tjh.dev / kernel
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kernel / arch / powerpc / lib / sstep.c
at v5.11-rc3 3537 lines 80 kB view raw
1// SPDX-License-Identifier: GPL-2.0-or-later 2/* 3 * Single-step support. 4 * 5 * Copyright (C) 2004 Paul Mackerras <paulus@au.ibm.com>, IBM 6 */ 7#include <linux/kernel.h> 8#include <linux/kprobes.h> 9#include <linux/ptrace.h> 10#include <linux/prefetch.h> 11#include <asm/sstep.h> 12#include <asm/processor.h> 13#include <linux/uaccess.h> 14#include <asm/cpu_has_feature.h> 15#include <asm/cputable.h> 16#include <asm/disassemble.h> 17 18extern char system_call_common[]; 19extern char system_call_vectored_emulate[]; 20 21#ifdef CONFIG_PPC64 22/* Bits in SRR1 that are copied from MSR */ 23#define MSR_MASK 0xffffffff87c0ffffUL 24#else 25#define MSR_MASK 0x87c0ffff 26#endif 27 28/* Bits in XER */ 29#define XER_SO 0x80000000U 30#define XER_OV 0x40000000U 31#define XER_CA 0x20000000U 32#define XER_OV32 0x00080000U 33#define XER_CA32 0x00040000U 34 35#ifdef CONFIG_VSX 36#define VSX_REGISTER_XTP(rd) ((((rd) & 1) << 5) | ((rd) & 0xfe)) 37#endif 38 39#ifdef CONFIG_PPC_FPU 40/* 41 * Functions in ldstfp.S 42 */ 43extern void get_fpr(int rn, double *p); 44extern void put_fpr(int rn, const double *p); 45extern void get_vr(int rn, __vector128 *p); 46extern void put_vr(int rn, __vector128 *p); 47extern void load_vsrn(int vsr, const void *p); 48extern void store_vsrn(int vsr, void *p); 49extern void conv_sp_to_dp(const float *sp, double *dp); 50extern void conv_dp_to_sp(const double *dp, float *sp); 51#endif 52 53#ifdef __powerpc64__ 54/* 55 * Functions in quad.S 56 */ 57extern int do_lq(unsigned long ea, unsigned long *regs); 58extern int do_stq(unsigned long ea, unsigned long val0, unsigned long val1); 59extern int do_lqarx(unsigned long ea, unsigned long *regs); 60extern int do_stqcx(unsigned long ea, unsigned long val0, unsigned long val1, 61 unsigned int *crp); 62#endif 63 64#ifdef __LITTLE_ENDIAN__ 65#define IS_LE 1 66#define IS_BE 0 67#else 68#define IS_LE 0 69#define IS_BE 1 70#endif 71 72/* 73 * Emulate the truncation of 64 bit values in 32-bit mode. 74 */ 75static nokprobe_inline unsigned long truncate_if_32bit(unsigned long msr, 76 unsigned long val) 77{ 78#ifdef __powerpc64__ 79 if ((msr & MSR_64BIT) == 0) 80 val &= 0xffffffffUL; 81#endif 82 return val; 83} 84 85/* 86 * Determine whether a conditional branch instruction would branch. 87 */ 88static nokprobe_inline int branch_taken(unsigned int instr, 89 const struct pt_regs *regs, 90 struct instruction_op *op) 91{ 92 unsigned int bo = (instr >> 21) & 0x1f; 93 unsigned int bi; 94 95 if ((bo & 4) == 0) { 96 /* decrement counter */ 97 op->type |= DECCTR; 98 if (((bo >> 1) & 1) ^ (regs->ctr == 1)) 99 return 0; 100 } 101 if ((bo & 0x10) == 0) { 102 /* check bit from CR */ 103 bi = (instr >> 16) & 0x1f; 104 if (((regs->ccr >> (31 - bi)) & 1) != ((bo >> 3) & 1)) 105 return 0; 106 } 107 return 1; 108} 109 110static nokprobe_inline long address_ok(struct pt_regs *regs, 111 unsigned long ea, int nb) 112{ 113 if (!user_mode(regs)) 114 return 1; 115 if (__access_ok(ea, nb)) 116 return 1; 117 if (__access_ok(ea, 1)) 118 /* Access overlaps the end of the user region */ 119 regs->dar = TASK_SIZE_MAX - 1; 120 else 121 regs->dar = ea; 122 return 0; 123} 124 125/* 126 * Calculate effective address for a D-form instruction 127 */ 128static nokprobe_inline unsigned long dform_ea(unsigned int instr, 129 const struct pt_regs *regs) 130{ 131 int ra; 132 unsigned long ea; 133 134 ra = (instr >> 16) & 0x1f; 135 ea = (signed short) instr; /* sign-extend */ 136 if (ra) 137 ea += regs->gpr[ra]; 138 139 return ea; 140} 141 142#ifdef __powerpc64__ 143/* 144 * Calculate effective address for a DS-form instruction 145 */ 146static nokprobe_inline unsigned long dsform_ea(unsigned int instr, 147 const struct pt_regs *regs) 148{ 149 int ra; 150 unsigned long ea; 151 152 ra = (instr >> 16) & 0x1f; 153 ea = (signed short) (instr & ~3); /* sign-extend */ 154 if (ra) 155 ea += regs->gpr[ra]; 156 157 return ea; 158} 159 160/* 161 * Calculate effective address for a DQ-form instruction 162 */ 163static nokprobe_inline unsigned long dqform_ea(unsigned int instr, 164 const struct pt_regs *regs) 165{ 166 int ra; 167 unsigned long ea; 168 169 ra = (instr >> 16) & 0x1f; 170 ea = (signed short) (instr & ~0xf); /* sign-extend */ 171 if (ra) 172 ea += regs->gpr[ra]; 173 174 return ea; 175} 176#endif /* __powerpc64 */ 177 178/* 179 * Calculate effective address for an X-form instruction 180 */ 181static nokprobe_inline unsigned long xform_ea(unsigned int instr, 182 const struct pt_regs *regs) 183{ 184 int ra, rb; 185 unsigned long ea; 186 187 ra = (instr >> 16) & 0x1f; 188 rb = (instr >> 11) & 0x1f; 189 ea = regs->gpr[rb]; 190 if (ra) 191 ea += regs->gpr[ra]; 192 193 return ea; 194} 195 196/* 197 * Calculate effective address for a MLS:D-form / 8LS:D-form 198 * prefixed instruction 199 */ 200static nokprobe_inline unsigned long mlsd_8lsd_ea(unsigned int instr, 201 unsigned int suffix, 202 const struct pt_regs *regs) 203{ 204 int ra, prefix_r; 205 unsigned int dd; 206 unsigned long ea, d0, d1, d; 207 208 prefix_r = GET_PREFIX_R(instr); 209 ra = GET_PREFIX_RA(suffix); 210 211 d0 = instr & 0x3ffff; 212 d1 = suffix & 0xffff; 213 d = (d0 << 16) | d1; 214 215 /* 216 * sign extend a 34 bit number 217 */ 218 dd = (unsigned int)(d >> 2); 219 ea = (signed int)dd; 220 ea = (ea << 2) | (d & 0x3); 221 222 if (!prefix_r && ra) 223 ea += regs->gpr[ra]; 224 else if (!prefix_r && !ra) 225 ; /* Leave ea as is */ 226 else if (prefix_r) 227 ea += regs->nip; 228 229 /* 230 * (prefix_r && ra) is an invalid form. Should already be 231 * checked for by caller! 