found_other->opcode->name,
(! Hmode && ! Smode ? "H8/300"
: SXmode ? "H8sx"
: Smode ? "H8/300S"
: "H8/300H"));
}
else if (found_mismatched)
{
as_warn (_("mismatch between opcode size and operand size"));
return found_mismatched;
}
return 0;
}
static void
check_operand (struct h8_op *operand, unsigned int width, char *string)
{
if (operand->exp.X_add_symbol == 0
&& operand->exp.X_op_symbol == 0)
{
/* No symbol involved, let's look at offset, it's dangerous if
any of the high bits are not 0 or ff's, find out by oring or
anding with the width and seeing if the answer is 0 or all
fs. */
if (! constant_fits_width_p (operand, width))
{
if (width == 255
&& (operand->exp.X_add_number & 0xff00) == 0xff00)
{
/* Just ignore this one - which happens when trying to
fit a 16 bit address truncated into an 8 bit address
of something like bset. */
}
else if (strcmp (string, "@") == 0
&& width == 0xffff
&& (operand->exp.X_add_number & 0xff8000) == 0xff8000)
{
/* Just ignore this one - which happens when trying to
fit a 24 bit address truncated into a 16 bit address
of something like mov.w. */
}
else
{
as_warn (_("operand %s0x%lx out of range."), string,
(unsigned long) operand->exp.X_add_number);
}
}
}
}
/* RELAXMODE has one of 3 values:
0 Output a "normal" reloc, no relaxing possible for this insn/reloc
1 Output a relaxable 24bit absolute mov.w address relocation
(may relax into a 16bit absolute address).
2 Output a relaxable 16/24 absolute mov.b address relocation
(may relax into an 8bit absolute address). */
static void
do_a_fix_imm (int offset, int nibble, struct h8_op *operand, int relaxmode, const struct h8_instruction *this_try)
{
int idx;
int size;
int where;
char *bytes = frag_now->fr_literal + offset;
char *t = ((operand->mode & MODE) == IMM) ? "#" : "@";
if (operand->exp.X_add_symbol == 0)
{
switch (operand->mode & SIZE)
{
case L_2:
check_operand (operand, 0x3, t);
bytes[0] |= (operand->exp.X_add_number & 3) << (nibble ? 0 : 4);
break;
case L_3:
case L_3NZ:
check_operand (operand, 0x7, t);
bytes[0] |= (operand->exp.X_add_number & 7) << (nibble ? 0 : 4);
break;
case L_4:
check_operand (operand, 0xF, t);
bytes[0] |= (operand->exp.X_add_number & 15) << (nibble ? 0 : 4);
break;
case L_5:
check_operand (operand, 0x1F, t);
bytes[0] |= operand->exp.X_add_number & 31;
break;
case L_8:
case L_8U:
check_operand (operand, 0xff, t);
bytes[0] |= operand->exp.X_add_number;
break;
case L_16:
case L_16U:
check_operand (operand, 0xffff, t);
bytes[0] |= operand->exp.X_add_number >> 8;
bytes[1] |= operand->exp.X_add_number >> 0;
#ifdef OBJ_ELF
/* MOVA needs both relocs to relax the second operand properly. */
if (relaxmode != 0
&& (OP_KIND(this_try->opcode->how) == O_MOVAB
|| OP_KIND(this_try->opcode->how) == O_MOVAW
|| OP_KIND(this_try->opcode->how) == O_MOVAL))
{
idx = BFD_RELOC_16;
fix_new_exp (frag_now, offset, 2, &operand->exp, 0, idx);
}
#endif
break;
case L_24:
check_operand (operand, 0xffffff, t);
bytes[0] |= operand->exp.X_add_number >> 16;
bytes[1] |= operand->exp.X_add_number >> 8;
bytes[2] |= operand->exp.X_add_number >> 0;
break;
case L_32:
/* This should be done with bfd. */
bytes[0] |= operand->exp.X_add_number >> 24;
bytes[1] |= operand->exp.X_add_number >> 16;
bytes[2] |= operand->exp.X_add_number >> 8;
bytes[3] |= operand->exp.X_add_number >> 0;
