fpu.c revision 1.7
1 1.7 mrg /* $NetBSD: fpu.c,v 1.7 2000/06/18 06:54:17 mrg Exp $ */ 2 1.2 deraadt 3 1.1 deraadt /* 4 1.1 deraadt * Copyright (c) 1992, 1993 5 1.1 deraadt * The Regents of the University of California. All rights reserved. 6 1.1 deraadt * 7 1.1 deraadt * This software was developed by the Computer Systems Engineering group 8 1.1 deraadt * at Lawrence Berkeley Laboratory under DARPA contract BG 91-66 and 9 1.1 deraadt * contributed to Berkeley. 10 1.1 deraadt * 11 1.1 deraadt * All advertising materials mentioning features or use of this software 12 1.1 deraadt * must display the following acknowledgement: 13 1.1 deraadt * This product includes software developed by the University of 14 1.1 deraadt * California, Lawrence Berkeley Laboratory. 15 1.1 deraadt * 16 1.1 deraadt * Redistribution and use in source and binary forms, with or without 17 1.1 deraadt * modification, are permitted provided that the following conditions 18 1.1 deraadt * are met: 19 1.1 deraadt * 1. Redistributions of source code must retain the above copyright 20 1.1 deraadt * notice, this list of conditions and the following disclaimer. 21 1.1 deraadt * 2. Redistributions in binary form must reproduce the above copyright 22 1.1 deraadt * notice, this list of conditions and the following disclaimer in the 23 1.1 deraadt * documentation and/or other materials provided with the distribution. 24 1.1 deraadt * 3. All advertising materials mentioning features or use of this software 25 1.1 deraadt * must display the following acknowledgement: 26 1.1 deraadt * This product includes software developed by the University of 27 1.1 deraadt * California, Berkeley and its contributors. 28 1.1 deraadt * 4. Neither the name of the University nor the names of its contributors 29 1.1 deraadt * may be used to endorse or promote products derived from this software 30 1.1 deraadt * without specific prior written permission. 31 1.1 deraadt * 32 1.1 deraadt * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND 33 1.1 deraadt * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 34 1.1 deraadt * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 35 1.1 deraadt * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE 36 1.1 deraadt * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 37 1.1 deraadt * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 38 1.1 deraadt * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 39 1.1 deraadt * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 40 1.1 deraadt * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 41 1.1 deraadt * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 42 1.1 deraadt * SUCH DAMAGE. 