gas/config/tc-sh.c

1.1  skrll /* tc-sh.c -- Assemble code for the Renesas / SuperH SH
1.1  skrll    Copyright 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000, 2001, 2002,
1.1  skrll    2003, 2004, 2005, 2006, 2007  Free Software Foundation, Inc.
1.1  skrll
1.1  skrll    This file is part of GAS, the GNU Assembler.
1.1  skrll
1.1  skrll    GAS is free software; you can redistribute it and/or modify
1.1  skrll    it under the terms of the GNU General Public License as published by
1.1  skrll    the Free Software Foundation; either version 3, or (at your option)
1.1  skrll    any later version.
1.1  skrll
1.1  skrll    GAS is distributed in the hope that it will be useful,
1.1  skrll    but WITHOUT ANY WARRANTY; without even the implied warranty of
1.1  skrll    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
1.1  skrll    GNU General Public License for more details.
1.1  skrll
1.1  skrll    You should have received a copy of the GNU General Public License
1.1  skrll    along with GAS; see the file COPYING.  If not, write to
1.1  skrll    the Free Software Foundation, 51 Franklin Street - Fifth Floor,
1.1  skrll    Boston, MA 02110-1301, USA.  */
1.1  skrll
1.1  skrll /* Written By Steve Chamberlain <sac (at) cygnus.com>  */
1.1  skrll
1.1  skrll #include "as.h"
1.1  skrll #include "subsegs.h"
1.1  skrll #define DEFINE_TABLE
1.1  skrll #include "opcodes/sh-opc.h"
1.1  skrll #include "safe-ctype.h"
1.1  skrll #include "struc-symbol.h"
1.1  skrll
1.1  skrll #ifdef OBJ_ELF
1.1  skrll #include "elf/sh.h"
1.1  skrll #endif
1.1  skrll
1.1  skrll #include "dwarf2dbg.h"
1.1  skrll #include "dw2gencfi.h"
1.1  skrll
1.1  skrll typedef struct
1.1  skrll   {
1.1  skrll     sh_arg_type type;
1.1  skrll     int reg;
1.1  skrll     expressionS immediate;
1.1  skrll   }
1.1  skrll sh_operand_info;
1.1  skrll
1.1  skrll const char comment_chars[] = "!";
1.1  skrll const char line_separator_chars[] = ";";
1.1  skrll const char line_comment_chars[] = "!#";
1.1  skrll
1.1  skrll static void s_uses (int);
1.1  skrll static void s_uacons (int);
1.1  skrll
1.1  skrll #ifdef OBJ_ELF
1.1  skrll static void sh_elf_cons (int);
1.1  skrll
1.1  skrll symbolS *GOT_symbol;		/* Pre-defined "_GLOBAL_OFFSET_TABLE_" */
1.1  skrll #endif
1.1  skrll
1.1  skrll static void
1.1  skrll big (int ignore ATTRIBUTE_UNUSED)
1.1  skrll {
1.1  skrll   if (! target_big_endian)
1.1  skrll     as_bad (_("directive .big encountered when option -big required"));
1.1  skrll
1.1  skrll   /* Stop further messages.  */
1.1  skrll   target_big_endian = 1;
1.1  skrll }
1.1  skrll
1.1  skrll static void
1.1  skrll little (int ignore ATTRIBUTE_UNUSED)
1.1  skrll {
1.1  skrll   if (target_big_endian)
1.1  skrll     as_bad (_("directive .little encountered when option -little required"));
1.1  skrll
1.1  skrll   /* Stop further messages.  */
1.1  skrll   target_big_endian = 0;
1.1  skrll }
1.1  skrll
1.1  skrll /* This table describes all the machine specific pseudo-ops the assembler
1.1  skrll    has to support.  The fields are:
1.1  skrll    pseudo-op name without dot
1.1  skrll    function to call to execute this pseudo-op
1.1  skrll    Integer arg to pass to the function.  */
1.1  skrll
1.1  skrll const pseudo_typeS md_pseudo_table[] =
1.1  skrll {
1.1  skrll #ifdef OBJ_ELF
1.1  skrll   {"long", sh_elf_cons, 4},
1.1  skrll   {"int", sh_elf_cons, 4},
1.1  skrll   {"word", sh_elf_cons, 2},
1.1  skrll   {"short", sh_elf_cons, 2},
1.1  skrll #else
1.1  skrll   {"int", cons, 4},
1.1  skrll   {"word", cons, 2},
1.1  skrll #endif /* OBJ_ELF */
1.1  skrll   {"big", big, 0},
1.1  skrll   {"form", listing_psize, 0},
1.1  skrll   {"little", little, 0},
1.1  skrll   {"heading", listing_title, 0},
1.1  skrll   {"import", s_ignore, 0},
1.1  skrll   {"page", listing_eject, 0},
1.1  skrll   {"program", s_ignore, 0},
1.1  skrll   {"uses", s_uses, 0},
1.1  skrll   {"uaword", s_uacons, 2},
1.1  skrll   {"ualong", s_uacons, 4},
1.1  skrll   {"uaquad", s_uacons, 8},
1.1  skrll   {"2byte", s_uacons, 2},
1.1  skrll   {"4byte", s_uacons, 4},
1.1  skrll   {"8byte", s_uacons, 8},
1.1  skrll #ifdef HAVE_SH64
1.1  skrll   {"mode", s_sh64_mode, 0 },
1.1  skrll
1.1  skrll   /* Have the old name too.  */
1.1  skrll   {"isa", s_sh64_mode, 0 },
1.1  skrll
1.1  skrll   /* Assert that the right ABI is used.  */
1.1  skrll   {"abi", s_sh64_abi, 0 },
1.1  skrll
1.1  skrll   { "vtable_inherit", sh64_vtable_inherit, 0 },
1.1  skrll   { "vtable_entry", sh64_vtable_entry, 0 },
1.1  skrll #endif /* HAVE_SH64 */
1.1  skrll   {0, 0, 0}
1.1  skrll };
1.1  skrll
1.1  skrll int sh_relax;		/* set if -relax seen */
1.1  skrll
1.1  skrll /* Whether -small was seen.  */
1.1  skrll
1.1  skrll int sh_small;
1.1  skrll
1.1  skrll /* Flag to generate relocations against symbol values for local symbols.  */
1.1  skrll
1.1  skrll static int dont_adjust_reloc_32;
1.1  skrll
1.1  skrll /* Flag to indicate that '$' is allowed as a register prefix.  */
1.1  skrll
1.1  skrll static int allow_dollar_register_prefix;
1.1  skrll
1.1  skrll /* Preset architecture set, if given; zero otherwise.  */
1.1  skrll
1.1  skrll static unsigned int preset_target_arch;
1.1  skrll
1.1  skrll /* The bit mask of architectures that could
1.1  skrll    accommodate the insns seen so far.  */
1.1  skrll static unsigned int valid_arch;
1.1  skrll
1.1  skrll const char EXP_CHARS[] = "eE";
1.1  skrll
1.1  skrll /* Chars that mean this number is a floating point constant.  */
1.1  skrll /* As in 0f12.456 */
1.1  skrll /* or    0d1.2345e12 */
1.1  skrll const char FLT_CHARS[] = "rRsSfFdDxXpP";
1.1  skrll
1.1  skrll #define C(a,b) ENCODE_RELAX(a,b)
1.1  skrll
1.1  skrll #define ENCODE_RELAX(what,length) (((what) << 4) + (length))
1.1  skrll #define GET_WHAT(x) ((x>>4))
1.1  skrll
1.1  skrll /* These are the three types of relaxable instruction.  */
1.1  skrll /* These are the types of relaxable instructions; except for END which is
1.1  skrll    a marker.  */
1.1  skrll #define COND_JUMP 1
1.1  skrll #define COND_JUMP_DELAY 2
1.1  skrll #define UNCOND_JUMP  3
1.1  skrll
1.1  skrll #ifdef HAVE_SH64
1.1  skrll
1.1  skrll /* A 16-bit (times four) pc-relative operand, at most expanded to 32 bits.  */
1.1  skrll #define SH64PCREL16_32 4
1.1  skrll /* A 16-bit (times four) pc-relative operand, at most expanded to 64 bits.  */
1.1  skrll #define SH64PCREL16_64 5
1.1  skrll
1.1  skrll /* Variants of the above for adjusting the insn to PTA or PTB according to
1.1  skrll    the label.  */
1.1  skrll #define SH64PCREL16PT_32 6
1.1  skrll #define SH64PCREL16PT_64 7
1.1  skrll
1.1  skrll /* A MOVI expansion, expanding to at most 32 or 64 bits.  */
1.1  skrll #define MOVI_IMM_32 8
1.1  skrll #define MOVI_IMM_32_PCREL 9
1.1  skrll #define MOVI_IMM_64 10
1.1  skrll #define MOVI_IMM_64_PCREL 11
1.1  skrll #define END 12
1.1  skrll
1.1  skrll #else  /* HAVE_SH64 */
1.1  skrll
1.1  skrll #define END 4
1.1  skrll
1.1  skrll #endif /* HAVE_SH64 */
1.1  skrll
1.1  skrll #define UNDEF_DISP 0
1.1  skrll #define COND8  1
1.1  skrll #define COND12 2
1.1  skrll #define COND32 3
1.1  skrll #define UNDEF_WORD_DISP 4
1.1  skrll
1.1  skrll #define UNCOND12 1
1.1  skrll #define UNCOND32 2
1.1  skrll
1.1  skrll #ifdef HAVE_SH64
1.1  skrll #define UNDEF_SH64PCREL 0
1.1  skrll #define SH64PCREL16 1
1.1  skrll #define SH64PCREL32 2
1.1  skrll #define SH64PCREL48 3
1.1  skrll #define SH64PCREL64 4
1.1  skrll #define SH64PCRELPLT 5
1.1  skrll
1.1  skrll #define UNDEF_MOVI 0
1.1  skrll #define MOVI_16 1
1.1  skrll #define MOVI_32 2
1.1  skrll #define MOVI_48 3
1.1  skrll #define MOVI_64 4
1.1  skrll #define MOVI_PLT 5
1.1  skrll #define MOVI_GOTOFF 6
1.1  skrll #define MOVI_GOTPC 7
1.1  skrll #endif /* HAVE_SH64 */
1.1  skrll
1.1  skrll /* Branch displacements are from the address of the branch plus
1.1  skrll    four, thus all minimum and maximum values have 4 added to them.  */
1.1  skrll #define COND8_F 258
1.1  skrll #define COND8_M -252
1.1  skrll #define COND8_LENGTH 2
1.1  skrll
1.1  skrll /* There is one extra instruction before the branch, so we must add
1.1  skrll    two more bytes to account for it.  */
1.1  skrll #define COND12_F 4100
1.1  skrll #define COND12_M -4090
1.1  skrll #define COND12_LENGTH 6
1.1  skrll
1.1  skrll #define COND12_DELAY_LENGTH 4
1.1  skrll
1.1  skrll /* ??? The minimum and maximum values are wrong, but this does not matter
1.1  skrll    since this relocation type is not supported yet.  */
1.1  skrll #define COND32_F (1<<30)
1.1  skrll #define COND32_M -(1<<30)
1.1  skrll #define COND32_LENGTH 14
1.1  skrll
1.1  skrll #define UNCOND12_F 4098
1.1  skrll #define UNCOND12_M -4092
1.1  skrll #define UNCOND12_LENGTH 2
1.1  skrll
1.1  skrll /* ??? The minimum and maximum values are wrong, but this does not matter
1.1  skrll    since this relocation type is not supported yet.  */
1.1  skrll #define UNCOND32_F (1<<30)
1.1  skrll #define UNCOND32_M -(1<<30)
1.1  skrll #define UNCOND32_LENGTH 14
1.1  skrll
1.1  skrll #ifdef HAVE_SH64
1.1  skrll /* The trivial expansion of a SH64PCREL16 relaxation is just a "PT label,
1.1  skrll    TRd" as is the current insn, so no extra length.  Note that the "reach"
1.1  skrll    is calculated from the address *after* that insn, but the offset in the
1.1  skrll    insn is calculated from the beginning of the insn.  We also need to
1.1  skrll    take into account the implicit 1 coded as the "A" in PTA when counting
1.1  skrll    forward.  If PTB reaches an odd address, we trap that as an error
1.1  skrll    elsewhere, so we don't have to have different relaxation entries.  We
1.1  skrll    don't add a one to the negative range, since PTB would then have the
1.1  skrll    farthest backward-reaching value skipped, not generated at relaxation.  */
1.1  skrll #define SH64PCREL16_F (32767 * 4 - 4 + 1)
1.1  skrll #define SH64PCREL16_M (-32768 * 4 - 4)
1.1  skrll #define SH64PCREL16_LENGTH 0
1.1  skrll
1.1  skrll /* The next step is to change that PT insn into
1.1  skrll      MOVI ((label - datalabel Ln) >> 16) & 65535, R25
1.1  skrll      SHORI (label - datalabel Ln) & 65535, R25
1.1  skrll     Ln:
1.1  skrll      PTREL R25,TRd
1.1  skrll    which means two extra insns, 8 extra bytes.  This is the limit for the
1.1  skrll    32-bit ABI.
1.1  skrll
1.1  skrll    The expressions look a bit bad since we have to adjust this to avoid overflow on a
1.1  skrll    32-bit host.  */
1.1  skrll #define SH64PCREL32_F ((((long) 1 << 30) - 1) * 2 + 1 - 4)
1.1  skrll #define SH64PCREL32_LENGTH (2 * 4)
1.1  skrll
1.1  skrll /* Similarly, we just change the MOVI and add a SHORI for the 48-bit
1.1  skrll    expansion.  */
1.1  skrll #if BFD_HOST_64BIT_LONG
1.1  skrll /* The "reach" type is long, so we can only do this for a 64-bit-long
1.1  skrll    host.  */
1.1  skrll #define SH64PCREL32_M (((long) -1 << 30) * 2 - 4)
1.1  skrll #define SH64PCREL48_F ((((long) 1 << 47) - 1) - 4)
1.1  skrll #define SH64PCREL48_M (((long) -1 << 47) - 4)
1.1  skrll #define SH64PCREL48_LENGTH (3 * 4)
1.1  skrll #else
1.1  skrll /* If the host does not have 64-bit longs, just make this state identical
1.1  skrll    in reach to the 32-bit state.  Note that we have a slightly incorrect
1.1  skrll    reach, but the correct one above will overflow a 32-bit number.  */
1.1  skrll #define SH64PCREL32_M (((long) -1 << 30) * 2)
1.1  skrll #define SH64PCREL48_F SH64PCREL32_F
1.1  skrll #define SH64PCREL48_M SH64PCREL32_M
1.1  skrll #define SH64PCREL48_LENGTH (3 * 4)
1.1  skrll #endif /* BFD_HOST_64BIT_LONG */
1.1  skrll
1.1  skrll /* And similarly for the 64-bit expansion; a MOVI + SHORI + SHORI + SHORI
1.1  skrll    + PTREL sequence.  */
1.1  skrll #define SH64PCREL64_LENGTH (4 * 4)
1.1  skrll
1.1  skrll /* For MOVI, we make the MOVI + SHORI... expansion you can see in the
1.1  skrll    SH64PCREL expansions.  The PCREL one is similar, but the other has no
1.1  skrll    pc-relative reach; it must be fully expanded in
1.1  skrll    shmedia_md_estimate_size_before_relax.  */
1.1  skrll #define MOVI_16_LENGTH 0
1.1  skrll #define MOVI_16_F (32767 - 4)
1.1  skrll #define MOVI_16_M (-32768 - 4)
1.1  skrll #define MOVI_32_LENGTH 4
1.1  skrll #define MOVI_32_F ((((long) 1 << 30) - 1) * 2 + 1 - 4)
1.1  skrll #define MOVI_48_LENGTH 8
1.1  skrll
1.1  skrll #if BFD_HOST_64BIT_LONG
1.1  skrll /* The "reach" type is long, so we can only do this for a 64-bit-long
1.1  skrll    host.  */
1.1  skrll #define MOVI_32_M (((long) -1 << 30) * 2 - 4)
1.1  skrll #define MOVI_48_F ((((long) 1 << 47) - 1) - 4)
1.1  skrll #define MOVI_48_M (((long) -1 << 47) - 4)
1.1  skrll #else
1.1  skrll /* If the host does not have 64-bit longs, just make this state identical
1.1  skrll    in reach to the 32-bit state.  Note that we have a slightly incorrect
1.1  skrll    reach, but the correct one above will overflow a 32-bit number.  */
1.1  skrll #define MOVI_32_M (((long) -1 << 30) * 2)
1.1  skrll #define MOVI_48_F MOVI_32_F
1.1  skrll #define MOVI_48_M MOVI_32_M
1.1  skrll #endif /* BFD_HOST_64BIT_LONG */
1.1  skrll
1.1  skrll #define MOVI_64_LENGTH 12
1.1  skrll #endif /* HAVE_SH64 */
1.1  skrll
1.1  skrll #define EMPTY { 0, 0, 0, 0 }
1.1  skrll
1.1  skrll const relax_typeS md_relax_table[C (END, 0)] = {
1.1  skrll   EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY,
1.1  skrll   EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY,
1.1  skrll
1.1  skrll   EMPTY,
1.1  skrll   /* C (COND_JUMP, COND8) */
1.1  skrll   { COND8_F, COND8_M, COND8_LENGTH, C (COND_JUMP, COND12) },
1.1  skrll   /* C (COND_JUMP, COND12) */
1.1  skrll   { COND12_F, COND12_M, COND12_LENGTH, C (COND_JUMP, COND32), },
1.1  skrll   /* C (COND_JUMP, COND32) */
1.1  skrll   { COND32_F, COND32_M, COND32_LENGTH, 0, },
1.1  skrll   /* C (COND_JUMP, UNDEF_WORD_DISP) */
1.1  skrll   { 0, 0, COND32_LENGTH, 0, },
1.1  skrll   EMPTY, EMPTY, EMPTY,
1.1  skrll   EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY,
1.1  skrll
1.1  skrll   EMPTY,
1.1  skrll   /* C (COND_JUMP_DELAY, COND8) */
1.1  skrll   { COND8_F, COND8_M, COND8_LENGTH, C (COND_JUMP_DELAY, COND12) },
1.1  skrll   /* C (COND_JUMP_DELAY, COND12) */
1.1  skrll   { COND12_F, COND12_M, COND12_DELAY_LENGTH, C (COND_JUMP_DELAY, COND32), },
1.1  skrll   /* C (COND_JUMP_DELAY, COND32) */
1.1  skrll   { COND32_F, COND32_M, COND32_LENGTH, 0, },
1.1  skrll   /* C (COND_JUMP_DELAY, UNDEF_WORD_DISP) */
1.1  skrll   { 0, 0, COND32_LENGTH, 0, },
1.1  skrll   EMPTY, EMPTY, EMPTY,
1.1  skrll   EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY,
1.1  skrll
1.1  skrll   EMPTY,
1.1  skrll   /* C (UNCOND_JUMP, UNCOND12) */
1.1  skrll   { UNCOND12_F, UNCOND12_M, UNCOND12_LENGTH, C (UNCOND_JUMP, UNCOND32), },
1.1  skrll   /* C (UNCOND_JUMP, UNCOND32) */
1.1  skrll   { UNCOND32_F, UNCOND32_M, UNCOND32_LENGTH, 0, },
1.1  skrll   EMPTY,
1.1  skrll   /* C (UNCOND_JUMP, UNDEF_WORD_DISP) */
1.1  skrll   { 0, 0, UNCOND32_LENGTH, 0, },
1.1  skrll   EMPTY, EMPTY, EMPTY,
1.1  skrll   EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY,
1.1  skrll
1.1  skrll #ifdef HAVE_SH64
1.1  skrll   /* C (SH64PCREL16_32, SH64PCREL16) */
1.1  skrll   EMPTY,
1.1  skrll   { SH64PCREL16_F, SH64PCREL16_M, SH64PCREL16_LENGTH, C (SH64PCREL16_32, SH64PCREL32) },
1.1  skrll   /* C (SH64PCREL16_32, SH64PCREL32) */
1.1  skrll   { 0, 0, SH64PCREL32_LENGTH, 0 },
1.1  skrll   EMPTY, EMPTY,
1.1  skrll   /* C (SH64PCREL16_32, SH64PCRELPLT) */
1.1  skrll   { 0, 0, SH64PCREL32_LENGTH, 0 },
1.1  skrll   EMPTY, EMPTY,
1.1  skrll   EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY,
1.1  skrll
1.1  skrll   /* C (SH64PCREL16_64, SH64PCREL16) */
1.1  skrll   EMPTY,
1.1  skrll   { SH64PCREL16_F, SH64PCREL16_M, SH64PCREL16_LENGTH, C (SH64PCREL16_64, SH64PCREL32) },
1.1  skrll   /* C (SH64PCREL16_64, SH64PCREL32) */
1.1  skrll   { SH64PCREL32_F, SH64PCREL32_M, SH64PCREL32_LENGTH, C (SH64PCREL16_64, SH64PCREL48) },
1.1  skrll   /* C (SH64PCREL16_64, SH64PCREL48) */
1.1  skrll   { SH64PCREL48_F, SH64PCREL48_M, SH64PCREL48_LENGTH, C (SH64PCREL16_64, SH64PCREL64) },
1.1  skrll   /* C (SH64PCREL16_64, SH64PCREL64) */
1.1  skrll   { 0, 0, SH64PCREL64_LENGTH, 0 },
1.1  skrll   /* C (SH64PCREL16_64, SH64PCRELPLT) */
1.1  skrll   { 0, 0, SH64PCREL64_LENGTH, 0 },
1.1  skrll   EMPTY, EMPTY,
1.1  skrll   EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY,
1.1  skrll
1.1  skrll   /* C (SH64PCREL16PT_32, SH64PCREL16) */
1.1  skrll   EMPTY,
1.1  skrll   { SH64PCREL16_F, SH64PCREL16_M, SH64PCREL16_LENGTH, C (SH64PCREL16PT_32, SH64PCREL32) },
1.1  skrll   /* C (SH64PCREL16PT_32, SH64PCREL32) */
1.1  skrll   { 0, 0, SH64PCREL32_LENGTH, 0 },
1.1  skrll   EMPTY, EMPTY,
1.1  skrll   /* C (SH64PCREL16PT_32, SH64PCRELPLT) */
1.1  skrll   { 0, 0, SH64PCREL32_LENGTH, 0 },
1.1  skrll   EMPTY, EMPTY,
1.1  skrll   EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY,
1.1  skrll
1.1  skrll   /* C (SH64PCREL16PT_64, SH64PCREL16) */
1.1  skrll   EMPTY,
1.1  skrll   { SH64PCREL16_F, SH64PCREL16_M, SH64PCREL16_LENGTH, C (SH64PCREL16PT_64, SH64PCREL32) },
1.1  skrll   /* C (SH64PCREL16PT_64, SH64PCREL32) */
1.1  skrll   { SH64PCREL32_F,
1.1  skrll     SH64PCREL32_M,
1.1  skrll     SH64PCREL32_LENGTH,
1.1  skrll     C (SH64PCREL16PT_64, SH64PCREL48) },
1.1  skrll   /* C (SH64PCREL16PT_64, SH64PCREL48) */
1.1  skrll   { SH64PCREL48_F, SH64PCREL48_M, SH64PCREL48_LENGTH, C (SH64PCREL16PT_64, SH64PCREL64) },
1.1  skrll   /* C (SH64PCREL16PT_64, SH64PCREL64) */
1.1  skrll   { 0, 0, SH64PCREL64_LENGTH, 0 },
1.1  skrll   /* C (SH64PCREL16PT_64, SH64PCRELPLT) */
1.1  skrll   { 0, 0, SH64PCREL64_LENGTH, 0},
1.1  skrll   EMPTY, EMPTY,
1.1  skrll   EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY,
1.1  skrll
1.1  skrll   /* C (MOVI_IMM_32, UNDEF_MOVI) */
1.1  skrll   { 0, 0, MOVI_32_LENGTH, 0 },
1.1  skrll   /* C (MOVI_IMM_32, MOVI_16) */
1.1  skrll   { MOVI_16_F, MOVI_16_M, MOVI_16_LENGTH, C (MOVI_IMM_32, MOVI_32) },
1.1  skrll   /* C (MOVI_IMM_32, MOVI_32) */
1.1  skrll   { MOVI_32_F, MOVI_32_M, MOVI_32_LENGTH, 0 },
1.1  skrll   EMPTY, EMPTY, EMPTY,
1.1  skrll   /* C (MOVI_IMM_32, MOVI_GOTOFF) */
1.1  skrll   { 0, 0, MOVI_32_LENGTH, 0 },
1.1  skrll   EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY,
1.1  skrll
1.1  skrll   /* C (MOVI_IMM_32_PCREL, MOVI_16) */
1.1  skrll   EMPTY,
1.1  skrll   { MOVI_16_F, MOVI_16_M, MOVI_16_LENGTH, C (MOVI_IMM_32_PCREL, MOVI_32) },
1.1  skrll   /* C (MOVI_IMM_32_PCREL, MOVI_32) */
1.1  skrll   { 0, 0, MOVI_32_LENGTH, 0 },
1.1  skrll   EMPTY, EMPTY,
1.1  skrll   /* C (MOVI_IMM_32_PCREL, MOVI_PLT) */
1.1  skrll   { 0, 0, MOVI_32_LENGTH, 0 },
1.1  skrll   EMPTY,
1.1  skrll   /* C (MOVI_IMM_32_PCREL, MOVI_GOTPC) */
1.1  skrll   { 0, 0, MOVI_32_LENGTH, 0 },
1.1  skrll   EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY,
1.1  skrll
1.1  skrll   /* C (MOVI_IMM_64, UNDEF_MOVI) */
1.1  skrll   { 0, 0, MOVI_64_LENGTH, 0 },
1.1  skrll   /* C (MOVI_IMM_64, MOVI_16) */
1.1  skrll   { MOVI_16_F, MOVI_16_M, MOVI_16_LENGTH, C (MOVI_IMM_64, MOVI_32) },
1.1  skrll   /* C (MOVI_IMM_64, MOVI_32) */
1.1  skrll   { MOVI_32_F, MOVI_32_M, MOVI_32_LENGTH, C (MOVI_IMM_64, MOVI_48) },
1.1  skrll   /* C (MOVI_IMM_64, MOVI_48) */
1.1  skrll   { MOVI_48_F, MOVI_48_M, MOVI_48_LENGTH, C (MOVI_IMM_64, MOVI_64) },
1.1  skrll   /* C (MOVI_IMM_64, MOVI_64) */
1.1  skrll   { 0, 0, MOVI_64_LENGTH, 0 },
1.1  skrll   EMPTY,
1.1  skrll   /* C (MOVI_IMM_64, MOVI_GOTOFF) */
1.1  skrll   { 0, 0, MOVI_64_LENGTH, 0 },
1.1  skrll   EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY,
1.1  skrll
1.1  skrll   /* C (MOVI_IMM_64_PCREL, MOVI_16) */
1.1  skrll   EMPTY,
1.1  skrll   { MOVI_16_F, MOVI_16_M, MOVI_16_LENGTH, C (MOVI_IMM_64_PCREL, MOVI_32) },
1.1  skrll   /* C (MOVI_IMM_64_PCREL, MOVI_32) */
1.1  skrll   { MOVI_32_F, MOVI_32_M, MOVI_32_LENGTH, C (MOVI_IMM_64_PCREL, MOVI_48) },
1.1  skrll   /* C (MOVI_IMM_64_PCREL, MOVI_48) */
1.1  skrll   { MOVI_48_F, MOVI_48_M, MOVI_48_LENGTH, C (MOVI_IMM_64_PCREL, MOVI_64) },
1.1  skrll   /* C (MOVI_IMM_64_PCREL, MOVI_64) */
1.1  skrll   { 0, 0, MOVI_64_LENGTH, 0 },
1.1  skrll   /* C (MOVI_IMM_64_PCREL, MOVI_PLT) */
1.1  skrll   { 0, 0, MOVI_64_LENGTH, 0 },
1.1  skrll   EMPTY,
1.1  skrll   /* C (MOVI_IMM_64_PCREL, MOVI_GOTPC) */
1.1  skrll   { 0, 0, MOVI_64_LENGTH, 0 },
1.1  skrll   EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY, EMPTY,
1.1  skrll
1.1  skrll #endif /* HAVE_SH64 */
1.1  skrll
1.1  skrll };
1.1  skrll
1.1  skrll #undef EMPTY
1.1  skrll
1.1  skrll static struct hash_control *opcode_hash_control;	/* Opcode mnemonics */
1.1  skrll
1.1  skrll
1.1  skrll #ifdef OBJ_ELF
1.1  skrll /* Determinet whether the symbol needs any kind of PIC relocation.  */
1.1  skrll
1.1  skrll inline static int
1.1  skrll sh_PIC_related_p (symbolS *sym)
1.1  skrll {
1.1  skrll   expressionS *exp;
1.1  skrll
1.1  skrll   if (! sym)
1.1  skrll     return 0;
1.1  skrll
1.1  skrll   if (sym == GOT_symbol)
1.1  skrll     return 1;
1.1  skrll
1.1  skrll #ifdef HAVE_SH64
1.1  skrll   if (sh_PIC_related_p (*symbol_get_tc (sym)))
1.1  skrll     return 1;
1.1  skrll #endif
1.1  skrll
1.1  skrll   exp = symbol_get_value_expression (sym);
1.1  skrll
1.1  skrll   return (exp->X_op == O_PIC_reloc
1.1  skrll 	  || sh_PIC_related_p (exp->X_add_symbol)
1.1  skrll 	  || sh_PIC_related_p (exp->X_op_symbol));
1.1  skrll }
1.1  skrll
1.1  skrll /* Determine the relocation type to be used to represent the
1.1  skrll    expression, that may be rearranged.  */
1.1  skrll
1.1  skrll static int
1.1  skrll sh_check_fixup (expressionS *main_exp, bfd_reloc_code_real_type *r_type_p)
1.1  skrll {
1.1  skrll   expressionS *exp = main_exp;
1.1  skrll
1.1  skrll   /* This is here for backward-compatibility only.  GCC used to generated:
1.1  skrll
1.1  skrll 	f@PLT + . - (.LPCS# + 2)
1.1  skrll
1.1  skrll      but we'd rather be able to handle this as a PIC-related reference
1.1  skrll      plus/minus a symbol.  However, gas' parser gives us:
1.1  skrll
1.1  skrll 	O_subtract (O_add (f@PLT, .), .LPCS#+2)
1.1  skrll
1.1  skrll      so we attempt to transform this into:
1.1  skrll
1.1  skrll         O_subtract (f@PLT, O_subtract (.LPCS#+2, .))