if (relaxmode != 0)
{
idx = (relaxmode == 2) ? R_MOV24B1 : R_MOVL1;
fix_new_exp (frag_now, offset, 4, &operand->exp, 0, idx);
}
break;
}
}
else
{
switch (operand->mode & SIZE)
{
case L_24:
case L_32:
size = 4;
where = (operand->mode & SIZE) == L_24 ? -1 : 0;
if (relaxmode == 2)
idx = R_MOV24B1;
else if (relaxmode == 1)
idx = R_MOVL1;
else
idx = R_RELLONG;
break;
default:
as_bad (_("Can't work out size of operand.\n"));
case L_16:
case L_16U:
size = 2;
where = 0;
if (relaxmode == 2)
idx = R_MOV16B1;
else
idx = R_RELWORD;
operand->exp.X_add_number =
((operand->exp.X_add_number & 0xffff) ^ 0x8000) - 0x8000;
operand->exp.X_add_number |= (bytes[0] << 8) | bytes[1];
break;
case L_8:
size = 1;
where = 0;
idx = R_RELBYTE;
operand->exp.X_add_number =
((operand->exp.X_add_number & 0xff) ^ 0x80) - 0x80;
operand->exp.X_add_number |= bytes[0];
}
fix_new_exp (frag_now,
offset + where,
size,
&operand->exp,
0,
idx);
}
}
/* Now we know what sort of opcodes it is, let's build the bytes. */
static void
build_bytes (const struct h8_instruction *this_try, struct h8_op *operand)
{
int i;
char *output = frag_more (this_try->length);
const op_type *nibble_ptr = this_try->opcode->data.nib;
op_type c;
unsigned int nibble_count = 0;
int op_at[3];
int nib = 0;
int movb = 0;
char asnibbles[100];
char *p = asnibbles;
int high, low;
if (!Hmode && this_try->opcode->available != AV_H8)
as_warn (_("Opcode `%s' with these operand types not available in H8/300 mode"),
this_try->opcode->name);
else if (!Smode
&& this_try->opcode->available != AV_H8
&& this_try->opcode->available != AV_H8H)
as_warn (_("Opcode `%s' with these operand types not available in H8/300H mode"),
this_try->opcode->name);
else if (!SXmode
&& this_try->opcode->available != AV_H8
&& this_try->opcode->available != AV_H8H
&& this_try->opcode->available != AV_H8S)
as_warn (_("Opcode `%s' with these operand types not available in H8/300S mode"),
this_try->opcode->name);
while (*nibble_ptr != (op_type) E)
{
int d;
nib = 0;
c = *nibble_ptr++;
d = (c & OP3) == OP3 ? 2 : (c & DST) == DST ? 1 : 0;
if (c < 16)
nib = c;
else
{
int c2 = c & MODE;
if (c2 == REG || c2 == LOWREG
|| c2 == IND || c2 == PREINC || c2 == PREDEC
|| c2 == POSTINC || c2 == POSTDEC)
{
nib = operand[d].reg;
if (c2 == LOWREG)
nib &= 7;
}
else if (c & CTRL) /* Control reg operand. */
nib = operand[d].reg;
else if ((c & DISPREG) == (DISPREG))
{
nib = operand[d].reg;
}
else if (c2 == ABS)
{
operand[d].mode = c;
op_at[d] = nibble_count;
nib = 0;
}
else if (c2 == IMM || c2 == PCREL || c2 == ABS
|| (c & ABSJMP) || c2 == DISP)
{
operand[d].mode = c;
op_at[d] = nibble_count;
nib = 0;
}
else if ((c & IGNORE) || (c & DATA))
nib = 0;
else if (c2 == DBIT)
{
switch (operand[0].exp.X_add_number)
{
case 1:
nib = c;
break;
case 2:
nib = 0x8 | c;
break;
default:
as_bad (_("Need #1 or #2 here"));
}
}
else if (c2 == KBIT)
{
switch (operand[0].exp.X_add_number)
{
case 1:
nib = 0;
break;
case 2:
nib = 8;
break;
case 4:
if (!Hmode)
as_warn (_("#4 not valid on H8/300."));
nib = 9;
break;
default:
as_bad (_("Need #1 or #2 here"));
break;
}
/* Stop it making a fix. */
operand[0].mode = 0;
}
if (c & MEMRELAX)
operand[d].mode |= MEMRELAX;
if (c & B31)
nib |= 0x8;
if (c & B21)
nib |= 0x4;
if (c & B11)
nib |= 0x2;
if (c & B01)
