| blob | 33c63f540e01b775f5ccadb07c9aad4ef313da3a |
1 /* tc-mn10300.c -- Assembler code for the Matsushita 10300
2 Copyright 1996, 1997, 1998, 1999, 2000, 2001, 2002, 2003, 2004, 2005,
3 2006, 2007 Free Software Foundation, Inc.
5 This file is part of GAS, the GNU Assembler.
7 GAS is free software; you can redistribute it and/or modify
8 it under the terms of the GNU General Public License as published by
9 the Free Software Foundation; either version 3, or (at your option)
10 any later version.
12 GAS is distributed in the hope that it will be useful,
13 but WITHOUT ANY WARRANTY; without even the implied warranty of
14 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 GNU General Public License for more details.
17 You should have received a copy of the GNU General Public License
18 along with GAS; see the file COPYING. If not, write to
19 the Free Software Foundation, 51 Franklin Street - Fifth Floor,
20 Boston, MA 02110-1301, USA. */
28 \f
29 /* Structure to hold information about predefined registers. */
30 struct reg_name
31 {
34 };
36 /* Generic assembler global variables which must be defined by all
37 targets. */
39 /* Characters which always start a comment. */
42 /* Characters which start a comment at the beginning of a line. */
45 /* Characters which may be used to separate multiple commands on a
46 single line. */
49 /* Characters which are used to indicate an exponent in a floating
50 point number. */
53 /* Characters which mean that a number is a floating point constant,
54 as in 0d1.0. */
56 \f
58 {
59 /* The plus values for the bCC and fBCC instructions in the table below
60 are because the branch instruction is translated into a jump
61 instruction that is now +2 or +3 bytes further on in memory, and the
62 correct size of jump instruction must be selected. */
63 /* bCC relaxing. */
68 /* bCC relaxing (uncommon cases for 3byte length instructions) */
73 /* call relaxing. */
77 /* calls relaxing. */
81 /* jmp relaxing. */
86 /* fbCC relaxing. */
91 };
93 /* Set linkrelax here to avoid fixups in most sections. */
98 /* Fixups. */
99 #define MAX_INSN_FIXUPS 5
101 struct mn10300_fixup
102 {
103 expressionS exp;
105 bfd_reloc_code_real_type reloc;
106 };
110 /* We must store the value of each register operand so that we can
111 verify that certain registers do not match. */
113 \f
117 {
119 };
123 #define HAVE_AM33_2 (current_machine == AM33_2)
124 #define HAVE_AM33 (current_machine == AM33 || HAVE_AM33_2)
125 #define HAVE_AM30 (current_machine == AM30)
127 /* Opcode hash table. */
130 /* This table is sorted. Suitable for searching by a binary search. */
132 {
137 };
140 {
145 };
148 {
189 };
192 {
214 };
217 {
250 };
253 {
270 };
272 /* We abuse the `value' field, that would be otherwise unused, to
273 encode the architecture on which (access to) the register was
274 introduced. FIXME: we should probably warn when we encounter a
275 register name when assembling for an architecture that doesn't
276 support it, before parsing it as a symbol name. */
278 {
284 };
286 #define OTHER_REG_NAME_CNT ARRAY_SIZE (other_registers)
288 /* Perform a binary search of the given register table REGS to see
289 if NAME is a valid regiter name. Returns the register number from
290 the array on success, or -1 on failure. */
292 static int
296 {
302 do
303 {
312 else
314 }
318 }
320 /* Looks at the current position in the input line to see if it is
321 the name of a register in TABLE. If it is, then the name is
322 converted into an expression returned in EXPRESSIONP (with X_op
323 set to O_register and X_add_number set to the register number), the
324 input pointer is left pointing at the first non-blank character after
325 the name and the function returns TRUE. Otherwise the input pointer
326 is left alone and the function returns FALSE. */
