fpu_emulate.c revision 1.21.2.1
1 1.21.2.1 bouyer /* $NetBSD: fpu_emulate.c,v 1.21.2.1 2001/01/18 09:22:39 bouyer Exp $ */ 2 1.1 gwr 3 1.1 gwr /* 4 1.1 gwr * Copyright (c) 1995 Gordon W. Ross 5 1.3 briggs * some portion Copyright (c) 1995 Ken Nakata 6 1.1 gwr * All rights reserved. 7 1.1 gwr * 8 1.1 gwr * Redistribution and use in source and binary forms, with or without 9 1.1 gwr * modification, are permitted provided that the following conditions 10 1.1 gwr * are met: 11 1.1 gwr * 1. Redistributions of source code must retain the above copyright 12 1.1 gwr * notice, this list of conditions and the following disclaimer. 13 1.1 gwr * 2. Redistributions in binary form must reproduce the above copyright 14 1.1 gwr * notice, this list of conditions and the following disclaimer in the 15 1.1 gwr * documentation and/or other materials provided with the distribution. 16 1.1 gwr * 3. The name of the author may not be used to endorse or promote products 17 1.1 gwr * derived from this software without specific prior written permission. 18 1.1 gwr * 4. All advertising materials mentioning features or use of this software 19 1.1 gwr * must display the following acknowledgement: 20 1.1 gwr * This product includes software developed by Gordon Ross 21 1.1 gwr * 22 1.1 gwr * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR 23 1.1 gwr * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES 24 1.1 gwr * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. 25 1.1 gwr * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, 26 1.1 gwr * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT 27 1.1 gwr * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, 28 1.1 gwr * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY 29 1.1 gwr * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 30 1.1 gwr * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF 31 1.1 gwr * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 32 1.1 gwr */ 33 1.1 gwr 34 1.1 gwr /* 35 1.1 gwr * mc68881 emulator 36 1.1 gwr * XXX - Just a start at it for now... 37 1.1 gwr */ 38 1.20 jonathan 39 1.1 gwr #include <sys/types.h> 40 1.1 gwr #include <sys/signal.h> 41 1.5 briggs #include <sys/systm.h> 42 1.1 gwr #include <machine/frame.h> 43 1.1 gwr 44 1.21 briggs #if defined(DDB) && defined(DEBUG_FPE) 45 1.15 veego # include <m68k/db_machdep.h> 46 1.15 veego #endif 47 1.15 veego 48 1.3 briggs #include "fpu_emulate.h" 49 1.1 gwr 50 1.3 briggs static int fpu_emul_fmovmcr __P((struct fpemu *fe, struct instruction *insn)); 51 1.3 briggs static int fpu_emul_fmovm __P((struct fpemu *fe, struct instruction *insn)); 52 1.3 briggs static int fpu_emul_arith __P((struct fpemu *fe, struct instruction *insn)); 53 1.3 briggs static int fpu_emul_type1 __P((struct fpemu *fe, struct instruction *insn)); 54 1.3 briggs static int fpu_emul_brcc __P((struct fpemu *fe, struct instruction *insn)); 55 1.4 briggs static int test_cc __P((struct fpemu *fe, int pred)); 56 1.4 briggs static struct fpn *fpu_cmp __P((struct fpemu *fe)); 57 1.5 briggs 58 1.21 briggs #if DEBUG_FPE 59 1.21 briggs # define DUMP_INSN(insn) \ 60 1.21 briggs printf("fpu_emulate: insn={adv=%d,siz=%d,op=%04x,w1=%04x}\n", \ 61 1.3 briggs (insn)->is_advance, (insn)->is_datasize, \ 62 1.21 briggs (insn)->is_opcode, (insn)->is_word1) 63 1.21 briggs #else 64 1.21 briggs # define DUMP_INSN(insn) 65 1.3 briggs #endif 66 1.1 gwr 67 1.1 gwr /* 68 1.1 gwr * Emulate a floating-point instruction. 69 1.1 gwr * Return zero for success, else signal number. 70 1.1 gwr * (Typically: zero, SIGFPE, SIGILL, SIGSEGV) 71 1.1 gwr */ 72 1.3 briggs int 73 1.3 briggs fpu_emulate(frame, fpf) 74 1.3 briggs struct frame *frame; 75 1.3 briggs struct fpframe *fpf; 76 1.1 gwr { 77 1.4 briggs static struct instruction insn; 78 1.4 briggs static struct fpemu fe; 79 1.3 briggs int word, optype, sig; 80 1.3 briggs 81 1.21 briggs 82 1.4 briggs /* initialize insn.is_datasize to tell it is *not* initialized */ 83 1.3 briggs insn.is_datasize = -1; 84 1.21 briggs 85 1.3 briggs fe.fe_frame = frame; 86 1.3 briggs fe.fe_fpframe = fpf; 87 1.3 briggs fe.fe_fpsr = fpf->fpf_fpsr; 88 1.3 briggs fe.fe_fpcr = fpf->fpf_fpcr; 89 1.1 gwr 90 1.21 briggs #if DEBUG_FPE 91 1.21 briggs printf("ENTERING fpu_emulate: FPSR=%08x, FPCR=%08x\n", 92 1.21 briggs fe.fe_fpsr, fe.fe_fpcr); 93 1.1 gwr #endif 94 1.1 gwr 95 1.13 gwr /* always set this (to avoid a warning) */ 96 1.21 briggs insn.is_pc = frame->f_pc; 97 1.21 briggs insn.is_nextpc = 0; 98 1.8 scottr if (frame->f_format == 4) { 99 1.8 scottr /* 100 1.8 scottr * A format 4 is generated by the 68{EC,LC}040. The PC is 101 1.8 scottr * already set to the instruction following the faulting 102 1.8 scottr * instruction. We need to calculate that, anyway. The 103 1.8 scottr * fslw is the PC of the faulted instruction, which is what 104 1.8 scottr * we expect to be in f_pc. 105 1.8 scottr * 106 1.8 scottr * XXX - This is a hack; it assumes we at least know the 107 1.21.2.1 bouyer * sizes of all instructions we run across. 108 1.21.2.1 bouyer * XXX TODO: This may not be true, so we might want to save the PC 109 1.21.2.1 bouyer * in order to restore it later. 