43 1.1 deraadt * 44 1.1 deraadt * @(#)fpu.c 8.1 (Berkeley) 6/11/93 45 1.1 deraadt */ 46 1.1 deraadt 47 1.1 deraadt #include <sys/param.h> 48 1.1 deraadt #include <sys/proc.h> 49 1.1 deraadt #include <sys/signal.h> 50 1.1 deraadt #include <sys/systm.h> 51 1.1 deraadt #include <sys/syslog.h> 52 1.3 christos #include <sys/signalvar.h> 53 1.1 deraadt 54 1.1 deraadt #include <machine/instr.h> 55 1.1 deraadt #include <machine/reg.h> 56 1.1 deraadt 57 1.1 deraadt #include <sparc/fpu/fpu_emu.h> 58 1.3 christos #include <sparc/fpu/fpu_extern.h> 59 1.1 deraadt 60 1.1 deraadt /* 61 1.1 deraadt * fpu_execute returns the following error numbers (0 = no error): 62 1.1 deraadt */ 63 1.1 deraadt #define FPE 1 /* take a floating point exception */ 64 1.1 deraadt #define NOTFPU 2 /* not an FPU instruction */ 65 1.1 deraadt 66 1.1 deraadt /* 67 1.1 deraadt * Translate current exceptions into `first' exception. The 68 1.1 deraadt * bits go the wrong way for ffs() (0x10 is most important, etc). 69 1.1 deraadt * There are only 5, so do it the obvious way. 70 1.1 deraadt */ 71 1.1 deraadt #define X1(x) x 72 1.1 deraadt #define X2(x) x,x 73 1.1 deraadt #define X4(x) x,x,x,x 74 1.1 deraadt #define X8(x) X4(x),X4(x) 75 1.1 deraadt #define X16(x) X8(x),X8(x) 76 1.1 deraadt 77 1.1 deraadt static char cx_to_trapx[] = { 78 1.1 deraadt X1(FSR_NX), 79 1.1 deraadt X2(FSR_DZ), 80 1.1 deraadt X4(FSR_UF), 81 1.1 deraadt X8(FSR_OF), 82 1.1 deraadt X16(FSR_NV) 83 1.1 deraadt }; 84 1.1 deraadt static u_char fpu_codes[] = { 85 1.1 deraadt X1(FPE_FLTINEX_TRAP), 86 1.1 deraadt X2(FPE_FLTDIV_TRAP), 87 1.1 deraadt X4(FPE_FLTUND_TRAP), 88 1.1 deraadt X8(FPE_FLTOVF_TRAP), 89 1.1 deraadt X16(FPE_FLTOPERR_TRAP) 90 1.1 deraadt }; 91 1.1 deraadt 92 1.1 deraadt /* 93 1.1 deraadt * The FPU gave us an exception. Clean up the mess. Note that the 94 1.1 deraadt * fp queue can only have FPops in it, never load/store FP registers 95 1.1 deraadt * nor FBfcc instructions. Experiments with `crashme' prove that 96 1.1 deraadt * unknown FPops do enter the queue, however. 97 1.1 deraadt */ 98 1.3 christos void 99 1.1 deraadt fpu_cleanup(p, fs) 100 1.1 deraadt register struct proc *p; 101 1.7 mrg #ifndef SUN4U 102 1.1 deraadt register struct fpstate *fs; 103 1.7 mrg #else /* SUN4U */ 104 1.7 mrg register struct fpstate64 *fs; 105 1.7 mrg #endif /* SUN4U */ 106 1.1 deraadt { 107 1.1 deraadt register int i, fsr = fs->fs_fsr, error; 108 1.1 deraadt union instr instr; 109 1.1 deraadt struct fpemu fe; 110 1.1 deraadt 111 1.1 deraadt switch ((fsr >> FSR_FTT_SHIFT) & FSR_FTT_MASK) { 112 1.1 deraadt 113 1.1 deraadt case FSR_TT_NONE: 114 1.7 mrg panic("fpu_cleanup: No fault"); /* ??? */ 115 1.1 deraadt break; 116 1.1 deraadt 117 1.1 deraadt case FSR_TT_IEEE: 118 1.1 deraadt /* XXX missing trap address! */ 119 1.1 deraadt if ((i = fsr & FSR_CX) == 