nib |= 0x1;
if (c2 == MACREG)
{
if (operand[0].mode == MACREG)
/* stmac has mac[hl] as the first operand. */
nib = 2 + operand[0].reg;
else
/* ldmac has mac[hl] as the second operand. */
nib = 2 + operand[1].reg;
}
}
nibble_count++;
*p++ = nib;
}
/* Disgusting. Why, oh why didn't someone ask us for advice
on the assembler format. */
if (OP_KIND (this_try->opcode->how) == O_LDM)
{
high = (operand[1].reg >> 8) & 0xf;
low = (operand[1].reg) & 0xf;
asnibbles[2] = high - low;
asnibbles[7] = high;
}
else if (OP_KIND (this_try->opcode->how) == O_STM)
{
high = (operand[0].reg >> 8) & 0xf;
low = (operand[0].reg) & 0xf;
asnibbles[2] = high - low;
asnibbles[7] = low;
}
for (i = 0; i < this_try->length; i++)
output[i] = (asnibbles[i * 2] << 4) | asnibbles[i * 2 + 1];
/* Note if this is a movb or a bit manipulation instruction
there is a special relaxation which only applies. */
if ( this_try->opcode->how == O (O_MOV, SB)
|| this_try->opcode->how == O (O_BCLR, SB)
|| this_try->opcode->how == O (O_BAND, SB)
|| this_try->opcode->how == O (O_BIAND, SB)
|| this_try->opcode->how == O (O_BILD, SB)
|| this_try->opcode->how == O (O_BIOR, SB)
|| this_try->opcode->how == O (O_BIST, SB)
|| this_try->opcode->how == O (O_BIXOR, SB)
|| this_try->opcode->how == O (O_BLD, SB)
|| this_try->opcode->how == O (O_BNOT, SB)
|| this_try->opcode->how == O (O_BOR, SB)
|| this_try->opcode->how == O (O_BSET, SB)
|| this_try->opcode->how == O (O_BST, SB)
|| this_try->opcode->how == O (O_BTST, SB)
|| this_try->opcode->how == O (O_BXOR, SB))
movb = 1;
/* Output any fixes. */
for (i = 0; i < this_try->noperands; i++)
{
int x = operand[i].mode;
int x_mode = x & MODE;
if (x_mode == IMM || x_mode == DISP)
do_a_fix_imm (output - frag_now->fr_literal + op_at[i] / 2,
op_at[i] & 1, operand + i, (x & MEMRELAX) != 0,
this_try);
else if (x_mode == ABS)
do_a_fix_imm (output - frag_now->fr_literal + op_at[i] / 2,
op_at[i] & 1, operand + i,
(x & MEMRELAX) ? movb + 1 : 0,
this_try);
else if (x_mode == PCREL)
{
int size16 = (x & SIZE) == L_16;
int size = size16 ? 2 : 1;
int type = size16 ? R_PCRWORD : R_PCRBYTE;
fixS *fixP;
check_operand (operand + i, size16 ? 0x7fff : 0x7f, "@");
if (operand[i].exp.X_add_number & 1)
as_warn (_("branch operand has odd offset (%lx)\n"),
(unsigned long) operand->exp.X_add_number);
#ifndef OBJ_ELF
/* The COFF port has always been off by one, changing it
now would be an incompatible change, so we leave it as-is.
We don't want to do this for ELF as we want to be
compatible with the proposed ELF format from Hitachi. */
operand[i].exp.X_add_number -= 1;
#endif
if (size16)
{
operand[i].exp.X_add_number =
((operand[i].exp.X_add_number & 0xffff) ^ 0x8000) - 0x8000;
}
else
{
operand[i].exp.X_add_number =
((operand[i].exp.X_add_number & 0xff) ^ 0x80) - 0x80;
}
/* For BRA/S. */
if (! size16)
operand[i].exp.X_add_number |= output[op_at[i] / 2];
fixP = fix_new_exp (frag_now,
output - frag_now->fr_literal + op_at[i] / 2,
size,
&operand[i].exp,
1,
type);
fixP->fx_signed = 1;
}
else if (x_mode == MEMIND)
{
check_operand (operand + i, 0xff, "@@");
fix_new_exp (frag_now,
output - frag_now->fr_literal + 1,
1,
&operand[i].exp,
0,
R_MEM_INDIRECT);
}
else if (x_mode == VECIND)
{
check_operand (operand + i, 0x7f, "@@");
/* FIXME: approximating the effect of "B31" here...