110 1.8 scottr */ 111 1.21.2.1 bouyer /* insn.is_nextpc = frame->f_pc; */ 112 1.21 briggs insn.is_pc = frame->f_fmt4.f_fslw; 113 1.21.2.1 bouyer frame->f_pc = insn.is_pc; 114 1.8 scottr } 115 1.8 scottr 116 1.21 briggs word = fusword((void *) (insn.is_pc)); 117 1.3 briggs if (word < 0) { 118 1.3 briggs #ifdef DEBUG 119 1.21 briggs printf("fpu_emulate: fault reading opcode\n"); 120 1.3 briggs #endif 121 1.3 briggs return SIGSEGV; 122 1.3 briggs } 123 1.3 briggs 124 1.3 briggs if ((word & 0xf000) != 0xf000) { 125 1.3 briggs #ifdef DEBUG 126 1.21 briggs printf("fpu_emulate: not coproc. insn.: opcode=0x%x\n", word); 127 1.1 gwr #endif 128 1.3 briggs return SIGILL; 129 1.3 briggs } 130 1.1 gwr 131 1.21 briggs if ((word & 0x0E00) != 0x0200) { 132 1.3 briggs #ifdef DEBUG 133 1.21 briggs printf("fpu_emulate: bad coproc. id: opcode=0x%x\n", word); 134 1.3 briggs #endif 135 1.3 briggs return SIGILL; 136 1.3 briggs } 137 1.1 gwr 138 1.3 briggs insn.is_opcode = word; 139 1.3 briggs optype = (word & 0x01C0); 140 1.1 gwr 141 1.21 briggs word = fusword((void *) (insn.is_pc + 2)); 142 1.3 briggs if (word < 0) { 143 1.3 briggs #ifdef DEBUG 144 1.21 briggs printf("fpu_emulate: fault reading word1\n"); 145 1.1 gwr #endif 146 1.3 briggs return SIGSEGV; 147 1.3 briggs } 148 1.3 briggs insn.is_word1 = word; 149 1.3 briggs /* all FPU instructions are at least 4-byte long */ 150 1.3 briggs insn.is_advance = 4; 151 1.3 briggs 152 1.3 briggs DUMP_INSN(&insn); 153 1.3 briggs 154 1.3 briggs /* 155 1.3 briggs * Which family (or type) of opcode is it? 156 1.3 briggs * Tests ordered by likelihood (hopefully). 157 1.3 briggs * Certainly, type 0 is the most common. 158 1.3 briggs */ 159 1.3 briggs if (optype == 0x0000) { 160 1.3 briggs /* type=0: generic */ 161 1.3 briggs if ((word & 0xc000) == 0xc000) { 162 1.21 briggs #if DEBUG_FPE 163 1.21 briggs printf("fpu_emulate: fmovm FPr\n"); 164 1.21 briggs #endif 165 1.3 briggs sig = fpu_emul_fmovm(&fe, &insn); 166 1.3 briggs } else if ((word & 0xc000) == 0x8000) { 167 1.21 briggs #if DEBUG_FPE 168 1.21 briggs printf("fpu_emulate: fmovm FPcr\n"); 169 1.21 briggs #endif 170 1.3 briggs sig = fpu_emul_fmovmcr(&fe, &insn); 171 1.3 briggs } else if ((word & 0xe000) == 0x6000) { 172 1.3 briggs /* fstore = fmove FPn,mem */ 173 1.21 briggs #if DEBUG_FPE 174 1.21 briggs printf("fpu_emulate: fmove to mem\n"); 175 1.21 briggs #endif 176 1.3 briggs sig = fpu_emul_fstore(&fe, &insn); 177 1.3 briggs } else if ((word & 0xfc00) == 0x5c00) { 178 1.3 briggs /* fmovecr */ 179 1.21 briggs #if DEBUG_FPE 180 1.21 briggs printf("fpu_emulate: fmovecr\n"); 181 1.21 briggs #endif 182 1.3 briggs sig = fpu_emul_fmovecr(&fe, &insn); 183 1.3 briggs } else if ((word & 0xa07f) == 0x26) { 184 1.3 briggs /* fscale */ 185 1.21 briggs #if DEBUG_FPE 186 1.21 briggs printf("fpu_emulate: fscale\n"); 187 1.21 briggs #endif 188 1.3 briggs sig = fpu_emul_fscale(&fe, &insn); 189 1.3 briggs } else { 190 1.21 briggs #if DEBUG_FPE 191 1.21 briggs printf("fpu_emulate: other type0\n"); 192 1.21 briggs #endif 193 1.3 briggs /* all other type0 insns are arithmetic */ 194 1.3 briggs sig = fpu_emul_arith(&fe, &insn); 195 1.1 gwr } 196 1.3 briggs if (sig == 0) { 197 1.21 briggs #if DEBUG_FPE 198 1.21 briggs printf("fpu_emulate: type 0 returned 0\n"); 199 1.21 briggs #endif 200 1.3 briggs sig = fpu_upd_excp(&fe); 201 1.1 gwr } 202 1.3 briggs } else if (optype == 0x0080 || optype == 0x00C0) { 203 1.3 briggs /* type=2 or 3: fbcc, short or long disp. */ 204 1.21 briggs #if DEBUG_FPE 205 1.21 briggs printf("fpu_emulate: fbcc %s\n", 206 1.21 briggs (optype & 0x40) ? "long" : "short"); 207 1.21 briggs #endif 208 1.3 briggs sig = fpu_emul_brcc(&fe, &insn); 209 1.3 briggs } else if (optype == 0x0040) { 210 1.3 briggs /* type=1: fdbcc, fscc, ftrapcc */ 211 1.21 briggs #if DEBUG_FPE 212 1.21 briggs printf("fpu_emulate: type1\n"); 213 1.21 briggs #endif 214 1.3 briggs sig = fpu_emul_type1(&fe, &insn); 215 1.3 briggs } else { 216 1.3 briggs /* type=4: fsave (privileged) */ 217 1.3 briggs /* type=5: frestore (privileged) */ 218 1.3 briggs /* type=6: reserved */ 219 1.3 briggs /* type=7: reserved */ 220 1.3 briggs #ifdef DEBUG 221 1.21 briggs printf("fpu_emulate: bad opcode type: opcode=0x%x\n", insn.is_opcode); 222 1.1 gwr #endif 223 1.3 briggs sig = SIGILL; 224 1.3 briggs } 225 1.3 briggs 226 1.3 briggs DUMP_INSN(&insn); 227 1.1 gwr 228 1.17 is /* 229 1.17 is * XXX it is not clear to me, if we should progress the PC always, 230 1.17 is * for SIGFPE || 0, or only for 0; however, without SIGFPE, we 231 1.17 is * don't pass the signalling regression tests. -is 232 1.17 is */ 233 1.17 is if ((sig == 0) || (sig == SIGFPE)) 234 1.3 briggs frame->f_pc += insn.is_advance; 235 1.1 gwr #if defined(DDB) && defined(DEBUG) 236 1.3 briggs else { 237 1.21 briggs printf("fpu_emulate: sig=%d, opcode=%x, word1=%x\n", 238 1.3 briggs sig, insn.is_opcode, insn.is_word1); 239 1.15 veego kdb_trap(-1, (db_regs_t *)&frame); 240 1.3 briggs } 241 1.1 gwr #endif 242 1.21.2.1 bouyer #if 0 /* XXX something is wrong */ 243 1.21.2.1 bouyer if (frame->f_format == 4) { 244 1.21 briggs /* XXX Restore PC -- 68{EC,LC}040 only */ 245 1.21.2.1 bouyer if (insn.is_nextpc) 246 1.21.2.1 bouyer frame->f_pc = insn.is_nextpc; 247 1.21.2.1 bouyer } 248 1.21.2.1 bouyer #endif 249 1.1 gwr 250 1.21 briggs #if DEBUG_FPE 251 1.21 briggs printf("EXITING fpu_emulate: w/FPSR=%08x, FPCR=%08x\n", 252 1.21 briggs fe.fe_fpsr, fe.fe_fpcr); 253 1.21 briggs #endif 254 1.3 briggs 255 1.3 briggs return (sig); 256 1.1 gwr } 257 1.1 gwr 258 1.3 briggs /* update accrued exception bits and see if there's an FP exception */ 259 1.3 briggs int 260 1.3 briggs fpu_upd_excp(fe) 261 1.3 briggs struct fpemu *fe; 262 1.1 gwr { 263 1.3 briggs u_int fpsr; 264 1.3 briggs u_int fpcr; 265 1.3 briggs 266 1.3 briggs fpsr = fe->fe_fpsr; 267 1.3 briggs fpcr = fe->fe_fpcr; 268 1.3 briggs /* update fpsr accrued exception bits; each insn doesn't have to 269 1.3 briggs update this */ 270 1.3 briggs if (fpsr & (FPSR_BSUN | FPSR_SNAN | FPSR_OPERR)) { 271 1.3 briggs fpsr |= FPSR_AIOP; 272 1.3 briggs } 273 1.3 briggs if (fpsr & FPSR_OVFL) { 274 1.3 briggs fpsr |= FPSR_AOVFL; 275 1.3 briggs } 276 1.3 briggs if ((fpsr & FPSR_UNFL) && (fpsr & FPSR_INEX2)) { 277 1.3 briggs fpsr |= FPSR_AUNFL; 278 1.3 briggs } 279 1.3 briggs if (fpsr & FPSR_DZ) { 280 1.3 briggs fpsr |= FPSR_ADZ; 281 1.3 briggs } 282 1.3 briggs if (fpsr & (FPSR_INEX1 | FPSR_INEX2 | FPSR_OVFL)) { 283 1.3 briggs fpsr |= FPSR_AINEX; 284 1.3 briggs } 285 1.1 gwr 286 1.3 briggs fe->fe_fpframe->fpf_fpsr = fe->fe_fpsr = fpsr; 287 1.1 gwr 288 1.3 briggs return (fpsr & fpcr & FPSR_EXCP) ? SIGFPE : 0; 289 1.3 briggs } 290 1.1 gwr 291 1.3 briggs /* update fpsr according to fp (= result of an fp op) */ 292 1.3 briggs u_int 293 1.3 briggs fpu_upd_fpsr(fe, fp) 294 1.3 briggs struct fpemu *fe; 295 1.3 briggs struct fpn *fp; 296 1.3 briggs { 297 1.3 briggs u_int fpsr; 298 1.1 gwr 299 1.21 briggs #if DEBUG_FPE 300 1.21 briggs printf("fpu_upd_fpsr: previous fpsr=%08x\n", fe->fe_fpsr); 301 1.21 briggs #endif 302 1.3 briggs /* clear all condition code */ 303 1.3 briggs fpsr = fe->fe_fpsr & ~FPSR_CCB; 304 1.1 gwr 305 1.21 briggs #if DEBUG_FPE 306 1.21 briggs printf("fpu_upd_fpsr: result is a "); 307 1.21 briggs #endif 308 1.3 briggs if (fp->fp_sign) { 309 1.21 briggs #if DEBUG_FPE 310 1.21 briggs printf("negative "); 311 1.21 briggs #endif 312 1.3 briggs fpsr |= FPSR_NEG; 313 1.21 briggs #if DEBUG_FPE 314 1.3 briggs } else { 315 1.21 briggs printf("positive "); 316 1.21 briggs #endif 317 1.3 briggs } 318 1.3 briggs 319 1.3 briggs switch (fp->fp_class) { 320 1.3 briggs case FPC_SNAN: 321 1.21 briggs #if DEBUG_FPE 322 1.21 briggs printf("signaling NAN\n"); 323 1.21 briggs #endif 324 1.3 briggs fpsr |= (FPSR_NAN | FPSR_SNAN); 325 1.3 briggs break; 326 1.3 briggs case FPC_QNAN: 327 1.21 briggs #if DEBUG_FPE 328 1.21 briggs printf("quiet NAN\n"); 329 1.21 briggs #endif 330 1.3 briggs fpsr |= FPSR_NAN; 331 1.3 briggs break; 332 1.3 briggs case FPC_ZERO: 333 1.21 briggs #if DEBUG_FPE 334 1.21 briggs printf("Zero\n"); 335 1.21 briggs #endif 336 1.3 briggs fpsr |= FPSR_ZERO; 337 1.3 briggs break; 338 1.3 briggs case FPC_INF: 339 1.21 briggs #if DEBUG_FPE 340 1.21 briggs printf("Inf\n"); 341 1.21 briggs #endif 342 1.3 briggs fpsr |= FPSR_INF; 343 1.3 briggs break; 344 1.3 briggs default: 345 1.21 briggs #if DEBUG_FPE 346 1.21 briggs printf("Number\n"); 347 1.21 briggs #endif 348 1.3 briggs /* anything else is treated as if it is a number */ 349 1.3 briggs break; 350 1.3 briggs } 351 1.1 gwr 352 1.3 briggs fe->fe_fpsr = fe->fe_fpframe->fpf_fpsr = fpsr; 353 1.1 gwr 354 1.21 briggs #if DEBUG_FPE 355 1.21 briggs printf("fpu_upd_fpsr: new fpsr=%08x\n", fe->fe_fpframe->fpf_fpsr); 356 1.21 briggs #endif 357 1.1 gwr 358 1.3 briggs return fpsr; 359 1.3 briggs } 360 1.1 gwr 361 1.3 briggs static int 362 1.3 briggs fpu_emul_fmovmcr(fe, insn) 363 1.3 briggs struct fpemu *fe; 364 1.3 briggs struct instruction *insn; 365 1.3 briggs { 366 1.3 briggs struct frame *frame = fe->fe_frame; 367 1.3 briggs struct fpframe *fpf = fe->fe_fpframe; 368 1.5 briggs int sig; 369 1.5 briggs int reglist; 370 1.3 briggs int fpu_to_mem; 371 1.3 briggs 372 1.3 briggs /* move to/from control registers */ 373 1.3 briggs reglist = (insn->is_word1 & 0x1c00) >> 10; 374 1.3 briggs /* Bit 13 selects direction (FPU to/from Mem) */ 375 1.3 briggs fpu_to_mem = insn->is_word1 & 0x2000; 376 1.3 briggs 377 1.3 briggs insn->is_datasize = 4; 378 1.3 briggs insn->is_advance = 4; 379 1.21 briggs sig = fpu_decode_ea(frame, insn, &insn->is_ea, insn->is_opcode); 380 1.3 briggs if (sig) { return sig; } 381 1.3 briggs 382 1.3 briggs if (reglist != 1 && reglist != 2 && reglist != 4 && 383 1.21 briggs (insn->is_ea.ea_flags & EA_DIRECT)) { 384 1.3 briggs /* attempted to copy more than one FPcr to CPU regs */ 385 1.3 briggs #ifdef DEBUG 386 1.21 briggs printf("fpu_emul_fmovmcr: tried to copy too many FPcr\n"); 387 1.3 briggs #endif 388 1.3 briggs return SIGILL; 389 1.3 briggs } 390 1.1 gwr 391 1.3 briggs if (reglist & 4) { 392 1.3 briggs /* fpcr */ 393 1.21 briggs if ((insn->is_ea.ea_flags & EA_DIRECT) && 394 1.21 briggs insn->is_ea.ea_regnum >= 8 /* address reg */) { 395 1.3 briggs /* attempted to copy FPCR to An */ 396 1.3 briggs #ifdef DEBUG 397 1.21 briggs printf("fpu_emul_fmovmcr: tried to copy FPCR from/to A%d\n", 398 1.21 briggs insn->is_ea.ea_regnum & 7); 399 1.1 gwr #endif 400 1.3 briggs return SIGILL; 401 1.3 briggs } 402 1.3 briggs if (fpu_to_mem) { 403 1.21 briggs sig = fpu_store_ea(frame, insn, &insn->is_ea, 404 1.3 briggs (char *)&fpf->fpf_fpcr); 405 1.3 briggs } else { 406 1.21 briggs sig = fpu_load_ea(frame, insn, &insn->is_ea, 407 1.3 briggs (char *)&fpf->fpf_fpcr); 408 1.3 briggs } 409 1.3 briggs } 410 1.3 briggs if (sig) { return sig; } 411 1.1 gwr 412 1.3 briggs if (reglist & 2) { 413 1.3 briggs /* fpsr */ 414 1.21 briggs if ((insn->is_ea.ea_flags & EA_DIRECT) && 415 1.21 briggs insn->is_ea.ea_regnum >= 8 /* address reg */) { 416 1.3 briggs /* attempted to copy FPSR to An */ 417 1.3 briggs #ifdef DEBUG 418 1.21 briggs printf("fpu_emul_fmovmcr: tried to copy FPSR from/to A%d\n", 419 1.21 briggs insn->is_ea.ea_regnum & 7); 420 1.3 briggs #endif 421 1.3 briggs return SIGILL; 422 1.3 briggs } 423 1.3 briggs if (fpu_to_mem) { 424 1.21 briggs sig = fpu_store_ea(frame, insn, &insn->is_ea, 425 1.3 briggs (char *)&fpf->fpf_fpsr); 426 1.3 briggs } else { 427 1.21 briggs sig = fpu_load_ea(frame, insn, &insn->is_ea, 428 1.3 briggs (char *)&fpf->fpf_fpsr); 429 1.3 briggs } 430 1.3 briggs } 431 1.3 briggs if (sig) { return sig; } 432 1.3 briggs 433 1.3 briggs if (reglist & 1) { 434 1.3 briggs /* fpiar - can be moved to/from An */ 435 1.3 briggs if (fpu_to_mem) { 436 1.21 briggs sig = fpu_store_ea(frame, insn, &insn->is_ea, 437 1.3 briggs (char *)&fpf->fpf_fpiar); 438 1.3 briggs } else { 439 1.21 briggs sig = fpu_load_ea(frame, insn, &insn->is_ea, 440 1.3 briggs (char *)&fpf->fpf_fpiar); 441 1.3 briggs } 442 1.3 briggs } 443 1.3 briggs return sig; 444 1.1 gwr } 445 1.1 gwr 446 1.1 gwr /* 447 1.3 briggs * type 0: fmovem 448 1.3 briggs * Separated out of fpu_emul_type0 for efficiency. 