232 */ 233 234 return ea; 235} 236 237/* 238 * Return the largest power of 2, not greater than sizeof(unsigned long), 239 * such that x is a multiple of it. 240 */ 241static nokprobe_inline unsigned long max_align(unsigned long x) 242{ 243 x |= sizeof(unsigned long); 244 return x & -x; /* isolates rightmost bit */ 245} 246 247static nokprobe_inline unsigned long byterev_2(unsigned long x) 248{ 249 return ((x >> 8) & 0xff) | ((x & 0xff) << 8); 250} 251 252static nokprobe_inline unsigned long byterev_4(unsigned long x) 253{ 254 return ((x >> 24) & 0xff) | ((x >> 8) & 0xff00) | 255 ((x & 0xff00) << 8) | ((x & 0xff) << 24); 256} 257 258#ifdef __powerpc64__ 259static nokprobe_inline unsigned long byterev_8(unsigned long x) 260{ 261 return (byterev_4(x) << 32) | byterev_4(x >> 32); 262} 263#endif 264 265static nokprobe_inline void do_byte_reverse(void *ptr, int nb) 266{ 267 switch (nb) { 268 case 2: 269 *(u16 *)ptr = byterev_2(*(u16 *)ptr); 270 break; 271 case 4: 272 *(u32 *)ptr = byterev_4(*(u32 *)ptr); 273 break; 274#ifdef __powerpc64__ 275 case 8: 276 *(unsigned long *)ptr = byterev_8(*(unsigned long *)ptr); 277 break; 278 case 16: { 279 unsigned long *up = (unsigned long *)ptr; 280 unsigned long tmp; 281 tmp = byterev_8(up[0]); 282 up[0] = byterev_8(up[1]); 283 up[1] = tmp; 284 break; 285 } 286 case 32: { 287 unsigned long *up = (unsigned long *)ptr; 288 unsigned long tmp; 289 290 tmp = byterev_8(up[0]); 291 up[0] = byterev_8(up[3]); 292 up[3] = tmp; 293 tmp = byterev_8(up[2]); 294 up[2] = byterev_8(up[1]); 295 up[1] = tmp; 296 break; 297 } 298 299#endif 300 default: 301 WARN_ON_ONCE(1); 302 } 303} 304 305static nokprobe_inline int read_mem_aligned(unsigned long *dest, 306 unsigned long ea, int nb, 307 struct pt_regs *regs) 308{ 309 int err = 0; 310 unsigned long x = 0; 311 312 switch (nb) { 313 case 1: 314 err = __get_user(x, (unsigned char __user *) ea); 315 break; 316 case 2: 317 err = __get_user(x, (unsigned short __user *) ea); 318 break; 319 case 4: 320 err = __get_user(x, (unsigned int __user *) ea); 321 break; 322#ifdef __powerpc64__ 323 case 8: 324 err = __get_user(x, (unsigned long __user *) ea); 325 break; 326#endif 327 } 328 if (!err) 329 *dest = x; 330 else 331 regs->dar = ea; 332 return err; 333} 334 335/* 336 * Copy from userspace to a buffer, using the largest possible 337 * aligned accesses, up to sizeof(long). 338 */ 339static nokprobe_inline int copy_mem_in(u8 *dest, unsigned long ea, int nb, 340 struct pt_regs *regs) 341{ 342 int err = 0; 343 int c; 344 345 for (; nb > 0; nb -= c) { 346 c = max_align(ea); 347 if (c > nb) 348 c = max_align(nb); 349 switch (c) { 350 case 1: 351 err = __get_user(*dest, (unsigned char __user *) ea); 352 break; 353 case 2: 354 err = __get_user(*(u16 *)dest, 355 (unsigned short __user *) ea); 356 break; 357 case 4: 358 err = __get_user(*(u32 *)dest, 359 (unsigned int __user *) ea); 360 break; 361#ifdef __powerpc64__ 362 case 8: 363 err = __get_user(*(unsigned long *)dest, 364 (unsigned long __user *) ea); 365 break; 366#endif 367 } 368 if (err) { 369 regs->dar = ea; 370 return err; 371 } 372 dest += c; 373 ea += c; 374 } 375 return 0; 376} 377 378static nokprobe_inline int read_mem_unaligned(unsigned long *dest, 379 unsigned long ea, int nb, 380 struct pt_regs *regs) 381{ 382 union { 383 unsigned long ul; 384 u8 b[sizeof(unsigned long)]; 385 } u; 386 int i; 387 int err; 388 389 u.ul = 0; 390 i = IS_BE ? sizeof(unsigned long) - nb : 0; 391 err = copy_mem_in(&u.b[i], ea, nb, regs); 392 if (!err) 393 *dest = u.ul; 394 return err; 395} 396 397/* 398 * Read memory at address ea for nb bytes, return 0 for success 399 * or -EFAULT if an error occurred. N.B. nb must be 1, 2, 4 or 8. 400 * If nb < sizeof(long), the result is right-justified on BE systems. 401 */ 402static int read_mem(unsigned long *dest, unsigned long ea, int nb, 403 struct pt_regs *regs) 404{ 405 if (!address_ok(regs, ea, nb)) 406 return -EFAULT; 407 if ((ea & (nb - 1)) == 0) 408 return read_mem_aligned(dest, ea, nb, regs); 409 return read_mem_unaligned(dest, ea, nb, regs); 410} 411NOKPROBE_SYMBOL(read_mem); 412 413static nokprobe_inline int write_mem_aligned(unsigned long val, 414 unsigned long ea, int nb, 415 struct pt_regs *regs) 416{ 417 int err = 0; 418 419 switch (nb) { 420 case 1: 421 err = __put_user(val, (unsigned char __user *) ea); 422 break; 423 case 2: 424 err = __put_user(val, (unsigned short __user *) ea); 425 break; 426 case 4: 427 err = __put_user(val, (unsigned int __user *) ea); 428 break; 429#ifdef __powerpc64__ 430 case 8: 431 err = __put_user(val, (unsigned long __user *) ea); 432 break; 433#endif 434 } 435 if (err) 436 regs->dar = ea; 437 return err; 438} 439 440/* 441 * Copy from a buffer to userspace, using the largest possible 442 * aligned accesses, up to sizeof(long). 