1.1  skrll
1.1  skrll      which we can handle simply below.  */
1.1  skrll   if (exp->X_op == O_subtract)
1.1  skrll     {
1.1  skrll       if (sh_PIC_related_p (exp->X_op_symbol))
1.1  skrll 	return 1;
1.1  skrll
1.1  skrll       exp = symbol_get_value_expression (exp->X_add_symbol);
1.1  skrll
1.1  skrll       if (exp && sh_PIC_related_p (exp->X_op_symbol))
1.1  skrll 	return 1;
1.1  skrll
1.1  skrll       if (exp && exp->X_op == O_add
1.1  skrll 	  && sh_PIC_related_p (exp->X_add_symbol))
1.1  skrll 	{
1.1  skrll 	  symbolS *sym = exp->X_add_symbol;
1.1  skrll
1.1  skrll 	  exp->X_op = O_subtract;
1.1  skrll 	  exp->X_add_symbol = main_exp->X_op_symbol;
1.1  skrll
1.1  skrll 	  main_exp->X_op_symbol = main_exp->X_add_symbol;
1.1  skrll 	  main_exp->X_add_symbol = sym;
1.1  skrll
1.1  skrll 	  main_exp->X_add_number += exp->X_add_number;
1.1  skrll 	  exp->X_add_number = 0;
1.1  skrll 	}
1.1  skrll
1.1  skrll       exp = main_exp;
1.1  skrll     }
1.1  skrll   else if (exp->X_op == O_add && sh_PIC_related_p (exp->X_op_symbol))
1.1  skrll     return 1;
1.1  skrll
1.1  skrll   if (exp->X_op == O_symbol || exp->X_op == O_add || exp->X_op == O_subtract)
1.1  skrll     {
1.1  skrll #ifdef HAVE_SH64
1.1  skrll       if (exp->X_add_symbol
1.1  skrll 	  && (exp->X_add_symbol == GOT_symbol
1.1  skrll 	      || (GOT_symbol
1.1  skrll 		  && *symbol_get_tc (exp->X_add_symbol) == GOT_symbol)))
1.1  skrll 	{
1.1  skrll 	  switch (*r_type_p)
1.1  skrll 	    {
1.1  skrll 	    case BFD_RELOC_SH_IMM_LOW16:
1.1  skrll 	      *r_type_p = BFD_RELOC_SH_GOTPC_LOW16;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case BFD_RELOC_SH_IMM_MEDLOW16:
1.1  skrll 	      *r_type_p = BFD_RELOC_SH_GOTPC_MEDLOW16;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case BFD_RELOC_SH_IMM_MEDHI16:
1.1  skrll 	      *r_type_p = BFD_RELOC_SH_GOTPC_MEDHI16;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case BFD_RELOC_SH_IMM_HI16:
1.1  skrll 	      *r_type_p = BFD_RELOC_SH_GOTPC_HI16;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case BFD_RELOC_NONE:
1.1  skrll 	    case BFD_RELOC_UNUSED:
1.1  skrll 	      *r_type_p = BFD_RELOC_SH_GOTPC;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    default:
1.1  skrll 	      abort ();
1.1  skrll 	    }
1.1  skrll 	  return 0;
1.1  skrll 	}
1.1  skrll #else
1.1  skrll       if (exp->X_add_symbol && exp->X_add_symbol == GOT_symbol)
1.1  skrll 	{
1.1  skrll 	  *r_type_p = BFD_RELOC_SH_GOTPC;
1.1  skrll 	  return 0;
1.1  skrll 	}
1.1  skrll #endif
1.1  skrll       exp = symbol_get_value_expression (exp->X_add_symbol);
1.1  skrll       if (! exp)
1.1  skrll 	return 0;
1.1  skrll     }
1.1  skrll
1.1  skrll   if (exp->X_op == O_PIC_reloc)
1.1  skrll     {
1.1  skrll #ifdef HAVE_SH64
1.1  skrll       switch (*r_type_p)
1.1  skrll 	{
1.1  skrll 	case BFD_RELOC_NONE:
1.1  skrll 	case BFD_RELOC_UNUSED:
1.1  skrll 	  *r_type_p = exp->X_md;
1.1  skrll 	  break;
1.1  skrll
1.1  skrll 	case BFD_RELOC_SH_IMM_LOW16:
1.1  skrll 	  switch (exp->X_md)
1.1  skrll 	    {
1.1  skrll 	    case BFD_RELOC_32_GOTOFF:
1.1  skrll 	      *r_type_p = BFD_RELOC_SH_GOTOFF_LOW16;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case BFD_RELOC_SH_GOTPLT32:
1.1  skrll 	      *r_type_p = BFD_RELOC_SH_GOTPLT_LOW16;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case BFD_RELOC_32_GOT_PCREL:
1.1  skrll 	      *r_type_p = BFD_RELOC_SH_GOT_LOW16;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case BFD_RELOC_32_PLT_PCREL:
1.1  skrll 	      *r_type_p = BFD_RELOC_SH_PLT_LOW16;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    default:
1.1  skrll 	      abort ();
1.1  skrll 	    }
1.1  skrll 	  break;
1.1  skrll
1.1  skrll 	case BFD_RELOC_SH_IMM_MEDLOW16:
1.1  skrll 	  switch (exp->X_md)
1.1  skrll 	    {
1.1  skrll 	    case BFD_RELOC_32_GOTOFF:
1.1  skrll 	      *r_type_p = BFD_RELOC_SH_GOTOFF_MEDLOW16;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case BFD_RELOC_SH_GOTPLT32:
1.1  skrll 	      *r_type_p = BFD_RELOC_SH_GOTPLT_MEDLOW16;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case BFD_RELOC_32_GOT_PCREL:
1.1  skrll 	      *r_type_p = BFD_RELOC_SH_GOT_MEDLOW16;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case BFD_RELOC_32_PLT_PCREL:
1.1  skrll 	      *r_type_p = BFD_RELOC_SH_PLT_MEDLOW16;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    default:
1.1  skrll 	      abort ();
1.1  skrll 	    }
1.1  skrll 	  break;
1.1  skrll
1.1  skrll 	case BFD_RELOC_SH_IMM_MEDHI16:
1.1  skrll 	  switch (exp->X_md)
1.1  skrll 	    {
1.1  skrll 	    case BFD_RELOC_32_GOTOFF:
1.1  skrll 	      *r_type_p = BFD_RELOC_SH_GOTOFF_MEDHI16;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case BFD_RELOC_SH_GOTPLT32:
1.1  skrll 	      *r_type_p = BFD_RELOC_SH_GOTPLT_MEDHI16;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case BFD_RELOC_32_GOT_PCREL:
1.1  skrll 	      *r_type_p = BFD_RELOC_SH_GOT_MEDHI16;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case BFD_RELOC_32_PLT_PCREL:
1.1  skrll 	      *r_type_p = BFD_RELOC_SH_PLT_MEDHI16;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    default:
1.1  skrll 	      abort ();
1.1  skrll 	    }
1.1  skrll 	  break;
1.1  skrll
1.1  skrll 	case BFD_RELOC_SH_IMM_HI16:
1.1  skrll 	  switch (exp->X_md)
1.1  skrll 	    {
1.1  skrll 	    case BFD_RELOC_32_GOTOFF:
1.1  skrll 	      *r_type_p = BFD_RELOC_SH_GOTOFF_HI16;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case BFD_RELOC_SH_GOTPLT32:
1.1  skrll 	      *r_type_p = BFD_RELOC_SH_GOTPLT_HI16;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case BFD_RELOC_32_GOT_PCREL:
1.1  skrll 	      *r_type_p = BFD_RELOC_SH_GOT_HI16;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case BFD_RELOC_32_PLT_PCREL:
1.1  skrll 	      *r_type_p = BFD_RELOC_SH_PLT_HI16;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    default:
1.1  skrll 	      abort ();
1.1  skrll 	    }
1.1  skrll 	  break;
1.1  skrll
1.1  skrll 	default:
1.1  skrll 	  abort ();
1.1  skrll 	}
1.1  skrll #else
1.1  skrll       *r_type_p = exp->X_md;
1.1  skrll #endif
1.1  skrll       if (exp == main_exp)
1.1  skrll 	exp->X_op = O_symbol;
1.1  skrll       else
1.1  skrll 	{
1.1  skrll 	  main_exp->X_add_symbol = exp->X_add_symbol;
1.1  skrll 	  main_exp->X_add_number += exp->X_add_number;
1.1  skrll 	}
1.1  skrll     }
1.1  skrll   else
1.1  skrll     return (sh_PIC_related_p (exp->X_add_symbol)
1.1  skrll 	    || sh_PIC_related_p (exp->X_op_symbol));
1.1  skrll
1.1  skrll   return 0;
1.1  skrll }
1.1  skrll
1.1  skrll /* Add expression EXP of SIZE bytes to offset OFF of fragment FRAG.  */
1.1  skrll
1.1  skrll void
1.1  skrll sh_cons_fix_new (fragS *frag, int off, int size, expressionS *exp)
1.1  skrll {
1.1  skrll   bfd_reloc_code_real_type r_type = BFD_RELOC_UNUSED;
1.1  skrll
1.1  skrll   if (sh_check_fixup (exp, &r_type))
1.1  skrll     as_bad (_("Invalid PIC expression."));
1.1  skrll
1.1  skrll   if (r_type == BFD_RELOC_UNUSED)
1.1  skrll     switch (size)
1.1  skrll       {
1.1  skrll       case 1:
1.1  skrll 	r_type = BFD_RELOC_8;
1.1  skrll 	break;
1.1  skrll
1.1  skrll       case 2:
1.1  skrll 	r_type = BFD_RELOC_16;
1.1  skrll 	break;
1.1  skrll
1.1  skrll       case 4:
1.1  skrll 	r_type = BFD_RELOC_32;
1.1  skrll 	break;
1.1  skrll
1.1  skrll #ifdef HAVE_SH64
1.1  skrll       case 8:
1.1  skrll 	r_type = BFD_RELOC_64;
1.1  skrll 	break;
1.1  skrll #endif
1.1  skrll
1.1  skrll       default:
1.1  skrll 	goto error;
1.1  skrll       }
1.1  skrll   else if (size != 4)
1.1  skrll     {
1.1  skrll     error:
1.1  skrll       as_bad (_("unsupported BFD relocation size %u"), size);
1.1  skrll       r_type = BFD_RELOC_UNUSED;
1.1  skrll     }
1.1  skrll
1.1  skrll   fix_new_exp (frag, off, size, exp, 0, r_type);
1.1  skrll }
1.1  skrll
1.1  skrll /* The regular cons() function, that reads constants, doesn't support
1.1  skrll    suffixes such as @GOT, @GOTOFF and @PLT, that generate
1.1  skrll    machine-specific relocation types.  So we must define it here.  */
1.1  skrll /* Clobbers input_line_pointer, checks end-of-line.  */
1.1  skrll /* NBYTES 1=.byte, 2=.word, 4=.long */
1.1  skrll static void
1.1  skrll sh_elf_cons (register int nbytes)
1.1  skrll {
1.1  skrll   expressionS exp;
1.1  skrll
1.1  skrll #ifdef HAVE_SH64
1.1  skrll
1.1  skrll   /* Update existing range to include a previous insn, if there was one.  */
1.1  skrll   sh64_update_contents_mark (TRUE);
1.1  skrll
1.1  skrll   /* We need to make sure the contents type is set to data.  */
1.1  skrll   sh64_flag_output ();
1.1  skrll
1.1  skrll #endif /* HAVE_SH64 */
1.1  skrll
1.1  skrll   if (is_it_end_of_statement ())
1.1  skrll     {
1.1  skrll       demand_empty_rest_of_line ();
1.1  skrll       return;
1.1  skrll     }
1.1  skrll
1.1  skrll #ifdef md_cons_align
1.1  skrll   md_cons_align (nbytes);
1.1  skrll #endif
1.1  skrll
1.1  skrll   do
1.1  skrll     {
1.1  skrll       expression (&exp);
1.1  skrll       emit_expr (&exp, (unsigned int) nbytes);
1.1  skrll     }
1.1  skrll   while (*input_line_pointer++ == ',');
1.1  skrll
1.1  skrll   input_line_pointer--;		/* Put terminator back into stream.  */
1.1  skrll   if (*input_line_pointer == '#' || *input_line_pointer == '!')
1.1  skrll     {
1.1  skrll        while (! is_end_of_line[(unsigned char) *input_line_pointer++]);
1.1  skrll     }
1.1  skrll   else
1.1  skrll     demand_empty_rest_of_line ();
1.1  skrll }
1.1  skrll
1.1  skrll /* The regular frag_offset_fixed_p doesn't work for rs_align_test
1.1  skrll    frags.  */
1.1  skrll
1.1  skrll static bfd_boolean
1.1  skrll align_test_frag_offset_fixed_p (const fragS *frag1, const fragS *frag2,
1.1  skrll 				bfd_vma *offset)
1.1  skrll {
1.1  skrll   const fragS *frag;
1.1  skrll   bfd_vma off;
1.1  skrll
1.1  skrll   /* Start with offset initialised to difference between the two frags.
1.1  skrll      Prior to assigning frag addresses this will be zero.  */
1.1  skrll   off = frag1->fr_address - frag2->fr_address;
1.1  skrll   if (frag1 == frag2)
1.1  skrll     {
1.1  skrll       *offset = off;
1.1  skrll       return TRUE;
1.1  skrll     }
1.1  skrll
1.1  skrll   /* Maybe frag2 is after frag1.  */
1.1  skrll   frag = frag1;
1.1  skrll   while (frag->fr_type == rs_fill
1.1  skrll 	 || frag->fr_type == rs_align_test)
1.1  skrll     {
1.1  skrll       if (frag->fr_type == rs_fill)
1.1  skrll 	off += frag->fr_fix + frag->fr_offset * frag->fr_var;
1.1  skrll       else
1.1  skrll 	off += frag->fr_fix;
1.1  skrll       frag = frag->fr_next;
1.1  skrll       if (frag == NULL)
1.1  skrll 	break;
1.1  skrll       if (frag == frag2)
1.1  skrll 	{
1.1  skrll 	  *offset = off;
1.1  skrll 	  return TRUE;
1.1  skrll 	}
1.1  skrll     }
1.1  skrll
1.1  skrll   /* Maybe frag1 is after frag2.  */
1.1  skrll   off = frag1->fr_address - frag2->fr_address;
1.1  skrll   frag = frag2;
1.1  skrll   while (frag->fr_type == rs_fill
1.1  skrll 	 || frag->fr_type == rs_align_test)
1.1  skrll     {
1.1  skrll       if (frag->fr_type == rs_fill)
1.1  skrll 	off -= frag->fr_fix + frag->fr_offset * frag->fr_var;
1.1  skrll       else
1.1  skrll 	off -= frag->fr_fix;
1.1  skrll       frag = frag->fr_next;
1.1  skrll       if (frag == NULL)
1.1  skrll 	break;
1.1  skrll       if (frag == frag1)
1.1  skrll 	{
1.1  skrll 	  *offset = off;
1.1  skrll 	  return TRUE;
1.1  skrll 	}
1.1  skrll     }
1.1  skrll
1.1  skrll   return FALSE;
1.1  skrll }
1.1  skrll
1.1  skrll /* Optimize a difference of symbols which have rs_align_test frag if
1.1  skrll    possible.  */
1.1  skrll
1.1  skrll int
1.1  skrll sh_optimize_expr (expressionS *l, operatorT op, expressionS *r)
1.1  skrll {
1.1  skrll   bfd_vma frag_off;
1.1  skrll
1.1  skrll   if (op == O_subtract
1.1  skrll       && l->X_op == O_symbol
1.1  skrll       && r->X_op == O_symbol
1.1  skrll       && S_GET_SEGMENT (l->X_add_symbol) == S_GET_SEGMENT (r->X_add_symbol)
1.1  skrll       && (SEG_NORMAL (S_GET_SEGMENT (l->X_add_symbol))
1.1  skrll 	  || r->X_add_symbol == l->X_add_symbol)
1.1  skrll       && align_test_frag_offset_fixed_p (symbol_get_frag (l->X_add_symbol),
1.1  skrll 					 symbol_get_frag (r->X_add_symbol),
1.1  skrll 					 &frag_off))
1.1  skrll     {
1.1  skrll       l->X_add_number -= r->X_add_number;
1.1  skrll       l->X_add_number -= frag_off / OCTETS_PER_BYTE;
1.1  skrll       l->X_add_number += (S_GET_VALUE (l->X_add_symbol)
1.1  skrll 			  - S_GET_VALUE (r->X_add_symbol));
1.1  skrll       l->X_op = O_constant;
1.1  skrll       l->X_add_symbol = 0;
1.1  skrll       return 1;
1.1  skrll     }
1.1  skrll   return 0;
1.1  skrll }
1.1  skrll #endif /* OBJ_ELF */
1.1  skrll
1.1  skrll /* This function is called once, at assembler startup time.  This should
1.1  skrll    set up all the tables, etc that the MD part of the assembler needs.  */
1.1  skrll
1.1  skrll void
1.1  skrll md_begin (void)
1.1  skrll {
1.1  skrll   const sh_opcode_info *opcode;
1.1  skrll   char *prev_name = "";
1.1  skrll   unsigned int target_arch;
1.1  skrll
1.1  skrll   target_arch
1.1  skrll     = preset_target_arch ? preset_target_arch : arch_sh_up & ~arch_sh_has_dsp;
1.1  skrll   valid_arch = target_arch;
1.1  skrll
1.1  skrll #ifdef HAVE_SH64
1.1  skrll   shmedia_md_begin ();
1.1  skrll #endif
1.1  skrll
1.1  skrll   opcode_hash_control = hash_new ();
1.1  skrll
1.1  skrll   /* Insert unique names into hash table.  */
1.1  skrll   for (opcode = sh_table; opcode->name; opcode++)
1.1  skrll     {
1.1  skrll       if (strcmp (prev_name, opcode->name) != 0)
1.1  skrll 	{
1.1  skrll 	  if (!SH_MERGE_ARCH_SET_VALID (opcode->arch, target_arch))
1.1  skrll 	    continue;
1.1  skrll 	  prev_name = opcode->name;
1.1  skrll 	  hash_insert (opcode_hash_control, opcode->name, (char *) opcode);
1.1  skrll 	}
1.1  skrll     }
1.1  skrll }
1.1  skrll
1.1  skrll static int reg_m;
1.1  skrll static int reg_n;
1.1  skrll static int reg_x, reg_y;
1.1  skrll static int reg_efg;
1.1  skrll static int reg_b;
1.1  skrll
1.1  skrll #define IDENT_CHAR(c) (ISALNUM (c) || (c) == '_')
1.1  skrll
1.1  skrll /* Try to parse a reg name.  Return the number of chars consumed.  */
1.1  skrll
1.1  skrll static unsigned int
1.1  skrll parse_reg_without_prefix (char *src, int *mode, int *reg)
1.1  skrll {
1.1  skrll   char l0 = TOLOWER (src[0]);
1.1  skrll   char l1 = l0 ? TOLOWER (src[1]) : 0;
1.1  skrll
1.1  skrll   /* We use ! IDENT_CHAR for the next character after the register name, to
1.1  skrll      make sure that we won't accidentally recognize a symbol name such as
1.1  skrll      'sram' or sr_ram as being a reference to the register 'sr'.  */
1.1  skrll
1.1  skrll   if (l0 == 'r')
1.1  skrll     {
1.1  skrll       if (l1 == '1')
1.1  skrll 	{
1.1  skrll 	  if (src[2] >= '0' && src[2] <= '5'
1.1  skrll 	      && ! IDENT_CHAR ((unsigned char) src[3]))
1.1  skrll 	    {
1.1  skrll 	      *mode = A_REG_N;
1.1  skrll 	      *reg = 10 + src[2] - '0';
1.1  skrll 	      return 3;
1.1  skrll 	    }
1.1  skrll 	}
1.1  skrll       if (l1 >= '0' && l1 <= '9'
1.1  skrll 	  && ! IDENT_CHAR ((unsigned char) src[2]))
1.1  skrll 	{
1.1  skrll 	  *mode = A_REG_N;
1.1  skrll 	  *reg = (l1 - '0');
1.1  skrll 	  return 2;
1.1  skrll 	}
1.1  skrll       if (l1 >= '0' && l1 <= '7' && strncasecmp (&src[2], "_bank", 5) == 0
1.1  skrll 	  && ! IDENT_CHAR ((unsigned char) src[7]))
1.1  skrll 	{
1.1  skrll 	  *mode = A_REG_B;
1.1  skrll 	  *reg  = (l1 - '0');
1.1  skrll 	  return 7;
1.1  skrll 	}
1.1  skrll
1.1  skrll       if (l1 == 'e' && ! IDENT_CHAR ((unsigned char) src[2]))
1.1  skrll 	{
1.1  skrll 	  *mode = A_RE;
1.1  skrll 	  return 2;
1.1  skrll 	}
1.1  skrll       if (l1 == 's' && ! IDENT_CHAR ((unsigned char) src[2]))
1.1  skrll 	{
1.1  skrll 	  *mode = A_RS;
1.1  skrll 	  return 2;
1.1  skrll 	}
1.1  skrll     }
1.1  skrll
1.1  skrll   if (l0 == 'a')
1.1  skrll     {
1.1  skrll       if (l1 == '0')
1.1  skrll 	{
1.1  skrll 	  if (! IDENT_CHAR ((unsigned char) src[2]))
1.1  skrll 	    {
1.1  skrll 	      *mode = DSP_REG_N;
1.1  skrll 	      *reg = A_A0_NUM;
1.1  skrll 	      return 2;
1.1  skrll 	    }
1.1  skrll 	  if (TOLOWER (src[2]) == 'g' && ! IDENT_CHAR ((unsigned char) src[3]))
1.1  skrll 	    {
1.1  skrll 	      *mode = DSP_REG_N;
1.1  skrll 	      *reg = A_A0G_NUM;
1.1  skrll 	      return 3;
1.1  skrll 	    }
1.1  skrll 	}
1.1  skrll       if (l1 == '1')
1.1  skrll 	{
1.1  skrll 	  if (! IDENT_CHAR ((unsigned char) src[2]))
1.1  skrll 	    {
1.1  skrll 	      *mode = DSP_REG_N;
1.1  skrll 	      *reg = A_A1_NUM;
1.1  skrll 	      return 2;
1.1  skrll 	    }
1.1  skrll 	  if (TOLOWER (src[2]) == 'g' && ! IDENT_CHAR ((unsigned char) src[3]))
1.1  skrll 	    {
1.1  skrll 	      *mode = DSP_REG_N;
1.1  skrll 	      *reg = A_A1G_NUM;
1.1  skrll 	      return 3;
1.1  skrll 	    }
1.1  skrll 	}
1.1  skrll
1.1  skrll       if (l1 == 'x' && src[2] >= '0' && src[2] <= '1'
1.1  skrll 	  && ! IDENT_CHAR ((unsigned char) src[3]))
1.1  skrll 	{
1.1  skrll 	  *mode = A_REG_N;
1.1  skrll 	  *reg = 4 + (l1 - '0');
1.1  skrll 	  return 3;
1.1  skrll 	}
1.1  skrll       if (l1 == 'y' && src[2] >= '0' && src[2] <= '1'
1.1  skrll 	  && ! IDENT_CHAR ((unsigned char) src[3]))
1.1  skrll 	{
1.1  skrll 	  *mode = A_REG_N;
1.1  skrll 	  *reg = 6 + (l1 - '0');
1.1  skrll 	  return 3;
1.1  skrll 	}
1.1  skrll       if (l1 == 's' && src[2] >= '0' && src[2] <= '3'
1.1  skrll 	  && ! IDENT_CHAR ((unsigned char) src[3]))
1.1  skrll 	{
1.1  skrll 	  int n = l1 - '0';
1.1  skrll
1.1  skrll 	  *mode = A_REG_N;
1.1  skrll 	  *reg = n | ((~n & 2) << 1);
1.1  skrll 	  return 3;
1.1  skrll 	}
1.1  skrll     }
1.1  skrll
1.1  skrll   if (l0 == 'i' && l1 && ! IDENT_CHAR ((unsigned char) src[2]))
1.1  skrll     {
1.1  skrll       if (l1 == 's')
1.1  skrll 	{
1.1  skrll 	  *mode = A_REG_N;
1.1  skrll 	  *reg = 8;