328 static bfd_boolean
332 {
338 /* Find the spelling of the operand. */
344 /* Put back the delimiting char. */
347 /* Look to see if it's in the register table. */
349 {
353 /* Make the rest nice. */
358 }
360 /* Reset the line as if we had not done anything. */
363 }
365 static bfd_boolean
367 {
369 }
372 static bfd_boolean
374 {
376 }
378 static bfd_boolean
380 {
382 }
384 static bfd_boolean
386 {
388 }
390 static bfd_boolean
392 {
394 }
396 static bfd_boolean
398 {
400 }
402 static bfd_boolean
404 {
410 /* Find the spelling of the operand. */
416 /* Put back the delimiting char. */
419 /* Look to see if it's in the register table. */
422 {
426 /* Make the rest nice. */
431 }
433 /* Reset the line as if we had not done anything. */
436 }
438 void
440 {
443 }
445 int
447 {
449 }
451 symbolS *
453 {
455 }
459 {
461 }
463 void
467 {
473 {
478 }
480 {
481 /* Reverse the condition of the first branch. */
486 {
519 }
522 /* Create a fixup for the reversed conditional branch. */
528 /* Now create the unconditional branch + fixup to the
529 final target. */
535 }
537 {
538 /* Reverse the condition of the first branch. */
543 {
576 }
579 /* Create a fixup for the reversed conditional branch. */
585 /* Now create the unconditional branch + fixup to the
586 final target. */
592 }
594 {
599 }
601 {
602 /* Reverse the condition of the first branch. */
607 {
622 }
625 /* Create a fixup for the reversed conditional branch. */
631 /* Now create the unconditional branch + fixup to the
632 final target. */
638 }
640 {
641 /* Reverse the condition of the first branch. */
646 {
658 }
661 /* Create a fixup for the reversed conditional branch. */
667 /* Now create the unconditional branch + fixup to the
668 final target. */
674 }
676 {
684 }
686 {
697 }
699 {
708 }
710 {
720 }
722 {
728 }
730 {
739 }
741 {
750 }
752 {
757 }
759 {
760 /* Reverse the condition of the first branch. */
765 {
810 }
813 /* Create a fixup for the reversed conditional branch. */
819 /* Now create the unconditional branch + fixup to the
820 final target. */
826 }
828 {
829 /* Reverse the condition of the first branch. */
834 {
879 }
882 /* Create a fixup for the reversed conditional branch. */
888 /* Now create the unconditional branch + fixup to the
889 final target. */
895 }
896 else
898 }
900 valueT
902 {
906 }
908 void
910 {
916 /* Insert unique names into hash table. The MN10300 instruction set
917 has many identical opcode names that have different opcodes based
918 on the operands. This hash table then provides a quick index to
919 the first opcode with a particular name in the opcode table. */
923 {
925 {
928 }
929 op++;
930 }
932 /* Set the default machine type. */
933 #ifdef TE_LINUX
938 #else
943 #endif
944 }
950 {
964 }
968 {
971 repeat:
973 {
976 and the expression that references it happen
977 to end up in different frags, the subtract
978 won't be simplified within expression(). */
979 /* The PIC-related operand must be the first operand of a sum. */
1007 }
1010 }
1012 void
1014 {
1025 {
1039 }
1042 {
1061 }
1063 {
1064 error:
1067 }
1070 }
1072 static bfd_boolean
1074 offsetT val)
1075 {
1076 /* No need to check 32bit operands for a bit. Note that
1077 MN10300_OPERAND_SPLIT is an implicit 32bit operand. */
1080 {
1082 offsetT test;
1090 {
1093 }
1094 else
1095 {
1098 }
1104 }
1106 }
1108 /* Insert an operand value into an instruction. */
1110 static void
1114 offsetT val,
1118 {
1119 /* No need to check 32bit operands for a bit. Note that
1120 MN10300_OPERAND_SPLIT is an implicit 32bit operand. */
1123 {
1125 offsetT test;
1133 {
1136 }
1137 else
1138 {
1141 }
1147 }
1150 {
1154 }
1156 {
1160 }
1162 {
1163 /* See devo/opcodes/m10300-opc.c just before #define FSM0 for an
1164 explanation of these variables. Note that FMT-implied shifts
1165 are not taken into account for FP registers. */