443 */ 444static nokprobe_inline int copy_mem_out(u8 *dest, unsigned long ea, int nb, 445 struct pt_regs *regs) 446{ 447 int err = 0; 448 int c; 449 450 for (; nb > 0; nb -= c) { 451 c = max_align(ea); 452 if (c > nb) 453 c = max_align(nb); 454 switch (c) { 455 case 1: 456 err = __put_user(*dest, (unsigned char __user *) ea); 457 break; 458 case 2: 459 err = __put_user(*(u16 *)dest, 460 (unsigned short __user *) ea); 461 break; 462 case 4: 463 err = __put_user(*(u32 *)dest, 464 (unsigned int __user *) ea); 465 break; 466#ifdef __powerpc64__ 467 case 8: 468 err = __put_user(*(unsigned long *)dest, 469 (unsigned long __user *) ea); 470 break; 471#endif 472 } 473 if (err) { 474 regs->dar = ea; 475 return err; 476 } 477 dest += c; 478 ea += c; 479 } 480 return 0; 481} 482 483static nokprobe_inline int write_mem_unaligned(unsigned long val, 484 unsigned long ea, int nb, 485 struct pt_regs *regs) 486{ 487 union { 488 unsigned long ul; 489 u8 b[sizeof(unsigned long)]; 490 } u; 491 int i; 492 493 u.ul = val; 494 i = IS_BE ? sizeof(unsigned long) - nb : 0; 495 return copy_mem_out(&u.b[i], ea, nb, regs); 496} 497 498/* 499 * Write memory at address ea for nb bytes, return 0 for success 500 * or -EFAULT if an error occurred. N.B. nb must be 1, 2, 4 or 8. 501 */ 502static int write_mem(unsigned long val, unsigned long ea, int nb, 503 struct pt_regs *regs) 504{ 505 if (!address_ok(regs, ea, nb)) 506 return -EFAULT; 507 if ((ea & (nb - 1)) == 0) 508 return write_mem_aligned(val, ea, nb, regs); 509 return write_mem_unaligned(val, ea, nb, regs); 510} 511NOKPROBE_SYMBOL(write_mem); 512 513#ifdef CONFIG_PPC_FPU 514/* 515 * These access either the real FP register or the image in the 516 * thread_struct, depending on regs->msr & MSR_FP. 517 */ 518static int do_fp_load(struct instruction_op *op, unsigned long ea, 519 struct pt_regs *regs, bool cross_endian) 520{ 521 int err, rn, nb; 522 union { 523 int i; 524 unsigned int u; 525 float f; 526 double d[2]; 527 unsigned long l[2]; 528 u8 b[2 * sizeof(double)]; 529 } u; 530 531 nb = GETSIZE(op->type); 532 if (!address_ok(regs, ea, nb)) 533 return -EFAULT; 534 rn = op->reg; 535 err = copy_mem_in(u.b, ea, nb, regs); 536 if (err) 537 return err; 538 if (unlikely(cross_endian)) { 539 do_byte_reverse(u.b, min(nb, 8)); 540 if (nb == 16) 541 do_byte_reverse(&u.b[8], 8); 542 } 543 preempt_disable(); 544 if (nb == 4) { 545 if (op->type & FPCONV) 546 conv_sp_to_dp(&u.f, &u.d[0]); 547 else if (op->type & SIGNEXT) 548 u.l[0] = u.i; 549 else 550 u.l[0] = u.u; 551 } 552 if (regs->msr & MSR_FP) 553 put_fpr(rn, &u.d[0]); 554 else 555 current->thread.TS_FPR(rn) = u.l[0]; 556 if (nb == 16) { 557 /* lfdp */ 558 rn |= 1; 559 if (regs->msr & MSR_FP) 560 put_fpr(rn, &u.d[1]); 561 else 562 current->thread.TS_FPR(rn) = u.l[1]; 563 } 564 preempt_enable(); 565 return 0; 566} 567NOKPROBE_SYMBOL(do_fp_load); 568 569static int do_fp_store(struct instruction_op *op, unsigned long ea, 570 struct pt_regs *regs, bool cross_endian) 571{ 572 int rn, nb; 573 union { 574 unsigned int u; 575 float f; 576 double d[2]; 577 unsigned long l[2]; 578 u8 b[2 * sizeof(double)]; 579 } u; 580 581 nb = GETSIZE(op->type); 582 if (!address_ok(regs, ea, nb)) 583 return -EFAULT; 584 rn = op->reg; 585 preempt_disable(); 586 if (regs->msr & MSR_FP) 587 get_fpr(rn, &u.d[0]); 588 else 589 u.l[0] = current->thread.TS_FPR(rn); 590 if (nb == 4) { 591 if (op->type & FPCONV) 592 conv_dp_to_sp(&u.d[0], &u.f); 593 else 594 u.u = u.l[0]; 595 } 596 if (nb == 16) { 597 rn |= 1; 598 if (regs->msr & MSR_FP) 599 get_fpr(rn, &u.d[1]); 600 else 601 u.l[1] = current->thread.TS_FPR(rn); 602 } 603 preempt_enable(); 604 if (unlikely(cross_endian)) { 605 do_byte_reverse(u.b, min(nb, 8)); 606 if (nb == 16) 607 do_byte_reverse(&u.b[8], 8); 608 } 609 return copy_mem_out(u.b, ea, nb, regs); 610} 611NOKPROBE_SYMBOL(do_fp_store); 612#endif 613 614#ifdef CONFIG_ALTIVEC 615/* For Altivec/VMX, no need to worry about alignment */ 616static nokprobe_inline int do_vec_load(int rn, unsigned long ea, 617 int size, struct pt_regs *regs, 618 bool cross_endian) 619{ 620 int err; 621 union { 622 __vector128 v; 623 u8 b[sizeof(__vector128)]; 624 } u = {}; 625 626 if (!address_ok(regs, ea & ~0xfUL, 16)) 627 return -EFAULT; 628 /* align to multiple of size */ 629 ea &= ~(size - 1); 630 err = copy_mem_in(&u.b[ea & 0xf], ea, size, regs); 631 if (err) 632 return err; 633 if (unlikely(cross_endian)) 634 do_byte_reverse(&u.b[ea & 0xf], size); 635 preempt_disable(); 