This is very hackish, and ought to be done a better way. */
operand[i].exp.X_add_number |= 0x80;
fix_new_exp (frag_now,
output - frag_now->fr_literal + 1,
1,
&operand[i].exp,
0,
R_MEM_INDIRECT);
}
else if (x & ABSJMP)
{
int where = 0;
bfd_reloc_code_real_type reloc_type = R_JMPL1;
#ifdef OBJ_ELF
/* To be compatible with the proposed H8 ELF format, we
want the relocation's offset to point to the first byte
that will be modified, not to the start of the instruction. */
if ((operand->mode & SIZE) == L_32)
{
where = 2;
reloc_type = R_RELLONG;
}
else
where = 1;
#endif
/* This jmp may be a jump or a branch. */
check_operand (operand + i,
SXmode ? 0xffffffff : Hmode ? 0xffffff : 0xffff,
"@");
if (operand[i].exp.X_add_number & 1)
as_warn (_("branch operand has odd offset (%lx)\n"),
(unsigned long) operand->exp.X_add_number);
if (!Hmode)
operand[i].exp.X_add_number =
((operand[i].exp.X_add_number & 0xffff) ^ 0x8000) - 0x8000;
fix_new_exp (frag_now,
output - frag_now->fr_literal + where,
4,
&operand[i].exp,
0,
reloc_type);
}
}
}
/* Try to give an intelligent error message for common and simple to
detect errors. */
static void
clever_message (const struct h8_instruction *instruction,
struct h8_op *operand)
{
/* Find out if there was more than one possible opcode. */
if ((instruction + 1)->idx != instruction->idx)
{
int argn;
/* Only one opcode of this flavour, try to guess which operand
didn't match. */
for (argn = 0; argn < instruction->noperands; argn++)
{
switch (instruction->opcode->args.nib[argn])
{
case RD16:
if (operand[argn].mode != RD16)
{
as_bad (_("destination operand must be 16 bit register"));
return;
}
break;
case RS8:
if (operand[argn].mode != RS8)
{
as_bad (_("source operand must be 8 bit register"));
return;
}
break;
case ABS16DST:
if (operand[argn].mode != ABS16DST)
{
as_bad (_("destination operand must be 16bit absolute address"));
return;
}
break;
case RD8:
if (operand[argn].mode != RD8)
{
as_bad (_("destination operand must be 8 bit register"));
return;
}
break;
case ABS16SRC:
if (operand[argn].mode != ABS16SRC)
{
as_bad (_("source operand must be 16bit absolute address"));
return;
}
break;
}
}
}
as_bad (_("invalid operands"));
}
/* If OPERAND is part of an address, adjust its size and value given
that it addresses SIZE bytes.
This function decides how big non-immediate constants are when no
size was explicitly given. It also scales down the assembly-level
displacement in an @(d:2,ERn) operand. */
static void
fix_operand_size (struct h8_op *operand, int size)
{
if (SXmode && (operand->mode & MODE) == DISP)
{
/* If the user didn't specify an operand width, see if we
can use @(d:2,ERn). */
if ((operand->mode & SIZE) == 0
&& operand->exp.X_add_symbol == 0
&& operand->exp.X_op_symbol == 0
&& (operand->exp.X_add_number == size
|| operand->exp.X_add_number == size * 2
|| operand->exp.X_add_number == size * 3))
operand->mode |= L_2;
/* Scale down the displacement in an @(d:2,ERn) operand.
X_add_number then contains the desired field value. */
if ((operand->mode & SIZE) == L_2)
{
if (operand->exp.X_add_number % size != 0)
as_warn (_("operand/size mis-match"));
operand->exp.X_add_number /= size;
}
}
if ((operand->mode & SIZE) == 0)
switch (operand->mode & MODE)
{
case DISP:
case INDEXB:
case INDEXW:
case INDEXL:
case ABS:
/* Pick a 24-bit address unless we know that a 16-bit address
is safe. get_specific() will relax L_24 into L_32 where
necessary. */
if (Hmode
&& !Nmode
&& ((((addressT) operand->exp.X_add_number + 0x8000)
& 0xffffffff) > 0xffff
|| operand->exp.X_add_symbol != 0
|| operand->exp.X_op_symbol != 0))
operand->mode |= L_24;
else
operand->mode |= L_16;
break;
case PCREL:
if ((((addressT) operand->exp.X_add_number + 0x80)
& 0xffffffff) <= 0xff)
{
if (operand->exp.X_add_symbol != NULL)
operand->mode |= bsize;
else
operand->mode |= L_8;
}
else
operand->mode |= L_16;
break;
}
}
/* This is the guts of the machine-dependent assembler. STR points to
a machine dependent instruction. This function is supposed to emit
the frags/bytes it assembles. */
void
md_assemble (char *str)
{
char *op_start;
char *op_end;
struct h8_op operand[3];
const struct h8_instruction *instruction;
const struct h8_instruction *prev_instruction;
char *dot = 0;
char *slash = 0;
char c;
int size, i;
/* Drop leading whitespace. */
while (*str == ' ')
str++;
/* Find the op code end. */
for (op_start = op_end = str;
*op_end != 0 && *op_end != ' ';
op_end++)
{
if (*op_end == '.')
