1 /* The common simulator framework for GDB, the GNU Debugger. 2 3 Copyright 2002-2013 Free Software Foundation, Inc. 4 5 Contributed by Andrew Cagney and Red Hat. 6 7 This file is part of GDB. 8 9 This program is free software; you can redistribute it and/or modify 10 it under the terms of the GNU General Public License as published by 11 the Free Software Foundation; either version 3 of the License, or 12 (at your option) any later version. 13 14 This program is distributed in the hope that it will be useful, 15 but WITHOUT ANY WARRANTY; without even the implied warranty of 16 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the 17 GNU General Public License for more details. 18 19 You should have received a copy of the GNU General Public License 20 along with this program. If not, see <http://www.gnu.org/licenses/>. */ 21 22 23 #ifndef _SIM_ENDIAN_H_ 24 #define _SIM_ENDIAN_H_ 25 26 27 /* C byte conversion functions */ 28 29 INLINE_SIM_ENDIAN(unsigned_1) endian_h2t_1(unsigned_1 x); 30 INLINE_SIM_ENDIAN(unsigned_2) endian_h2t_2(unsigned_2 x); 31 INLINE_SIM_ENDIAN(unsigned_4) endian_h2t_4(unsigned_4 x); 32 INLINE_SIM_ENDIAN(unsigned_8) endian_h2t_8(unsigned_8 x); 33 INLINE_SIM_ENDIAN(unsigned_16) endian_h2t_16(unsigned_16 x); 34 35 INLINE_SIM_ENDIAN(unsigned_1) endian_t2h_1(unsigned_1 x); 36 INLINE_SIM_ENDIAN(unsigned_2) endian_t2h_2(unsigned_2 x); 37 INLINE_SIM_ENDIAN(unsigned_4) endian_t2h_4(unsigned_4 x); 38 INLINE_SIM_ENDIAN(unsigned_8) endian_t2h_8(unsigned_8 x); 39 INLINE_SIM_ENDIAN(unsigned_16) endian_t2h_16(unsigned_16 x); 40 41 INLINE_SIM_ENDIAN(unsigned_1) swap_1(unsigned_1 x); 42 INLINE_SIM_ENDIAN(unsigned_2) swap_2(unsigned_2 x); 43 INLINE_SIM_ENDIAN(unsigned_4) swap_4(unsigned_4 x); 44 INLINE_SIM_ENDIAN(unsigned_8) swap_8(unsigned_8 x); 45 INLINE_SIM_ENDIAN(unsigned_16) swap_16(unsigned_16 x); 46 47 INLINE_SIM_ENDIAN(unsigned_1) endian_h2be_1(unsigned_1 x); 48 INLINE_SIM_ENDIAN(unsigned_2) endian_h2be_2(unsigned_2 x); 49 INLINE_SIM_ENDIAN(unsigned_4) endian_h2be_4(unsigned_4 x); 50 INLINE_SIM_ENDIAN(unsigned_8) endian_h2be_8(unsigned_8 x); 51 INLINE_SIM_ENDIAN(unsigned_16) endian_h2be_16(unsigned_16 x); 52 53 INLINE_SIM_ENDIAN(unsigned_1) endian_be2h_1(unsigned_1 x); 54 INLINE_SIM_ENDIAN(unsigned_2) endian_be2h_2(unsigned_2 x); 55 INLINE_SIM_ENDIAN(unsigned_4) endian_be2h_4(unsigned_4 x); 56 INLINE_SIM_ENDIAN(unsigned_8) endian_be2h_8(unsigned_8 x); 57 INLINE_SIM_ENDIAN(unsigned_16) endian_be2h_16(unsigned_16 x); 58 59 INLINE_SIM_ENDIAN(unsigned_1) endian_h2le_1(unsigned_1 x); 60 INLINE_SIM_ENDIAN(unsigned_2) endian_h2le_2(unsigned_2 x); 61 INLINE_SIM_ENDIAN(unsigned_4) endian_h2le_4(unsigned_4 x); 62 INLINE_SIM_ENDIAN(unsigned_8) endian_h2le_8(unsigned_8 x); 63 INLINE_SIM_ENDIAN(unsigned_16) endian_h2le_16(unsigned_16 x); 64 65 INLINE_SIM_ENDIAN(unsigned_1) endian_le2h_1(unsigned_1 x); 