636 if (regs->msr & MSR_VEC) 637 put_vr(rn, &u.v); 638 else 639 current->thread.vr_state.vr[rn] = u.v; 640 preempt_enable(); 641 return 0; 642} 643 644static nokprobe_inline int do_vec_store(int rn, unsigned long ea, 645 int size, struct pt_regs *regs, 646 bool cross_endian) 647{ 648 union { 649 __vector128 v; 650 u8 b[sizeof(__vector128)]; 651 } u; 652 653 if (!address_ok(regs, ea & ~0xfUL, 16)) 654 return -EFAULT; 655 /* align to multiple of size */ 656 ea &= ~(size - 1); 657 658 preempt_disable(); 659 if (regs->msr & MSR_VEC) 660 get_vr(rn, &u.v); 661 else 662 u.v = current->thread.vr_state.vr[rn]; 663 preempt_enable(); 664 if (unlikely(cross_endian)) 665 do_byte_reverse(&u.b[ea & 0xf], size); 666 return copy_mem_out(&u.b[ea & 0xf], ea, size, regs); 667} 668#endif /* CONFIG_ALTIVEC */ 669 670#ifdef __powerpc64__ 671static nokprobe_inline int emulate_lq(struct pt_regs *regs, unsigned long ea, 672 int reg, bool cross_endian) 673{ 674 int err; 675 676 if (!address_ok(regs, ea, 16)) 677 return -EFAULT; 678 /* if aligned, should be atomic */ 679 if ((ea & 0xf) == 0) { 680 err = do_lq(ea, &regs->gpr[reg]); 681 } else { 682 err = read_mem(&regs->gpr[reg + IS_LE], ea, 8, regs); 683 if (!err) 684 err = read_mem(&regs->gpr[reg + IS_BE], ea + 8, 8, regs); 685 } 686 if (!err && unlikely(cross_endian)) 687 do_byte_reverse(&regs->gpr[reg], 16); 688 return err; 689} 690 691static nokprobe_inline int emulate_stq(struct pt_regs *regs, unsigned long ea, 692 int reg, bool cross_endian) 693{ 694 int err; 695 unsigned long vals[2]; 696 697 if (!address_ok(regs, ea, 16)) 698 return -EFAULT; 699 vals[0] = regs->gpr[reg]; 700 vals[1] = regs->gpr[reg + 1]; 701 if (unlikely(cross_endian)) 702 do_byte_reverse(vals, 16); 703 704 /* if aligned, should be atomic */ 705 if ((ea & 0xf) == 0) 706 return do_stq(ea, vals[0], vals[1]); 707 708 err = write_mem(vals[IS_LE], ea, 8, regs); 709 if (!err) 710 err = write_mem(vals[IS_BE], ea + 8, 8, regs); 711 return err; 712} 713#endif /* __powerpc64 */ 714 715#ifdef CONFIG_VSX 716void emulate_vsx_load(struct instruction_op *op, union vsx_reg *reg, 717 const void *mem, bool rev) 718{ 719 int size, read_size; 720 int i, j; 721 const unsigned int *wp; 722 const unsigned short *hp; 723 const unsigned char *bp; 724 725 size = GETSIZE(op->type); 726 reg->d[0] = reg->d[1] = 0; 727 728 switch (op->element_size) { 729 case 32: 730 /* [p]lxvp[x] */ 731 case 16: 732 /* whole vector; lxv[x] or lxvl[l] */ 733 if (size == 0) 734 break; 735 memcpy(reg, mem, size); 736 if (IS_LE && (op->vsx_flags & VSX_LDLEFT)) 737 rev = !rev; 738 if (rev) 739 do_byte_reverse(reg, size); 740 break; 741 case 8: 742 /* scalar loads, lxvd2x, lxvdsx */ 743 read_size = (size >= 8) ? 8 : size; 744 i = IS_LE ? 8 : 8 - read_size; 745 memcpy(&reg->b[i], mem, read_size); 746 if (rev) 747 do_byte_reverse(&reg->b[i], 8); 748 if (size < 8) { 749 if (op->type & SIGNEXT) { 750 /* size == 4 is the only case here */ 751 reg->d[IS_LE] = (signed int) reg->d[IS_LE]; 752 } else if (op->vsx_flags & VSX_FPCONV) { 753 preempt_disable(); 754 conv_sp_to_dp(&reg->fp[1 + IS_LE], 755 &reg->dp[IS_LE]); 756 preempt_enable(); 757 } 758 } else { 759 if (size == 16) { 760 unsigned long v = *(unsigned long *)(mem + 8); 761 reg->d[IS_BE] = !rev ? v : byterev_8(v); 762 } else if (op->vsx_flags & VSX_SPLAT) 763 reg->d[IS_BE] = reg->d[IS_LE]; 764 } 765 break; 766 case 4: 767 /* lxvw4x, lxvwsx */ 768 wp = mem; 769 for (j = 0; j < size / 4; ++j) { 770 i = IS_LE ? 3 - j : j; 771 reg->w[i] = !rev ? *wp++ : byterev_4(*wp++); 772 } 773 if (op->vsx_flags & VSX_SPLAT) { 774 u32 val = reg->w[IS_LE ? 3 : 0]; 775 for (; j < 4; ++j) { 776 i = IS_LE ? 3 - j : j; 777 reg->w[i] = val; 778 } 779 } 780 break; 781 case 2: 782 /* lxvh8x */ 783 hp = mem; 784 for (j = 0; j < size / 2; ++j) { 785 i = IS_LE ? 7 - j : j; 786 reg->h[i] = !rev ? *hp++ : byterev_2(*hp++); 787 } 788 break; 789 case 1: 790 /* lxvb16x */ 791 bp = mem; 792 for (j = 0; j < size; ++j) { 793 i = IS_LE ? 15 - j : j; 794 reg->b[i] = *bp++; 795 } 796 break; 797 } 798} 799EXPORT_SYMBOL_GPL(emulate_vsx_load); 800NOKPROBE_SYMBOL(emulate_vsx_load); 801 802void emulate_vsx_store(struct instruction_op *op, const union vsx_reg *reg, 803 void *mem, bool rev) 804{ 805 int size, write_size; 806 int i, j; 807 union vsx_reg buf; 808 unsigned int *wp; 809 unsigned short *hp; 810 unsigned char *bp; 811 812 size = GETSIZE(op->type); 813 814 switch (op->element_size) { 815 case 32: 816 /* [p]stxvp[x] */ 817 if (size == 0) 818 break; 819 if (rev) { 820 /* reverse 32 bytes */ 821 buf.d[0] = byterev_8(reg->d[3]); 822 buf.d[1] = byterev_8(reg->d[2]); 823 buf.d[2] = byterev_8(reg->d[1]); 824 buf.d[3] = byterev_8(reg->d[0]); 825 reg = &buf; 826 } 827 memcpy(mem, reg, size); 828 break; 829 case 16: 830 /* stxv, stxvx, stxvl, stxvll */ 831 if (size == 0) 832 break; 833 if (IS_LE && (op->vsx_flags & VSX_LDLEFT)) 834 rev = !rev; 835 if (rev) { 836 /* reverse 16 bytes */ 837 buf.d[0] = byterev_8(reg->d[1]); 838 buf.d[1] = byterev_8(reg->d[0]); 839 reg = &buf; 840 } 841 memcpy(mem, reg, size); 842 break; 843 case 8: 844 /* scalar stores, stxvd2x */ 845 write_size = (size >= 8) ? 