0) 120 1.1 deraadt panic("fpu ieee trap, but no exception"); 121 1.1 deraadt trapsignal(p, SIGFPE, fpu_codes[i - 1]); 122 1.1 deraadt break; /* XXX should return, but queue remains */ 123 1.1 deraadt 124 1.1 deraadt case FSR_TT_UNFIN: 125 1.7 mrg #ifdef SUN4U 126 1.7 mrg if (fs->fs_qsize == 0) { 127 1.7 mrg printf("fpu_cleanup: unfinished fpop"); 128 1.7 mrg /* The book sez reexecute or emulate. */ 129 1.7 mrg return; 130 1.7 mrg } 131 1.7 mrg break; 132 1.7 mrg 133 1.7 mrg #endif /* SUN4U */ 134 1.1 deraadt case FSR_TT_UNIMP: 135 1.1 deraadt if (fs->fs_qsize == 0) 136 1.7 mrg panic("fpu_cleanup: unimplemented fpop"); 137 1.1 deraadt break; 138 1.1 deraadt 139 1.1 deraadt case FSR_TT_SEQ: 140 1.1 deraadt panic("fpu sequence error"); 141 1.1 deraadt /* NOTREACHED */ 142 1.1 deraadt 143 1.1 deraadt case FSR_TT_HWERR: 144 1.1 deraadt log(LOG_ERR, "fpu hardware error (%s[%d])\n", 145 1.1 deraadt p->p_comm, p->p_pid); 146 1.1 deraadt uprintf("%s[%d]: fpu hardware error\n", p->p_comm, p->p_pid); 147 1.1 deraadt trapsignal(p, SIGFPE, -1); /* ??? */ 148 1.1 deraadt goto out; 149 1.1 deraadt 150 1.1 deraadt default: 151 1.6 fair printf("fsr=0x%x\n", fsr); 152 1.1 deraadt panic("fpu error"); 153 1.1 deraadt } 154 1.1 deraadt 155 1.1 deraadt /* emulate the instructions left in the queue */ 156 1.1 deraadt fe.fe_fpstate = fs; 157 1.1 deraadt for (i = 0; i < fs->fs_qsize; i++) { 158 1.1 deraadt instr.i_int = fs->fs_queue[i].fq_instr; 159 1.1 deraadt if (instr.i_any.i_op != IOP_reg || 160 1.1 deraadt (instr.i_op3.i_op3 != IOP3_FPop1 && 161 1.1 deraadt instr.i_op3.i_op3 != IOP3_FPop2)) 162 1.1 deraadt panic("bogus fpu queue"); 163 1.1 deraadt error = fpu_execute(&fe, instr); 164 1.1 deraadt switch (error) { 165 1.1 deraadt 166 1.1 deraadt case 0: 167 1.1 deraadt continue; 168 1.1 deraadt 169 1.1 deraadt case FPE: 170 1.1 deraadt trapsignal(p, SIGFPE, 171 1.1 deraadt fpu_codes[(fs->fs_fsr & FSR_CX) - 1]); 172 1.1 deraadt break; 173 1.1 deraadt 174 1.1 deraadt case NOTFPU: 175 1.7 mrg #ifdef SUN4U 176 1.7 mrg #ifdef DEBUG 177 1.7 mrg printf("fpu_cleanup: not an FPU error -- sending SIGILL\n", p); 178 1.7 mrg Debugger(); 179 1.7 mrg #endif 180 1.7 mrg #endif /* SUN4U */ 181 1.1 deraadt trapsignal(p, SIGILL, 0); /* ??? code? */ 182 1.1 deraadt break; 183 1.1 deraadt 184 1.1 deraadt default: 185 1.1 deraadt panic("fpu_cleanup 3"); 186 1.1 deraadt /* NOTREACHED */ 187 1.1 deraadt } 188 1.1 deraadt /* XXX should stop here, but queue remains */ 189 1.1 deraadt } 190 1.1 deraadt out: 191 1.1 deraadt fs->fs_qsize = 0; 192 1.1 deraadt } 193 1.1 deraadt 194 1.1 deraadt #ifdef notyet 195 1.1 deraadt /* 196 1.1 deraadt * If we have no FPU at all (are there any machines like this out 197 1.1 deraadt * there!?) we have to emulate