1170 {
1172 /* Handle regular FP registers. */
1174 {
1175 /* This is an `m' register. */
1178 }
1179 else
1180 {
1181 /* This is an `n' register. */
1184 }
1192 /* Handle accumulators. */
1202 }
1205 }
1207 {
1214 }
1215 else
1216 {
1223 }
1224 }
1226 void
1228 {
1239 /* Get the opcode. */
1241 ;
1245 /* Find the first opcode with the proper name. */
1248 {
1251 }
1260 {
1268 /* Reset the array of register operands. */
1278 /* If the instruction is not available on the current machine
1279 then it can not possibly match. */
1289 {
1291 expressionS ex;
1294 {
1296 }
1297 else
1298 {
1301 }
1309 /* Gather the operand. */
1314 {
1316 {
1320 }
1321 input_line_pointer++;
1323 }
1324 /* See if we can match the operands. */
1326 {
1328 {
1332 }
1333 }
1335 {
1337 {
1341 }
1342 }
1344 {
1349 {
1354 }
1357 }
1359 {
1361 {
1365 }
1366 }
1368 {
1370 {
1374 }
1375 }
1377 {
1379 {
1383 }
1384 }
1386 {
1388 {
1392 }
1393 }
1395 {
1400 {
1405 }
1408 }
1410 {
1415 {
1420 }
1423 }
1425 {
1430 {
1435 }
1438 }
1440 {
1445 {
1450 }
1453 }
1455 {
1460 {
1465 }
1468 }
1470 {
1475 {
1480 }
1483 }
1485 {
1487 {
1491 }
1492 input_line_pointer++;
1494 }
1496 {
1501 {
1506 }
1509 }
1511 {
1516 {
1521 }
1524 }
1526 {
1529 {
1533 }
1535 /* Eat the '['. */
1536 input_line_pointer++;
1538 /* We used to reject a null register list here; however,
1539 we accept it now so the compiler can emit "call"
1540 instructions for all calls to named functions.
1542 The linker can then fill in the appropriate bits for the
1543 register list and stack size or change the instruction
1544 into a "calls" if using "call" is not profitable. */
1546 {
1551 input_line_pointer++;
1557 {
1560 }
1562 {
1565 }
1567 {
1570 }
1572 {
1575 }
1577 {
1580 }
1583 {
1586 }
1589 {
1592 }
1595 {
1598 }
1601 {
1604 }
1605 else
1606 {
1610 }
1611 }
1612 input_line_pointer++;
1617 }
1619 {
1623 }
1625 {
1629 }
1631 {
1635 }
1637 {
1641 }
1643 {
1647 }
1649 {
1653 }
1655 {
1659 }
1661 {
1665 }
1666 else
1667 {
1669 }
1672 {
1680 {
1689 {
1693 }
1708 else
1715 /* And note the register number in the register array. */
1718 }
1721 /* If this operand can be promoted, and it doesn't
1722 fit into the allocated bitfield for this insn,
1723 then promote it (ie this opcode does not match). */
1727 {
1731 }
1738 /* If this operand can be promoted, then this opcode didn't
1739 match since we can't know if it needed promotion! */
1741 {
1745 }
1747 /* We need to generate a fixup for this expression. */
1757 }
1759 keep_going:
1765 }
1767 /* Make sure we used all the operands! */
1771 /* If this instruction has registers that must not match, verify
1772 that they do indeed not match. */
1774 {
1777 /* Look at each operand to see if it's marked. */
1779 {
1781 {
1784 /* operand I is marked. Check that it does not match any
1785 operands > I which are marked. */
1787 {
1790 {
1794 }
1795 }
1796 }
1797 }
1798 }
1800 error:
1802 {
1805 {
1808 }
1812 }
1814 }
1824 /* Determine the size of the instruction. */
1862 {
1863 /* On a 64-bit host the size of an 'int' is not the same
1864 as the size of a pointer, so we need a union to convert
1865 the opindex field of the fr_cgen structure into a char *
1866 so that it can be stored in the frag. We do not have
1867 to worry about loosing accuracy as we are not going to
1868 be even close to the 32bit limit of the int. */
1869 union
1870 {
1873 }
1874 opindex_converter;
1877 /* We want to anchor the line info to the previous frag (if
1878 there isn't one, create it), so that, when the insn is
1879 resized, we still get the right address for the beginning of
1880 the region. */
1884 /* bCC */
1886 {
1887 /* Handle bra specially. Basically treat it like jmp so
1888 that we automatically handle 8, 16 and 32 bit offsets
1889 correctly as well as jumps to an undefined address.