{
dot = op_end + 1;
*op_end = 0;
op_end += 2;
break;
}
else if (*op_end == '/' && ! slash)
slash = op_end;
}
if (op_end == op_start)
{
as_bad (_("can't find opcode "));
}
c = *op_end;
*op_end = 0;
/* The assembler stops scanning the opcode at slashes, so it fails
to make characters following them lower case. Fix them. */
if (slash)
while (*++slash)
*slash = TOLOWER (*slash);
instruction = (const struct h8_instruction *)
hash_find (opcode_hash_control, op_start);
if (instruction == NULL)
{
as_bad (_("unknown opcode"));
return;
}
/* We used to set input_line_pointer to the result of get_operands,
but that is wrong. Our caller assumes we don't change it. */
operand[0].mode = 0;
operand[1].mode = 0;
operand[2].mode = 0;
if (OP_KIND (instruction->opcode->how) == O_MOVAB
|| OP_KIND (instruction->opcode->how) == O_MOVAW
|| OP_KIND (instruction->opcode->how) == O_MOVAL)
get_mova_operands (op_end, operand);
else if (OP_KIND (instruction->opcode->how) == O_RTEL
|| OP_KIND (instruction->opcode->how) == O_RTSL)
get_rtsl_operands (op_end, operand);
else
get_operands (instruction->noperands, op_end, operand);
*op_end = c;
prev_instruction = instruction;
/* Now we have operands from instruction.
Let's check them out for ldm and stm. */
if (OP_KIND (instruction->opcode->how) == O_LDM)
{
/* The first operand must be @er7+, and the
second operand must be a register pair. */
if ((operand[0].mode != RSINC)
|| (operand[0].reg != 7)
|| ((operand[1].reg & 0x80000000) == 0))
as_bad (_("invalid operand in ldm"));
}
else if (OP_KIND (instruction->opcode->how) == O_STM)
{
/* The first operand must be a register pair,
and the second operand must be @-er7. */
if (((operand[0].reg & 0x80000000) == 0)
|| (operand[1].mode != RDDEC)
|| (operand[1].reg != 7))
as_bad (_("invalid operand in stm"));
}
size = SN;
if (dot)
{
switch (TOLOWER (*dot))
{
case 'b':
size = SB;
break;
case 'w':
size = SW;
break;
case 'l':
size = SL;
break;
}
}
if (OP_KIND (instruction->opcode->how) == O_MOVAB ||
OP_KIND (instruction->opcode->how) == O_MOVAW ||
OP_KIND (instruction->opcode->how) == O_MOVAL)
{
switch (operand[0].mode & MODE)
{
case INDEXB:
default:
fix_operand_size (&operand[1], 1);
break;
case INDEXW:
fix_operand_size (&operand[1], 2);
break;
case INDEXL:
fix_operand_size (&operand[1], 4);
break;
}
}
else
{
for (i = 0; i < 3 && operand[i].mode != 0; i++)
switch (size)
{
case SN:
case SB:
default:
fix_operand_size (&operand[i], 1);
break;
case SW:
fix_operand_size (&operand[i], 2);
break;
case SL:
fix_operand_size (&operand[i], 4);
break;
}
}
instruction = get_specific (instruction, operand, size);
if (instruction == 0)
{
/* Couldn't find an opcode which matched the operands. */
char *where = frag_more (2);
where[0] = 0x0;
where[1] = 0x0;
clever_message (prev_instruction, operand);
return;
}
build_bytes (instruction, operand);
dwarf2_emit_insn (instruction->length);
}
symbolS *
md_undefined_symbol (char *name ATTRIBUTE_UNUSED)
{
return 0;
}
/* Various routines to kill one day. */
char *
md_atof (int type, char *litP, int *sizeP)
{
return ieee_md_atof (type, litP, sizeP, TRUE);
}
#define OPTION_H_TICK_HEX (OPTION_MD_BASE)