1.1  skrll 	  return 2;
1.1  skrll 	}
1.1  skrll       if (l1 == 'x')
1.1  skrll 	{
1.1  skrll 	  *mode = A_REG_N;
1.1  skrll 	  *reg = 8;
1.1  skrll 	  return 2;
1.1  skrll 	}
1.1  skrll       if (l1 == 'y')
1.1  skrll 	{
1.1  skrll 	  *mode = A_REG_N;
1.1  skrll 	  *reg = 9;
1.1  skrll 	  return 2;
1.1  skrll 	}
1.1  skrll     }
1.1  skrll
1.1  skrll   if (l0 == 'x' && l1 >= '0' && l1 <= '1'
1.1  skrll       && ! IDENT_CHAR ((unsigned char) src[2]))
1.1  skrll     {
1.1  skrll       *mode = DSP_REG_N;
1.1  skrll       *reg = A_X0_NUM + l1 - '0';
1.1  skrll       return 2;
1.1  skrll     }
1.1  skrll
1.1  skrll   if (l0 == 'y' && l1 >= '0' && l1 <= '1'
1.1  skrll       && ! IDENT_CHAR ((unsigned char) src[2]))
1.1  skrll     {
1.1  skrll       *mode = DSP_REG_N;
1.1  skrll       *reg = A_Y0_NUM + l1 - '0';
1.1  skrll       return 2;
1.1  skrll     }
1.1  skrll
1.1  skrll   if (l0 == 'm' && l1 >= '0' && l1 <= '1'
1.1  skrll       && ! IDENT_CHAR ((unsigned char) src[2]))
1.1  skrll     {
1.1  skrll       *mode = DSP_REG_N;
1.1  skrll       *reg = l1 == '0' ? A_M0_NUM : A_M1_NUM;
1.1  skrll       return 2;
1.1  skrll     }
1.1  skrll
1.1  skrll   if (l0 == 's'
1.1  skrll       && l1 == 's'
1.1  skrll       && TOLOWER (src[2]) == 'r' && ! IDENT_CHAR ((unsigned char) src[3]))
1.1  skrll     {
1.1  skrll       *mode = A_SSR;
1.1  skrll       return 3;
1.1  skrll     }
1.1  skrll
1.1  skrll   if (l0 == 's' && l1 == 'p' && TOLOWER (src[2]) == 'c'
1.1  skrll       && ! IDENT_CHAR ((unsigned char) src[3]))
1.1  skrll     {
1.1  skrll       *mode = A_SPC;
1.1  skrll       return 3;
1.1  skrll     }
1.1  skrll
1.1  skrll   if (l0 == 's' && l1 == 'g' && TOLOWER (src[2]) == 'r'
1.1  skrll       && ! IDENT_CHAR ((unsigned char) src[3]))
1.1  skrll     {
1.1  skrll       *mode = A_SGR;
1.1  skrll       return 3;
1.1  skrll     }
1.1  skrll
1.1  skrll   if (l0 == 'd' && l1 == 's' && TOLOWER (src[2]) == 'r'
1.1  skrll       && ! IDENT_CHAR ((unsigned char) src[3]))
1.1  skrll     {
1.1  skrll       *mode = A_DSR;
1.1  skrll       return 3;
1.1  skrll     }
1.1  skrll
1.1  skrll   if (l0 == 'd' && l1 == 'b' && TOLOWER (src[2]) == 'r'
1.1  skrll       && ! IDENT_CHAR ((unsigned char) src[3]))
1.1  skrll     {
1.1  skrll       *mode = A_DBR;
1.1  skrll       return 3;
1.1  skrll     }
1.1  skrll
1.1  skrll   if (l0 == 's' && l1 == 'r' && ! IDENT_CHAR ((unsigned char) src[2]))
1.1  skrll     {
1.1  skrll       *mode = A_SR;
1.1  skrll       return 2;
1.1  skrll     }
1.1  skrll
1.1  skrll   if (l0 == 's' && l1 == 'p' && ! IDENT_CHAR ((unsigned char) src[2]))
1.1  skrll     {
1.1  skrll       *mode = A_REG_N;
1.1  skrll       *reg = 15;
1.1  skrll       return 2;
1.1  skrll     }
1.1  skrll
1.1  skrll   if (l0 == 'p' && l1 == 'r' && ! IDENT_CHAR ((unsigned char) src[2]))
1.1  skrll     {
1.1  skrll       *mode = A_PR;
1.1  skrll       return 2;
1.1  skrll     }
1.1  skrll   if (l0 == 'p' && l1 == 'c' && ! IDENT_CHAR ((unsigned char) src[2]))
1.1  skrll     {
1.1  skrll       /* Don't use A_DISP_PC here - that would accept stuff like 'mova pc,r0'
1.1  skrll          and use an uninitialized immediate.  */
1.1  skrll       *mode = A_PC;
1.1  skrll       return 2;
1.1  skrll     }
1.1  skrll   if (l0 == 'g' && l1 == 'b' && TOLOWER (src[2]) == 'r'
1.1  skrll       && ! IDENT_CHAR ((unsigned char) src[3]))
1.1  skrll     {
1.1  skrll       *mode = A_GBR;
1.1  skrll       return 3;
1.1  skrll     }
1.1  skrll   if (l0 == 'v' && l1 == 'b' && TOLOWER (src[2]) == 'r'
1.1  skrll       && ! IDENT_CHAR ((unsigned char) src[3]))
1.1  skrll     {
1.1  skrll       *mode = A_VBR;
1.1  skrll       return 3;
1.1  skrll     }
1.1  skrll
1.1  skrll   if (l0 == 't' && l1 == 'b' && TOLOWER (src[2]) == 'r'
1.1  skrll       && ! IDENT_CHAR ((unsigned char) src[3]))
1.1  skrll     {
1.1  skrll       *mode = A_TBR;
1.1  skrll       return 3;
1.1  skrll     }
1.1  skrll   if (l0 == 'm' && l1 == 'a' && TOLOWER (src[2]) == 'c'
1.1  skrll       && ! IDENT_CHAR ((unsigned char) src[4]))
1.1  skrll     {
1.1  skrll       if (TOLOWER (src[3]) == 'l')
1.1  skrll 	{
1.1  skrll 	  *mode = A_MACL;
1.1  skrll 	  return 4;
1.1  skrll 	}
1.1  skrll       if (TOLOWER (src[3]) == 'h')
1.1  skrll 	{
1.1  skrll 	  *mode = A_MACH;
1.1  skrll 	  return 4;
1.1  skrll 	}
1.1  skrll     }
1.1  skrll   if (l0 == 'm' && l1 == 'o' && TOLOWER (src[2]) == 'd'
1.1  skrll       && ! IDENT_CHAR ((unsigned char) src[3]))
1.1  skrll     {
1.1  skrll       *mode = A_MOD;
1.1  skrll       return 3;
1.1  skrll     }
1.1  skrll   if (l0 == 'f' && l1 == 'r')
1.1  skrll     {
1.1  skrll       if (src[2] == '1')
1.1  skrll 	{
1.1  skrll 	  if (src[3] >= '0' && src[3] <= '5'
1.1  skrll 	      && ! IDENT_CHAR ((unsigned char) src[4]))
1.1  skrll 	    {
1.1  skrll 	      *mode = F_REG_N;
1.1  skrll 	      *reg = 10 + src[3] - '0';
1.1  skrll 	      return 4;
1.1  skrll 	    }
1.1  skrll 	}
1.1  skrll       if (src[2] >= '0' && src[2] <= '9'
1.1  skrll 	  && ! IDENT_CHAR ((unsigned char) src[3]))
1.1  skrll 	{
1.1  skrll 	  *mode = F_REG_N;
1.1  skrll 	  *reg = (src[2] - '0');
1.1  skrll 	  return 3;
1.1  skrll 	}
1.1  skrll     }
1.1  skrll   if (l0 == 'd' && l1 == 'r')
1.1  skrll     {
1.1  skrll       if (src[2] == '1')
1.1  skrll 	{
1.1  skrll 	  if (src[3] >= '0' && src[3] <= '4' && ! ((src[3] - '0') & 1)
1.1  skrll 	      && ! IDENT_CHAR ((unsigned char) src[4]))
1.1  skrll 	    {
1.1  skrll 	      *mode = D_REG_N;
1.1  skrll 	      *reg = 10 + src[3] - '0';
1.1  skrll 	      return 4;
1.1  skrll 	    }
1.1  skrll 	}
1.1  skrll       if (src[2] >= '0' && src[2] <= '8' && ! ((src[2] - '0') & 1)
1.1  skrll 	  && ! IDENT_CHAR ((unsigned char) src[3]))
1.1  skrll 	{
1.1  skrll 	  *mode = D_REG_N;
1.1  skrll 	  *reg = (src[2] - '0');
1.1  skrll 	  return 3;
1.1  skrll 	}
1.1  skrll     }
1.1  skrll   if (l0 == 'x' && l1 == 'd')
1.1  skrll     {
1.1  skrll       if (src[2] == '1')
1.1  skrll 	{
1.1  skrll 	  if (src[3] >= '0' && src[3] <= '4' && ! ((src[3] - '0') & 1)
1.1  skrll 	      && ! IDENT_CHAR ((unsigned char) src[4]))
1.1  skrll 	    {
1.1  skrll 	      *mode = X_REG_N;
1.1  skrll 	      *reg = 11 + src[3] - '0';
1.1  skrll 	      return 4;
1.1  skrll 	    }
1.1  skrll 	}
1.1  skrll       if (src[2] >= '0' && src[2] <= '8' && ! ((src[2] - '0') & 1)
1.1  skrll 	  && ! IDENT_CHAR ((unsigned char) src[3]))
1.1  skrll 	{
1.1  skrll 	  *mode = X_REG_N;
1.1  skrll 	  *reg = (src[2] - '0') + 1;
1.1  skrll 	  return 3;
1.1  skrll 	}
1.1  skrll     }
1.1  skrll   if (l0 == 'f' && l1 == 'v')
1.1  skrll     {
1.1  skrll       if (src[2] == '1'&& src[3] == '2' && ! IDENT_CHAR ((unsigned char) src[4]))
1.1  skrll 	{
1.1  skrll 	  *mode = V_REG_N;
1.1  skrll 	  *reg = 12;
1.1  skrll 	  return 4;
1.1  skrll 	}
1.1  skrll       if ((src[2] == '0' || src[2] == '4' || src[2] == '8')
1.1  skrll 	  && ! IDENT_CHAR ((unsigned char) src[3]))
1.1  skrll 	{
1.1  skrll 	  *mode = V_REG_N;
1.1  skrll 	  *reg = (src[2] - '0');
1.1  skrll 	  return 3;
1.1  skrll 	}
1.1  skrll     }
1.1  skrll   if (l0 == 'f' && l1 == 'p' && TOLOWER (src[2]) == 'u'
1.1  skrll       && TOLOWER (src[3]) == 'l'
1.1  skrll       && ! IDENT_CHAR ((unsigned char) src[4]))
1.1  skrll     {
1.1  skrll       *mode = FPUL_N;
1.1  skrll       return 4;
1.1  skrll     }
1.1  skrll
1.1  skrll   if (l0 == 'f' && l1 == 'p' && TOLOWER (src[2]) == 's'
1.1  skrll       && TOLOWER (src[3]) == 'c'
1.1  skrll       && TOLOWER (src[4]) == 'r' && ! IDENT_CHAR ((unsigned char) src[5]))
1.1  skrll     {
1.1  skrll       *mode = FPSCR_N;
1.1  skrll       return 5;
1.1  skrll     }
1.1  skrll
1.1  skrll   if (l0 == 'x' && l1 == 'm' && TOLOWER (src[2]) == 't'
1.1  skrll       && TOLOWER (src[3]) == 'r'
1.1  skrll       && TOLOWER (src[4]) == 'x' && ! IDENT_CHAR ((unsigned char) src[5]))
1.1  skrll     {
1.1  skrll       *mode = XMTRX_M4;
1.1  skrll       return 5;
1.1  skrll     }
1.1  skrll
1.1  skrll   return 0;
1.1  skrll }
1.1  skrll
1.1  skrll /* Like parse_reg_without_prefix, but this version supports
1.1  skrll    $-prefixed register names if enabled by the user.  */
1.1  skrll
1.1  skrll static unsigned int
1.1  skrll parse_reg (char *src, int *mode, int *reg)
1.1  skrll {
1.1  skrll   unsigned int prefix;
1.1  skrll   unsigned int consumed;
1.1  skrll
1.1  skrll   if (src[0] == '$')
1.1  skrll     {
1.1  skrll       if (allow_dollar_register_prefix)
1.1  skrll 	{
1.1  skrll 	  src ++;
1.1  skrll 	  prefix = 1;
1.1  skrll 	}
1.1  skrll       else
1.1  skrll 	return 0;
1.1  skrll     }
1.1  skrll   else
1.1  skrll     prefix = 0;
1.1  skrll
1.1  skrll   consumed = parse_reg_without_prefix (src, mode, reg);
1.1  skrll
1.1  skrll   if (consumed == 0)
1.1  skrll     return 0;
1.1  skrll
1.1  skrll   return consumed + prefix;
1.1  skrll }
1.1  skrll
1.1  skrll static char *
1.1  skrll parse_exp (char *s, sh_operand_info *op)
1.1  skrll {
1.1  skrll   char *save;
1.1  skrll   char *new;
1.1  skrll
1.1  skrll   save = input_line_pointer;
1.1  skrll   input_line_pointer = s;
1.1  skrll   expression (&op->immediate);
1.1  skrll   if (op->immediate.X_op == O_absent)
1.1  skrll     as_bad (_("missing operand"));
1.1  skrll #ifdef OBJ_ELF
1.1  skrll   else if (op->immediate.X_op == O_PIC_reloc
1.1  skrll 	   || sh_PIC_related_p (op->immediate.X_add_symbol)
1.1  skrll 	   || sh_PIC_related_p (op->immediate.X_op_symbol))
1.1  skrll     as_bad (_("misplaced PIC operand"));
1.1  skrll #endif
1.1  skrll   new = input_line_pointer;
1.1  skrll   input_line_pointer = save;
1.1  skrll   return new;
1.1  skrll }
1.1  skrll
1.1  skrll /* The many forms of operand:
1.1  skrll
1.1  skrll    Rn                   Register direct
1.1  skrll    @Rn                  Register indirect
1.1  skrll    @Rn+                 Autoincrement
1.1  skrll    @-Rn                 Autodecrement
1.1  skrll    @(disp:4,Rn)
1.1  skrll    @(disp:8,GBR)
1.1  skrll    @(disp:8,PC)
1.1  skrll
1.1  skrll    @(R0,Rn)
1.1  skrll    @(R0,GBR)
1.1  skrll
1.1  skrll    disp:8
1.1  skrll    disp:12
1.1  skrll    #imm8
1.1  skrll    pr, gbr, vbr, macl, mach
1.1  skrll  */
1.1  skrll
1.1  skrll static char *
1.1  skrll parse_at (char *src, sh_operand_info *op)
1.1  skrll {
1.1  skrll   int len;
1.1  skrll   int mode;
1.1  skrll   src++;
1.1  skrll   if (src[0] == '@')
1.1  skrll     {
1.1  skrll       src = parse_at (src, op);
1.1  skrll       if (op->type == A_DISP_TBR)
1.1  skrll 	op->type = A_DISP2_TBR;
1.1  skrll       else
1.1  skrll 	as_bad (_("illegal double indirection"));
1.1  skrll     }
1.1  skrll   else if (src[0] == '-')
1.1  skrll     {
1.1  skrll       /* Must be predecrement.  */
1.1  skrll       src++;
1.1  skrll
1.1  skrll       len = parse_reg (src, &mode, &(op->reg));
1.1  skrll       if (mode != A_REG_N)
1.1  skrll 	as_bad (_("illegal register after @-"));
1.1  skrll
1.1  skrll       op->type = A_DEC_N;
1.1  skrll       src += len;
1.1  skrll     }
1.1  skrll   else if (src[0] == '(')
1.1  skrll     {
1.1  skrll       /* Could be @(disp, rn), @(disp, gbr), @(disp, pc),  @(r0, gbr) or
1.1  skrll          @(r0, rn).  */
1.1  skrll       src++;
1.1  skrll       len = parse_reg (src, &mode, &(op->reg));
1.1  skrll       if (len && mode == A_REG_N)
1.1  skrll 	{
1.1  skrll 	  src += len;
1.1  skrll 	  if (op->reg != 0)
1.1  skrll 	    {
1.1  skrll 	      as_bad (_("must be @(r0,...)"));
1.1  skrll 	    }
1.1  skrll 	  if (src[0] == ',')
1.1  skrll 	    {
1.1  skrll 	      src++;
1.1  skrll 	      /* Now can be rn or gbr.  */
1.1  skrll 	      len = parse_reg (src, &mode, &(op->reg));
1.1  skrll 	    }
1.1  skrll 	  else
1.1  skrll 	    {
1.1  skrll 	      len = 0;
1.1  skrll 	    }
1.1  skrll 	  if (len)
1.1  skrll 	    {
1.1  skrll 	      if (mode == A_GBR)
1.1  skrll 		{
1.1  skrll 		  op->type = A_R0_GBR;
1.1  skrll 		}
1.1  skrll 	      else if (mode == A_REG_N)
1.1  skrll 		{
1.1  skrll 		  op->type = A_IND_R0_REG_N;
1.1  skrll 		}
1.1  skrll 	      else
1.1  skrll 		{
1.1  skrll 		  as_bad (_("syntax error in @(r0,...)"));
1.1  skrll 		}
1.1  skrll 	    }
1.1  skrll 	  else
1.1  skrll 	    {
1.1  skrll 	      as_bad (_("syntax error in @(r0...)"));
1.1  skrll 	    }
1.1  skrll 	}
1.1  skrll       else
1.1  skrll 	{
1.1  skrll 	  /* Must be an @(disp,.. thing).  */
1.1  skrll 	  src = parse_exp (src, op);
1.1  skrll 	  if (src[0] == ',')
1.1  skrll 	    src++;
1.1  skrll 	  /* Now can be rn, gbr or pc.  */
1.1  skrll 	  len = parse_reg (src, &mode, &op->reg);
1.1  skrll 	  if (len)
1.1  skrll 	    {
1.1  skrll 	      if (mode == A_REG_N)
1.1  skrll 		{
1.1  skrll 		  op->type = A_DISP_REG_N;
1.1  skrll 		}
1.1  skrll 	      else if (mode == A_GBR)
1.1  skrll 		{
1.1  skrll 		  op->type = A_DISP_GBR;
1.1  skrll 		}
1.1  skrll 	      else if (mode == A_TBR)
1.1  skrll 		{
1.1  skrll 		  op->type = A_DISP_TBR;
1.1  skrll 		}
1.1  skrll 	      else if (mode == A_PC)
1.1  skrll 		{
1.1  skrll 		  /* We want @(expr, pc) to uniformly address . + expr,
1.1  skrll 		     no matter if expr is a constant, or a more complex
1.1  skrll 		     expression, e.g. sym-. or sym1-sym2.
1.1  skrll 		     However, we also used to accept @(sym,pc)
1.1  skrll 		     as addressing sym, i.e. meaning the same as plain sym.
1.1  skrll 		     Some existing code does use the @(sym,pc) syntax, so
1.1  skrll 		     we give it the old semantics for now, but warn about
1.1  skrll 		     its use, so that users have some time to fix their code.
1.1  skrll
1.1  skrll 		     Note that due to this backward compatibility hack,
1.1  skrll 		     we'll get unexpected results when @(offset, pc) is used,
1.1  skrll 		     and offset is a symbol that is set later to an an address
1.1  skrll 		     difference, or an external symbol that is set to an
1.1  skrll 		     address difference in another source file, so we want to
1.1  skrll 		     eventually remove it.  */
1.1  skrll 		  if (op->immediate.X_op == O_symbol)
1.1  skrll 		    {
1.1  skrll 		      op->type = A_DISP_PC;
1.1  skrll 		      as_warn (_("Deprecated syntax."));
1.1  skrll 		    }
1.1  skrll 		  else
1.1  skrll 		    {
1.1  skrll 		      op->type = A_DISP_PC_ABS;
1.1  skrll 		      /* Such operands don't get corrected for PC==.+4, so
1.1  skrll 			 make the correction here.  */
1.1  skrll 		      op->immediate.X_add_number -= 4;
1.1  skrll 		    }
1.1  skrll 		}
1.1  skrll 	      else
1.1  skrll 		{
1.1  skrll 		  as_bad (_("syntax error in @(disp,[Rn, gbr, pc])"));
1.1  skrll 		}
1.1  skrll 	    }
1.1  skrll 	  else
1.1  skrll 	    {
1.1  skrll 	      as_bad (_("syntax error in @(disp,[Rn, gbr, pc])"));
1.1  skrll 	    }
1.1  skrll 	}
1.1  skrll       src += len;
1.1  skrll       if (src[0] != ')')
1.1  skrll 	as_bad (_("expecting )"));
1.1  skrll       else
1.1  skrll 	src++;
1.1  skrll     }
1.1  skrll   else
1.1  skrll     {
1.1  skrll       src += parse_reg (src, &mode, &(op->reg));
1.1  skrll       if (mode != A_REG_N)
1.1  skrll 	as_bad (_("illegal register after @"));
1.1  skrll
1.1  skrll       if (src[0] == '+')
1.1  skrll 	{
1.1  skrll 	  char l0, l1;
1.1  skrll
1.1  skrll 	  src++;
1.1  skrll 	  l0 = TOLOWER (src[0]);
1.1  skrll 	  l1 = TOLOWER (src[1]);
1.1  skrll
1.1  skrll 	  if ((l0 == 'r' && l1 == '8')
1.1  skrll 	      || (l0 == 'i' && (l1 == 'x' || l1 == 's')))
1.1  skrll 	    {
1.1  skrll 	      src += 2;
1.1  skrll 	      op->type = AX_PMOD_N;
1.1  skrll 	    }
1.1  skrll 	  else if (   (l0 == 'r' && l1 == '9')
1.1  skrll 		   || (l0 == 'i' && l1 == 'y'))
1.1  skrll 	    {
1.1  skrll 	      src += 2;
1.1  skrll 	      op->type = AY_PMOD_N;
1.1  skrll 	    }
1.1  skrll 	  else
1.1  skrll 	    op->type = A_INC_N;
1.1  skrll 	}
1.1  skrll       else
1.1  skrll 	op->type = A_IND_N;
1.1  skrll     }
1.1  skrll   return src;
1.1  skrll }
1.1  skrll
1.1  skrll static void
1.1  skrll get_operand (char **ptr, sh_operand_info *op)
1.1  skrll {
1.1  skrll   char *src = *ptr;
1.1  skrll   int mode = -1;
1.1  skrll   unsigned int len;
1.1  skrll
1.1  skrll   if (src[0] == '#')
1.1  skrll     {
1.1  skrll       src++;
1.1  skrll       *ptr = parse_exp (src, op);
1.1  skrll       op->type = A_IMM;
1.1  skrll       return;
1.1  skrll     }
1.1  skrll
1.1  skrll   else if (src[0] == '@')
1.1  skrll     {
1.1  skrll       *ptr = parse_at (src, op);
1.1  skrll       return;
1.1  skrll     }
1.1  skrll   len = parse_reg (src, &mode, &(op->reg));
1.1  skrll   if (len)
1.1  skrll     {
1.1  skrll       *ptr = src + len;
1.1  skrll       op->type = mode;
1.1  skrll       return;
1.1  skrll     }
1.1  skrll   else
1.1  skrll     {
1.1  skrll       /* Not a reg, the only thing left is a displacement.  */
1.1  skrll       *ptr = parse_exp (src, op);
1.1  skrll       op->type = A_DISP_PC;
1.1  skrll       return;
1.1  skrll     }
1.1  skrll }
1.1  skrll
1.1  skrll static char *
1.1  skrll get_operands (sh_opcode_info *info, char *args, sh_operand_info *operand)
1.1  skrll {
1.1  skrll   char *ptr = args;
1.1  skrll   if (info->arg[0])
1.1  skrll     {
1.1  skrll       /* The pre-processor will eliminate whitespace in front of '@'
1.1  skrll 	 after the first argument; we may be called multiple times
1.1  skrll 	 from assemble_ppi, so don't insist on finding whitespace here.  */
1.1  skrll       if (*ptr == ' ')
1.1  skrll 	ptr++;
1.1  skrll
1.1  skrll       get_operand (&ptr, operand + 0);
1.1  skrll       if (info->arg[1])
1.1  skrll 	{
1.1  skrll 	  if (*ptr == ',')
1.1  skrll 	    {
1.1  skrll 	      ptr++;
1.1  skrll 	    }
1.1  skrll 	  get_operand (&ptr, operand + 1);
1.1  skrll 	  /* ??? Hack: psha/pshl have a varying operand number depending on
1.1  skrll 	     the type of the first operand.  We handle this by having the
1.1  skrll 	     three-operand version first and reducing the number of operands
1.1  skrll 	     parsed to two if we see that the first operand is an immediate.