66 INLINE_SIM_ENDIAN(unsigned_2) endian_le2h_2(unsigned_2 x); 67 INLINE_SIM_ENDIAN(unsigned_4) endian_le2h_4(unsigned_4 x); 68 INLINE_SIM_ENDIAN(unsigned_8) endian_le2h_8(unsigned_8 x); 69 INLINE_SIM_ENDIAN(unsigned_16) endian_le2h_16(unsigned_16 x); 70 71 INLINE_SIM_ENDIAN(void*) offset_1(unsigned_1 *x, unsigned ws, unsigned w); 72 INLINE_SIM_ENDIAN(void*) offset_2(unsigned_2 *x, unsigned ws, unsigned w); 73 INLINE_SIM_ENDIAN(void*) offset_4(unsigned_4 *x, unsigned ws, unsigned w); 74 INLINE_SIM_ENDIAN(void*) offset_8(unsigned_8 *x, unsigned ws, unsigned w); 75 INLINE_SIM_ENDIAN(void*) offset_16(unsigned_16 *x, unsigned ws, unsigned w); 76 77 INLINE_SIM_ENDIAN(unsigned_16) sim_endian_join_16 (unsigned_8 h, unsigned_8 l); 78 INLINE_SIM_ENDIAN(unsigned_8) sim_endian_split_16 (unsigned_16 word, int w); 79 80 81 /* SWAP */ 82 83 #define SWAP_1 swap_1 84 #define SWAP_2 swap_2 85 #define SWAP_4 swap_4 86 #define SWAP_8 swap_8 87 #define SWAP_16 swap_16 88 89 90 /* HOST to BE */ 91 92 #define H2BE_1 endian_h2be_1 93 #define H2BE_2 endian_h2be_2 94 #define H2BE_4 endian_h2be_4 95 #define H2BE_8 endian_h2be_8 96 #define H2BE_16 endian_h2be_16 97 #define BE2H_1 endian_be2h_1 98 #define BE2H_2 endian_be2h_2 99 #define BE2H_4 endian_be2h_4 100 #define BE2H_8 endian_be2h_8 101 #define BE2H_16 endian_be2h_16 102 103 104 /* HOST to LE */ 105 106 #define H2LE_1 endian_h2le_1 107 #define H2LE_2 endian_h2le_2 108 #define H2LE_4 endian_h2le_4 109 #define H2LE_8 endian_h2le_8 110 #define H2LE_16 endian_h2le_16 111 #define LE2H_1 endian_le2h_1 112 #define LE2H_2 endian_le2h_2 113 #define LE2H_4 endian_le2h_4 114 #define LE2H_8 endian_le2h_8 115 #define LE2H_16 endian_le2h_16 116 117 118 /* HOST to TARGET */ 119 120 #define H2T_1 endian_h2t_1 121 #define H2T_2 endian_h2t_2 122 #define H2T_4 endian_h2t_4 123 #define H2T_8 endian_h2t_8 124 #define H2T_16 endian_h2t_16 125 #define T2H_1 endian_t2h_1 126 #define T2H_2 endian_t2h_2 127 #define T2H_4 endian_t2h_4 128 #define T2H_8 endian_t2h_8 129 #define T2H_16 endian_t2h_16 130 131 132 /* CONVERT IN PLACE 133 134 These macros, given an argument of unknown size, swap its value in 135 place if a host/target conversion is required. */ 136 137 #define H2T(VARIABLE) \ 138 do { \ 139 void *vp = &(VARIABLE); \ 140 switch (sizeof (VARIABLE)) { \ 141 case 1: *(unsigned_1*)vp = H2T_1(*(unsigned_1*)vp); break; \ 142 case 2: *(unsigned_2*)vp = H2T_2(*(unsigned_2*)vp); break; \ 143 case 4: *(unsigned_4*)vp = H2T_4(*(unsigned_4*)vp); break; \ 144 case 8: *(unsigned_8*)vp = H2T_8(*(unsigned_8*)vp); break; \ 145 case 16: *(unsigned_16*)vp = H2T_16(*(unsigned_16*)vp); break; \ 146 } \ 147 } while (0) 148 149 #define T2H(VARIABLE) \ 150 do { \ 151 switch (sizeof(VARIABLE)) { \ 152 case 1: VARIABLE = T2H_1(VARIABLE); break; \ 153 case 2: VARIABLE = T2H_2(VARIABLE); break; \ 154 case 4: VARIABLE = T2H_4(VARIABLE); break; \ 155 case 8: VARIABLE = T2H_8(VARIABLE); break; \ 156 /*case 16: VARIABLE = T2H_16(VARIABLE); break;*/ \ 157 } \ 158 } while (0) 159 160 #define SWAP(VARIABLE) \ 161 do { \ 162 switch (sizeof(VARIABLE)) { \ 163 case 1: VARIABLE = SWAP_1(VARIABLE); break; \ 164 case 2: VARIABLE = SWAP_2(VARIABLE); break; \ 165 case 4: VARIABLE = SWAP_4(VARIABLE); break; \ 166 case 8: VARIABLE = SWAP_8(VARIABLE); break; \ 167 /*case 16: VARIABLE = SWAP_16(VARIABLE); break;*/ \ 168 } \ 169 } while (0) 170 171 #define H2BE(VARIABLE) \ 172 do { \ 173 switch (sizeof(VARIABLE)) { \ 174 case 1: VARIABLE = H2BE_1(VARIABLE); break; \ 175 case 2: VARIABLE = H2BE_2(VARIABLE); break; \ 176 case 4: VARIABLE = H2BE_4(VARIABLE); break; \ 177 case 8: VARIABLE = H2BE_8(VARIABLE); break; \ 178 /*case 16: VARIABLE = H2BE_16(VARIABLE); break;*/ \ 179 } \ 180 } while (0) 181 182 #define BE2H(VARIABLE) \ 183 do { \ 184 switch (sizeof(VARIABLE)) { \ 185 case 1: VARIABLE = BE2H_1(VARIABLE); break; \ 186 case 2: VARIABLE = BE2H_2(VARIABLE); break; \ 187 case 4: VARIABLE = BE2H_4(VARIABLE); break; \ 188 case 8: VARIABLE = BE2H_8(VARIABLE); break; \ 189 /*case 16: VARIABLE = BE2H_16(VARIABLE); break;*/ \ 190 } \ 191 } while (0) 192 193 #define H2LE(VARIABLE) \ 194 do { \ 195 switch (sizeof(VARIABLE)) { \ 196 case 1: VARIABLE = H2LE_1(VARIABLE); break; \ 197 case 2: VARIABLE = H2LE_2(VARIABLE); break; \ 198 case 4: VARIABLE = H2LE_4(VARIABLE); break; \ 199 case 8: VARIABLE = H2LE_8(VARIABLE); break; \ 200 /*case 16: VARIABLE = H2LE_16(VARIABLE); break;*/ \ 201 } \ 202 } while (0) 203 204 #define LE2H(VARIABLE) \ 205 do { \ 206 switch (sizeof(VARIABLE)) { \ 207 case 1: VARIABLE = LE2H_1(VARIABLE); break; \ 208 case 2: VARIABLE = LE2H_2(VARIABLE); break; \ 209 case 4: VARIABLE = LE2H_4(VARIABLE); break; \ 210 case 8: VARIABLE = LE2H_8(VARIABLE); break; \ 211 /*case 16: VARIABLE = LE2H_16(VARIABLE); break;*/ \ 212 } \ 213 } while (0) 214 215 216 217 /* TARGET WORD: 218 219 Byte swap a quantity the size of the targets word */ 220 221 #if (WITH_TARGET_WORD_BITSIZE == 64) 222 #define H2T_word H2T_8 223 #define T2H_word T2H_8 224 #define H2BE_word H2BE_8 225 #define BE2H_word BE2H_8 226 #define H2LE_word H2LE_8 227 #define LE2H_word LE2H_8 228 #define SWAP_word SWAP_8 229 #endif 230 #if (WITH_TARGET_WORD_BITSIZE == 32) 231 #define H2T_word H2T_4 232 #define T2H_word T2H_4 233 #define H2BE_word H2BE_4 234 #define BE2H_word BE2H_4 235 #define H2LE_word H2LE_4 236 #define LE2H_word LE2H_4 237 #define SWAP_word SWAP_4 238 #endif 239 240 241 242 /* TARGET CELL: 243 244 Byte swap a quantity the size of the targets IEEE 1275 memory cell */ 245 246 #define H2T_cell H2T_4 247 #define T2H_cell T2H_4 248 #define H2BE_cell H2BE_4 249 #define BE2H_cell BE2H_4 250 #define H2LE_cell H2LE_4 251 #define LE2H_cell LE2H_4 252 #define SWAP_cell SWAP_4 253 254 255 256 /* HOST Offsets: 257 258 Address of high/low sub-word within a host word quantity. 