8 : size; 846 i = IS_LE ? 8 : 8 - write_size; 847 if (size < 8 && op->vsx_flags & VSX_FPCONV) { 848 buf.d[0] = buf.d[1] = 0; 849 preempt_disable(); 850 conv_dp_to_sp(&reg->dp[IS_LE], &buf.fp[1 + IS_LE]); 851 preempt_enable(); 852 reg = &buf; 853 } 854 memcpy(mem, &reg->b[i], write_size); 855 if (size == 16) 856 memcpy(mem + 8, &reg->d[IS_BE], 8); 857 if (unlikely(rev)) { 858 do_byte_reverse(mem, write_size); 859 if (size == 16) 860 do_byte_reverse(mem + 8, 8); 861 } 862 break; 863 case 4: 864 /* stxvw4x */ 865 wp = mem; 866 for (j = 0; j < size / 4; ++j) { 867 i = IS_LE ? 3 - j : j; 868 *wp++ = !rev ? reg->w[i] : byterev_4(reg->w[i]); 869 } 870 break; 871 case 2: 872 /* stxvh8x */ 873 hp = mem; 874 for (j = 0; j < size / 2; ++j) { 875 i = IS_LE ? 7 - j : j; 876 *hp++ = !rev ? reg->h[i] : byterev_2(reg->h[i]); 877 } 878 break; 879 case 1: 880 /* stvxb16x */ 881 bp = mem; 882 for (j = 0; j < size; ++j) { 883 i = IS_LE ? 15 - j : j; 884 *bp++ = reg->b[i]; 885 } 886 break; 887 } 888} 889EXPORT_SYMBOL_GPL(emulate_vsx_store); 890NOKPROBE_SYMBOL(emulate_vsx_store); 891 892static nokprobe_inline int do_vsx_load(struct instruction_op *op, 893 unsigned long ea, struct pt_regs *regs, 894 bool cross_endian) 895{ 896 int reg = op->reg; 897 int i, j, nr_vsx_regs; 898 u8 mem[32]; 899 union vsx_reg buf[2]; 900 int size = GETSIZE(op->type); 901 902 if (!address_ok(regs, ea, size) || copy_mem_in(mem, ea, size, regs)) 903 return -EFAULT; 904 905 nr_vsx_regs = size / sizeof(__vector128); 906 emulate_vsx_load(op, buf, mem, cross_endian); 907 preempt_disable(); 908 if (reg < 32) { 909 /* FP regs + extensions */ 910 if (regs->msr & MSR_FP) { 911 for (i = 0; i < nr_vsx_regs; i++) { 912 j = IS_LE ? nr_vsx_regs - i - 1 : i; 913 load_vsrn(reg + i, &buf[j].v); 914 } 915 } else { 916 for (i = 0; i < nr_vsx_regs; i++) { 917 j = IS_LE ? nr_vsx_regs - i - 1 : i; 918 current->thread.fp_state.fpr[reg + i][0] = buf[j].d[0]; 919 current->thread.fp_state.fpr[reg + i][1] = buf[j].d[1]; 920 } 921 } 922 } else { 923 if (regs->msr & MSR_VEC) { 924 for (i = 0; i < nr_vsx_regs; i++) { 925 j = IS_LE ? nr_vsx_regs - i - 1 : i; 926 load_vsrn(reg + i, &buf[j].v); 927 } 928 } else { 929 for (i = 0; i < nr_vsx_regs; i++) { 930 j = IS_LE ? nr_vsx_regs - i - 1 : i; 931 current->thread.vr_state.vr[reg - 32 + i] = buf[j].v; 932 } 933 } 934 } 935 preempt_enable(); 936 return 0; 937} 938 939static nokprobe_inline int do_vsx_store(struct instruction_op *op, 940 unsigned long ea, struct pt_regs *regs, 941 bool cross_endian) 942{ 943 int reg = op->reg; 944 int i, j, nr_vsx_regs; 945 u8 mem[32]; 946 union vsx_reg buf[2]; 947 int size = GETSIZE(op->type); 948 949 if (!address_ok(regs, ea, size)) 950 return -EFAULT; 951 952 nr_vsx_regs = size / sizeof(__vector128); 953 preempt_disable(); 954 if (reg < 32) { 955 /* FP regs + extensions */ 956 if (regs->msr & MSR_FP) { 957 for (i = 0; i < nr_vsx_regs; i++) { 958 j = IS_LE ? nr_vsx_regs - i - 1 : i; 959 store_vsrn(reg + i, &buf[j].v); 960 } 961 } else { 962 for (i = 0; i < nr_vsx_regs; i++) { 963 j = IS_LE ? nr_vsx_regs - i - 1 : i; 964 buf[j].d[0] = current->thread.fp_state.fpr[reg + i][0]; 965 buf[j].d[1] = current->thread.fp_state.fpr[reg + i][1]; 966 } 967 } 968 } else { 969 if (regs->msr & MSR_VEC) { 970 for (i = 0; i < nr_vsx_regs; i++) { 971 j = IS_LE ? nr_vsx_regs - i - 1 : i; 972 store_vsrn(reg + i, &buf[j].v); 973 } 974 } else { 975 for (i = 0; i < nr_vsx_regs; i++) { 976 j = IS_LE ? nr_vsx_regs - i - 1 : i; 977 buf[j].v = current->thread.vr_state.vr[reg - 32 + i]; 978 } 979 } 980 } 981 preempt_enable(); 982 emulate_vsx_store(op, buf, mem, cross_endian); 983 return copy_mem_out(mem, ea, size, regs); 984} 985#endif /* CONFIG_VSX */ 986 987int emulate_dcbz(unsigned long ea, struct pt_regs *regs) 988{ 989 int err; 990 unsigned long i, size; 991 992#ifdef __powerpc64__ 993 size = ppc64_caches.l1d.block_size; 994 if (!(regs->msr & MSR_64BIT)) 995 ea &= 0xffffffffUL; 996#else 997 size = L1_CACHE_BYTES; 998#endif 999 ea &= ~(size - 1); 1000 if (!address_ok(regs, ea, size)) 1001 return -EFAULT; 1002 for (i = 0; i < size; i += sizeof(long)) { 1003 err = __put_user(0, (unsigned long __user *) (ea + i)); 1004 if (err) { 1005 regs->dar = ea; 1006 return err; 1007 } 1008 } 1009 return 0; 1010} 1011NOKPROBE_SYMBOL(emulate_dcbz); 1012 1013#define __put_user_asmx(x, addr, err, op, cr) \ 1014 __asm__ __volatile__( \ 1015 "1: " op " %2,0,%3\n" \ 1016 " mfcr %1\n" \ 1017 "2:\n" \ 1018 ".section .fixup,\"ax\"\n" \ 1019 "3: li %0,%4\n" \ 1020 " b 2b\n" \ 1021 ".previous\n" \ 1022 EX_TABLE(1b, 3b) \ 1023 : "=r" (err), "=r" (cr) \ 1024 : "r" (x), "r" (addr), "i" (-EFAULT), "0" (err)) 1025 1026#define __get_user_asmx(x, addr, err, op) \ 1027 __asm__ __volatile__( \ 1028 "1: "op" %1,0,%2\n" \ 1029 "2:\n" \ 1030 ".section .fixup,\"ax\"\n" \ 1031 "3: li %0,%3\n" \ 1032 " b 2b\n" \ 1033 ".previous\n" \ 1034 EX_TABLE(1b, 3b) \ 1035 : "=r" (err), "=r" (x) \ 1036 : "r" (addr), "i" (-EFAULT), "0" (err)) 1037 1038#define __cacheop_user_asmx(addr, err, op) \ 1039 __asm__ __volatile__( \ 1040 "1: "op" 0,%1\n" \ 1041 "2:\n" \ 1042 ".section .fixup,\"ax\"\n" \ 1043 "3: li %0,%3\n" \ 1044 " b 2b\n" \ 1045 ".previous\n" \ 1046 EX_TABLE(1b, 3b) \ 1047 : "=r" (err) \ 1048 : "r" (addr), "i" (-EFAULT), "0" (err)) 1049 1050static nokprobe_inline void set_cr0(const struct pt_regs *regs, 1051 struct instruction_op *op) 1052{ 1053 long val = op->val; 1054 1055 op->type |= SETCC; 1056 op->ccval = (regs->ccr & 0x0fffffff) | ((regs->xer >> 3) & 0x10000000); 1057#ifdef __powerpc64__ 1058 if (!