1.1  skrll              This works because no insn with three operands has an immediate
1.1  skrll 	     as first operand.  */
1.1  skrll 	  if (info->arg[2] && operand[0].type != A_IMM)
1.1  skrll 	    {
1.1  skrll 	      if (*ptr == ',')
1.1  skrll 		{
1.1  skrll 		  ptr++;
1.1  skrll 		}
1.1  skrll 	      get_operand (&ptr, operand + 2);
1.1  skrll 	    }
1.1  skrll 	  else
1.1  skrll 	    {
1.1  skrll 	      operand[2].type = 0;
1.1  skrll 	    }
1.1  skrll 	}
1.1  skrll       else
1.1  skrll 	{
1.1  skrll 	  operand[1].type = 0;
1.1  skrll 	  operand[2].type = 0;
1.1  skrll 	}
1.1  skrll     }
1.1  skrll   else
1.1  skrll     {
1.1  skrll       operand[0].type = 0;
1.1  skrll       operand[1].type = 0;
1.1  skrll       operand[2].type = 0;
1.1  skrll     }
1.1  skrll   return ptr;
1.1  skrll }
1.1  skrll
1.1  skrll /* Passed a pointer to a list of opcodes which use different
1.1  skrll    addressing modes, return the opcode which matches the opcodes
1.1  skrll    provided.  */
1.1  skrll
1.1  skrll static sh_opcode_info *
1.1  skrll get_specific (sh_opcode_info *opcode, sh_operand_info *operands)
1.1  skrll {
1.1  skrll   sh_opcode_info *this_try = opcode;
1.1  skrll   char *name = opcode->name;
1.1  skrll   int n = 0;
1.1  skrll
1.1  skrll   while (opcode->name)
1.1  skrll     {
1.1  skrll       this_try = opcode++;
1.1  skrll       if ((this_try->name != name) && (strcmp (this_try->name, name) != 0))
1.1  skrll 	{
1.1  skrll 	  /* We've looked so far down the table that we've run out of
1.1  skrll 	     opcodes with the same name.  */
1.1  skrll 	  return 0;
1.1  skrll 	}
1.1  skrll
1.1  skrll       /* Look at both operands needed by the opcodes and provided by
1.1  skrll          the user - since an arg test will often fail on the same arg
1.1  skrll          again and again, we'll try and test the last failing arg the
1.1  skrll          first on each opcode try.  */
1.1  skrll       for (n = 0; this_try->arg[n]; n++)
1.1  skrll 	{
1.1  skrll 	  sh_operand_info *user = operands + n;
1.1  skrll 	  sh_arg_type arg = this_try->arg[n];
1.1  skrll
1.1  skrll 	  if (SH_MERGE_ARCH_SET_VALID (valid_arch, arch_sh2a_nofpu_up)
1.1  skrll 	      && (   arg == A_DISP_REG_M
1.1  skrll 		  || arg == A_DISP_REG_N))
1.1  skrll 	    {
1.1  skrll 	      /* Check a few key IMM* fields for overflow.  */
1.1  skrll 	      int opf;
1.1  skrll 	      long val = user->immediate.X_add_number;
1.1  skrll
1.1  skrll 	      for (opf = 0; opf < 4; opf ++)
1.1  skrll 		switch (this_try->nibbles[opf])
1.1  skrll 		  {
1.1  skrll 		  case IMM0_4:
1.1  skrll 		  case IMM1_4:
1.1  skrll 		    if (val < 0 || val > 15)
1.1  skrll 		      goto fail;
1.1  skrll 		    break;
1.1  skrll 		  case IMM0_4BY2:
1.1  skrll 		  case IMM1_4BY2:
1.1  skrll 		    if (val < 0 || val > 15 * 2)
1.1  skrll 		      goto fail;
1.1  skrll 		    break;
1.1  skrll 		  case IMM0_4BY4:
1.1  skrll 		  case IMM1_4BY4:
1.1  skrll 		    if (val < 0 || val > 15 * 4)
1.1  skrll 		      goto fail;
1.1  skrll 		    break;
1.1  skrll 		  default:
1.1  skrll 		    break;
1.1  skrll 		  }
1.1  skrll 	    }
1.1  skrll 	  switch (arg)
1.1  skrll 	    {
1.1  skrll 	    case A_DISP_PC:
1.1  skrll 	      if (user->type == A_DISP_PC_ABS)
1.1  skrll 		break;
1.1  skrll 	      /* Fall through.  */
1.1  skrll 	    case A_IMM:
1.1  skrll 	    case A_BDISP12:
1.1  skrll 	    case A_BDISP8:
1.1  skrll 	    case A_DISP_GBR:
1.1  skrll 	    case A_DISP2_TBR:
1.1  skrll 	    case A_MACH:
1.1  skrll 	    case A_PR:
1.1  skrll 	    case A_MACL:
1.1  skrll 	      if (user->type != arg)
1.1  skrll 		goto fail;
1.1  skrll 	      break;
1.1  skrll 	    case A_R0:
1.1  skrll 	      /* opcode needs r0 */
1.1  skrll 	      if (user->type != A_REG_N || user->reg != 0)
1.1  skrll 		goto fail;
1.1  skrll 	      break;
1.1  skrll 	    case A_R0_GBR:
1.1  skrll 	      if (user->type != A_R0_GBR || user->reg != 0)
1.1  skrll 		goto fail;
1.1  skrll 	      break;
1.1  skrll 	    case F_FR0:
1.1  skrll 	      if (user->type != F_REG_N || user->reg != 0)
1.1  skrll 		goto fail;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case A_REG_N:
1.1  skrll 	    case A_INC_N:
1.1  skrll 	    case A_DEC_N:
1.1  skrll 	    case A_IND_N:
1.1  skrll 	    case A_IND_R0_REG_N:
1.1  skrll 	    case A_DISP_REG_N:
1.1  skrll 	    case F_REG_N:
1.1  skrll 	    case D_REG_N:
1.1  skrll 	    case X_REG_N:
1.1  skrll 	    case V_REG_N:
1.1  skrll 	    case FPUL_N:
1.1  skrll 	    case FPSCR_N:
1.1  skrll 	    case DSP_REG_N:
1.1  skrll 	      /* Opcode needs rn */
1.1  skrll 	      if (user->type != arg)
1.1  skrll 		goto fail;
1.1  skrll 	      reg_n = user->reg;
1.1  skrll 	      break;
1.1  skrll 	    case DX_REG_N:
1.1  skrll 	      if (user->type != D_REG_N && user->type != X_REG_N)
1.1  skrll 		goto fail;
1.1  skrll 	      reg_n = user->reg;
1.1  skrll 	      break;
1.1  skrll 	    case A_GBR:
1.1  skrll 	    case A_TBR:
1.1  skrll 	    case A_SR:
1.1  skrll 	    case A_VBR:
1.1  skrll 	    case A_DSR:
1.1  skrll 	    case A_MOD:
1.1  skrll 	    case A_RE:
1.1  skrll 	    case A_RS:
1.1  skrll 	    case A_SSR:
1.1  skrll 	    case A_SPC:
1.1  skrll 	    case A_SGR:
1.1  skrll 	    case A_DBR:
1.1  skrll 	      if (user->type != arg)
1.1  skrll 		goto fail;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case A_REG_B:
1.1  skrll 	      if (user->type != arg)
1.1  skrll 		goto fail;
1.1  skrll 	      reg_b = user->reg;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case A_INC_R15:
1.1  skrll 	      if (user->type != A_INC_N)
1.1  skrll 		goto fail;
1.1  skrll 	      if (user->reg != 15)
1.1  skrll 		goto fail;
1.1  skrll 	      reg_n = user->reg;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case A_DEC_R15:
1.1  skrll 	      if (user->type != A_DEC_N)
1.1  skrll 		goto fail;
1.1  skrll 	      if (user->reg != 15)
1.1  skrll 		goto fail;
1.1  skrll 	      reg_n = user->reg;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case A_REG_M:
1.1  skrll 	    case A_INC_M:
1.1  skrll 	    case A_DEC_M:
1.1  skrll 	    case A_IND_M:
1.1  skrll 	    case A_IND_R0_REG_M:
1.1  skrll 	    case A_DISP_REG_M:
1.1  skrll 	    case DSP_REG_M:
1.1  skrll 	      /* Opcode needs rn */
1.1  skrll 	      if (user->type != arg - A_REG_M + A_REG_N)
1.1  skrll 		goto fail;
1.1  skrll 	      reg_m = user->reg;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case AS_DEC_N:
1.1  skrll 	      if (user->type != A_DEC_N)
1.1  skrll 		goto fail;
1.1  skrll 	      if (user->reg < 2 || user->reg > 5)
1.1  skrll 		goto fail;
1.1  skrll 	      reg_n = user->reg;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case AS_INC_N:
1.1  skrll 	      if (user->type != A_INC_N)
1.1  skrll 		goto fail;
1.1  skrll 	      if (user->reg < 2 || user->reg > 5)
1.1  skrll 		goto fail;
1.1  skrll 	      reg_n = user->reg;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case AS_IND_N:
1.1  skrll 	      if (user->type != A_IND_N)
1.1  skrll 		goto fail;
1.1  skrll 	      if (user->reg < 2 || user->reg > 5)
1.1  skrll 		goto fail;
1.1  skrll 	      reg_n = user->reg;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case AS_PMOD_N:
1.1  skrll 	      if (user->type != AX_PMOD_N)
1.1  skrll 		goto fail;
1.1  skrll 	      if (user->reg < 2 || user->reg > 5)
1.1  skrll 		goto fail;
1.1  skrll 	      reg_n = user->reg;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case AX_INC_N:
1.1  skrll 	      if (user->type != A_INC_N)
1.1  skrll 		goto fail;
1.1  skrll 	      if (user->reg < 4 || user->reg > 5)
1.1  skrll 		goto fail;
1.1  skrll 	      reg_n = user->reg;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case AX_IND_N:
1.1  skrll 	      if (user->type != A_IND_N)
1.1  skrll 		goto fail;
1.1  skrll 	      if (user->reg < 4 || user->reg > 5)
1.1  skrll 		goto fail;
1.1  skrll 	      reg_n = user->reg;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case AX_PMOD_N:
1.1  skrll 	      if (user->type != AX_PMOD_N)
1.1  skrll 		goto fail;
1.1  skrll 	      if (user->reg < 4 || user->reg > 5)
1.1  skrll 		goto fail;
1.1  skrll 	      reg_n = user->reg;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case AXY_INC_N:
1.1  skrll 	      if (user->type != A_INC_N)
1.1  skrll 		goto fail;
1.1  skrll 	      if ((user->reg < 4 || user->reg > 5)
1.1  skrll 		  && (user->reg < 0 || user->reg > 1))
1.1  skrll 		goto fail;
1.1  skrll 	      reg_n = user->reg;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case AXY_IND_N:
1.1  skrll 	      if (user->type != A_IND_N)
1.1  skrll 		goto fail;
1.1  skrll 	      if ((user->reg < 4 || user->reg > 5)
1.1  skrll 		  && (user->reg < 0 || user->reg > 1))
1.1  skrll 		goto fail;
1.1  skrll 	      reg_n = user->reg;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case AXY_PMOD_N:
1.1  skrll 	      if (user->type != AX_PMOD_N)
1.1  skrll 		goto fail;
1.1  skrll 	      if ((user->reg < 4 || user->reg > 5)
1.1  skrll 		  && (user->reg < 0 || user->reg > 1))
1.1  skrll 		goto fail;
1.1  skrll 	      reg_n = user->reg;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case AY_INC_N:
1.1  skrll 	      if (user->type != A_INC_N)
1.1  skrll 		goto fail;
1.1  skrll 	      if (user->reg < 6 || user->reg > 7)
1.1  skrll 		goto fail;
1.1  skrll 	      reg_n = user->reg;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case AY_IND_N:
1.1  skrll 	      if (user->type != A_IND_N)
1.1  skrll 		goto fail;
1.1  skrll 	      if (user->reg < 6 || user->reg > 7)
1.1  skrll 		goto fail;
1.1  skrll 	      reg_n = user->reg;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case AY_PMOD_N:
1.1  skrll 	      if (user->type != AY_PMOD_N)
1.1  skrll 		goto fail;
1.1  skrll 	      if (user->reg < 6 || user->reg > 7)
1.1  skrll 		goto fail;
1.1  skrll 	      reg_n = user->reg;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case AYX_INC_N:
1.1  skrll 	      if (user->type != A_INC_N)
1.1  skrll 		goto fail;
1.1  skrll 	      if ((user->reg < 6 || user->reg > 7)
1.1  skrll 		  && (user->reg < 2 || user->reg > 3))
1.1  skrll 		goto fail;
1.1  skrll 	      reg_n = user->reg;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case AYX_IND_N:
1.1  skrll 	      if (user->type != A_IND_N)
1.1  skrll 		goto fail;
1.1  skrll 	      if ((user->reg < 6 || user->reg > 7)
1.1  skrll 		  && (user->reg < 2 || user->reg > 3))
1.1  skrll 		goto fail;
1.1  skrll 	      reg_n = user->reg;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case AYX_PMOD_N:
1.1  skrll 	      if (user->type != AY_PMOD_N)
1.1  skrll 		goto fail;
1.1  skrll 	      if ((user->reg < 6 || user->reg > 7)
1.1  skrll 		  && (user->reg < 2 || user->reg > 3))
1.1  skrll 		goto fail;
1.1  skrll 	      reg_n = user->reg;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case DSP_REG_A_M:
1.1  skrll 	      if (user->type != DSP_REG_N)
1.1  skrll 		goto fail;
1.1  skrll 	      if (user->reg != A_A0_NUM
1.1  skrll 		  && user->reg != A_A1_NUM)
1.1  skrll 		goto fail;
1.1  skrll 	      reg_m = user->reg;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case DSP_REG_AX:
1.1  skrll 	      if (user->type != DSP_REG_N)
1.1  skrll 		goto fail;
1.1  skrll 	      switch (user->reg)
1.1  skrll 		{
1.1  skrll 		case A_A0_NUM:
1.1  skrll 		  reg_x = 0;
1.1  skrll 		  break;
1.1  skrll 		case A_A1_NUM:
1.1  skrll 		  reg_x = 2;
1.1  skrll 		  break;
1.1  skrll 		case A_X0_NUM:
1.1  skrll 		  reg_x = 1;
1.1  skrll 		  break;
1.1  skrll 		case A_X1_NUM:
1.1  skrll 		  reg_x = 3;
1.1  skrll 		  break;
1.1  skrll 		default:
1.1  skrll 		  goto fail;
1.1  skrll 		}
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case DSP_REG_XY:
1.1  skrll 	      if (user->type != DSP_REG_N)
1.1  skrll 		goto fail;
1.1  skrll 	      switch (user->reg)
1.1  skrll 		{
1.1  skrll 		case A_X0_NUM:
1.1  skrll 		  reg_x = 0;
1.1  skrll 		  break;
1.1  skrll 		case A_X1_NUM:
1.1  skrll 		  reg_x = 2;
1.1  skrll 		  break;
1.1  skrll 		case A_Y0_NUM:
1.1  skrll 		  reg_x = 1;
1.1  skrll 		  break;
1.1  skrll 		case A_Y1_NUM:
1.1  skrll 		  reg_x = 3;
1.1  skrll 		  break;
1.1  skrll 		default:
1.1  skrll 		  goto fail;
1.1  skrll 		}
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case DSP_REG_AY:
1.1  skrll 	      if (user->type != DSP_REG_N)
1.1  skrll 		goto fail;
1.1  skrll 	      switch (user->reg)
1.1  skrll 		{
1.1  skrll 		case A_A0_NUM:
1.1  skrll 		  reg_y = 0;
1.1  skrll 		  break;
1.1  skrll 		case A_A1_NUM:
1.1  skrll 		  reg_y = 1;
1.1  skrll 		  break;
1.1  skrll 		case A_Y0_NUM:
1.1  skrll 		  reg_y = 2;
1.1  skrll 		  break;
1.1  skrll 		case A_Y1_NUM:
1.1  skrll 		  reg_y = 3;
1.1  skrll 		  break;
1.1  skrll 		default:
1.1  skrll 		  goto fail;
1.1  skrll 		}
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case DSP_REG_YX:
1.1  skrll 	      if (user->type != DSP_REG_N)
1.1  skrll 		goto fail;
1.1  skrll 	      switch (user->reg)
1.1  skrll 		{
1.1  skrll 		case A_Y0_NUM:
1.1  skrll 		  reg_y = 0;
1.1  skrll 		  break;
1.1  skrll 		case A_Y1_NUM:
1.1  skrll 		  reg_y = 1;
1.1  skrll 		  break;
1.1  skrll 		case A_X0_NUM:
1.1  skrll 		  reg_y = 2;
1.1  skrll 		  break;
1.1  skrll 		case A_X1_NUM:
1.1  skrll 		  reg_y = 3;
1.1  skrll 		  break;
1.1  skrll 		default:
1.1  skrll 		  goto fail;
1.1  skrll 		}
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case DSP_REG_X:
1.1  skrll 	      if (user->type != DSP_REG_N)
1.1  skrll 		goto fail;
1.1  skrll 	      switch (user->reg)
1.1  skrll 		{
1.1  skrll 		case A_X0_NUM:
1.1  skrll 		  reg_x = 0;
1.1  skrll 		  break;
1.1  skrll 		case A_X1_NUM:
1.1  skrll 		  reg_x = 1;
1.1  skrll 		  break;
1.1  skrll 		case A_A0_NUM:
1.1  skrll 		  reg_x = 2;
1.1  skrll 		  break;
1.1  skrll 		case A_A1_NUM:
1.1  skrll 		  reg_x = 3;
1.1  skrll 		  break;
1.1  skrll 		default:
1.1  skrll 		  goto fail;
1.1  skrll 		}
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case DSP_REG_Y:
1.1  skrll 	      if (user->type != DSP_REG_N)
1.1  skrll 		goto fail;
1.1  skrll 	      switch (user->reg)
1.1  skrll 		{
1.1  skrll 		case A_Y0_NUM:
1.1  skrll 		  reg_y = 0;
1.1  skrll 		  break;
1.1  skrll 		case A_Y1_NUM:
1.1  skrll 		  reg_y = 1;
1.1  skrll 		  break;
1.1  skrll 		case A_M0_NUM:
1.1  skrll 		  reg_y = 2;
1.1  skrll 		  break;
1.1  skrll 		case A_M1_NUM:
1.1  skrll 		  reg_y = 3;
1.1  skrll 		  break;
1.1  skrll 		default:
1.1  skrll 		  goto fail;
1.1  skrll 		}
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case DSP_REG_E:
1.1  skrll 	      if (user->type != DSP_REG_N)
1.1  skrll 		goto fail;
1.1  skrll 	      switch (user->reg)
1.1  skrll 		{
1.1  skrll 		case A_X0_NUM:
1.1  skrll 		  reg_efg = 0 << 10;
1.1  skrll 		  break;
1.1  skrll 		case A_X1_NUM:
1.1  skrll 		  reg_efg = 1 << 10;
1.1  skrll 		  break;
1.1  skrll 		case A_Y0_NUM:
1.1  skrll 		  reg_efg = 2 << 10;
1.1  skrll 		  break;
1.1  skrll 		case A_A1_NUM:
1.1  skrll 		  reg_efg = 3 << 10;
1.1  skrll 		  break;
1.1  skrll 		default:
1.1  skrll 		  goto fail;
1.1  skrll 		}
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case DSP_REG_F:
1.1  skrll 	      if (user->type != DSP_REG_N)
1.1  skrll 		goto fail;
1.1  skrll 	      switch (user->reg)
1.1  skrll 		{
1.1  skrll 		case A_Y0_NUM:
1.1  skrll 		  reg_efg |= 0 << 8;
1.1  skrll 		  break;
1.1  skrll 		case A_Y1_NUM:
1.1  skrll 		  reg_efg |= 1 << 8;
1.1  skrll 		  break;
1.1  skrll 		case A_X0_NUM:
1.1  skrll 		  reg_efg |= 2 << 8;
1.1  skrll 		  break;
1.1  skrll 		case A_A1_NUM:
1.1  skrll 		  reg_efg |= 3 << 8;
1.1  skrll 		  break;
1.1  skrll 		default:
1.1  skrll 		  goto fail;
1.1  skrll 		}
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case DSP_REG_G:
1.1  skrll 	      if (user->type != DSP_REG_N)
1.1  skrll 		goto fail;
1.1  skrll 	      switch (user->reg)
1.1  skrll 		{
1.1  skrll 		case A_M0_NUM:
1.1  skrll 		  reg_efg |= 0 << 2;
1.1  skrll 		  break;
1.1  skrll 		case A_M1_NUM:
1.1  skrll 		  reg_efg |= 1 << 2;
1.1  skrll 		  break;
1.1  skrll 		case A_A0_NUM:
1.1  skrll 		  reg_efg |= 2 << 2;
1.1  skrll 		  break;
1.1  skrll 		case A_A1_NUM:
1.1  skrll 		  reg_efg |= 3 << 2;
1.1  skrll 		  break;
1.1  skrll 		default:
1.1  skrll 		  goto fail;
1.1  skrll 		}
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case A_A0:
1.1  skrll 	      if (user->type != DSP_REG_N || user->reg != A_A0_NUM)
1.1  skrll 		goto fail;
1.1  skrll 	      break;
1.1  skrll 	    case A_X0:
1.1  skrll 	      if (user->type != DSP_REG_N || user->reg != A_X0_NUM)
1.1  skrll 		goto fail;
1.1  skrll 	      break;
1.1  skrll 	    case A_X1:
1.1  skrll 	      if (user->type != DSP_REG_N || user->reg != A_X1_NUM)
1.1  skrll 		goto fail;
1.1  skrll 	      break;
1.1  skrll 	    case A_Y0:
1.1  skrll 	      if (user->type != DSP_REG_N || user->reg != A_Y0_NUM)
1.1  skrll 		goto fail;
1.1  skrll 	      break;
1.1  skrll 	    case A_Y1:
1.1  skrll 	      if (user->type != DSP_REG_N || user->reg != A_Y1_NUM)
1.1  skrll 		goto fail;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    case F_REG_M:
1.1  skrll 	    case D_REG_M:
1.1  skrll 	    case X_REG_M:
1.1  skrll 	    case V_REG_M:
1.1  skrll 	    case FPUL_M:
1.1  skrll 	    case FPSCR_M:
1.1  skrll 	      /* Opcode needs rn */
1.1  skrll 	      if (user->type != arg - F_REG_M + F_REG_N)
1.1  skrll 		goto fail;
1.1  skrll 	      reg_m = user->reg;
1.1  skrll 	      break;
1.1  skrll 	    case DX_REG_M:
1.1  skrll 	      if (user->type != D_REG_N && user->type != X_REG_N)
1.1  skrll 		goto fail;
1.1  skrll 	      reg_m = user->reg;
1.1  skrll 	      break;
1.1  skrll 	    case XMTRX_M4:
1.1  skrll 	      if (user->type != XMTRX_M4)
1.1  skrll 		goto fail;
1.1  skrll 	      reg_m = 4;
1.1  skrll 	      break;
1.1  skrll
1.1  skrll 	    default:
1.1  skrll 	      printf (_("unhandled %d\n"), arg);
1.1  skrll 	      goto fail;
1.1  skrll 	    }
1.1  skrll 	}
1.1  skrll       if ( !SH_MERGE_ARCH_SET_VALID (valid_arch, this_try->arch))
1.1  skrll 	goto fail;
1.1  skrll       valid_arch = SH_MERGE_ARCH_SET (valid_arch, this_try->arch);
1.1  skrll       return this_try;
1.1  skrll     fail:
1.1  skrll       ;
1.1  skrll     }
1.1  skrll
1.1  skrll   return 0;
1.1  skrll }
1.1  skrll
1.1  skrll static void
1.1  skrll insert (char *where, int how, int pcrel, sh_operand_info *op)
1.1  skrll {
1.1  skrll   fix_new_exp (frag_now,
1.1  skrll 	       where - frag_now->fr_literal,
1.1  skrll 	       2,
1.1  skrll 	       &op->immediate,
1.1  skrll 	       pcrel,
1.1  skrll 	       how);
1.1  skrll }
1.1  skrll
1.1  skrll static void
1.1  skrll insert4 (char * where, int how, int pcrel, sh_operand_info * op)
1.1  skrll {
1.1  skrll   fix_new_exp (frag_now,
1.1  skrll 	       where - frag_now->fr_literal,
1.1  skrll 	       4,
1.1  skrll 	       & op->immediate,
1.1  skrll 	       pcrel,
1.1  skrll 	       how);
1.1  skrll }
1.1  skrll static void
1.1  skrll build_relax (sh_opcode_info *opcode, sh_operand_info *op)
1.1  skrll {
1.1  skrll   int high_byte = target_big_endian ? 0 : 1;
1.1  skrll   char *p;
1.1  skrll
1.1  skrll   if (opcode->arg[0] == A_BDISP8)
1.1  skrll     {
1.1  skrll       int what = (opcode->nibbles[1] & 4) ? COND_JUMP_DELAY : COND_JUMP;
1.1  skrll       p = frag_var (rs_machine_dependent,
1.1  skrll 		    md_relax_table[C (what, COND32)].rlx_length,
1.1  skrll 		    md_relax_table[C (what, COND8)].rlx_length,
1.1  skrll 		    C (what, 0),
1.1  skrll 		    op->immediate.X_add_symbol,
1.1  skrll 		    op->immediate.X_add_number,
1.1  skrll 		    0);
1.1  skrll       p[high_byte] = (opcode->nibbles[0] << 4) | (opcode->nibbles[1]);
1.1  skrll     }
1.1  skrll   else if (opcode->arg[0] == A_BDISP12)
1.1  skrll     {
1.1  skrll       p = frag_var (rs_machine_dependent,
1.1  skrll 		    md_relax_table[C (UNCOND_JUMP, UNCOND32)].rlx_length,
1.1  skrll 		    md_relax_table[C (UNCOND_JUMP, UNCOND12)].rlx_length,
1.1  skrll 		    C (UNCOND_JUMP, 0),
1.1  skrll 		    op->immediate.X_add_symbol,
1.1  skrll 		    op->immediate.X_add_number,
1.1  skrll 		    0);
1.1  skrll       p[high_byte] = (opcode->nibbles[0] << 4);
1.1  skrll     }
1.1  skrll
1.1  skrll }
1.1  skrll
1.1  skrll /* Insert ldrs & ldre with fancy relocations that relaxation can recognize.  */
1.1  skrll
1.1  skrll static char *
1.1  skrll insert_loop_bounds (char *output, sh_operand_info *operand)
1.1  skrll {
1.1  skrll   char *name;
1.1  skrll   symbolS *end_sym;
1.1  skrll
1.1  skrll   /* Since the low byte of the opcode will be overwritten by the reloc, we
1.1  skrll      can just stash the high byte into both bytes and ignore endianness.  */
1.1  skrll   output[0] = 0x8c;
1.1  skrll   output[1] = 0x8c;
1.1  skrll   insert (output, BFD_RELOC_SH_LOOP_START, 1, operand);
1.1  skrll   insert (output, BFD_RELOC_SH_LOOP_END, 1, operand + 1);
1.1  skrll
1.1  skrll   if (sh_relax)
1.1  skrll     {
1.1  skrll       static int count = 0;
1.1  skrll
1.1  skrll       /* If the last loop insn is a two-byte-insn, it is in danger of being
1.1  skrll 	 swapped with the insn after it.  To prevent this, create a new
1.1  skrll 	 symbol - complete with SH_LABEL reloc - after the last loop insn.
1.1  skrll 	 If the last loop insn is four bytes long, the symbol will be
1.1  skrll 	 right in the middle, but four byte insns are not swapped anyways.  */
1.1  skrll       /* A REPEAT takes 6 bytes.  The SH has a 32 bit address space.