each instruction, and we need a pointer 198 1.1 deraadt * to the trapframe so that we can step over them and do FBfcc's. 199 1.1 deraadt * We know the `queue' is empty, though; we just want to emulate 200 1.1 deraadt * the instruction at tf->tf_pc. 201 1.1 deraadt */ 202 1.1 deraadt fpu_emulate(p, tf, fs) 203 1.1 deraadt struct proc *p; 204 1.1 deraadt register struct trapframe *tf; 205 1.7 mrg #ifndef SUN4U 206 1.1 deraadt register struct fpstate *fs; 207 1.7 mrg #else /* SUN4U */ 208 1.7 mrg register struct fpstate64 *fs; 209 1.7 mrg #endif /* SUN4U */ 210 1.1 deraadt { 211 1.1 deraadt 212 1.1 deraadt do { 213 1.1 deraadt fetch instr from pc 214 1.1 deraadt decode 215 1.1 deraadt if (integer instr) { 216 1.1 deraadt /* 217 1.1 deraadt * We do this here, rather than earlier, to avoid 218 1.1 deraadt * losing even more badly than usual. 219 1.1 deraadt */ 220 1.1 deraadt if (p->p_addr->u_pcb.pcb_uw) { 221 1.1 deraadt write_user_windows(); 222 1.1 deraadt if (rwindow_save(p)) 223 1.1 deraadt sigexit(p, SIGILL); 224 1.1 deraadt } 225 1.1 deraadt if (loadstore) { 226 1.1 deraadt do_it; 227 1.1 deraadt pc = npc, npc += 4 228 1.1 deraadt } else if (fbfcc) { 229 1.1 deraadt do_annul_stuff; 230 1.1 deraadt } else 231 1.1 deraadt return; 232 1.1 deraadt } else if (fpu instr) { 233 1.1 deraadt fe.fe_fsr = fs->fs_fsr &= ~FSR_CX; 234 1.1 deraadt error = fpu_execute(&fe, fs, instr); 235 1.1 deraadt switch (error) { 236 1.1 deraadt etc; 237 1.1 deraadt } 238 1.1 deraadt } else 239 1.1 deraadt return; 240 1.1 deraadt if (want to reschedule) 241 1.1 deraadt return; 242 1.1 deraadt } while (error == 0); 243 1.1 deraadt } 244 1.1 deraadt #endif 245 1.1 deraadt 246 1.1 deraadt /* 247 1.1 deraadt * Execute an FPU instruction (one that runs entirely in the FPU; not 248 1.1 deraadt * FBfcc or STF, for instance). On return, fe->fe_fs->fs_fsr will be 249 1.1 deraadt * modified to reflect the setting the hardware would have left. 250 1.1 deraadt * 251 1.1 deraadt * Note that we do not catch all illegal opcodes, so you can, for instance, 252 1.1 deraadt * multiply two integers this way. 253 1.1 deraadt */ 254 1.1 deraadt int 255 1.1 deraadt fpu_execute(fe, instr) 256 1.1 deraadt register struct fpemu *fe; 257 1.1 deraadt union instr instr; 258 1.1 deraadt { 259 1.1 deraadt register struct fpn *fp; 260 1.7 mrg #ifndef SUN4U 261 1.1 deraadt register int opf, rs1, rs2, rd, type, mask, fsr, cx; 262 1.1 deraadt register struct fpstate *fs; 263 1.7 mrg #else /* SUN4U */ 264 1.7 mrg register int opf, rs1, rs2, rd, type, mask, fsr, cx, i, cond; 265 1.7 mrg register struct fpstate64 *fs; 266 1.7 mrg #endif /* SUN4U */ 267 1.1 deraadt u_int space[4]; 268 1.1 deraadt 269 1.1 deraadt /* 270 1.1 deraadt * `Decode' and execute instruction. Start with no exceptions. 