1891 It is also important to not treat it like other bCC
1892 instructions since the long forms of bra is different
1893 from other bCC instructions. */
1896 else
1898 }
1899 /* call */
1902 /* calls */
1905 /* jmp */
1910 /* bCC (uncommon cases) */
1911 else
1920 /* This is pretty hokey. We basically just care about the
1921 opcode, so we have to write out the first word big endian.
1923 The exception is "call", which has two operands that we
1924 care about.
1926 The first operand (the register list) happens to be in the
1927 first instruction word, and will be in the right place if
1928 we output the first word in big endian mode.
1930 The second operand (stack size) is in the extension word,
1931 and we want it to appear as the first character in the extension
1932 word (as it appears in memory). Luckily, writing the extension
1933 word in big endian format will do what we want. */
1936 {
1939 }
1942 }
1943 else
1944 {
1945 /* Allocate space for the instruction. */
1948 /* Fill in bytes for the instruction. Note that opcode fields
1949 are written big-endian, 16 & 32bit immediates are written
1950 little endian. Egad. */
1958 {
1960 }
1964 {
1965 /* A format S2 instruction that is _not_ "ret" and "retf". */
1968 }
1970 {
1971 /* This must be a ret or retf, which is written entirely in
1972 big-endian format. */
1974 }
1977 {
1978 /* This must be a format S4 "call" instruction. What a pain. */
1984 }
1986 {
1987 /* This must be a format S4 "jmp" instruction. */
1991 }
1993 {
2000 }
2005 {
2006 /* A format D2 instruction where the 16bit immediate is
2007 really a single 16bit value, not two 8bit values. */
2010 }
2012 {
2013 /* A format D2 instruction where the 16bit immediate
2014 is really two 8bit immediates. */
2016 }
2018 {
2022 }
2024 {
2029 }
2031 {
2038 }
2040 {
2046 }
2048 {
2053 }
2055 /* Create any fixups. */
2057 {
2066 {
2088 }
2089 else
2090 {
2097 /* How big is the reloc? Remember SPLIT relocs are
2098 implicitly 32bits. */
2103 else
2106 /* Is the reloc pc-relative? */
2113 /* Choose a proper BFD relocation type. */
2115 ;
2117 {
2124 else
2126 }
2127 else
2128 {
2135 else
2137 }
2145 }
2146 }
2149 }
2151 /* Label this frag as one that contains instructions. */
2153 }
2155 /* If while processing a fixup, a reloc really needs to be created
2156 then it is done here. */
2158 arelent **
2160 {
2169 {
2175 }
2183 {
2186 }
2189 {
2197 /* If we have a difference between two (non-absolute) symbols we must
2198 generate two relocs (one for each symbol) and allow the linker to
2199 resolve them - relaxation may change the distances between symbols,
2200 even local symbols defined in the same section. */
2202 {
2224 }
2225 else
2226 {
2233 {
2251 reloc->sym_ptr_ptr
2254 }
2260 }
2261 }
2262 else
2263 {
2267 }
2269 }
2271 /* Returns true iff the symbol attached to the frag is at a known location
2272 in the given section, (and hence the relocation to it can be relaxed by
2273 the assembler). */
2276 {
2283 }
2285 int
2287 {
2305 }
2307 long
2309 {
2312 /* The symbol is undefined or weak. Let the linker figure it out. */
2316 }
2318 void
2320 {
2327 /* This should never happen. */
2331 /* The value we are passed in *valuep includes the symbol values.