1.1  skrll 	 Hence a 9 digit number should be enough to count all REPEATs.  */
1.1  skrll       name = alloca (11);
1.1  skrll       sprintf (name, "_R%x", count++ & 0x3fffffff);
1.1  skrll       end_sym = symbol_new (name, undefined_section, 0, &zero_address_frag);
1.1  skrll       /* Make this a local symbol.  */
1.1  skrll #ifdef OBJ_COFF
1.1  skrll       SF_SET_LOCAL (end_sym);
1.1  skrll #endif /* OBJ_COFF */
1.1  skrll       symbol_table_insert (end_sym);
1.1  skrll       end_sym->sy_value = operand[1].immediate;
1.1  skrll       end_sym->sy_value.X_add_number += 2;
1.1  skrll       fix_new (frag_now, frag_now_fix (), 2, end_sym, 0, 1, BFD_RELOC_SH_LABEL);
1.1  skrll     }
1.1  skrll
1.1  skrll   output = frag_more (2);
1.1  skrll   output[0] = 0x8e;
1.1  skrll   output[1] = 0x8e;
1.1  skrll   insert (output, BFD_RELOC_SH_LOOP_START, 1, operand);
1.1  skrll   insert (output, BFD_RELOC_SH_LOOP_END, 1, operand + 1);
1.1  skrll
1.1  skrll   return frag_more (2);
1.1  skrll }
1.1  skrll
1.1  skrll /* Now we know what sort of opcodes it is, let's build the bytes.  */
1.1  skrll
1.1  skrll static unsigned int
1.1  skrll build_Mytes (sh_opcode_info *opcode, sh_operand_info *operand)
1.1  skrll {
1.1  skrll   int index;
1.1  skrll   char nbuf[8];
1.1  skrll   char *output;
1.1  skrll   unsigned int size = 2;
1.1  skrll   int low_byte = target_big_endian ? 1 : 0;
1.1  skrll   int max_index = 4;
1.1  skrll
1.1  skrll   nbuf[0] = 0;
1.1  skrll   nbuf[1] = 0;
1.1  skrll   nbuf[2] = 0;
1.1  skrll   nbuf[3] = 0;
1.1  skrll   nbuf[4] = 0;
1.1  skrll   nbuf[5] = 0;
1.1  skrll   nbuf[6] = 0;
1.1  skrll   nbuf[7] = 0;
1.1  skrll
1.1  skrll   if (SH_MERGE_ARCH_SET (opcode->arch, arch_op32))
1.1  skrll     {
1.1  skrll       output = frag_more (4);
1.1  skrll       size = 4;
1.1  skrll       max_index = 8;
1.1  skrll     }
1.1  skrll   else
1.1  skrll     output = frag_more (2);
1.1  skrll
1.1  skrll   for (index = 0; index < max_index; index++)
1.1  skrll     {
1.1  skrll       sh_nibble_type i = opcode->nibbles[index];
1.1  skrll       if (i < 16)
1.1  skrll 	{
1.1  skrll 	  nbuf[index] = i;
1.1  skrll 	}
1.1  skrll       else
1.1  skrll 	{
1.1  skrll 	  switch (i)
1.1  skrll 	    {
1.1  skrll 	    case REG_N:
1.1  skrll 	    case REG_N_D:
1.1  skrll 	      nbuf[index] = reg_n;
1.1  skrll 	      break;
1.1  skrll 	    case REG_M:
1.1  skrll 	      nbuf[index] = reg_m;
1.1  skrll 	      break;
1.1  skrll 	    case SDT_REG_N:
1.1  skrll 	      if (reg_n < 2 || reg_n > 5)
1.1  skrll 		as_bad (_("Invalid register: 'r%d'"), reg_n);
1.1  skrll 	      nbuf[index] = (reg_n & 3) | 4;
1.1  skrll 	      break;
1.1  skrll 	    case REG_NM:
1.1  skrll 	      nbuf[index] = reg_n | (reg_m >> 2);
1.1  skrll 	      break;
1.1  skrll 	    case REG_B:
1.1  skrll 	      nbuf[index] = reg_b | 0x08;
1.1  skrll 	      break;
1.1  skrll 	    case REG_N_B01:
1.1  skrll 	      nbuf[index] = reg_n | 0x01;
1.1  skrll 	      break;
1.1  skrll 	    case IMM0_3s:
1.1  skrll 	      nbuf[index] |= 0x08;
1.1  skrll 	    case IMM0_3c:
1.1  skrll 	      insert (output + low_byte, BFD_RELOC_SH_IMM3, 0, operand);
1.1  skrll 	      break;
1.1  skrll 	    case IMM0_3Us:
1.1  skrll 	      nbuf[index] |= 0x80;
1.1  skrll 	    case IMM0_3Uc:
1.1  skrll 	      insert (output + low_byte, BFD_RELOC_SH_IMM3U, 0, operand);
1.1  skrll 	      break;
1.1  skrll 	    case DISP0_12:
1.1  skrll 	      insert (output + 2, BFD_RELOC_SH_DISP12, 0, operand);
1.1  skrll 	      break;
1.1  skrll 	    case DISP0_12BY2:
1.1  skrll 	      insert (output + 2, BFD_RELOC_SH_DISP12BY2, 0, operand);
1.1  skrll 	      break;
1.1  skrll 	    case DISP0_12BY4:
1.1  skrll 	      insert (output + 2, BFD_RELOC_SH_DISP12BY4, 0, operand);
1.1  skrll 	      break;
1.1  skrll 	    case DISP0_12BY8:
1.1  skrll 	      insert (output + 2, BFD_RELOC_SH_DISP12BY8, 0, operand);
1.1  skrll 	      break;
1.1  skrll 	    case DISP1_12:
1.1  skrll 	      insert (output + 2, BFD_RELOC_SH_DISP12, 0, operand+1);
1.1  skrll 	      break;
1.1  skrll 	    case DISP1_12BY2:
1.1  skrll 	      insert (output + 2, BFD_RELOC_SH_DISP12BY2, 0, operand+1);
1.1  skrll 	      break;
1.1  skrll 	    case DISP1_12BY4:
1.1  skrll 	      insert (output + 2, BFD_RELOC_SH_DISP12BY4, 0, operand+1);
1.1  skrll 	      break;
1.1  skrll 	    case DISP1_12BY8:
1.1  skrll 	      insert (output + 2, BFD_RELOC_SH_DISP12BY8, 0, operand+1);
1.1  skrll 	      break;
1.1  skrll 	    case IMM0_20_4:
1.1  skrll 	      break;
1.1  skrll 	    case IMM0_20:
1.1  skrll 	      insert4 (output, BFD_RELOC_SH_DISP20, 0, operand);
1.1  skrll 	      break;
1.1  skrll 	    case IMM0_20BY8:
1.1  skrll 	      insert4 (output, BFD_RELOC_SH_DISP20BY8, 0, operand);
1.1  skrll 	      break;
1.1  skrll 	    case IMM0_4BY4:
1.1  skrll 	      insert (output + low_byte, BFD_RELOC_SH_IMM4BY4, 0, operand);
1.1  skrll 	      break;
1.1  skrll 	    case IMM0_4BY2:
1.1  skrll 	      insert (output + low_byte, BFD_RELOC_SH_IMM4BY2, 0, operand);
1.1  skrll 	      break;
1.1  skrll 	    case IMM0_4:
1.1  skrll 	      insert (output + low_byte, BFD_RELOC_SH_IMM4, 0, operand);
1.1  skrll 	      break;
1.1  skrll 	    case IMM1_4BY4:
1.1  skrll 	      insert (output + low_byte, BFD_RELOC_SH_IMM4BY4, 0, operand + 1);
1.1  skrll 	      break;
1.1  skrll 	    case IMM1_4BY2:
1.1  skrll 	      insert (output + low_byte, BFD_RELOC_SH_IMM4BY2, 0, operand + 1);
1.1  skrll 	      break;
1.1  skrll 	    case IMM1_4:
1.1  skrll 	      insert (output + low_byte, BFD_RELOC_SH_IMM4, 0, operand + 1);
1.1  skrll 	      break;
1.1  skrll 	    case IMM0_8BY4:
1.1  skrll 	      insert (output + low_byte, BFD_RELOC_SH_IMM8BY4, 0, operand);
1.1  skrll 	      break;
1.1  skrll 	    case IMM0_8BY2:
1.1  skrll 	      insert (output + low_byte, BFD_RELOC_SH_IMM8BY2, 0, operand);
1.1  skrll 	      break;
1.1  skrll 	    case IMM0_8:
1.1  skrll 	      insert (output + low_byte, BFD_RELOC_SH_IMM8, 0, operand);
1.1  skrll 	      break;
1.1  skrll 	    case IMM1_8BY4:
1.1  skrll 	      insert (output + low_byte, BFD_RELOC_SH_IMM8BY4, 0, operand + 1);
1.1  skrll 	      break;
1.1  skrll 	    case IMM1_8BY2:
1.1  skrll 	      insert (output + low_byte, BFD_RELOC_SH_IMM8BY2, 0, operand + 1);
1.1  skrll 	      break;
1.1  skrll 	    case IMM1_8:
1.1  skrll 	      insert (output + low_byte, BFD_RELOC_SH_IMM8, 0, operand + 1);
1.1  skrll 	      break;
1.1  skrll 	    case PCRELIMM_8BY4:
1.1  skrll 	      insert (output, BFD_RELOC_SH_PCRELIMM8BY4,
1.1  skrll 		      operand->type != A_DISP_PC_ABS, operand);
1.1  skrll 	      break;
1.1  skrll 	    case PCRELIMM_8BY2:
1.1  skrll 	      insert (output, BFD_RELOC_SH_PCRELIMM8BY2,
1.1  skrll 		      operand->type != A_DISP_PC_ABS, operand);
1.1  skrll 	      break;
1.1  skrll 	    case REPEAT:
1.1  skrll 	      output = insert_loop_bounds (output, operand);
1.1  skrll 	      nbuf[index] = opcode->nibbles[3];
1.1  skrll 	      operand += 2;
1.1  skrll 	      break;
1.1  skrll 	    default:
1.1  skrll 	      printf (_("failed for %d\n"), i);
1.1  skrll 	    }
1.1  skrll 	}
1.1  skrll     }
1.1  skrll   if (!target_big_endian)
1.1  skrll     {
1.1  skrll       output[1] = (nbuf[0] << 4) | (nbuf[1]);
1.1  skrll       output[0] = (nbuf[2] << 4) | (nbuf[3]);
1.1  skrll     }
1.1  skrll   else
1.1  skrll     {
1.1  skrll       output[0] = (nbuf[0] << 4) | (nbuf[1]);
1.1  skrll       output[1] = (nbuf[2] << 4) | (nbuf[3]);
1.1  skrll     }
1.1  skrll   if (SH_MERGE_ARCH_SET (opcode->arch, arch_op32))
1.1  skrll     {
1.1  skrll       if (!target_big_endian)
1.1  skrll 	{
1.1  skrll 	  output[3] = (nbuf[4] << 4) | (nbuf[5]);
1.1  skrll 	  output[2] = (nbuf[6] << 4) | (nbuf[7]);
1.1  skrll 	}
1.1  skrll       else
1.1  skrll 	{
1.1  skrll 	  output[2] = (nbuf[4] << 4) | (nbuf[5]);
1.1  skrll 	  output[3] = (nbuf[6] << 4) | (nbuf[7]);
1.1  skrll 	}
1.1  skrll     }
1.1  skrll   return size;
1.1  skrll }
1.1  skrll
1.1  skrll /* Find an opcode at the start of *STR_P in the hash table, and set
1.1  skrll    *STR_P to the first character after the last one read.  */
1.1  skrll
1.1  skrll static sh_opcode_info *
1.1  skrll find_cooked_opcode (char **str_p)
1.1  skrll {
1.1  skrll   char *str = *str_p;
1.1  skrll   unsigned char *op_start;
1.1  skrll   unsigned char *op_end;
1.1  skrll   char name[20];
1.1  skrll   int nlen = 0;
1.1  skrll
1.1  skrll   /* Drop leading whitespace.  */
1.1  skrll   while (*str == ' ')
1.1  skrll     str++;
1.1  skrll
1.1  skrll   /* Find the op code end.
1.1  skrll      The pre-processor will eliminate whitespace in front of
1.1  skrll      any '@' after the first argument; we may be called from
1.1  skrll      assemble_ppi, so the opcode might be terminated by an '@'.  */
1.1  skrll   for (op_start = op_end = (unsigned char *) str;
1.1  skrll        *op_end
1.1  skrll        && nlen < 20
1.1  skrll        && !is_end_of_line[*op_end] && *op_end != ' ' && *op_end != '@';
1.1  skrll        op_end++)
1.1  skrll     {
1.1  skrll       unsigned char c = op_start[nlen];
1.1  skrll
1.1  skrll       /* The machine independent code will convert CMP/EQ into cmp/EQ
1.1  skrll 	 because it thinks the '/' is the end of the symbol.  Moreover,
1.1  skrll 	 all but the first sub-insn is a parallel processing insn won't
1.1  skrll 	 be capitalized.  Instead of hacking up the machine independent
1.1  skrll 	 code, we just deal with it here.  */
1.1  skrll       c = TOLOWER (c);
1.1  skrll       name[nlen] = c;
1.1  skrll       nlen++;
1.1  skrll     }
1.1  skrll
1.1  skrll   name[nlen] = 0;
1.1  skrll   *str_p = (char *) op_end;
1.1  skrll
1.1  skrll   if (nlen == 0)
1.1  skrll     as_bad (_("can't find opcode "));
1.1  skrll
1.1  skrll   return (sh_opcode_info *) hash_find (opcode_hash_control, name);
1.1  skrll }
1.1  skrll
1.1  skrll /* Assemble a parallel processing insn.  */
1.1  skrll #define DDT_BASE 0xf000 /* Base value for double data transfer insns */
1.1  skrll
1.1  skrll static unsigned int
1.1  skrll assemble_ppi (char *op_end, sh_opcode_info *opcode)
1.1  skrll {
1.1  skrll   int movx = 0;
1.1  skrll   int movy = 0;
1.1  skrll   int cond = 0;
1.1  skrll   int field_b = 0;
1.1  skrll   char *output;
1.1  skrll   int move_code;
1.1  skrll   unsigned int size;
1.1  skrll
1.1  skrll   for (;;)
1.1  skrll     {
1.1  skrll       sh_operand_info operand[3];
1.1  skrll
1.1  skrll       /* Some insn ignore one or more register fields, e.g. psts machl,a0.
1.1  skrll 	 Make sure we encode a defined insn pattern.  */
1.1  skrll       reg_x = 0;
1.1  skrll       reg_y = 0;
1.1  skrll       reg_n = 0;
1.1  skrll
1.1  skrll       if (opcode->arg[0] != A_END)
1.1  skrll 	op_end = get_operands (opcode, op_end, operand);
1.1  skrll     try_another_opcode:
1.1  skrll       opcode = get_specific (opcode, operand);
1.1  skrll       if (opcode == 0)
1.1  skrll 	{
1.1  skrll 	  /* Couldn't find an opcode which matched the operands.  */
1.1  skrll 	  char *where = frag_more (2);
1.1  skrll 	  size = 2;
1.1  skrll
1.1  skrll 	  where[0] = 0x0;
1.1  skrll 	  where[1] = 0x0;
1.1  skrll 	  as_bad (_("invalid operands for opcode"));
1.1  skrll 	  return size;
1.1  skrll 	}
1.1  skrll
1.1  skrll       if (opcode->nibbles[0] != PPI)
1.1  skrll 	as_bad (_("insn can't be combined with parallel processing insn"));
1.1  skrll
1.1  skrll       switch (opcode->nibbles[1])
1.1  skrll 	{
1.1  skrll
1.1  skrll 	case NOPX:
1.1  skrll 	  if (movx)
1.1  skrll 	    as_bad (_("multiple movx specifications"));
1.1  skrll 	  movx = DDT_BASE;
1.1  skrll 	  break;
1.1  skrll 	case NOPY:
1.1  skrll 	  if (movy)
1.1  skrll 	    as_bad (_("multiple movy specifications"));
1.1  skrll 	  movy = DDT_BASE;
1.1  skrll 	  break;
1.1  skrll
1.1  skrll 	case MOVX_NOPY:
1.1  skrll 	  if (movx)
1.1  skrll 	    as_bad (_("multiple movx specifications"));
1.1  skrll 	  if ((reg_n < 4 || reg_n > 5)
1.1  skrll 	      && (reg_n < 0 || reg_n > 1))
1.1  skrll 	    as_bad (_("invalid movx address register"));
1.1  skrll 	  if (movy && movy != DDT_BASE)
1.1  skrll 	    as_bad (_("insn cannot be combined with non-nopy"));
1.1  skrll 	  movx = ((((reg_n & 1) != 0) << 9)
1.1  skrll 		  + (((reg_n & 4) == 0) << 8)
1.1  skrll 		  + (reg_x << 6)
1.1  skrll 		  + (opcode->nibbles[2] << 4)
1.1  skrll 		  + opcode->nibbles[3]
1.1  skrll 		  + DDT_BASE);
1.1  skrll 	  break;
1.1  skrll
1.1  skrll 	case MOVY_NOPX:
1.1  skrll 	  if (movy)
1.1  skrll 	    as_bad (_("multiple movy specifications"));
1.1  skrll 	  if ((reg_n < 6 || reg_n > 7)
1.1  skrll 	      && (reg_n < 2 || reg_n > 3))
1.1  skrll 	    as_bad (_("invalid movy address register"));
1.1  skrll 	  if (movx && movx != DDT_BASE)
1.1  skrll 	    as_bad (_("insn cannot be combined with non-nopx"));
1.1  skrll 	  movy = ((((reg_n & 1) != 0) << 8)
1.1  skrll 		  + (((reg_n & 4) == 0) << 9)
1.1  skrll 		  + (reg_y << 6)
1.1  skrll 		  + (opcode->nibbles[2] << 4)
1.1  skrll 		  + opcode->nibbles[3]
1.1  skrll 		  + DDT_BASE);
1.1  skrll 	  break;
1.1  skrll
1.1  skrll 	case MOVX:
1.1  skrll 	  if (movx)
1.1  skrll 	    as_bad (_("multiple movx specifications"));
1.1  skrll 	  if (movy & 0x2ac)
1.1  skrll 	    as_bad (_("previous movy requires nopx"));
1.1  skrll 	  if (reg_n < 4 || reg_n > 5)
1.1  skrll 	    as_bad (_("invalid movx address register"));
1.1  skrll 	  if (opcode->nibbles[2] & 8)
1.1  skrll 	    {
1.1  skrll 	      if (reg_m == A_A1_NUM)
1.1  skrll 		movx = 1 << 7;
1.1  skrll 	      else if (reg_m != A_A0_NUM)
1.1  skrll 		as_bad (_("invalid movx dsp register"));
1.1  skrll 	    }
1.1  skrll 	  else
1.1  skrll 	    {
1.1  skrll 	      if (reg_x > 1)
1.1  skrll 		as_bad (_("invalid movx dsp register"));
1.1  skrll 	      movx = reg_x << 7;
1.1  skrll 	    }
1.1  skrll 	  movx += ((reg_n - 4) << 9) + (opcode->nibbles[2] << 2) + DDT_BASE;
1.1  skrll 	  break;
1.1  skrll
1.1  skrll 	case MOVY:
1.1  skrll 	  if (movy)
1.1  skrll 	    as_bad (_("multiple movy specifications"));
1.1  skrll 	  if (movx & 0x153)
1.1  skrll 	    as_bad (_("previous movx requires nopy"));
1.1  skrll 	  if (opcode->nibbles[2] & 8)
1.1  skrll 	    {
1.1  skrll 	      /* Bit 3 in nibbles[2] is intended for bit 4 of the opcode,
1.1  skrll 		 so add 8 more.  */
1.1  skrll 	      movy = 8;
1.1  skrll 	      if (reg_m == A_A1_NUM)
1.1  skrll 		movy += 1 << 6;
1.1  skrll 	      else if (reg_m != A_A0_NUM)
1.1  skrll 		as_bad (_("invalid movy dsp register"));
1.1  skrll 	    }
1.1  skrll 	  else
1.1  skrll 	    {
1.1  skrll 	      if (reg_y > 1)
1.1  skrll 		as_bad (_("invalid movy dsp register"));
1.1  skrll 	      movy = reg_y << 6;
1.1  skrll 	    }
1.1  skrll 	  if (reg_n < 6 || reg_n > 7)
1.1  skrll 	    as_bad (_("invalid movy address register"));
1.1  skrll 	  movy += ((reg_n - 6) << 8) + opcode->nibbles[2] + DDT_BASE;
1.1  skrll 	  break;
1.1  skrll
1.1  skrll 	case PSH:
1.1  skrll 	  if (operand[0].immediate.X_op != O_constant)
1.1  skrll 	    as_bad (_("dsp immediate shift value not constant"));
1.1  skrll 	  field_b = ((opcode->nibbles[2] << 12)
1.1  skrll 		     | (operand[0].immediate.X_add_number & 127) << 4
1.1  skrll 		     | reg_n);
1.1  skrll 	  break;
1.1  skrll 	case PPI3NC:
1.1  skrll 	  if (cond)
1.1  skrll 	    {
1.1  skrll 	      opcode++;
1.1  skrll 	      goto try_another_opcode;
1.1  skrll 	    }
1.1  skrll 	  /* Fall through.  */
1.1  skrll 	case PPI3:
1.1  skrll 	  if (field_b)
1.1  skrll 	    as_bad (_("multiple parallel processing specifications"));
1.1  skrll 	  field_b = ((opcode->nibbles[2] << 12) + (opcode->nibbles[3] << 8)
1.1  skrll 		     + (reg_x << 6) + (reg_y << 4) + reg_n);
1.1  skrll 	  switch (opcode->nibbles[4])
1.1  skrll 	    {
1.1  skrll 	    case HEX_0:
1.1  skrll 	    case HEX_XX00:
1.1  skrll 	    case HEX_00YY:
1.1  skrll 	      break;
1.1  skrll 	    case HEX_1:
1.1  skrll 	    case HEX_4:
1.1  skrll 	      field_b += opcode->nibbles[4] << 4;
1.1  skrll 	      break;
1.1  skrll 	    default:
1.1  skrll 	      abort ();
1.1  skrll 	    }
1.1  skrll 	  break;
1.1  skrll 	case PDC:
1.1  skrll 	  if (cond)
1.1  skrll 	    as_bad (_("multiple condition specifications"));
1.1  skrll 	  cond = opcode->nibbles[2] << 8;
1.1  skrll 	  if (*op_end)
1.1  skrll 	    goto skip_cond_check;
1.1  skrll 	  break;
1.1  skrll 	case PPIC:
1.1  skrll 	  if (field_b)
1.1  skrll 	    as_bad (_("multiple parallel processing specifications"));
1.1  skrll 	  field_b = ((opcode->nibbles[2] << 12) + (opcode->nibbles[3] << 8)
1.1  skrll 		     + cond + (reg_x << 6) + (reg_y << 4) + reg_n);
1.1  skrll 	  cond = 0;
1.1  skrll 	  switch (opcode->nibbles[4])
1.1  skrll 	    {
1.1  skrll 	    case HEX_0:
1.1  skrll 	    case HEX_XX00:
1.1  skrll 	    case HEX_00YY:
1.1  skrll 	      break;
1.1  skrll 	    case HEX_1:
1.1  skrll 	    case HEX_4:
1.1  skrll 	      field_b += opcode->nibbles[4] << 4;
1.1  skrll 	      break;
1.1  skrll 	    default:
1.1  skrll 	      abort ();
1.1  skrll 	    }
1.1  skrll 	  break;
1.1  skrll 	case PMUL:
1.1  skrll 	  if (field_b)
1.1  skrll 	    {
1.1  skrll 	      if ((field_b & 0xef00) == 0xa100)
1.1  skrll 		field_b -= 0x8100;
1.1  skrll 	      /* pclr Dz pmuls Se,Sf,Dg */
1.1  skrll 	      else if ((field_b & 0xff00) == 0x8d00
1.1  skrll 		       && (SH_MERGE_ARCH_SET_VALID (valid_arch, arch_sh4al_dsp_up)))
1.1  skrll 		{
1.1  skrll 		  valid_arch = SH_MERGE_ARCH_SET (valid_arch, arch_sh4al_dsp_up);
1.1  skrll 		  field_b -= 0x8cf0;
1.1  skrll 		}
1.1  skrll 	      else
1.1  skrll 		as_bad (_("insn cannot be combined with pmuls"));
1.1  skrll 	      switch (field_b & 0xf)
1.1  skrll 		{
1.1  skrll 		case A_X0_NUM:
1.1  skrll 		  field_b += 0 - A_X0_NUM;
1.1  skrll 		  break;
1.1  skrll 		case A_Y0_NUM:
1.1  skrll 		  field_b += 1 - A_Y0_NUM;
1.1  skrll 		  break;
1.1  skrll 		case A_A0_NUM:
1.1  skrll 		  field_b += 2 - A_A0_NUM;
1.1  skrll 		  break;
1.1  skrll 		case A_A1_NUM:
1.1  skrll 		  field_b += 3 - A_A1_NUM;
1.1  skrll 		  break;
1.1  skrll 		default:
1.1  skrll 		  as_bad (_("bad combined pmuls output operand"));
1.1  skrll 		}
1.1  skrll 		/* Generate warning if the destination register for padd / psub
1.1  skrll 		   and pmuls is the same ( only for A0 or A1 ).
1.1  skrll 		   If the last nibble is 1010 then A0 is used in both
1.1  skrll 		   padd / psub and pmuls. If it is 1111 then A1 is used
1.1  skrll 		   as destination register in both padd / psub and pmuls.  */
1.1  skrll
1.1  skrll 		if ((((field_b | reg_efg) & 0x000F) == 0x000A)
1.1  skrll 		    || (((field_b | reg_efg) & 0x000F) == 0x000F))
1.1  skrll 		  as_warn (_("destination register is same for parallel insns"));
1.1  skrll 	    }
1.1  skrll 	  field_b += 0x4000 + reg_efg;
1.1  skrll 	  break;
1.1  skrll 	default:
1.1  skrll 	  abort ();
1.1  skrll 	}
1.1  skrll       if (cond)
1.1  skrll 	{
1.1  skrll 	  as_bad (_("condition not followed by conditionalizable insn"));
1.1  skrll 	  cond = 0;
1.1  skrll 	}
1.1  skrll       if (! *op_end)
1.1  skrll 	break;
1.1  skrll     skip_cond_check:
1.1  skrll       opcode = find_cooked_opcode (&op_end);
1.1  skrll       if (opcode == NULL)
1.1  skrll 	{
1.1  skrll 	  (as_bad
1.1  skrll 	   (_("unrecognized characters at end of parallel processing insn")));
1.1  skrll 	  break;
1.1  skrll 	}
1.1  skrll     }
1.1  skrll
1.1  skrll   move_code = movx | movy;
1.1  skrll   if (field_b)
1.1  skrll     {
1.1  skrll       /* Parallel processing insn.  */
1.1  skrll       unsigned long ppi_code = (movx | movy | 0xf800) << 16 | field_b;
1.1  skrll
1.1  skrll       output = frag_more (4);
1.1  skrll       size = 4;
1.1  skrll       if (! target_big_endian)
1.1  skrll 	{
1.1  skrll 	  output[3] = ppi_code >> 8;
1.1  skrll 	  output[2] = ppi_code;
1.1  skrll 	}
1.1  skrll       else
1.1  skrll 	{
1.1  skrll 	  output[2] = ppi_code >> 8;
1.1  skrll 	  output[3] = ppi_code;
1.1  skrll 	}
1.1  skrll       move_code |= 0xf800;
1.1  skrll     }
1.1  skrll   else
1.1  skrll     {
1.1  skrll       /* Just a double data transfer.  */
1.1  skrll       output = frag_more (2);
1.1  skrll       size = 2;
1.1  skrll     }
1.1  skrll   if (! target_big_endian)
1.1  skrll     {
1.1  skrll       output[1] = move_code >> 8;
1.1  skrll       output[0] = move_code;
1.1  skrll     }
1.1  skrll   else
1.1  skrll     {
1.1  skrll       output[0] = move_code >> 8;
1.1  skrll       output[1] = move_code;
1.1  skrll     }
1.1  skrll   return size;
1.1  skrll }
1.1  skrll
1.1  skrll /* This is the guts of the machine-dependent assembler.  STR points to a
1.1  skrll    machine dependent instruction.  This function is supposed to emit
1.1  skrll    the frags/bytes it assembles to.  */
1.1  skrll
1.1  skrll void
1.1  skrll md_assemble (char *str)
1.1  skrll {
1.1  skrll   char *op_end;
1.1  skrll   sh_operand_info operand[3];
1.1  skrll   sh_opcode_info *opcode;
1.1  skrll   unsigned int size = 0;
1.1  skrll   char *initial_str = str;
1.1  skrll
1.1  skrll #ifdef HAVE_SH64
1.1  skrll   if (sh64_isa_mode == sh64_isa_shmedia)
1.1  skrll     {
1.1  skrll       shmedia_md_assemble (str);
1.1  skrll       return;
1.1  skrll     }
1.1  skrll   else
1.1  skrll     {
1.1  skrll       /* If we've seen pseudo-directives, make sure any emitted data or
1.1  skrll 	 frags are marked as data.  */
1.1  skrll       if (!seen_insn)
1.1  skrll 	{
1.1  skrll 	  sh64_update_contents_mark (TRUE);
1.1  skrll 	  sh64_set_contents_type (CRT_SH5_ISA16);
1.1  skrll 	}
1.1  skrll
1.1  skrll       seen_insn = TRUE;
1.1  skrll     }
1.1  skrll #endif /* HAVE_SH64 */
1.1  skrll
1.1  skrll   opcode = find_cooked_opcode (&str);
1.1  skrll   op_end = str;
1.1  skrll
1.1  skrll   if (opcode == NULL)
1.1  skrll     {
1.1  skrll       /* The opcode is not in the hash table.
1.1  skrll 	 This means we definitely have an assembly failure,
1.1  skrll 	 but the instruction may be valid in another CPU variant.
1.1  skrll 	 In this case emit something better than 'unknown opcode'.