271 1.1 deraadt * The type of any i_opf opcode is in the bottom two bits, so we 272 1.1 deraadt * squish them out here. 273 1.1 deraadt */ 274 1.1 deraadt opf = instr.i_opf.i_opf; 275 1.1 deraadt type = opf & 3; 276 1.1 deraadt mask = "\0\0\1\3"[type]; 277 1.1 deraadt rs1 = instr.i_opf.i_rs1 & ~mask; 278 1.1 deraadt rs2 = instr.i_opf.i_rs2 & ~mask; 279 1.1 deraadt rd = instr.i_opf.i_rd & ~mask; 280 1.1 deraadt #ifdef notdef 281 1.1 deraadt if ((rs1 | rs2 | rd) & mask) 282 1.1 deraadt return (BADREG); 283 1.1 deraadt #endif 284 1.1 deraadt fs = fe->fe_fpstate; 285 1.1 deraadt fe->fe_fsr = fs->fs_fsr & ~FSR_CX; 286 1.1 deraadt fe->fe_cx = 0; 287 1.7 mrg #ifdef SUN4U 288 1.7 mrg /* 289 1.7 mrg * Check to see if we're dealing with a fancy cmove and handle 290 1.7 mrg * it first. 291 1.7 mrg */ 292 1.7 mrg if (instr.i_op3.i_op3 == IOP3_FPop2 && (opf&0xff0) != (FCMP&0xff0)) { 293 1.7 mrg switch (opf >>= 2) { 294 1.7 mrg case FMVFC0 >> 2: 295 1.7 mrg cond = (fs->fs_fsr>>FSR_FCC_SHIFT)&FSR_FCC_MASK; 296 1.7 mrg if (instr.i_fmovcc.i_cond != cond) return(0); /* success */ 297 1.7 mrg rs1 = fs->fs_regs[rs2]; 298 1.7 mrg goto mov; 299 1.7 mrg case FMVFC1 >> 2: 300 1.7 mrg cond = (fs->fs_fsr>>FSR_FCC1_SHIFT)&FSR_FCC_MASK; 301 1.7 mrg if (instr.i_fmovcc.i_cond != cond) return(0); /* success */ 302 1.7 mrg rs1 = fs->fs_regs[rs2]; 303 1.7 mrg goto mov; 304 1.7 mrg case FMVFC2 >> 2: 305 1.7 mrg cond = (fs->fs_fsr>>FSR_FCC2_SHIFT)&FSR_FCC_MASK; 306 1.7 mrg if (instr.i_fmovcc.i_cond != cond) return(0); /* success */ 307 1.7 mrg rs1 = fs->fs_regs[rs2]; 308 1.7 mrg goto mov; 309 1.7 mrg case FMVFC3 >> 2: 310 1.7 mrg cond = (fs->fs_fsr>>FSR_FCC3_SHIFT)&FSR_FCC_MASK; 311 1.7 mrg if (instr.i_fmovcc.i_cond != cond) return(0); /* success */ 312 1.7 mrg rs1 = fs->fs_regs[rs2]; 313 1.7 mrg goto mov; 314 1.7 mrg case FMVIC >> 2: 315 1.7 mrg /* Presume we're curproc */ 316 1.7 mrg cond = (curproc->p_md.md_tf->tf_tstate>>TSTATE_CCR_SHIFT)&PSR_ICC; 317 1.7 mrg if (instr.i_fmovcc.i_cond != cond) return(0); /* success */ 318 1.7 mrg rs1 = fs->fs_regs[rs2]; 319 1.7 mrg goto mov; 320 1.7 mrg case FMVXC >> 2: 321 1.7 mrg /* Presume we're curproc */ 322 1.7 mrg cond = (curproc->p_md.md_tf->tf_tstate>>(TSTATE_CCR_SHIFT+XCC_SHIFT))&PSR_ICC; 323 1.7 mrg if (instr.i_fmovcc.i_cond != cond) return(0); /* success */ 324 1.7 mrg rs1 = fs->fs_regs[rs2]; 325 1.7 mrg goto mov; 326 1.7 mrg case FMVRZ >> 2: 327 1.7 mrg /* Presume we're curproc */ 328 1.7 mrg rs1 = instr.i_fmovr.i_rs1; 329 1.7 mrg if (rs1 != 0 && (int64_t)curproc->p_md.md_tf->tf_global[rs1] != 0) 330 1.7 mrg return (0); /* success */ 331 1.7 mrg rs1 = fs->fs_regs[rs2]; 332 1.7 mrg goto mov; 333 1.7 mrg case FMVRLEZ >> 2: 334 1.7 mrg /* Presume we're