449 1.1 gwr * In this function, we know: 450 1.3 briggs * (opcode & 0x01C0) == 0 451 1.3 briggs * (word1 & 0x8000) == 0x8000 452 1.3 briggs * 453 1.3 briggs * No conversion or rounding is done by this instruction, 454 1.3 briggs * and the FPSR is not affected. 455 1.1 gwr */ 456 1.3 briggs static int 457 1.3 briggs fpu_emul_fmovm(fe, insn) 458 1.3 briggs struct fpemu *fe; 459 1.3 briggs struct instruction *insn; 460 1.1 gwr { 461 1.3 briggs struct frame *frame = fe->fe_frame; 462 1.3 briggs struct fpframe *fpf = fe->fe_fpframe; 463 1.3 briggs int word1, sig; 464 1.3 briggs int reglist, regmask, regnum; 465 1.3 briggs int fpu_to_mem, order; 466 1.7 scottr int w1_post_incr; 467 1.3 briggs int *fpregs; 468 1.3 briggs 469 1.3 briggs insn->is_advance = 4; 470 1.3 briggs insn->is_datasize = 12; 471 1.3 briggs word1 = insn->is_word1; 472 1.3 briggs 473 1.3 briggs /* Bit 13 selects direction (FPU to/from Mem) */ 474 1.3 briggs fpu_to_mem = word1 & 0x2000; 475 1.3 briggs 476 1.3 briggs /* 477 1.3 briggs * Bits 12,11 select register list mode: 478 1.3 briggs * 0,0: Static reg list, pre-decr. 479 1.3 briggs * 0,1: Dynamic reg list, pre-decr. 480 1.3 briggs * 1,0: Static reg list, post-incr. 481 1.3 briggs * 1,1: Dynamic reg list, post-incr 482 1.3 briggs */ 483 1.3 briggs w1_post_incr = word1 & 0x1000; 484 1.3 briggs if (word1 & 0x0800) { 485 1.3 briggs /* dynamic reg list */ 486 1.3 briggs reglist = frame->f_regs[(word1 & 0x70) >> 4]; 487 1.3 briggs } else { 488 1.3 briggs reglist = word1; 489 1.3 briggs } 490 1.3 briggs reglist &= 0xFF; 491 1.3 briggs 492 1.3 briggs /* Get effective address. (modreg=opcode&077) */ 493 1.21 briggs sig = fpu_decode_ea(frame, insn, &insn->is_ea, insn->is_opcode); 494 1.3 briggs if (sig) { return sig; } 495 1.3 briggs 496 1.3 briggs /* Get address of soft coprocessor regs. */ 497 1.3 briggs fpregs = &fpf->fpf_regs[0]; 498 1.3 briggs 499 1.21 briggs if (insn->is_ea.ea_flags & EA_PREDECR) { 500 1.3 briggs regnum = 7; 501 1.3 briggs order = -1; 502 1.3 briggs } else { 503 1.3 briggs regnum = 0; 504 1.3 briggs order = 1; 505 1.3 briggs } 506 1.3 briggs 507 1.21 briggs regmask = 0x80; 508 1.3 briggs while ((0 <= regnum) && (regnum < 8)) { 509 1.3 briggs if (regmask & reglist) { 510 1.3 briggs if (fpu_to_mem) { 511 1.21 briggs sig = fpu_store_ea(frame, insn, &insn->is_ea, 512 1.3 briggs (char*)&fpregs[regnum * 3]); 513 1.21 briggs #if DEBUG_FPE 514 1.21 briggs printf("fpu_emul_fmovm: FP%d (%08x,%08x,%08x) saved\n", 515 1.21 briggs regnum, fpregs[regnum * 3], fpregs[regnum * 3 + 1], 516 1.21 briggs fpregs[regnum * 3 + 2]); 517 1.21 briggs #endif 518 1.3 briggs } else { /* mem to fpu */ 519 1.21 briggs sig = fpu_load_ea(frame, insn, &insn->is_ea, 520 1.3 briggs (char*)&fpregs[regnum * 3]); 521 1.21 briggs #if DEBUG_FPE 522 1.21 briggs printf("fpu_emul_fmovm: FP%d (%08x,%08x,%08x) loaded\n", 523 1.21 briggs regnum, fpregs[regnum * 3], fpregs[regnum * 3 + 1], 524 1.21 briggs fpregs[regnum * 3 + 2]); 525 1.21 briggs #endif 526 1.3 briggs } 527 1.3 briggs if (sig) { break; } 528 1.3 briggs } 529 1.3 briggs regnum += order; 530 1.21 briggs regmask >>= 1; 531 1.3 briggs } 532 1.1 gwr 533 1.3 briggs return sig; 534 1.1 gwr } 535 1.1 gwr 536 1.3 briggs static struct fpn * 537 1.3 briggs fpu_cmp(fe) 538 1.3 briggs struct fpemu *fe; 539 1.1 gwr { 540 1.3 briggs struct fpn *x = &fe->fe_f1, *y = &fe->fe_f2; 541 1.1 gwr 542 1.3 briggs /* take care of special cases */ 543 1.3 briggs if (x->fp_class < 0 || y->fp_class < 0) { 544 1.3 briggs /* if either of two is a SNAN, result is SNAN */ 545 1.3 briggs x->fp_class = (y->fp_class < x->fp_class) ? y->fp_class : x->fp_class; 546 1.3 briggs } else if (x->fp_class == FPC_INF) { 547 1.3 briggs if (y->fp_class == FPC_INF) { 548 1.3 briggs /* both infinities */ 549 1.3 briggs if (x->fp_sign == y->fp_sign) { 550 1.3 briggs x->fp_class = FPC_ZERO; /* return a signed zero */ 551 1.3 briggs } else { 552 1.3 briggs x->fp_class = FPC_NUM; /* return a faked number w/x's sign */ 553 1.3 briggs x->fp_exp = 16383; 554 1.3 briggs x->fp_mant[0] = FP_1; 555 1.3 briggs } 556 1.3 briggs } else { 557 1.3 briggs /* y is a number */ 558 1.3 briggs x->fp_class = FPC_NUM; /* return a forged number w/x's sign */ 559 1.3 briggs x->fp_exp = 16383; 560 1.3 briggs x->fp_mant[0] = FP_1; 561 1.3 briggs } 562 1.3 briggs } else if (y->fp_class == FPC_INF) { 563 1.3 briggs /* x is a Num but y is an Inf */ 564 1.3 briggs /* return a forged number w/y's sign inverted */ 565 1.3 briggs x->fp_class = FPC_NUM; 566 1.3 briggs x->fp_sign = !y->fp_sign; 567 1.3 briggs x->fp_exp = 16383; 568 1.3 briggs x->fp_mant[0] = FP_1; 569 1.3 briggs } else { 570 1.3 briggs /* x and y are both numbers or zeros, or pair of a number and a zero */ 571 1.3 briggs y->fp_sign = !y->fp_sign; 572 1.3 briggs x = fpu_add(fe); /* (x - y) */ 573 1.1 gwr /* 574 1.3 briggs * FCMP does not set Inf bit in CC, so return a forged number 575 1.3 briggs * (value doesn't matter) if Inf is the result of fsub. 576 1.1 