1.1  skrll 	 Search the full table in sh-opc.h to check. */
1.1  skrll
1.1  skrll       char *name = initial_str;
1.1  skrll       int name_length = 0;
1.1  skrll       const sh_opcode_info *op;
1.1  skrll       int found = 0;
1.1  skrll
1.1  skrll       /* identify opcode in string */
1.1  skrll       while (ISSPACE (*name))
1.1  skrll 	{
1.1  skrll 	  name++;
1.1  skrll 	}
1.1  skrll       while (!ISSPACE (name[name_length]))
1.1  skrll 	{
1.1  skrll 	  name_length++;
1.1  skrll 	}
1.1  skrll
1.1  skrll       /* search for opcode in full list */
1.1  skrll       for (op = sh_table; op->name; op++)
1.1  skrll 	{
1.1  skrll 	  if (strncasecmp (op->name, name, name_length) == 0
1.1  skrll 	      && op->name[name_length] == '\0')
1.1  skrll 	    {
1.1  skrll 	      found = 1;
1.1  skrll 	      break;
1.1  skrll 	    }
1.1  skrll 	}
1.1  skrll
1.1  skrll       if ( found )
1.1  skrll 	{
1.1  skrll 	  as_bad (_("opcode not valid for this cpu variant"));
1.1  skrll 	}
1.1  skrll       else
1.1  skrll 	{
1.1  skrll 	  as_bad (_("unknown opcode"));
1.1  skrll 	}
1.1  skrll       return;
1.1  skrll     }
1.1  skrll
1.1  skrll   if (sh_relax
1.1  skrll       && ! seg_info (now_seg)->tc_segment_info_data.in_code)
1.1  skrll     {
1.1  skrll       /* Output a CODE reloc to tell the linker that the following
1.1  skrll          bytes are instructions, not data.  */
1.1  skrll       fix_new (frag_now, frag_now_fix (), 2, &abs_symbol, 0, 0,
1.1  skrll 	       BFD_RELOC_SH_CODE);
1.1  skrll       seg_info (now_seg)->tc_segment_info_data.in_code = 1;
1.1  skrll     }
1.1  skrll
1.1  skrll   if (opcode->nibbles[0] == PPI)
1.1  skrll     {
1.1  skrll       size = assemble_ppi (op_end, opcode);
1.1  skrll     }
1.1  skrll   else
1.1  skrll     {
1.1  skrll       if (opcode->arg[0] == A_BDISP12
1.1  skrll 	  || opcode->arg[0] == A_BDISP8)
1.1  skrll 	{
1.1  skrll 	  /* Since we skip get_specific here, we have to check & update
1.1  skrll 	     valid_arch now.  */
1.1  skrll 	  if (SH_MERGE_ARCH_SET_VALID (valid_arch, opcode->arch))
1.1  skrll 	    valid_arch = SH_MERGE_ARCH_SET (valid_arch, opcode->arch);
1.1  skrll 	  else
1.1  skrll 	    as_bad (_("Delayed branches not available on SH1"));
1.1  skrll 	  parse_exp (op_end + 1, &operand[0]);
1.1  skrll 	  build_relax (opcode, &operand[0]);
1.1  skrll
1.1  skrll 	  /* All branches are currently 16 bit.  */
1.1  skrll 	  size = 2;
1.1  skrll 	}
1.1  skrll       else
1.1  skrll 	{
1.1  skrll 	  if (opcode->arg[0] == A_END)
1.1  skrll 	    {
1.1  skrll 	      /* Ignore trailing whitespace.  If there is any, it has already
1.1  skrll 		 been compressed to a single space.  */
1.1  skrll 	      if (*op_end == ' ')
1.1  skrll 		op_end++;
1.1  skrll 	    }
1.1  skrll 	  else
1.1  skrll 	    {
1.1  skrll 	      op_end = get_operands (opcode, op_end, operand);
1.1  skrll 	    }
1.1  skrll 	  opcode = get_specific (opcode, operand);
1.1  skrll
1.1  skrll 	  if (opcode == 0)
1.1  skrll 	    {
1.1  skrll 	      /* Couldn't find an opcode which matched the operands.  */
1.1  skrll 	      char *where = frag_more (2);
1.1  skrll 	      size = 2;
1.1  skrll
1.1  skrll 	      where[0] = 0x0;
1.1  skrll 	      where[1] = 0x0;
1.1  skrll 	      as_bad (_("invalid operands for opcode"));
1.1  skrll 	    }
1.1  skrll 	  else
1.1  skrll 	    {
1.1  skrll 	      if (*op_end)
1.1  skrll 		as_bad (_("excess operands: '%s'"), op_end);
1.1  skrll
1.1  skrll 	      size = build_Mytes (opcode, operand);
1.1  skrll 	    }
1.1  skrll 	}
1.1  skrll     }
1.1  skrll
1.1  skrll   dwarf2_emit_insn (size);
1.1  skrll }
1.1  skrll
1.1  skrll /* This routine is called each time a label definition is seen.  It
1.1  skrll    emits a BFD_RELOC_SH_LABEL reloc if necessary.  */
1.1  skrll
1.1  skrll void
1.1  skrll sh_frob_label (symbolS *sym)
1.1  skrll {
1.1  skrll   static fragS *last_label_frag;
1.1  skrll   static int last_label_offset;
1.1  skrll
1.1  skrll   if (sh_relax
1.1  skrll       && seg_info (now_seg)->tc_segment_info_data.in_code)
1.1  skrll     {
1.1  skrll       int offset;
1.1  skrll
1.1  skrll       offset = frag_now_fix ();
1.1  skrll       if (frag_now != last_label_frag
1.1  skrll 	  || offset != last_label_offset)
1.1  skrll 	{
1.1  skrll 	  fix_new (frag_now, offset, 2, &abs_symbol, 0, 0, BFD_RELOC_SH_LABEL);
1.1  skrll 	  last_label_frag = frag_now;
1.1  skrll 	  last_label_offset = offset;
1.1  skrll 	}
1.1  skrll     }
1.1  skrll
1.1  skrll   dwarf2_emit_label (sym);
1.1  skrll }
1.1  skrll
1.1  skrll /* This routine is called when the assembler is about to output some
1.1  skrll    data.  It emits a BFD_RELOC_SH_DATA reloc if necessary.  */
1.1  skrll
1.1  skrll void
1.1  skrll sh_flush_pending_output (void)
1.1  skrll {
1.1  skrll   if (sh_relax
1.1  skrll       && seg_info (now_seg)->tc_segment_info_data.in_code)
1.1  skrll     {
1.1  skrll       fix_new (frag_now, frag_now_fix (), 2, &abs_symbol, 0, 0,
1.1  skrll 	       BFD_RELOC_SH_DATA);
1.1  skrll       seg_info (now_seg)->tc_segment_info_data.in_code = 0;
1.1  skrll     }
1.1  skrll }
1.1  skrll
1.1  skrll symbolS *
1.1  skrll md_undefined_symbol (char *name ATTRIBUTE_UNUSED)
1.1  skrll {
1.1  skrll   return 0;
1.1  skrll }
1.1  skrll
1.1  skrll /* Various routines to kill one day.  */
1.1  skrll
1.1  skrll char *
1.1  skrll md_atof (int type, char *litP, int *sizeP)
1.1  skrll {
1.1  skrll   return ieee_md_atof (type, litP, sizeP, target_big_endian);
1.1  skrll }
1.1  skrll
1.1  skrll /* Handle the .uses pseudo-op.  This pseudo-op is used just before a
1.1  skrll    call instruction.  It refers to a label of the instruction which
1.1  skrll    loads the register which the call uses.  We use it to generate a
1.1  skrll    special reloc for the linker.  */
1.1  skrll
1.1  skrll static void
1.1  skrll s_uses (int ignore ATTRIBUTE_UNUSED)
1.1  skrll {
1.1  skrll   expressionS ex;
1.1  skrll
1.1  skrll   if (! sh_relax)
1.1  skrll     as_warn (_(".uses pseudo-op seen when not relaxing"));
1.1  skrll
1.1  skrll   expression (&ex);
1.1  skrll
1.1  skrll   if (ex.X_op != O_symbol || ex.X_add_number != 0)
1.1  skrll     {
1.1  skrll       as_bad (_("bad .uses format"));
1.1  skrll       ignore_rest_of_line ();
1.1  skrll       return;
1.1  skrll     }
1.1  skrll
1.1  skrll   fix_new_exp (frag_now, frag_now_fix (), 2, &ex, 1, BFD_RELOC_SH_USES);
1.1  skrll
1.1  skrll   demand_empty_rest_of_line ();
1.1  skrll }
1.1  skrll
1.1  skrll enum options
1.1  skrll {
1.1  skrll   OPTION_RELAX = OPTION_MD_BASE,
1.1  skrll   OPTION_BIG,
1.1  skrll   OPTION_LITTLE,
1.1  skrll   OPTION_SMALL,
1.1  skrll   OPTION_DSP,
1.1  skrll   OPTION_ISA,
1.1  skrll   OPTION_RENESAS,
1.1  skrll   OPTION_ALLOW_REG_PREFIX,
1.1  skrll #ifdef HAVE_SH64
1.1  skrll   OPTION_ABI,
1.1  skrll   OPTION_NO_MIX,
1.1  skrll   OPTION_SHCOMPACT_CONST_CRANGE,
1.1  skrll   OPTION_NO_EXPAND,
1.1  skrll   OPTION_PT32,
1.1  skrll #endif
1.1  skrll   OPTION_H_TICK_HEX,
1.1  skrll   OPTION_DUMMY  /* Not used.  This is just here to make it easy to add and subtract options from this enum.  */
1.1  skrll };
1.1  skrll
1.1  skrll const char *md_shortopts = "";
1.1  skrll struct option md_longopts[] =
1.1  skrll {
1.1  skrll   {"relax", no_argument, NULL, OPTION_RELAX},
1.1  skrll   {"big", no_argument, NULL, OPTION_BIG},
1.1  skrll   {"little", no_argument, NULL, OPTION_LITTLE},
1.1  skrll   /* The next two switches are here because the
1.1  skrll      generic parts of the linker testsuite uses them.  */
1.1  skrll   {"EB", no_argument, NULL, OPTION_BIG},
1.1  skrll   {"EL", no_argument, NULL, OPTION_LITTLE},
1.1  skrll   {"small", no_argument, NULL, OPTION_SMALL},
1.1  skrll   {"dsp", no_argument, NULL, OPTION_DSP},
1.1  skrll   {"isa", required_argument, NULL, OPTION_ISA},
1.1  skrll   {"renesas", no_argument, NULL, OPTION_RENESAS},
1.1  skrll   {"allow-reg-prefix", no_argument, NULL, OPTION_ALLOW_REG_PREFIX},
1.1  skrll
1.1  skrll #ifdef HAVE_SH64
1.1  skrll   {"abi",                    required_argument, NULL, OPTION_ABI},
1.1  skrll   {"no-mix",                 no_argument, NULL, OPTION_NO_MIX},
1.1  skrll   {"shcompact-const-crange", no_argument, NULL, OPTION_SHCOMPACT_CONST_CRANGE},
1.1  skrll   {"no-expand",              no_argument, NULL, OPTION_NO_EXPAND},
1.1  skrll   {"expand-pt32",            no_argument, NULL, OPTION_PT32},
1.1  skrll #endif /* HAVE_SH64 */
1.1  skrll   { "h-tick-hex", no_argument,	      NULL, OPTION_H_TICK_HEX  },
1.1  skrll
1.1  skrll   {NULL, no_argument, NULL, 0}
1.1  skrll };
1.1  skrll size_t md_longopts_size = sizeof (md_longopts);
1.1  skrll
1.1  skrll int
1.1  skrll md_parse_option (int c, char *arg ATTRIBUTE_UNUSED)
1.1  skrll {
1.1  skrll   switch (c)
1.1  skrll     {
1.1  skrll     case OPTION_RELAX:
1.1  skrll       sh_relax = 1;
1.1  skrll       break;
1.1  skrll
1.1  skrll     case OPTION_BIG:
1.1  skrll       target_big_endian = 1;
1.1  skrll       break;
1.1  skrll
1.1  skrll     case OPTION_LITTLE:
1.1  skrll       target_big_endian = 0;
1.1  skrll       break;
1.1  skrll
1.1  skrll     case OPTION_SMALL:
1.1  skrll       sh_small = 1;
1.1  skrll       break;
1.1  skrll
1.1  skrll     case OPTION_DSP:
1.1  skrll       preset_target_arch = arch_sh_up & ~(arch_sh_sp_fpu|arch_sh_dp_fpu);
1.1  skrll       break;
1.1  skrll
1.1  skrll     case OPTION_RENESAS:
1.1  skrll       dont_adjust_reloc_32 = 1;
1.1  skrll       break;
1.1  skrll
1.1  skrll     case OPTION_ALLOW_REG_PREFIX:
1.1  skrll       allow_dollar_register_prefix = 1;
1.1  skrll       break;
1.1  skrll
1.1  skrll     case OPTION_ISA:
1.1  skrll       if (strcasecmp (arg, "dsp") == 0)
1.1  skrll 	preset_target_arch = arch_sh_up & ~(arch_sh_sp_fpu|arch_sh_dp_fpu);
1.1  skrll       else if (strcasecmp (arg, "fp") == 0)
1.1  skrll 	preset_target_arch = arch_sh_up & ~arch_sh_has_dsp;
1.1  skrll       else if (strcasecmp (arg, "any") == 0)
1.1  skrll 	preset_target_arch = arch_sh_up;
1.1  skrll #ifdef HAVE_SH64
1.1  skrll       else if (strcasecmp (arg, "shmedia") == 0)
1.1  skrll 	{
1.1  skrll 	  if (sh64_isa_mode == sh64_isa_shcompact)
1.1  skrll 	    as_bad (_("Invalid combination: --isa=SHcompact with --isa=SHmedia"));
1.1  skrll 	  sh64_isa_mode = sh64_isa_shmedia;
1.1  skrll 	}
1.1  skrll       else if (strcasecmp (arg, "shcompact") == 0)
1.1  skrll 	{
1.1  skrll 	  if (sh64_isa_mode == sh64_isa_shmedia)
1.1  skrll 	    as_bad (_("Invalid combination: --isa=SHmedia with --isa=SHcompact"));
1.1  skrll 	  if (sh64_abi == sh64_abi_64)
1.1  skrll 	    as_bad (_("Invalid combination: --abi=64 with --isa=SHcompact"));
1.1  skrll 	  sh64_isa_mode = sh64_isa_shcompact;
1.1  skrll 	}
1.1  skrll #endif /* HAVE_SH64 */
1.1  skrll       else
1.1  skrll 	{
1.1  skrll 	  extern const bfd_arch_info_type bfd_sh_arch;
1.1  skrll 	  bfd_arch_info_type const *bfd_arch = &bfd_sh_arch;
1.1  skrll
1.1  skrll 	  preset_target_arch = 0;
1.1  skrll 	  for (; bfd_arch; bfd_arch=bfd_arch->next)
1.1  skrll 	    {
1.1  skrll 	      int len = strlen(bfd_arch->printable_name);
1.1  skrll
1.1  skrll 	      if (bfd_arch->mach == bfd_mach_sh5)
1.1  skrll 		continue;
1.1  skrll
1.1  skrll 	      if (strncasecmp (bfd_arch->printable_name, arg, len) != 0)
1.1  skrll 		continue;
1.1  skrll
1.1  skrll 	      if (arg[len] == '\0')
1.1  skrll 		preset_target_arch =
1.1  skrll 		  sh_get_arch_from_bfd_mach (bfd_arch->mach);
1.1  skrll 	      else if (strcasecmp(&arg[len], "-up") == 0)
1.1  skrll 		preset_target_arch =
1.1  skrll 		  sh_get_arch_up_from_bfd_mach (bfd_arch->mach);
1.1  skrll 	      else
1.1  skrll 		continue;
1.1  skrll 	      break;
1.1  skrll 	    }
1.1  skrll
1.1  skrll 	  if (!preset_target_arch)
1.1  skrll 	    as_bad ("Invalid argument to --isa option: %s", arg);
1.1  skrll 	}
1.1  skrll       break;
1.1  skrll
1.1  skrll #ifdef HAVE_SH64
1.1  skrll     case OPTION_ABI:
1.1  skrll       if (strcmp (arg, "32") == 0)
1.1  skrll 	{
1.1  skrll 	  if (sh64_abi == sh64_abi_64)
1.1  skrll 	    as_bad (_("Invalid combination: --abi=32 with --abi=64"));
1.1  skrll 	  sh64_abi = sh64_abi_32;
1.1  skrll 	}
1.1  skrll       else if (strcmp (arg, "64") == 0)
1.1  skrll 	{
1.1  skrll 	  if (sh64_abi == sh64_abi_32)
1.1  skrll 	    as_bad (_("Invalid combination: --abi=64 with --abi=32"));
1.1  skrll 	  if (sh64_isa_mode == sh64_isa_shcompact)
1.1  skrll 	    as_bad (_("Invalid combination: --isa=SHcompact with --abi=64"));
1.1  skrll 	  sh64_abi = sh64_abi_64;
1.1  skrll 	}
1.1  skrll       else
1.1  skrll 	as_bad ("Invalid argument to --abi option: %s", arg);
1.1  skrll       break;
1.1  skrll
1.1  skrll     case OPTION_NO_MIX:
1.1  skrll       sh64_mix = FALSE;
1.1  skrll       break;
1.1  skrll
1.1  skrll     case OPTION_SHCOMPACT_CONST_CRANGE:
1.1  skrll       sh64_shcompact_const_crange = TRUE;
1.1  skrll       break;
1.1  skrll
1.1  skrll     case OPTION_NO_EXPAND:
1.1  skrll       sh64_expand = FALSE;
1.1  skrll       break;
1.1  skrll
1.1  skrll     case OPTION_PT32:
1.1  skrll       sh64_pt32 = TRUE;
1.1  skrll       break;
1.1  skrll #endif /* HAVE_SH64 */
1.1  skrll
1.1  skrll     case OPTION_H_TICK_HEX:
1.1  skrll       enable_h_tick_hex = 1;
1.1  skrll       break;
1.1  skrll
1.1  skrll     default:
1.1  skrll       return 0;
1.1  skrll     }
1.1  skrll
1.1  skrll   return 1;
1.1  skrll }
1.1  skrll
1.1  skrll void
1.1  skrll md_show_usage (FILE *stream)
1.1  skrll {
1.1  skrll   fprintf (stream, _("\
1.1  skrll SH options:\n\
1.1  skrll --little		generate little endian code\n\
1.1  skrll --big			generate big endian code\n\
1.1  skrll --relax			alter jump instructions for long displacements\n\
1.1  skrll --renesas		disable optimization with section symbol for\n\
1.1  skrll 			compatibility with Renesas assembler.\n\
1.1  skrll --small			align sections to 4 byte boundaries, not 16\n\
1.1  skrll --dsp			enable sh-dsp insns, and disable floating-point ISAs.\n\
1.1  skrll --allow-reg-prefix	allow '$' as a register name prefix.\n\
1.1  skrll --isa=[any		use most appropriate isa\n\
1.1  skrll     | dsp               same as '-dsp'\n\
1.1  skrll     | fp"));
1.1  skrll   {
1.1  skrll     extern const bfd_arch_info_type bfd_sh_arch;
1.1  skrll     bfd_arch_info_type const *bfd_arch = &bfd_sh_arch;
1.1  skrll
1.1  skrll     for (; bfd_arch; bfd_arch=bfd_arch->next)
1.1  skrll       if (bfd_arch->mach != bfd_mach_sh5)
1.1  skrll 	{
1.1  skrll 	  fprintf (stream, "\n    | %s", bfd_arch->printable_name);
1.1  skrll 	  fprintf (stream, "\n    | %s-up", bfd_arch->printable_name);
1.1  skrll 	}
1.1  skrll   }
1.1  skrll   fprintf (stream, "]\n");
1.1  skrll #ifdef HAVE_SH64
1.1  skrll   fprintf (stream, _("\
1.1  skrll --isa=[shmedia		set as the default instruction set for SH64\n\
1.1  skrll     | SHmedia\n\
1.1  skrll     | shcompact\n\
1.1  skrll     | SHcompact]\n"));
1.1  skrll   fprintf (stream, _("\
1.1  skrll --abi=[32|64]		set size of expanded SHmedia operands and object\n\
1.1  skrll 			file type\n\
1.1  skrll --shcompact-const-crange  emit code-range descriptors for constants in\n\
1.1  skrll 			SHcompact code sections\n\
1.1  skrll --no-mix		disallow SHmedia code in the same section as\n\
1.1  skrll 			constants and SHcompact code\n\
1.1  skrll --no-expand		do not expand MOVI, PT, PTA or PTB instructions\n\
1.1  skrll --expand-pt32		with -abi=64, expand PT, PTA and PTB instructions\n\
1.1  skrll 			to 32 bits only\n"));
1.1  skrll #endif /* HAVE_SH64 */
1.1  skrll }
1.1  skrll
1.1  skrll /* This struct is used to pass arguments to sh_count_relocs through
1.1  skrll    bfd_map_over_sections.  */
1.1  skrll
1.1  skrll struct sh_count_relocs
1.1  skrll {
1.1  skrll   /* Symbol we are looking for.  */
1.1  skrll   symbolS *sym;
1.1  skrll   /* Count of relocs found.  */
1.1  skrll   int count;
1.1  skrll };
1.1  skrll
1.1  skrll /* Count the number of fixups in a section which refer to a particular
1.1  skrll    symbol.  This is called via bfd_map_over_sections.  */
1.1  skrll
1.1  skrll static void
1.1  skrll sh_count_relocs (bfd *abfd ATTRIBUTE_UNUSED, segT sec, void *data)
1.1  skrll {
1.1  skrll   struct sh_count_relocs *info = (struct sh_count_relocs *) data;
1.1  skrll   segment_info_type *seginfo;
1.1  skrll   symbolS *sym;
1.1  skrll   fixS *fix;
1.1  skrll
1.1  skrll   seginfo = seg_info (sec);
1.1  skrll   if (seginfo == NULL)
1.1  skrll     return;
1.1  skrll
1.1  skrll   sym = info->sym;
1.1  skrll   for (fix = seginfo->fix_root; fix != NULL; fix = fix->fx_next)
1.1  skrll     {
1.1  skrll       if (fix->fx_addsy == sym)
1.1  skrll 	{
1.1  skrll 	  ++info->count;
1.1  skrll 	  fix->fx_tcbit = 1;
1.1  skrll 	}
1.1  skrll     }
1.1  skrll }
1.1  skrll
1.1  skrll /* Handle the count relocs for a particular section.
1.1  skrll    This is called via bfd_map_over_sections.  */
1.1  skrll
1.1  skrll static void
1.1  skrll sh_frob_section (bfd *abfd ATTRIBUTE_UNUSED, segT sec,
1.1  skrll 		 void *ignore ATTRIBUTE_UNUSED)
1.1  skrll {
1.1  skrll   segment_info_type *seginfo;
1.1  skrll   fixS *fix;
1.1  skrll
1.1  skrll   seginfo = seg_info (sec);
1.1  skrll   if (seginfo == NULL)
1.1  skrll     return;
1.1  skrll
1.1  skrll   for (fix = seginfo->fix_root; fix != NULL; fix = fix->fx_next)
1.1  skrll     {
1.1  skrll       symbolS *sym;
1.1  skrll
1.1  skrll       sym = fix->fx_addsy;
1.1  skrll       /* Check for a local_symbol.  */
1.1  skrll       if (sym && sym->bsym == NULL)
1.1  skrll 	{
1.1  skrll 	  struct local_symbol *ls = (struct local_symbol *)sym;
1.1  skrll 	  /* See if it's been converted.  If so, canonicalize.  */
1.1  skrll 	  if (local_symbol_converted_p (ls))
1.1  skrll 	    fix->fx_addsy = local_symbol_get_real_symbol (ls);
1.1  skrll 	}
1.1  skrll     }
1.1  skrll
1.1  skrll   for (fix = seginfo->fix_root; fix != NULL; fix = fix->fx_next)
1.1  skrll     {
1.1  skrll       symbolS *sym;
1.1  skrll       bfd_vma val;
1.1  skrll       fixS *fscan;
1.1  skrll       struct sh_count_relocs info;
1.1  skrll
1.1  skrll       if (fix->fx_r_type != BFD_RELOC_SH_USES)
1.1  skrll 	continue;
1.1  skrll
1.1  skrll       /* The BFD_RELOC_SH_USES reloc should refer to a defined local
1.1  skrll 	 symbol in the same section.  */
1.1  skrll       sym = fix->fx_addsy;
1.1  skrll       if (sym == NULL
1.1  skrll 	  || fix->fx_subsy != NULL
1.1  skrll 	  || fix->fx_addnumber != 0
1.1  skrll 	  || S_GET_SEGMENT (sym) != sec
1.1  skrll 	  || S_IS_EXTERNAL (sym))
1.1  skrll 	{
1.1  skrll 	  as_warn_where (fix->fx_file, fix->fx_line,
1.1  skrll 			 _(".uses does not refer to a local symbol in the same section"));
1.1  skrll 	  continue;
1.1  skrll 	}
1.1  skrll
1.1  skrll       /* Look through the fixups again, this time looking for one
1.1  skrll 	 at the same location as sym.  */
1.1  skrll       val = S_GET_VALUE (sym);
1.1  skrll       for (fscan = seginfo->fix_root;
1.1  skrll 	   fscan != NULL;
1.1  skrll 	   fscan = fscan->fx_next)
1.1  skrll 	if (val == fscan->fx_frag->fr_address + fscan->fx_where
1.1  skrll 	    && fscan->fx_r_type != BFD_RELOC_SH_ALIGN
1.1  skrll 	    && fscan->fx_r_type != BFD_RELOC_SH_CODE
1.1  skrll 	    && fscan->fx_r_type != BFD_RELOC_SH_DATA
1.1  skrll 	    && fscan->fx_r_type != BFD_RELOC_SH_LABEL)
1.1  skrll 	  break;
1.1  skrll       if (fscan == NULL)
1.1  skrll 	{
1.1  skrll 	  as_warn_where (fix->fx_file, fix->fx_line,
1.1  skrll 			 _("can't find fixup pointed to by .uses"));
1.1  skrll 	  continue;
1.1  skrll 	}
1.1  skrll
1.1  skrll       if (fscan->fx_tcbit)
1.1  skrll 	{
1.1  skrll 	  /* We've already done this one.  */
1.1  skrll 	  continue;
1.1  skrll 	}
1.1  skrll
1.1  skrll       /* The variable fscan should also be a fixup to a local symbol
1.1  skrll 	 in the same section.  */
1.1  skrll       sym = fscan->fx_addsy;
1.1  skrll       if (sym == NULL
1.1  skrll 	  || fscan->fx_subsy != NULL
1.1  skrll 	  || fscan->fx_addnumber != 0
1.1  skrll 	  || S_GET_SEGMENT (sym) != sec
1.1  skrll 	  || S_IS_EXTERNAL (sym))
1.1  skrll 	{
1.1  skrll 	  as_warn_where (fix->fx_file, fix->fx_line,
1.1  skrll 			 _(".uses target does not refer to a local symbol in the same section"));
1.1  skrll 	  continue;
1.1  skrll 	}
1.1  skrll
1.1  skrll       /* Now we look through all the fixups of all the sections,
1.1  skrll 	 counting the number of times we find a reference to sym.  */
1.1  skrll       info.sym = sym;
1.1  skrll       info.count = 0;
1.1  skrll       bfd_map_over_sections (stdoutput, sh_count_relocs, &info);
1.1  skrll
1.1  skrll       if (info.count < 1)
1.1  skrll 	abort ();
1.1  skrll
1.1  skrll       /* Generate a BFD_RELOC_SH_COUNT fixup at the location of sym.
1.1  skrll 	 We have already adjusted the value of sym to include the
1.1  skrll 	 fragment address, so we undo that adjustment here.  */
1.1  skrll       subseg_change (sec, 0);
1.1  skrll       fix_new (fscan->fx_frag,
1.1  skrll 	       S_GET_VALUE (sym) - fscan->fx_frag->fr_address,
1.1  skrll 	       4, &abs_symbol, info.count, 0, BFD_RELOC_SH_COUNT);
1.1  skrll     }
1.1  skrll }
1.1  skrll
1.1  skrll /* This function is called after the symbol table has been completed,
1.1  skrll    but before the relocs or section contents have been written out.