259 260 Address of sub-word N within a host word quantity. NOTE: Numbering 261 is BIG endian always. */ 262 263 #define AH1_2(X) (unsigned_1*)offset_2((X), 1, 0) 264 #define AL1_2(X) (unsigned_1*)offset_2((X), 1, 1) 265 266 #define AH2_4(X) (unsigned_2*)offset_4((X), 2, 0) 267 #define AL2_4(X) (unsigned_2*)offset_4((X), 2, 1) 268 269 #define AH4_8(X) (unsigned_4*)offset_8((X), 4, 0) 270 #define AL4_8(X) (unsigned_4*)offset_8((X), 4, 1) 271 272 #define AH8_16(X) (unsigned_8*)offset_16((X), 8, 0) 273 #define AL8_16(X) (unsigned_8*)offset_16((X), 8, 1) 274 275 #if (WITH_TARGET_WORD_BITSIZE == 64) 276 #define AH_word(X) AH4_8(X) 277 #define AL_word(X) AL4_8(X) 278 #endif 279 #if (WITH_TARGET_WORD_BITSIZE == 32) 280 #define AH_word(X) AH2_4(X) 281 #define AL_word(X) AL2_4(X) 282 #endif 283 284 285 #define A1_2(X,N) (unsigned_1*)offset_2((X), 1, (N)) 286 287 #define A1_4(X,N) (unsigned_1*)offset_4((X), 1, (N)) 288 #define A2_4(X,N) (unsigned_2*)offset_4((X), 2, (N)) 289 290 #define A1_8(X,N) (unsigned_1*)offset_8((X), 1, (N)) 291 #define A2_8(X,N) (unsigned_2*)offset_8((X), 2, (N)) 292 #define A4_8(X,N) (unsigned_4*)offset_8((X), 4, (N)) 293 294 #define A1_16(X,N) (unsigned_1*)offset_16((X), 1, (N)) 295 #define A2_16(X,N) (unsigned_2*)offset_16((X), 2, (N)) 296 #define A4_16(X,N) (unsigned_4*)offset_16((X), 4, (N)) 297 #define A8_16(X,N) (unsigned_8*)offset_16((X), 8, (N)) 298 299 300 301 302 /* HOST Components: 303 304 Value of sub-word within a host word quantity */ 305 306 #define VH1_2(X) ((unsigned_1)((unsigned_2)(X) >> 8)) 307 #define VL1_2(X) (unsigned_1)(X) 308 309 #define VH2_4(X) ((unsigned_2)((unsigned_4)(X) >> 16)) 310 #define VL2_4(X) ((unsigned_2)(X)) 311 312 #define VH4_8(X) ((unsigned_4)((unsigned_8)(X) >> 32)) 313 #define VL4_8(X) ((unsigned_4)(X)) 314 315 #define VH8_16(X) (sim_endian_split_16 ((X), 0)) 316 #define VL8_16(X) (sim_endian_split_16 ((X), 1)) 317 318 #if (WITH_TARGET_WORD_BITSIZE == 64) 319 #define VH_word(X) VH4_8(X) 320 #define VL_word(X) VL4_8(X) 321 #endif 322 #if (WITH_TARGET_WORD_BITSIZE == 32) 323 #define VH_word(X) VH2_4(X) 324 #define VL_word(X) VL2_4(X) 325 #endif 326 327 328 #define V1_2(X,N) ((unsigned_1)((unsigned_2)(X) >> ( 8 * (1 - (N))))) 329 330 #define V1_4(X,N) ((unsigned_1)((unsigned_4)(X) >> ( 8 * (3 - (N))))) 331 #define V2_4(X,N) ((unsigned_2)((unsigned_4)(X) >> (16 * (1 - (N))))) 332 333 #define V1_8(X,N) ((unsigned_1)((unsigned_8)(X) >> ( 8 * (7 - (N))))) 334 #define V2_8(X,N) ((unsigned_2)((unsigned_8)(X) >> (16 * (3 - (N))))) 335 #define V4_8(X,N) ((unsigned_4)((unsigned_8)(X) >> (32 * (1 - (N))))) 336 337 #define V1_16(X,N) (*A1_16 (&(X),N)) 338 #define V2_16(X,N) (*A2_16 (&(X),N)) 339 #define V4_16(X,N) (*A4_16 (&(X),N)) 340 #define V8_16(X,N) (*A8_16 (&(X),N)) 341 342 343 /* Reverse - insert sub-word into word quantity */ 344 345 #define V2_H1(X) ((unsigned_2)(unsigned_1)(X) << 8) 346 #define V2_L1(X) ((unsigned_2)(unsigned_1)(X)) 347 348 #define V4_H2(X) ((unsigned_4)(unsigned_2)(X) << 16) 349 #define V4_L2(X) ((unsigned_4)(unsigned_2)(X)) 350 351 #define V8_H4(X) ((unsigned_8)(unsigned_4)(X) << 32) 352 #define V8_L4(X) ((unsigned_8)(unsigned_4)(X)) 353 354 #define V16_H8(X) ((unsigned_16)(unsigned_8)(X) << 64) 355 #define V16_L8(X) ((unsigned_16)(unsigned_8)(X)) 356 357 358 #define V2_1(X,N) ((unsigned_2)(unsigned_1)(X) << ( 8 * (1 - (N)))) 359 360 #define V4_1(X,N) ((unsigned_4)(unsigned_1)(X) << ( 8 * (3 - (N)))) 361 #define V4_2(X,N) ((unsigned_4)(unsigned_2)(X) << (16 * (1 - (N)))) 362 363 #define V8_1(X,N) ((unsigned_8)(unsigned_1)(X) << ( 8 * (7 - (N)))) 364 #define V8_2(X,N) ((unsigned_8)(unsigned_2)(X) << (16 * (3 - (N)))) 365 #define V8_4(X,N) ((unsigned_8)(unsigned_4)(X) << (32 * (1 - (N)))) 366 367 #define V16_1(X,N) ((unsigned_16)(unsigned_1)(X) << ( 8 * (15 - (N)))) 368 #define V16_2(X,N) ((unsigned_16)(unsigned_2)(X) << (16 * (7 - (N)))) 369 #define V16_4(X,N) ((unsigned_16)(unsigned_4)(X) << (32 * (3 - (N)))) 370 #define V16_8(X,N) ((unsigned_16)(unsigned_8)(X) << (64 * (1 - (N)))) 371 372 373 /* Reverse - insert N sub-words into single word quantity */ 374 375 #define U2_1(I0,I1) (V2_1(I0,0) | V2_1(I1,1)) 376 #define U4_1(I0,I1,I2,I3) (V4_1(I0,0) | V4_1(I1,1) | V4_1(I2,2) | V4_1(I3,3)) 377 #define U8_1(I0,I1,I2,I3,I4,I5,I6,I7) \ 378 (V8_1(I0,0) | V8_1(I1,1) | V8_1(I2,2) | V8_1(I3,3) \ 379 | V8_1(I4,4) | V8_1(I5,5) | V8_1(I6,6) | V8_1(I7,7)) 380 #define U16_1(I0,I1,I2,I3,I4,I5,I6,I7,I8,I9,I10,I11,I12,I13,I14,I15) \ 381 (V16_1(I0,0) | V16_1(I1,1) | V16_1(I2,2) | V16_1(I3,3) \ 382 | V16_1(I4,4) | V16_1(I5,5) | V16_1(I6,6) | V16_1(I7,7) \ 383 | V16_1(I8,8) | V16_1(I9,9) | V16_1(I10,10) | V16_1(I11,11) \ 384 | V16_1(I12,12) | V16_1(I13,13) | V16_1(I14,14) | V16_1(I15,15)) 385 386 #define U4_2(I0,I1) (V4_2(I0,0) | V4_2(I1,1)) 387 #define U8_2(I0,I1,I2,I3) (V8_2(I0,0) | V8_2(I1,1) | V8_2(I2,2) | V8_2(I3,3)) 388 #define U16_2(I0,I1,I2,I3,I4,I5,I6,I7) \ 389 (V16_2(I0,0) | V16_2(I1,1) | V16_2(I2,2) | V16_2(I3,3) \ 390 | V16_2(I4,4) | V16_2(I5,5) | V16_2(I6,6) | V16_2(I7,7) ) 391 392 #define U8_4(I0,I1) (V8_4(I0,0) | V8_4(I1,1)) 393 #define U16_4(I0,I1,I2,I3) (V16_4(I0,0) | V16_4(I1,1) | V16_4(I2,2) | V16_4(I3,3)) 394 395 #define U16_8(I0,I1) (sim_endian_join_16 (I0, I1)) 396 397 398 #if (WITH_TARGET_WORD_BITSIZE == 64) 399 #define Vword_H(X) V8_H4(X) 400 #define Vword_L(X) V8_L4(X) 401 #endif 402 #if (WITH_TARGET_WORD_BITSIZE == 32) 403 #define Vword_H(X) V4_H2(X) 404 #define Vword_L(X) V4_L2(X) 405 #endif 406 407 408 409 410 #if H_REVEALS_MODULE_P (SIM_ENDIAN_INLINE) 411 #include "sim-endian.c" 412 #endif 413 414 #endif /* _SIM_ENDIAN_H_ */ 415