gwr */ 577 1.3 briggs if (x->fp_class == FPC_INF) { 578 1.3 briggs x->fp_class = FPC_NUM; 579 1.3 briggs x->fp_exp = 16383; 580 1.3 briggs x->fp_mant[0] = FP_1; 581 1.1 gwr } 582 1.3 briggs } 583 1.3 briggs return x; 584 1.1 gwr } 585 1.1 gwr 586 1.1 gwr /* 587 1.3 briggs * arithmetic oprations 588 1.1 gwr */ 589 1.3 briggs static int 590 1.3 briggs fpu_emul_arith(fe, insn) 591 1.3 briggs struct fpemu *fe; 592 1.3 briggs struct instruction *insn; 593 1.1 gwr { 594 1.3 briggs struct frame *frame = fe->fe_frame; 595 1.3 briggs u_int *fpregs = &(fe->fe_fpframe->fpf_regs[0]); 596 1.3 briggs struct fpn *res; 597 1.3 briggs int word1, sig = 0; 598 1.3 briggs int regnum, format; 599 1.3 briggs int discard_result = 0; 600 1.3 briggs u_int buf[3]; 601 1.21 briggs #if DEBUG_FPE 602 1.3 briggs int flags; 603 1.3 briggs char regname; 604 1.21 briggs #endif 605 1.16 is 606 1.16 is fe->fe_fpsr &= ~FPSR_EXCP; 607 1.3 briggs 608 1.3 briggs DUMP_INSN(insn); 609 1.3 briggs 610 1.21 briggs #if DEBUG_FPE 611 1.21 briggs printf("fpu_emul_arith: FPSR = %08x, FPCR = %08x\n", 612 1.21 briggs fe->fe_fpsr, fe->fe_fpcr); 613 1.21 briggs #endif 614 1.3 briggs 615 1.3 briggs word1 = insn->is_word1; 616 1.3 briggs format = (word1 >> 10) & 7; 617 1.3 briggs regnum = (word1 >> 7) & 7; 618 1.3 briggs 619 1.3 briggs /* fetch a source operand : may not be used */ 620 1.21 briggs #if DEBUG_FPE 621 1.21 briggs printf("fpu_emul_arith: dst/src FP%d=%08x,%08x,%08x\n", 622 1.21 briggs regnum, fpregs[regnum*3], fpregs[regnum*3+1], 623 1.21 briggs fpregs[regnum*3+2]); 624 1.21 briggs #endif 625 1.21 briggs 626 1.3 briggs fpu_explode(fe, &fe->fe_f1, FTYPE_EXT, &fpregs[regnum * 3]); 627 1.3 briggs 628 1.3 briggs DUMP_INSN(insn); 629 1.3 briggs 630 1.3 briggs /* get the other operand which is always the source */ 631 1.3 briggs if ((word1 & 0x4000) == 0) { 632 1.21 briggs #if DEBUG_FPE 633 1.21 briggs printf("fpu_emul_arith: FP%d op FP%d => FP%d\n", 634 1.21 briggs format, regnum, regnum); 635 1.21 briggs printf("fpu_emul_arith: src opr FP%d=%08x,%08x,%08x\n", 636 1.21 briggs format, fpregs[format*3], fpregs[format*3+1], 637 1.21 briggs fpregs[format*3+2]); 638 1.21 briggs #endif 639 1.3 briggs fpu_explode(fe, &fe->fe_f2, FTYPE_EXT, &fpregs[format * 3]); 640 1.3 briggs } else { 641 1.3 briggs /* the operand is in memory */ 642 1.3 briggs if (format == FTYPE_DBL) { 643 1.3 briggs insn->is_datasize = 8; 644 1.3 briggs } else if (format == FTYPE_SNG || format == FTYPE_LNG) { 645 1.3 briggs insn->is_datasize = 4; 646 1.3 briggs } else if (format == FTYPE_WRD) { 647 1.3 briggs insn->is_datasize = 2; 648 1.3 briggs } else if (format == FTYPE_BYT) { 649 1.3 briggs insn->is_datasize = 1; 650 1.3 briggs } else if (format == FTYPE_EXT) { 651 1.3 briggs insn->is_datasize = 12; 652 1.3 briggs } else { 653 1.3 briggs /* invalid or unsupported operand format */ 654 1.3 briggs sig = SIGFPE; 655 1.3 briggs return sig; 656 1.3 briggs } 657 1.1 gwr 658 1.3 briggs /* Get effective address. (modreg=opcode&077) */ 659 1.21 briggs sig = fpu_decode_ea(frame, insn, &insn->is_ea, insn->is_opcode); 660 1.3 briggs if (sig) { 661 1.21 briggs #if DEBUG_FPE 662 1.21 briggs printf("fpu_emul_arith: error in fpu_decode_ea\n"); 663 1.21 briggs #endif 664 1.3 briggs return sig; 665 1.3 briggs } 666 1.1 gwr 667 1.3 briggs DUMP_INSN(insn); 668 1.1 gwr 669 1.21 briggs #if DEBUG_FPE 670 1.21 briggs printf("fpu_emul_arith: addr mode = "); 671 1.21 briggs flags = insn->is_ea.ea_flags; 672 1.21 briggs regname = (insn->is_ea.ea_regnum & 8) ? 'a' : 'd'; 673 1.21 briggs 674 1.21 briggs if (flags & EA_DIRECT) { 675 1.21 briggs printf("%c%d\n", 676 1.21 briggs regname, insn->is_ea.ea_regnum & 7); 677 1.21 briggs } else if (flags & EA_PC_REL) { 678 1.21 briggs if (flags & EA_OFFSET) { 679 1.21 briggs printf("pc@(%d)\n", insn->is_ea.ea_offset); 680 1.3 briggs } else if (flags & EA_INDEXED) { 681 1.21 briggs printf("pc@(...)\n"); 682 1.21 briggs } 683 1.21 briggs } else if (flags & EA_PREDECR) { 684 1.21 briggs printf("%c%d@-\n", 685 1.21 briggs regname, insn->is_ea.ea_regnum & 7); 686 1.21 briggs } else if (flags & EA_POSTINCR) { 687 1.21 briggs printf("%c%d@+\n", regname, insn->is_ea.ea_regnum & 7); 688 1.21 briggs } else if (flags & EA_OFFSET) { 689 1.21 briggs printf("%c%d@(%d)\n", regname, insn->is_ea.ea_regnum & 7, 690 1.21 briggs insn->is_ea.ea_offset); 691 1.21 briggs } else if (flags & EA_INDEXED) { 692 1.21 briggs printf("%c%d@(...)\n", regname, insn->is_ea.ea_regnum & 7); 693 1.21 briggs } else if (flags & EA_ABS) { 694 1.21 briggs printf("0x%08x\n", insn->is_ea.ea_absaddr); 695 1.21 briggs } else if (flags & EA_IMMED) { 696 1.3 briggs 697 1.21 briggs printf("#0x%08x,%08x,%08x\n", insn->is_ea.ea_immed[0], 698 1.21 briggs insn->is_ea.ea_immed[1], insn->is_ea.ea_immed[2]); 699 1.21 briggs } else { 700 1.21 briggs printf("%c%d@\n", regname, insn->is_ea.ea_regnum & 7); 701 1.21 briggs } 702 1.21 briggs #endif /* DEBUG_FPE */ 703 1.3 briggs 704 1.21 briggs fpu_load_ea(frame, insn, &insn->is_ea, (char*)buf); 705 1.3 briggs if (format == FTYPE_WRD) { 706 1.3 briggs /* sign-extend */ 707 1.3 briggs buf[0] &= 0xffff; 708 1.3 briggs if (buf[0] & 0x8000) { 709 1.3 briggs buf[0] |= 0xffff0000; 710 1.3 briggs } 711 1.3 briggs format = FTYPE_LNG; 712 1.3 briggs } else if (format == FTYPE_BYT) { 713 1.3 briggs /* sign-extend */ 714 1.3 briggs buf[0] &= 0xff; 715 1.3 briggs if (buf[0] & 0x80) { 716 1.3 briggs buf[0] |= 0xffffff00; 717 1.3 briggs } 718 1.3 briggs format = FTYPE_LNG; 719 1.3 briggs } 720 1.21 briggs #if DEBUG_FPE 721 1.21 briggs printf("fpu_emul_arith: src = %08x %08x %08x, siz = %d\n", 722 1.21 briggs buf[0], buf[1], buf[2], insn->is_datasize); 723 1.21 briggs #endif 724 1.3 briggs fpu_explode(fe, &fe->fe_f2, format, buf); 725 1.3 briggs } 726 1.1 gwr 727 1.3 briggs DUMP_INSN(insn); 728 1.1 gwr 729 1.3 briggs /* An arithmetic instruction emulate function has a prototype of 730 1.3 briggs * struct fpn *fpu_op(struct fpemu *); 731 1.3 briggs 732 1.3 briggs * 1) If the instruction is monadic, then fpu_op() must use 733 1.3 briggs * fe->fe_f2 as its operand, and return a pointer to the 734 1.3 briggs * result. 