(regs->msr & MSR_64BIT)) 1059 val = (int) val; 1060#endif 1061 if (val < 0) 1062 op->ccval |= 0x80000000; 1063 else if (val > 0) 1064 op->ccval |= 0x40000000; 1065 else 1066 op->ccval |= 0x20000000; 1067} 1068 1069static nokprobe_inline void set_ca32(struct instruction_op *op, bool val) 1070{ 1071 if (cpu_has_feature(CPU_FTR_ARCH_300)) { 1072 if (val) 1073 op->xerval |= XER_CA32; 1074 else 1075 op->xerval &= ~XER_CA32; 1076 } 1077} 1078 1079static nokprobe_inline void add_with_carry(const struct pt_regs *regs, 1080 struct instruction_op *op, int rd, 1081 unsigned long val1, unsigned long val2, 1082 unsigned long carry_in) 1083{ 1084 unsigned long val = val1 + val2; 1085 1086 if (carry_in) 1087 ++val; 1088 op->type = COMPUTE + SETREG + SETXER; 1089 op->reg = rd; 1090 op->val = val; 1091#ifdef __powerpc64__ 1092 if (!(regs->msr & MSR_64BIT)) { 1093 val = (unsigned int) val; 1094 val1 = (unsigned int) val1; 1095 } 1096#endif 1097 op->xerval = regs->xer; 1098 if (val < val1 || (carry_in && val == val1)) 1099 op->xerval |= XER_CA; 1100 else 1101 op->xerval &= ~XER_CA; 1102 1103 set_ca32(op, (unsigned int)val < (unsigned int)val1 || 1104 (carry_in && (unsigned int)val == (unsigned int)val1)); 1105} 1106 1107static nokprobe_inline void do_cmp_signed(const struct pt_regs *regs, 1108 struct instruction_op *op, 1109 long v1, long v2, int crfld) 1110{ 1111 unsigned int crval, shift; 1112 1113 op->type = COMPUTE + SETCC; 1114 crval = (regs->xer >> 31) & 1; /* get SO bit */ 1115 if (v1 < v2) 1116 crval |= 8; 1117 else if (v1 > v2) 1118 crval |= 4; 1119 else 1120 crval |= 2; 1121 shift = (7 - crfld) * 4; 1122 op->ccval = (regs->ccr & ~(0xf << shift)) | (crval << shift); 1123} 1124 1125static nokprobe_inline void do_cmp_unsigned(const struct pt_regs *regs, 1126 struct instruction_op *op, 1127 unsigned long v1, 1128 unsigned long v2, int crfld) 1129{ 1130 unsigned int crval, shift; 1131 1132 op->type = COMPUTE + SETCC; 1133 crval = (regs->xer >> 31) & 1; /* get SO bit */ 1134 if (v1 < v2) 1135 crval |= 8; 1136 else if (v1 > v2) 1137 crval |= 4; 1138 else 1139 crval |= 2; 1140 shift = (7 - crfld) * 4; 1141 op->ccval = (regs->ccr & ~(0xf << shift)) | (crval << shift); 1142} 1143 1144static nokprobe_inline void do_cmpb(const struct pt_regs *regs, 1145 struct instruction_op *op, 1146 unsigned long v1, unsigned long v2) 1147{ 1148 unsigned long long out_val, mask; 1149 int i; 1150 1151 out_val = 0; 1152 for (i = 0; i < 8; i++) { 1153 mask = 0xffUL << (i * 8); 1154 if ((v1 & mask) == (v2 & mask)) 1155 out_val |= mask; 1156 } 1157 op->val = out_val; 1158} 1159 1160/* 1161 * The size parameter is used to adjust the equivalent popcnt instruction. 1162 * popcntb = 8, popcntw = 32, popcntd = 64 1163 */ 1164static nokprobe_inline void do_popcnt(const struct pt_regs *regs, 1165 struct instruction_op *op, 1166 unsigned long v1, int size) 1167{ 1168 unsigned long long out = v1; 1169 1170 out -= (out >> 1) & 0x5555555555555555ULL; 1171 out = (0x3333333333333333ULL & out) + 1172 (0x3333333333333333ULL & (out >> 2)); 1173 out = (out + (out >> 4)) & 0x0f0f0f0f0f0f0f0fULL; 1174 1175 if (size == 8) { /* popcntb */ 1176 op->val = out; 1177 return; 1178 } 1179 out += out >> 8; 1180 out += out >> 16; 1181 if (size == 32) { /* popcntw */ 1182 op->val = out & 0x0000003f0000003fULL; 1183 return; 1184 } 1185 1186 out = (out + (out >> 32)) & 0x7f; 1187 op->val = out; /* popcntd */ 1188} 1189 1190#ifdef CONFIG_PPC64 1191static nokprobe_inline void do_bpermd(const struct pt_regs *regs, 1192 struct instruction_op *op, 1193 unsigned long v1, unsigned long v2) 1194{ 1195 unsigned char perm, idx; 1196 unsigned int i; 1197 1198 perm = 0; 1199 for (i = 0; i < 8; i++) { 1200 idx = (v1 >> (i * 8)) & 0xff; 1201 if (idx < 64) 1202 if (v2 & PPC_BIT(idx)) 1203 perm |= 1 << i; 1204 } 1205 op->val = perm; 1206} 1207#endif /* CONFIG_PPC64 */ 1208/* 1209 * The size parameter adjusts the equivalent prty instruction. 