2332 If we are doing this relocation the code in write.c is going to
2333 call bfd_install_relocation, which is also going to use the symbol
2334 value. That means that if the reloc is fully resolved we want to
2335 use *valuep since bfd_install_relocation is not being used.
2337 However, if the reloc is not fully resolved we do not want to use
2338 *valuep, and must use fx_offset instead. However, if the reloc
2339 is PC relative, we do want to use *valuep since it includes the
2340 result of md_pcrel_from. */
2344 /* If the fix is relative to a symbol which is not defined, or not
2345 in the same segment as the fix, we cannot resolve it here. */
2349 {
2352 }
2355 {
2384 }
2388 /* If a symbol remains, pass the fixup, as a reloc, onto the linker. */
2391 }
2393 /* Return zero if the fixup in fixp should be left alone and not
2394 adjusted. */
2396 bfd_boolean
2398 {
2400 {
2403 }
2404 /* Non-relative relocs can (and must) be adjusted if they do
2405 not meet the criteria below, or the generic criteria. */
2409 /* Do not adjust relocations involving symbols in code sections,
2410 because it breaks linker relaxations. This could be fixed in the
2411 linker, but this fix is simpler, and it pretty much only affects
2412 object size a little bit. */
2416 /* Likewise, do not adjust symbols that won't be merged, or debug
2417 symbols, because they too break relaxation. We do want to adjust
2418 other mergable symbols, like .rodata, because code relaxations
2419 need section-relative symbols to properly relax them. */
2427 }
2429 static void
2431 {
2436 }
2440 {
2448 }
2450 int
2455 {
2459 segT segment;
2464 {
2469 no_suffix:
2470 /* If we have an absolute symbol or a reg,
2471 then we know its value now. */
2474 {
2478 }
2480 {
2484 }
2485 else
2486 {
2489 }
2492 }
2504 else
2517 }
2519 /* The target specific pseudo-ops which we support. */
2521 {
2527 };
2529 /* Returns FALSE if there is some mn10300 specific reason why the
2530 subtraction of two same-section symbols cannot be computed by
2531 the assembler. */
2533 bfd_boolean
2535 {
2536 bfd_boolean result;
2541 /* If we are not performing linker relaxation then we have nothing
2542 to worry about. */
2546 /* If the symbols are not in a code section then they are OK. */
2550 /* Otherwise we have to scan the fragments between the two symbols.
2551 If any instructions are found then we have to assume that linker
2552 relaxation may change their size and so we must delay resolving
2553 the subtraction until the final link. */
2562 {
2567 }
2571 {
2576 }
2579 /* The two symbols are on disjoint fragment chains
2580 - we cannot possibly compute their difference. */
2584 }
2586 /* When relaxing, we need to output a reloc for any .align directive
2587 that requests alignment to a two byte boundary or larger. */
2589 void
2591 {
2598 /* Do not create relocs for the merging sections - such
2599 relocs will prevent the contents from being merged. */
2601 /* Create a new fixup to record the alignment request. The symbol is
2602 irrelevent but must be present so we use the absolute section symbol.
2603 The offset from the symbol is used to record the power-of-two alignment
2604 value. The size is set to 0 because the frag may already be aligned,
2605 thus causing cvt_frag_to_fill to reduce the size of the frag to zero. */
2607 BFD_RELOC_MN10300_ALIGN);
2608 }
2610 bfd_boolean
2612 {
2619 }