tc-sparc.c revision 1.7
1 1.1 skrll /* tc-sparc.c -- Assemble for the SPARC 2 1.7 christos Copyright (C) 1989-2022 Free Software Foundation, Inc. 3 1.1 skrll This file is part of GAS, the GNU Assembler. 4 1.1 skrll 5 1.1 skrll GAS is free software; you can redistribute it and/or modify 6 1.1 skrll it under the terms of the GNU General Public License as published by 7 1.1 skrll the Free Software Foundation; either version 3, or (at your option) 8 1.1 skrll any later version. 9 1.1 skrll 10 1.1 skrll GAS is distributed in the hope that it will be useful, 11 1.1 skrll but WITHOUT ANY WARRANTY; without even the implied warranty of 12 1.1 skrll MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the 13 1.1 skrll GNU General Public License for more details. 14 1.1 skrll 15 1.1 skrll You should have received a copy of the GNU General Public 16 1.1 skrll License along with GAS; see the file COPYING. If not, write 17 1.1 skrll to the Free Software Foundation, 51 Franklin Street - Fifth Floor, 18 1.1 skrll Boston, MA 02110-1301, USA. */ 19 1.1 skrll 20 1.1 skrll #include "as.h" 21 1.1 skrll #include "safe-ctype.h" 22 1.1 skrll #include "subsegs.h" 23 1.1 skrll 24 1.1 skrll #include "opcode/sparc.h" 25 1.1 skrll #include "dw2gencfi.h" 26 1.1 skrll 27 1.1 skrll #include "elf/sparc.h" 28 1.1 skrll #include "dwarf2dbg.h" 29 1.1 skrll 30 1.1 skrll /* Some ancient Sun C compilers would not take such hex constants as 31 1.1 skrll unsigned, and would end up sign-extending them to form an offsetT, 32 1.1 skrll so use these constants instead. */ 33 1.1 skrll #define U0xffffffff ((((unsigned long) 1 << 16) << 16) - 1) 34 1.1 skrll #define U0x80000000 ((((unsigned long) 1 << 16) << 15)) 35 1.1 skrll 36 1.1 skrll static int sparc_ip (char *, const struct sparc_opcode **); 37 1.4 christos static int parse_sparc_asi (char **, const sparc_asi **); 38 1.1 skrll static int parse_keyword_arg (int (*) (const char *), char **, int *); 39 1.1 skrll static int parse_const_expr_arg (char **, int *); 40 1.1 skrll static int get_expression (char *); 41 1.1 skrll 42 1.1 skrll /* Default architecture. */ 43 1.1 skrll /* ??? The default value should be V8, but sparclite support was added 44 1.1 skrll by making it the default. GCC now passes -Asparclite, so maybe sometime in 45 1.1 skrll the future we can set this to V8. */ 46 1.1 skrll #ifndef DEFAULT_ARCH 47 1.1 skrll #define DEFAULT_ARCH "sparclite" 48 1.1 skrll #endif 49 1.3 christos static const char *default_arch = DEFAULT_ARCH; 50 1.1 skrll 51 1.1 skrll /* Non-zero if the initial values of `max_architecture' and `sparc_arch_size' 52 1.1 skrll have been set. */ 53 1.1 skrll static int default_init_p; 54 1.1 skrll 55 1.1 skrll /* Current architecture. We don't bump up unless necessary. */ 56 1.1 skrll static enum sparc_opcode_arch_val current_architecture = SPARC_OPCODE_ARCH_V6; 57 1.1 skrll 58 1.1 skrll /* The maximum architecture level we can bump up to. 59 1.1 skrll In a 32 bit environment, don't allow bumping up to v9 by default. 60 1.1 skrll The native assembler works this way. The user is required to pass 61 1.1 skrll an explicit argument before we'll create v9 object files. However, if 62 1.1 skrll we don't see any v9 insns, a v8plus object file is not created. */ 63 1.1 skrll static enum sparc_opcode_arch_val max_architecture; 64 1.1 skrll 65 1.1 skrll /* Either 32 or 64, selects file format. */ 66 1.1 skrll static int sparc_arch_size; 67 1.1 skrll /* Initial (default) value, recorded separately in case a user option 68 1.1 skrll changes the value before md_show_usage is called. */ 69 1.1 skrll static int default_arch_size; 70 1.1 skrll 71 1.1 skrll /* The currently selected v9 memory model. Currently only used for 72 1.1 skrll ELF. */ 73 1.1 skrll static enum { MM_TSO, MM_PSO, MM_RMO } sparc_memory_model = MM_RMO; 74 1.2 joerg 75 1.2 joerg #ifndef TE_SOLARIS 76 1.2 joerg /* Bitmask of instruction types seen so far, used to populate the 77 1.2 joerg GNU attributes section with hwcap information. */ 78 1.7 christos static uint64_t hwcap_seen; 79 1.2 joerg #endif 80 1.1 skrll 81 1.7 christos static uint64_t hwcap_allowed; 82 1.2 joerg 83 1.1 skrll static int architecture_requested; 84 1.1 skrll static int warn_on_bump; 85 1.1 skrll 86 1.1 skrll /* If warn_on_bump and the needed architecture is higher than this 87 1.1 skrll architecture, issue a warning. */ 88 1.1 skrll static enum sparc_opcode_arch_val warn_after_architecture; 89 1.1 skrll 90 1.4 christos /* Non-zero if the assembler should generate error if an undeclared 91 1.4 christos g[23] register has been used in -64. */ 92 1.1 skrll static int no_undeclared_regs; 93 1.1 skrll 94 1.4 christos /* Non-zero if the assembler should generate a warning if an 95 1.4 christos unpredictable DCTI (delayed control transfer instruction) couple is 96 1.4 christos found. */ 97 1.4 christos static int dcti_couples_detect; 98 1.4 christos 99 1.1 skrll /* Non-zero if we should try to relax jumps and calls. */ 100 1.1 skrll static int sparc_relax; 101 1.1 skrll 102 1.1 skrll /* Non-zero if we are generating PIC code. */ 103 1.1 skrll int sparc_pic_code; 104 1.1 skrll 105 1.1 skrll /* Non-zero if we should give an error when misaligned data is seen. */ 106 1.1 skrll static int enforce_aligned_data; 107 1.1 skrll 108 1.1 skrll extern int target_big_endian; 109 1.1 skrll 110 1.1 skrll static int target_little_endian_data; 111 1.1 skrll 112 1.1 skrll /* Symbols for global registers on v9. */ 113 1.1 skrll static symbolS *globals[8]; 114 1.1 skrll 115 1.1 skrll /* The dwarf2 data alignment, adjusted for 32 or 64 bit. */ 116 1.1 skrll int sparc_cie_data_alignment; 117 1.1 skrll 118 1.1 skrll /* V9 and 86x have big and little endian data, but instructions are always big 119 1.1 skrll endian. The sparclet has bi-endian support but both data and insns have 120 1.1 skrll the same endianness. Global `target_big_endian' is used for data. 121 1.1 skrll The following macro is used for instructions. */ 122 1.1 skrll #ifndef INSN_BIG_ENDIAN 123 1.1 skrll #define INSN_BIG_ENDIAN (target_big_endian \ 124 1.1 skrll || default_arch_type == sparc86x \ 125 1.1 skrll || SPARC_OPCODE_ARCH_V9_P (max_architecture)) 126 1.1 skrll #endif 127 1.1 skrll 128 1.1 skrll /* Handle of the OPCODE hash table. */ 129 1.7 christos static htab_t op_hash; 130 1.1 skrll 131 1.1 skrll static void s_data1 (void); 132 1.1 skrll static void s_seg (int); 133 1.1 skrll static void s_proc (int); 134 1.1 skrll static void s_reserve (int); 135 1.1 skrll static void s_common (int); 136 1.1 skrll static void s_empty (int); 137 1.1 skrll static void s_uacons (int); 138 1.1 skrll static void s_ncons (int); 139 1.1 skrll static void s_register (int); 140 1.1 skrll 141 1.1 skrll const pseudo_typeS md_pseudo_table[] = 142 1.1 skrll { 143 1.1 skrll {"align", s_align_bytes, 0}, /* Defaulting is invalid (0). */ 144 1.1 skrll {"common", s_common, 0}, 145 1.1 skrll {"empty", s_empty, 0}, 146 1.1 skrll {"global", s_globl, 0}, 147 1.1 skrll {"half", cons, 2}, 148 1.1 skrll {"nword", s_ncons, 0}, 149 1.1 skrll {"optim", s_ignore, 0}, 150 1.1 skrll {"proc", s_proc, 0}, 151 1.1 skrll {"reserve", s_reserve, 0}, 152 1.1 skrll {"seg", s_seg, 0}, 153 1.1 skrll {"skip", s_space, 0}, 154 1.1 skrll {"word", cons, 4}, 155 1.1 skrll {"xword", cons, 8}, 156 1.1 skrll {"uahalf", s_uacons, 2}, 157 1.1 skrll {"uaword", s_uacons, 4}, 158 1.1 skrll {"uaxword", s_uacons, 8}, 159 1.1 skrll /* These are specific to sparc/svr4. */ 160 1.1 skrll {"2byte", s_uacons, 2}, 161 1.1 skrll {"4byte", s_uacons, 4}, 162 1.1 skrll {"8byte", s_uacons, 8}, 163 1.1 skrll {"register", s_register, 0}, 164 1.1 skrll {NULL, 0, 0}, 165 1.1 skrll }; 166 1.1 skrll 167 1.1 skrll /* This array holds the chars that always start a comment. If the 168 1.1 skrll pre-processor is disabled, these aren't very useful. */ 169 1.1 skrll const char comment_chars[] = "!"; /* JF removed '|' from 170 1.1 skrll comment_chars. */ 171 1.1 skrll 172 1.1 skrll /* This array holds the chars that only start a comment at the beginning of 173 1.1 skrll a line. If the line seems to have the form '# 123 filename' 174 1.1 skrll .line and .file directives will appear in the pre-processed output. */ 175 1.1 skrll /* Note that input_file.c hand checks for '#' at the beginning of the 176 1.1 skrll first line of the input file. This is because the compiler outputs 177 1.1 skrll #NO_APP at the beginning of its output. */ 178 1.1 skrll /* Also note that comments started like this one will always 179 1.1 skrll work if '/' isn't otherwise defined. */ 180 1.1 skrll const char line_comment_chars[] = "#"; 181 1.1 skrll 182 1.1 skrll const char line_separator_chars[] = ";"; 183 1.1 skrll 184 1.1 skrll /* Chars that can be used to separate mant from exp in floating point 185 1.1 skrll nums. */ 186 1.1 skrll const char EXP_CHARS[] = "eE"; 187 1.1 skrll 188 1.1 skrll /* Chars that mean this number is a floating point constant. 189 1.1 skrll As in 0f12.456 190 1.1 skrll or 0d1.2345e12 */ 191 1.1 skrll const char FLT_CHARS[] = "rRsSfFdDxXpP"; 192 1.1 skrll 193 1.1 skrll /* Also be aware that MAXIMUM_NUMBER_OF_CHARS_FOR_FLOAT may have to be 194 1.1 skrll changed in read.c. Ideally it shouldn't have to know about it at all, 195 1.1 skrll but nothing is ideal around here. */ 196 1.1 skrll 197 1.1 skrll #define isoctal(c) ((unsigned) ((c) - '0') < 8) 198 1.1 skrll 199 1.1 skrll struct sparc_it 200 1.1 skrll { 201 1.3 christos const char *error; 202 1.1 skrll unsigned long opcode; 203 1.1 skrll struct nlist *nlistp; 204 1.1 skrll expressionS exp; 205 1.1 skrll expressionS exp2; 206 1.1 skrll int pcrel; 207 1.1 skrll bfd_reloc_code_real_type reloc; 208 1.1 skrll }; 209 1.1 skrll 210 1.1 skrll struct sparc_it the_insn, set_insn; 211 1.1 skrll 212 1.1 skrll static void output_insn (const struct sparc_opcode *, struct sparc_it *); 213 1.1 skrll 214 1.1 skrll /* Table of arguments to -A. 216 1.1 skrll The sparc_opcode_arch table in sparc-opc.c is insufficient and incorrect 217 1.1 skrll for this use. That table is for opcodes only. This table is for opcodes 218 1.1 skrll and file formats. */ 219 1.2 joerg 220 1.1 skrll enum sparc_arch_types {v6, v7, v8, leon, sparclet, sparclite, sparc86x, v8plus, 221 1.1 skrll v8plusa, v9, v9a, v9b, v9_64}; 222 1.1 skrll 223 1.3 christos static struct sparc_arch { 224 1.3 christos const char *name; 225 1.1 skrll const char *opcode_arch; 226 1.1 skrll enum sparc_arch_types arch_type; 227 1.1 skrll /* Default word size, as specified during configuration. 228 1.1 skrll A value of zero means can't be used to specify default architecture. */ 229 1.1 skrll int default_arch_size; 230 1.1 skrll /* Allowable arg to -A? */ 231 1.4 christos int user_option_p; 232 1.4 christos /* Extra hardware capabilities allowed. These are added to the 233 1.4 christos hardware capabilities associated with the opcode 234 1.2 joerg architecture. */ 235 1.2 joerg int hwcap_allowed; 236 1.1 skrll int hwcap2_allowed; 237 1.2 joerg } sparc_arch_table[] = { 238 1.2 joerg { "v6", "v6", v6, 0, 1, 0, 0 }, 239 1.4 christos { "v7", "v7", v7, 0, 1, 0, 0 }, 240 1.4 christos { "v8", "v8", v8, 32, 1, 0, 0 }, 241 1.4 christos { "v8a", "v8", v8, 32, 1, 0, 0 }, 242 1.4 christos { "sparc", "v9", v9, 0, 1, HWCAP_V8PLUS, 0 }, 243 1.4 christos { "sparcvis", "v9a", v9, 0, 1, 0, 0 }, 244 1.4 christos { "sparcvis2", "v9b", v9, 0, 1, 0, 0 }, 245 1.4 christos { "sparcfmaf", "v9b", v9, 0, 1, HWCAP_FMAF, 0 }, 246 1.4 christos { "sparcima", "v9b", v9, 0, 1, HWCAP_FMAF|HWCAP_IMA, 0 }, 247 1.4 christos { "sparcvis3", "v9b", v9, 0, 1, HWCAP_FMAF|HWCAP_VIS3|HWCAP_HPC, 0 }, 248 1.4 christos { "sparcvis3r", "v9b", v9, 0, 1, HWCAP_FMAF|HWCAP_VIS3|HWCAP_HPC|HWCAP_FJFMAU, 0 }, 249 1.4 christos 250 1.4 christos { "sparc4", "v9v", v9, 0, 1, 0, 0 }, 251 1.4 christos { "sparc5", "v9m", v9, 0, 1, 0, 0 }, 252 1.4 christos { "sparc6", "m8", v9, 0, 1, 0, 0 }, 253 1.4 christos 254 1.4 christos { "leon", "leon", leon, 32, 1, 0, 0 }, 255 1.4 christos { "sparclet", "sparclet", sparclet, 32, 1, 0, 0 }, 256 1.4 christos { "sparclite", "sparclite", sparclite, 32, 1, 0, 0 }, 257 1.4 christos { "sparc86x", "sparclite", sparc86x, 32, 1, 0, 0 }, 258 1.4 christos 259 1.4 christos { "v8plus", "v9", v9, 0, 1, HWCAP_V8PLUS, 0 }, 260 1.4 christos { "v8plusa", "v9a", v9, 0, 1, HWCAP_V8PLUS, 0 }, 261 1.4 christos { "v8plusb", "v9b", v9, 0, 1, HWCAP_V8PLUS, 0 }, 262 1.4 christos { "v8plusc", "v9c", v9, 0, 1, HWCAP_V8PLUS, 0 }, 263 1.4 christos { "v8plusd", "v9d", v9, 0, 1, HWCAP_V8PLUS, 0 }, 264 1.4 christos { "v8pluse", "v9e", v9, 0, 1, HWCAP_V8PLUS, 0 }, 265 1.4 christos { "v8plusv", "v9v", v9, 0, 1, HWCAP_V8PLUS, 0 }, 266 1.4 christos { "v8plusm", "v9m", v9, 0, 1, HWCAP_V8PLUS, 0 }, 267 1.4 christos { "v8plusm8", "m8", v9, 0, 1, HWCAP_V8PLUS, 0 }, 268 1.4 christos 269 1.4 christos { "v9", "v9", v9, 0, 1, 0, 0 }, 270 1.4 christos { "v9a", "v9a", v9, 0, 1, 0, 0 }, 271 1.4 christos { "v9b", "v9b", v9, 0, 1, 0, 0 }, 272 1.4 christos { "v9c", "v9c", v9, 0, 1, 0, 0 }, 273 1.4 christos { "v9d", "v9d", v9, 0, 1, 0, 0 }, 274 1.4 christos { "v9e", "v9e", v9, 0, 1, 0, 0 }, 275 1.4 christos { "v9v", "v9v", v9, 0, 1, 0, 0 }, 276 1.4 christos { "v9m", "v9m", v9, 0, 1, 0, 0 }, 277 1.2 joerg { "v9m8", "m8", v9, 0, 1, 0, 0 }, 278 1.2 joerg 279 1.1 skrll /* This exists to allow configure.tgt to pass one 280 1.4 christos value to specify both the default machine and default word size. */ 281 1.2 joerg { "v9-64", "v9", v9, 64, 0, 0, 0 }, 282 1.1 skrll { NULL, NULL, v8, 0, 0, 0, 0 } 283 1.1 skrll }; 284 1.1 skrll 285 1.1 skrll /* Variant of default_arch */ 286 1.1 skrll static enum sparc_arch_types default_arch_type; 287 1.1 skrll 288 1.3 christos static struct sparc_arch * 289 1.1 skrll lookup_arch (const char *name) 290 1.1 skrll { 291 1.1 skrll struct sparc_arch *sa; 292 1.1 skrll 293 1.1 skrll for (sa = &sparc_arch_table[0]; sa->name != NULL; sa++) 294 1.1 skrll if (strcmp (sa->name, name) == 0) 295 1.1 skrll break; 296 1.1 skrll if (sa->name == NULL) 297 1.1 skrll return NULL; 298 1.1 skrll return sa; 299 1.1 skrll } 300 1.1 skrll 301 1.1 skrll /* Initialize the default opcode arch and word size from the default 302 1.1 skrll architecture name. */ 303 1.1 skrll 304 1.1 skrll static void 305 1.1 skrll init_default_arch (void) 306 1.1 skrll { 307 1.1 skrll struct sparc_arch *sa = lookup_arch (default_arch); 308 1.1 skrll 309 1.1 skrll if (sa == NULL 310 1.1 skrll || sa->default_arch_size == 0) 311 1.1 skrll as_fatal (_("Invalid default architecture, broken assembler.")); 312 1.1 skrll 313 1.1 skrll max_architecture = sparc_opcode_lookup_arch (sa->opcode_arch); 314 1.1 skrll if (max_architecture == SPARC_OPCODE_ARCH_BAD) 315 1.1 skrll as_fatal (_("Bad opcode table, broken assembler.")); 316 1.1 skrll default_arch_size = sparc_arch_size = sa->default_arch_size; 317 1.1 skrll default_init_p = 1; 318 1.1 skrll default_arch_type = sa->arch_type; 319 1.1 skrll } 320 1.5 christos 321 1.5 christos /* Called by TARGET_MACH. */ 322 1.5 christos 323 1.5 christos unsigned long 324 1.5 christos sparc_mach (void) 325 1.5 christos { 326 1.5 christos /* We don't get a chance to initialize anything before we're called, 327 1.5 christos so handle that now. */ 328 1.5 christos if (! default_init_p) 329 1.5 christos init_default_arch (); 330 1.5 christos 331 1.5 christos return sparc_arch_size == 64 ? bfd_mach_sparc_v9 : bfd_mach_sparc; 332 1.5 christos } 333 1.1 skrll 334 1.1 skrll /* Called by TARGET_FORMAT. */ 335 1.1 skrll 336 1.1 skrll const char * 337 1.1 skrll sparc_target_format (void) 338 1.1 skrll { 339 1.1 skrll /* We don't get a chance to initialize anything before we're called, 340 1.1 skrll so handle that now. */ 341 1.1 skrll if (! default_init_p) 342 1.1 skrll init_default_arch (); 343 1.1 skrll 344 1.1 skrll #ifdef TE_VXWORKS 345 1.1 skrll return "elf32-sparc-vxworks"; 346 1.1 skrll #endif 347 1.1 skrll 348 1.1 skrll return sparc_arch_size == 64 ? ELF64_TARGET_FORMAT : ELF_TARGET_FORMAT; 349 1.1 skrll } 350 1.1 skrll 351 1.1 skrll /* md_parse_option 353 1.1 skrll * Invocation line includes a switch not recognized by the base assembler. 354 1.1 skrll * See if it's a processor-specific option. These are: 355 1.1 skrll * 356 1.1 skrll * -bump 357 1.2 joerg * Warn on architecture bumps. See also -A. 358 1.1 skrll * 359 1.1 skrll * -Av6, -Av7, -Av8, -Aleon, -Asparclite, -Asparclet 360 1.1 skrll * Standard 32 bit architectures. 361 1.1 skrll * -Av9, -Av9a, -Av9b 362 1.1 skrll * Sparc64 in either a 32 or 64 bit world (-32/-64 says which). 363 1.1 skrll * This used to only mean 64 bits, but properly specifying it 364 1.1 skrll * complicated gcc's ASM_SPECs, so now opcode selection is 365 1.1 skrll * specified orthogonally to word size (except when specifying 366 1.1 skrll * the default, but that is an internal implementation detail). 367 1.1 skrll * -Av8plus, -Av8plusa, -Av8plusb 368 1.1 skrll * Same as -Av9{,a,b}. 369 1.1 skrll * -xarch=v8plus, -xarch=v8plusa, -xarch=v8plusb 370 1.1 skrll * Same as -Av8plus{,a,b} -32, for compatibility with Sun's 371 1.1 skrll * assembler. 372 1.1 skrll * -xarch=v9, -xarch=v9a, -xarch=v9b 373 1.1 skrll * Same as -Av9{,a,b} -64, for compatibility with Sun's 374 1.1 skrll * assembler. 375 1.1 skrll * 376 1.1 skrll * Select the architecture and possibly the file format. 377 1.1 skrll * Instructions or features not supported by the selected 378 1.1 skrll * architecture cause fatal errors. 379 1.1 skrll * 380 1.1 skrll * The default is to start at v6, and bump the architecture up 381 1.1 skrll * whenever an instruction is seen at a higher level. In 32 bit 382 1.1 skrll * environments, v9 is not bumped up to, the user must pass 383 1.1 skrll * -Av8plus{,a,b}. 384 1.1 skrll * 385 1.1 skrll * If -bump is specified, a warning is printing when bumping to 386 1.1 skrll * higher levels. 387 1.1 skrll * 388 1.1 skrll * If an architecture is specified, all instructions must match 389 1.1 skrll * that architecture. Any higher level instructions are flagged 390 1.1 skrll * as errors. Note that in the 32 bit environment specifying 391 1.1 skrll * -Av8plus does not automatically create a v8plus object file, a 392 1.1 skrll * v9 insn must be seen. 393 1.1 skrll * 394 1.1 skrll * If both an architecture and -bump are specified, the 395 1.1 skrll * architecture starts at the specified level, but bumps are 396 1.1 skrll * warnings. Note that we can't set `current_architecture' to 397 1.1 skrll * the requested level in this case: in the 32 bit environment, 398 1.1 skrll * we still must avoid creating v8plus object files unless v9 399 1.1 skrll * insns are seen. 400 1.1 skrll * 401 1.1 skrll * Note: 402 1.1 skrll * Bumping between incompatible architectures is always an 403 1.1 skrll * error. For example, from sparclite to v9. 404 1.1 skrll */ 405 1.1 skrll 406 1.1 skrll const char *md_shortopts = "A:K:VQ:sq"; 407 1.1 skrll struct option md_longopts[] = { 408 1.1 skrll #define OPTION_BUMP (OPTION_MD_BASE) 409 1.1 skrll {"bump", no_argument, NULL, OPTION_BUMP}, 410 1.1 skrll #define OPTION_SPARC (OPTION_MD_BASE + 1) 411 1.1 skrll {"sparc", no_argument, NULL, OPTION_SPARC}, 412 1.1 skrll #define OPTION_XARCH (OPTION_MD_BASE + 2) 413 1.1 skrll {"xarch", required_argument, NULL, OPTION_XARCH}, 414 1.1 skrll #define OPTION_32 (OPTION_MD_BASE + 3) 415 1.1 skrll {"32", no_argument, NULL, OPTION_32}, 416 1.1 skrll #define OPTION_64 (OPTION_MD_BASE + 4) 417 1.1 skrll {"64", no_argument, NULL, OPTION_64}, 418 1.1 skrll #define OPTION_TSO (OPTION_MD_BASE + 5) 419 1.1 skrll {"TSO", no_argument, NULL, OPTION_TSO}, 420 1.1 skrll #define OPTION_PSO (OPTION_MD_BASE + 6) 421 1.1 skrll {"PSO", no_argument, NULL, OPTION_PSO}, 422 1.1 skrll #define OPTION_RMO (OPTION_MD_BASE + 7) 423 1.1 skrll {"RMO", no_argument, NULL, OPTION_RMO}, 424 1.1 skrll #ifdef SPARC_BIENDIAN 425 1.1 skrll #define OPTION_LITTLE_ENDIAN (OPTION_MD_BASE + 8) 426 1.1 skrll {"EL", no_argument, NULL, OPTION_LITTLE_ENDIAN}, 427 1.1 skrll #define OPTION_BIG_ENDIAN (OPTION_MD_BASE + 9) 428 1.1 skrll {"EB", no_argument, NULL, OPTION_BIG_ENDIAN}, 429 1.1 skrll #endif 430 1.1 skrll #define OPTION_ENFORCE_ALIGNED_DATA (OPTION_MD_BASE + 10) 431 1.1 skrll {"enforce-aligned-data", no_argument, NULL, OPTION_ENFORCE_ALIGNED_DATA}, 432 1.1 skrll #define OPTION_LITTLE_ENDIAN_DATA (OPTION_MD_BASE + 11) 433 1.1 skrll {"little-endian-data", no_argument, NULL, OPTION_LITTLE_ENDIAN_DATA}, 434 1.1 skrll #define OPTION_NO_UNDECLARED_REGS (OPTION_MD_BASE + 12) 435 1.1 skrll {"no-undeclared-regs", no_argument, NULL, OPTION_NO_UNDECLARED_REGS}, 436 1.1 skrll #define OPTION_UNDECLARED_REGS (OPTION_MD_BASE + 13) 437 1.1 skrll {"undeclared-regs", no_argument, NULL, OPTION_UNDECLARED_REGS}, 438 1.1 skrll #define OPTION_RELAX (OPTION_MD_BASE + 14) 439 1.1 skrll {"relax", no_argument, NULL, OPTION_RELAX}, 440 1.4 christos #define OPTION_NO_RELAX (OPTION_MD_BASE + 15) 441 1.4 christos {"no-relax", no_argument, NULL, OPTION_NO_RELAX}, 442 1.1 skrll #define OPTION_DCTI_COUPLES_DETECT (OPTION_MD_BASE + 16) 443 1.1 skrll {"dcti-couples-detect", no_argument, NULL, OPTION_DCTI_COUPLES_DETECT}, 444 1.1 skrll {NULL, no_argument, NULL, 0} 445 1.1 skrll }; 446 1.1 skrll 447 1.1 skrll size_t md_longopts_size = sizeof (md_longopts); 448 1.3 christos 449 1.1 skrll int 450 1.1 skrll md_parse_option (int c, const char *arg) 451 1.1 skrll { 452 1.1 skrll /* We don't get a chance to initialize anything before we're called, 453 1.1 skrll so handle that now. */ 454 1.1 skrll if (! default_init_p) 455 1.1 skrll init_default_arch (); 456 1.1 skrll 457 1.1 skrll switch (c) 458 1.1 skrll { 459 1.1 skrll case OPTION_BUMP: 460 1.1 skrll warn_on_bump = 1; 461 1.1 skrll warn_after_architecture = SPARC_OPCODE_ARCH_V6; 462 1.1 skrll break; 463 1.7 christos 464 1.2 joerg case OPTION_XARCH: 465 1.1 skrll if (startswith (arg, "v9")) 466 1.2 joerg md_parse_option (OPTION_64, NULL); 467 1.7 christos else 468 1.7 christos { 469 1.7 christos if (startswith (arg, "v8") 470 1.2 joerg || startswith (arg, "v7") 471 1.2 joerg || startswith (arg, "v6") 472 1.2 joerg || !strcmp (arg, "sparclet") 473 1.2 joerg || !strcmp (arg, "sparclite") 474 1.2 joerg || !strcmp (arg, "sparc86x")) 475 1.1 skrll md_parse_option (OPTION_32, NULL); 476 1.1 skrll } 477 1.1 skrll /* Fall through. */ 478 1.1 skrll 479 1.1 skrll case 'A': 480 1.1 skrll { 481 1.1 skrll struct sparc_arch *sa; 482 1.1 skrll enum sparc_opcode_arch_val opcode_arch; 483 1.1 skrll 484 1.1 skrll sa = lookup_arch (arg); 485 1.1 skrll if (sa == NULL 486 1.1 skrll || ! sa->user_option_p) 487 1.1 skrll { 488 1.1 skrll if (c == OPTION_XARCH) 489 1.1 skrll as_bad (_("invalid architecture -xarch=%s"), arg); 490 1.1 skrll else 491 1.1 skrll as_bad (_("invalid architecture -A%s"), arg); 492 1.1 skrll return 0; 493 1.1 skrll } 494 1.1 skrll 495 1.1 skrll opcode_arch = sparc_opcode_lookup_arch (sa->opcode_arch); 496 1.1 skrll if (opcode_arch == SPARC_OPCODE_ARCH_BAD) 497 1.2 joerg as_fatal (_("Bad opcode table, broken assembler.")); 498 1.2 joerg 499 1.2 joerg if (!architecture_requested 500 1.4 christos || opcode_arch > max_architecture) 501 1.7 christos max_architecture = opcode_arch; 502 1.7 christos 503 1.7 christos /* The allowed hardware capabilities are the implied by the 504 1.7 christos opcodes arch plus any extra capabilities defined in the GAS 505 1.7 christos arch. */ 506 1.7 christos hwcap_allowed 507 1.7 christos = (hwcap_allowed 508 1.7 christos | ((uint64_t) sparc_opcode_archs[opcode_arch].hwcaps2 << 32) 509 1.7 christos | ((uint64_t) sa->hwcap2_allowed << 32) 510 1.1 skrll | sparc_opcode_archs[opcode_arch].hwcaps 511 1.1 skrll | sa->hwcap_allowed); 512 1.1 skrll architecture_requested = 1; 513 1.1 skrll } 514 1.1 skrll break; 515 1.1 skrll 516 1.1 skrll case OPTION_SPARC: 517 1.1 skrll /* Ignore -sparc, used by SunOS make default .s.o rule. */ 518 1.1 skrll break; 519 1.1 skrll 520 1.1 skrll case OPTION_ENFORCE_ALIGNED_DATA: 521 1.1 skrll enforce_aligned_data = 1; 522 1.1 skrll break; 523 1.1 skrll 524 1.1 skrll #ifdef SPARC_BIENDIAN 525 1.1 skrll case OPTION_LITTLE_ENDIAN: 526 1.1 skrll target_big_endian = 0; 527 1.1 skrll if (default_arch_type != sparclet) 528 1.1 skrll as_fatal ("This target does not support -EL"); 529 1.1 skrll break; 530 1.1 skrll case OPTION_LITTLE_ENDIAN_DATA: 531 1.1 skrll target_little_endian_data = 1; 532 1.1 skrll target_big_endian = 0; 533 1.1 skrll if (default_arch_type != sparc86x 534 1.1 skrll && default_arch_type != v9) 535 1.1 skrll as_fatal ("This target does not support --little-endian-data"); 536 1.1 skrll break; 537 1.1 skrll case OPTION_BIG_ENDIAN: 538 1.1 skrll target_big_endian = 1; 539 1.1 skrll break; 540 1.1 skrll #endif 541 1.1 skrll 542 1.1 skrll case OPTION_32: 543 1.1 skrll case OPTION_64: 544 1.1 skrll { 545 1.1 skrll const char **list, **l; 546 1.1 skrll 547 1.1 skrll sparc_arch_size = c == OPTION_32 ? 