const char *md_shortopts = "";
struct option md_longopts[] = {
{ "h-tick-hex", no_argument, NULL, OPTION_H_TICK_HEX },
{NULL, no_argument, NULL, 0}
};
size_t md_longopts_size = sizeof (md_longopts);
int
md_parse_option (int c ATTRIBUTE_UNUSED, char *arg ATTRIBUTE_UNUSED)
{
switch (c)
{
case OPTION_H_TICK_HEX:
enable_h_tick_hex = 1;
break;
default:
return 0;
}
return 1;
}
void
md_show_usage (FILE *stream ATTRIBUTE_UNUSED)
{
}
void tc_aout_fix_to_chars (void);
void
tc_aout_fix_to_chars (void)
{
printf (_("call to tc_aout_fix_to_chars \n"));
abort ();
}
void
md_convert_frag (bfd *headers ATTRIBUTE_UNUSED,
segT seg ATTRIBUTE_UNUSED,
fragS *fragP ATTRIBUTE_UNUSED)
{
printf (_("call to md_convert_frag \n"));
abort ();
}
valueT
md_section_align (segT segment, valueT size)
{
int align = bfd_get_section_alignment (stdoutput, segment);
return ((size + (1 << align) - 1) & (-1 << align));
}
void
md_apply_fix (fixS *fixP, valueT *valP, segT seg ATTRIBUTE_UNUSED)
{
char *buf = fixP->fx_where + fixP->fx_frag->fr_literal;
long val = *valP;
switch (fixP->fx_size)
{
case 1:
*buf++ = val;
break;
case 2:
*buf++ = (val >> 8);
*buf++ = val;
break;
case 4:
*buf++ = (val >> 24);
*buf++ = (val >> 16);
*buf++ = (val >> 8);
*buf++ = val;
break;
case 8:
/* This can arise when the .quad or .8byte pseudo-ops are used.
Returning here (without setting fx_done) will cause the code
to attempt to generate a reloc which will then fail with the
slightly more helpful error message: "Cannot represent
relocation type BFD_RELOC_64". */
return;
default:
abort ();
}
if (fixP->fx_addsy == NULL && fixP->fx_pcrel == 0)
fixP->fx_done = 1;
}
int
md_estimate_size_before_relax (fragS *fragP ATTRIBUTE_UNUSED,
segT segment_type ATTRIBUTE_UNUSED)
{
printf (_("call to md_estimate_size_before_relax \n"));
abort ();
}
/* Put number into target byte order. */
void
md_number_to_chars (char *ptr, valueT use, int nbytes)
{
number_to_chars_bigendian (ptr, use, nbytes);
}
long
md_pcrel_from (fixS *fixp)
{
as_bad_where (fixp->fx_file, fixp->fx_line,
_("Unexpected reference to a symbol in a non-code section"));
return 0;
}
arelent *
tc_gen_reloc (asection *section ATTRIBUTE_UNUSED, fixS *fixp)
{
arelent *rel;
bfd_reloc_code_real_type r_type;
if (fixp->fx_addsy && fixp->fx_subsy)
{
if ((S_GET_SEGMENT (fixp->fx_addsy) != S_GET_SEGMENT (fixp->fx_subsy))
|| S_GET_SEGMENT (fixp->fx_addsy) == undefined_section)
{
as_bad_where (fixp->fx_file, fixp->fx_line,
_("Difference of symbols in different sections is not supported"));
return NULL;
}
}
rel = xmalloc (sizeof (arelent));
rel->sym_ptr_ptr = xmalloc (sizeof (asymbol *));
*rel->sym_ptr_ptr = symbol_get_bfdsym (fixp->fx_addsy);
rel->address = fixp->fx_frag->fr_address + fixp->fx_where;
rel->addend = fixp->fx_offset;
r_type = fixp->fx_r_type;
#define DEBUG 0
#if DEBUG
fprintf (stderr, "%s\n", bfd_get_reloc_code_name (r_type));
fflush (stderr);
#endif
rel->howto = bfd_reloc_type_lookup (stdoutput, r_type);
if (rel->howto == NULL)
{
as_bad_where (fixp->fx_file, fixp->fx_line,
_("Cannot represent relocation type %s"),
bfd_get_reloc_code_name (r_type));
return NULL;
}
return rel;
}