1.1  skrll    If we have seen any .uses pseudo-ops, they point to an instruction
1.1  skrll    which loads a register with the address of a function.  We look
1.1  skrll    through the fixups to find where the function address is being
1.1  skrll    loaded from.  We then generate a COUNT reloc giving the number of
1.1  skrll    times that function address is referred to.  The linker uses this
1.1  skrll    information when doing relaxing, to decide when it can eliminate
1.1  skrll    the stored function address entirely.  */
1.1  skrll
1.1  skrll void
1.1  skrll sh_frob_file (void)
1.1  skrll {
1.1  skrll #ifdef HAVE_SH64
1.1  skrll   shmedia_frob_file_before_adjust ();
1.1  skrll #endif
1.1  skrll
1.1  skrll   if (! sh_relax)
1.1  skrll     return;
1.1  skrll
1.1  skrll   bfd_map_over_sections (stdoutput, sh_frob_section, NULL);
1.1  skrll }
1.1  skrll
1.1  skrll /* Called after relaxing.  Set the correct sizes of the fragments, and
1.1  skrll    create relocs so that md_apply_fix will fill in the correct values.  */
1.1  skrll
1.1  skrll void
1.1  skrll md_convert_frag (bfd *headers ATTRIBUTE_UNUSED, segT seg, fragS *fragP)
1.1  skrll {
1.1  skrll   int donerelax = 0;
1.1  skrll
1.1  skrll   switch (fragP->fr_subtype)
1.1  skrll     {
1.1  skrll     case C (COND_JUMP, COND8):
1.1  skrll     case C (COND_JUMP_DELAY, COND8):
1.1  skrll       subseg_change (seg, 0);
1.1  skrll       fix_new (fragP, fragP->fr_fix, 2, fragP->fr_symbol, fragP->fr_offset,
1.1  skrll 	       1, BFD_RELOC_SH_PCDISP8BY2);
1.1  skrll       fragP->fr_fix += 2;
1.1  skrll       fragP->fr_var = 0;
1.1  skrll       break;
1.1  skrll
1.1  skrll     case C (UNCOND_JUMP, UNCOND12):
1.1  skrll       subseg_change (seg, 0);
1.1  skrll       fix_new (fragP, fragP->fr_fix, 2, fragP->fr_symbol, fragP->fr_offset,
1.1  skrll 	       1, BFD_RELOC_SH_PCDISP12BY2);
1.1  skrll       fragP->fr_fix += 2;
1.1  skrll       fragP->fr_var = 0;
1.1  skrll       break;
1.1  skrll
1.1  skrll     case C (UNCOND_JUMP, UNCOND32):
1.1  skrll     case C (UNCOND_JUMP, UNDEF_WORD_DISP):
1.1  skrll       if (fragP->fr_symbol == NULL)
1.1  skrll 	as_bad_where (fragP->fr_file, fragP->fr_line,
1.1  skrll 		      _("displacement overflows 12-bit field"));
1.1  skrll       else if (S_IS_DEFINED (fragP->fr_symbol))
1.1  skrll 	as_bad_where (fragP->fr_file, fragP->fr_line,
1.1  skrll 		      _("displacement to defined symbol %s overflows 12-bit field"),
1.1  skrll 		      S_GET_NAME (fragP->fr_symbol));
1.1  skrll       else
1.1  skrll 	as_bad_where (fragP->fr_file, fragP->fr_line,
1.1  skrll 		      _("displacement to undefined symbol %s overflows 12-bit field"),
1.1  skrll 		      S_GET_NAME (fragP->fr_symbol));
1.1  skrll       /* Stabilize this frag, so we don't trip an assert.  */
1.1  skrll       fragP->fr_fix += fragP->fr_var;
1.1  skrll       fragP->fr_var = 0;
1.1  skrll       break;
1.1  skrll
1.1  skrll     case C (COND_JUMP, COND12):
1.1  skrll     case C (COND_JUMP_DELAY, COND12):
1.1  skrll       /* A bcond won't fit, so turn it into a b!cond; bra disp; nop.  */
1.1  skrll       /* I found that a relax failure for gcc.c-torture/execute/930628-1.c
1.1  skrll 	 was due to gas incorrectly relaxing an out-of-range conditional
1.1  skrll 	 branch with delay slot.  It turned:
1.1  skrll                      bf.s    L6              (slot mov.l   r12,@(44,r0))
1.1  skrll          into:
1.1  skrll
1.1  skrll 2c:  8f 01 a0 8b     bf.s    32 <_main+32>   (slot bra       L6)
1.1  skrll 30:  00 09           nop
1.1  skrll 32:  10 cb           mov.l   r12,@(44,r0)
1.1  skrll          Therefore, branches with delay slots have to be handled
1.1  skrll 	 differently from ones without delay slots.  */
1.1  skrll       {
1.1  skrll 	unsigned char *buffer =
1.1  skrll 	  (unsigned char *) (fragP->fr_fix + fragP->fr_literal);
1.1  skrll 	int highbyte = target_big_endian ? 0 : 1;
1.1  skrll 	int lowbyte = target_big_endian ? 1 : 0;
1.1  skrll 	int delay = fragP->fr_subtype == C (COND_JUMP_DELAY, COND12);
1.1  skrll
1.1  skrll 	/* Toggle the true/false bit of the bcond.  */
1.1  skrll 	buffer[highbyte] ^= 0x2;
1.1  skrll
1.1  skrll 	/* If this is a delayed branch, we may not put the bra in the
1.1  skrll 	   slot.  So we change it to a non-delayed branch, like that:
1.1  skrll 	   b! cond slot_label; bra disp; slot_label: slot_insn
1.1  skrll 	   ??? We should try if swapping the conditional branch and
1.1  skrll 	   its delay-slot insn already makes the branch reach.  */
1.1  skrll
1.1  skrll 	/* Build a relocation to six / four bytes farther on.  */
1.1  skrll 	subseg_change (seg, 0);
1.1  skrll 	fix_new (fragP, fragP->fr_fix, 2, section_symbol (seg),
1.1  skrll 		 fragP->fr_address + fragP->fr_fix + (delay ? 4 : 6),
1.1  skrll 		 1, BFD_RELOC_SH_PCDISP8BY2);
1.1  skrll
1.1  skrll 	/* Set up a jump instruction.  */
1.1  skrll 	buffer[highbyte + 2] = 0xa0;
1.1  skrll 	buffer[lowbyte + 2] = 0;
1.1  skrll 	fix_new (fragP, fragP->fr_fix + 2, 2, fragP->fr_symbol,
1.1  skrll 		 fragP->fr_offset, 1, BFD_RELOC_SH_PCDISP12BY2);
1.1  skrll
1.1  skrll 	if (delay)
1.1  skrll 	  {
1.1  skrll 	    buffer[highbyte] &= ~0x4; /* Removes delay slot from branch.  */
1.1  skrll 	    fragP->fr_fix += 4;
1.1  skrll 	  }
1.1  skrll 	else
1.1  skrll 	  {
1.1  skrll 	    /* Fill in a NOP instruction.  */
1.1  skrll 	    buffer[highbyte + 4] = 0x0;
1.1  skrll 	    buffer[lowbyte + 4] = 0x9;
1.1  skrll
1.1  skrll 	    fragP->fr_fix += 6;
1.1  skrll 	  }
1.1  skrll 	fragP->fr_var = 0;
1.1  skrll 	donerelax = 1;
1.1  skrll       }
1.1  skrll       break;
1.1  skrll
1.1  skrll     case C (COND_JUMP, COND32):
1.1  skrll     case C (COND_JUMP_DELAY, COND32):
1.1  skrll     case C (COND_JUMP, UNDEF_WORD_DISP):
1.1  skrll     case C (COND_JUMP_DELAY, UNDEF_WORD_DISP):
1.1  skrll       if (fragP->fr_symbol == NULL)
1.1  skrll 	as_bad_where (fragP->fr_file, fragP->fr_line,
1.1  skrll 		      _("displacement overflows 8-bit field"));
1.1  skrll       else if (S_IS_DEFINED (fragP->fr_symbol))
1.1  skrll 	as_bad_where (fragP->fr_file, fragP->fr_line,
1.1  skrll 		      _("displacement to defined symbol %s overflows 8-bit field"),
1.1  skrll 		      S_GET_NAME (fragP->fr_symbol));
1.1  skrll       else
1.1  skrll 	as_bad_where (fragP->fr_file, fragP->fr_line,
1.1  skrll 		      _("displacement to undefined symbol %s overflows 8-bit field "),
1.1  skrll 		      S_GET_NAME (fragP->fr_symbol));
1.1  skrll       /* Stabilize this frag, so we don't trip an assert.  */
1.1  skrll       fragP->fr_fix += fragP->fr_var;
1.1  skrll       fragP->fr_var = 0;
1.1  skrll       break;
1.1  skrll
1.1  skrll     default:
1.1  skrll #ifdef HAVE_SH64
1.1  skrll       shmedia_md_convert_frag (headers, seg, fragP, TRUE);
1.1  skrll #else
1.1  skrll       abort ();
1.1  skrll #endif
1.1  skrll     }
1.1  skrll
1.1  skrll   if (donerelax && !sh_relax)
1.1  skrll     as_warn_where (fragP->fr_file, fragP->fr_line,
1.1  skrll 		   _("overflow in branch to %s; converted into longer instruction sequence"),
1.1  skrll 		   (fragP->fr_symbol != NULL
1.1  skrll 		    ? S_GET_NAME (fragP->fr_symbol)
1.1  skrll 		    : ""));
1.1  skrll }
1.1  skrll
1.1  skrll valueT
1.1  skrll md_section_align (segT seg ATTRIBUTE_UNUSED, valueT size)
1.1  skrll {
1.1  skrll #ifdef OBJ_ELF
1.1  skrll   return size;
1.1  skrll #else /* ! OBJ_ELF */
1.1  skrll   return ((size + (1 << bfd_get_section_alignment (stdoutput, seg)) - 1)
1.1  skrll 	  & (-1 << bfd_get_section_alignment (stdoutput, seg)));
1.1  skrll #endif /* ! OBJ_ELF */
1.1  skrll }
1.1  skrll
1.1  skrll /* This static variable is set by s_uacons to tell sh_cons_align that
1.1  skrll    the expression does not need to be aligned.  */
1.1  skrll
1.1  skrll static int sh_no_align_cons = 0;
1.1  skrll
1.1  skrll /* This handles the unaligned space allocation pseudo-ops, such as
1.1  skrll    .uaword.  .uaword is just like .word, but the value does not need
1.1  skrll    to be aligned.  */
1.1  skrll
1.1  skrll static void
1.1  skrll s_uacons (int bytes)
1.1  skrll {
1.1  skrll   /* Tell sh_cons_align not to align this value.  */
1.1  skrll   sh_no_align_cons = 1;
1.1  skrll   cons (bytes);
1.1  skrll }
1.1  skrll
1.1  skrll /* If a .word, et. al., pseud-op is seen, warn if the value is not
1.1  skrll    aligned correctly.  Note that this can cause warnings to be issued
1.1  skrll    when assembling initialized structured which were declared with the
1.1  skrll    packed attribute.  FIXME: Perhaps we should require an option to
1.1  skrll    enable this warning?  */
1.1  skrll
1.1  skrll void
1.1  skrll sh_cons_align (int nbytes)
1.1  skrll {
1.1  skrll   int nalign;
1.1  skrll   char *p;
1.1  skrll
1.1  skrll   if (sh_no_align_cons)
1.1  skrll     {
1.1  skrll       /* This is an unaligned pseudo-op.  */
1.1  skrll       sh_no_align_cons = 0;
1.1  skrll       return;
1.1  skrll     }
1.1  skrll
1.1  skrll   nalign = 0;
1.1  skrll   while ((nbytes & 1) == 0)
1.1  skrll     {
1.1  skrll       ++nalign;
1.1  skrll       nbytes >>= 1;
1.1  skrll     }
1.1  skrll
1.1  skrll   if (nalign == 0)
1.1  skrll     return;
1.1  skrll
1.1  skrll   if (now_seg == absolute_section)
1.1  skrll     {
1.1  skrll       if ((abs_section_offset & ((1 << nalign) - 1)) != 0)
1.1  skrll 	as_warn (_("misaligned data"));
1.1  skrll       return;
1.1  skrll     }
1.1  skrll
1.1  skrll   p = frag_var (rs_align_test, 1, 1, (relax_substateT) 0,
1.1  skrll 		(symbolS *) NULL, (offsetT) nalign, (char *) NULL);
1.1  skrll
1.1  skrll   record_alignment (now_seg, nalign);
1.1  skrll }
1.1  skrll
1.1  skrll /* When relaxing, we need to output a reloc for any .align directive
1.1  skrll    that requests alignment to a four byte boundary or larger.  This is
1.1  skrll    also where we check for misaligned data.  */
1.1  skrll
1.1  skrll void
1.1  skrll sh_handle_align (fragS *frag)
1.1  skrll {
1.1  skrll   int bytes = frag->fr_next->fr_address - frag->fr_address - frag->fr_fix;
1.1  skrll
1.1  skrll   if (frag->fr_type == rs_align_code)
1.1  skrll     {
1.1  skrll       static const unsigned char big_nop_pattern[] = { 0x00, 0x09 };
1.1  skrll       static const unsigned char little_nop_pattern[] = { 0x09, 0x00 };
1.1  skrll
1.1  skrll       char *p = frag->fr_literal + frag->fr_fix;
1.1  skrll
1.1  skrll       if (bytes & 1)
1.1  skrll 	{
1.1  skrll 	  *p++ = 0;
1.1  skrll 	  bytes--;
1.1  skrll 	  frag->fr_fix += 1;
1.1  skrll 	}
1.1  skrll
1.1  skrll       if (target_big_endian)
1.1  skrll 	{
1.1  skrll 	  memcpy (p, big_nop_pattern, sizeof big_nop_pattern);
1.1  skrll 	  frag->fr_var = sizeof big_nop_pattern;
1.1  skrll 	}
1.1  skrll       else
1.1  skrll 	{
1.1  skrll 	  memcpy (p, little_nop_pattern, sizeof little_nop_pattern);
1.1  skrll 	  frag->fr_var = sizeof little_nop_pattern;
1.1  skrll 	}
1.1  skrll     }
1.1  skrll   else if (frag->fr_type == rs_align_test)
1.1  skrll     {
1.1  skrll       if (bytes != 0)
1.1  skrll 	as_bad_where (frag->fr_file, frag->fr_line, _("misaligned data"));
1.1  skrll     }
1.1  skrll
1.1  skrll   if (sh_relax
1.1  skrll       && (frag->fr_type == rs_align
1.1  skrll 	  || frag->fr_type == rs_align_code)
1.1  skrll       && frag->fr_address + frag->fr_fix > 0
1.1  skrll       && frag->fr_offset > 1
1.1  skrll       && now_seg != bss_section)
1.1  skrll     fix_new (frag, frag->fr_fix, 2, &abs_symbol, frag->fr_offset, 0,
1.1  skrll 	     BFD_RELOC_SH_ALIGN);
1.1  skrll }
1.1  skrll
1.1  skrll /* See whether the relocation should be resolved locally.  */
1.1  skrll
1.1  skrll static bfd_boolean
1.1  skrll sh_local_pcrel (fixS *fix)
1.1  skrll {
1.1  skrll   return (! sh_relax
1.1  skrll 	  && (fix->fx_r_type == BFD_RELOC_SH_PCDISP8BY2
1.1  skrll 	      || fix->fx_r_type == BFD_RELOC_SH_PCDISP12BY2
1.1  skrll 	      || fix->fx_r_type == BFD_RELOC_SH_PCRELIMM8BY2
1.1  skrll 	      || fix->fx_r_type == BFD_RELOC_SH_PCRELIMM8BY4
1.1  skrll 	      || fix->fx_r_type == BFD_RELOC_8_PCREL
1.1  skrll 	      || fix->fx_r_type == BFD_RELOC_SH_SWITCH16
1.1  skrll 	      || fix->fx_r_type == BFD_RELOC_SH_SWITCH32));
1.1  skrll }
1.1  skrll
1.1  skrll /* See whether we need to force a relocation into the output file.
1.1  skrll    This is used to force out switch and PC relative relocations when
1.1  skrll    relaxing.  */
1.1  skrll
1.1  skrll int
1.1  skrll sh_force_relocation (fixS *fix)
1.1  skrll {
1.1  skrll   /* These relocations can't make it into a DSO, so no use forcing
1.1  skrll      them for global symbols.  */
1.1  skrll   if (sh_local_pcrel (fix))
1.1  skrll     return 0;
1.1  skrll
1.1  skrll   /* Make sure some relocations get emitted.  */
1.1  skrll   if (fix->fx_r_type == BFD_RELOC_SH_LOOP_START
1.1  skrll       || fix->fx_r_type == BFD_RELOC_SH_LOOP_END
1.1  skrll       || fix->fx_r_type == BFD_RELOC_SH_TLS_GD_32
1.1  skrll       || fix->fx_r_type == BFD_RELOC_SH_TLS_LD_32
1.1  skrll       || fix->fx_r_type == BFD_RELOC_SH_TLS_IE_32
1.1  skrll       || fix->fx_r_type == BFD_RELOC_SH_TLS_LDO_32
1.1  skrll       || fix->fx_r_type == BFD_RELOC_SH_TLS_LE_32
1.1  skrll       || generic_force_reloc (fix))
1.1  skrll     return 1;
1.1  skrll
1.1  skrll   if (! sh_relax)
1.1  skrll     return 0;
1.1  skrll
1.1  skrll   return (fix->fx_pcrel
1.1  skrll 	  || SWITCH_TABLE (fix)
1.1  skrll 	  || fix->fx_r_type == BFD_RELOC_SH_COUNT
1.1  skrll 	  || fix->fx_r_type == BFD_RELOC_SH_ALIGN
1.1  skrll 	  || fix->fx_r_type == BFD_RELOC_SH_CODE
1.1  skrll 	  || fix->fx_r_type == BFD_RELOC_SH_DATA
1.1  skrll #ifdef HAVE_SH64
1.1  skrll 	  || fix->fx_r_type == BFD_RELOC_SH_SHMEDIA_CODE
1.1  skrll #endif
1.1  skrll 	  || fix->fx_r_type == BFD_RELOC_SH_LABEL);
1.1  skrll }
1.1  skrll
1.1  skrll #ifdef OBJ_ELF
1.1  skrll bfd_boolean
1.1  skrll sh_fix_adjustable (fixS *fixP)
1.1  skrll {
1.1  skrll   if (fixP->fx_r_type == BFD_RELOC_32_PLT_PCREL
1.1  skrll       || fixP->fx_r_type == BFD_RELOC_32_GOT_PCREL
1.1  skrll       || fixP->fx_r_type == BFD_RELOC_SH_GOTPC
1.1  skrll       || ((fixP->fx_r_type == BFD_RELOC_32) && dont_adjust_reloc_32)
1.1  skrll       || fixP->fx_r_type == BFD_RELOC_RVA)
1.1  skrll     return 0;
1.1  skrll
1.1  skrll   /* We need the symbol name for the VTABLE entries */
1.1  skrll   if (fixP->fx_r_type == BFD_RELOC_VTABLE_INHERIT
1.1  skrll       || fixP->fx_r_type == BFD_RELOC_VTABLE_ENTRY)
1.1  skrll     return 0;
1.1  skrll
1.1  skrll   return 1;
1.1  skrll }
1.1  skrll
1.1  skrll void
1.1  skrll sh_elf_final_processing (void)
1.1  skrll {
1.1  skrll   int val;
1.1  skrll
1.1  skrll   /* Set file-specific flags to indicate if this code needs
1.1  skrll      a processor with the sh-dsp / sh2e ISA to execute.  */
1.1  skrll #ifdef HAVE_SH64
1.1  skrll   /* SH5 and above don't know about the valid_arch arch_sh* bits defined
1.1  skrll      in sh-opc.h, so check SH64 mode before checking valid_arch.  */
1.1  skrll   if (sh64_isa_mode != sh64_isa_unspecified)
1.1  skrll     val = EF_SH5;
1.1  skrll   else
1.1  skrll #elif defined TARGET_SYMBIAN
1.1  skrll     if (1)
1.1  skrll       {
1.1  skrll 	extern int sh_symbian_find_elf_flags (unsigned int);
1.1  skrll
1.1  skrll 	val = sh_symbian_find_elf_flags (valid_arch);
1.1  skrll       }
1.1  skrll     else
1.1  skrll #endif /* HAVE_SH64 */
1.1  skrll     val = sh_find_elf_flags (valid_arch);
1.1  skrll
1.1  skrll   elf_elfheader (stdoutput)->e_flags &= ~EF_SH_MACH_MASK;
1.1  skrll   elf_elfheader (stdoutput)->e_flags |= val;
1.1  skrll }
1.1  skrll #endif
1.1  skrll
1.1  skrll /* Apply fixup FIXP to SIZE-byte field BUF given that VAL is its
1.1  skrll    assembly-time value.  If we're generating a reloc for FIXP,
1.1  skrll    see whether the addend should be stored in-place or whether
1.1  skrll    it should be in an ELF r_addend field.  */
1.1  skrll
1.1  skrll static void
1.1  skrll apply_full_field_fix (fixS *fixP, char *buf, bfd_vma val, int size)
1.1  skrll {
1.1  skrll   reloc_howto_type *howto;
1.1  skrll
1.1  skrll   if (fixP->fx_addsy != NULL || fixP->fx_pcrel)
1.1  skrll     {
1.1  skrll       howto = bfd_reloc_type_lookup (stdoutput, fixP->fx_r_type);
1.1  skrll       if (howto && !howto->partial_inplace)
1.1  skrll 	{
1.1  skrll 	  fixP->fx_addnumber = val;
1.1  skrll 	  return;
1.1  skrll 	}
1.1  skrll     }
1.1  skrll   md_number_to_chars (buf, val, size);
1.1  skrll }
1.1  skrll
1.1  skrll /* Apply a fixup to the object file.  */
1.1  skrll
1.1  skrll void
1.1  skrll md_apply_fix (fixS *fixP, valueT *valP, segT seg ATTRIBUTE_UNUSED)
1.1  skrll {
1.1  skrll   char *buf = fixP->fx_where + fixP->fx_frag->fr_literal;
1.1  skrll   int lowbyte = target_big_endian ? 1 : 0;
1.1  skrll   int highbyte = target_big_endian ? 0 : 1;
1.1  skrll   long val = (long) *valP;
1.1  skrll   long max, min;
1.1  skrll   int shift;
1.1  skrll
1.1  skrll   /* A difference between two symbols, the second of which is in the
1.1  skrll      current section, is transformed in a PC-relative relocation to
1.1  skrll      the other symbol.  We have to adjust the relocation type here.  */
1.1  skrll   if (fixP->fx_pcrel)
1.1  skrll     {
1.1  skrll       switch (fixP->fx_r_type)
1.1  skrll 	{
1.1  skrll 	default:
1.1  skrll 	  break;
1.1  skrll
1.1  skrll 	case BFD_RELOC_32:
1.1  skrll 	  fixP->fx_r_type = BFD_RELOC_32_PCREL;
1.1  skrll 	  break;
1.1  skrll
1.1  skrll 	  /* Currently, we only support 32-bit PCREL relocations.
1.1  skrll 	     We'd need a new reloc type to handle 16_PCREL, and
1.1  skrll 	     8_PCREL is already taken for R_SH_SWITCH8, which
1.1  skrll 	     apparently does something completely different than what
1.1  skrll 	     we need.  FIXME.  */
1.1  skrll 	case BFD_RELOC_16:
1.1  skrll 	  bfd_set_error (bfd_error_bad_value);
1.1  skrll 	  return;
1.1  skrll
1.1  skrll 	case BFD_RELOC_8:
1.1  skrll 	  bfd_set_error (bfd_error_bad_value);
1.1  skrll 	  return;
1.1  skrll 	}
1.1  skrll     }
1.1  skrll
1.1  skrll   /* The function adjust_reloc_syms won't convert a reloc against a weak
1.1  skrll      symbol into a reloc against a section, but bfd_install_relocation
1.1  skrll      will screw up if the symbol is defined, so we have to adjust val here
1.1  skrll      to avoid the screw up later.
1.1  skrll
1.1  skrll      For ordinary relocs, this does not happen for ELF, since for ELF,
1.1  skrll      bfd_install_relocation uses the "special function" field of the
1.1  skrll      howto, and does not execute the code that needs to be undone, as long
1.1  skrll      as the special function does not return bfd_reloc_continue.
1.1  skrll      It can happen for GOT- and PLT-type relocs the way they are
1.1  skrll      described in elf32-sh.c as they use bfd_elf_generic_reloc, but it
1.1  skrll      doesn't matter here since those relocs don't use VAL; see below.  */
1.1  skrll   if (OUTPUT_FLAVOR != bfd_target_elf_flavour
1.1  skrll       && fixP->fx_addsy != NULL
1.1  skrll       && S_IS_WEAK (fixP->fx_addsy))
1.1  skrll     val -= S_GET_VALUE  (fixP->fx_addsy);
1.1  skrll
1.1  skrll   if (SWITCH_TABLE (fixP))
1.1  skrll     val -= S_GET_VALUE  (fixP->fx_subsy);
1.1  skrll
1.1  skrll   max = min = 0;
1.1  skrll   shift = 0;
1.1  skrll   switch (fixP->fx_r_type)
1.1  skrll     {
1.1  skrll     case BFD_RELOC_SH_IMM3:
1.1  skrll       max = 0x7;
1.1  skrll       * buf = (* buf & 0xf8) | (val & 0x7);
1.1  skrll       break;
1.1  skrll     case BFD_RELOC_SH_IMM3U:
1.1  skrll       max = 0x7;
1.1  skrll       * buf = (* buf & 0x8f) | ((val & 0x7) << 4);
1.1  skrll       break;
1.1  skrll     case BFD_RELOC_SH_DISP12:
1.1  skrll       max = 0xfff;
1.1  skrll       buf[lowbyte] = val & 0xff;
1.1  skrll       buf[highbyte] |= (val >> 8) & 0x0f;
1.1  skrll       break;
1.1  skrll     case BFD_RELOC_SH_DISP12BY2:
1.1  skrll       max = 0xfff;
1.1  skrll       shift = 1;
1.1  skrll       buf[lowbyte] = (val >> 1) & 0xff;
1.1  skrll       buf[highbyte] |= (val >> 9) & 0x0f;
1.1  skrll       break;
1.1  skrll     case BFD_RELOC_SH_DISP12BY4:
1.1  skrll       max = 0xfff;
1.1  skrll       shift = 2;
1.1  skrll       buf[lowbyte] = (val >> 2) & 0xff;
1.1  skrll       buf[highbyte] |= (val >> 10) & 0x0f;
1.1  skrll       break;
1.1  skrll     case BFD_RELOC_SH_DISP12BY8:
1.1  skrll       max = 0xfff;
1.1  skrll       shift = 3;
1.1  skrll       buf[lowbyte] = (val >> 3) & 0xff;
1.1  skrll       buf[highbyte] |= (val >> 11) & 0x0f;
1.1  skrll       break;
1.1  skrll     case BFD_RELOC_SH_DISP20:
1.1  skrll       if (! target_big_endian)
1.1  skrll 	abort();
1.1  skrll       max = 0x7ffff;
1.1  skrll       min = -0x80000;
1.1  skrll       buf[1] = (buf[1] & 0x0f) | ((val >> 12) & 0xf0);
1.1  skrll       buf[2] = (val >> 8) & 0xff;
1.1  skrll       buf[3] = val & 0xff;
1.1  skrll       break;
1.1  skrll     case BFD_RELOC_SH_DISP20BY8:
1.1  skrll       if (!target_big_endian)
1.1  skrll 	abort();
1.1  skrll       max = 0x7ffff;
1.1  skrll       min = -0x80000;
1.1  skrll       shift = 8;
1.1  skrll       buf[1] = (buf[1] & 0x0f) | ((val >> 20) & 0xf0);
1.1  skrll       buf[2] = (val >> 16) & 0xff;
1.1  skrll       buf[3] = (val >> 8) & 0xff;
1.1  skrll       break;
1.1  skrll
1.1  skrll     case BFD_RELOC_SH_IMM4:
1.1  skrll       max = 0xf;
1.1  skrll       *buf = (*buf & 0xf0) | (val & 0xf);
1.1  skrll       break;
1.1  skrll
1.1  skrll     case BFD_RELOC_SH_IMM4BY2:
1.1  skrll       max = 0xf;
1.1  skrll       shift = 1;
1.1  skrll       *buf = (*buf & 0xf0) | ((val >> 1) & 0xf);
1.1  skrll       break;
1.1  skrll
1.1  skrll     case BFD_RELOC_SH_IMM4BY4:
1.1  skrll       max = 0xf;
1.1  skrll       shift = 2;
1.1  skrll       *buf = (*buf & 0xf0) | ((val >> 2) & 0xf);
1.1  skrll       break;
1.1  skrll
1.1  skrll     case BFD_RELOC_SH_IMM8BY2:
1.1  skrll       max = 0xff;
1.1  skrll       shift = 1;
1.1  skrll       *buf = val >> 1;
1.1  skrll       break;
1.1  skrll
1.1  skrll     case BFD_RELOC_SH_IMM8BY4:
1.1  skrll       max = 0xff;
1.1  skrll       shift = 2;
1.1  skrll       *buf = val >> 2;
1.1  skrll       break;
1.1  skrll
1.1  skrll     case BFD_RELOC_8:
1.1  skrll     case BFD_RELOC_SH_IMM8:
1.1  skrll       /* Sometimes the 8 bit value is sign extended (e.g., add) and
1.1  skrll          sometimes it is not (e.g., and).  We permit any 8 bit value.