32 : 64; 548 1.1 skrll list = bfd_target_list (); 549 1.1 skrll for (l = list; *l != NULL; l++) 550 1.1 skrll { 551 1.7 christos if (sparc_arch_size == 32) 552 1.1 skrll { 553 1.1 skrll if (startswith (*l, "elf32-sparc")) 554 1.1 skrll break; 555 1.1 skrll } 556 1.7 christos else 557 1.1 skrll { 558 1.1 skrll if (startswith (*l, "elf64-sparc")) 559 1.1 skrll break; 560 1.1 skrll } 561 1.1 skrll } 562 1.1 skrll if (*l == NULL) 563 1.1 skrll as_fatal (_("No compiled in support for %d bit object file format"), 564 1.2 joerg sparc_arch_size); 565 1.2 joerg free (list); 566 1.2 joerg 567 1.2 joerg if (sparc_arch_size == 64 568 1.1 skrll && max_architecture < SPARC_OPCODE_ARCH_V9) 569 1.1 skrll max_architecture = SPARC_OPCODE_ARCH_V9; 570 1.1 skrll } 571 1.1 skrll break; 572 1.1 skrll 573 1.1 skrll case OPTION_TSO: 574 1.1 skrll sparc_memory_model = MM_TSO; 575 1.1 skrll break; 576 1.1 skrll 577 1.1 skrll case OPTION_PSO: 578 1.1 skrll sparc_memory_model = MM_PSO; 579 1.1 skrll break; 580 1.1 skrll 581 1.1 skrll case OPTION_RMO: 582 1.1 skrll sparc_memory_model = MM_RMO; 583 1.1 skrll break; 584 1.1 skrll 585 1.1 skrll case 'V': 586 1.1 skrll print_version_id (); 587 1.1 skrll break; 588 1.1 skrll 589 1.1 skrll case 'Q': 590 1.1 skrll /* Qy - do emit .comment 591 1.1 skrll Qn - do not emit .comment. */ 592 1.1 skrll break; 593 1.1 skrll 594 1.1 skrll case 's': 595 1.1 skrll /* Use .stab instead of .stab.excl. */ 596 1.1 skrll break; 597 1.1 skrll 598 1.1 skrll case 'q': 599 1.1 skrll /* quick -- Native assembler does fewer checks. */ 600 1.1 skrll break; 601 1.1 skrll 602 1.1 skrll case 'K': 603 1.1 skrll if (strcmp (arg, "PIC") != 0) 604 1.1 skrll as_warn (_("Unrecognized option following -K")); 605 1.1 skrll else 606 1.1 skrll sparc_pic_code = 1; 607 1.1 skrll break; 608 1.1 skrll 609 1.1 skrll case OPTION_NO_UNDECLARED_REGS: 610 1.1 skrll no_undeclared_regs = 1; 611 1.1 skrll break; 612 1.1 skrll 613 1.1 skrll case OPTION_UNDECLARED_REGS: 614 1.1 skrll no_undeclared_regs = 0; 615 1.1 skrll break; 616 1.1 skrll 617 1.1 skrll case OPTION_RELAX: 618 1.1 skrll sparc_relax = 1; 619 1.1 skrll break; 620 1.1 skrll 621 1.1 skrll case OPTION_NO_RELAX: 622 1.1 skrll sparc_relax = 0; 623 1.4 christos break; 624 1.4 christos 625 1.4 christos case OPTION_DCTI_COUPLES_DETECT: 626 1.4 christos dcti_couples_detect = 1; 627 1.1 skrll break; 628 1.1 skrll 629 1.1 skrll default: 630 1.1 skrll return 0; 631 1.1 skrll } 632 1.1 skrll 633 1.1 skrll return 1; 634 1.1 skrll } 635 1.1 skrll 636 1.1 skrll void 637 1.1 skrll md_show_usage (FILE *stream) 638 1.1 skrll { 639 1.1 skrll const struct sparc_arch *arch; 640 1.1 skrll int column; 641 1.1 skrll 642 1.1 skrll /* We don't get a chance to initialize anything before we're called, 643 1.1 skrll so handle that now. */ 644 1.1 skrll if (! default_init_p) 645 1.1 skrll init_default_arch (); 646 1.1 skrll 647 1.1 skrll fprintf (stream, _("SPARC options:\n")); 648 1.1 skrll column = 0; 649 1.1 skrll for (arch = &sparc_arch_table[0]; arch->name; arch++) 650 1.1 skrll { 651 1.1 skrll if (!arch->user_option_p) 652 1.1 skrll continue; 653 1.1 skrll if (arch != &sparc_arch_table[0]) 654 1.1 skrll fprintf (stream, " | "); 655 1.1 skrll if (column + strlen (arch->name) > 70) 656 1.1 skrll { 657 1.1 skrll column = 0; 658 1.1 skrll fputc ('\n', stream); 659 1.1 skrll } 660 1.1 skrll column += 5 + 2 + strlen (arch->name); 661 1.1 skrll fprintf (stream, "-A%s", arch->name); 662 1.1 skrll } 663 1.1 skrll for (arch = &sparc_arch_table[0]; arch->name; arch++) 664 1.1 skrll { 665 1.1 skrll if (!arch->user_option_p) 666 1.1 skrll continue; 667 1.1 skrll fprintf (stream, " | "); 668 1.1 skrll if (column + strlen (arch->name) > 65) 669 1.1 skrll { 670 1.1 skrll column = 0; 671 1.1 skrll fputc ('\n', stream); 672 1.1 skrll } 673 1.1 skrll column += 5 + 7 + strlen (arch->name); 674 1.1 skrll fprintf (stream, "-xarch=%s", arch->name); 675 1.1 skrll } 676 1.1 skrll fprintf (stream, _("\n\ 677 1.1 skrll specify variant of SPARC architecture\n\ 678 1.1 skrll -bump warn when assembler switches architectures\n\ 679 1.1 skrll -sparc ignored\n\ 680 1.1 skrll --enforce-aligned-data force .long, etc., to be aligned correctly\n\ 681 1.1 skrll -relax relax jumps and branches (default)\n\ 682 1.1 skrll -no-relax avoid changing any jumps and branches\n")); 683 1.1 skrll fprintf (stream, _("\ 684 1.1 skrll -32 create 32 bit object file\n\ 685 1.1 skrll -64 create 64 bit object file\n")); 686 1.1 skrll fprintf (stream, _("\ 687 1.1 skrll [default is %d]\n"), default_arch_size); 688 1.1 skrll fprintf (stream, _("\ 689 1.1 skrll -TSO use Total Store Ordering\n\ 690 1.1 skrll -PSO use Partial Store Ordering\n\ 691 1.1 skrll -RMO use Relaxed Memory Ordering\n")); 692 1.1 skrll fprintf (stream, _("\ 693 1.1 skrll [default is %s]\n"), (default_arch_size == 64) ? "RMO" : "TSO"); 694 1.1 skrll fprintf (stream, _("\ 695 1.1 skrll -KPIC generate PIC\n\ 696 1.1 skrll -V print assembler version number\n\ 697 1.1 skrll -undeclared-regs ignore application global register usage without\n\ 698 1.1 skrll appropriate .register directive (default)\n\ 699 1.4 christos -no-undeclared-regs force error on application global register usage\n\ 700 1.1 skrll without appropriate .register directive\n\ 701 1.1 skrll --dcti-couples-detect warn when an unpredictable DCTI couple is found\n\ 702 1.1 skrll -q ignored\n\ 703 1.1 skrll -Qy, -Qn ignored\n\ 704 1.1 skrll -s ignored\n")); 705 1.1 skrll #ifdef SPARC_BIENDIAN 706 1.1 skrll fprintf (stream, _("\ 707 1.1 skrll -EL generate code for a little endian machine\n\ 708 1.1 skrll -EB generate code for a big endian machine\n\ 709 1.1 skrll --little-endian-data generate code for a machine having big endian\n\ 710 1.1 skrll instructions and little endian data.\n")); 711 1.1 skrll #endif 712 1.1 skrll } 713 1.3 christos 714 1.1 skrll /* Native operand size opcode translation. */ 716 1.3 christos static struct 717 1.3 christos { 718 1.1 skrll const char *name; 719 1.1 skrll const char *name32; 720 1.1 skrll const char *name64; 721 1.1 skrll } native_op_table[] = 722 1.1 skrll { 723 1.1 skrll {"ldn", "ld", "ldx"}, 724 1.1 skrll {"ldna", "lda", "ldxa"}, 725 1.1 skrll {"stn", "st", "stx"}, 726 1.1 skrll {"stna", "sta", "stxa"}, 727 1.1 skrll {"slln", "sll", "sllx"}, 728 1.1 skrll {"srln", "srl", "srlx"}, 729 1.1 skrll {"sran", "sra", "srax"}, 730 1.1 skrll {"casn", "cas", "casx"}, 731 1.1 skrll {"casna", "casa", "casxa"}, 732 1.1 skrll {"clrn", "clr", "clrx"}, 733 1.1 skrll {NULL, NULL, NULL}, 734 1.1 skrll }; 735 1.1 skrll 736 1.1 skrll /* sparc64 privileged and hyperprivileged registers. */ 738 1.1 skrll 739 1.1 skrll struct priv_reg_entry 740 1.1 skrll { 741 1.1 skrll const char *name; 742 1.1 skrll int regnum; 743 1.1 skrll }; 744 1.1 skrll 745 1.1 skrll struct priv_reg_entry priv_reg_table[] = 746 1.1 skrll { 747 1.1 skrll {"tpc", 0}, 748 1.1 skrll {"tnpc", 1}, 749 1.1 skrll {"tstate", 2}, 750 1.1 skrll {"tt", 3}, 751 1.1 skrll {"tick", 4}, 752 1.1 skrll {"tba", 5}, 753 1.1 skrll {"pstate", 6}, 754 1.1 skrll {"tl", 7}, 755 1.1 skrll {"pil", 8}, 756 1.1 skrll {"cwp", 9}, 757 1.1 skrll {"cansave", 10}, 758 1.1 skrll {"canrestore", 11}, 759 1.1 skrll {"cleanwin", 12}, 760 1.2 joerg {"otherwin", 13}, 761 1.1 skrll {"wstate", 14}, 762 1.3 christos {"fq", 15}, 763 1.1 skrll {"gl", 16}, 764 1.1 skrll {"pmcdper", 23}, 765 1.1 skrll {"ver", 31}, 766 1.1 skrll {NULL, -1}, /* End marker. */ 767 1.1 skrll }; 768 1.1 skrll 769 1.1 skrll struct priv_reg_entry hpriv_reg_table[] = 770 1.1 skrll { 771 1.1 skrll {"hpstate", 0}, 772 1.3 christos {"htstate", 1}, 773 1.3 christos {"hintp", 3}, 774 1.3 christos {"htba", 5}, 775 1.2 joerg {"hver", 6}, 776 1.2 joerg {"hmcdper", 23}, 777 1.1 skrll {"hmcddfr", 24}, 778 1.3 christos {"hva_mask_nz", 27}, 779 1.1 skrll {"hstick_offset", 28}, 780 1.1 skrll {"hstick_enable", 29}, 781 1.3 christos {"hstick_cmpr", 31}, 782 1.1 skrll {NULL, -1}, /* End marker. */ 783 1.1 skrll }; 784 1.1 skrll 785 1.1 skrll /* v9a or later specific ancillary state registers. */ 786 1.1 skrll 787 1.1 skrll struct priv_reg_entry v9a_asr_table[] = 788 1.1 skrll { 789 1.1 skrll {"tick_cmpr", 23}, 790 1.1 skrll {"sys_tick_cmpr", 25}, 791 1.1 skrll {"sys_tick", 24}, 792 1.1 skrll {"stick_cmpr", 25}, 793 1.1 skrll {"stick", 24}, 794 1.2 joerg {"softint_clear", 21}, 795 1.1 skrll {"softint_set", 20}, 796 1.1 skrll {"softint", 22}, 797 1.2 joerg {"set_softint", 20}, 798 1.1 skrll {"pause", 27}, 799 1.1 skrll {"pic", 17}, 800 1.2 joerg {"pcr", 16}, 801 1.1 skrll {"mwait", 28}, 802 1.3 christos {"gsr", 19}, 803 1.1 skrll {"dcr", 18}, 804 1.1 skrll {"cfr", 26}, 805 1.1 skrll {"clear_softint", 21}, 806 1.1 skrll {NULL, -1}, /* End marker. */ 807 1.1 skrll }; 808 1.1 skrll 809 1.1 skrll static int 810 1.1 skrll cmp_reg_entry (const void *parg, const void *qarg) 811 1.3 christos { 812 1.3 christos const struct priv_reg_entry *p = (const struct priv_reg_entry *) parg; 813 1.3 christos const struct priv_reg_entry *q = (const struct priv_reg_entry *) qarg; 814 1.3 christos 815 1.3 christos if (p->name == q->name) 816 1.3 christos return 0; 817 1.3 christos else if (p->name == NULL) 818 1.3 christos return 1; 819 1.3 christos else if (q->name == NULL) 820 1.3 christos return -1; 821 1.3 christos else 822 1.3 christos return strcmp (q->name, p->name); 823 1.3 christos } 824 1.3 christos 825 1.3 christos /* sparc %-pseudo-operations. */ 827 1.3 christos 828 1.3 christos 829 1.3 christos #define F_POP_V9 0x1 /* The pseudo-op is for v9 only. */ 830 1.3 christos #define F_POP_PCREL 0x2 /* The pseudo-op can be used in pc-relative 831 1.3 christos contexts. */ 832 1.3 christos #define F_POP_TLS_CALL 0x4 /* The pseudo-op marks a tls call. */ 833 1.3 christos #define F_POP_POSTFIX 0x8 /* The pseudo-op should appear after the 834 1.3 christos last operand of an 835 1.3 christos instruction. (Generally they can appear 836 1.3 christos anywhere an immediate operand is 837 1.3 christos expected. */ 838 1.4 christos struct pop_entry 839 1.3 christos { 840 1.3 christos /* The name as it appears in assembler. */ 841 1.3 christos const char *name; 842 1.3 christos /* The reloc this pseudo-op translates to. */ 843 1.3 christos bfd_reloc_code_real_type reloc; 844 1.3 christos /* Flags. See F_POP_* above. */ 845 1.3 christos int flags; 846 1.3 christos }; 847 1.3 christos 848 1.3 christos struct pop_entry pop_table[] = 849 1.3 christos { 850 1.3 christos { "hix", BFD_RELOC_SPARC_HIX22, F_POP_V9 }, 851 1.3 christos { "lox", BFD_RELOC_SPARC_LOX10, F_POP_V9 }, 852 1.3 christos { "hi", BFD_RELOC_HI22, F_POP_PCREL }, 853 1.3 christos { "lo", BFD_RELOC_LO10, F_POP_PCREL }, 854 1.3 christos { "pc22", BFD_RELOC_SPARC_PC22, F_POP_PCREL }, 855 1.3 christos { "pc10", BFD_RELOC_SPARC_PC10, F_POP_PCREL }, 856 1.3 christos { "hh", BFD_RELOC_SPARC_HH22, F_POP_V9|F_POP_PCREL }, 857 1.3 christos { "hm", BFD_RELOC_SPARC_HM10, F_POP_V9|F_POP_PCREL }, 858 1.3 christos { "lm", BFD_RELOC_SPARC_LM22, F_POP_V9|F_POP_PCREL }, 859 1.3 christos { "h34", BFD_RELOC_SPARC_H34, F_POP_V9 }, 860 1.3 christos { "l34", BFD_RELOC_SPARC_L44, F_POP_V9 }, 861 1.3 christos { "h44", BFD_RELOC_SPARC_H44, F_POP_V9 }, 862 1.3 christos { "m44", BFD_RELOC_SPARC_M44, F_POP_V9 }, 863 1.3 christos { "l44", BFD_RELOC_SPARC_L44, F_POP_V9 }, 864 1.3 christos { "uhi", BFD_RELOC_SPARC_HH22, F_POP_V9 }, 865 1.3 christos { "ulo", BFD_RELOC_SPARC_HM10, F_POP_V9 }, 866 1.3 christos { "tgd_hi22", BFD_RELOC_SPARC_TLS_GD_HI22, 0 }, 867 1.3 christos { "tgd_lo10", BFD_RELOC_SPARC_TLS_GD_LO10, 0 }, 868 1.3 christos { "tldm_hi22", BFD_RELOC_SPARC_TLS_LDM_HI22, 0 }, 869 1.3 christos { "tldm_lo10", BFD_RELOC_SPARC_TLS_LDM_LO10, 0 }, 870 1.3 christos { "tldo_hix22", BFD_RELOC_SPARC_TLS_LDO_HIX22, 0 }, 871 1.3 christos { "tldo_lox10", BFD_RELOC_SPARC_TLS_LDO_LOX10, 0 }, 872 1.3 christos { "tie_hi22", BFD_RELOC_SPARC_TLS_IE_HI22, 0 }, 873 1.3 christos { "tie_lo10", BFD_RELOC_SPARC_TLS_IE_LO10, 0 }, 874 1.3 christos { "tle_hix22", BFD_RELOC_SPARC_TLS_LE_HIX22, 0 }, 875 1.3 christos { "tle_lox10", BFD_RELOC_SPARC_TLS_LE_LOX10, 0 }, 876 1.3 christos { "gdop_hix22", BFD_RELOC_SPARC_GOTDATA_OP_HIX22, 0 }, 877 1.3 christos { "gdop_lox10", BFD_RELOC_SPARC_GOTDATA_OP_LOX10, 0 }, 878 1.3 christos { "tgd_add", BFD_RELOC_SPARC_TLS_GD_ADD, F_POP_POSTFIX }, 879 1.3 christos { "tgd_call", BFD_RELOC_SPARC_TLS_GD_CALL, F_POP_POSTFIX|F_POP_TLS_CALL }, 880 1.3 christos { "tldm_add", BFD_RELOC_SPARC_TLS_LDM_ADD, F_POP_POSTFIX }, 881 1.4 christos { "tldm_call", BFD_RELOC_SPARC_TLS_LDM_CALL, F_POP_POSTFIX|F_POP_TLS_CALL }, 882 1.3 christos { "tldo_add", BFD_RELOC_SPARC_TLS_LDO_ADD, F_POP_POSTFIX }, 883 1.3 christos { "tie_ldx", BFD_RELOC_SPARC_TLS_IE_LDX, F_POP_POSTFIX }, 884 1.3 christos { "tie_ld", BFD_RELOC_SPARC_TLS_IE_LD, F_POP_POSTFIX }, 885 1.3 christos { "tie_add", BFD_RELOC_SPARC_TLS_IE_ADD, F_POP_POSTFIX }, 886 1.3 christos { "gdop", BFD_RELOC_SPARC_GOTDATA_OP, F_POP_POSTFIX } 887 1.3 christos }; 888 1.3 christos 889 1.3 christos /* Table of %-names that can appear in a sparc assembly program. This 891 1.3 christos table is initialized in md_begin and contains entries for each 892 1.3 christos privileged/hyperprivileged/alternate register and %-pseudo-op. */ 893 1.3 christos 894 1.3 christos enum perc_entry_type 895 1.3 christos { 896 1.3 christos perc_entry_none = 0, 897 1.3 christos perc_entry_reg, 898 1.3 christos perc_entry_post_pop, 899 1.3 christos perc_entry_imm_pop 900 1.3 christos }; 901 1.3 christos 902 1.3 christos struct perc_entry 903 1.3 christos { 904 1.3 christos /* Entry type. */ 905 1.3 christos enum perc_entry_type type; 906 1.3 christos /* Name of the %-entity. */ 907 1.3 christos const char *name; 908 1.3 christos /* strlen (name). */ 909 1.3 christos int len; 910 1.3 christos /* Value. Either a pop or a reg depending on type.*/ 911 1.3 christos union 912 1.3 christos { 913 1.3 christos struct pop_entry *pop; 914 1.3 christos struct priv_reg_entry *reg; 915 1.3 christos }; 916 1.4 christos }; 917 1.3 christos 918 1.3 christos #define NUM_PERC_ENTRIES \ 919 1.3 christos (((sizeof (priv_reg_table) / sizeof (priv_reg_table[0])) - 1) \ 920 1.3 christos + ((sizeof (hpriv_reg_table) / sizeof (hpriv_reg_table[0])) - 1) \ 921 1.3 christos + ((sizeof (v9a_asr_table) / sizeof (v9a_asr_table[0])) - 1) \ 922 1.3 christos + ARRAY_SIZE (pop_table) \ 923 1.3 christos + 1) 924 1.3 christos 925 1.3 christos struct perc_entry perc_table[NUM_PERC_ENTRIES]; 926 1.3 christos 927 1.3 christos static int 928 1.3 christos cmp_perc_entry (const void *parg, const void *qarg) 929 1.3 christos { 930 1.3 christos const struct perc_entry *p = (const struct perc_entry *) parg; 931 1.3 christos const struct perc_entry *q = (const struct perc_entry *) qarg; 932 1.3 christos 933 1.3 christos if (p->name == q->name) 934 1.3 christos return 0; 935 1.1 skrll else if (p->name == NULL) 936 1.1 skrll return 1; 937 1.1 skrll else if (q->name == NULL) 938 1.1 skrll return -1; 939 1.1 skrll else 940 1.1 skrll return strcmp (q->name, p->name); 941 1.1 skrll } 942 1.1 skrll 943 1.1 skrll /* This function is called once, at assembler startup time. It should 945 1.2 joerg set up all the tables, etc. that the MD part of the assembler will 946 1.1 skrll need. */ 947 1.1 skrll 948 1.1 skrll void 949 1.1 skrll md_begin (void) 950 1.1 skrll { 951 1.1 skrll int lose = 0; 952 1.1 skrll unsigned int i = 0; 953 1.1 skrll 954 1.7 christos /* We don't get a chance to initialize anything before md_parse_option 955 1.1 skrll is called, and it may not be called, so handle default initialization 956 1.1 skrll now if not already done. */ 957 1.1 skrll if (! default_init_p) 958 1.1 skrll init_default_arch (); 959 1.7 christos 960 1.1 skrll sparc_cie_data_alignment = sparc_arch_size == 64 ? -8 : -4; 961 1.7 christos op_hash = str_htab_create (); 962 1.1 skrll 963 1.1 skrll while (i < (unsigned int) sparc_num_opcodes) 964 1.1 skrll { 965 1.1 skrll const char *name = sparc_opcodes[i].name; 966 1.1 skrll if (str_hash_insert (op_hash, name, &sparc_opcodes[i], 0) != NULL) 967 1.1 skrll { 968 1.1 skrll as_bad (_("duplicate %s"), name); 969 1.1 skrll lose = 1; 970 1.1 skrll } 971 1.1 skrll do 972 1.1 skrll { 973 1.1 skrll if (sparc_opcodes[i].match & sparc_opcodes[i].lose) 974 1.1 skrll { 975 1.1 skrll as_bad (_("Internal error: losing opcode: `%s' \"%s\"\n"), 976 1.1 skrll sparc_opcodes[i].name, sparc_opcodes[i].args); 977 1.1 skrll lose = 1; 978 1.1 skrll } 979 1.1 skrll ++i; 980 1.1 skrll } 981 1.3 christos while (i < (unsigned int) sparc_num_opcodes 982 1.1 skrll && !strcmp (sparc_opcodes[i].name, name)); 983 1.1 skrll } 984 1.7 christos 985 1.1 skrll for (i = 0; native_op_table[i].name; i++) 986 1.1 skrll { 987 1.1 skrll const struct sparc_opcode *insn; 988 1.1 skrll const char *name = ((sparc_arch_size == 32) 989 1.1 skrll ? native_op_table[i].name32 990 1.1 skrll : native_op_table[i].name64); 991 1.7 christos insn = (struct sparc_opcode *) str_hash_find (op_hash, name); 992 1.1 skrll if (insn == NULL) 993 1.7 christos { 994 1.7 christos as_bad (_("Internal error: can't find opcode `%s' for `%s'\n"), 995 1.1 skrll name, native_op_table[i].name); 996 1.1 skrll lose = 1; 997 1.1 skrll } 998 1.1 skrll else if (str_hash_insert (op_hash, native_op_table[i].name, insn, 0)) 999 1.1 skrll { 1000 1.1 skrll as_bad (_("duplicate %s"), native_op_table[i].name); 1001 1.1 skrll lose = 1; 1002 1.1 skrll } 1003 1.3 christos } 1004 1.3 christos 1005 1.3 christos if (lose) 1006 1.3 christos as_fatal (_("Broken assembler. No assembly attempted.")); 1007 1.3 christos 1008 1.1 skrll qsort (priv_reg_table, sizeof (priv_reg_table) / sizeof (priv_reg_table[0]), 1009 1.1 skrll sizeof (priv_reg_table[0]), cmp_reg_entry); 1010 1.1 skrll qsort (hpriv_reg_table, sizeof (hpriv_reg_table) / sizeof (hpriv_reg_table[0]), 1011 1.1 skrll sizeof (hpriv_reg_table[0]), cmp_reg_entry); 1012 1.1 skrll qsort (v9a_asr_table, sizeof (v9a_asr_table) / sizeof (v9a_asr_table[0]), 1013 1.1 skrll sizeof (v9a_asr_table[0]), cmp_reg_entry); 1014 1.1 skrll 1015 1.1 skrll /* If -bump, record the architecture level at which we start issuing 1016 1.1 skrll warnings. The behaviour is different depending upon whether an 1017 1.1 skrll architecture was explicitly specified. If it wasn't, we issue warnings 1018 1.1 skrll for all upwards bumps. If it was, we don't start issuing warnings until 1019 1.1 skrll we need to bump beyond the requested architecture or when we bump between 1020 1.1 skrll conflicting architectures. */ 1021 1.2 joerg 1022 1.2 joerg if (warn_on_bump 1023 1.2 joerg && architecture_requested) 1024 1.2 joerg { 1025 1.2 joerg /* `max_architecture' records the requested architecture. 