735 1.3 briggs 736 1.3 briggs * 2) If the instruction is diadic, then fpu_op() must use 737 1.3 briggs * fe->fe_f1 and fe->fe_f2 as its two operands, and return a 738 1.3 briggs * pointer to the result. 739 1.3 briggs 740 1.3 briggs */ 741 1.6 leo res = 0; 742 1.3 briggs switch (word1 & 0x3f) { 743 1.3 briggs case 0x00: /* fmove */ 744 1.3 briggs res = &fe->fe_f2; 745 1.3 briggs break; 746 1.3 briggs 747 1.3 briggs case 0x01: /* fint */ 748 1.3 briggs res = fpu_int(fe); 749 1.3 briggs break; 750 1.3 briggs 751 1.3 briggs case 0x02: /* fsinh */ 752 1.3 briggs res = fpu_sinh(fe); 753 1.3 briggs break; 754 1.3 briggs 755 1.3 briggs case 0x03: /* fintrz */ 756 1.3 briggs res = fpu_intrz(fe); 757 1.3 briggs break; 758 1.3 briggs 759 1.3 briggs case 0x04: /* fsqrt */ 760 1.3 briggs res = fpu_sqrt(fe); 761 1.3 briggs break; 762 1.3 briggs 763 1.3 briggs case 0x06: /* flognp1 */ 764 1.3 briggs res = fpu_lognp1(fe); 765 1.3 briggs break; 766 1.3 briggs 767 1.3 briggs case 0x08: /* fetoxm1 */ 768 1.3 briggs res = fpu_etoxm1(fe); 769 1.3 briggs break; 770 1.3 briggs 771 1.3 briggs case 0x09: /* ftanh */ 772 1.3 briggs res = fpu_tanh(fe); 773 1.3 briggs break; 774 1.3 briggs 775 1.3 briggs case 0x0A: /* fatan */ 776 1.3 briggs res = fpu_atan(fe); 777 1.3 briggs break; 778 1.3 briggs 779 1.3 briggs case 0x0C: /* fasin */ 780 1.3 briggs res = fpu_asin(fe); 781 1.3 briggs break; 782 1.3 briggs 783 1.3 briggs case 0x0D: /* fatanh */ 784 1.3 briggs res = fpu_atanh(fe); 785 1.3 briggs break; 786 1.3 briggs 787 1.3 briggs case 0x0E: /* fsin */ 788 1.3 briggs res = fpu_sin(fe); 789 1.3 briggs break; 790 1.3 briggs 791 1.3 briggs case 0x0F: /* ftan */ 792 1.3 briggs res = fpu_tan(fe); 793 1.3 briggs break; 794 1.3 briggs 795 1.3 briggs case 0x10: /* fetox */ 796 1.3 briggs res = fpu_etox(fe); 797 1.3 briggs break; 798 1.3 briggs 799 1.3 briggs case 0x11: /* ftwotox */ 800 1.3 briggs res = fpu_twotox(fe); 801 1.3 briggs break; 802 1.3 briggs 803 1.3 briggs case 0x12: /* ftentox */ 804 1.3 briggs res = fpu_tentox(fe); 805 1.3 briggs break; 806 1.3 briggs 807 1.3 briggs case 0x14: /* flogn */ 808 1.3 briggs res = fpu_logn(fe); 809 1.3 briggs break; 810 1.3 briggs 811 1.3 briggs case 0x15: /* flog10 */ 812 1.3 briggs res = fpu_log10(fe); 813 1.3 briggs break; 814 1.3 briggs 815 1.3 briggs case 0x16: /* flog2 */ 816 1.3 briggs res = fpu_log2(fe); 817 1.3 briggs break; 818 1.3 briggs 819 1.3 briggs case 0x18: /* fabs */ 820 1.3 briggs fe->fe_f2.fp_sign = 0; 821 1.3 briggs res = &fe->fe_f2; 822 1.3 briggs break; 823 1.3 briggs 824 1.3 briggs case 0x19: /* fcosh */ 825 1.3 briggs res = fpu_cosh(fe); 826 1.3 briggs break; 827 1.3 briggs 828 1.3 briggs case 0x1A: /* fneg */ 829 1.3 briggs fe->fe_f2.fp_sign = !fe->fe_f2.fp_sign; 830 1.3 briggs res = &fe->fe_f2; 831 1.3 briggs break; 832 1.3 briggs 833 1.3 briggs case 0x1C: /* facos */ 834 1.3 briggs res = fpu_acos(fe); 835 1.3 briggs break; 836 1.3 briggs 837 1.3 briggs case 0x1D: /* fcos */ 838 1.3 briggs res = fpu_cos(fe); 839 1.3 briggs break; 840 1.3 briggs 841 1.3 briggs case 0x1E: /* fgetexp */ 842 1.3 briggs res = fpu_getexp(fe); 843 1.3 briggs break; 844 1.3 briggs 845 1.3 briggs case 0x1F: /* fgetman */ 846 1.3 briggs res = fpu_getman(fe); 847 1.3 briggs break; 848 1.3 briggs 849 1.3 briggs case 0x20: /* fdiv */ 850 1.3 briggs case 0x24: /* fsgldiv: cheating - better than nothing */ 851 1.3 briggs res = fpu_div(fe); 852 1.3 briggs break; 853 1.3 briggs 854 1.3 briggs case 0x21: /* fmod */ 855 1.3 briggs res = fpu_mod(fe); 856 1.3 briggs break; 857 1.3 briggs 858 1.3 briggs case 0x28: /* fsub */ 859 1.3 briggs fe->fe_f2.fp_sign = !fe->fe_f2.fp_sign; /* f2 = -f2 */ 860 1.3 briggs case 0x22: /* fadd */ 861 1.3 briggs res = fpu_add(fe); 862 1.3 briggs break; 863 1.3 briggs 864 1.3 briggs case 0x23: /* fmul */ 865 1.3 briggs case 0x27: /* fsglmul: cheating - better than nothing */ 866 1.3 briggs res = fpu_mul(fe); 867 1.3 briggs break; 868 1.3 briggs 869 1.3 briggs case 0x25: /* frem */ 870 1.3 briggs res = fpu_rem(fe); 871 1.3 briggs break; 872 1.3 briggs 873 1.3 briggs case 0x26: 874 1.3 briggs /* fscale is handled by a separate function */ 875 1.3 briggs break; 876 1.3 briggs 877 1.3 briggs case 0x30: 878 1.12 is case 0x31: 879 1.3 briggs case 0x32: 880 1.3 briggs case 0x33: 881 1.3 briggs case 0x34: 882 1.3 briggs case 0x35: 883 1.3 briggs case 0x36: 884 1.3 briggs case 0x37: /* fsincos */ 885 1.3 briggs res = fpu_sincos(fe, word1 & 7); 886 1.3 briggs break; 887 1.3 briggs 888 1.3 briggs case 0x38: /* fcmp */ 889 1.3 briggs res = fpu_cmp(fe); 890 1.3 briggs discard_result = 1; 891 1.3 briggs break; 892 1.3 briggs 893 1.3 briggs case 0x3A: /* ftst */ 894 1.3 briggs res = &fe->fe_f2; 895 1.3 briggs discard_result = 1; 896 1.3 briggs break; 897 1.3 briggs 898 1.3 briggs default: 899 1.3 briggs #ifdef DEBUG 900 1.21 briggs printf("fpu_emul_arith: bad opcode=0x%x, word1=0x%x\n", 901 1.3 briggs insn->is_opcode, insn->is_word1); 902 1.3 briggs #endif 903 1.3 briggs sig = SIGILL; 