1.1  skrll          Note that adding further restrictions may invalidate
1.1  skrll          reasonable looking assembly code, such as ``and -0x1,r0''.  */
1.1  skrll       max = 0xff;
1.1  skrll       min = -0xff;
1.1  skrll       *buf++ = val;
1.1  skrll       break;
1.1  skrll
1.1  skrll     case BFD_RELOC_SH_PCRELIMM8BY4:
1.1  skrll       /* If we are dealing with a known destination ... */
1.1  skrll       if ((fixP->fx_addsy == NULL || S_IS_DEFINED (fixP->fx_addsy))
1.1  skrll 	  && (fixP->fx_subsy == NULL || S_IS_DEFINED (fixP->fx_addsy)))
1.1  skrll       {
1.1  skrll 	/* Don't silently move the destination due to misalignment.
1.1  skrll 	   The absolute address is the fragment base plus the offset into
1.1  skrll 	   the fragment plus the pc relative offset to the label.  */
1.1  skrll 	if ((fixP->fx_frag->fr_address + fixP->fx_where + val) & 3)
1.1  skrll 	  as_bad_where (fixP->fx_file, fixP->fx_line,
1.1  skrll 			_("offset to unaligned destination"));
1.1  skrll
1.1  skrll 	/* The displacement cannot be zero or backward even if aligned.
1.1  skrll 	   Allow -2 because val has already been adjusted somewhere.  */
1.1  skrll 	if (val < -2)
1.1  skrll 	  as_bad_where (fixP->fx_file, fixP->fx_line, _("negative offset"));
1.1  skrll       }
1.1  skrll
1.1  skrll       /* The lower two bits of the PC are cleared before the
1.1  skrll          displacement is added in.  We can assume that the destination
1.1  skrll          is on a 4 byte boundary.  If this instruction is also on a 4
1.1  skrll          byte boundary, then we want
1.1  skrll 	   (target - here) / 4
1.1  skrll 	 and target - here is a multiple of 4.
1.1  skrll 	 Otherwise, we are on a 2 byte boundary, and we want
1.1  skrll 	   (target - (here - 2)) / 4
1.1  skrll 	 and target - here is not a multiple of 4.  Computing
1.1  skrll 	   (target - (here - 2)) / 4 == (target - here + 2) / 4
1.1  skrll 	 works for both cases, since in the first case the addition of
1.1  skrll 	 2 will be removed by the division.  target - here is in the
1.1  skrll 	 variable val.  */
1.1  skrll       val = (val + 2) / 4;
1.1  skrll       if (val & ~0xff)
1.1  skrll 	as_bad_where (fixP->fx_file, fixP->fx_line, _("pcrel too far"));
1.1  skrll       buf[lowbyte] = val;
1.1  skrll       break;
1.1  skrll
1.1  skrll     case BFD_RELOC_SH_PCRELIMM8BY2:
1.1  skrll       val /= 2;
1.1  skrll       if (val & ~0xff)
1.1  skrll 	as_bad_where (fixP->fx_file, fixP->fx_line, _("pcrel too far"));
1.1  skrll       buf[lowbyte] = val;
1.1  skrll       break;
1.1  skrll
1.1  skrll     case BFD_RELOC_SH_PCDISP8BY2:
1.1  skrll       val /= 2;
1.1  skrll       if (val < -0x80 || val > 0x7f)
1.1  skrll 	as_bad_where (fixP->fx_file, fixP->fx_line, _("pcrel too far"));
1.1  skrll       buf[lowbyte] = val;
1.1  skrll       break;
1.1  skrll
1.1  skrll     case BFD_RELOC_SH_PCDISP12BY2:
1.1  skrll       val /= 2;
1.1  skrll       if (val < -0x800 || val > 0x7ff)
1.1  skrll 	as_bad_where (fixP->fx_file, fixP->fx_line, _("pcrel too far"));
1.1  skrll       buf[lowbyte] = val & 0xff;
1.1  skrll       buf[highbyte] |= (val >> 8) & 0xf;
1.1  skrll       break;
1.1  skrll
1.1  skrll     case BFD_RELOC_32:
1.1  skrll     case BFD_RELOC_32_PCREL:
1.1  skrll       apply_full_field_fix (fixP, buf, val, 4);
1.1  skrll       break;
1.1  skrll
1.1  skrll     case BFD_RELOC_16:
1.1  skrll       apply_full_field_fix (fixP, buf, val, 2);
1.1  skrll       break;
1.1  skrll
1.1  skrll     case BFD_RELOC_SH_USES:
1.1  skrll       /* Pass the value into sh_reloc().  */
1.1  skrll       fixP->fx_addnumber = val;
1.1  skrll       break;
1.1  skrll
1.1  skrll     case BFD_RELOC_SH_COUNT:
1.1  skrll     case BFD_RELOC_SH_ALIGN:
1.1  skrll     case BFD_RELOC_SH_CODE:
1.1  skrll     case BFD_RELOC_SH_DATA:
1.1  skrll     case BFD_RELOC_SH_LABEL:
1.1  skrll       /* Nothing to do here.  */
1.1  skrll       break;
1.1  skrll
1.1  skrll     case BFD_RELOC_SH_LOOP_START:
1.1  skrll     case BFD_RELOC_SH_LOOP_END:
1.1  skrll
1.1  skrll     case BFD_RELOC_VTABLE_INHERIT:
1.1  skrll     case BFD_RELOC_VTABLE_ENTRY:
1.1  skrll       fixP->fx_done = 0;
1.1  skrll       return;
1.1  skrll
1.1  skrll #ifdef OBJ_ELF
1.1  skrll     case BFD_RELOC_32_PLT_PCREL:
1.1  skrll       /* Make the jump instruction point to the address of the operand.  At
1.1  skrll 	 runtime we merely add the offset to the actual PLT entry.  */
1.1  skrll       * valP = 0xfffffffc;
1.1  skrll       val = fixP->fx_offset;
1.1  skrll       if (fixP->fx_subsy)
1.1  skrll 	val -= S_GET_VALUE (fixP->fx_subsy);
1.1  skrll       apply_full_field_fix (fixP, buf, val, 4);
1.1  skrll       break;
1.1  skrll
1.1  skrll     case BFD_RELOC_SH_GOTPC:
1.1  skrll       /* This is tough to explain.  We end up with this one if we have
1.1  skrll          operands that look like "_GLOBAL_OFFSET_TABLE_+[.-.L284]".
1.1  skrll          The goal here is to obtain the absolute address of the GOT,
1.1  skrll          and it is strongly preferable from a performance point of
1.1  skrll          view to avoid using a runtime relocation for this.  There are
1.1  skrll          cases where you have something like:
1.1  skrll
1.1  skrll          .long	_GLOBAL_OFFSET_TABLE_+[.-.L66]
1.1  skrll
1.1  skrll          and here no correction would be required.  Internally in the
1.1  skrll          assembler we treat operands of this form as not being pcrel
1.1  skrll          since the '.' is explicitly mentioned, and I wonder whether
1.1  skrll          it would simplify matters to do it this way.  Who knows.  In
1.1  skrll          earlier versions of the PIC patches, the pcrel_adjust field
1.1  skrll          was used to store the correction, but since the expression is
1.1  skrll          not pcrel, I felt it would be confusing to do it this way.  */
1.1  skrll       * valP -= 1;
1.1  skrll       apply_full_field_fix (fixP, buf, val, 4);
1.1  skrll       break;
1.1  skrll
1.1  skrll     case BFD_RELOC_SH_TLS_GD_32:
1.1  skrll     case BFD_RELOC_SH_TLS_LD_32:
1.1  skrll     case BFD_RELOC_SH_TLS_IE_32:
1.1  skrll       S_SET_THREAD_LOCAL (fixP->fx_addsy);
1.1  skrll       /* Fallthrough */
1.1  skrll     case BFD_RELOC_32_GOT_PCREL:
1.1  skrll     case BFD_RELOC_SH_GOTPLT32:
1.1  skrll       * valP = 0; /* Fully resolved at runtime.  No addend.  */
1.1  skrll       apply_full_field_fix (fixP, buf, 0, 4);
1.1  skrll       break;
1.1  skrll
1.1  skrll     case BFD_RELOC_SH_TLS_LDO_32:
1.1  skrll     case BFD_RELOC_SH_TLS_LE_32:
1.1  skrll       S_SET_THREAD_LOCAL (fixP->fx_addsy);
1.1  skrll       /* Fallthrough */
1.1  skrll     case BFD_RELOC_32_GOTOFF:
1.1  skrll       apply_full_field_fix (fixP, buf, val, 4);
1.1  skrll       break;
1.1  skrll #endif
1.1  skrll
1.1  skrll     default:
1.1  skrll #ifdef HAVE_SH64
1.1  skrll       shmedia_md_apply_fix (fixP, valP);
1.1  skrll       return;
1.1  skrll #else
1.1  skrll       abort ();
1.1  skrll #endif
1.1  skrll     }
1.1  skrll
1.1  skrll   if (shift != 0)
1.1  skrll     {
1.1  skrll       if ((val & ((1 << shift) - 1)) != 0)
1.1  skrll 	as_bad_where (fixP->fx_file, fixP->fx_line, _("misaligned offset"));
1.1  skrll       if (val >= 0)
1.1  skrll 	val >>= shift;
1.1  skrll       else
1.1  skrll 	val = ((val >> shift)
1.1  skrll 	       | ((long) -1 & ~ ((long) -1 >> shift)));
1.1  skrll     }
1.1  skrll   if (max != 0 && (val < min || val > max))
1.1  skrll     as_bad_where (fixP->fx_file, fixP->fx_line, _("offset out of range"));
1.1  skrll   else if (max != 0)
1.1  skrll     /* Stop the generic code from trying to overlow check the value as well.
1.1  skrll        It may not have the correct value anyway, as we do not store val back
1.1  skrll        into *valP.  */
1.1  skrll     fixP->fx_no_overflow = 1;
1.1  skrll
1.1  skrll   if (fixP->fx_addsy == NULL && fixP->fx_pcrel == 0)
1.1  skrll     fixP->fx_done = 1;
1.1  skrll }
1.1  skrll
1.1  skrll /* Called just before address relaxation.  Return the length
1.1  skrll    by which a fragment must grow to reach it's destination.  */
1.1  skrll
1.1  skrll int
1.1  skrll md_estimate_size_before_relax (fragS *fragP, segT segment_type)
1.1  skrll {
1.1  skrll   int what;
1.1  skrll
1.1  skrll   switch (fragP->fr_subtype)
1.1  skrll     {
1.1  skrll     default:
1.1  skrll #ifdef HAVE_SH64
1.1  skrll       return shmedia_md_estimate_size_before_relax (fragP, segment_type);
1.1  skrll #else
1.1  skrll       abort ();
1.1  skrll #endif
1.1  skrll
1.1  skrll
1.1  skrll     case C (UNCOND_JUMP, UNDEF_DISP):
1.1  skrll       /* Used to be a branch to somewhere which was unknown.  */
1.1  skrll       if (!fragP->fr_symbol)
1.1  skrll 	{
1.1  skrll 	  fragP->fr_subtype = C (UNCOND_JUMP, UNCOND12);
1.1  skrll 	}
1.1  skrll       else if (S_GET_SEGMENT (fragP->fr_symbol) == segment_type)
1.1  skrll 	{
1.1  skrll 	  fragP->fr_subtype = C (UNCOND_JUMP, UNCOND12);
1.1  skrll 	}
1.1  skrll       else
1.1  skrll 	{
1.1  skrll 	  fragP->fr_subtype = C (UNCOND_JUMP, UNDEF_WORD_DISP);
1.1  skrll 	}
1.1  skrll       break;
1.1  skrll
1.1  skrll     case C (COND_JUMP, UNDEF_DISP):
1.1  skrll     case C (COND_JUMP_DELAY, UNDEF_DISP):
1.1  skrll       what = GET_WHAT (fragP->fr_subtype);
1.1  skrll       /* Used to be a branch to somewhere which was unknown.  */
1.1  skrll       if (fragP->fr_symbol
1.1  skrll 	  && S_GET_SEGMENT (fragP->fr_symbol) == segment_type)
1.1  skrll 	{
1.1  skrll 	  /* Got a symbol and it's defined in this segment, become byte
1.1  skrll 	     sized - maybe it will fix up.  */
1.1  skrll 	  fragP->fr_subtype = C (what, COND8);
1.1  skrll 	}
1.1  skrll       else if (fragP->fr_symbol)
1.1  skrll 	{
1.1  skrll 	  /* Its got a segment, but its not ours, so it will always be long.  */
1.1  skrll 	  fragP->fr_subtype = C (what, UNDEF_WORD_DISP);
1.1  skrll 	}
1.1  skrll       else
1.1  skrll 	{
1.1  skrll 	  /* We know the abs value.  */
1.1  skrll 	  fragP->fr_subtype = C (what, COND8);
1.1  skrll 	}
1.1  skrll       break;
1.1  skrll
1.1  skrll     case C (UNCOND_JUMP, UNCOND12):
1.1  skrll     case C (UNCOND_JUMP, UNCOND32):
1.1  skrll     case C (UNCOND_JUMP, UNDEF_WORD_DISP):
1.1  skrll     case C (COND_JUMP, COND8):
1.1  skrll     case C (COND_JUMP, COND12):
1.1  skrll     case C (COND_JUMP, COND32):
1.1  skrll     case C (COND_JUMP, UNDEF_WORD_DISP):
1.1  skrll     case C (COND_JUMP_DELAY, COND8):
1.1  skrll     case C (COND_JUMP_DELAY, COND12):
1.1  skrll     case C (COND_JUMP_DELAY, COND32):
1.1  skrll     case C (COND_JUMP_DELAY, UNDEF_WORD_DISP):
1.1  skrll       /* When relaxing a section for the second time, we don't need to
1.1  skrll 	 do anything besides return the current size.  */
1.1  skrll       break;
1.1  skrll     }
1.1  skrll
1.1  skrll   fragP->fr_var = md_relax_table[fragP->fr_subtype].rlx_length;
1.1  skrll   return fragP->fr_var;
1.1  skrll }
1.1  skrll
1.1  skrll /* Put number into target byte order.  */
1.1  skrll
1.1  skrll void
1.1  skrll md_number_to_chars (char *ptr, valueT use, int nbytes)
1.1  skrll {
1.1  skrll #ifdef HAVE_SH64
1.1  skrll   /* We might need to set the contents type to data.  */
1.1  skrll   sh64_flag_output ();
1.1  skrll #endif
1.1  skrll
1.1  skrll   if (! target_big_endian)
1.1  skrll     number_to_chars_littleendian (ptr, use, nbytes);
1.1  skrll   else
1.1  skrll     number_to_chars_bigendian (ptr, use, nbytes);
1.1  skrll }
1.1  skrll
1.1  skrll /* This version is used in obj-coff.c eg. for the sh-hms target.  */
1.1  skrll
1.1  skrll long
1.1  skrll md_pcrel_from (fixS *fixP)
1.1  skrll {
1.1  skrll   return fixP->fx_size + fixP->fx_where + fixP->fx_frag->fr_address + 2;
1.1  skrll }
1.1  skrll
1.1  skrll long
1.1  skrll md_pcrel_from_section (fixS *fixP, segT sec)
1.1  skrll {
1.1  skrll   if (! sh_local_pcrel (fixP)
1.1  skrll       && fixP->fx_addsy != (symbolS *) NULL
1.1  skrll       && (generic_force_reloc (fixP)
1.1  skrll 	  || S_GET_SEGMENT (fixP->fx_addsy) != sec))
1.1  skrll     {
1.1  skrll       /* The symbol is undefined (or is defined but not in this section,
1.1  skrll 	 or we're not sure about it being the final definition).  Let the
1.1  skrll 	 linker figure it out.  We need to adjust the subtraction of a
1.1  skrll 	 symbol to the position of the relocated data, though.  */
1.1  skrll       return fixP->fx_subsy ? fixP->fx_where + fixP->fx_frag->fr_address : 0;
1.1  skrll     }
1.1  skrll
1.1  skrll   return md_pcrel_from (fixP);
1.1  skrll }
1.1  skrll
1.1  skrll /* Create a reloc.  */
1.1  skrll
1.1  skrll arelent *
1.1  skrll tc_gen_reloc (asection *section ATTRIBUTE_UNUSED, fixS *fixp)
1.1  skrll {
1.1  skrll   arelent *rel;
1.1  skrll   bfd_reloc_code_real_type r_type;
1.1  skrll
1.1  skrll   rel = (arelent *) xmalloc (sizeof (arelent));
1.1  skrll   rel->sym_ptr_ptr = (asymbol **) xmalloc (sizeof (asymbol *));
1.1  skrll   *rel->sym_ptr_ptr = symbol_get_bfdsym (fixp->fx_addsy);
1.1  skrll   rel->address = fixp->fx_frag->fr_address + fixp->fx_where;
1.1  skrll
1.1  skrll   r_type = fixp->fx_r_type;
1.1  skrll
1.1  skrll   if (SWITCH_TABLE (fixp))
1.1  skrll     {
1.1  skrll       *rel->sym_ptr_ptr = symbol_get_bfdsym (fixp->fx_subsy);
1.1  skrll       rel->addend = 0;
1.1  skrll       if (r_type == BFD_RELOC_16)
1.1  skrll 	r_type = BFD_RELOC_SH_SWITCH16;
1.1  skrll       else if (r_type == BFD_RELOC_8)
1.1  skrll 	r_type = BFD_RELOC_8_PCREL;
1.1  skrll       else if (r_type == BFD_RELOC_32)
1.1  skrll 	r_type = BFD_RELOC_SH_SWITCH32;
1.1  skrll       else
1.1  skrll 	abort ();
1.1  skrll     }
1.1  skrll   else if (r_type == BFD_RELOC_SH_USES)
1.1  skrll     rel->addend = fixp->fx_addnumber;
1.1  skrll   else if (r_type == BFD_RELOC_SH_COUNT)
1.1  skrll     rel->addend = fixp->fx_offset;
1.1  skrll   else if (r_type == BFD_RELOC_SH_ALIGN)
1.1  skrll     rel->addend = fixp->fx_offset;
1.1  skrll   else if (r_type == BFD_RELOC_VTABLE_INHERIT
1.1  skrll            || r_type == BFD_RELOC_VTABLE_ENTRY)
1.1  skrll     rel->addend = fixp->fx_offset;
1.1  skrll   else if (r_type == BFD_RELOC_SH_LOOP_START
1.1  skrll            || r_type == BFD_RELOC_SH_LOOP_END)
1.1  skrll     rel->addend = fixp->fx_offset;
1.1  skrll   else if (r_type == BFD_RELOC_SH_LABEL && fixp->fx_pcrel)
1.1  skrll     {
1.1  skrll       rel->addend = 0;
1.1  skrll       rel->address = rel->addend = fixp->fx_offset;
1.1  skrll     }
1.1  skrll #ifdef HAVE_SH64
1.1  skrll   else if (shmedia_init_reloc (rel, fixp))
1.1  skrll     ;
1.1  skrll #endif
1.1  skrll   else
1.1  skrll     rel->addend = fixp->fx_addnumber;
1.1  skrll
1.1  skrll   rel->howto = bfd_reloc_type_lookup (stdoutput, r_type);
1.1  skrll
1.1  skrll   if (rel->howto == NULL)
1.1  skrll     {
1.1  skrll       as_bad_where (fixp->fx_file, fixp->fx_line,
1.1  skrll 		    _("Cannot represent relocation type %s"),
1.1  skrll 		    bfd_get_reloc_code_name (r_type));
1.1  skrll       /* Set howto to a garbage value so that we can keep going.  */
1.1  skrll       rel->howto = bfd_reloc_type_lookup (stdoutput, BFD_RELOC_32);
1.1  skrll       assert (rel->howto != NULL);
1.1  skrll     }
1.1  skrll #ifdef OBJ_ELF
1.1  skrll   else if (rel->howto->type == R_SH_IND12W)
1.1  skrll     rel->addend += fixp->fx_offset - 4;
1.1  skrll #endif
1.1  skrll
1.1  skrll   return rel;
1.1  skrll }
1.1  skrll
1.1  skrll #ifdef OBJ_ELF
1.1  skrll inline static char *
1.1  skrll sh_end_of_match (char *cont, char *what)
1.1  skrll {
1.1  skrll   int len = strlen (what);
1.1  skrll
1.1  skrll   if (strncasecmp (cont, what, strlen (what)) == 0
1.1  skrll       && ! is_part_of_name (cont[len]))
1.1  skrll     return cont + len;
1.1  skrll
1.1  skrll   return NULL;
1.1  skrll }
1.1  skrll
1.1  skrll int
1.1  skrll sh_parse_name (char const *name,
1.1  skrll 	       expressionS *exprP,
1.1  skrll 	       enum expr_mode mode,
1.1  skrll 	       char *nextcharP)
1.1  skrll {
1.1  skrll   char *next = input_line_pointer;
1.1  skrll   char *next_end;
1.1  skrll   int reloc_type;
1.1  skrll   segT segment;
1.1  skrll
1.1  skrll   exprP->X_op_symbol = NULL;
1.1  skrll
1.1  skrll   if (strcmp (name, GLOBAL_OFFSET_TABLE_NAME) == 0)
1.1  skrll     {
1.1  skrll       if (! GOT_symbol)
1.1  skrll 	GOT_symbol = symbol_find_or_make (name);
1.1  skrll
1.1  skrll       exprP->X_add_symbol = GOT_symbol;
1.1  skrll     no_suffix:
1.1  skrll       /* If we have an absolute symbol or a reg, then we know its
1.1  skrll 	 value now.  */
1.1  skrll       segment = S_GET_SEGMENT (exprP->X_add_symbol);
1.1  skrll       if (mode != expr_defer && segment == absolute_section)
1.1  skrll 	{
1.1  skrll 	  exprP->X_op = O_constant;
1.1  skrll 	  exprP->X_add_number = S_GET_VALUE (exprP->X_add_symbol);
1.1  skrll 	  exprP->X_add_symbol = NULL;
1.1  skrll 	}
1.1  skrll       else if (mode != expr_defer && segment == reg_section)
1.1  skrll 	{
1.1  skrll 	  exprP->X_op = O_register;
1.1  skrll 	  exprP->X_add_number = S_GET_VALUE (exprP->X_add_symbol);
1.1  skrll 	  exprP->X_add_symbol = NULL;
1.1  skrll 	}
1.1  skrll       else
1.1  skrll 	{
1.1  skrll 	  exprP->X_op = O_symbol;
1.1  skrll 	  exprP->X_add_number = 0;
1.1  skrll 	}
1.1  skrll
1.1  skrll       return 1;
1.1  skrll     }
1.1  skrll
1.1  skrll   exprP->X_add_symbol = symbol_find_or_make (name);
1.1  skrll
1.1  skrll   if (*nextcharP != '@')
1.1  skrll     goto no_suffix;
1.1  skrll   else if ((next_end = sh_end_of_match (next + 1, "GOTOFF")))
1.1  skrll     reloc_type = BFD_RELOC_32_GOTOFF;
1.1  skrll   else if ((next_end = sh_end_of_match (next + 1, "GOTPLT")))
1.1  skrll     reloc_type = BFD_RELOC_SH_GOTPLT32;
1.1  skrll   else if ((next_end = sh_end_of_match (next + 1, "GOT")))
1.1  skrll     reloc_type = BFD_RELOC_32_GOT_PCREL;
1.1  skrll   else if ((next_end = sh_end_of_match (next + 1, "PLT")))
1.1  skrll     reloc_type = BFD_RELOC_32_PLT_PCREL;
1.1  skrll   else if ((next_end = sh_end_of_match (next + 1, "TLSGD")))
1.1  skrll     reloc_type = BFD_RELOC_SH_TLS_GD_32;
1.1  skrll   else if ((next_end = sh_end_of_match (next + 1, "TLSLDM")))
1.1  skrll     reloc_type = BFD_RELOC_SH_TLS_LD_32;
1.1  skrll   else if ((next_end = sh_end_of_match (next + 1, "GOTTPOFF")))
1.1  skrll     reloc_type = BFD_RELOC_SH_TLS_IE_32;
1.1  skrll   else if ((next_end = sh_end_of_match (next + 1, "TPOFF")))
1.1  skrll     reloc_type = BFD_RELOC_SH_TLS_LE_32;
1.1  skrll   else if ((next_end = sh_end_of_match (next + 1, "DTPOFF")))
1.1  skrll     reloc_type = BFD_RELOC_SH_TLS_LDO_32;
1.1  skrll   else
1.1  skrll     goto no_suffix;
1.1  skrll
1.1  skrll   *input_line_pointer = *nextcharP;
1.1  skrll   input_line_pointer = next_end;
1.1  skrll   *nextcharP = *input_line_pointer;
1.1  skrll   *input_line_pointer = '\0';
1.1  skrll
1.1  skrll   exprP->X_op = O_PIC_reloc;
1.1  skrll   exprP->X_add_number = 0;
1.1  skrll   exprP->X_md = reloc_type;
1.1  skrll
1.1  skrll   return 1;
1.1  skrll }
1.1  skrll
1.1  skrll void
1.1  skrll sh_cfi_frame_initial_instructions (void)
1.1  skrll {
1.1  skrll   cfi_add_CFA_def_cfa (15, 0);
1.1  skrll }
1.1  skrll
1.1  skrll int
1.1  skrll sh_regname_to_dw2regnum (char *regname)
1.1  skrll {
1.1  skrll   unsigned int regnum = -1;
1.1  skrll   unsigned int i;
1.1  skrll   const char *p;
1.1  skrll   char *q;
1.1  skrll   static struct { char *name; int dw2regnum; } regnames[] =
1.1  skrll     {
1.1  skrll       { "pr", 17 }, { "t", 18 }, { "gbr", 19 }, { "mach", 20 },
1.1  skrll       { "macl", 21 }, { "fpul", 23 }
1.1  skrll     };
1.1  skrll
1.1  skrll   for (i = 0; i < ARRAY_SIZE (regnames); ++i)
1.1  skrll     if (strcmp (regnames[i].name, regname) == 0)
1.1  skrll       return regnames[i].dw2regnum;
1.1  skrll
1.1  skrll   if (regname[0] == 'r')
1.1  skrll     {
1.1  skrll       p = regname + 1;
1.1  skrll       regnum = strtoul (p, &q, 10);
1.1  skrll       if (p == q || *q || regnum >= 16)
1.1  skrll 	return -1;
1.1  skrll     }
1.1  skrll   else if (regname[0] == 'f' && regname[1] == 'r')
1.1  skrll     {
1.1  skrll       p = regname + 2;
1.1  skrll       regnum = strtoul (p, &q, 10);
1.1  skrll       if (p == q || *q || regnum >= 16)
1.1  skrll 	return -1;
1.1  skrll       regnum += 25;
1.1  skrll     }
1.1  skrll   else if (regname[0] == 'x' && regname[1] == 'd')
1.1  skrll     {
1.1  skrll       p = regname + 2;
1.1  skrll       regnum = strtoul (p, &q, 10);
1.1  skrll       if (p == q || *q || regnum >= 8)
1.1  skrll 	return -1;
1.1  skrll       regnum += 87;
               }
             return regnum;
           }
           #endif /* OBJ_ELF */