1026 1.2 joerg Issue warnings if we go above it. */ 1027 1.2 joerg warn_after_architecture = max_architecture; 1028 1.2 joerg } 1029 1.2 joerg 1030 1.2 joerg /* Find the highest architecture level that doesn't conflict with 1031 1.1 skrll the requested one. */ 1032 1.2 joerg 1033 1.2 joerg if (warn_on_bump 1034 1.2 joerg || !architecture_requested) 1035 1.2 joerg { 1036 1.2 joerg enum sparc_opcode_arch_val current_max_architecture 1037 1.2 joerg = max_architecture; 1038 1.2 joerg 1039 1.3 christos for (max_architecture = SPARC_OPCODE_ARCH_MAX; 1040 1.3 christos max_architecture > warn_after_architecture; 1041 1.3 christos --max_architecture) 1042 1.3 christos if (! SPARC_OPCODE_CONFLICT_P (max_architecture, 1043 1.3 christos current_max_architecture)) 1044 1.3 christos break; 1045 1.3 christos } 1046 1.3 christos 1047 1.3 christos /* Prepare the tables of %-pseudo-ops. */ 1048 1.3 christos { 1049 1.3 christos struct priv_reg_entry *reg_tables[] 1050 1.3 christos = {priv_reg_table, hpriv_reg_table, v9a_asr_table, NULL}; 1051 1.3 christos struct priv_reg_entry **reg_table; 1052 1.3 christos int entry = 0; 1053 1.3 christos 1054 1.3 christos /* Add registers. */ 1055 1.3 christos for (reg_table = reg_tables; reg_table[0]; reg_table++) 1056 1.3 christos { 1057 1.3 christos struct priv_reg_entry *reg; 1058 1.3 christos for (reg = *reg_table; reg->name; reg++) 1059 1.3 christos { 1060 1.3 christos struct perc_entry *p = &perc_table[entry++]; 1061 1.3 christos p->type = perc_entry_reg; 1062 1.4 christos p->name = reg->name; 1063 1.4 christos p->len = strlen (reg->name); 1064 1.4 christos p->reg = reg; 1065 1.4 christos } 1066 1.4 christos } 1067 1.4 christos 1068 1.4 christos /* Add %-pseudo-ops. */ 1069 1.4 christos for (i = 0; i < ARRAY_SIZE (pop_table); i++) 1070 1.4 christos { 1071 1.3 christos struct perc_entry *p = &perc_table[entry++]; 1072 1.4 christos p->type = (pop_table[i].flags & F_POP_POSTFIX 1073 1.3 christos ? perc_entry_post_pop : perc_entry_imm_pop); 1074 1.3 christos p->name = pop_table[i].name; 1075 1.3 christos p->len = strlen (pop_table[i].name); 1076 1.3 christos p->pop = &pop_table[i]; 1077 1.3 christos } 1078 1.3 christos 1079 1.1 skrll /* Last entry is the sentinel. */ 1080 1.1 skrll perc_table[entry].type = perc_entry_none; 1081 1.1 skrll 1082 1.1 skrll qsort (perc_table, sizeof (perc_table) / sizeof (perc_table[0]), 1083 1.1 skrll sizeof (perc_table[0]), cmp_perc_entry); 1084 1.1 skrll 1085 1.1 skrll } 1086 1.5 christos } 1087 1.5 christos 1088 1.2 joerg /* Called after all assembly has been done. */ 1089 1.2 joerg 1090 1.1 skrll void 1091 1.1 skrll sparc_md_end (void) 1092 1.1 skrll { 1093 1.1 skrll unsigned long mach; 1094 1.1 skrll #ifndef TE_SOLARIS 1095 1.1 skrll int hwcaps, hwcaps2; 1096 1.3 christos #endif 1097 1.3 christos 1098 1.3 christos if (sparc_arch_size == 64) 1099 1.3 christos switch (current_architecture) 1100 1.3 christos { 1101 1.4 christos case SPARC_OPCODE_ARCH_V9A: mach = bfd_mach_sparc_v9a; break; 1102 1.1 skrll case SPARC_OPCODE_ARCH_V9B: mach = bfd_mach_sparc_v9b; break; 1103 1.1 skrll case SPARC_OPCODE_ARCH_V9C: mach = bfd_mach_sparc_v9c; break; 1104 1.1 skrll case SPARC_OPCODE_ARCH_V9D: mach = bfd_mach_sparc_v9d; break; 1105 1.1 skrll case SPARC_OPCODE_ARCH_V9E: mach = bfd_mach_sparc_v9e; break; 1106 1.1 skrll case SPARC_OPCODE_ARCH_V9V: mach = bfd_mach_sparc_v9v; break; 1107 1.1 skrll case SPARC_OPCODE_ARCH_V9M: mach = bfd_mach_sparc_v9m; break; 1108 1.1 skrll case SPARC_OPCODE_ARCH_M8: mach = bfd_mach_sparc_v9m8; break; 1109 1.1 skrll default: mach = bfd_mach_sparc_v9; break; 1110 1.1 skrll } 1111 1.3 christos else 1112 1.3 christos switch (current_architecture) 1113 1.3 christos { 1114 1.3 christos case SPARC_OPCODE_ARCH_SPARCLET: mach = bfd_mach_sparc_sparclet; break; 1115 1.3 christos case SPARC_OPCODE_ARCH_V9: mach = bfd_mach_sparc_v8plus; break; 1116 1.4 christos case SPARC_OPCODE_ARCH_V9A: mach = bfd_mach_sparc_v8plusa; break; 1117 1.1 skrll case SPARC_OPCODE_ARCH_V9B: mach = bfd_mach_sparc_v8plusb; break; 1118 1.1 skrll case SPARC_OPCODE_ARCH_V9C: mach = bfd_mach_sparc_v8plusc; break; 1119 1.1 skrll case SPARC_OPCODE_ARCH_V9D: mach = bfd_mach_sparc_v8plusd; break; 1120 1.5 christos case SPARC_OPCODE_ARCH_V9E: mach = bfd_mach_sparc_v8pluse; break; 1121 1.1 skrll case SPARC_OPCODE_ARCH_V9V: mach = bfd_mach_sparc_v8plusv; break; 1122 1.1 skrll case SPARC_OPCODE_ARCH_V9M: mach = bfd_mach_sparc_v8plusm; break; 1123 1.2 joerg case SPARC_OPCODE_ARCH_M8: mach = bfd_mach_sparc_v8plusm8; break; 1124 1.5 christos /* The sparclite is treated like a normal sparc. Perhaps it shouldn't 1125 1.2 joerg be but for now it is (since that's the way it's always been 1126 1.2 joerg treated). */ 1127 1.2 joerg default: mach = bfd_mach_sparc; break; 1128 1.2 joerg } 1129 1.2 joerg bfd_set_arch_mach (stdoutput, bfd_arch_sparc, mach); 1130 1.2 joerg 1131 1.2 joerg #ifndef TE_SOLARIS 1132 1.2 joerg hwcaps = hwcap_seen & U0xffffffff; 1133 1.1 skrll hwcaps2 = hwcap_seen >> 32; 1134 1.1 skrll 1135 1.1 skrll if (hwcaps) 1136 1.1 skrll bfd_elf_add_obj_attr_int (stdoutput, OBJ_ATTR_GNU, Tag_GNU_Sparc_HWCAPS, hwcaps); 1137 1.1 skrll if (hwcaps2) 1138 1.1 skrll bfd_elf_add_obj_attr_int (stdoutput, OBJ_ATTR_GNU, Tag_GNU_Sparc_HWCAPS2, hwcaps2); 1139 1.1 skrll #endif 1140 1.1 skrll } 1141 1.1 skrll 1142 1.1 skrll /* Return non-zero if VAL is in the range -(MAX+1) to MAX. */ 1144 1.1 skrll 1145 1.1 skrll static inline int 1146 1.7 christos in_signed_range (bfd_signed_vma val, bfd_signed_vma max) 1147 1.1 skrll { 1148 1.1 skrll if (max <= 0) 1149 1.1 skrll abort (); 1150 1.1 skrll /* Sign-extend the value from the architecture word size, so that 1151 1.1 skrll 0xffffffff is always considered -1 on sparc32. */ 1152 1.1 skrll if (sparc_arch_size == 32) 1153 1.1 skrll { 1154 1.1 skrll bfd_vma sign = (bfd_vma) 1 << 31; 1155 1.1 skrll val = ((val & U0xffffffff) ^ sign) - sign; 1156 1.1 skrll } 1157 1.1 skrll if (val > max) 1158 1.1 skrll return 0; 1159 1.1 skrll if (val < ~max) 1160 1.1 skrll return 0; 1161 1.1 skrll return 1; 1162 1.1 skrll } 1163 1.1 skrll 1164 1.1 skrll /* Return non-zero if VAL is in the range 0 to MAX. */ 1165 1.1 skrll 1166 1.1 skrll static inline int 1167 1.1 skrll in_unsigned_range (bfd_vma val, bfd_vma max) 1168 1.1 skrll { 1169 1.1 skrll if (val > max) 1170 1.1 skrll return 0; 1171 1.1 skrll return 1; 1172 1.1 skrll } 1173 1.1 skrll 1174 1.1 skrll /* Return non-zero if VAL is in the range -(MAX/2+1) to MAX. 1175 1.1 skrll (e.g. -15 to +31). */ 1176 1.1 skrll 1177 1.1 skrll static inline int 1178 1.1 skrll in_bitfield_range (bfd_signed_vma val, bfd_signed_vma max) 1179 1.1 skrll { 1180 1.1 skrll if (max <= 0) 1181 1.1 skrll abort (); 1182 1.1 skrll if (val > max) 1183 1.1 skrll return 0; 1184 1.1 skrll if (val < ~(max >> 1)) 1185 1.1 skrll return 0; 1186 1.1 skrll return 1; 1187 1.1 skrll } 1188 1.1 skrll 1189 1.1 skrll static int 1190 1.1 skrll sparc_ffs (unsigned int mask) 1191 1.1 skrll { 1192 1.1 skrll int i; 1193 1.1 skrll 1194 1.1 skrll if (mask == 0) 1195 1.1 skrll return -1; 1196 1.1 skrll 1197 1.1 skrll for (i = 0; (mask & 1) == 0; ++i) 1198 1.1 skrll mask >>= 1; 1199 1.1 skrll return i; 1200 1.1 skrll } 1201 1.1 skrll 1202 1.1 skrll /* Implement big shift right. */ 1203 1.1 skrll static bfd_vma 1204 1.1 skrll BSR (bfd_vma val, int amount) 1205 1.1 skrll { 1206 1.1 skrll if (sizeof (bfd_vma) <= 4 && amount >= 32) 1207 1.4 christos as_fatal (_("Support for 64-bit arithmetic not compiled in.")); 1208 1.1 skrll return val >> amount; 1209 1.1 skrll } 1210 1.1 skrll 1211 1.1 skrll /* For communication between sparc_ip and get_expression. */ 1213 1.1 skrll static char *expr_end; 1214 1.1 skrll 1215 1.1 skrll /* Values for `special_case'. 1216 1.1 skrll Instructions that require weird handling because they're longer than 1217 1.1 skrll 4 bytes. */ 1218 1.1 skrll #define SPECIAL_CASE_NONE 0 1219 1.1 skrll #define SPECIAL_CASE_SET 1 1220 1.1 skrll #define SPECIAL_CASE_SETSW 2 1221 1.1 skrll #define SPECIAL_CASE_SETX 3 1222 1.1 skrll /* FIXME: sparc-opc.c doesn't have necessary "S" trigger to enable this. */ 1223 1.1 skrll #define SPECIAL_CASE_FDIV 4 1224 1.1 skrll 1225 1.1 skrll /* Bit masks of various insns. */ 1226 1.1 skrll #define NOP_INSN 0x01000000 1227 1.1 skrll #define OR_INSN 0x80100000 1228 1.1 skrll #define XOR_INSN 0x80180000 1229 1.1 skrll #define FMOVS_INSN 0x81A00020 1230 1.1 skrll #define SETHI_INSN 0x01000000 1231 1.1 skrll #define SLLX_INSN 0x81281000 1232 1.1 skrll #define SRA_INSN 0x81380000 1233 1.1 skrll 1234 1.1 skrll /* The last instruction to be assembled. */ 1235 1.1 skrll static const struct sparc_opcode *last_insn; 1236 1.1 skrll /* The assembled opcode of `last_insn'. */ 1237 1.1 skrll static unsigned long last_opcode; 1238 1.1 skrll 1239 1.1 skrll /* Handle the set and setuw synthetic instructions. */ 1241 1.1 skrll 1242 1.1 skrll static void 1243 1.1 skrll synthetize_setuw (const struct sparc_opcode *insn) 1244 1.1 skrll { 1245 1.1 skrll int need_hi22_p = 0; 1246 1.1 skrll int rd = (the_insn.opcode & RD (~0)) >> 25; 1247 1.1 skrll 1248 1.1 skrll if (the_insn.exp.X_op == O_constant) 1249 1.1 skrll { 1250 1.1 skrll if (SPARC_OPCODE_ARCH_V9_P (max_architecture)) 1251 1.1 skrll { 1252 1.1 skrll if (sizeof (offsetT) > 4 1253 1.1 skrll && (the_insn.exp.X_add_number < 0 1254 1.1 skrll || the_insn.exp.X_add_number > (offsetT) U0xffffffff)) 1255 1.1 skrll as_warn (_("set: number not in 0..4294967295 range")); 1256 1.1 skrll } 1257 1.1 skrll else 1258 1.1 skrll { 1259 1.1 skrll if (sizeof (offsetT) > 4 1260 1.1 skrll && (the_insn.exp.X_add_number < -(offsetT) U0x80000000 1261 1.1 skrll || the_insn.exp.X_add_number > (offsetT) U0xffffffff)) 1262 1.1 skrll as_warn (_("set: number not in -2147483648..4294967295 range")); 1263 1.1 skrll the_insn.exp.X_add_number = (int) the_insn.exp.X_add_number; 1264 1.1 skrll } 1265 1.1 skrll } 1266 1.1 skrll 1267 1.1 skrll /* See if operand is absolute and small; skip sethi if so. */ 1268 1.1 skrll if (the_insn.exp.X_op != O_constant 1269 1.1 skrll || the_insn.exp.X_add_number >= (1 << 12) 1270 1.1 skrll || the_insn.exp.X_add_number < -(1 << 12)) 1271 1.1 skrll { 1272 1.1 skrll the_insn.opcode = (SETHI_INSN | RD (rd) 1273 1.1 skrll | ((the_insn.exp.X_add_number >> 10) 1274 1.1 skrll & (the_insn.exp.X_op == O_constant 1275 1.1 skrll ? 0x3fffff : 0))); 1276 1.1 skrll the_insn.reloc = (the_insn.exp.X_op != O_constant 1277 1.1 skrll ? BFD_RELOC_HI22 : BFD_RELOC_NONE); 1278 1.1 skrll output_insn (insn, &the_insn); 1279 1.1 skrll need_hi22_p = 1; 1280 1.1 skrll } 1281 1.1 skrll 1282 1.1 skrll /* See if operand has no low-order bits; skip OR if so. */ 1283 1.1 skrll if (the_insn.exp.X_op != O_constant 1284 1.1 skrll || (need_hi22_p && (the_insn.exp.X_add_number & 0x3FF) != 0) 1285 1.1 skrll || ! need_hi22_p) 1286 1.1 skrll { 1287 1.1 skrll the_insn.opcode = (OR_INSN | (need_hi22_p ? RS1 (rd) : 0) 1288 1.1 skrll | RD (rd) | IMMED 1289 1.1 skrll | (the_insn.exp.X_add_number 1290 1.1 skrll & (the_insn.exp.X_op != O_constant 1291 1.1 skrll ? 0 : need_hi22_p ? 0x3ff : 0x1fff))); 1292 1.1 skrll the_insn.reloc = (the_insn.exp.X_op != O_constant 1293 1.1 skrll ? BFD_RELOC_LO10 : BFD_RELOC_NONE); 1294 1.1 skrll output_insn (insn, &the_insn); 1295 1.1 skrll } 1296 1.1 skrll } 1297 1.1 skrll 1298 1.1 skrll /* Handle the setsw synthetic instruction. */ 1299 1.1 skrll 1300 1.1 skrll static void 1301 1.1 skrll synthetize_setsw (const struct sparc_opcode *insn) 1302 1.1 skrll { 1303 1.1 skrll int low32, rd, opc; 1304 1.1 skrll 1305 1.1 skrll rd = (the_insn.opcode & RD (~0)) >> 25; 1306 1.1 skrll 1307 1.1 skrll if (the_insn.exp.X_op != O_constant) 1308 1.1 skrll { 1309 1.1 skrll synthetize_setuw (insn); 1310 1.1 skrll 1311 1.1 skrll /* Need to sign extend it. */ 1312 1.1 skrll the_insn.opcode = (SRA_INSN | RS1 (rd) | RD (rd)); 1313 1.1 skrll the_insn.reloc = BFD_RELOC_NONE; 1314 1.1 skrll output_insn (insn, &the_insn); 1315 1.1 skrll return; 1316 1.1 skrll } 1317 1.1 skrll 1318 1.1 skrll if (sizeof (offsetT) > 4 1319 1.1 skrll && (the_insn.exp.X_add_number < -(offsetT) U0x80000000 1320 1.1 skrll || the_insn.exp.X_add_number > (offsetT) U0xffffffff)) 1321 1.1 skrll as_warn (_("setsw: number not in -2147483648..4294967295 range")); 1322 1.1 skrll 1323 1.1 skrll low32 = the_insn.exp.X_add_number; 1324 1.1 skrll 1325 1.1 skrll if (low32 >= 0) 1326 1.1 skrll { 1327 1.1 skrll synthetize_setuw (insn); 1328 1.1 skrll return; 1329 1.1 skrll } 1330 1.1 skrll 1331 1.1 skrll opc = OR_INSN; 1332 1.1 skrll 1333 1.1 skrll the_insn.reloc = BFD_RELOC_NONE; 1334 1.1 skrll /* See if operand is absolute and small; skip sethi if so. */ 1335 1.1 skrll if (low32 < -(1 << 12)) 1336 1.1 skrll { 1337 1.1 skrll the_insn.opcode = (SETHI_INSN | RD (rd) 1338 1.1 skrll | (((~the_insn.exp.X_add_number) >> 10) & 0x3fffff)); 1339 1.2 joerg output_insn (insn, &the_insn); 1340 1.1 skrll low32 = 0x1c00 | (low32 & 0x3ff); 1341 1.1 skrll opc = RS1 (rd) | XOR_INSN; 1342 1.1 skrll } 1343 1.1 skrll 1344 1.1 skrll the_insn.opcode = (opc | RD (rd) | IMMED 1345 1.1 skrll | (low32 & 0x1fff)); 1346 1.1 skrll output_insn (insn, &the_insn); 1347 1.1 skrll } 1348 1.1 skrll 1349 1.1 skrll /* Handle the setx synthetic instruction. */ 1350 1.1 skrll 1351 1.1 skrll static void 1352 1.1 skrll synthetize_setx (const struct sparc_opcode *insn) 1353 1.1 skrll { 1354 1.1 skrll int upper32, lower32; 1355 1.1 skrll int tmpreg = (the_insn.opcode & RS1 (~0)) >> 14; 1356 1.1 skrll int dstreg = (the_insn.opcode & RD (~0)) >> 25; 1357 1.1 skrll int upper_dstreg; 1358 1.1 skrll int need_hh22_p = 0, need_hm10_p = 0, need_hi22_p = 0, need_lo10_p = 0; 1359 1.1 skrll int need_xor10_p = 0; 1360 1.1 skrll 1361 1.1 skrll #define SIGNEXT32(x) ((((x) & U0xffffffff) ^ U0x80000000) - U0x80000000) 1362 1.1 skrll lower32 = SIGNEXT32 (the_insn.exp.X_add_number); 1363 1.1 skrll upper32 = SIGNEXT32 (BSR (the_insn.exp.X_add_number, 32)); 1364 1.1 skrll #undef SIGNEXT32 1365 1.1 skrll 1366 1.1 skrll upper_dstreg = tmpreg; 1367 1.1 skrll /* The tmp reg should not be the dst reg. */ 1368 1.1 skrll if (tmpreg == dstreg) 1369 1.1 skrll as_warn (_("setx: temporary register same as destination register")); 1370 1.1 skrll 1371 1.1 skrll /* ??? Obviously there are other optimizations we can do 1372 1.1 skrll (e.g. sethi+shift for 0x1f0000000) and perhaps we shouldn't be 1373 1.1 skrll doing some of these. Later. If you do change things, try to 1374 1.1 skrll change all of this to be table driven as well. */ 1375 1.1 skrll /* What to output depends on the number if it's constant. 1376 1.1 skrll Compute that first, then output what we've decided upon. */ 1377 1.1 skrll if (the_insn.exp.X_op != O_constant) 1378 1.1 skrll { 1379 1.1 skrll if (sparc_arch_size == 32) 1380 1.1 skrll { 1381 1.1 skrll /* When arch size is 32, we want setx to be equivalent 1382 1.1 skrll to setuw for anything but constants. */ 1383 1.1 skrll the_insn.exp.X_add_number &= 0xffffffff; 1384 1.1 skrll synthetize_setuw (insn); 1385 1.1 skrll return; 1386 1.1 skrll } 1387 1.1 skrll need_hh22_p = need_hm10_p = need_hi22_p = need_lo10_p = 1; 1388 1.1 skrll lower32 = 0; 1389 1.1 skrll upper32 = 0; 1390 1.1 skrll } 1391 1.1 skrll else 1392 1.1 skrll { 1393 1.1 skrll /* Reset X_add_number, we've extracted it as upper32/lower32. 1394 1.1 skrll Otherwise fixup_segment will complain about not being able to 1395 1.1 skrll write an 8 byte number in a 4 byte field. */ 1396 1.1 skrll the_insn.exp.X_add_number = 0; 1397 1.1 skrll 1398 1.1 skrll /* Only need hh22 if `or' insn can't handle constant. */ 1399 1.1 skrll if (upper32 < -(1 << 12) || upper32 >= (1 << 12)) 1400 1.1 skrll need_hh22_p = 1; 1401 1.1 skrll 1402 1.1 skrll /* Does bottom part (after sethi) have bits? */ 1403 1.1 skrll if ((need_hh22_p && (upper32 & 0x3ff) != 0) 1404 1.1 skrll /* No hh22, but does upper32 still have bits we can't set 1405 1.1 skrll from lower32? */ 1406 1.1 skrll || (! need_hh22_p && upper32 != 0 && upper32 != -1)) 1407 1.1 skrll need_hm10_p = 1; 1408 1.1 skrll 1409 1.1 skrll /* If the lower half is all zero, we build the upper half directly 1410 1.1 skrll into the dst reg. */ 1411 1.1 skrll if (lower32 != 0 1412 1.1 skrll /* Need lower half if number is zero or 0xffffffff00000000. */ 1413 1.1 skrll || (! need_hh22_p && ! need_hm10_p)) 1414 1.1 skrll { 1415 1.1 skrll /* No need for sethi if `or' insn can handle constant. */ 1416 1.1 skrll if (lower32 < -(1 << 12) || lower32 >= (1 << 12) 1417 1.1 skrll /* Note that we can't use a negative constant in the `or' 1418 1.1 skrll insn unless the upper 32 bits are all ones. */ 1419 1.1 skrll || (lower32 < 0 && upper32 != -1) 1420 1.1 skrll || (lower32 >= 0 && upper32 == -1)) 1421 1.1 skrll need_hi22_p = 1; 1422 1.1 skrll 1423 1.1 skrll if (need_hi22_p && upper32 == -1) 1424 1.1 skrll need_xor10_p = 1; 1425 1.1 skrll 1426 1.1 skrll /* Does bottom part (after sethi) have bits? */ 1427 1.1 skrll else if ((need_hi22_p && (lower32 & 0x3ff) != 0) 1428 1.1 skrll /* No sethi. */ 1429 1.1 skrll || (! need_hi22_p && (lower32 & 0x1fff) != 0) 1430 1.1 skrll /* Need `or' if we didn't set anything else. */ 1431 1.1 skrll || (! need_hi22_p && ! need_hh22_p && ! need_hm10_p)) 1432 1.1 skrll need_lo10_p = 1; 1433 1.1 skrll } 1434 1.1 skrll else 1435 1.1 skrll /* Output directly to dst reg if lower 32 bits are all zero. */ 1436 1.1 skrll upper_dstreg = dstreg; 1437 1.1 skrll } 1438 1.1 skrll 1439 1.1 skrll if (!upper_dstreg && dstreg) 1440 1.1 skrll as_warn (_("setx: illegal temporary register g0")); 1441 1.1 skrll 1442 1.1 skrll if (need_hh22_p) 1443 1.1 skrll { 1444 1.1 skrll the_insn.opcode = (SETHI_INSN | RD (upper_dstreg) 1445 1.1 skrll | ((upper32 >> 10) & 0x3fffff)); 1446 1.1 skrll the_insn.reloc = (the_insn.exp.X_op != O_constant 1447 1.1 skrll ? BFD_RELOC_SPARC_HH22 : BFD_RELOC_NONE); 1448 1.1 skrll output_insn (insn, &the_insn); 1449 1.1 skrll } 1450 1.1 skrll 1451 1.1 skrll if (need_hi22_p) 1452 1.1 skrll { 1453 1.1 skrll the_insn.opcode = (SETHI_INSN | RD (dstreg) 1454 1.1 skrll | (((need_xor10_p ? ~lower32 : lower32) 1455 1.1 skrll >> 10) & 0x3fffff)); 1456 1.1 skrll the_insn.reloc = (the_insn.exp.X_op != O_constant 1457 1.1 skrll ? BFD_RELOC_SPARC_LM22 : BFD_RELOC_NONE); 1458 1.1 skrll output_insn (insn, &the_insn); 1459 1.1 skrll } 1460 1.1 skrll 1461 1.1 skrll if (need_hm10_p) 1462 1.1 skrll { 1463 1.1 skrll the_insn.opcode = (OR_INSN 1464 1.1 skrll | (need_hh22_p ? RS1 (upper_dstreg) : 0) 1465 1.1 skrll | RD (upper_dstreg) 1466 1.1 skrll | IMMED 1467 1.1 skrll | (upper32 & (need_hh22_p ? 0x3ff : 0x1fff))); 1468 1.1 skrll the_insn.reloc = (the_insn.exp.X_op != O_constant 1469 1.1 skrll ? BFD_RELOC_SPARC_HM10 : BFD_RELOC_NONE); 1470 1.1 skrll output_insn (insn, &the_insn); 1471 1.1 skrll } 1472 1.1 skrll 1473 1.1 skrll if (need_lo10_p) 1474 1.1 skrll { 1475 1.1 skrll /* FIXME: One nice optimization to do here is to OR the low part 1476 1.1 skrll with the highpart if hi22 isn't needed and the low part is 1477 1.1 skrll positive. */ 1478 1.1 skrll the_insn.opcode = (OR_INSN | (need_hi22_p ? RS1 (dstreg) : 0) 1479 1.1 skrll | RD (dstreg) 1480 1.1 skrll | IMMED 1481 1.1 skrll | (lower32 & (need_hi22_p ? 0x3ff : 0x1fff))); 1482 1.1 skrll the_insn.reloc = (the_insn.exp.X_op != O_constant 1483 1.1 skrll ? BFD_RELOC_LO10 : BFD_RELOC_NONE); 1484 1.1 skrll output_insn (insn, &the_insn); 1485 1.1 skrll } 1486 1.1 skrll 1487 1.1 skrll /* If we needed to build the upper part, shift it into place. */ 1488 1.1 skrll if (need_hh22_p || need_hm10_p) 1489 1.1 skrll { 1490 1.1 skrll the_insn.opcode = (SLLX_INSN | RS1 (upper_dstreg) | RD (upper_dstreg) 1491 1.1 skrll | IMMED | 32); 1492 1.1 skrll the_insn.reloc = BFD_RELOC_NONE; 1493 1.1 skrll output_insn (insn, &the_insn); 1494 1.1 skrll } 1495 1.1 skrll 1496 1.1 skrll /* To get -1 in upper32, we do sethi %hi(~x), r; xor r, -0x400 | x, r. */ 1497 1.1 skrll if (need_xor10_p) 1498 1.1 skrll { 1499 1.1 skrll the_insn.opcode = (XOR_INSN | RS1 (dstreg) | RD (dstreg) | IMMED 1500 1.1 skrll | 0x1c00 | (lower32 & 0x3ff)); 1501 1.1 skrll the_insn.reloc = BFD_RELOC_NONE; 1502 1.1 skrll output_insn (insn, &the_insn); 1503 1.1 skrll } 1504 1.1 skrll 1505 1.1 skrll /* If we needed to build both upper and lower parts, OR them together. */ 1506 1.1 skrll else if ((need_hh22_p || need_hm10_p) && (need_hi22_p || need_lo10_p)) 1507 1.1 skrll { 1508 1.1 skrll the_insn.opcode = (OR_INSN | RS1 (dstreg) | RS2 (upper_dstreg) 1509 1.1 skrll | RD (dstreg)); 1510 1.1 skrll the_insn.reloc = BFD_RELOC_NONE; 1511 1.1 skrll output_insn (insn, &the_insn); 1512 1.1 skrll } 1513 1.1 skrll } 1514 1.1 skrll 1515 1.1 skrll /* Main entry point to assemble one instruction. */ 1517 1.1 skrll 1518 1.4 christos void 1519 1.4 christos md_assemble (char *str) 1520 1.1 skrll { 1521 1.4 christos const struct sparc_opcode *insn; 1522 1.4 christos int special_case; 1523 1.4 christos 1524 1.4 christos know (str); 1525 1.4 christos special_case = sparc_ip (str, &insn); 1526 1.4 christos if (insn == NULL) 1527 1.4 christos return; 1528 1.4 christos 1529 1.4 christos /* Certain instructions may not appear on delay slots. Check for 1530 1.4 christos these situations. */ 1531 1.4 christos if (last_insn != NULL 1532 1.4 christos && (last_insn->flags & F_DELAYED) != 0) 1533 1.4 christos { 1534 1.4 christos /* Before SPARC V9 the effect of having a delayed branch 1535 1.4 christos instruction in the delay slot of a conditional delayed branch 1536 1.4 christos was undefined. 1537 1.4 christos 1538 1.4 christos In SPARC V9 DCTI couples are well defined. 1539 1.4 christos 1540 1.4 christos However, starting with the UltraSPARC Architecture 2005, DCTI 1541 1.4 christos couples (of all kind) are deprecated and should not be used, 1542 1.4 christos as they may be slow or behave differently to what the 1543 1.4 christos programmer expects. */ 1544 1.4 christos if (dcti_couples_detect 1545 1.4 christos && (insn->flags & F_DELAYED) != 0 1546 1.4 christos && ((max_architecture < SPARC_OPCODE_ARCH_V9 1547 1.4 christos && (last_insn->flags & F_CONDBR) != 0) 1548 1.4 christos || max_architecture >= SPARC_OPCODE_ARCH_V9C)) 1549 1.4 christos as_warn (_("unpredictable DCTI couple")); 1550 1.1 skrll 1551 1.6 christos 1552 1.6 christos /* We warn about attempts to put a floating point branch in a 1553 1.6 christos delay slot, unless the delay slot has been annulled. */ 1554 1.6 christos if ((insn->flags & F_FBR) != 0 1555 1.6 christos /* ??? This test isn't completely accurate. We assume anything with 1556 1.1 skrll F_{UNBR,CONDBR,FBR} set is annullable. */ 1557 1.2 joerg && ((last_insn->flags & (F_UNBR | F_CONDBR | F_FBR)) == 0 1558 1.6 christos || (last_opcode & ANNUL) == 0)) 1559 1.1 skrll as_warn (_("FP branch in delay slot")); 1560 1.1 skrll } 1561 1.1 skrll 1562 1.1 skrll /* SPARC before v9 does not allow a floating point compare 1563 1.1 skrll directly before a floating point branch. Insert a nop 1564 1.1 skrll instruction if needed, with a warning. */ 1565 1.6 christos if (max_architecture < SPARC_OPCODE_ARCH_V9 1566 1.1 skrll && last_insn != NULL 1567 1.1 skrll && (insn->flags & F_FBR) != 0 1568 1.1 skrll && (last_insn->flags & F_FLOAT) != 0 1569 1.1 skrll && (last_insn->match & OP3 (0x35)) == OP3 (0x35)) 1570 1.1 skrll { 1571 1.1 skrll struct sparc_it nop_insn; 1572 1.1 skrll 1573 1.1 skrll nop_insn.opcode = NOP_INSN; 1574 1.1 skrll nop_insn.reloc = BFD_RELOC_NONE; 1575 1.1 skrll output_insn (insn, &nop_insn); 1576 1.1 skrll as_warn (_("FP branch preceded by FP compare; NOP inserted")); 1577 1.1 skrll } 1578 1.1 skrll 1579 1.1 skrll switch (special_case) 1580 1.1 skrll { 1581 1.1 skrll case SPECIAL_CASE_NONE: 1582 1.1 skrll /* Normal insn. */ 1583 1.1 skrll output_insn (insn, &the_insn); 1584 1.1 skrll break; 1585 1.1 skrll 1586 1.1 skrll case SPECIAL_CASE_SETSW: 1587 1.1 skrll synthetize_setsw (insn); 1588 1.1 skrll break; 1589 1.1 skrll 1590 1.1 skrll case SPECIAL_CASE_SET: 1591 1.1 skrll synthetize_setuw (insn); 1592 1.1 skrll break; 1593 1.1 skrll 1594 1.1 skrll case SPECIAL_CASE_SETX: 1595 1.1 skrll synthetize_setx (insn); 1596 1.1 skrll break; 1597 1.1 skrll 1598 1.2 joerg case SPECIAL_CASE_FDIV: 1599 1.1 skrll { 1600 1.1 skrll int rd = (the_insn.opcode >> 25) & 0x1f; 1601 1.1 skrll 1602 1.1 skrll output_insn (insn, &the_insn); 1603 1.1 skrll 1604 1.1 skrll /* According to information leaked from Sun, the "fdiv" instructions 1605 1.1 skrll on early SPARC machines would produce incorrect results sometimes. 