904 1.3 briggs } /* switch (word1 & 0x3f) */ 905 1.1 gwr 906 1.3 briggs if (!discard_result && sig == 0) { 907 1.3 briggs fpu_implode(fe, res, FTYPE_EXT, &fpregs[regnum * 3]); 908 1.21 briggs #if DEBUG_FPE 909 1.21 briggs printf("fpu_emul_arith: %08x,%08x,%08x stored in FP%d\n", 910 1.21 briggs fpregs[regnum*3], fpregs[regnum*3+1], 911 1.21 briggs fpregs[regnum*3+2], regnum); 912 1.21 briggs } else if (sig == 0) { 913 1.3 briggs static char *class_name[] = { "SNAN", "QNAN", "ZERO", "NUM", "INF" }; 914 1.21 briggs printf("fpu_emul_arith: result(%s,%c,%d,%08x,%08x,%08x) discarded\n", 915 1.3 briggs class_name[res->fp_class + 2], 916 1.3 briggs res->fp_sign ? '-' : '+', res->fp_exp, 917 1.3 briggs res->fp_mant[0], res->fp_mant[1], 918 1.21 briggs res->fp_mant[2]); 919 1.21 briggs } else { 920 1.21 briggs printf("fpu_emul_arith: received signal %d\n", sig); 921 1.21 briggs #endif 922 1.3 briggs } 923 1.3 briggs 924 1.3 briggs /* update fpsr according to the result of operation */ 925 1.3 briggs fpu_upd_fpsr(fe, res); 926 1.3 briggs 927 1.21 briggs #if DEBUG_FPE 928 1.21 briggs printf("fpu_emul_arith: FPSR = %08x, FPCR = %08x\n", 929 1.21 briggs fe->fe_fpsr, fe->fe_fpcr); 930 1.21 briggs #endif 931 1.1 gwr 932 1.3 briggs DUMP_INSN(insn); 933 1.1 gwr 934 1.3 briggs return sig; 935 1.1 gwr } 936 1.1 gwr 937 1.3 briggs /* test condition code according to the predicate in the opcode. 938 1.3 briggs * returns -1 when the predicate evaluates to true, 0 when false. 939 1.3 briggs * signal numbers are returned when an error is detected. 940 1.1 gwr */ 941 1.3 briggs static int 942 1.3 briggs test_cc(fe, pred) 943 1.3 briggs struct fpemu *fe; 944 1.3 briggs int pred; 945 1.1 gwr { 946 1.3 briggs int result, sig_bsun, invert; 947 1.3 briggs int fpsr; 948 1.1 gwr 949 1.3 briggs fpsr = fe->fe_fpsr; 950 1.3 briggs invert = 0; 951 1.3 briggs fpsr &= ~FPSR_EXCP; /* clear all exceptions */ 952 1.21 briggs #if DEBUG_FPE 953 1.21 briggs printf("test_cc: fpsr=0x%08x\n", fpsr); 954 1.21 briggs #endif 955 1.3 briggs pred &= 0x3f; /* lowest 6 bits */ 956 1.3 briggs 957 1.21 briggs #if DEBUG_FPE 958 1.21 briggs printf("test_cc: "); 959 1.21 briggs #endif 960 1.1 gwr 961 1.21 briggs if (pred >= 0x20) { 962 1.3 briggs return SIGILL; 963 1.3 briggs } else if (pred & 0x10) { 964 1.3 briggs /* IEEE nonaware tests */ 965 1.3 briggs sig_bsun = 1; 966 1.21 briggs pred &= 0x0f; /* lower 4 bits */ 967 1.3 briggs } else { 968 1.3 briggs /* IEEE aware tests */ 969 1.21 briggs #if DEBUG_FPE 970 1.21 briggs printf("IEEE "); 971 1.21 briggs #endif 972 1.3 briggs sig_bsun = 0; 973 1.3 briggs } 974 1.1 gwr 975 1.21 briggs if (pred & 0x08) { 976 1.21 briggs #if DEBUG_FPE 977 1.21 briggs printf("Not "); 978 1.21 briggs #endif 979 1.3 briggs /* predicate is "NOT ..." */ 980 1.3 briggs pred ^= 0xf; /* invert */ 981 1.3 briggs invert = -1; 982 1.3 briggs } 983 1.3 briggs switch (pred) { 984 1.3 briggs case 0: /* (Signaling) False */ 985 1.21 briggs #if DEBUG_FPE 986 1.21 briggs printf("False"); 987 1.21 briggs #endif 988 1.3 briggs result = 0; 989 1.3 briggs break; 990 1.3 briggs case 1: /* (Signaling) Equal */ 991 1.21 briggs #if DEBUG_FPE 992 1.21 briggs printf("Equal"); 993 1.21 briggs #endif 994 1.3 briggs result = -((fpsr & FPSR_ZERO) == FPSR_ZERO); 995 1.3 briggs break; 996 1.3 briggs case 2: /* Greater Than */ 997 1.21 briggs #if DEBUG_FPE 998 1.21 briggs printf("GT"); 999 1.21 briggs #endif 1000 1.3 briggs result = -((fpsr & (FPSR_NAN|FPSR_ZERO|FPSR_NEG)) == 0); 1001 1.3 briggs break; 1002 1.3 briggs case 3: /* Greater or Equal */ 1003 1.21 briggs #if DEBUG_FPE 1004 1.21 briggs printf("GE"); 1005 1.21 briggs #endif 1006 1.3 briggs result = -((fpsr & FPSR_ZERO) || 1007 1.3 briggs (fpsr & (FPSR_NAN|FPSR_NEG)) == 0); 1008 1.3 briggs break; 1009 1.3 briggs case 4: /* Less Than */ 1010 1.21 briggs #if DEBUG_FPE 1011 1.21 briggs printf("LT"); 1012 1.21 briggs #endif 1013 1.3 briggs result = -((fpsr & (FPSR_NAN|FPSR_ZERO|FPSR_NEG)) == FPSR_NEG); 1014 1.3 briggs break; 1015 1.3 briggs case 5: /* Less or Equal */ 1016 1.21 briggs #if DEBUG_FPE 1017 1.21 briggs printf("LE"); 1018 1.21 briggs #endif 1019 1.3 briggs result = -((fpsr & FPSR_ZERO) || 1020 1.3 briggs ((fpsr & (FPSR_NAN|FPSR_NEG)) == FPSR_NEG)); 1021 1.3 briggs break; 1022 1.3 briggs case 6: /* Greater or Less than */ 1023 1.21 briggs #if DEBUG_FPE 1024 1.21 briggs printf("GLT"); 1025 1.21 briggs #endif 1026 1.3 briggs result = -((fpsr & (FPSR_NAN|FPSR_ZERO)) == 0); 1027 1.3 briggs break; 1028 1.3 briggs case 7: /* Greater, Less or Equal */ 1029 1.21 briggs #if DEBUG_FPE 1030 1.21 briggs printf("GLE"); 1031 1.21 briggs #endif 1032 1.3 briggs result = -((fpsr & FPSR_NAN) == 0); 1033 1.3 briggs break; 1034 1.3 briggs default: 1035 1.3 briggs /* invalid predicate */ 1036 1.3 briggs return SIGILL; 1037 1.3 briggs } 1038 1.3 briggs result ^= invert; /* if the predicate is "NOT ...", then 1039 1.3 briggs invert the result */ 1040 1.21 briggs #if DEBUG_FPE 1041 1.21 briggs printf("=> %s (%d)\n", result ? "true" : "false", result); 1042 1.21 briggs #endif 1043 1.3 briggs /* if it's an IEEE unaware test and NAN is set, BSUN is set */ 1044 1.3 briggs if (sig_bsun && (fpsr & FPSR_NAN)) { 1045 1.3 briggs fpsr |= FPSR_BSUN; 1046 1.3 briggs } 1047 1.1 gwr 1048 1.3 briggs /* put fpsr back */ 1049 1.3 briggs fe->fe_fpframe->fpf_fpsr = fe->fe_fpsr = fpsr; 1050 1.1 gwr 1051 1.3 briggs return result; 1052 1.1 gwr } 1053 1.1 gwr 1054 1.1 gwr /* 1055 1.3 briggs * type 1: fdbcc, fscc, ftrapcc 1056 1.3 briggs * In this function, we know: 1057 1.3 briggs * (opcode & 0x01C0) == 