1210 * prtyw = 32, prtyd = 64 1211 */ 1212static nokprobe_inline void do_prty(const struct pt_regs *regs, 1213 struct instruction_op *op, 1214 unsigned long v, int size) 1215{ 1216 unsigned long long res = v ^ (v >> 8); 1217 1218 res ^= res >> 16; 1219 if (size == 32) { /* prtyw */ 1220 op->val = res & 0x0000000100000001ULL; 1221 return; 1222 } 1223 1224 res ^= res >> 32; 1225 op->val = res & 1; /*prtyd */ 1226} 1227 1228static nokprobe_inline int trap_compare(long v1, long v2) 1229{ 1230 int ret = 0; 1231 1232 if (v1 < v2) 1233 ret |= 0x10; 1234 else if (v1 > v2) 1235 ret |= 0x08; 1236 else 1237 ret |= 0x04; 1238 if ((unsigned long)v1 < (unsigned long)v2) 1239 ret |= 0x02; 1240 else if ((unsigned long)v1 > (unsigned long)v2) 1241 ret |= 0x01; 1242 return ret; 1243} 1244 1245/* 1246 * Elements of 32-bit rotate and mask instructions. 1247 */ 1248#define MASK32(mb, me) ((0xffffffffUL >> (mb)) + \ 1249 ((signed long)-0x80000000L >> (me)) + ((me) >= (mb))) 1250#ifdef __powerpc64__ 1251#define MASK64_L(mb) (~0UL >> (mb)) 1252#define MASK64_R(me) ((signed long)-0x8000000000000000L >> (me)) 1253#define MASK64(mb, me) (MASK64_L(mb) + MASK64_R(me) + ((me) >= (mb))) 1254#define DATA32(x) (((x) & 0xffffffffUL) | (((x) & 0xffffffffUL) << 32)) 1255#else 1256#define DATA32(x) (x) 1257#endif 1258#define ROTATE(x, n) ((n) ? (((x) << (n)) | ((x) >> (8 * sizeof(long) - (n)))) : (x)) 1259 1260/* 1261 * Decode an instruction, and return information about it in *op 1262 * without changing *regs. 1263 * Integer arithmetic and logical instructions, branches, and barrier 1264 * instructions can be emulated just using the information in *op. 1265 * 1266 * Return value is 1 if the instruction can be emulated just by 1267 * updating *regs with the information in *op, -1 if we need the 1268 * GPRs but *regs doesn't contain the full register set, or 0 1269 * otherwise. 1270 */ 1271int analyse_instr(struct instruction_op *op, const struct pt_regs *regs, 1272 struct ppc_inst instr) 1273{ 1274#ifdef CONFIG_PPC64 1275 unsigned int suffixopcode, prefixtype, prefix_r; 1276#endif 1277 unsigned int opcode, ra, rb, rc, rd, spr, u; 1278 unsigned long int imm; 1279 unsigned long int val, val2; 1280 unsigned int mb, me, sh; 1281 unsigned int word, suffix; 1282 long ival; 1283 1284 word = ppc_inst_val(instr); 1285 suffix = ppc_inst_suffix(instr); 1286 1287 op->type = COMPUTE; 1288 1289 opcode = ppc_inst_primary_opcode(instr); 1290 switch (opcode) { 1291 case 16: /* bc */ 1292 op->type = BRANCH; 1293 imm = (signed short)(word & 0xfffc); 1294 if ((word & 2) == 0) 1295 imm += regs->nip; 1296 op->val = truncate_if_32bit(regs->msr, imm); 1297 if (word & 1) 1298 op->type |= SETLK; 1299 if (branch_taken(word, regs, op)) 1300 op->type |= BRTAKEN; 1301 return 1; 1302#ifdef CONFIG_PPC64 1303 case 17: /* sc */ 1304 if ((word & 0xfe2) == 2) 1305 op->type = SYSCALL; 1306 else if (IS_ENABLED(CONFIG_PPC_BOOK3S_64) && 1307 (word & 0xfe3) == 1) 1308 op->type = SYSCALL_VECTORED_0; 1309 else 1310 op->type = UNKNOWN; 1311 return 0; 1312#endif 1313 case 18: /* b */ 1314 op->type = BRANCH | BRTAKEN; 1315 imm = word & 0x03fffffc; 1316 if (imm & 0x02000000) 1317 imm -= 0x04000000; 1318 if ((word & 2) == 0) 1319 imm += regs->nip; 1320 op->val = truncate_if_32bit(regs->msr, imm); 1321 if (word & 1) 1322 op->type |= SETLK; 1323 return 1; 1324 case 19: 1325 switch ((word >> 1) & 0x3ff) { 1326 case 0: /* mcrf */ 1327 op->type = COMPUTE + SETCC; 1328 rd = 7 - ((word >> 23) & 0x7); 1329 ra = 7 - ((word >> 18) & 0x7); 1330 rd *= 4; 1331 ra *= 4; 1332 val = (regs->ccr >> ra) & 0xf; 1333 op->ccval = (regs->ccr & ~(0xfUL << rd)) | (val << rd); 1334 return 1; 1335 1336 case 16: /* bclr */ 1337 case 528: /* bcctr */ 1338 op->type = BRANCH; 1339 imm = (word & 0x400)? regs->ctr: regs->link; 1340 op->val = truncate_if_32bit(regs->msr, imm); 1341 if (word & 1) 1342 op->type |= SETLK; 1343 if (branch_taken(word, regs, op)) 1344 op->type |= BRTAKEN; 1345 return 1; 1346 1347 case 18: /* rfid, scary */ 1348 if (regs->msr & MSR_PR) 1349 goto priv; 1350 op->type = RFI; 1351 return 0; 1352 1353 case 150: /* isync */ 1354 op->type = BARRIER | BARRIER_ISYNC; 1355 return 1; 1356 1357 case 33: /* crnor */ 1358 case 129: /* crandc */ 1359 case 193: /* crxor */ 1360 case 225: /* crnand */ 1361 case 257: /* crand */ 1362 case 289: /* creqv */ 1363 case 417: /* crorc */ 1364 case 449: /* cror */ 1365 op->type = COMPUTE + SETCC; 1366 ra = (word >> 16) & 0x1f; 1367 rb = (word >> 11) & 0x1f; 1368 rd = (word >> 21) & 0x1f; 1369 ra = (regs->ccr >> (31 - ra)) & 1; 1370 rb = (regs->ccr >> (31 - rb)) & 1; 1371 val = (word >> (6 + ra * 2 + rb)) & 1; 1372 op->ccval = (regs->ccr & ~(1UL << (31 - rd))) | 1373 (val << (31 - rd)); 1374 return 1; 1375 } 1376 break; 1377 case 31: 1378 switch ((word >> 1) & 0x3ff) { 1379 case 598: /* sync */ 1380 op->type = BARRIER + BARRIER_SYNC; 1381#ifdef __powerpc64__ 1382 switch ((word >> 21) & 3) { 1383 case 1: /* lwsync */ 1384 op->type = BARRIER + BARRIER_LWSYNC; 1385 break; 1386 case 2: /* ptesync */ 1387 op->type = BARRIER + BARRIER_PTESYNC; 1388 break; 1389 } 1390#endif 1391 return 1; 1392 1393 case 854: /* eieio */ 1394 op->type = BARRIER + BARRIER_EIEIO; 1395 return 1; 1396 } 1397 break; 1398 } 1399 1400 /* Following cases refer to regs->gpr[], so we need all regs */ 1401 if (!FULL_REGS(regs)) 