1606 1.1 skrll The workaround is to add an fmovs of the destination register to 1607 1.1 skrll itself just after the instruction. This was true on machines 1608 1.1 skrll with Weitek 1165 float chips, such as the Sun-4/260 and /280. */ 1609 1.2 joerg gas_assert (the_insn.reloc == BFD_RELOC_NONE); 1610 1.7 christos the_insn.opcode = FMOVS_INSN | rd | RD (rd); 1611 1.2 joerg output_insn (insn, &the_insn); 1612 1.2 joerg return; 1613 1.2 joerg } 1614 1.2 joerg 1615 1.2 joerg default: 1616 1.2 joerg as_fatal (_("failed special case insn sanity check")); 1617 1.2 joerg } 1618 1.2 joerg } 1619 1.2 joerg 1620 1.2 joerg static const char * 1621 1.2 joerg get_hwcap_name (uint64_t mask) 1622 1.2 joerg { 1623 1.2 joerg if (mask & HWCAP_MUL32) 1624 1.2 joerg return "mul32"; 1625 1.2 joerg if (mask & HWCAP_DIV32) 1626 1.2 joerg return "div32"; 1627 1.2 joerg if (mask & HWCAP_FSMULD) 1628 1.2 joerg return "fsmuld"; 1629 1.2 joerg if (mask & HWCAP_V8PLUS) 1630 1.2 joerg return "v8plus"; 1631 1.2 joerg if (mask & HWCAP_POPC) 1632 1.2 joerg return "popc"; 1633 1.2 joerg if (mask & HWCAP_VIS) 1634 1.2 joerg return "vis"; 1635 1.2 joerg if (mask & HWCAP_VIS2) 1636 1.2 joerg return "vis2"; 1637 1.2 joerg if (mask & HWCAP_ASI_BLK_INIT) 1638 1.2 joerg return "ASIBlkInit"; 1639 1.2 joerg if (mask & HWCAP_FMAF) 1640 1.2 joerg return "fmaf"; 1641 1.2 joerg if (mask & HWCAP_VIS3) 1642 1.2 joerg return "vis3"; 1643 1.2 joerg if (mask & HWCAP_HPC) 1644 1.2 joerg return "hpc"; 1645 1.2 joerg if (mask & HWCAP_RANDOM) 1646 1.2 joerg return "random"; 1647 1.2 joerg if (mask & HWCAP_TRANS) 1648 1.2 joerg return "trans"; 1649 1.2 joerg if (mask & HWCAP_FJFMAU) 1650 1.2 joerg return "fjfmau"; 1651 1.2 joerg if (mask & HWCAP_IMA) 1652 1.2 joerg return "ima"; 1653 1.2 joerg if (mask & HWCAP_ASI_CACHE_SPARING) 1654 1.2 joerg return "cspare"; 1655 1.2 joerg if (mask & HWCAP_AES) 1656 1.2 joerg return "aes"; 1657 1.2 joerg if (mask & HWCAP_DES) 1658 1.2 joerg return "des"; 1659 1.2 joerg if (mask & HWCAP_KASUMI) 1660 1.2 joerg return "kasumi"; 1661 1.2 joerg if (mask & HWCAP_CAMELLIA) 1662 1.2 joerg return "camellia"; 1663 1.2 joerg if (mask & HWCAP_MD5) 1664 1.2 joerg return "md5"; 1665 1.2 joerg if (mask & HWCAP_SHA1) 1666 1.2 joerg return "sha1"; 1667 1.2 joerg if (mask & HWCAP_SHA256) 1668 1.2 joerg return "sha256"; 1669 1.2 joerg if (mask & HWCAP_SHA512) 1670 1.2 joerg return "sha512"; 1671 1.2 joerg if (mask & HWCAP_MPMUL) 1672 1.2 joerg return "mpmul"; 1673 1.2 joerg if (mask & HWCAP_MONT) 1674 1.2 joerg return "mont"; 1675 1.2 joerg if (mask & HWCAP_PAUSE) 1676 1.2 joerg return "pause"; 1677 1.2 joerg if (mask & HWCAP_CBCOND) 1678 1.2 joerg return "cbcond"; 1679 1.2 joerg if (mask & HWCAP_CRC32C) 1680 1.2 joerg return "crc32c"; 1681 1.2 joerg 1682 1.2 joerg mask = mask >> 32; 1683 1.2 joerg if (mask & HWCAP2_FJATHPLUS) 1684 1.2 joerg return "fjathplus"; 1685 1.2 joerg if (mask & HWCAP2_VIS3B) 1686 1.2 joerg return "vis3b"; 1687 1.2 joerg if (mask & HWCAP2_ADP) 1688 1.4 christos return "adp"; 1689 1.4 christos if (mask & HWCAP2_SPARC5) 1690 1.4 christos return "sparc5"; 1691 1.4 christos if (mask & HWCAP2_MWAIT) 1692 1.4 christos return "mwait"; 1693 1.4 christos if (mask & HWCAP2_XMPMUL) 1694 1.4 christos return "xmpmul"; 1695 1.4 christos if (mask & HWCAP2_XMONT) 1696 1.4 christos return "xmont"; 1697 1.4 christos if (mask & HWCAP2_NSEC) 1698 1.4 christos return "nsec"; 1699 1.4 christos if (mask & HWCAP2_SPARC6) 1700 1.4 christos return "sparc6"; 1701 1.4 christos if (mask & HWCAP2_ONADDSUB) 1702 1.4 christos return "onaddsub"; 1703 1.4 christos if (mask & HWCAP2_ONMUL) 1704 1.2 joerg return "onmul"; 1705 1.2 joerg if (mask & HWCAP2_ONDIV) 1706 1.2 joerg return "ondiv"; 1707 1.2 joerg if (mask & HWCAP2_DICTUNP) 1708 1.1 skrll return "dictunp"; 1709 1.1 skrll if (mask & HWCAP2_FPCMPSHL) 1710 1.1 skrll return "fpcmpshl"; 1711 1.1 skrll if (mask & HWCAP2_RLE) 1712 1.1 skrll return "rle"; 1713 1.3 christos if (mask & HWCAP2_SHA3) 1714 1.1 skrll return "sha3"; 1715 1.1 skrll 1716 1.1 skrll return "UNKNOWN"; 1717 1.1 skrll } 1718 1.1 skrll 1719 1.1 skrll /* Subroutine of md_assemble to do the actual parsing. */ 1720 1.1 skrll 1721 1.1 skrll static int 1722 1.1 skrll sparc_ip (char *str, const struct sparc_opcode **pinsn) 1723 1.1 skrll { 1724 1.1 skrll const char *error_message = ""; 1725 1.4 christos char *s; 1726 1.1 skrll const char *args; 1727 1.1 skrll char c; 1728 1.1 skrll const struct sparc_opcode *insn; 1729 1.1 skrll char *argsStart; 1730 1.1 skrll unsigned long opcode; 1731 1.1 skrll unsigned int mask = 0; 1732 1.2 joerg int match = 0; 1733 1.1 skrll int comma = 0; 1734 1.1 skrll int v9_arg_p; 1735 1.1 skrll int special_case = SPECIAL_CASE_NONE; 1736 1.1 skrll const sparc_asi *sasi = NULL; 1737 1.1 skrll 1738 1.1 skrll s = str; 1739 1.1 skrll if (ISLOWER (*s)) 1740 1.1 skrll { 1741 1.1 skrll do 1742 1.1 skrll ++s; 1743 1.1 skrll while (ISLOWER (*s) || ISDIGIT (*s) || *s == '_'); 1744 1.1 skrll } 1745 1.1 skrll 1746 1.1 skrll switch (*s) 1747 1.1 skrll { 1748 1.1 skrll case '\0': 1749 1.1 skrll break; 1750 1.1 skrll 1751 1.1 skrll case ',': 1752 1.1 skrll comma = 1; 1753 1.7 christos /* Fall through. */ 1754 1.1 skrll 1755 1.1 skrll case ' ': 1756 1.1 skrll *s++ = '\0'; 1757 1.1 skrll break; 1758 1.1 skrll 1759 1.1 skrll default: 1760 1.1 skrll as_bad (_("Unknown opcode: `%s'"), str); 1761 1.1 skrll *pinsn = NULL; 1762 1.1 skrll return special_case; 1763 1.1 skrll } 1764 1.1 skrll insn = (struct sparc_opcode *) str_hash_find (op_hash, str); 1765 1.1 skrll *pinsn = insn; 1766 1.1 skrll if (insn == NULL) 1767 1.1 skrll { 1768 1.1 skrll as_bad (_("Unknown opcode: `%s'"), str); 1769 1.1 skrll return special_case; 1770 1.1 skrll } 1771 1.1 skrll if (comma) 1772 1.1 skrll { 1773 1.1 skrll *--s = ','; 1774 1.1 skrll } 1775 1.1 skrll 1776 1.1 skrll argsStart = s; 1777 1.1 skrll for (;;) 1778 1.1 skrll { 1779 1.1 skrll opcode = insn->match; 1780 1.1 skrll memset (&the_insn, '\0', sizeof (the_insn)); 1781 1.1 skrll the_insn.reloc = BFD_RELOC_NONE; 1782 1.1 skrll v9_arg_p = 0; 1783 1.1 skrll 1784 1.1 skrll /* Build the opcode, checking as we go to make sure that the 1785 1.1 skrll operands match. */ 1786 1.1 skrll for (args = insn->args;; ++args) 1787 1.1 skrll { 1788 1.2 joerg switch (*args) 1789 1.1 skrll { 1790 1.1 skrll case 'K': 1791 1.2 joerg { 1792 1.1 skrll int kmask = 0; 1793 1.1 skrll 1794 1.1 skrll /* Parse a series of masks. */ 1795 1.1 skrll if (*s == '#') 1796 1.2 joerg { 1797 1.1 skrll while (*s == '#') 1798 1.1 skrll { 1799 1.1 skrll int jmask; 1800 1.1 skrll 1801 1.1 skrll if (! parse_keyword_arg (sparc_encode_membar, &s, 1802 1.1 skrll &jmask)) 1803 1.1 skrll { 1804 1.1 skrll error_message = _(": invalid membar mask name"); 1805 1.1 skrll goto error; 1806 1.1 skrll } 1807 1.1 skrll kmask |= jmask; 1808 1.1 skrll while (*s == ' ') 1809 1.1 skrll ++s; 1810 1.1 skrll if (*s == '|' || *s == '+') 1811 1.1 skrll ++s; 1812 1.1 skrll while (*s == ' ') 1813 1.1 skrll ++s; 1814 1.1 skrll } 1815 1.1 skrll } 1816 1.1 skrll else 1817 1.1 skrll { 1818 1.1 skrll if (! parse_const_expr_arg (&s, &kmask)) 1819 1.1 skrll { 1820 1.1 skrll error_message = _(": invalid membar mask expression"); 1821 1.1 skrll goto error; 1822 1.1 skrll } 1823 1.1 skrll if (kmask < 0 || kmask > 127) 1824 1.1 skrll { 1825 1.1 skrll error_message = _(": invalid membar mask number"); 1826 1.1 skrll goto error; 1827 1.1 skrll } 1828 1.1 skrll } 1829 1.1 skrll 1830 1.1 skrll opcode |= MEMBAR (kmask); 1831 1.1 skrll continue; 1832 1.1 skrll } 1833 1.1 skrll 1834 1.1 skrll case '3': 1835 1.1 skrll { 1836 1.1 skrll int smask = 0; 1837 1.1 skrll 1838 1.1 skrll if (! parse_const_expr_arg (&s, &smask)) 1839 1.1 skrll { 1840 1.1 skrll error_message = _(": invalid siam mode expression"); 1841 1.1 skrll goto error; 1842 1.1 skrll } 1843 1.1 skrll if (smask < 0 || smask > 7) 1844 1.1 skrll { 1845 1.1 skrll error_message = _(": invalid siam mode number"); 1846 1.1 skrll goto error; 1847 1.1 skrll } 1848 1.1 skrll opcode |= smask; 1849 1.1 skrll continue; 1850 1.1 skrll } 1851 1.1 skrll 1852 1.1 skrll case '*': 1853 1.1 skrll { 1854 1.1 skrll int fcn = 0; 1855 1.1 skrll 1856 1.1 skrll /* Parse a prefetch function. */ 1857 1.1 skrll if (*s == '#') 1858 1.1 skrll { 1859 1.1 skrll if (! parse_keyword_arg (sparc_encode_prefetch, &s, &fcn)) 1860 1.1 skrll { 1861 1.1 skrll error_message = _(": invalid prefetch function name"); 1862 1.1 skrll goto error; 1863 1.1 skrll } 1864 1.1 skrll } 1865 1.1 skrll else 1866 1.1 skrll { 1867 1.1 skrll if (! parse_const_expr_arg (&s, &fcn)) 1868 1.1 skrll { 1869 1.1 skrll error_message = _(": invalid prefetch function expression"); 1870 1.1 skrll goto error; 1871 1.1 skrll } 1872 1.1 skrll if (fcn < 0 || fcn > 31) 1873 1.1 skrll { 1874 1.1 skrll error_message = _(": invalid prefetch function number"); 1875 1.1 skrll goto error; 1876 1.3 christos } 1877 1.1 skrll } 1878 1.1 skrll opcode |= RD (fcn); 1879 1.1 skrll continue; 1880 1.3 christos } 1881 1.3 christos 1882 1.3 christos case '!': 1883 1.3 christos case '?': 1884 1.3 christos /* Parse a sparc64 privileged register. */ 1885 1.3 christos if (*s == '%') 1886 1.3 christos { 1887 1.3 christos struct priv_reg_entry *p; 1888 1.3 christos unsigned int len = 9999999; /* Init to make gcc happy. */ 1889 1.1 skrll 1890 1.1 skrll s += 1; 1891 1.1 skrll for (p = priv_reg_table; p->name; p++) 1892 1.1 skrll if (p->name[0] == s[0]) 1893 1.3 christos { 1894 1.3 christos len = strlen (p->name); 1895 1.3 christos if (strncmp (p->name, s, len) == 0) 1896 1.3 christos break; 1897 1.3 christos } 1898 1.3 christos 1899 1.3 christos if (!p->name) 1900 1.1 skrll { 1901 1.1 skrll error_message = _(": unrecognizable privileged register"); 1902 1.1 skrll goto error; 1903 1.1 skrll } 1904 1.1 skrll 1905 1.1 skrll if (((opcode >> (*args == '?' ? 14 : 25)) & 0x1f) != (unsigned) p->regnum) 1906 1.1 skrll { 1907 1.1 skrll error_message = _(": unrecognizable privileged register"); 1908 1.1 skrll goto error; 1909 1.1 skrll } 1910 1.1 skrll 1911 1.1 skrll s += len; 1912 1.1 skrll continue; 1913 1.1 skrll } 1914 1.3 christos else 1915 1.1 skrll { 1916 1.1 skrll error_message = _(": unrecognizable privileged register"); 1917 1.1 skrll goto error; 1918 1.3 christos } 1919 1.3 christos 1920 1.3 christos case '$': 1921 1.3 christos case '%': 1922 1.3 christos /* Parse a sparc64 hyperprivileged register. */ 1923 1.3 christos if (*s == '%') 1924 1.3 christos { 1925 1.3 christos struct priv_reg_entry *p; 1926 1.3 christos unsigned int len = 9999999; /* Init to make gcc happy. */ 1927 1.1 skrll 1928 1.1 skrll s += 1; 1929 1.1 skrll for (p = hpriv_reg_table; p->name; p++) 1930 1.1 skrll if (p->name[0] == s[0]) 1931 1.3 christos { 1932 1.3 christos len = strlen (p->name); 1933 1.3 christos if (strncmp (p->name, s, len) == 0) 1934 1.3 christos break; 1935 1.3 christos } 1936 1.3 christos 1937 1.3 christos if (!p->name) 1938 1.3 christos { 1939 1.1 skrll error_message = _(": unrecognizable hyperprivileged register"); 1940 1.1 skrll goto error; 1941 1.1 skrll } 1942 1.1 skrll 1943 1.1 skrll if (((opcode >> (*args == '$' ? 14 : 25)) & 0x1f) != (unsigned) p->regnum) 1944 1.1 skrll { 1945 1.1 skrll error_message = _(": unrecognizable hyperprivileged register"); 1946 1.1 skrll goto error; 1947 1.1 skrll } 1948 1.1 skrll 1949 1.3 christos s += len; 1950 1.1 skrll continue; 1951 1.1 skrll } 1952 1.3 christos else 1953 1.1 skrll { 1954 1.1 skrll error_message = _(": unrecognizable hyperprivileged register"); 1955 1.1 skrll goto error; 1956 1.3 christos } 1957 1.3 christos 1958 1.3 christos case '_': 1959 1.3 christos case '/': 1960 1.3 christos /* Parse a v9a or later ancillary state register. */ 1961 1.3 christos if (*s == '%') 1962 1.3 christos { 1963 1.3 christos struct priv_reg_entry *p; 1964 1.3 christos unsigned int len = 9999999; /* Init to make gcc happy. */ 1965 1.1 skrll 1966 1.3 christos s += 1; 1967 1.1 skrll for (p = v9a_asr_table; p->name; p++) 1968 1.1 skrll if (p->name[0] == s[0]) 1969 1.3 christos { 1970 1.3 christos len = strlen (p->name); 1971 1.3 christos if (strncmp (p->name, s, len) == 0) 1972 1.3 christos break; 1973 1.3 christos } 1974 1.3 christos 1975 1.3 christos if (!p->name) 1976 1.1 skrll { 1977 1.1 skrll error_message = _(": unrecognizable ancillary state register"); 1978 1.1 skrll goto error; 1979 1.1 skrll } 1980 1.1 skrll 1981 1.3 christos if (((opcode >> (*args == '/' ? 14 : 25)) & 0x1f) != (unsigned) p->regnum) 1982 1.1 skrll { 1983 1.1 skrll error_message = _(": unrecognizable ancillary state register"); 1984 1.1 skrll goto error; 1985 1.1 skrll } 1986 1.1 skrll 1987 1.7 christos s += len; 1988 1.1 skrll continue; 1989 1.1 skrll } 1990 1.1 skrll else 1991 1.1 skrll { 1992 1.1 skrll error_message = _(": unrecognizable ancillary state register"); 1993 1.1 skrll goto error; 1994 1.1 skrll } 1995 1.1 skrll 1996 1.1 skrll case 'M': 1997 1.1 skrll case 'm': 1998 1.1 skrll if (startswith (s, "%asr")) 1999 1.1 skrll { 2000 1.1 skrll s += 4; 2001 1.3 christos 2002 1.3 christos if (ISDIGIT (*s)) 2003 1.3 christos { 2004 1.3 christos long num = 0; 2005 1.3 christos 2006 1.3 christos while (ISDIGIT (*s)) 2007 1.3 christos { 2008 1.3 christos num = num * 10 + *s - '0'; 2009 1.3 christos ++s; 2010 1.3 christos } 2011 1.3 christos 2012 1.3 christos /* We used to check here for the asr number to 2013 1.3 christos be between 16 and 31 in V9 and later, as 2014 1.3 christos mandated by the section C.1.1 "Register 2015 1.3 christos Names" in the SPARC spec. However, we 2016 1.3 christos decided to remove this restriction as a) it 2017 1.1 skrll introduces problems when new V9 asr registers 2018 1.1 skrll are introduced, b) the Solaris assembler 2019 1.1 skrll doesn't implement this restriction and c) the 2020 1.1 skrll restriction will go away in future revisions 2021 1.1 skrll of the Oracle SPARC Architecture. */ 2022 1.1 skrll 2023 1.1 skrll if (num < 0 || 31 < num) 2024 1.1 skrll { 2025 1.1 skrll error_message = _(": asr number must be between 0 and 31"); 2026 1.1 skrll goto error; 2027 1.1 skrll } 2028 1.1 skrll 2029 1.1 skrll opcode |= (*args == 'M' ? RS1 (num) : RD (num)); 2030 1.1 skrll continue; 2031 1.1 skrll } 2032 1.1 skrll else 2033 1.1 skrll { 2034 1.1 skrll error_message = _(": expecting %asrN"); 2035 1.1 skrll goto error; 2036 1.1 skrll } 2037 1.2 joerg } /* if %asr */ 2038 1.2 joerg break; 2039 1.2 joerg 2040 1.2 joerg case 'I': 2041 1.2 joerg the_insn.reloc = BFD_RELOC_SPARC_11; 2042 1.2 joerg goto immediate; 2043 1.2 joerg 2044 1.2 joerg case 'j': 2045 1.2 joerg the_insn.reloc = BFD_RELOC_SPARC_10; 2046 1.2 joerg goto immediate; 2047 1.2 joerg 2048 1.2 joerg case ')': 2049 1.2 joerg if (*s == ' ') 2050 1.2 joerg s++; 2051 1.2 joerg if ((s[0] == '0' && s[1] == 'x' && ISXDIGIT (s[2])) 2052 1.2 joerg || ISDIGIT (*s)) 2053 1.2 joerg { 2054 1.2 joerg long num = 0; 2055 1.2 joerg 2056 1.2 joerg if (s[0] == '0' && s[1] == 'x') 2057 1.2 joerg { 2058 1.2 joerg s += 2; 2059 1.2 joerg while (ISXDIGIT (*s)) 2060 1.2 joerg { 2061 1.2 joerg num <<= 4; 2062 1.2 joerg num |= hex_value (*s); 2063 1.2 joerg ++s; 2064 1.2 joerg } 2065 1.2 joerg } 2066 1.2 joerg else 2067 1.2 joerg { 2068 1.2 joerg while (ISDIGIT (*s)) 2069 1.2 joerg { 2070 1.2 joerg num = num * 10 + *s - '0'; 2071 1.2 joerg ++s; 2072 1.2 joerg } 2073 1.2 joerg } 2074 1.2 joerg if (num < 0 || num > 31) 2075 1.2 joerg { 2076 1.2 joerg error_message = _(": crypto immediate must be between 0 and 31"); 2077 1.2 joerg goto error; 2078 1.1 skrll } 2079 1.1 skrll 2080 1.1 skrll opcode |= RS3 (num); 2081 1.1 skrll continue; 2082 1.1 skrll } 2083 1.1 skrll else 2084 1.1 skrll { 2085 1.1 skrll error_message = _(": expecting crypto immediate"); 2086 1.1 skrll goto error; 2087 1.1 skrll } 2088 1.1 skrll 2089 1.1 skrll case 'X': 2090 1.1 skrll /* V8 systems don't understand BFD_RELOC_SPARC_5. */ 2091 1.1 skrll if (SPARC_OPCODE_ARCH_V9_P (max_architecture)) 2092 1.1 skrll the_insn.reloc = BFD_RELOC_SPARC_5; 2093 1.1 skrll else 2094 1.1 skrll the_insn.reloc = BFD_RELOC_SPARC13; 2095 1.1 skrll /* These fields are unsigned, but for upward compatibility, 2096 1.1 skrll allow negative values as well. */ 2097 1.1 skrll goto immediate; 2098 1.1 skrll 2099 1.1 skrll case 'Y': 2100 1.1 skrll /* V8 systems don't understand BFD_RELOC_SPARC_6. */ 2101 1.1 skrll if (SPARC_OPCODE_ARCH_V9_P (max_architecture)) 2102 1.1 skrll the_insn.reloc = BFD_RELOC_SPARC_6; 2103 1.2 joerg else 2104 1.2 joerg the_insn.reloc = BFD_RELOC_SPARC13; 2105 1.2 joerg /* These fields are unsigned, but for upward compatibility, 2106 1.2 joerg allow negative values as well. */ 2107 1.2 joerg goto immediate; 2108 1.1 skrll 2109 1.1 skrll case 'k': 2110 1.1 skrll the_insn.reloc = /* RELOC_WDISP2_14 */ BFD_RELOC_SPARC_WDISP16; 2111 1.1 skrll the_insn.pcrel = 1; 2112 1.1 skrll goto immediate; 2113 1.1 skrll 2114 1.1 skrll case '=': 2115 1.1 skrll the_insn.reloc = /* RELOC_WDISP2_8 */ BFD_RELOC_SPARC_WDISP10; 2116 1.1 skrll the_insn.pcrel = 1; 2117 1.1 skrll goto immediate; 2118 1.1 skrll 2119 1.1 skrll case 'G': 2120 1.1 skrll the_insn.reloc = BFD_RELOC_SPARC_WDISP19; 2121 1.1 skrll the_insn.pcrel = 1; 2122 1.1 skrll goto immediate; 2123 1.1 skrll 2124 1.1 skrll case 'N': 2125 1.1 skrll if (*s == 'p' && s[1] == 'n') 2126 1.1 skrll { 2127 1.1 skrll s += 2; 2128 1.1 skrll continue; 2129 1.1 skrll } 2130 1.1 skrll break; 2131 1.1 skrll 2132 1.1 skrll case 'T': 2133 1.1 skrll if (*s == 'p' && s[1] == 't') 2134 1.7 christos { 2135 1.7 christos s += 2; 2136 1.1 skrll continue; 2137 1.1 skrll } 2138 1.1 skrll break; 2139 1.1 skrll 2140 1.1 skrll case 'z': 2141 1.1 skrll if (*s == ' ') 2142 1.1 skrll { 2143 1.1 skrll ++s; 2144 1.1 skrll } 2145 1.1 skrll if ((startswith (s, "%icc")) 2146 1.1 skrll || (sparc_arch_size == 32 && startswith (s, "%ncc"))) 2147 1.7 christos { 2148 1.7 christos s += 4; 2149 1.1 skrll continue; 2150 1.1 skrll } 2151 1.1 skrll break; 2152 1.1 skrll 2153 1.1 skrll case 'Z': 2154 1.1 skrll if (*s == ' ') 2155 1.1 skrll { 2156 1.1 skrll ++s; 2157 1.1 skrll } 2158 1.1 skrll if ((startswith (s, "%xcc")) 2159 1.1 skrll || (sparc_arch_size == 64 && startswith (s, "%ncc"))) 2160 1.7 christos { 2161 1.1 skrll s += 4; 2162 1.1 skrll continue; 2163 1.1 skrll } 2164 1.1 skrll break; 2165 1.1 skrll 2166 1.1 skrll case '6': 2167 1.1 skrll if (*s == ' ') 2168 1.1 skrll { 2169 1.1 skrll ++s; 2170 1.1 skrll } 2171 1.1 skrll if (startswith (s, "%fcc0")) 2172 1.7 christos { 2173 1.1 skrll s += 5; 2174 1.1 skrll continue; 2175 1.1 skrll } 2176 1.1 skrll break; 2177 1.1 skrll 2178 1.1 skrll case '7': 2179 1.1 skrll if (*s == ' ') 2180 1.1 skrll { 2181 1.1 skrll ++s; 2182 1.1 skrll } 2183 1.1 skrll if (startswith (s, "%fcc1")) 2184 1.7 christos { 2185 1.1 skrll s += 5; 2186 1.1 skrll continue; 2187 1.1 skrll } 2188 1.1 skrll break; 2189 1.1 skrll 2190 1.1 skrll case '8': 2191 1.1 skrll if (*s == ' ') 2192 1.1 skrll { 2193 1.1 skrll ++s; 2194 1.1 skrll } 2195 1.1 skrll if (startswith (s, "%fcc2")) 2196 1.7 christos { 2197 1.1 skrll s += 5; 2198 1.1 skrll continue; 2199 1.1 skrll } 2200 1.1 skrll break; 2201 1.1 skrll 2202 1.1 skrll case '9': 2203 1.1 skrll if (*s == ' ') 2204 1.7 christos { 2205 1.1 skrll ++s; 2206 1.1 skrll } 2207 1.1 skrll if (startswith (s, "%fcc3")) 2208 1.1 skrll { 2209 1.1 skrll s += 5; 2210 1.1 skrll continue; 2211 1.1 skrll } 2212 1.7 christos break; 2213 1.1 skrll 2214 1.1 skrll case 'P': 2215 1.1 skrll if (startswith (s, "%pc")) 2216 1.1 skrll { 2217 1.1 skrll s += 3; 2218 1.1 skrll continue; 2219 1.1 skrll } 2220 1.1 skrll break; 2221 1.1 skrll 2222 1.1 skrll case 'W': 2223 1.1 skrll if (startswith (s, "%tick")) 2224 1.3 christos { 2225 1.1 skrll s += 5; 2226 1.3 christos continue; 2227 1.3 christos } 2228 1.3 christos break; 2229 1.3 christos 2230 1.3 christos case '\0': /* End of args. */ 2231 1.3 christos if (s[0] == ',' && s[1] == '%') 2232 1.1 skrll { 2233 1.3 christos char *s1; 2234 1.1 skrll int npar = 0; 2235 1.3 christos const struct perc_entry *p; 2236 1.1 skrll 2237 1.1 skrll for (p = perc_table; p->type != perc_entry_none; p++) 2238 1.1 skrll if ((p->type == perc_entry_post_pop || p->type == perc_entry_reg) 2239 1.3 christos && strncmp (s + 2, p->name, p->len) == 0) 2240 1.3 christos break; 2241 1.1 skrll if (p->type == perc_entry_none || p->type == perc_entry_reg) 2242 1.1 skrll break; 2243 1.3 christos 2244 1.1 skrll if (s[p->len + 2] != '(') 2245 1.1 skrll { 2246 1.1 skrll as_bad (_("Illegal operands: %%%s requires arguments in ()"), p->name); 2247 1.3 christos return special_case; 2248 1.1 skrll } 2249 1.1 skrll 2250 1.1 skrll if (! (p->pop->flags & F_POP_TLS_CALL) 2251 1.1 skrll && the_insn.reloc != BFD_RELOC_NONE) 2252 1.1 skrll { 2253 1.1 skrll as_bad (_("Illegal operands: %%%s cannot be used together with other relocs in the insn ()"), 2254 1.3 christos p->name); 2255 1.1 skrll return special_case; 2256 1.1 skrll } 2257 1.1 skrll 2258 1.3 christos if ((p->pop->flags & F_POP_TLS_CALL) 2259 1.1 skrll && (the_insn.reloc != BFD_RELOC_32_PCREL_S2 2260 1.3 christos || the_insn.exp.X_add_number != 0 2261 1.1 skrll || the_insn.exp.X_add_symbol 2262 1.1 skrll != symbol_find_or_make ("__tls_get_addr"))) 2263 1.1 skrll { 2264 1.1 skrll as_bad (_("Illegal operands: %%%s can be only used with call __tls_get_addr"), 2265 1.1 skrll p->name); 2266 1.1 skrll return special_case; 2267 1.1 skrll } 2268 1.1 skrll 2269 1.1 skrll the_insn.reloc = p->pop->reloc; 2270 1.1 skrll memset (&the_insn.exp, 0, sizeof (the_insn.exp)); 2271 1.1 skrll s += p->len + 3; 2272 1.1 skrll 2273 1.1 skrll for (s1 = s; *s1 && *s1 != ',' && *s1 != ']'; s1++) 2274 1.3 christos if (*s1 == '(') 2275 1.1 skrll npar++; 2276 1.1 skrll else if (*s1 == ')') 2277 1.1 skrll { 2278 1.1 skrll if (!npar) 2279 1.1 skrll break; 2280 1.1 skrll npar--; 2281 1.1 skrll } 2282 1.1 skrll 2283 1.1 skrll if (*s1 != ')') 2284 1.1 skrll { 2285 1.1 skrll as_bad (_("Illegal operands: %%%s requires arguments in ()"), p->name); 2286 1.1 skrll return special_case; 2287 1.1 skrll } 2288 1.1 skrll 2289 1.1 skrll *s1 = '\0'; 2290 1.1 skrll (void) get_expression (s); 2291 1.1 skrll *s1 = ')'; 2292 1.1 skrll s = s1 + 1; 2293 1.1 skrll } 2294 1.1 skrll if (*s == '\0') 2295 1.1 skrll match = 1; 2296 1.1 skrll break; 2297 1.1 skrll 2298 1.1 skrll case '+': 2299 1.1 skrll if (*s == '+') 2300 1.1 skrll { 2301 1.1 skrll ++s; 2302 1.1 skrll continue; 2303 1.1 skrll } 2304 1.1 skrll if (*s == '-') 2305 1.1 skrll { 2306 1.1 skrll continue; 2307 1.1 skrll } 2308 1.1 skrll break; 2309 1.1 skrll 2310 1.1 skrll case '[': /* These must match exactly. */ 2311 1.1 skrll case ']': 2312 1.1 skrll case ',': 2313 1.1 skrll case ' ': 2314 1.1 skrll if (*s++ == *args) 2315 1.1 skrll continue; 2316 1.1 skrll break; 2317 1.1 skrll 2318 1.1 skrll case '#': /* Must be at least one digit. */ 2319 1.7 christos if (ISDIGIT (*s++)) 2320 1.1 skrll { 2321 1.1 skrll while (ISDIGIT (*s)) 2322 1.1 skrll { 2323 1.1 skrll ++s; 2324 1.1 skrll } 2325 1.1 skrll continue; 2326 1.1 skrll } 2327 1.1 skrll break; 2328 1.1 skrll 2329 1.1 skrll case 'C': /* Coprocessor state register. */ 2330 1.1 skrll if (startswith (s, "%csr")) 2331 1.1 skrll { 2332 1.1 skrll s += 4; 2333 1.1 skrll continue; 2334 1.1 skrll } 2335 1.1 skrll break; 2336 1.1 skrll 2337 1.1 skrll case 'b': /* Next operand is a coprocessor register. */ 2338 1.1 skrll case 'c': 2339 1.1 skrll case 'D': 2340 1.1 skrll if (*s++ == '%' && *s++ == 'c' && ISDIGIT (*s)) 2341 1.1 skrll { 2342 1.1 skrll mask = *s++; 2343 1.1 skrll if (ISDIGIT (*s)) 2344 1.1 skrll { 2345 1.1 skrll mask = 10 * (mask - '0') + (*s++ - '0'); 2346 1.1 skrll if (mask >= 32) 2347 1.1 skrll { 2348 1.1 skrll break; 2349 1.1 skrll } 2350 1.1 skrll } 2351 1.1 skrll else 2352 1.1 skrll { 2353 1.1 skrll mask -= '0'; 2354 1.1 skrll } 2355 1.1 skrll switch (*args) 2356 1.1 skrll { 2357 1.1 skrll 2358 1.1 skrll case 'b': 2359 1.1 skrll opcode |= mask << 14; 2360 1.1 skrll continue; 2361 1.1 skrll 2362 1.1 skrll case 'c': 2363 1.1 skrll opcode |= mask; 2364 1.1 skrll continue; 2365 1.1 skrll 2366 1.1 skrll case 'D': 2367 1.1 skrll opcode |= mask << 25; 2368 1.1 skrll continue; 2369 1.1 skrll } 2370 1.1 skrll } 2371 1.1 skrll break; 2372 1.1 skrll 2373 1.1 skrll case 'r': /* next operand must be a register */ 2374 1.1 skrll case 'O': 2375 1.1 skrll case '1': 2376 1.1 skrll case '2': 2377 1.1 skrll case 'd': 2378 1.1 skrll if (*s++ == '%') 2379 1.1 skrll { 2380 1.1 skrll switch (c = *s++) 2381 1.1 skrll { 2382 1.1 skrll 2383 1.1 skrll case 'f': /* frame pointer */ 2384 1.1 skrll if (*s++ == 'p') 2385 1.1 skrll { 2386 1.1 skrll mask = 0x1e; 2387 1.1 skrll break; 2388 1.1 skrll } 2389 1.1 skrll goto error; 2390 1.1 skrll 2391 1.1 skrll case 'g': /* global register */ 2392 1.1 skrll c = *s++; 2393 1.1 skrll if (isoctal (c)) 2394 1.1 skrll { 2395 1.1 skrll mask = c - '0'; 2396 1.1 skrll break; 2397 1.1 skrll } 2398 1.1 skrll goto error; 2399 1.1 skrll 2400 1.1 skrll case 'i': /* in register */ 2401 