0x0040 1058 1.1 gwr */ 1059 1.3 briggs static int 1060 1.3 briggs fpu_emul_type1(fe, insn) 1061 1.3 briggs struct fpemu *fe; 1062 1.3 briggs struct instruction *insn; 1063 1.1 gwr { 1064 1.3 briggs struct frame *frame = fe->fe_frame; 1065 1.3 briggs int advance, sig, branch, displ; 1066 1.3 briggs 1067 1.3 briggs branch = test_cc(fe, insn->is_word1); 1068 1.3 briggs fe->fe_fpframe->fpf_fpsr = fe->fe_fpsr; 1069 1.3 briggs 1070 1.3 briggs insn->is_advance = 4; 1071 1.3 briggs sig = 0; 1072 1.3 briggs 1073 1.3 briggs switch (insn->is_opcode & 070) { 1074 1.3 briggs case 010: /* fdbcc */ 1075 1.3 briggs if (branch == -1) { 1076 1.3 briggs /* advance */ 1077 1.3 briggs insn->is_advance = 6; 1078 1.3 briggs } else if (!branch) { 1079 1.3 briggs /* decrement Dn and if (Dn != -1) branch */ 1080 1.3 briggs u_int16_t count = frame->f_regs[insn->is_opcode & 7]; 1081 1.3 briggs 1082 1.3 briggs if (count-- != 0) { 1083 1.21 briggs displ = fusword((void *) (insn->is_pc + insn->is_advance)); 1084 1.3 briggs if (displ < 0) { 1085 1.3 briggs #ifdef DEBUG 1086 1.21 briggs printf("fpu_emul_type1: fault reading displacement\n"); 1087 1.3 briggs #endif 1088 1.3 briggs return SIGSEGV; 1089 1.3 briggs } 1090 1.3 briggs /* sign-extend the displacement */ 1091 1.3 briggs displ &= 0xffff; 1092 1.3 briggs if (displ & 0x8000) { 1093 1.3 briggs displ |= 0xffff0000; 1094 1.3 briggs } 1095 1.3 briggs insn->is_advance += displ; 1096 1.21.2.1 bouyer /* XXX insn->is_nextpc = insn->is_pc + insn->is_advance; */ 1097 1.3 briggs } else { 1098 1.3 briggs insn->is_advance = 6; 1099 1.3 briggs } 1100 1.3 briggs /* write it back */ 1101 1.3 briggs frame->f_regs[insn->is_opcode & 7] &= 0xffff0000; 1102 1.3 briggs frame->f_regs[insn->is_opcode & 7] |= (u_int32_t)count; 1103 1.3 briggs } else { /* got a signal */ 1104 1.3 briggs sig = SIGFPE; 1105 1.3 briggs } 1106 1.3 briggs break; 1107 1.1 gwr 1108 1.3 briggs case 070: /* ftrapcc or fscc */ 1109 1.3 briggs advance = 4; 1110 1.3 briggs if ((insn->is_opcode & 07) >= 2) { 1111 1.3 briggs switch (insn->is_opcode & 07) { 1112 1.3 briggs case 3: /* long opr */ 1113 1.3 briggs advance += 2; 1114 1.3 briggs case 2: /* word opr */ 1115 1.3 briggs advance += 2; 1116 1.3 briggs case 4: /* no opr */ 1117 1.3 briggs break; 1118 1.3 briggs default: 1119 1.1 gwr return SIGILL; 1120 1.3 briggs break; 1121 1.3 briggs } 1122 1.1 gwr 1123 1.3 briggs if (branch == 0) { 1124 1.3 briggs /* no trap */ 1125 1.3 briggs insn->is_advance = advance; 1126 1.3 briggs sig = 0; 1127 1.3 briggs } else { 1128 1.3 briggs /* trap */ 1129 1.3 briggs sig = SIGFPE; 1130 1.3 briggs } 1131 1.3 briggs break; 1132 1.3 briggs } /* if ((insn->is_opcode & 7) < 2), fall through to FScc */ 1133 1.3 briggs 1134 1.3 briggs default: /* fscc */ 1135 1.3 briggs insn->is_advance = 4; 1136 1.3 briggs insn->is_datasize = 1; /* always byte */ 1137 1.21 briggs sig = fpu_decode_ea(frame, insn, &insn->is_ea, insn->is_opcode); 1138 1.3 briggs if (sig) { 1139 1.3 briggs break; 1140 1.3 briggs } 1141 1.3 briggs if (branch == -1 || branch == 0) { 1142 1.3 briggs /* set result */ 1143 1.21 briggs sig = fpu_store_ea(frame, insn, &insn->is_ea, (char *)&branch); 1144 1.1 gwr } else { 1145 1.3 briggs /* got an exception */ 1146 1.3 briggs sig = branch; 1147 1.3 briggs } 1148 1.3 briggs break; 1149 1.3 briggs } 1150 1.3 briggs return sig; 1151 1.3 briggs } 1152 1.1 gwr 1153 1.3 briggs /* 1154 1.3 briggs * Type 2 or 3: fbcc (also fnop) 1155 1.3 briggs * In this function, we know: 1156 1.3 briggs * (opcode & 0x0180) == 0x0080 1157 1.3 briggs */ 1158 1.3 briggs static int 1159 1.3 briggs fpu_emul_brcc(fe, insn) 1160 1.3 briggs struct fpemu *fe; 1161 1.3 briggs struct instruction *insn; 1162 1.3 briggs { 1163 1.3 briggs int displ, word2; 1164 1.5 briggs int sig; 1165 1.3 briggs 1166 1.3 briggs /* 1167 1.3 briggs * Get branch displacement. 1168 1.3 briggs */ 1169 1.3 briggs insn->is_advance = 4; 1170 1.3 briggs displ = insn->is_word1; 1171 1.3 briggs 1172 1.3 briggs if (insn->is_opcode & 0x40) { 1173 1.21 briggs word2 = fusword((void *) (insn->is_pc + insn->is_advance)); 1174 1.3 briggs if (word2 < 0) { 1175 1.3 briggs #ifdef DEBUG 1176 1.21 briggs printf("fpu_emul_brcc: fault reading word2\n"); 1177 1.3 briggs #endif 1178 1.3 briggs return SIGSEGV; 1179 1.1 gwr } 1180 1.3 briggs displ <<= 16; 1181 1.3 briggs displ |= word2; 1182 1.3 briggs insn->is_advance += 2; 1183 1.3 briggs } else /* displacement is word sized */ 1184 1.3 briggs if (displ & 0x8000) 1185 1.3 briggs displ |= 0xFFFF0000; 1186 1.3 briggs 1187 1.21 briggs /* XXX: If CC, insn->is_pc += displ */ 1188 1.3 briggs sig = test_cc(fe, insn->is_opcode); 1189 1.3 briggs fe->fe_fpframe->fpf_fpsr = fe->fe_fpsr; 1190 1.3 briggs 1191 1.3 briggs if (fe->fe_fpsr & fe->fe_fpcr & FPSR_EXCP) { 1192 1.3 briggs return SIGFPE; /* caught an exception */ 1193 1.3 briggs } 1194 1.3 briggs if (sig == -1) { 1195 1.3 briggs /* branch does take place; 2 is the offset to the 1st disp word */ 1196 1.3 briggs insn->is_advance = displ + 2; 1197 1.21.2.1 bouyer /* XXX insn->is_nextpc = insn->is_pc + insn->is_advance; */ 1198 1.3 briggs } else if (sig) { 1199 1.3 briggs return SIGILL; /* got a signal */ 1200 1.3 briggs } 1201 1.21 briggs #if DEBUG_FPE 1202 1.21 briggs printf("fpu_emul_brcc: %s insn @ %x (%x+%x) (disp=%x)\n", 1203 1.21 briggs (sig == -1) ? "BRANCH to" : "NEXT", 1204 1.21 briggs insn->is_pc + insn->is_advance, insn->is_pc, insn->is_advance, 1205 1.21 briggs displ); 1206 1.21 briggs #endif 1207 1.3 briggs return 0; 1208 1.1 gwr } 1209
Indexes created Wed Oct 22 13:09:56 GMT 2025