curproc */ 335 1.7 mrg rs1 = instr.i_fmovr.i_rs1; 336 1.7 mrg if (rs1 != 0 && (int64_t)curproc->p_md.md_tf->tf_global[rs1] > 0) 337 1.7 mrg return (0); /* success */ 338 1.7 mrg rs1 = fs->fs_regs[rs2]; 339 1.7 mrg goto mov; 340 1.7 mrg case FMVRLZ >> 2: 341 1.7 mrg /* Presume we're curproc */ 342 1.7 mrg rs1 = instr.i_fmovr.i_rs1; 343 1.7 mrg if (rs1 == 0 || (int64_t)curproc->p_md.md_tf->tf_global[rs1] >= 0) 344 1.7 mrg return (0); /* success */ 345 1.7 mrg rs1 = fs->fs_regs[rs2]; 346 1.7 mrg goto mov; 347 1.7 mrg case FMVRNZ >> 2: 348 1.7 mrg /* Presume we're curproc */ 349 1.7 mrg rs1 = instr.i_fmovr.i_rs1; 350 1.7 mrg if (rs1 == 0 || (int64_t)curproc->p_md.md_tf->tf_global[rs1] == 0) 351 1.7 mrg return (0); /* success */ 352 1.7 mrg rs1 = fs->fs_regs[rs2]; 353 1.7 mrg goto mov; 354 1.7 mrg case FMVRGZ >> 2: 355 1.7 mrg /* Presume we're curproc */ 356 1.7 mrg rs1 = instr.i_fmovr.i_rs1; 357 1.7 mrg if (rs1 == 0 || (int64_t)curproc->p_md.md_tf->tf_global[rs1] <= 0) 358 1.7 mrg return (0); /* success */ 359 1.7 mrg rs1 = fs->fs_regs[rs2]; 360 1.7 mrg goto mov; 361 1.7 mrg case FMVRGEZ >> 2: 362 1.7 mrg /* Presume we're curproc */ 363 1.7 mrg rs1 = instr.i_fmovr.i_rs1; 364 1.7 mrg if (rs1 != 0 && (int64_t)curproc->p_md.md_tf->tf_global[rs1] < 0) 365 1.7 mrg return (0); /* success */ 366 1.7 mrg rs1 = fs->fs_regs[rs2]; 367 1.7 mrg goto mov; 368 1.7 mrg case FCMP >> 2: 369 1.7 mrg fpu_explode(fe, &fe->fe_f1, type, rs1); 370 1.7 mrg fpu_explode(fe, &fe->fe_f2, type, rs2); 371 1.7 mrg fpu_compare(fe, 0); 372 1.7 mrg goto cmpdone; 373 1.7 mrg 374 1.7 mrg case FCMPE >> 2: 375 1.7 mrg fpu_explode(fe, &fe->fe_f1, type, rs1); 376 1.7 mrg fpu_explode(fe, &fe->fe_f2, type, rs2); 377 1.7 mrg fpu_compare(fe, 1); 378 1.7 mrg cmpdone: 379 1.7 mrg /* 380 1.7 mrg * The only possible exception here is NV; catch it 381 1.7 mrg * early and get out, as there is no result register. 382 1.7 mrg */ 383 1.7 mrg cx = fe->fe_cx; 384 1.7 mrg fsr = fe->fe_fsr | (cx << FSR_CX_SHIFT); 385 1.7 mrg if (cx != 0) { 386 1.7 mrg if (fsr & (FSR_NV << FSR_TEM_SHIFT)) { 387 1.7 mrg fs->fs_fsr = (fsr & ~FSR_FTT) | 388 1.7 mrg (FSR_TT_IEEE << FSR_FTT_SHIFT); 389 1.7 mrg return (FPE); 390 1.7 mrg } 391 1.7 mrg fsr |= FSR_NV << FSR_AX_SHIFT; 392 1.7 mrg } 393 1.7 mrg fs->fs_fsr = fsr; 394 1.7 mrg return (0); 395 1.7 mrg default: 396 1.7 mrg return (NOTFPU); 397 1.7 mrg } 398 1.7 mrg } 399 1.7 mrg #endif /* SUN4U */ 400 1.1 deraadt switch (opf >>= 2) { 401 1.1 deraadt 402 1.1 deraadt default: 403 1.1 deraadt return (NOTFPU); 404 1.1 deraadt 405 1.1 deraadt case FMOV >> 2: /* these should all be pretty obvious */ 406 1.1 deraadt rs1 = fs->fs_regs[rs2]; 407 1.1 deraadt goto mov; 408 1.1 deraadt 409 1.1 deraadt case FNEG >> 2: 410 1.1 deraadt rs1 = fs->fs_regs[rs2] ^ (1 << 31); 411 1.1 deraadt goto mov; 412 1.1 deraadt 413 1.1 deraadt case FABS >> 2: 414 1.1 deraadt rs1 = fs->fs_regs[rs2] & ~(1 << 31); 415 1.1 deraadt mov: 416 1.7 mrg #ifndef SUN4U 417 1.1 deraadt fs->fs_regs[rd] = rs1; 418 1.7 mrg #else /* SUN4U */ 419 1.7 mrg i = 1<<type; 420 1.7 mrg fs->fs_regs[rd++] = rs1; 421 1.7 mrg while (--i) 422 1.7 mrg fs->fs_regs[rd++] = fs->fs_regs[++rs2]; 423 1.7 mrg #endif /* SUN4U */ 424 1.1 deraadt fs->fs_fsr = fe->fe_fsr; 425 1.1 deraadt return (0); /* success */ 426 1.1 deraadt 427 1.1 deraadt case FSQRT >> 2: 428 1.1 deraadt fpu_explode(fe, &fe->fe_f1, type, rs2); 429 1.1 deraadt fp = fpu_sqrt(fe); 430 1.1 deraadt break; 431 1.1 deraadt 432 1.1 deraadt case FADD >> 2: 433 1.1 deraadt fpu_explode(fe, &fe->fe_f1, type, rs1); 434 1.1 deraadt fpu_explode(fe, &fe->fe_f2, type, rs2); 435 1.1 deraadt fp = fpu_add(fe); 436 1.1 deraadt break; 437 1.1 deraadt 438 1.1 deraadt case FSUB >> 2: 439 1.1 deraadt fpu_explode(fe, &fe->fe_f1, type, rs1); 440 1.1 deraadt fpu_explode(fe, &fe->fe_f2, type, rs2); 441 1.1 deraadt fp = fpu_sub(fe); 442 1.1 deraadt break; 443 1.1 deraadt 444 1.1 deraadt case FMUL >> 2: 445 1.1 deraadt fpu_explode(fe, &fe->fe_f1, type, rs1); 446 1.1 deraadt fpu_explode(fe, &fe->fe_f2, type, rs2); 447 1.1 deraadt fp = fpu_mul(fe); 448 1.1 deraadt break; 449 1.1 deraadt 450 1.1 deraadt case FDIV >> 2: 451 1.1 deraadt fpu_explode(fe, &fe->fe_f1, type, rs1); 452 1.1 deraadt fpu_explode(fe, &fe->fe_f2, type, rs2); 453 1.1 deraadt fp = fpu_div(fe); 454 1.1 deraadt break; 455 1.1 deraadt 456 1.7 mrg #ifndef SUN4U 457 1.1 deraadt case FCMP >> 2: 458 1.1 deraadt fpu_explode(fe, &fe->fe_f1, type, rs1); 459 1.1 deraadt fpu_explode(fe, &fe->fe_f2, type, rs2); 460 1.1 deraadt fpu_compare(fe, 0); 461 1.1 deraadt goto cmpdone; 462 1.1 deraadt 463 1.1 deraadt case FCMPE >> 2: 464 1.1 deraadt fpu_explode(fe, &fe->fe_f1, type, rs1); 465 1.1 deraadt fpu_explode(fe, &fe->fe_f2, type, rs2); 466 1.1 deraadt fpu_compare(fe, 1); 467 1.1 deraadt cmpdone: 468 1.1 deraadt /* 469 1.1 deraadt * The only possible exception here is NV; catch it 470 1.1 deraadt * early and get out, as there is no result register. 471 1.1 deraadt */ 472 1.1 deraadt cx = fe->fe_cx; 473 1.1 deraadt fsr = fe->fe_fsr | (cx << FSR_CX_SHIFT); 474 1.1 deraadt if (cx != 0) { 475 1.1 deraadt if (fsr & (FSR_NV << FSR_TEM_SHIFT)) { 476 1.1 deraadt fs->fs_fsr = (fsr & ~FSR_FTT) | 477 1.1 deraadt (FSR_TT_IEEE << FSR_FTT_SHIFT); 478 1.1 deraadt return (FPE); 479 1.1 deraadt } 480 1.1 deraadt fsr |= FSR_NV << FSR_AX_SHIFT; 481 1.1 deraadt } 482 1.1 deraadt fs->fs_fsr = fsr; 483 1.1 deraadt return (0); 484 1.1 deraadt 485 1.7 mrg #endif /* not SUN4U */ 486 1.1 deraadt case FSMULD >> 2: 487 1.1 deraadt