1.1 skrll c = *s++; 2402 1.1 skrll if (isoctal (c)) 2403 1.1 skrll { 2404 1.1 skrll mask = c - '0' + 24; 2405 1.1 skrll break; 2406 1.1 skrll } 2407 1.1 skrll goto error; 2408 1.1 skrll 2409 1.1 skrll case 'l': /* local register */ 2410 1.1 skrll c = *s++; 2411 1.1 skrll if (isoctal (c)) 2412 1.1 skrll { 2413 1.1 skrll mask = (c - '0' + 16); 2414 1.1 skrll break; 2415 1.1 skrll } 2416 1.1 skrll goto error; 2417 1.1 skrll 2418 1.1 skrll case 'o': /* out register */ 2419 1.1 skrll c = *s++; 2420 1.1 skrll if (isoctal (c)) 2421 1.1 skrll { 2422 1.1 skrll mask = (c - '0' + 8); 2423 1.1 skrll break; 2424 1.1 skrll } 2425 1.1 skrll goto error; 2426 1.1 skrll 2427 1.1 skrll case 's': /* stack pointer */ 2428 1.1 skrll if (*s++ == 'p') 2429 1.1 skrll { 2430 1.1 skrll mask = 0xe; 2431 1.1 skrll break; 2432 1.1 skrll } 2433 1.1 skrll goto error; 2434 1.1 skrll 2435 1.1 skrll case 'r': /* any register */ 2436 1.1 skrll if (!ISDIGIT ((c = *s++))) 2437 1.1 skrll { 2438 1.1 skrll goto error; 2439 1.1 skrll } 2440 1.1 skrll /* FALLTHROUGH */ 2441 1.1 skrll case '0': 2442 1.1 skrll case '1': 2443 1.1 skrll case '2': 2444 1.1 skrll case '3': 2445 1.1 skrll case '4': 2446 1.1 skrll case '5': 2447 1.1 skrll case '6': 2448 1.1 skrll case '7': 2449 1.1 skrll case '8': 2450 1.1 skrll case '9': 2451 1.1 skrll if (ISDIGIT (*s)) 2452 1.1 skrll { 2453 1.1 skrll if ((c = 10 * (c - '0') + (*s++ - '0')) >= 32) 2454 1.1 skrll { 2455 1.1 skrll goto error; 2456 1.1 skrll } 2457 1.1 skrll } 2458 1.1 skrll else 2459 1.1 skrll { 2460 1.1 skrll c -= '0'; 2461 1.1 skrll } 2462 1.1 skrll mask = c; 2463 1.1 skrll break; 2464 1.1 skrll 2465 1.1 skrll default: 2466 1.1 skrll goto error; 2467 1.1 skrll } 2468 1.1 skrll 2469 1.1 skrll if ((mask & ~1) == 2 && sparc_arch_size == 64 2470 1.1 skrll && no_undeclared_regs && ! globals[mask]) 2471 1.1 skrll as_bad (_("detected global register use not covered by .register pseudo-op")); 2472 1.1 skrll 2473 1.1 skrll /* Got the register, now figure out where 2474 1.1 skrll it goes in the opcode. */ 2475 1.1 skrll switch (*args) 2476 1.1 skrll { 2477 1.1 skrll case '1': 2478 1.1 skrll opcode |= mask << 14; 2479 1.1 skrll continue; 2480 1.1 skrll 2481 1.1 skrll case '2': 2482 1.1 skrll opcode |= mask; 2483 1.1 skrll continue; 2484 1.1 skrll 2485 1.1 skrll case 'd': 2486 1.1 skrll opcode |= mask << 25; 2487 1.1 skrll continue; 2488 1.1 skrll 2489 1.1 skrll case 'r': 2490 1.1 skrll opcode |= (mask << 25) | (mask << 14); 2491 1.1 skrll continue; 2492 1.4 christos 2493 1.1 skrll case 'O': 2494 1.1 skrll opcode |= (mask << 25) | (mask << 0); 2495 1.1 skrll continue; 2496 1.1 skrll } 2497 1.4 christos } 2498 1.4 christos break; 2499 1.1 skrll 2500 1.2 joerg case 'e': /* next operand is a floating point register */ 2501 1.2 joerg case 'v': 2502 1.2 joerg case 'V': 2503 1.1 skrll case ';': 2504 1.1 skrll 2505 1.1 skrll case 'f': 2506 1.2 joerg case 'B': 2507 1.4 christos case 'R': 2508 1.1 skrll case ':': 2509 1.1 skrll case '\'': 2510 1.1 skrll 2511 1.1 skrll case '4': 2512 1.3 christos case '5': 2513 1.3 christos 2514 1.3 christos case 'g': 2515 1.1 skrll case 'H': 2516 1.1 skrll case 'J': 2517 1.1 skrll case '}': 2518 1.1 skrll case '^': 2519 1.1 skrll { 2520 1.1 skrll char format; 2521 1.1 skrll 2522 1.1 skrll if (*s++ == '%' 2523 1.1 skrll && ((format = *s) == 'f' 2524 1.2 joerg || format == 'd' 2525 1.3 christos || format == 'q') 2526 1.4 christos && ISDIGIT (*++s)) 2527 1.3 christos { 2528 1.1 skrll for (mask = 0; ISDIGIT (*s); ++s) 2529 1.1 skrll { 2530 1.3 christos mask = 10 * mask + (*s - '0'); 2531 1.1 skrll } /* read the number */ 2532 1.3 christos 2533 1.1 skrll if ((*args == 'v' 2534 1.1 skrll || *args == 'B' 2535 1.1 skrll || *args == '5' 2536 1.3 christos || *args == 'H' 2537 1.3 christos || *args == '\'' 2538 1.1 skrll || format == 'd') 2539 1.1 skrll && (mask & 1)) 2540 1.3 christos { 2541 1.1 skrll /* register must be even numbered */ 2542 1.3 christos break; 2543 1.1 skrll } 2544 1.4 christos 2545 1.4 christos if ((*args == 'V' 2546 1.4 christos || *args == 'R' 2547 1.4 christos || *args == 'J' 2548 1.4 christos || format == 'q') 2549 1.4 christos && (mask & 3)) 2550 1.4 christos { 2551 1.4 christos /* register must be multiple of 4 */ 2552 1.4 christos break; 2553 1.4 christos } 2554 1.4 christos 2555 1.4 christos if ((*args == ':' 2556 1.4 christos || *args == ';' 2557 1.4 christos || *args == '^') 2558 1.4 christos && (mask & 7)) 2559 1.1 skrll { 2560 1.1 skrll /* register must be multiple of 8 */ 2561 1.1 skrll break; 2562 1.1 skrll } 2563 1.1 skrll 2564 1.1 skrll if (*args == '\'' && mask < 48) 2565 1.1 skrll { 2566 1.1 skrll /* register must be higher or equal than %f48 */ 2567 1.1 skrll break; 2568 1.1 skrll } 2569 1.1 skrll 2570 1.1 skrll if (mask >= 64) 2571 1.1 skrll { 2572 1.1 skrll if (SPARC_OPCODE_ARCH_V9_P (max_architecture)) 2573 1.1 skrll error_message = _(": There are only 64 f registers; [0-63]"); 2574 1.1 skrll else 2575 1.1 skrll error_message = _(": There are only 32 f registers; [0-31]"); 2576 1.1 skrll goto error; 2577 1.1 skrll } /* on error */ 2578 1.1 skrll else if (mask >= 32) 2579 1.1 skrll { 2580 1.1 skrll if (SPARC_OPCODE_ARCH_V9_P (max_architecture)) 2581 1.1 skrll { 2582 1.1 skrll if (*args == 'e' || *args == 'f' || *args == 'g') 2583 1.1 skrll { 2584 1.1 skrll error_message 2585 1.1 skrll = _(": There are only 32 single precision f registers; [0-31]"); 2586 1.1 skrll goto error; 2587 1.1 skrll } 2588 1.1 skrll v9_arg_p = 1; 2589 1.1 skrll mask -= 31; /* wrap high bit */ 2590 1.1 skrll } 2591 1.1 skrll else 2592 1.2 joerg { 2593 1.2 joerg error_message = _(": There are only 32 f registers; [0-31]"); 2594 1.2 joerg goto error; 2595 1.2 joerg } 2596 1.2 joerg } 2597 1.2 joerg } 2598 1.2 joerg else 2599 1.1 skrll { 2600 1.1 skrll break; 2601 1.1 skrll } /* if not an 'f' register. */ 2602 1.1 skrll 2603 1.1 skrll if (*args == '}' && mask != RS2 (opcode)) 2604 1.4 christos { 2605 1.1 skrll error_message 2606 1.1 skrll = _(": Instruction requires frs2 and frsd must be the same register"); 2607 1.1 skrll goto error; 2608 1.1 skrll } 2609 1.1 skrll 2610 1.1 skrll switch (*args) 2611 1.4 christos { 2612 1.1 skrll case 'v': 2613 1.1 skrll case 'V': 2614 1.1 skrll case 'e': 2615 1.4 christos case ';': 2616 1.4 christos opcode |= RS1 (mask); 2617 1.4 christos continue; 2618 1.4 christos 2619 1.2 joerg case 'f': 2620 1.2 joerg case 'B': 2621 1.2 joerg case 'R': 2622 1.2 joerg case ':': 2623 1.2 joerg opcode |= RS2 (mask); 2624 1.1 skrll continue; 2625 1.1 skrll 2626 1.1 skrll case '\'': 2627 1.2 joerg opcode |= RS2 (mask & 0xe); 2628 1.4 christos continue; 2629 1.1 skrll 2630 1.1 skrll case '4': 2631 1.1 skrll case '5': 2632 1.1 skrll opcode |= RS3 (mask); 2633 1.1 skrll continue; 2634 1.1 skrll 2635 1.1 skrll case 'g': 2636 1.1 skrll case 'H': 2637 1.1 skrll case 'J': 2638 1.7 christos case '}': 2639 1.1 skrll case '^': 2640 1.1 skrll opcode |= RD (mask); 2641 1.1 skrll continue; 2642 1.1 skrll } /* Pack it in. */ 2643 1.1 skrll 2644 1.1 skrll know (0); 2645 1.2 joerg break; 2646 1.7 christos } /* float arg */ 2647 1.2 joerg 2648 1.2 joerg case 'F': 2649 1.2 joerg if (startswith (s, "%fsr")) 2650 1.2 joerg { 2651 1.2 joerg s += 4; 2652 1.2 joerg continue; 2653 1.1 skrll } 2654 1.1 skrll break; 2655 1.1 skrll 2656 1.1 skrll case '(': 2657 1.1 skrll if (startswith (s, "%efsr")) 2658 1.1 skrll { 2659 1.1 skrll s += 5; 2660 1.1 skrll continue; 2661 1.1 skrll } 2662 1.1 skrll break; 2663 1.1 skrll 2664 1.1 skrll case '0': /* 64 bit immediate (set, setsw, setx insn) */ 2665 1.1 skrll the_insn.reloc = BFD_RELOC_NONE; /* reloc handled elsewhere */ 2666 1.1 skrll goto immediate; 2667 1.1 skrll 2668 1.1 skrll case 'l': /* 22 bit PC relative immediate */ 2669 1.1 skrll the_insn.reloc = BFD_RELOC_SPARC_WDISP22; 2670 1.1 skrll the_insn.pcrel = 1; 2671 1.1 skrll goto immediate; 2672 1.1 skrll 2673 1.1 skrll case 'L': /* 30 bit immediate */ 2674 1.1 skrll the_insn.reloc = BFD_RELOC_32_PCREL_S2; 2675 1.1 skrll the_insn.pcrel = 1; 2676 1.1 skrll goto immediate; 2677 1.1 skrll 2678 1.1 skrll case 'h': 2679 1.1 skrll case 'n': /* 22 bit immediate */ 2680 1.1 skrll the_insn.reloc = BFD_RELOC_SPARC22; 2681 1.1 skrll goto immediate; 2682 1.1 skrll 2683 1.3 christos case 'i': /* 13 bit immediate */ 2684 1.1 skrll the_insn.reloc = BFD_RELOC_SPARC13; 2685 1.1 skrll 2686 1.1 skrll /* fallthrough */ 2687 1.1 skrll 2688 1.1 skrll immediate: 2689 1.1 skrll if (*s == ' ') 2690 1.3 christos s++; 2691 1.3 christos 2692 1.3 christos { 2693 1.3 christos char *s1; 2694 1.3 christos const char *op_arg = NULL; 2695 1.3 christos static expressionS op_exp; 2696 1.3 christos bfd_reloc_code_real_type old_reloc = the_insn.reloc; 2697 1.3 christos 2698 1.1 skrll /* Check for %hi, etc. */ 2699 1.3 christos if (*s == '%') 2700 1.1 skrll { 2701 1.3 christos const struct perc_entry *p; 2702 1.1 skrll 2703 1.1 skrll for (p = perc_table; p->type != perc_entry_none; p++) 2704 1.1 skrll if ((p->type == perc_entry_imm_pop || p->type == perc_entry_reg) 2705 1.3 christos && strncmp (s + 1, p->name, p->len) == 0) 2706 1.3 christos break; 2707 1.3 christos if (p->type == perc_entry_none || p->type == perc_entry_reg) 2708 1.3 christos break; 2709 1.1 skrll 2710 1.1 skrll if (s[p->len + 1] != '(') 2711 1.1 skrll { 2712 1.1 skrll as_bad (_("Illegal operands: %%%s requires arguments in ()"), p->name); 2713 1.1 skrll return special_case; 2714 1.1 skrll } 2715 1.1 skrll 2716 1.1 skrll op_arg = p->name; 2717 1.1 skrll the_insn.reloc = p->pop->reloc; 2718 1.1 skrll s += p->len + 2; 2719 1.1 skrll v9_arg_p = p->pop->flags & F_POP_V9; 2720 1.1 skrll } 2721 1.1 skrll 2722 1.1 skrll /* Note that if the get_expression() fails, we will still 2723 1.1 skrll have created U entries in the symbol table for the 2724 1.1 skrll 'symbols' in the input string. Try not to create U 2725 1.1 skrll symbols for registers, etc. */ 2726 1.1 skrll 2727 1.1 skrll /* This stuff checks to see if the expression ends in 2728 1.1 skrll +%reg. If it does, it removes the register from 2729 1.1 skrll the expression, and re-sets 's' to point to the 2730 1.1 skrll right place. */ 2731 1.1 skrll 2732 1.1 skrll if (op_arg) 2733 1.1 skrll { 2734 1.1 skrll int npar = 0; 2735 1.1 skrll 2736 1.1 skrll for (s1 = s; *s1 && *s1 != ',' && *s1 != ']'; s1++) 2737 1.1 skrll if (*s1 == '(') 2738 1.1 skrll npar++; 2739 1.1 skrll else if (*s1 == ')') 2740 1.1 skrll { 2741 1.1 skrll if (!npar) 2742 1.1 skrll break; 2743 1.1 skrll npar--; 2744 1.3 christos } 2745 1.3 christos 2746 1.3 christos if (*s1 != ')') 2747 1.3 christos { 2748 1.3 christos as_bad (_("Illegal operands: %%%s requires arguments in ()"), op_arg); 2749 1.1 skrll return special_case; 2750 1.1 skrll } 2751 1.1 skrll 2752 1.1 skrll *s1 = '\0'; 2753 1.1 skrll (void) get_expression (s); 2754 1.1 skrll *s1 = ')'; 2755 1.1 skrll if (expr_end != s1) 2756 1.1 skrll { 2757 1.1 skrll as_bad (_("Expression inside %%%s could not be parsed"), op_arg); 2758 1.1 skrll return special_case; 2759 1.1 skrll } 2760 1.1 skrll s = s1 + 1; 2761 1.1 skrll if (*s == ',' || *s == ']' || !*s) 2762 1.1 skrll continue; 2763 1.1 skrll if (*s != '+' && *s != '-') 2764 1.1 skrll { 2765 1.1 skrll as_bad (_("Illegal operands: Can't do arithmetics other than + and - involving %%%s()"), op_arg); 2766 1.1 skrll return special_case; 2767 1.1 skrll } 2768 1.1 skrll *s1 = '0'; 2769 1.1 skrll s = s1; 2770 1.2 joerg op_exp = the_insn.exp; 2771 1.1 skrll memset (&the_insn.exp, 0, sizeof (the_insn.exp)); 2772 1.2 joerg } 2773 1.2 joerg 2774 1.1 skrll for (s1 = s; *s1 && *s1 != ',' && *s1 != ']'; s1++) 2775 1.1 skrll ; 2776 1.1 skrll 2777 1.1 skrll if (s1 != s && ISDIGIT (s1[-1])) 2778 1.1 skrll { 2779 1.1 skrll if (s1[-2] == '%' && s1[-3] == '+') 2780 1.1 skrll s1 -= 3; 2781 1.1 skrll else if (strchr ("golir0123456789", s1[-2]) && s1[-3] == '%' && s1[-4] == '+') 2782 1.1 skrll s1 -= 4; 2783 1.1 skrll else if (s1[-3] == 'r' && s1[-4] == '%' && s1[-5] == '+') 2784 1.1 skrll s1 -= 5; 2785 1.1 skrll else 2786 1.1 skrll s1 = NULL; 2787 1.1 skrll if (s1) 2788 1.1 skrll { 2789 1.1 skrll *s1 = '\0'; 2790 1.1 skrll if (op_arg && s1 == s + 1) 2791 1.1 skrll the_insn.exp.X_op = O_absent; 2792 1.1 skrll else 2793 1.1 skrll (void) get_expression (s); 2794 1.1 skrll *s1 = '+'; 2795 1.1 skrll if (op_arg) 2796 1.1 skrll *s = ')'; 2797 1.1 skrll s = s1; 2798 1.1 skrll } 2799 1.1 skrll } 2800 1.1 skrll else 2801 1.1 skrll s1 = NULL; 2802 1.1 skrll 2803 1.1 skrll if (!s1) 2804 1.1 skrll { 2805 1.1 skrll (void) get_expression (s); 2806 1.1 skrll if (op_arg) 2807 1.1 skrll *s = ')'; 2808 1.1 skrll s = expr_end; 2809 1.1 skrll } 2810 1.1 skrll 2811 1.1 skrll if (op_arg) 2812 1.1 skrll { 2813 1.1 skrll the_insn.exp2 = the_insn.exp; 2814 1.1 skrll the_insn.exp = op_exp; 2815 1.1 skrll if (the_insn.exp2.X_op == O_absent) 2816 1.1 skrll the_insn.exp2.X_op = O_illegal; 2817 1.1 skrll else if (the_insn.exp.X_op == O_absent) 2818 1.1 skrll { 2819 1.1 skrll the_insn.exp = the_insn.exp2; 2820 1.1 skrll the_insn.exp2.X_op = O_illegal; 2821 1.1 skrll } 2822 1.1 skrll else if (the_insn.exp.X_op == O_constant) 2823 1.1 skrll { 2824 1.1 skrll valueT val = the_insn.exp.X_add_number; 2825 1.1 skrll switch (the_insn.reloc) 2826 1.1 skrll { 2827 1.1 skrll default: 2828 1.1 skrll break; 2829 1.1 skrll 2830 1.1 skrll case BFD_RELOC_SPARC_HH22: 2831 1.1 skrll val = BSR (val, 32); 2832 1.1 skrll /* Fall through. */ 2833 1.1 skrll 2834 1.1 skrll case BFD_RELOC_SPARC_LM22: 2835 1.1 skrll case BFD_RELOC_HI22: 2836 1.2 joerg val = (val >> 10) & 0x3fffff; 2837 1.2 joerg break; 2838 1.2 joerg 2839 1.2 joerg case BFD_RELOC_SPARC_HM10: 2840 1.2 joerg val = BSR (val, 32); 2841 1.1 skrll /* Fall through. */ 2842 1.1 skrll 2843 1.1 skrll case BFD_RELOC_LO10: 2844 1.1 skrll val &= 0x3ff; 2845 1.1 skrll break; 2846 1.1 skrll 2847 1.1 skrll case BFD_RELOC_SPARC_H34: 2848 1.1 skrll val >>= 12; 2849 1.1 skrll val &= 0x3fffff; 2850 1.1 skrll break; 2851 1.1 skrll 2852 1.1 skrll case BFD_RELOC_SPARC_H44: 2853 1.1 skrll val >>= 22; 2854 1.1 skrll val &= 0x3fffff; 2855 1.1 skrll break; 2856 1.1 skrll 2857 1.1 skrll case BFD_RELOC_SPARC_M44: 2858 1.1 skrll val >>= 12; 2859 1.1 skrll val &= 0x3ff; 2860 1.1 skrll break; 2861 1.1 skrll 2862 1.1 skrll case BFD_RELOC_SPARC_L44: 2863 1.1 skrll val &= 0xfff; 2864 1.1 skrll break; 2865 1.1 skrll 2866 1.1 skrll case BFD_RELOC_SPARC_HIX22: 2867 1.1 skrll val = ~val; 2868 1.1 skrll val = (val >> 10) & 0x3fffff; 2869 1.1 skrll break; 2870 1.1 skrll 2871 1.1 skrll case BFD_RELOC_SPARC_LOX10: 2872 1.1 skrll val = (val & 0x3ff) | 0x1c00; 2873 1.1 skrll break; 2874 1.1 skrll } 2875 1.1 skrll the_insn.exp = the_insn.exp2; 2876 1.1 skrll the_insn.exp.X_add_number += val; 2877 1.1 skrll the_insn.exp2.X_op = O_illegal; 2878 1.1 skrll the_insn.reloc = old_reloc; 2879 1.1 skrll } 2880 1.1 skrll else if (the_insn.exp2.X_op != O_constant) 2881 1.1 skrll { 2882 1.1 skrll as_bad (_("Illegal operands: Can't add non-constant expression to %%%s()"), op_arg); 2883 1.1 skrll return special_case; 2884 1.1 skrll } 2885 1.1 skrll else 2886 1.1 skrll { 2887 1.1 skrll if (old_reloc != BFD_RELOC_SPARC13 2888 1.1 skrll || the_insn.reloc != BFD_RELOC_LO10 2889 1.1 skrll || sparc_arch_size != 64 2890 1.1 skrll || sparc_pic_code) 2891 1.1 skrll { 2892 1.1 skrll as_bad (_("Illegal operands: Can't do arithmetics involving %%%s() of a relocatable symbol"), op_arg); 2893 1.1 skrll return special_case; 2894 1.1 skrll } 2895 1.1 skrll the_insn.reloc = BFD_RELOC_SPARC_OLO10; 2896 1.1 skrll } 2897 1.1 skrll } 2898 1.1 skrll } 2899 1.1 skrll /* Check for constants that don't require emitting a reloc. */ 2900 1.1 skrll if (the_insn.exp.X_op == O_constant 2901 1.1 skrll && the_insn.exp.X_add_symbol == 0 2902 1.1 skrll && the_insn.exp.X_op_symbol == 0) 2903 1.1 skrll { 2904 1.1 skrll /* For pc-relative call instructions, we reject 2905 1.1 skrll constants to get better code. */ 2906 1.1 skrll if (the_insn.pcrel 2907 1.1 skrll && the_insn.reloc == BFD_RELOC_32_PCREL_S2 2908 1.1 skrll && in_signed_range (the_insn.exp.X_add_number, 0x3fff)) 2909 1.1 skrll { 2910 1.1 skrll error_message = _(": PC-relative operand can't be a constant"); 2911 1.1 skrll goto error; 2912 1.1 skrll } 2913 1.1 skrll 2914 1.1 skrll if (the_insn.reloc >= BFD_RELOC_SPARC_TLS_GD_HI22 2915 1.1 skrll && the_insn.reloc <= BFD_RELOC_SPARC_TLS_TPOFF64) 2916 1.1 skrll { 2917 1.1 skrll error_message = _(": TLS operand can't be a constant"); 2918 1.2 joerg goto error; 2919 1.2 joerg } 2920 1.2 joerg 2921 1.2 joerg /* Constants that won't fit are checked in md_apply_fix 2922 1.2 joerg and bfd_install_relocation. 2923 1.2 joerg ??? It would be preferable to install the constants 2924 1.2 joerg into the insn here and save having to create a fixS 2925 1.2 joerg for each one. There already exists code to handle 2926 1.4 christos all the various cases (e.g. in md_apply_fix and 2927 1.4 christos bfd_install_relocation) so duplicating all that code 2928 1.2 joerg here isn't right. */ 2929 1.2 joerg 2930 1.2 joerg /* This is a special case to handle cbcond instructions 2931 1.4 christos properly, which can need two relocations. The first 2932 1.2 joerg one is for the 5-bit immediate field and the latter 2933 1.2 joerg is going to be for the WDISP10 branch part. We 2934 1.2 joerg handle the R_SPARC_5 immediate directly here so that 2935 1.2 joerg we don't need to add support for multiple relocations 2936 1.2 joerg in one instruction just yet. */ 2937 1.2 joerg if (the_insn.reloc == BFD_RELOC_SPARC_5 2938 1.2 joerg && ((insn->match & OP(0x3)) == 0)) 2939 1.1 skrll { 2940 1.1 skrll valueT val = the_insn.exp.X_add_number; 2941 1.1 skrll 2942 1.1 skrll the_insn.reloc = BFD_RELOC_NONE; 2943 1.1 skrll if (! in_bitfield_range (val, 0x1f)) 2944 1.1 skrll { 2945 1.1 skrll error_message = _(": Immediate value in cbcond is out of range."); 2946 1.1 skrll goto error; 2947 1.1 skrll } 2948 1.1 skrll opcode |= val & 0x1f; 2949 1.1 skrll } 2950 1.1 skrll } 2951 1.1 skrll 2952 1.1 skrll continue; 2953 1.1 skrll 2954 1.1 skrll case 'a': 2955 1.1 skrll if (*s++ == 'a') 2956 1.1 skrll { 2957 1.1 skrll opcode |= ANNUL; 2958 1.4 christos continue; 2959 1.1 skrll } 2960 1.1 skrll break; 2961 1.1 skrll 2962 1.1 skrll case 'A': 2963 1.4 christos { 2964 1.1 skrll int asi = 0; 2965 1.1 skrll 2966 1.1 skrll /* Parse an asi. */ 2967 1.1 skrll if (*s == '#') 2968 1.1 skrll { 2969 1.1 skrll if (! parse_sparc_asi (&s, &sasi)) 2970 1.1 skrll { 2971 1.1 skrll error_message = _(": invalid ASI name"); 2972 1.1 skrll goto error; 2973 1.1 skrll } 2974 1.1 skrll asi = sasi->value; 2975 1.1 skrll } 2976 1.1 skrll else 2977 1.1 skrll { 2978 1.1 skrll if (! parse_const_expr_arg (&s, &asi)) 2979 1.1 skrll { 2980 1.1 skrll error_message = _(": invalid ASI expression"); 2981 1.1 skrll goto error; 2982 1.1 skrll } 2983 1.7 christos if (asi < 0 || asi > 255) 2984 1.1 skrll { 2985 1.1 skrll error_message = _(": invalid ASI number"); 2986 1.1 skrll goto error; 2987 1.1 skrll } 2988 1.1 skrll } 2989 1.1 skrll opcode |= ASI (asi); 2990 1.1 skrll continue; 2991 1.7 christos } /* Alternate space. */ 2992 1.1 skrll 2993 1.1 skrll case 'p': 2994 1.1 skrll if (startswith (s, "%psr")) 2995 1.1 skrll { 2996 1.1 skrll s += 4; 2997 1.1 skrll continue; 2998 1.1 skrll } 2999 1.7 christos break; 3000 1.1 skrll 3001 1.1 skrll case 'q': /* Floating point queue. */ 3002 1.1 skrll if (startswith (s, "%fq")) 3003 1.1 skrll { 3004 1.1 skrll s += 3; 3005 1.1 skrll continue; 3006 1.1 skrll } 3007 1.1 skrll break; 3008 1.1 skrll 3009 1.1 skrll case 'Q': /* Coprocessor queue. */ 3010 1.1 skrll if (startswith (s, "%cq")) 3011 1.1 skrll { 3012 1.1 skrll s += 3; 3013 1.1 skrll continue; 3014 1.1 skrll } 3015 1.1 skrll break; 3016 1.1 skrll 3017 1.1 skrll case 'S': 3018 1.1 skrll if (strcmp (str, "set") == 0 3019 1.1 skrll || strcmp (str, "setuw") == 0) 3020 1.1 skrll { 3021 1.1 skrll special_case = SPECIAL_CASE_SET; 3022 1.1 skrll continue; 3023 1.7 christos } 3024 1.1 skrll else if (strcmp (str, "setsw") == 0) 3025 1.1 skrll { 3026 1.1 skrll special_case = SPECIAL_CASE_SETSW; 3027 1.1 skrll continue; 3028 1.1 skrll } 3029 1.1 skrll else if (strcmp (str, "setx") == 0) 3030 1.1 skrll { 3031 1.7 christos special_case = SPECIAL_CASE_SETX; 3032 1.1 skrll continue; 3033 1.1 skrll } 3034 1.1 skrll else if (startswith (str, "fdiv")) 3035 1.1 skrll { 3036 1.1 skrll special_case = SPECIAL_CASE_FDIV; 3037 1.7 christos continue; 3038 1.1 skrll } 3039 1.1 skrll break; 3040 1.1 skrll 3041 1.1 skrll case 'o': 3042 1.2 joerg if (!startswith (s, "%asi")) 3043 1.7 christos break; 3044 1.2 joerg s += 4; 3045 1.2 joerg continue; 3046 1.2 joerg 3047 1.2 joerg case 's': 3048 1.4 christos if (!startswith (s, "%fprs")) 3049 1.7 christos break; 3050 1.4 christos s += 5; 3051 1.4 christos continue; 3052 1.4 christos 3053 1.4 christos case '{': 3054 1.1 skrll if (!startswith (s, "%mcdper")) 3055 1.7 christos break; 3056 1.1 skrll s += 7; 3057 1.1 skrll continue; 3058 1.1 skrll 3059 1.1 skrll case '&': 3060 1.1 skrll if (!startswith (s, "%entropy")) 3061 1.7 christos break; 3062 1.1 skrll s += 8; 3063 1.1 skrll continue; 3064 1.1 skrll 3065 1.1 skrll case 'E': 3066 1.1 skrll if (!startswith (s, "%ccr")) 3067 1.7 christos break; 3068 1.1 skrll s += 4; 3069 1.1 skrll continue; 3070 1.1 skrll 3071 1.1 skrll case 't': 3072 1.4 christos if (!startswith (s, "%tbr")) 3073 1.4 christos break; 3074 1.4 christos s += 4; 3075 1.4 christos continue; 3076 1.4 christos 3077 1.4 christos case 'w': 3078 1.4 christos if (!startswith (s, "%wim")) 3079 1.4 christos break; 3080 1.4 christos s += 4; 3081 1.4 christos continue; 3082 1.4 christos 3083 1.4 christos case '|': 3084 1.4 christos { 3085 1.4 christos int imm2 = 0; 3086 1.4 christos 3087 1.4 christos /* Parse a 2-bit immediate. */ 3088 1.4 christos if (! parse_const_expr_arg (&s, &imm2)) 3089 1.4 christos { 3090 1.4 christos error_message = _(": non-immdiate imm2 operand"); 3091 1.4 christos goto error; 3092 1.1 skrll } 3093 1.1 skrll if ((imm2 & ~0x3) != 0) 3094 1.1 skrll { 3095 1.1 skrll error_message = _(": imm2 immediate operand out of range (0-3)"); 3096 1.1 skrll goto error; 3097 1.1 skrll } 3098 1.1 skrll 3099 1.1 skrll opcode |= ((imm2 & 0x2) << 3) | (imm2 & 0x1); 3100 1.1 skrll continue; 3101 1.1 skrll } 3102 1.1 skrll 3103 1.1 skrll case 'x': 3104 1.1 skrll { 3105 1.1 skrll char *push = input_line_pointer; 3106 1.1 skrll expressionS e; 3107 1.1 skrll 3108 1.1 skrll input_line_pointer = s; 3109 1.1 skrll expression (&e); 3110 1.1 skrll if (e.X_op == O_constant) 3111 1.1 skrll { 3112 1.1 skrll int n = e.X_add_number; 3113 1.1 skrll if (n != e.X_add_number || (n & ~0x1ff) != 0) 3114 1.1 skrll as_bad (_("OPF immediate operand out of range (0-0x1ff)")); 3115 1.7 christos else 3116 1.1 skrll opcode |= e.X_add_number << 5; 3117 1.1 skrll } 3118 1.1 skrll else 3119 1.1 skrll as_bad (_("non-immediate OPF operand, ignored")); 3120 1.1 skrll s = input_line_pointer; 3121 1.1 skrll input_line_pointer = push; 3122 1.1 skrll continue; 3123 1.1 skrll } 3124 1.1 skrll 3125 1.1 skrll case 'y': 3126 1.1 skrll if (!startswith (s, "%y")) 3127 1.1 skrll break; 3128 1.1 skrll s += 2; 3129 1.1 skrll continue; 3130 1.1 skrll 3131 1.1 skrll case 'u': 3132 1.1 skrll case 'U': 3133 1.1 skrll { 3134 1.1 skrll /* Parse a sparclet cpreg. */ 3135 1.1 skrll int cpreg; 3136 1.1 skrll if (! parse_keyword_arg (sparc_encode_sparclet_cpreg, &s, &cpreg)) 3137 1.1 skrll { 3138 1.1 skrll error_message = _(": invalid cpreg name"); 3139 1.1 skrll goto error; 3140 1.1 skrll } 3141 1.1 skrll opcode |= (*args == 'U' ? RS1 (cpreg) : RD (cpreg)); 3142 1.1 skrll continue; 3143 1.1 skrll } 3144 1.1 skrll 3145 1.1 skrll default: 3146 1.1 skrll as_fatal (_("failed sanity check.")); 3147 1.1 skrll } /* switch on arg code. */ 3148 1.1 skrll 3149 1.1 skrll /* Break out of for() loop. */ 3150 1.1 skrll break; 3151 1.1 skrll } /* For each arg that we expect. */ 3152 1.1 skrll 3153 1.1 skrll error: 3154 1.1 skrll if (match == 0) 3155 1.1 skrll { 3156 1.1 skrll /* Args don't match. */ 3157 1.1 skrll if (&insn[1] - sparc_opcodes < sparc_num_opcodes 3158 1.1 skrll && (insn->name == insn[1].name 3159 1.1 skrll || !strcmp (insn->name, insn[1].name))) 3160 1.1 skrll { 3161 1.1 skrll ++insn; 3162 1.1 skrll s = argsStart; 3163 1.4 christos continue; 3164 1.4 christos } 3165 1.1 skrll else 3166 1.4 christos { 3167 1.4 christos as_bad (_("Illegal operands%s"), error_message); 3168 1.4 christos return special_case; 3169 1.4 christos } 3170 1.4 christos } 3171 1.4 christos else 3172 1.4 christos { 3173 1.4 christos /* We have a match. Now see if the architecture is OK. */ 3174 1.7 christos /* String to use in case of architecture warning. */ 3175 1.1 skrll const char *msg_str = str; 3176 1.5 christos int needed_arch_mask = insn->architecture; 3177 1.2 joerg 3178 1.2 joerg /* Include the ASI architecture needed as well */ 3179 1.2 joerg if (sasi && needed_arch_mask > sasi->architecture) 3180 1.1 skrll { 3181 1.1 skrll needed_arch_mask = sasi->architecture; 3182 1.1 skrll msg_str = sasi->name; 3183 1.1 skrll } 3184 1.1 skrll 3185 1.1 skrll uint64_t hwcaps = ((uint64_t) insn->hwcaps2 << 32) | insn->hwcaps; 3186 1.1 skrll 3187 1.1 skrll #ifndef TE_SOLARIS 3188 1.1 skrll if (hwcaps) 3189 1.1 skrll hwcap_seen |= hwcaps; 3190 1.1 skrll #endif 3191 1.1 skrll if (v9_arg_p) 3192 1.1 skrll { 3193 1.1 skrll needed_arch_mask &= 3194 1.1 skrll ~(SPARC_OPCODE_ARCH_MASK (SPARC_OPCODE_ARCH_V9) - 1); 3195 1.1 skrll if (! needed_arch_mask) 3196 1.1 skrll needed_arch_mask = 3197 1.1 skrll SPARC_OPCODE_ARCH_MASK (SPARC_OPCODE_ARCH_V9); 3198 1.1 skrll } 3199 1.1 skrll 3200 1.1 skrll if (needed_arch_mask 3201 1.2 joerg & SPARC_OPCODE_SUPPORTED (current_architecture)) 3202 1.1 skrll /* OK. */ 3203 1.1 skrll ; 3204 1.1 skrll /* Can we bump up the architecture? */ 3205 1.1 skrll else if (needed_arch_mask 3206 1.1 skrll & SPARC_OPCODE_SUPPORTED (max_architecture)) 3207 1.1 skrll { 3208 1.4 christos enum sparc_opcode_arch_val needed_architecture = 3209 1.1 skrll sparc_ffs (SPARC_OPCODE_SUPPORTED (max_architecture) 3210 1.1 skrll & needed_arch_mask); 3211 1.1 skrll 3212 1.4 christos gas_assert (needed_architecture <= SPARC_OPCODE_ARCH_MAX); 3213 1.7 christos if (warn_on_bump 3214 1.7 christos && needed_architecture > warn_after_architecture) 3215 1.7 christos { 3216 1.7 christos as_warn (_("architecture bumped from \"%s\" to \"%s\" on \"%s\""), 3217 1.1 skrll sparc_opcode_archs[current_architecture].name, 3218 1.1 skrll sparc_opcode_archs[needed_architecture].name, 3219 1.1 skrll msg_str); 3220 1.1 skrll warn_after_architecture = needed_architecture; 3221 1.1 skrll } 3222 1.1 skrll current_architecture = needed_architecture; 3223 1.1 skrll hwcap_allowed 3224 1.1 skrll = (hwcap_allowed 3225 1.1 skrll | hwcaps 3226 1.1 skrll | ((uint64_t) sparc_opcode_archs[current_architecture].hwcaps2 << 32) 3227 1.1 skrll | sparc_opcode_archs[current_architecture].hwcaps); 3228 1.1 skrll } 3229 1.1 skrll /* Conflict. */ 3230 1.1 skrll /* ??? This seems to be a bit fragile. What if the next entry in 3231 1.1 skrll the opcode table is the one we want and it is supported? 3232 1.1 skrll It is possible to arrange the table today so that this can't 3233 1.1 skrll happen but what about tomorrow? */ 3234 1.1 skrll else 3235 1.1 skrll { 3236 1.1 skrll int arch, printed_one_p = 0; 3237 1.1 skrll char *p; 3238 1.1 skrll char required_archs[SPARC_OPCODE_ARCH_MAX * 16]; 3239 1.1 skrll 3240 1.1 skrll /* Create a list of the architectures that support the insn. */ 3241 1.1 skrll needed_arch_mask &= ~SPARC_OPCODE_SUPPORTED (max_architecture); 3242 1.1 skrll p = required_archs; 3243 1.1 skrll arch = sparc_ffs (needed_arch_mask); 3244 1.1 skrll while ((1 << arch) <= needed_arch_mask) 3245 1.1 skrll { 3246 1.4 christos if ((1 << arch) & needed_arch_mask) 3247 1.4 christos { 3248 1.1 skrll if (printed_one_p) 3249 1.1 skrll *p++ = '|'; 3250 1.1 skrll strcpy (p, sparc_opcode_archs[arch].name); 3251 1.1 skrll p += strlen (p); 3252 1.2 joerg printed_one_p = 1; 3253 1.2 joerg } 3254 1.2 joerg ++arch; 3255 1.2 joerg } 3256 1.2 joerg 3257 1.2 joerg as_bad (_("Architecture mismatch on \"%s %s\"."), str, argsStart); 3258 1.2 joerg as_tsktsk (_("(Requires %s; requested architecture is %s.)"), 3259 1.2 joerg required_archs, 3260 1.2 joerg sparc_opcode_archs[max_architecture].name); 3261 1.2 joerg return special_case; 3262 1.2 joerg } 3263 1.1 skrll 3264 1.1 skrll /* Make sure the hwcaps used by the instruction are 3265 1.1 skrll currently enabled. */ 3266 1.1 skrll if (hwcaps & ~hwcap_allowed) 3267 1.1 skrll { 3268 1.1 skrll const char *hwcap_name = get_hwcap_name(hwcaps & ~hwcap_allowed); 3269 1.1 skrll 3270 1.1 skrll as_bad (_("Hardware capability \"%s\" not enabled for \"%s\"."), 3271 1.1 skrll hwcap_name, str); 3272 1.4 christos return special_case; 3273 1.4 christos } 3274 1.4 christos } /* If no match. */ 3275 1.4 christos 3276 1.4 christos break; 3277 1.4 christos } /* Forever looking for a match. */ 3278 1.4 christos 3279 1.4 christos the_insn.opcode = opcode; 3280 1.4 christos return special_case; 3281 1.4 christos } 3282 1.4 christos 3283 1.4 christos static char * 3284 1.4 christos skip_over_keyword (char *q) 3285 1.4 christos { 3286 1.4 christos for (q = q + (*q == '#' || *q == '%'); 3287 1.4 christos ISALNUM (*q) || *q == '_'; 3288 1.4 christos ++q) 3289 1.4 christos continue; 3290 1.4 christos return q; 3291 1.4 christos } 3292 1.4 christos 3293 1.4 christos static int 3294 1.4 christos parse_sparc_asi (char **input_pointer_p, const sparc_asi **value_p) 3295 1.4 christos { 3296 1.4 christos const sparc_asi *value; 3297 1.4 christos char c, *p, *q; 3298 1.4 christos 3299 1.4 christos p = *input_pointer_p; 3300 1.4 christos q = skip_over_keyword(p); 3301 1.1 skrll c = *q; 3302 1.1 skrll *q = 0; 3303 1.1 skrll value = sparc_encode_asi (p); 3304 1.1 skrll *q = c; 3305 1.1 skrll if (value == NULL) 3306 1.1 skrll return 0; 3307 1.1 skrll *value_p = value; 3308 1.1 skrll *input_pointer_p = q; 3309 1.1 skrll return 1; 3310 1.1 skrll } 3311 1.1 skrll 3312 1.1 skrll /* Parse an argument that can be expressed as a keyword. 3313 1.1 skrll (eg: #StoreStore or %ccfr). 3314 1.1 skrll The result is a boolean indicating success. 3315 1.4 christos If successful, INPUT_POINTER is updated. */ 3316 1.1 skrll 3317 1.1 skrll static int 3318 1.1 skrll parse_keyword_arg (int (*lookup_fn) (const char *), 3319 1.1 skrll char **input_pointerP, 3320 1.1 skrll int *valueP) 3321 1.1 skrll { 3322 1.1 skrll int value; 3323 1.1 skrll char c, *p, *q; 3324 1.1 skrll 3325 1.1 skrll p = *input_pointerP; 3326 1.1 skrll q = skip_over_keyword(p); 3327 1.1 skrll c = *q; 3328 1.1 skrll *q = 0; 3329 1.1 skrll value = (*lookup_fn) (p); 3330 1.1 skrll *q = c; 3331 1.1 skrll if (value == -1) 3332 1.1 skrll return 0; 3333 1.1 skrll *valueP = value; 3334 1.1 skrll *input_pointerP = q; 3335 1.1 skrll return 1; 3336 1.1 skrll } 3337 1.1 skrll 3338 1.1 skrll /* Parse an argument that is a constant expression. 3339 1.1 skrll The result is a boolean indicating success. */ 3340 1.1 skrll 3341 1.1 skrll static int 3342 1.1 skrll parse_const_expr_arg (char **input_pointerP, int *valueP) 3343 1.1 skrll { 3344 1.1 skrll char *save = input_line_pointer; 3345 1.1 skrll expressionS exp; 3346 1.1 skrll 3347 1.1 skrll input_line_pointer = *input_pointerP; 3348 1.1 skrll /* The next expression may be something other than a constant 3349 1.1 skrll (say if we're not processing the right variant of the insn). 3350 1.1 skrll Don't call expression unless we're sure it will succeed as it will 3351 1.1 skrll signal an error (which we want to defer until later). */ 3352 1.1 skrll /* FIXME: It might be better to define md_operand and have it recognize 3353 1.1 skrll things like %asi, etc. but continuing that route through to the end 3354 1.1 skrll is a lot of work. */ 3355 1.1 skrll if (*input_line_pointer == '%') 3356 1.1 skrll { 3357 1.1 skrll input_line_pointer = save; 3358 1.1 skrll return 0; 3359 1.1 skrll } 3360 1.1 skrll expression (&exp); 3361 1.1 skrll *input_pointerP = input_line_pointer; 3362 1.1 skrll input_line_pointer = save; 3363 1.1 skrll if (exp.X_op != O_constant) 3364 1.1 skrll return 0; 3365 1.1 skrll *valueP = exp.X_add_number; 3366 1.1 skrll return 1; 3367 1.1 skrll } 3368 1.1 skrll 3369 1.1 skrll /* Subroutine of sparc_ip to parse an expression. */ 3370 1.1 skrll 3371 1.1 skrll static int 3372 1.1 skrll get_expression (char *str) 3373 1.1 skrll { 3374 1.1 skrll char *save_in; 3375 1.1 skrll segT seg; 3376 1.1 skrll 3377 1.1 skrll save_in = input_line_pointer; 3378 1.1 skrll input_line_pointer = str; 3379 1.1 skrll seg = expression (&the_insn.exp); 3380 1.1 skrll if (seg != absolute_section 3381 1.1 skrll && seg != text_section 3382 1.1 skrll && seg != data_section 3383 1.1 skrll && seg != bss_section 3384 1.1 skrll && seg != undefined_section) 3385 1.1 skrll { 3386 1.1 skrll the_insn.error = _("bad segment"); 3387 1.1 skrll expr_end = input_line_pointer; 3388 1.2 joerg input_line_pointer = save_in; 3389 1.1 skrll return 1; 3390 1.1 skrll } 3391 1.1 skrll expr_end = input_line_pointer; 3392 1.1 skrll input_line_pointer = save_in; 3393 1.1 skrll return 0; 3394 1.2 joerg } 3395 1.1 skrll 3396 1.2 joerg /* Subroutine of md_assemble to output one insn. */ 3397 1.1 skrll 3398 1.1 skrll static void 3399 1.2 joerg output_insn (const struct sparc_opcode *insn, struct sparc_it *theinsn) 3400 1.1 skrll { 3401 1.1 skrll char *toP = frag_more (4); 3402 1.1 skrll 3403 1.1 skrll /* Put out the opcode. */ 3404 1.2 joerg if (INSN_BIG_ENDIAN) 3405 1.2 joerg number_to_chars_bigendian (toP, (valueT) theinsn->opcode, 4); 3406 1.2 joerg else 3407 1.1 skrll number_to_chars_littleendian (toP, (valueT) theinsn->opcode, 4); 3408 1.1 skrll 3409 1.1 skrll /* Put out the symbol-dependent stuff. */ 3410 1.1 skrll if (theinsn->reloc != BFD_RELOC_NONE) 3411 1.1 skrll { 3412 1.2 joerg fixS *fixP = fix_new_exp (frag_now, /* Which frag. */ 3413 1.2 joerg (toP - frag_now->fr_literal), /* Where. */ 3414 1.1 skrll 4, /* Size. */ 3415 1.1 skrll &theinsn->exp, 3416 1.1 skrll theinsn->pcrel, 3417 1.2 joerg theinsn->reloc); 3418 1.1 skrll /* Turn off overflow checking in fixup_segment. We'll do our 3419 1.1 skrll own overflow checking in md_apply_fix. This is necessary because 3420 1.1 skrll the insn size is 4 and fixup_segment will signal an overflow for 3421 1.1 skrll large 8 byte quantities. */ 3422 1.3 christos fixP->fx_no_overflow = 1; 3423 1.1 skrll if (theinsn->reloc == BFD_RELOC_SPARC_OLO10) 3424 1.1 skrll fixP->tc_fix_data = theinsn->exp2.X_add_number; 3425 1.1 skrll } 3426 1.1 skrll 3427 1.1 skrll last_insn = insn; 3428 1.1 skrll last_opcode = theinsn->opcode; 3429 1.1 skrll 3430 1.1 skrll dwarf2_emit_insn (4); 3431 1.1 skrll } 3432 1.1 skrll 3433 1.1 skrll const char * 3435 1.1 skrll md_atof (int type, char *litP, int *sizeP) 3436 1.1 skrll { 3437 1.1 skrll return ieee_md_atof (type, litP, sizeP, target_big_endian); 3438 1.1 skrll } 3439 1.1 skrll 3440 1.1 skrll /* Write a value out to the object file, using the appropriate 3441 1.1 skrll endianness. */ 3442 1.1 skrll 3443 1.1 skrll void 3444 1.1 skrll md_number_to_chars (char *buf, valueT val, int n) 3445 1.1 skrll { 3446 1.1 skrll if (target_big_endian) 3447 1.1 skrll number_to_chars_bigendian (buf, val, n); 3448 1.1 skrll else if (target_little_endian_data 3449 1.1 skrll && ((n == 4 || n == 2) && ~now_seg->flags & SEC_ALLOC)) 3450 1.1 skrll /* Output debug words, which are not in allocated sections, as big 3451 1.1 skrll endian. */ 3452 1.1 skrll number_to_chars_bigendian (buf, val, n); 3453 1.1 skrll else if (target_little_endian_data || ! target_big_endian) 3454 1.1 skrll number_to_chars_littleendian (buf, val, n); 3455 1.2 joerg } 3456 1.1 skrll 3457 1.1 skrll /* Apply a fixS to the frags, now that we know the value it ought to 3459 1.1 skrll hold. */ 3460 1.1 skrll 3461 1.1 skrll void 3462 1.1 skrll md_apply_fix (fixS *fixP, valueT *valP, segT segment ATTRIBUTE_UNUSED) 3463 1.1 skrll { 3464 1.1 skrll char *buf = fixP->fx_where + fixP->fx_frag->fr_literal; 3465 1.1 skrll offsetT val = * (offsetT *) valP; 3466 1.1 skrll long insn; 3467 1.1 skrll 3468 1.1 skrll gas_assert (fixP->fx_r_type < BFD_RELOC_UNUSED); 3469 1.1 skrll 3470 1.1 skrll fixP->fx_addnumber = val; /* Remember value for emit_reloc. */ 3471 1.1 skrll 3472 1.1 skrll /* SPARC ELF relocations don't use an addend in the data field. */ 3473 1.1 skrll if (fixP->fx_addsy != NULL) 3474 1.1 skrll { 3475 1.1 skrll switch (fixP->fx_r_type) 3476 1.1 skrll { 3477 1.1 skrll case BFD_RELOC_SPARC_TLS_GD_HI22: 3478 1.1 skrll case BFD_RELOC_SPARC_TLS_GD_LO10: 3479 1.1 skrll case BFD_RELOC_SPARC_TLS_GD_ADD: 3480 1.1 skrll case BFD_RELOC_SPARC_TLS_GD_CALL: 3481 1.1 skrll case BFD_RELOC_SPARC_TLS_LDM_HI22: 3482 1.1 skrll case BFD_RELOC_SPARC_TLS_LDM_LO10: 3483 1.1 skrll case BFD_RELOC_SPARC_TLS_LDM_ADD: 3484 1.1 skrll case BFD_RELOC_SPARC_TLS_LDM_CALL: 3485 1.1 skrll case BFD_RELOC_SPARC_TLS_LDO_HIX22: 3486 1.1 skrll case BFD_RELOC_SPARC_TLS_LDO_LOX10: 3487 1.1 skrll case BFD_RELOC_SPARC_TLS_LDO_ADD: 3488 1.1 skrll case BFD_RELOC_SPARC_TLS_IE_HI22: 3489 1.1 skrll case BFD_RELOC_SPARC_TLS_IE_LO10: 3490 1.1 skrll case BFD_RELOC_SPARC_TLS_IE_LD: 3491 1.1 skrll case BFD_RELOC_SPARC_TLS_IE_LDX: 3492 1.1 skrll case BFD_RELOC_SPARC_TLS_IE_ADD: 3493 1.1 skrll case BFD_RELOC_SPARC_TLS_LE_HIX22: 3494 1.1 skrll case BFD_RELOC_SPARC_TLS_LE_LOX10: 3495 1.1 skrll case BFD_RELOC_SPARC_TLS_DTPMOD32: 3496 1.1 skrll case BFD_RELOC_SPARC_TLS_DTPMOD64: 3497 1.1 skrll case BFD_RELOC_SPARC_TLS_DTPOFF32: 3498 1.1 skrll case BFD_RELOC_SPARC_TLS_DTPOFF64: 3499 1.1 skrll case BFD_RELOC_SPARC_TLS_TPOFF32: 3500 1.1 skrll case BFD_RELOC_SPARC_TLS_TPOFF64: 3501 1.1 skrll S_SET_THREAD_LOCAL (fixP->fx_addsy); 3502 1.1 skrll 3503 1.1 skrll default: 3504 1.1 skrll break; 3505 1.2 joerg } 3506 1.2 joerg 3507 1.2 joerg return; 3508 1.2 joerg } 3509 1.2 joerg 3510 1.2 joerg /* This is a hack. There should be a better way to 3511 1.1 skrll handle this. Probably in terms of howto fields, once 3512 1.1 skrll we can look at these fixups in terms of howtos. */ 3513 1.1 skrll if (fixP->fx_r_type == BFD_RELOC_32_PCREL_S2 && fixP->fx_addsy) 3514 1.1 skrll val += fixP->fx_where + fixP->fx_frag->fr_address; 3515 1.1 skrll 3516 1.1 skrll /* If this is a data relocation, just output VAL. */ 3517 1.1 skrll 3518 1.1 skrll if (fixP->fx_r_type == BFD_RELOC_8) 3519 1.1 skrll { 3520 1.1 skrll md_number_to_chars (buf, val, 1); 3521 1.1 skrll } 3522 1.1 skrll else if (fixP->fx_r_type == BFD_RELOC_16 3523 1.1 skrll || fixP->fx_r_type == BFD_RELOC_SPARC_UA16) 3524 1.1 skrll { 3525 1.1 skrll md_number_to_chars (buf, val, 2); 3526 1.1 skrll } 3527 1.1 skrll else if (fixP->fx_r_type == BFD_RELOC_32 3528 1.1 skrll || fixP->fx_r_type == BFD_RELOC_SPARC_UA32 3529 1.1 skrll || fixP->fx_r_type == BFD_RELOC_SPARC_REV32) 3530 1.1 skrll { 3531 1.1 skrll md_number_to_chars (buf, val, 4); 3532 1.1 skrll } 3533 1.1 skrll else if (fixP->fx_r_type == BFD_RELOC_64 3534 1.1 skrll || fixP->fx_r_type == BFD_RELOC_SPARC_UA64) 3535 1.1 skrll { 3536 1.1 skrll md_number_to_chars (buf, val, 8); 3537 1.1 skrll } 3538 1.1 skrll else if (fixP->fx_r_type == BFD_RELOC_VTABLE_INHERIT 3539 1.1 skrll || fixP->fx_r_type == BFD_RELOC_VTABLE_ENTRY) 3540 1.1 skrll { 3541 1.1 skrll fixP->fx_done = 0; 3542 1.1 skrll return; 3543 1.1 skrll } 3544 1.1 skrll else 3545 1.1 skrll { 3546 1.1 skrll /* It's a relocation against an instruction. */ 3547 1.1 skrll 3548 1.1 skrll if (INSN_BIG_ENDIAN) 3549 1.1 skrll insn = bfd_getb32 ((unsigned char *) buf); 3550 1.1 skrll else 3551 1.1 skrll insn = bfd_getl32 ((unsigned char *) buf); 3552 1.1 skrll 3553 1.4 christos switch (fixP->fx_r_type) 3554 1.4 christos { 3555 1.4 christos case BFD_RELOC_32_PCREL_S2: 3556 1.4 christos val = val >> 2; 3557 1.4 christos /* FIXME: This increment-by-one deserves a comment of why it's 3558 1.4 christos being done! */ 3559 1.4 christos if (! sparc_pic_code 3560 1.1 skrll || fixP->fx_addsy == NULL 3561 1.1 skrll || symbol_section_p (fixP->fx_addsy)) 3562 1.1 skrll ++val; 3563 1.1 skrll 3564 1.1 skrll insn |= val & 0x3fffffff; 3565 1.1 skrll 3566 1.1 skrll /* See if we have a delay slot. In that case we attempt to 3567 1.1 skrll optimize several cases transforming CALL instructions 3568 1.1 skrll into branches. But we can only do that if the relocation 3569 1.1 skrll can be completely resolved here, i.e. if no undefined 3570 1.1 skrll symbol is associated with it. */ 3571 1.1 skrll if (sparc_relax && fixP->fx_addsy == NULL 3572 1.1 skrll && fixP->fx_where + 8 <= fixP->fx_frag->fr_fix) 3573 1.1 skrll { 3574 1.1 skrll #define G0 0 3575 1.1 skrll #define O7 15 3576 1.1 skrll #define XCC (2 << 20) 3577 1.1 skrll #define COND(x) (((x)&0xf)<<25) 3578 1.1 skrll #define CONDA COND(0x8) 3579 1.1 skrll #define INSN_BPA (F2(0,1) | CONDA | BPRED | XCC) 3580 1.1 skrll #define INSN_BA (F2(0,2) | CONDA) 3581 1.1 skrll #define INSN_OR F3(2, 0x2, 0) 3582 1.1 skrll #define INSN_NOP F2(0,4) 3583 1.1 skrll 3584 1.1 skrll long delay; 3585 1.1 skrll 3586 1.1 skrll /* If the instruction is a call with either: 3587 1.1 skrll restore 3588 1.1 skrll arithmetic instruction with rd == %o7 3589 1.1 skrll where rs1 != %o7 and rs2 if it is register != %o7 3590 1.1 skrll then we can optimize if the call destination is near 3591 1.1 skrll by changing the call into a branch always. */ 3592 1.1 skrll if (INSN_BIG_ENDIAN) 3593 1.1 skrll delay = bfd_getb32 ((unsigned char *) buf + 4); 3594 1.1 skrll else 3595 1.1 skrll delay = bfd_getl32 ((unsigned char *) buf + 4); 3596 1.1 skrll if ((insn & OP (~0)) != OP (1) || (delay & OP (~0)) != OP (2)) 3597 1.1 skrll break; 3598 1.1 skrll if ((delay & OP3 (~0)) != OP3 (0x3d) /* Restore. */ 3599 1.1 skrll && ((delay & OP3 (0x28)) != 0 /* Arithmetic. */ 3600 1.1 skrll || ((delay & RD (~0)) != RD (O7)))) 3601 1.1 skrll break; 3602 1.1 skrll if ((delay & RS1 (~0)) == RS1 (O7) 3603 1.1 skrll || ((delay & F3I (~0)) == 0 3604 1.1 skrll && (delay & RS2 (~0)) == RS2 (O7))) 3605 1.1 skrll break; 3606 1.1 skrll /* Ensure the branch will fit into simm22. */ 3607 1.1 skrll if ((val & 0x3fe00000) 3608 1.1 skrll && (val & 0x3fe00000) != 0x3fe00000) 3609 1.1 skrll break; 3610 1.1 skrll /* Check if the arch is v9 and branch will fit 3611 1.1 skrll into simm19. */ 3612 1.1 skrll if (((val & 0x3c0000) == 0 3613 1.1 skrll || (val & 0x3c0000) == 0x3c0000) 3614 1.1 skrll && (sparc_arch_size == 64 3615 1.1 skrll || current_architecture >= SPARC_OPCODE_ARCH_V9)) 3616 1.1 skrll /* ba,pt %xcc */ 3617 1.1 skrll insn = INSN_BPA | (val & 0x7ffff); 3618 1.1 skrll else 3619 1.1 skrll /* ba */ 3620 1.1 skrll insn = INSN_BA | (val & 0x3fffff); 3621 1.1 skrll if (fixP->fx_where >= 4 3622 1.1 skrll && ((delay & (0xffffffff ^ RS1 (~0))) 3623 1.1 skrll == (INSN_OR | RD (O7) | RS2 (G0)))) 3624 1.1 skrll { 3625 1.1 skrll long setter; 3626 1.1 skrll int reg; 3627 1.1 skrll 3628 1.1 skrll if (INSN_BIG_ENDIAN) 3629 1.1 skrll setter = bfd_getb32 ((unsigned char *) buf - 4); 3630 1.1 skrll else 3631 1.1 skrll setter = bfd_getl32 ((unsigned char *) buf - 4); 3632 1.1 skrll if ((setter & (0xffffffff ^ RD (~0))) 3633 1.1 skrll != (INSN_OR | RS1 (O7) | RS2 (G0))) 3634 1.1 skrll break; 3635 1.1 skrll /* The sequence was 3636 1.1 skrll or %o7, %g0, %rN 3637 1.1 skrll call foo 3638 1.1 skrll or %rN, %g0, %o7 3639 1.1 skrll 3640 1.1 skrll If call foo was replaced with ba, replace 3641 1.1 skrll or %rN, %g0, %o7 with nop. */ 3642 1.1 skrll reg = (delay & RS1 (~0)) >> 14; 3643 1.1 skrll if (reg != ((setter & RD (~0)) >> 25) 3644 1.1 skrll || reg == G0 || reg == O7) 3645 1.1 skrll break; 3646 1.1 skrll 3647 1.1 skrll if (INSN_BIG_ENDIAN) 3648 1.1 skrll bfd_putb32 (INSN_NOP, (unsigned char *) buf + 4); 3649 1.1 skrll else 3650 1.1 skrll bfd_putl32 (INSN_NOP, (unsigned char *) buf + 4); 3651 1.1 skrll } 3652 1.1 skrll } 3653 1.1 skrll break; 3654 1.1 skrll 3655 1.1 skrll case BFD_RELOC_SPARC_11: 3656 1.1 skrll if (! in_signed_range (val, 0x7ff)) 3657 1.1 skrll as_bad_where (fixP->fx_file, fixP->fx_line, 3658 1.1 skrll _("relocation overflow")); 3659 1.1 skrll insn |= val & 0x7ff; 3660 1.1 skrll break; 3661 1.1 skrll 3662 1.1 skrll case BFD_RELOC_SPARC_10: 3663 1.1 skrll if (! in_signed_range (val, 0x3ff)) 3664 1.1 skrll as_bad_where (fixP->fx_file, fixP->fx_line, 3665 1.1 skrll _("relocation overflow")); 3666 1.1 skrll insn |= val & 0x3ff; 3667 1.1 skrll break; 3668 1.1 skrll 3669 1.1 skrll case BFD_RELOC_SPARC_7: 3670 1.1 skrll if (! in_bitfield_range (val, 0x7f)) 3671 1.1 skrll as_bad_where (fixP->fx_file, fixP->fx_line, 3672 1.1 skrll _("relocation overflow")); 3673 1.1 skrll insn |= val & 0x7f; 3674 1.1 skrll break; 3675 1.1 skrll 3676 1.1 skrll case BFD_RELOC_SPARC_6: 3677 1.2 joerg if (! in_bitfield_range (val, 0x3f)) 3678 1.2 joerg as_bad_where (fixP->fx_file, fixP->fx_line, 3679 1.2 joerg _("relocation overflow")); 3680 1.2 joerg insn |= val & 0x3f; 3681 1.2 joerg break; 3682 1.2 joerg 3683 1.2 joerg case BFD_RELOC_SPARC_5: 3684 1.2 joerg if (! in_bitfield_range (val, 0x1f)) 3685 1.2 joerg as_bad_where (fixP->fx_file, fixP->fx_line, 3686 1.2 joerg _("relocation overflow")); 3687 1.2 joerg insn |= val & 0x1f; 3688 1.2 joerg break; 3689 1.1 skrll 3690 1.1 skrll case BFD_RELOC_SPARC_WDISP10: 3691 1.1 skrll if ((val & 3) 3692 1.1 skrll || val >= 0x007fc 3693 1.1 skrll || val <= -(offsetT) 0x808) 3694 1.1 skrll as_bad_where (fixP->fx_file, fixP->fx_line, 3695 1.1 skrll _("relocation overflow")); 3696 1.1 skrll /* FIXME: The +1 deserves a comment. */ 3697 1.1 skrll val = (val >> 2) + 1; 3698 1.1 skrll insn |= ((val & 0x300) << 11) 3699 1.1 skrll | ((val & 0xff) << 5); 3700 1.1 skrll break; 3701 1.1 skrll 3702 1.1 skrll case BFD_RELOC_SPARC_WDISP16: 3703 1.1 skrll if ((val & 3) 3704 1.1 skrll || val >= 0x1fffc 3705 1.1 skrll || val <= -(offsetT) 0x20008) 3706 1.1 skrll as_bad_where (fixP->fx_file, fixP->fx_line, 3707 1.1 skrll _("relocation overflow")); 3708 1.1 skrll /* FIXME: The +1 deserves a comment. */ 3709 1.1 skrll val = (val >> 2) + 1; 3710 1.1 skrll insn |= ((val & 0xc000) << 6) | (val & 0x3fff); 3711 1.1 skrll break; 3712 1.1 skrll 3713 1.1 skrll case BFD_RELOC_SPARC_WDISP19: 3714 1.1 skrll if ((val & 3) 3715 1.1 skrll || val >= 0xffffc 3716 1.1 skrll || val <= -(offsetT) 0x100008) 3717 1.1 skrll as_bad_where (fixP->fx_file, fixP->fx_line, 3718 1.1 skrll _("relocation overflow")); 3719 1.1 skrll /* FIXME: The +1 deserves a comment. */ 3720 1.1 skrll val = (val >> 2) + 1; 3721 1.1 skrll insn |= val & 0x7ffff; 3722 1.1 skrll break; 3723 1.1 skrll 3724 1.1 skrll case BFD_RELOC_SPARC_HH22: 3725 1.1 skrll val = BSR (val, 32); 3726 1.1 skrll /* Fall through. */ 3727 1.1 skrll 3728 1.1 skrll case BFD_RELOC_SPARC_LM22: 3729 1.1 skrll case BFD_RELOC_HI22: 3730 1.1 skrll if (!fixP->fx_addsy) 3731 1.1 skrll insn |= (val >> 10) & 0x3fffff; 3732 1.1 skrll else 3733 1.1 skrll /* FIXME: Need comment explaining why we do this. */ 3734 1.1 skrll insn &= ~0xffff; 3735 1.1 skrll break; 3736 1.1 skrll 3737 1.1 skrll case BFD_RELOC_SPARC22: 3738 1.1 skrll if (val & ~0x003fffff) 3739 1.1 skrll as_bad_where (fixP->fx_file, fixP->fx_line, 3740 1.1 skrll _("relocation overflow")); 3741 1.1 skrll insn |= (val & 0x3fffff); 3742 1.1 skrll break; 3743 1.1 skrll 3744 1.1 skrll case BFD_RELOC_SPARC_HM10: 3745 1.1 skrll val = BSR (val, 32); 3746 1.1 skrll /* Fall through. */ 3747 1.1 skrll 3748 1.1 skrll case BFD_RELOC_LO10: 3749 1.1 skrll if (!fixP->fx_addsy) 3750 1.1 skrll insn |= val & 0x3ff; 3751 1.1 skrll else 3752 1.1 skrll /* FIXME: Need comment explaining why we do this. */ 3753 1.1 skrll insn &= ~0xff; 3754 1.1 skrll break; 3755 1.1 skrll 3756 1.1 skrll case BFD_RELOC_SPARC_OLO10: 3757 1.1 skrll val &= 0x3ff; 3758 1.1 skrll val += fixP->tc_fix_data; 3759 1.1 skrll /* Fall through. */ 3760 1.1 skrll 3761 1.1 skrll case BFD_RELOC_SPARC13: 3762 1.2 joerg if (! in_signed_range (val, 0x1fff)) 3763 1.2 joerg as_bad_where (fixP->fx_file, fixP->fx_line, 3764 1.2 joerg _("relocation overflow")); 3765 1.2 joerg insn |= val & 0x1fff; 3766 1.2 joerg break; 3767 1.2 joerg 3768 1.2 joerg case BFD_RELOC_SPARC_WDISP22: 3769 1.2 joerg val = (val >> 2) + 1; 3770 1.2 joerg /* Fall through. */ 3771 1.1 skrll case BFD_RELOC_SPARC_BASE22: 3772 1.1 skrll insn |= val & 0x3fffff; 3773 1.1 skrll break; 3774 1.1 skrll 3775 1.1 skrll case BFD_RELOC_SPARC_H34: 3776 1.1 skrll if (!fixP->fx_addsy) 3777 1.1 skrll { 3778 1.1 skrll bfd_vma tval = val; 3779 1.1 skrll tval >>= 12; 3780 1.1 skrll insn |= tval & 0x3fffff; 3781 1.1 skrll } 3782 1.1 skrll break; 3783 1.1 skrll 3784 1.1 skrll case BFD_RELOC_SPARC_H44: 3785 1.1 skrll if (!fixP->fx_addsy) 3786 1.1 skrll { 3787 1.1 skrll bfd_vma tval = val; 3788 1.1 skrll tval >>= 22; 3789 1.1 skrll insn |= tval & 0x3fffff; 3790 1.1 skrll } 3791 1.1 skrll break; 3792 1.1 skrll 3793 1.1 skrll case BFD_RELOC_SPARC_M44: 3794 1.1 skrll if (!fixP->fx_addsy) 3795 1.1 skrll insn |= (val >> 12) & 0x3ff; 3796 1.1 skrll break; 3797 1.1 skrll 3798 1.1 skrll case BFD_RELOC_SPARC_L44: 3799 1.1 skrll if (!fixP->fx_addsy) 3800 1.1 skrll insn |= val & 0xfff; 3801 1.1 skrll break; 3802 1.1 skrll 3803 1.1 skrll case BFD_RELOC_SPARC_HIX22: 3804 1.1 skrll if (!fixP->fx_addsy) 3805 1.1 skrll { 3806 1.1 skrll val ^= ~(offsetT) 0; 3807 1.1 skrll insn |= (val >> 10) & 0x3fffff; 3808 1.1 skrll } 3809 1.1 skrll break; 3810 1.1 skrll 3811 1.1 skrll case BFD_RELOC_SPARC_LOX10: 3812 1.1 skrll if (!fixP->fx_addsy) 3813 1.1 skrll insn |= 0x1c00 | (val & 0x3ff); 3814 1.1 skrll break; 3815 1.1 skrll 3816 1.1 skrll case BFD_RELOC_NONE: 3817 1.1 skrll default: 3818 1.1 skrll as_bad_where (fixP->fx_file, fixP->fx_line, 3819 1.1 skrll _("bad or unhandled relocation type: 0x%02x"), 3820 1.1 skrll fixP->fx_r_type); 3821 1.1 skrll break; 3822 1.1 skrll } 3823 1.1 skrll 3824 1.1 skrll if (INSN_BIG_ENDIAN) 3825 1.1 skrll bfd_putb32 (insn, (unsigned char *) buf); 3826 1.1 skrll else 3827 1.1 skrll bfd_putl32 (insn, (unsigned char *) buf); 3828 1.1 skrll } 3829 1.1 skrll 3830 1.1 skrll /* Are we finished with this relocation now? */ 3831 1.1 skrll if (fixP->fx_addsy == 0 && !fixP->fx_pcrel) 3832 1.3 christos fixP->fx_done = 1; 3833 1.1 skrll } 3834 1.1 skrll 3835 1.3 christos /* Translate internal representation of relocation info to BFD target 3836 1.1 skrll format. */ 3837 1.1 skrll 3838 1.1 skrll arelent ** 3839 1.1 skrll tc_gen_reloc (asection *section, fixS *fixp) 3840 1.1 skrll { 3841 1.4 christos static arelent *relocs[3]; 3842 1.1 skrll arelent *reloc; 3843 1.1 skrll bfd_reloc_code_real_type code; 3844 1.4 christos 3845 1.4 christos relocs[0] = reloc = XNEW (arelent); 3846 1.4 christos relocs[1] = NULL; 3847 1.4 christos 3848 1.4 christos reloc->sym_ptr_ptr = XNEW (asymbol *); 3849 1.4 christos *reloc->sym_ptr_ptr = symbol_get_bfdsym (fixp->fx_addsy); 3850 1.4 christos reloc->address = fixp->fx_frag->fr_address + fixp->fx_where; 3851 1.4 christos 3852 1.4 christos switch (fixp->fx_r_type) 3853 1.4 christos { 3854 1.4 christos case BFD_RELOC_8: 3855 1.4 christos case BFD_RELOC_16: 3856 1.4 christos case BFD_RELOC_32: 3857 1.4 christos case BFD_RELOC_64: 3858 1.4 christos if (fixp->fx_pcrel) 3859 1.4 christos { 3860 1.4 christos switch (fixp->fx_size) 3861 1.4 christos { 3862 1.4 christos default: 3863 1.4 christos as_bad_where (fixp->fx_file, fixp->fx_line, 3864 1.4 christos _("can not do %d byte pc-relative relocation"), 3865 1.4 christos fixp->fx_size); 3866 1.4 christos code = fixp->fx_r_type; 3867 1.4 christos fixp->fx_pcrel = 0; 3868 1.1 skrll break; 3869 1.1 skrll case 1: code = BFD_RELOC_8_PCREL; break; 3870 1.1 skrll case 2: code = BFD_RELOC_16_PCREL; break; 3871 1.1 skrll case 4: code = BFD_RELOC_32_PCREL; break; 3872 1.1 skrll #ifdef BFD64 3873 1.1 skrll case 8: code = BFD_RELOC_64_PCREL; break; 3874 1.1 skrll #endif 3875 1.1 skrll } 3876 1.2 joerg if (fixp->fx_pcrel) 3877 1.1 skrll fixp->fx_addnumber = fixp->fx_offset; 3878 1.1 skrll break; 3879 1.1 skrll } 3880 1.1 skrll /* Fall through. */ 3881 1.1 skrll case BFD_RELOC_HI22: 3882 1.1 skrll case BFD_RELOC_LO10: 3883 1.1 skrll case BFD_RELOC_32_PCREL_S2: 3884 1.1 skrll case BFD_RELOC_SPARC13: 3885 1.1 skrll case BFD_RELOC_SPARC22: 3886 1.1 skrll case BFD_RELOC_SPARC_PC22: 3887 1.1 skrll case BFD_RELOC_SPARC_PC10: 3888 1.1 skrll case BFD_RELOC_SPARC_BASE13: 3889 1.1 skrll case BFD_RELOC_SPARC_WDISP10: 3890 1.1 skrll case BFD_RELOC_SPARC_WDISP16: 3891 1.2 joerg case BFD_RELOC_SPARC_WDISP19: 3892 1.1 skrll case BFD_RELOC_SPARC_WDISP22: 3893 1.1 skrll case BFD_RELOC_SPARC_5: 3894 1.1 skrll case BFD_RELOC_SPARC_6: 3895 1.1 skrll case BFD_RELOC_SPARC_7: 3896 1.1 skrll case BFD_RELOC_SPARC_10: 3897 1.1 skrll case BFD_RELOC_SPARC_11: 3898 1.1 skrll case BFD_RELOC_SPARC_HH22: 3899 1.1 skrll case BFD_RELOC_SPARC_HM10: 3900 1.1 skrll case BFD_RELOC_SPARC_LM22: 3901 1.1 skrll case BFD_RELOC_SPARC_PC_HH22: 3902 1.1 skrll case BFD_RELOC_SPARC_PC_HM10: 3903 1.1 skrll case BFD_RELOC_SPARC_PC_LM22: 3904 1.1 skrll case BFD_RELOC_SPARC_H34: 3905 1.1 skrll case BFD_RELOC_SPARC_H44: 3906 1.1 skrll case BFD_RELOC_SPARC_M44: 3907 1.1 skrll case BFD_RELOC_SPARC_L44: 3908 1.1 skrll case BFD_RELOC_SPARC_HIX22: 3909 1.1 skrll case BFD_RELOC_SPARC_LOX10: 3910 1.1 skrll case BFD_RELOC_SPARC_REV32: 3911 1.1 skrll case BFD_RELOC_SPARC_OLO10: 3912 1.1 skrll case BFD_RELOC_SPARC_UA16: 3913 1.1 skrll case BFD_RELOC_SPARC_UA32: 3914 1.1 skrll case BFD_RELOC_SPARC_UA64: 3915 1.1 skrll case BFD_RELOC_8_PCREL: 3916 1.1 skrll case BFD_RELOC_16_PCREL: 3917 1.1 skrll case BFD_RELOC_32_PCREL: 3918 1.1 skrll case BFD_RELOC_64_PCREL: 3919 1.1 skrll case BFD_RELOC_SPARC_PLT32: 3920 1.1 skrll case BFD_RELOC_SPARC_PLT64: 3921 1.1 skrll case BFD_RELOC_VTABLE_ENTRY: 3922 1.1 skrll case BFD_RELOC_VTABLE_INHERIT: 3923 1.1 skrll case BFD_RELOC_SPARC_TLS_GD_HI22: 3924 1.1 skrll case BFD_RELOC_SPARC_TLS_GD_LO10: 3925 1.1 skrll case BFD_RELOC_SPARC_TLS_GD_ADD: 3926 1.1 skrll case BFD_RELOC_SPARC_TLS_GD_CALL: 3927 1.1 skrll case BFD_RELOC_SPARC_TLS_LDM_HI22: 3928 1.1 skrll case BFD_RELOC_SPARC_TLS_LDM_LO10: 3929 1.1 skrll case BFD_RELOC_SPARC_TLS_LDM_ADD: 3930 1.1 skrll case BFD_RELOC_SPARC_TLS_LDM_CALL: 3931 1.1 skrll case BFD_RELOC_SPARC_TLS_LDO_HIX22: 3932 1.1 skrll case BFD_RELOC_SPARC_TLS_LDO_LOX10: 3933 1.1 skrll case BFD_RELOC_SPARC_TLS_LDO_ADD: 3934 1.1 skrll case BFD_RELOC_SPARC_TLS_IE_HI22: 3935 1.1 skrll case BFD_RELOC_SPARC_TLS_IE_LO10: 3936 1.1 skrll case BFD_RELOC_SPARC_TLS_IE_LD: 3937 1.1 skrll case BFD_RELOC_SPARC_TLS_IE_LDX: 3938 1.1 skrll case BFD_RELOC_SPARC_TLS_IE_ADD: 3939 1.1 skrll case BFD_RELOC_SPARC_TLS_LE_HIX22: 3940 1.1 skrll case BFD_RELOC_SPARC_TLS_LE_LOX10: 3941 1.1 skrll case BFD_RELOC_SPARC_TLS_DTPOFF32: 3942 1.1 skrll case BFD_RELOC_SPARC_TLS_DTPOFF64: 3943 1.1 skrll case BFD_RELOC_SPARC_GOTDATA_OP_HIX22: 3944 1.1 skrll case BFD_RELOC_SPARC_GOTDATA_OP_LOX10: 3945 1.1 skrll case BFD_RELOC_SPARC_GOTDATA_OP: 3946 1.1 skrll code = fixp->fx_r_type; 3947 1.1 skrll break; 3948 1.1 skrll default: 3949 1.5 christos abort (); 3950 1.1 skrll return NULL; 3951 1.1 skrll } 3952 1.1 skrll 3953 1.1 skrll /* If we are generating PIC code, we need to generate a different 3954 1.1 skrll set of relocs. */ 3955 1.1 skrll 3956 1.1 skrll #define GOT_NAME "_GLOBAL_OFFSET_TABLE_" 3957 1.1 skrll #ifdef TE_VXWORKS 3958 1.1 skrll #define GOTT_BASE "__GOTT_BASE__" 3959 1.1 skrll #define GOTT_INDEX "__GOTT_INDEX__" 3960 1.1 skrll #endif 3961 1.1 skrll 3962 1.1 skrll /* This code must be parallel to tc_fix_adjustable. */ 3963 1.1 skrll 3964 1.1 skrll if (sparc_pic_code) 3965 1.1 skrll { 3966 1.1 skrll switch (code) 3967 1.1 skrll { 3968 1.1 skrll case BFD_RELOC_32_PCREL_S2: 3969 1.1 skrll if (generic_force_reloc (fixp)) 3970 1.1 skrll code = BFD_RELOC_SPARC_WPLT30; 3971 1.1 skrll break; 3972 1.1 skrll case BFD_RELOC_HI22: 3973 1.1 skrll code = BFD_RELOC_SPARC_GOT22; 3974 1.1 skrll if (fixp->fx_addsy != NULL) 3975 1.1 skrll { 3976 1.1 skrll if (strcmp (S_GET_NAME (fixp->fx_addsy), GOT_NAME) == 0) 3977 1.1 skrll code = BFD_RELOC_SPARC_PC22; 3978 1.1 skrll #ifdef TE_VXWORKS 3979 1.1 skrll if (strcmp (S_GET_NAME (fixp->fx_addsy), GOTT_BASE) == 0 3980 1.1 skrll || strcmp (S_GET_NAME (fixp->fx_addsy), GOTT_INDEX) == 0) 3981 1.1 skrll code = BFD_RELOC_HI22; /* Unchanged. */ 3982 1.1 skrll #endif 3983 1.1 skrll } 3984 1.1 skrll break; 3985 1.1 skrll case BFD_RELOC_LO10: 3986 1.1 skrll code = BFD_RELOC_SPARC_GOT10; 3987 1.1 skrll if (fixp->fx_addsy != NULL) 3988 1.1 skrll { 3989 1.1 skrll if (strcmp (S_GET_NAME (fixp->fx_addsy), GOT_NAME) == 0) 3990 1.1 skrll code = BFD_RELOC_SPARC_PC10; 3991 1.1 skrll #ifdef TE_VXWORKS 3992 1.1 skrll if (strcmp (S_GET_NAME (fixp->fx_addsy), GOTT_BASE) == 0 3993 1.1 skrll || strcmp (S_GET_NAME (fixp->fx_addsy), GOTT_INDEX) == 0) 3994 1.6 christos code = BFD_RELOC_LO10; /* Unchanged. */ 3995 1.1 skrll #endif 3996 1.1 skrll } 3997 1.1 skrll break; 3998 1.1 skrll case BFD_RELOC_SPARC13: 3999 1.1 skrll code = BFD_RELOC_SPARC_GOT13; 4000 1.1 skrll break; 4001 1.1 skrll default: 4002 1.1 skrll break; 4003 1.1 skrll } 4004 1.1 skrll } 4005 1.1 skrll 4006 1.1 skrll /* Nothing is aligned in DWARF debugging sections. */ 4007 1.1 skrll if (bfd_section_flags (section) & SEC_DEBUGGING) 4008 1.1 skrll switch (code) 4009 1.1 skrll { 4010 1.1 skrll case BFD_RELOC_16: code = BFD_RELOC_SPARC_UA16; break; 4011 1.1 skrll case BFD_RELOC_32: code = BFD_RELOC_SPARC_UA32; break; 4012 1.1 skrll case BFD_RELOC_64: code = BFD_RELOC_SPARC_UA64; break; 4013 1.1 skrll default: break; 4014 1.1 skrll } 4015 1.1 skrll 4016 1.1 skrll if (code == BFD_RELOC_SPARC_OLO10) 4017 1.1 skrll reloc->howto = bfd_reloc_type_lookup (stdoutput, BFD_RELOC_LO10); 4018 1.1 skrll else 4019 1.1 skrll reloc->howto = bfd_reloc_type_lookup (stdoutput, code); 4020 1.1 skrll if (reloc->howto == 0) 4021 1.1 skrll { 4022 1.2 joerg as_bad_where (fixp->fx_file, fixp->fx_line, 4023 1.1 skrll _("internal error: can't export reloc type %d (`%s')"), 4024 1.1 skrll fixp->fx_r_type, bfd_get_reloc_code_name (code)); 4025 1.1 skrll xfree (reloc); 4026 1.1 skrll relocs[0] = NULL; 4027 1.1 skrll return relocs; 4028 1.1 skrll } 4029 1.1 skrll 4030 1.1 skrll /* @@ Why fx_addnumber sometimes and fx_offset other times? */ 4031 1.1 skrll if (code != BFD_RELOC_32_PCREL_S2 4032 1.1 skrll && code != BFD_RELOC_SPARC_WDISP22 4033 1.1 skrll && code != BFD_RELOC_SPARC_WDISP16 4034 1.1 skrll && code != BFD_RELOC_SPARC_WDISP19 4035 1.1 skrll && code != BFD_RELOC_SPARC_WDISP10 4036 1.1 skrll && code != BFD_RELOC_SPARC_WPLT30 4037 1.1 skrll && code != BFD_RELOC_SPARC_TLS_GD_CALL 4038 1.3 christos && code != BFD_RELOC_SPARC_TLS_LDM_CALL) 4039 1.1 skrll reloc->addend = fixp->fx_addnumber; 4040 1.1 skrll else if (symbol_section_p (fixp->fx_addsy)) 4041 1.3 christos reloc->addend = (section->vma 4042 1.1 skrll + fixp->fx_addnumber 4043 1.1 skrll + md_pcrel_from (fixp)); 4044 1.1 skrll else 4045 1.1 skrll reloc->addend = fixp->fx_offset; 4046 1.1 skrll 4047 1.1 skrll /* We expand R_SPARC_OLO10 to R_SPARC_LO10 and R_SPARC_13 4048 1.1 skrll on the same location. */ 4049 1.1 skrll if (code == BFD_RELOC_SPARC_OLO10) 4050 1.1 skrll { 4051 1.1 skrll relocs[1] = reloc = XNEW (arelent); 4052 1.1 skrll relocs[2] = NULL; 4053 1.1 skrll 4054 1.1 skrll reloc->sym_ptr_ptr = XNEW (asymbol *); 4055 1.1 skrll *reloc->sym_ptr_ptr 4056 1.1 skrll = symbol_get_bfdsym (section_symbol (absolute_section)); 4057 1.1 skrll reloc->address = fixp->fx_frag->fr_address + fixp->fx_where; 4058 1.1 skrll reloc->howto = bfd_reloc_type_lookup (stdoutput, BFD_RELOC_SPARC13); 4059 1.1 skrll reloc->addend = fixp->tc_fix_data; 4060 1.1 skrll } 4061 1.1 skrll 4062 1.1 skrll return relocs; 4063 1.1 skrll } 4064 1.1 skrll 4065 1.1 skrll /* We have no need to default values of symbols. */ 4067 1.1 skrll 4068 1.1 skrll symbolS * 4069 1.1 skrll md_undefined_symbol (char *name ATTRIBUTE_UNUSED) 4070 1.1 skrll { 4071 1.1 skrll return 0; 4072 1.1 skrll } 4073 1.1 skrll 4074 1.1 skrll /* Round up a section size to the appropriate boundary. */ 4075 1.1 skrll 4076 1.1 skrll valueT 4077 1.1 skrll md_section_align (segT segment ATTRIBUTE_UNUSED, valueT size) 4078 1.1 skrll { 4079 1.1 skrll return size; 4080 1.1 skrll } 4081 1.1 skrll 4082 1.1 skrll /* Exactly what point is a PC-relative offset relative TO? 4083 1.1 skrll On the sparc, they're relative to the address of the offset, plus 4084 1.1 skrll its size. This gets us to the following instruction. 4085 1.1 skrll (??? Is this right? FIXME-SOON) */ 4086 1.1 skrll long 4087 1.1 skrll md_pcrel_from (fixS *fixP) 4088 1.1 skrll { 4089 1.1 skrll long ret; 4090 1.1 skrll 4091 1.1 skrll ret = fixP->fx_where + fixP->fx_frag->fr_address; 4092 1.1 skrll if (! sparc_pic_code 4093 1.1 skrll || fixP->fx_addsy == NULL 4094 1.1 skrll || symbol_section_p (fixP->fx_addsy)) 4095 1.1 skrll ret += fixP->fx_size; 4096 1.1 skrll return ret; 4097 1.1 skrll } 4098 1.1 skrll 4099 1.1 skrll /* Return log2 (VALUE), or -1 if VALUE is not an exact positive power 4101 1.1 skrll of two. */ 4102 1.1 skrll 4103 1.1 skrll static int 4104 1.1 skrll mylog2 (int value) 4105 1.1 skrll { 4106 1.1 skrll int shift; 4107 1.1 skrll 4108 1.1 skrll if (value <= 0) 4109 1.1 skrll return -1; 4110 1.1 skrll 4111 1.1 skrll for (shift = 0; (value & 1) == 0; value >>= 1) 4112 1.1 skrll ++shift; 4113 1.1 skrll 4114 1.1 skrll return (value == 1) ? shift : -1; 4115 1.2 joerg } 4116 1.1 skrll 4117 1.1 skrll /* Sort of like s_lcomm. */ 4118 1.2 joerg 4119 1.1 skrll static void 4120 1.1 skrll s_reserve (int ignore ATTRIBUTE_UNUSED) 4121 1.1 skrll { 4122 1.1 skrll char *name; 4123 1.1 skrll char *p; 4124 1.1 skrll char c; 4125 1.1 skrll int align; 4126 1.1 skrll int size; 4127 1.1 skrll int temp; 4128 1.1 skrll symbolS *symbolP; 4129 1.1 skrll 4130 1.1 skrll c = get_symbol_name (&name); 4131 1.1 skrll p = input_line_pointer; 4132 1.1 skrll *p = c; 4133 1.1 skrll SKIP_WHITESPACE_AFTER_NAME (); 4134 1.1 skrll 4135 1.1 skrll if (*input_line_pointer != ',') 4136 1.1 skrll { 4137 1.1 skrll as_bad (_("Expected comma after name")); 4138 1.1 skrll ignore_rest_of_line (); 4139 1.1 skrll return; 4140 1.7 christos } 4141 1.7 christos 4142 1.1 skrll ++input_line_pointer; 4143 1.1 skrll 4144 1.1 skrll if ((size = get_absolute_expression ()) < 0) 4145 1.1 skrll { 4146 1.1 skrll as_bad (_("BSS length (%d.) <0! Ignored."), size); 4147 1.1 skrll ignore_rest_of_line (); 4148 1.1 skrll return; 4149 1.1 skrll } /* Bad length. */ 4150 1.1 skrll 4151 1.1 skrll *p = 0; 4152 1.1 skrll symbolP = symbol_find_or_make (name); 4153 1.1 skrll *p = c; 4154 1.1 skrll 4155 1.1 skrll if (!startswith (input_line_pointer, ",\"bss\"") 4156 1.1 skrll && !startswith (input_line_pointer, ",\".bss\"")) 4157 1.1 skrll { 4158 1.1 skrll as_bad (_("bad .reserve segment -- expected BSS segment")); 4159 1.1 skrll return; 4160 1.1 skrll } 4161 1.1 skrll 4162 1.1 skrll if (input_line_pointer[2] == '.') 4163 1.1 skrll input_line_pointer += 7; 4164 1.1 skrll else 4165 1.1 skrll input_line_pointer += 6; 4166 1.1 skrll SKIP_WHITESPACE (); 4167 1.1 skrll 4168 1.1 skrll if (*input_line_pointer == ',') 4169 1.1 skrll { 4170 1.1 skrll ++input_line_pointer; 4171 1.1 skrll 4172 1.1 skrll SKIP_WHITESPACE (); 4173 1.1 skrll if (*input_line_pointer == '\n') 4174 1.1 skrll { 4175 1.1 skrll as_bad (_("missing alignment")); 4176 1.1 skrll ignore_rest_of_line (); 4177 1.1 skrll return; 4178 1.1 skrll } 4179 1.1 skrll 4180 1.1 skrll align = (int) get_absolute_expression (); 4181 1.1 skrll 4182 1.1 skrll if (align < 0) 4183 1.1 skrll { 4184 1.1 skrll as_bad (_("negative alignment")); 4185 1.1 skrll ignore_rest_of_line (); 4186 1.1 skrll return; 4187 1.1 skrll } 4188 1.1 skrll 4189 1.1 skrll if (align != 0) 4190 1.1 skrll { 4191 1.1 skrll temp = mylog2 (align); 4192 1.5 christos if (temp < 0) 4193 1.1 skrll { 4194 1.1 skrll as_bad (_("alignment not a power of 2")); 4195 1.1 skrll ignore_rest_of_line (); 4196 1.1 skrll return; 4197 1.1 skrll } 4198 1.1 skrll 4199 1.1 skrll align = temp; 4200 1.1 skrll } 4201 1.1 skrll 4202 1.1 skrll record_alignment (bss_section, align); 4203 1.1 skrll } 4204 1.1 skrll else 4205 1.1 skrll align = 0; 4206 1.1 skrll 4207 1.1 skrll if (!S_IS_DEFINED (symbolP)) 4208 1.1 skrll { 4209 1.1 skrll if (! need_pass_2) 4210 1.1 skrll { 4211 1.1 skrll char *pfrag; 4212 1.1 skrll segT current_seg = now_seg; 4213 1.1 skrll subsegT current_subseg = now_subseg; 4214 1.1 skrll 4215 1.1 skrll /* Switch to bss. */ 4216 1.1 skrll subseg_set (bss_section, 1); 4217 1.1 skrll 4218 1.1 skrll if (align) 4219 1.1 skrll /* Do alignment. */ 4220 1.1 skrll frag_align (align, 0, 0); 4221 1.1 skrll 4222 1.1 skrll /* Detach from old frag. */ 4223 1.1 skrll if (S_GET_SEGMENT (symbolP) == bss_section) 4224 1.1 skrll symbol_get_frag (symbolP)->fr_symbol = NULL; 4225 1.2 joerg 4226 1.1 skrll symbol_set_frag (symbolP, frag_now); 4227 1.2 joerg pfrag = frag_var (rs_org, 1, 1, (relax_substateT) 0, symbolP, 4228 1.1 skrll (offsetT) size, (char *) 0); 4229 1.1 skrll *pfrag = 0; 4230 1.1 skrll 4231 1.1 skrll S_SET_SEGMENT (symbolP, bss_section); 4232 1.1 skrll 4233 1.1 skrll subseg_set (current_seg, current_subseg); 4234 1.1 skrll 4235 1.1 skrll S_SET_SIZE (symbolP, size); 4236 1.1 skrll } 4237 1.1 skrll } 4238 1.1 skrll else 4239 1.1 skrll { 4240 1.1 skrll as_warn (_("Ignoring attempt to re-define symbol %s"), 4241 1.2 joerg S_GET_NAME (symbolP)); 4242 1.1 skrll } 4243 1.1 skrll 4244 1.1 skrll demand_empty_rest_of_line (); 4245 1.2 joerg } 4246 1.1 skrll 4247 1.1 skrll static void 4248 1.1 skrll s_common (int ignore ATTRIBUTE_UNUSED) 4249 1.1 skrll { 4250 1.1 skrll char *name; 4251 1.1 skrll char c; 4252 1.1 skrll char *p; 4253 1.1 skrll offsetT temp, size; 4254 1.1 skrll symbolS *symbolP; 4255 1.1 skrll 4256 1.1 skrll c = get_symbol_name (&name); 4257 1.1 skrll /* Just after name is now '\0'. */ 4258 1.1 skrll p = input_line_pointer; 4259 1.1 skrll *p = c; 4260 1.1 skrll SKIP_WHITESPACE_AFTER_NAME (); 4261 1.1 skrll if (*input_line_pointer != ',') 4262 1.1 skrll { 4263 1.1 skrll as_bad (_("Expected comma after symbol-name")); 4264 1.1 skrll ignore_rest_of_line (); 4265 1.1 skrll return; 4266 1.1 skrll } 4267 1.1 skrll 4268 1.1 skrll /* Skip ','. */ 4269 1.1 skrll input_line_pointer++; 4270 1.1 skrll 4271 1.1 skrll if ((temp = get_absolute_expression ()) < 0) 4272 1.1 skrll { 4273 1.1 skrll as_bad (_(".COMMon length (%lu) out of range ignored"), 4274 1.1 skrll (unsigned long) temp); 4275 1.1 skrll ignore_rest_of_line (); 4276 1.1 skrll return; 4277 1.1 skrll } 4278 1.1 skrll size = temp; 4279 1.1 skrll *p = 0; 4280 1.1 skrll symbolP = symbol_find_or_make (name); 4281 1.1 skrll *p = c; 4282 1.1 skrll if (S_IS_DEFINED (symbolP) && ! S_IS_COMMON (symbolP)) 4283 1.1 skrll { 4284 1.1 skrll as_bad (_("Ignoring attempt to re-define symbol")); 4285 1.1 skrll ignore_rest_of_line (); 4286 1.1 skrll return; 4287 1.1 skrll } 4288 1.1 skrll if (S_GET_VALUE (symbolP) != 0) 4289 1.1 skrll { 4290 1.1 skrll if (S_GET_VALUE (symbolP) != (valueT) size) 4291 1.1 skrll { 4292 1.1 skrll as_warn (_("Length of .comm \"%s\" is already %ld. Not changed to %ld."), 4293 1.1 skrll S_GET_NAME (symbolP), (long) S_GET_VALUE (symbolP), (long) size); 4294 1.1 skrll } 4295 1.1 skrll } 4296 1.1 skrll know (symbol_get_frag (symbolP) == &zero_address_frag); 4297 1.1 skrll if (*input_line_pointer != ',') 4298 1.1 skrll { 4299 1.1 skrll as_bad (_("Expected comma after common length")); 4300 1.1 skrll ignore_rest_of_line (); 4301 1.1 skrll return; 4302 1.1 skrll } 4303 1.1 skrll input_line_pointer++; 4304 1.1 skrll SKIP_WHITESPACE (); 4305 1.1 skrll if (*input_line_pointer != '"') 4306 1.1 skrll { 4307 1.1 skrll temp = get_absolute_expression (); 4308 1.1 skrll 4309 1.1 skrll if (temp < 0) 4310 1.1 skrll { 4311 1.1 skrll as_bad (_("negative alignment")); 4312 1.1 skrll ignore_rest_of_line (); 4313 1.1 skrll return; 4314 1.1 skrll } 4315 1.1 skrll 4316 1.1 skrll if (symbol_get_obj (symbolP)->local) 4317 1.1 skrll { 4318 1.1 skrll segT old_sec; 4319 1.1 skrll int old_subsec; 4320 1.1 skrll int align; 4321 1.1 skrll 4322 1.1 skrll old_sec = now_seg; 4323 1.1 skrll old_subsec = now_subseg; 4324 1.1 skrll 4325 1.1 skrll if (temp == 0) 4326 1.1 skrll align = 0; 4327 1.1 skrll else 4328 1.1 skrll align = mylog2 (temp); 4329 1.1 skrll 4330 1.1 skrll if (align < 0) 4331 1.1 skrll { 4332 1.1 skrll as_bad (_("alignment not a power of 2")); 4333 1.1 skrll ignore_rest_of_line (); 4334 1.1 skrll return; 4335 1.1 skrll } 4336 1.1 skrll 4337 1.1 skrll record_alignment (bss_section, align); 4338 1.1 skrll subseg_set (bss_section, 0); 4339 1.1 skrll if (align) 4340 1.1 skrll frag_align (align, 0, 0); 4341 1.1 skrll if (S_GET_SEGMENT (symbolP) == bss_section) 4342 1.1 skrll symbol_get_frag (symbolP)->fr_symbol = 0; 4343 1.1 skrll symbol_set_frag (symbolP, frag_now); 4344 1.1 skrll p = frag_var (rs_org, 1, 1, (relax_substateT) 0, symbolP, 4345 1.1 skrll (offsetT) size, (char *) 0); 4346 1.1 skrll *p = 0; 4347 1.1 skrll S_SET_SEGMENT (symbolP, bss_section); 4348 1.1 skrll S_CLEAR_EXTERNAL (symbolP); 4349 1.1 skrll S_SET_SIZE (symbolP, size); 4350 1.1 skrll subseg_set (old_sec, old_subsec); 4351 1.1 skrll } 4352 1.1 skrll else 4353 1.1 skrll { 4354 1.7 christos allocate_common: 4355 1.7 christos S_SET_VALUE (symbolP, (valueT) size); 4356 1.1 skrll S_SET_ALIGN (symbolP, temp); 4357 1.1 skrll S_SET_SIZE (symbolP, size); 4358 1.1 skrll S_SET_EXTERNAL (symbolP); 4359 1.1 skrll S_SET_SEGMENT (symbolP, bfd_com_section_ptr); 4360 1.1 skrll } 4361 1.1 skrll } 4362 1.1 skrll else 4363 1.1 skrll { 4364 1.1 skrll input_line_pointer++; 4365 1.1 skrll /* @@ Some use the dot, some don't. Can we get some consistency?? */ 4366 1.1 skrll if (*input_line_pointer == '.') 