case FDMULX >> 2: 488 1.1 deraadt if (type == FTYPE_EXT) 489 1.1 deraadt return (NOTFPU); 490 1.1 deraadt fpu_explode(fe, &fe->fe_f1, type, rs1); 491 1.1 deraadt fpu_explode(fe, &fe->fe_f2, type, rs2); 492 1.1 deraadt type++; /* single to double, or double to quad */ 493 1.1 deraadt fp = fpu_mul(fe); 494 1.1 deraadt break; 495 1.1 deraadt 496 1.7 mrg #ifdef SUN4U 497 1.7 mrg case FXTOS >> 2: 498 1.7 mrg case FXTOD >> 2: 499 1.7 mrg case FXTOQ >> 2: 500 1.7 mrg type = FTYPE_LNG; 501 1.7 mrg fpu_explode(fe, fp = &fe->fe_f1, type, rs2); 502 1.7 mrg type = opf & 3; /* sneaky; depends on instruction encoding */ 503 1.7 mrg break; 504 1.7 mrg 505 1.7 mrg case FTOX >> 2: 506 1.7 mrg fpu_explode(fe, fp = &fe->fe_f1, type, rs2); 507 1.7 mrg type = FTYPE_LNG; 508 1.7 mrg #endif /* SUN4U */ 509 1.7 mrg 510 1.1 deraadt case FTOS >> 2: 511 1.1 deraadt case FTOD >> 2: 512 1.7 mrg #ifndef SUN4U 513 1.1 deraadt case FTOX >> 2: 514 1.7 mrg #else /* SUN4U */ 515 1.7 mrg case FTOQ >> 2: 516 1.7 mrg #endif /* SUN4U */ 517 1.1 deraadt case FTOI >> 2: 518 1.1 deraadt fpu_explode(fe, fp = &fe->fe_f1, type, rs2); 519 1.1 deraadt type = opf & 3; /* sneaky; depends on instruction encoding */ 520 1.1 deraadt break; 521 1.1 deraadt } 522 1.1 deraadt 523 1.1 deraadt /* 524 1.1 deraadt * ALU operation is complete. Collapse the result and then check 525 1.1 deraadt * for exceptions. If we got any, and they are enabled, do not 526 1.1 deraadt * alter the destination register, just stop with an exception. 527 1.1 deraadt * Otherwise set new current exceptions and accrue. 528 1.1 deraadt */ 529 1.1 deraadt fpu_implode(fe, fp, type, space); 530 1.1 deraadt cx = fe->fe_cx; 531 1.1 deraadt fsr = fe->fe_fsr; 532 1.1 deraadt if (cx != 0) { 533 1.1 deraadt mask = (fsr >> FSR_TEM_SHIFT) & FSR_TEM_MASK; 534 1.1 deraadt if (cx & mask) { 535 1.1 deraadt /* not accrued??? */ 536 1.1 deraadt fs->fs_fsr = (fsr & ~FSR_FTT) | 537 1.1 deraadt (FSR_TT_IEEE << FSR_FTT_SHIFT) | 538 1.1 deraadt (cx_to_trapx[(cx & mask) - 1] << FSR_CX_SHIFT); 539 1.1 deraadt return (FPE); 540 1.1 deraadt } 541 1.1 deraadt fsr |= (cx << FSR_CX_SHIFT) | (cx << FSR_AX_SHIFT); 542 1.1 deraadt } 543 1.1 deraadt fs->fs_fsr = fsr; 544 1.1 deraadt fs->fs_regs[rd] = space[0]; 545 1.7 mrg #ifndef SUN4U 546 1.1 deraadt if (type >= FTYPE_DBL) { 547 1.7 mrg #else /* SUN4U */ 548 1.7 mrg if (type >= FTYPE_DBL || type == FTYPE_LNG) { 549 1.7 mrg #endif /* SUN4U */ 550 1.1 deraadt fs->fs_regs[rd + 1] = space[1]; 551 1.1 deraadt if (type > FTYPE_DBL) { 552 1.1 deraadt fs->fs_regs[rd + 2] = space[2]; 553 1.1 deraadt fs->fs_regs[rd + 3] = space[3]; 554 1.1 deraadt } 555 1.1 deraadt } 556 1.1 deraadt return (0); /* success */ 557 1.1 deraadt } 558
Indexes created Wed Sep 24 15:09:51 GMT 2025