4367 1.1 skrll input_line_pointer++; 4368 1.1 skrll /* @@ Some say data, some say bss. */ 4369 1.1 skrll if (!startswith (input_line_pointer, "bss\"") 4370 1.1 skrll && !startswith (input_line_pointer, "data\"")) 4371 1.1 skrll { 4372 1.1 skrll while (*--input_line_pointer != '"') 4373 1.1 skrll ; 4374 1.1 skrll input_line_pointer--; 4375 1.1 skrll goto bad_common_segment; 4376 1.1 skrll } 4377 1.1 skrll while (*input_line_pointer++ != '"') 4378 1.1 skrll ; 4379 1.1 skrll goto allocate_common; 4380 1.1 skrll } 4381 1.1 skrll 4382 1.1 skrll symbol_get_bfdsym (symbolP)->flags |= BSF_OBJECT; 4383 1.1 skrll 4384 1.1 skrll demand_empty_rest_of_line (); 4385 1.1 skrll return; 4386 1.1 skrll 4387 1.1 skrll { 4388 1.1 skrll bad_common_segment: 4389 1.1 skrll p = input_line_pointer; 4390 1.1 skrll while (*p && *p != '\n') 4391 1.1 skrll p++; 4392 1.1 skrll c = *p; 4393 1.1 skrll *p = '\0'; 4394 1.1 skrll as_bad (_("bad .common segment %s"), input_line_pointer + 1); 4395 1.1 skrll *p = c; 4396 1.1 skrll input_line_pointer = p; 4397 1.1 skrll ignore_rest_of_line (); 4398 1.1 skrll return; 4399 1.1 skrll } 4400 1.1 skrll } 4401 1.1 skrll 4402 1.7 christos /* Handle the .empty pseudo-op. This suppresses the warnings about 4403 1.1 skrll invalid delay slot usage. */ 4404 1.1 skrll 4405 1.1 skrll static void 4406 1.1 skrll s_empty (int ignore ATTRIBUTE_UNUSED) 4407 1.1 skrll { 4408 1.7 christos /* The easy way to implement is to just forget about the last 4409 1.1 skrll instruction. */ 4410 1.1 skrll last_insn = NULL; 4411 1.1 skrll } 4412 1.1 skrll 4413 1.1 skrll static void 4414 1.7 christos s_seg (int ignore ATTRIBUTE_UNUSED) 4415 1.1 skrll { 4416 1.1 skrll 4417 1.1 skrll if (startswith (input_line_pointer, "\"text\"")) 4418 1.1 skrll { 4419 1.1 skrll input_line_pointer += 6; 4420 1.7 christos s_text (0); 4421 1.1 skrll return; 4422 1.1 skrll } 4423 1.1 skrll if (startswith (input_line_pointer, "\"data\"")) 4424 1.1 skrll { 4425 1.1 skrll input_line_pointer += 6; 4426 1.1 skrll s_data (0); 4427 1.1 skrll return; 4428 1.1 skrll } 4429 1.1 skrll if (startswith (input_line_pointer, "\"data1\"")) 4430 1.1 skrll { 4431 1.1 skrll input_line_pointer += 7; 4432 1.1 skrll s_data1 (); 4433 1.1 skrll return; 4434 1.1 skrll } 4435 1.1 skrll if (startswith (input_line_pointer, "\"bss\"")) 4436 1.1 skrll { 4437 1.1 skrll input_line_pointer += 5; 4438 1.1 skrll /* We only support 2 segments -- text and data -- for now, so 4439 1.1 skrll things in the "bss segment" will have to go into data for now. 4440 1.1 skrll You can still allocate SEG_BSS stuff with .lcomm or .reserve. */ 4441 1.1 skrll subseg_set (data_section, 255); /* FIXME-SOMEDAY. */ 4442 1.1 skrll return; 4443 1.1 skrll } 4444 1.1 skrll as_bad (_("Unknown segment type")); 4445 1.1 skrll demand_empty_rest_of_line (); 4446 1.1 skrll } 4447 1.1 skrll 4448 1.1 skrll static void 4449 1.1 skrll s_data1 (void) 4450 1.1 skrll { 4451 1.1 skrll subseg_set (data_section, 1); 4452 1.1 skrll demand_empty_rest_of_line (); 4453 1.1 skrll } 4454 1.1 skrll 4455 1.1 skrll static void 4456 1.1 skrll s_proc (int ignore ATTRIBUTE_UNUSED) 4457 1.1 skrll { 4458 1.1 skrll while (!is_end_of_line[(unsigned char) *input_line_pointer]) 4459 1.1 skrll { 4460 1.1 skrll ++input_line_pointer; 4461 1.1 skrll } 4462 1.1 skrll ++input_line_pointer; 4463 1.1 skrll } 4464 1.1 skrll 4465 1.1 skrll /* This static variable is set by s_uacons to tell sparc_cons_align 4466 1.1 skrll that the expression does not need to be aligned. */ 4467 1.1 skrll 4468 1.1 skrll static int sparc_no_align_cons = 0; 4469 1.1 skrll 4470 1.1 skrll /* This handles the unaligned space allocation pseudo-ops, such as 4471 1.1 skrll .uaword. .uaword is just like .word, but the value does not need 4472 1.1 skrll to be aligned. */ 4473 1.1 skrll 4474 1.1 skrll static void 4475 1.1 skrll s_uacons (int bytes) 4476 1.1 skrll { 4477 1.1 skrll /* Tell sparc_cons_align not to align this value. */ 4478 1.1 skrll sparc_no_align_cons = 1; 4479 1.1 skrll cons (bytes); 4480 1.1 skrll sparc_no_align_cons = 0; 4481 1.1 skrll } 4482 1.1 skrll 4483 1.1 skrll /* This handles the native word allocation pseudo-op .nword. 4484 1.1 skrll For sparc_arch_size 32 it is equivalent to .word, for 4485 1.1 skrll sparc_arch_size 64 it is equivalent to .xword. */ 4486 1.1 skrll 4487 1.1 skrll static void 4488 1.1 skrll s_ncons (int bytes ATTRIBUTE_UNUSED) 4489 1.1 skrll { 4490 1.1 skrll cons (sparc_arch_size == 32 ? 4 : 8); 4491 1.2 joerg } 4492 1.1 skrll 4493 1.1 skrll /* Handle the SPARC ELF .register pseudo-op. This sets the binding of a 4494 1.1 skrll global register. 4495 1.1 skrll The syntax is: 4496 1.1 skrll 4497 1.1 skrll .register %g[2367],{#scratch|symbolname|#ignore} 4498 1.1 skrll */ 4499 1.1 skrll 4500 1.1 skrll static void 4501 1.1 skrll s_register (int ignore ATTRIBUTE_UNUSED) 4502 1.1 skrll { 4503 1.1 skrll char c; 4504 1.1 skrll int reg; 4505 1.2 joerg int flags; 4506 1.1 skrll char *regname; 4507 1.1 skrll 4508 1.1 skrll if (input_line_pointer[0] != '%' 4509 1.1 skrll || input_line_pointer[1] != 'g' 4510 1.1 skrll || ((input_line_pointer[2] & ~1) != '2' 4511 1.3 christos && (input_line_pointer[2] & ~1) != '6') 4512 1.1 skrll || input_line_pointer[3] != ',') 4513 1.1 skrll as_bad (_("register syntax is .register %%g[2367],{#scratch|symbolname|#ignore}")); 4514 1.1 skrll reg = input_line_pointer[2] - '0'; 4515 1.2 joerg input_line_pointer += 4; 4516 1.1 skrll 4517 1.2 joerg if (*input_line_pointer == '#') 4518 1.1 skrll { 4519 1.1 skrll ++input_line_pointer; 4520 1.1 skrll c = get_symbol_name (®name); 4521 1.1 skrll if (strcmp (regname, "scratch") && strcmp (regname, "ignore")) 4522 1.1 skrll as_bad (_("register syntax is .register %%g[2367],{#scratch|symbolname|#ignore}")); 4523 1.1 skrll if (regname[0] == 'i') 4524 1.1 skrll regname = NULL; 4525 1.1 skrll else 4526 1.1 skrll regname = (char *) ""; 4527 1.1 skrll } 4528 1.1 skrll else 4529 1.1 skrll { 4530 1.1 skrll c = get_symbol_name (®name); 4531 1.1 skrll } 4532 1.1 skrll 4533 1.1 skrll if (sparc_arch_size == 64) 4534 1.1 skrll { 4535 1.1 skrll if (globals[reg]) 4536 1.1 skrll { 4537 1.1 skrll if ((regname && globals[reg] != (symbolS *) 1 4538 1.1 skrll && strcmp (S_GET_NAME (globals[reg]), regname)) 4539 1.1 skrll || ((regname != NULL) ^ (globals[reg] != (symbolS *) 1))) 4540 1.1 skrll as_bad (_("redefinition of global register")); 4541 1.1 skrll } 4542 1.1 skrll else 4543 1.1 skrll { 4544 1.1 skrll if (regname == NULL) 4545 1.1 skrll globals[reg] = (symbolS *) 1; 4546 1.1 skrll else 4547 1.1 skrll { 4548 1.1 skrll if (*regname) 4549 1.1 skrll { 4550 1.1 skrll if (symbol_find (regname)) 4551 1.1 skrll as_bad (_("Register symbol %s already defined."), 4552 1.1 skrll regname); 4553 1.1 skrll } 4554 1.1 skrll globals[reg] = symbol_make (regname); 4555 1.1 skrll flags = symbol_get_bfdsym (globals[reg])->flags; 4556 1.1 skrll if (! *regname) 4557 1.1 skrll flags = flags & ~(BSF_GLOBAL|BSF_LOCAL|BSF_WEAK); 4558 1.1 skrll if (! (flags & (BSF_GLOBAL|BSF_LOCAL|BSF_WEAK))) 4559 1.1 skrll flags |= BSF_GLOBAL; 4560 1.1 skrll symbol_get_bfdsym (globals[reg])->flags = flags; 4561 1.1 skrll S_SET_VALUE (globals[reg], (valueT) reg); 4562 1.1 skrll S_SET_ALIGN (globals[reg], reg); 4563 1.1 skrll S_SET_SIZE (globals[reg], 0); 4564 1.2 joerg /* Although we actually want undefined_section here, 4565 1.1 skrll we have to use absolute_section, because otherwise 4566 1.1 skrll generic as code will make it a COM section. 4567 1.1 skrll We fix this up in sparc_adjust_symtab. */ 4568 1.1 skrll S_SET_SEGMENT (globals[reg], absolute_section); 4569 1.1 skrll S_SET_OTHER (globals[reg], 0); 4570 1.1 skrll elf_symbol (symbol_get_bfdsym (globals[reg])) 4571 1.1 skrll ->internal_elf_sym.st_info = 4572 1.1 skrll ELF_ST_INFO(STB_GLOBAL, STT_REGISTER); 4573 1.1 skrll elf_symbol (symbol_get_bfdsym (globals[reg])) 4574 1.1 skrll ->internal_elf_sym.st_shndx = SHN_UNDEF; 4575 1.1 skrll } 4576 1.1 skrll } 4577 1.1 skrll } 4578 1.1 skrll 4579 1.1 skrll (void) restore_line_pointer (c); 4580 1.1 skrll 4581 1.1 skrll demand_empty_rest_of_line (); 4582 1.1 skrll } 4583 1.1 skrll 4584 1.1 skrll /* Adjust the symbol table. We set undefined sections for STT_REGISTER 4585 1.1 skrll symbols which need it. */ 4586 1.1 skrll 4587 1.1 skrll void 4588 1.1 skrll sparc_adjust_symtab (void) 4589 1.1 skrll { 4590 1.1 skrll symbolS *sym; 4591 1.1 skrll 4592 1.1 skrll for (sym = symbol_rootP; sym != NULL; sym = symbol_next (sym)) 4593 1.1 skrll { 4594 1.1 skrll if (ELF_ST_TYPE (elf_symbol (symbol_get_bfdsym (sym)) 4595 1.1 skrll ->internal_elf_sym.st_info) != STT_REGISTER) 4596 1.1 skrll continue; 4597 1.1 skrll 4598 1.1 skrll if (ELF_ST_TYPE (elf_symbol (symbol_get_bfdsym (sym)) 4599 1.1 skrll ->internal_elf_sym.st_shndx != SHN_UNDEF)) 4600 1.1 skrll continue; 4601 1.1 skrll 4602 1.1 skrll S_SET_SEGMENT (sym, undefined_section); 4603 1.1 skrll } 4604 1.1 skrll } 4605 1.1 skrll 4606 1.1 skrll /* If the --enforce-aligned-data option is used, we require .word, 4607 1.1 skrll et. al., to be aligned correctly. We do it by setting up an 4608 1.1 skrll rs_align_code frag, and checking in HANDLE_ALIGN to make sure that 4609 1.1 skrll no unexpected alignment was introduced. 4610 1.1 skrll 4611 1.1 skrll The SunOS and Solaris native assemblers enforce aligned data by 4612 1.1 skrll default. We don't want to do that, because gcc can deliberately 4613 1.1 skrll generate misaligned data if the packed attribute is used. Instead, 4614 1.1 skrll we permit misaligned data by default, and permit the user to set an 4615 1.1 skrll option to check for it. */ 4616 1.1 skrll 4617 1.1 skrll void 4618 1.1 skrll sparc_cons_align (int nbytes) 4619 1.2 joerg { 4620 1.1 skrll int nalign; 4621 1.1 skrll 4622 1.1 skrll /* Only do this if we are enforcing aligned data. */ 4623 1.1 skrll if (! enforce_aligned_data) 4624 1.1 skrll return; 4625 1.1 skrll 4626 1.1 skrll /* Don't align if this is an unaligned pseudo-op. */ 4627 1.1 skrll if (sparc_no_align_cons) 4628 1.2 joerg return; 4629 1.2 joerg 4630 1.1 skrll nalign = mylog2 (nbytes); 4631 1.1 skrll if (nalign == 0) 4632 1.1 skrll return; 4633 1.1 skrll 4634 1.1 skrll gas_assert (nalign > 0); 4635 1.1 skrll 4636 1.1 skrll if (now_seg == absolute_section) 4637 1.1 skrll { 4638 1.1 skrll if ((abs_section_offset & ((1 << nalign) - 1)) != 0) 4639 1.1 skrll as_bad (_("misaligned data")); 4640 1.1 skrll return; 4641 1.1 skrll } 4642 1.1 skrll 4643 1.1 skrll frag_var (rs_align_test, 1, 1, (relax_substateT) 0, 4644 1.1 skrll (symbolS *) NULL, (offsetT) nalign, (char *) NULL); 4645 1.1 skrll 4646 1.1 skrll record_alignment (now_seg, nalign); 4647 1.1 skrll } 4648 1.1 skrll 4649 1.1 skrll /* This is called from HANDLE_ALIGN in tc-sparc.h. */ 4650 1.1 skrll 4651 1.1 skrll void 4652 1.1 skrll sparc_handle_align (fragS *fragp) 4653 1.1 skrll { 4654 1.1 skrll int count, fix; 4655 1.1 skrll char *p; 4656 1.1 skrll 4657 1.1 skrll count = fragp->fr_next->fr_address - fragp->fr_address - fragp->fr_fix; 4658 1.1 skrll 4659 1.1 skrll switch (fragp->fr_type) 4660 1.1 skrll { 4661 1.1 skrll case rs_align_test: 4662 1.1 skrll if (count != 0) 4663 1.1 skrll as_bad_where (fragp->fr_file, fragp->fr_line, _("misaligned data")); 4664 1.1 skrll break; 4665 1.1 skrll 4666 1.1 skrll case rs_align_code: 4667 1.1 skrll p = fragp->fr_literal + fragp->fr_fix; 4668 1.1 skrll fix = 0; 4669 1.1 skrll 4670 1.1 skrll if (count & 3) 4671 1.1 skrll { 4672 1.1 skrll fix = count & 3; 4673 1.1 skrll memset (p, 0, fix); 4674 1.1 skrll p += fix; 4675 1.1 skrll count -= fix; 4676 1.1 skrll } 4677 1.1 skrll 4678 1.1 skrll if (SPARC_OPCODE_ARCH_V9_P (max_architecture) && count > 8) 4679 1.1 skrll { 4680 1.1 skrll unsigned wval = (0x30680000 | count >> 2); /* ba,a,pt %xcc, 1f */ 4681 1.1 skrll if (INSN_BIG_ENDIAN) 4682 1.1 skrll number_to_chars_bigendian (p, wval, 4); 4683 1.1 skrll else 4684 1.1 skrll number_to_chars_littleendian (p, wval, 4); 4685 1.1 skrll p += 4; 4686 1.1 skrll count -= 4; 4687 1.1 skrll fix += 4; 4688 1.1 skrll } 4689 1.1 skrll 4690 1.1 skrll if (INSN_BIG_ENDIAN) 4691 1.1 skrll number_to_chars_bigendian (p, 0x01000000, 4); 4692 1.1 skrll else 4693 1.1 skrll number_to_chars_littleendian (p, 0x01000000, 4); 4694 1.1 skrll 4695 1.1 skrll fragp->fr_fix += fix; 4696 1.1 skrll fragp->fr_var = 4; 4697 1.1 skrll break; 4698 1.1 skrll 4699 1.1 skrll default: 4700 1.1 skrll break; 4701 1.1 skrll } 4702 1.1 skrll } 4703 1.1 skrll 4704 1.1 skrll /* Some special processing for a Sparc ELF file. */ 4705 1.1 skrll 4706 1.1 skrll void 4707 1.1 skrll sparc_elf_final_processing (void) 4708 1.1 skrll { 4709 1.1 skrll /* Set the Sparc ELF flag bits. FIXME: There should probably be some 4710 1.1 skrll sort of BFD interface for this. */ 4711 1.1 skrll if (sparc_arch_size == 64) 4712 1.1 skrll { 4713 1.1 skrll switch (sparc_memory_model) 4714 1.1 skrll { 4715 1.1 skrll case MM_RMO: 4716 1.1 skrll elf_elfheader (stdoutput)->e_flags |= EF_SPARCV9_RMO; 4717 1.1 skrll break; 4718 1.2 joerg case MM_PSO: 4719 1.1 skrll elf_elfheader (stdoutput)->e_flags |= EF_SPARCV9_PSO; 4720 1.1 skrll break; 4721 1.1 skrll default: 4722 1.2 joerg break; 4723 1.1 skrll } 4724 1.1 skrll } 4725 1.1 skrll else if (current_architecture >= SPARC_OPCODE_ARCH_V9) 4726 1.1 skrll elf_elfheader (stdoutput)->e_flags |= EF_SPARC_32PLUS; 4727 1.1 skrll if (current_architecture == SPARC_OPCODE_ARCH_V9A) 4728 1.1 skrll elf_elfheader (stdoutput)->e_flags |= EF_SPARC_SUN_US1; 4729 1.1 skrll else if (current_architecture == SPARC_OPCODE_ARCH_V9B) 4730 1.7 christos elf_elfheader (stdoutput)->e_flags |= EF_SPARC_SUN_US1|EF_SPARC_SUN_US3; 4731 1.1 skrll } 4732 1.1 skrll 4733 1.1 skrll const char * 4734 1.1 skrll sparc_cons (expressionS *exp, int size) 4735 1.7 christos { 4736 1.1 skrll char *save; 4737 1.1 skrll const char *sparc_cons_special_reloc = NULL; 4738 1.1 skrll 4739 1.1 skrll SKIP_WHITESPACE (); 4740 1.1 skrll save = input_line_pointer; 4741 1.1 skrll if (input_line_pointer[0] == '%' 4742 1.1 skrll && input_line_pointer[1] == 'r' 4743 1.1 skrll && input_line_pointer[2] == '_') 4744 1.1 skrll { 4745 1.7 christos if (startswith (input_line_pointer + 3, "disp")) 4746 1.1 skrll { 4747 1.1 skrll input_line_pointer += 7; 4748 1.1 skrll sparc_cons_special_reloc = "disp"; 4749 1.1 skrll } 4750 1.1 skrll else if (startswith (input_line_pointer + 3, "plt")) 4751 1.1 skrll { 4752 1.1 skrll if (size != 4 && size != 8) 4753 1.1 skrll as_bad (_("Illegal operands: %%r_plt in %d-byte data field"), size); 4754 1.1 skrll else 4755 1.1 skrll { 4756 1.1 skrll input_line_pointer += 6; 4757 1.1 skrll sparc_cons_special_reloc = "plt"; 4758 1.1 skrll } 4759 1.1 skrll } 4760 1.1 skrll else if (startswith (input_line_pointer + 3, "tls_dtpoff")) 4761 1.1 skrll { 4762 1.1 skrll if (size != 4 && size != 8) 4763 1.1 skrll as_bad (_("Illegal operands: %%r_tls_dtpoff in %d-byte data field"), size); 4764 1.1 skrll else 4765 1.1 skrll { 4766 1.1 skrll input_line_pointer += 13; 4767 1.1 skrll sparc_cons_special_reloc = "tls_dtpoff"; 4768 1.1 skrll } 4769 1.1 skrll } 4770 1.1 skrll if (sparc_cons_special_reloc) 4771 1.1 skrll { 4772 1.1 skrll int bad = 0; 4773 1.1 skrll 4774 1.1 skrll switch (size) 4775 1.1 skrll { 4776 1.1 skrll case 1: 4777 1.1 skrll if (*input_line_pointer != '8') 4778 1.1 skrll bad = 1; 4779 1.1 skrll input_line_pointer--; 4780 1.1 skrll break; 4781 1.1 skrll case 2: 4782 1.1 skrll if (input_line_pointer[0] != '1' || input_line_pointer[1] != '6') 4783 1.1 skrll bad = 1; 4784 1.1 skrll break; 4785 1.1 skrll case 4: 4786 1.1 skrll if (input_line_pointer[0] != '3' || input_line_pointer[1] != '2') 4787 1.1 skrll bad = 1; 4788 1.1 skrll break; 4789 1.1 skrll case 8: 4790 1.1 skrll if (input_line_pointer[0] != '6' || input_line_pointer[1] != '4') 4791 1.1 skrll bad = 1; 4792 1.1 skrll break; 4793 1.1 skrll default: 4794 1.1 skrll bad = 1; 4795 1.1 skrll break; 4796 1.1 skrll } 4797 1.1 skrll 4798 1.1 skrll if (bad) 4799 1.1 skrll { 4800 1.1 skrll as_bad (_("Illegal operands: Only %%r_%s%d allowed in %d-byte data fields"), 4801 1.1 skrll sparc_cons_special_reloc, size * 8, size); 4802 1.1 skrll } 4803 1.1 skrll else 4804 1.1 skrll { 4805 1.1 skrll input_line_pointer += 2; 4806 1.1 skrll if (*input_line_pointer != '(') 4807 1.1 skrll { 4808 1.1 skrll as_bad (_("Illegal operands: %%r_%s%d requires arguments in ()"), 4809 1.1 skrll sparc_cons_special_reloc, size * 8); 4810 1.1 skrll bad = 1; 4811 1.1 skrll } 4812 1.1 skrll } 4813 1.1 skrll 4814 1.1 skrll if (bad) 4815 1.1 skrll { 4816 1.1 skrll input_line_pointer = save; 4817 1.1 skrll sparc_cons_special_reloc = NULL; 4818 1.1 skrll } 4819 1.1 skrll else 4820 1.1 skrll { 4821 1.1 skrll int c; 4822 1.1 skrll char *end = ++input_line_pointer; 4823 1.1 skrll int npar = 0; 4824 1.1 skrll 4825 1.1 skrll while (! is_end_of_line[(c = *end)]) 4826 1.1 skrll { 4827 1.1 skrll if (c == '(') 4828 1.1 skrll npar++; 4829 1.1 skrll else if (c == ')') 4830 1.1 skrll { 4831 1.1 skrll if (!npar) 4832 1.1 skrll break; 4833 1.1 skrll npar--; 4834 1.1 skrll } 4835 1.1 skrll end++; 4836 1.1 skrll } 4837 1.1 skrll 4838 1.1 skrll if (c != ')') 4839 1.1 skrll as_bad (_("Illegal operands: %%r_%s%d requires arguments in ()"), 4840 1.1 skrll sparc_cons_special_reloc, size * 8); 4841 1.1 skrll else 4842 1.1 skrll { 4843 1.1 skrll *end = '\0'; 4844 1.1 skrll expression (exp); 4845 1.1 skrll *end = c; 4846 1.1 skrll if (input_line_pointer != end) 4847 1.1 skrll { 4848 1.1 skrll as_bad (_("Illegal operands: %%r_%s%d requires arguments in ()"), 4849 1.1 skrll sparc_cons_special_reloc, size * 8); 4850 1.1 skrll } 4851 1.2 joerg else 4852 1.1 skrll { 4853 1.1 skrll input_line_pointer++; 4854 1.1 skrll SKIP_WHITESPACE (); 4855 1.1 skrll c = *input_line_pointer; 4856 1.1 skrll if (! is_end_of_line[c] && c != ',') 4857 1.1 skrll as_bad (_("Illegal operands: garbage after %%r_%s%d()"), 4858 1.1 skrll sparc_cons_special_reloc, size * 8); 4859 1.1 skrll } 4860 1.1 skrll } 4861 1.1 skrll } 4862 1.2 joerg } 4863 1.2 joerg } 4864 1.1 skrll if (sparc_cons_special_reloc == NULL) 4865 1.1 skrll expression (exp); 4866 1.1 skrll return sparc_cons_special_reloc; 4867 1.1 skrll } 4868 1.1 skrll 4869 1.1 skrll /* This is called by emit_expr via TC_CONS_FIX_NEW when creating a 4870 1.1 skrll reloc for a cons. We could use the definition there, except that 4871 1.1 skrll we want to handle little endian relocs specially. */ 4872 1.1 skrll 4873 1.1 skrll void 4874 1.1 skrll cons_fix_new_sparc (fragS *frag, 4875 1.1 skrll int where, 4876 1.4 christos unsigned int nbytes, 4877 1.4 christos expressionS *exp, 4878 1.4 christos const char *sparc_cons_special_reloc) 4879 1.4 christos { 4880 1.4 christos bfd_reloc_code_real_type r; 4881 1.4 christos 4882 1.4 christos r = (nbytes == 1 ? BFD_RELOC_8 : 4883 1.4 christos (nbytes == 2 ? BFD_RELOC_16 : 4884 1.4 christos (nbytes == 4 ? BFD_RELOC_32 : BFD_RELOC_64))); 4885 1.1 skrll 4886 1.1 skrll if (target_little_endian_data 4887 1.1 skrll && nbytes == 4 4888 1.1 skrll && now_seg->flags & SEC_ALLOC) 4889 1.1 skrll r = BFD_RELOC_SPARC_REV32; 4890 1.1 skrll 4891 1.1 skrll #ifdef TE_SOLARIS 4892 1.1 skrll /* The Solaris linker does not allow R_SPARC_UA64 4893 1.1 skrll relocations for 32-bit executables. */ 4894 1.1 skrll if (!target_little_endian_data 4895 1.1 skrll && sparc_arch_size != 64 4896 1.1 skrll && r == BFD_RELOC_64) 4897 1.1 skrll r = BFD_RELOC_32; 4898 1.1 skrll #endif 4899 1.1 skrll 4900 1.1 skrll if (sparc_cons_special_reloc) 4901 1.1 skrll { 4902 1.1 skrll if (*sparc_cons_special_reloc == 'd') 4903 1.1 skrll switch (nbytes) 4904 1.1 skrll { 4905 1.1 skrll case 1: r = BFD_RELOC_8_PCREL; break; 4906 1.1 skrll case 2: r = BFD_RELOC_16_PCREL; break; 4907 1.1 skrll case 4: r = BFD_RELOC_32_PCREL; break; 4908 1.1 skrll case 8: r = BFD_RELOC_64_PCREL; break; 4909 1.4 christos default: abort (); 4910 1.4 christos } 4911 1.4 christos else if (*sparc_cons_special_reloc == 'p') 4912 1.4 christos switch (nbytes) 4913 1.1 skrll { 4914 1.1 skrll case 4: r = BFD_RELOC_SPARC_PLT32; break; 4915 1.1 skrll case 8: r = BFD_RELOC_SPARC_PLT64; break; 4916 1.1 skrll } 4917 1.1 skrll else 4918 1.4 christos switch (nbytes) 4919 1.4 christos { 4920 1.4 christos case 4: r = BFD_RELOC_SPARC_TLS_DTPOFF32; break; 4921 1.4 christos case 8: r = BFD_RELOC_SPARC_TLS_DTPOFF64; break; 4922 1.4 christos } 4923 1.4 christos } 4924 1.1 skrll else if (sparc_no_align_cons 4925 1.4 christos || /* PR 20803 - relocs in the .eh_frame section 4926 1.1 skrll need to support unaligned access. */ 4927 1.1 skrll strcmp (now_seg->name, ".eh_frame") == 0) 4928 1.1 skrll { 4929 1.1 skrll switch (nbytes) 4930 1.1 skrll { 4931 1.1 skrll case 2: r = BFD_RELOC_SPARC_UA16; break; 4932 1.1 skrll case 4: r = BFD_RELOC_SPARC_UA32; break; 4933 1.1 skrll #ifdef TE_SOLARIS 4934 1.1 skrll /* The Solaris linker does not allow R_SPARC_UA64 4935 1.1 skrll relocations for 32-bit executables. */ 4936 1.1 skrll case 8: r = sparc_arch_size == 64 ? 4937 1.1 skrll BFD_RELOC_SPARC_UA64 : BFD_RELOC_SPARC_UA32; break; 4938 1.1 skrll #else 4939 1.1 skrll case 8: r = BFD_RELOC_SPARC_UA64; break; 4940 1.1 skrll #endif 4941 1.1 skrll default: abort (); 4942 1.3 christos } 4943 1.3 christos } 4944 1.1 skrll 4945 1.1 skrll fix_new_exp (frag, where, (int) nbytes, exp, 0, r); 4946 1.1 skrll } 4947 1.1 skrll 4948 1.3 christos void 4949 1.3 christos sparc_cfi_frame_initial_instructions (void) 4950 1.3 christos { 4951 1.3 christos cfi_add_CFA_def_cfa (14, sparc_arch_size == 64 ? 0x7ff : 0); 4952 1.3 christos } 4953 1.3 christos 4954 1.3 christos int 4955 1.3 christos sparc_regname_to_dw2regnum (char *regname) 4956 1.3 christos { 4957 1.1 skrll char *q; 4958 1.1 skrll int i; 4959 1.1 skrll 4960 1.3 christos if (!regname[0]) 4961 1.1 skrll return -1; 4962 1.1 skrll 4963 1.1 skrll switch (regname[0]) 4964 1.1 skrll { 4965 1.1 skrll case 'g': i = 0; break; 4966 1.1 skrll case 'o': i = 1; break; 4967 1.1 skrll case 'l': i = 2; break; 4968 1.1 skrll case 'i': i = 3; break; 4969 1.1 skrll default: i = -1; break; 4970 1.1 skrll } 4971 1.3 christos if (i != -1) 4972 1.1 skrll { 4973 1.1 skrll if (regname[1] < '0' || regname[1] > '8' || regname[2]) 4974 1.1 skrll return -1; 4975 1.1 skrll return i * 8 + regname[1] - '0'; 4976 1.1 skrll } 4977 1.1 skrll if (regname[0] == 's' && regname[1] == 'p' && !regname[2]) 4978 1.1 skrll return 14; 4979 1.1 skrll if (regname[0] == 'f' && regname[1] == 'p' && !regname[2]) 4980 1.1 skrll return 30; 4981 1.1 skrll if (regname[0] == 'f' || regname[0] == 'r') 4982 1.1 skrll { 4983 1.1 skrll unsigned int regnum; 4984 1.1 skrll 4985 1.1 skrll regnum = strtoul (regname + 1, &q, 10); 4986 1.1 skrll if (q == NULL || *q) 4987 1.1 skrll return -1; 4988 1.1 skrll if (regnum >= ((regname[0] == 'f' 4989 1.1 skrll && SPARC_OPCODE_ARCH_V9_P (max_architecture)) 4990 1.1 skrll ? 64 : 32)) 4991 1.1 skrll return -1; 4992 1.2 joerg if (regname[0] == 'f') 4993 1.1 skrll { 4994 1.1 skrll regnum += 32; 4995 if (regnum >= 64 && (regnum & 1)) 4996 return -1; 4997 } 4998 return regnum; 4999 } 5000 return -1; 5001 } 5002 5003 void 5004 sparc_cfi_emit_pcrel_expr (expressionS *exp, unsigned int nbytes) 5005 { 5006 sparc_no_align_cons = 1; 5007 emit_expr_with_reloc (exp, nbytes, "disp"); 5008 sparc_no_align_cons = 0; 5009 } 5010
Indexes created Sun Mar 01 05:31:48 UTC 2026