1402 return -1; 1403 1404 rd = (word >> 21) & 0x1f; 1405 ra = (word >> 16) & 0x1f; 1406 rb = (word >> 11) & 0x1f; 1407 rc = (word >> 6) & 0x1f; 1408 1409 switch (opcode) { 1410#ifdef __powerpc64__ 1411 case 1: 1412 if (!cpu_has_feature(CPU_FTR_ARCH_31)) 1413 return -1; 1414 1415 prefix_r = GET_PREFIX_R(word); 1416 ra = GET_PREFIX_RA(suffix); 1417 rd = (suffix >> 21) & 0x1f; 1418 op->reg = rd; 1419 op->val = regs->gpr[rd]; 1420 suffixopcode = get_op(suffix); 1421 prefixtype = (word >> 24) & 0x3; 1422 switch (prefixtype) { 1423 case 2: 1424 if (prefix_r && ra) 1425 return 0; 1426 switch (suffixopcode) { 1427 case 14: /* paddi */ 1428 op->type = COMPUTE | PREFIXED; 1429 op->val = mlsd_8lsd_ea(word, suffix, regs); 1430 goto compute_done; 1431 } 1432 } 1433 break; 1434 case 2: /* tdi */ 1435 if (rd & trap_compare(regs->gpr[ra], (short) word)) 1436 goto trap; 1437 return 1; 1438#endif 1439 case 3: /* twi */ 1440 if (rd & trap_compare((int)regs->gpr[ra], (short) word)) 1441 goto trap; 1442 return 1; 1443 1444#ifdef __powerpc64__ 1445 case 4: 1446 if (!cpu_has_feature(CPU_FTR_ARCH_300)) 1447 return -1; 1448 1449 switch (word & 0x3f) { 1450 case 48: /* maddhd */ 1451 asm volatile(PPC_MADDHD(%0, %1, %2, %3) : 1452 "=r" (op->val) : "r" (regs->gpr[ra]), 1453 "r" (regs->gpr[rb]), "r" (regs->gpr[rc])); 1454 goto compute_done; 1455 1456 case 49: /* maddhdu */ 1457 asm volatile(PPC_MADDHDU(%0, %1, %2, %3) : 1458 "=r" (op->val) : "r" (regs->gpr[ra]), 1459 "r" (regs->gpr[rb]), "r" (regs->gpr[rc])); 1460 goto compute_done; 1461 1462 case 51: /* maddld */ 1463 asm volatile(PPC_MADDLD(%0, %1, %2, %3) : 1464 "=r" (op->val) : "r" (regs->gpr[ra]), 1465 "r" (regs->gpr[rb]), "r" (regs->gpr[rc])); 1466 goto compute_done; 1467 } 1468 1469 /* 1470 * There are other instructions from ISA 3.0 with the same 1471 * primary opcode which do not have emulation support yet. 1472 */ 1473 return -1; 1474#endif 1475 1476 case 7: /* mulli */ 1477 op->val = regs->gpr[ra] * (short) word; 1478 goto compute_done; 1479 1480 case 8: /* subfic */ 1481 imm = (short) word; 1482 add_with_carry(regs, op, rd, ~regs->gpr[ra], imm, 1); 1483 return 1; 1484 1485 case 10: /* cmpli */ 1486 imm = (unsigned short) word; 1487 val = regs->gpr[ra]; 1488#ifdef __powerpc64__ 1489 if ((rd & 1) == 0) 1490 val = (unsigned int) val; 1491#endif 1492 do_cmp_unsigned(regs, op, val, imm, rd >> 2); 1493 return 1; 1494 1495 case 11: /* cmpi */ 1496 imm = (short) word; 1497 val = regs->gpr[ra]; 1498#ifdef __powerpc64__ 1499 if ((rd & 1) == 0) 1500 val = (int) val; 1501#endif 1502 do_cmp_signed(regs, op, val, imm, rd >> 2); 1503 return 1; 1504 1505 case 12: /* addic */ 1506 imm = (short) word; 1507 add_with_carry(regs, op, rd, regs->gpr[ra], imm, 0); 1508 return 1; 1509 1510 case 13: /* addic. */ 1511 imm = (short) word; 1512 add_with_carry(regs, op, rd, regs->gpr[ra], imm, 0); 1513 set_cr0(regs, op); 1514 return 1; 1515 1516 case 14: /* addi */ 1517 imm = (short) word; 1518 if (ra) 1519 imm += regs->gpr[ra]; 1520 op->val = imm; 1521 goto compute_done; 1522 1523 case 15: /* addis */ 1524 imm = ((short) word) << 16; 1525 if (ra) 1526 imm += regs->gpr[ra]; 1527 op->val = imm; 1528 goto compute_done; 1529 1530 case 19: 1531 if (((word >> 1) & 0x1f) == 2) { 1532 /* addpcis */ 1533 imm = (short) (word & 0xffc1); /* d0 + d2 fields */ 1534 imm |= (word >> 15) & 0x3e; /* d1 field */ 1535 op->val = regs->nip + (imm << 16) + 4; 1536 goto compute_done; 1537 } 1538 op->type = UNKNOWN; 1539 return 0; 1540 1541 case 20: /* rlwimi */ 1542 mb = (word >> 6) & 0x1f; 1543 me = (word >> 1) & 0x1f; 1544 val = DATA32(regs->gpr[rd]); 1545 imm = MASK32(mb, me); 1546 op->val = (regs->gpr[ra] & ~imm) | (ROTATE(val, rb) & imm); 1547 goto logical_done; 1548 1549 case 21: /* rlwinm */ 1550 mb = (word >> 6) & 0x1f; 1551 me = (word >> 1) & 0x1f; 1552 val = DATA32(regs->gpr[rd]); 1553 op->val = ROTATE(val, rb) & MASK32(mb, me); 1554 goto logical_done; 1555 1556 case 23: /* rlwnm */ 1557 mb = (word >> 6) & 0x1f; 1558 me = (word >> 1) & 0x1f; 1559 rb = regs->gpr[rb] & 0x1f; 1560 val = DATA32(regs->gpr[rd]); 1561 op->val = ROTATE(val, rb) & MASK32(mb, me); 1562 goto logical_done; 1563 1564 case 24: /* ori */ 1565 op->val = regs->gpr[rd] | (unsigned short) word; 1566 goto logical_done_nocc; 1567 1568 case 25: /* oris */ 1569 imm = (unsigned short) word; 1570 op->val = regs->gpr[rd] | (imm << 16); 1571 goto logical_done_nocc; 1572 1573 case 26: /* xori */ 1574 op->val = regs->gpr[rd] ^ (unsigned short) word; 1575 goto logical_done_nocc; 1576 1577 case 27: /* xoris */ 1578 imm = (unsigned short) word; 1579 op->val = regs->gpr[rd] ^ (imm << 16); 1580 goto logical_done_nocc; 1581 1582 case 28: /* andi. */ 1583 op->val = regs->gpr[rd] & (unsigned short) word; 1584 set_cr0(regs, op); 1585 goto logical_done_nocc; 1586 1587 case 29: /* andis. */ 1588 imm = (unsigned short) word; 1589 op->val = regs->gpr[rd] & (imm << 16); 1590 set_cr0(regs, op); 1591 goto logical_done_nocc; 1592 1593#ifdef __powerpc64__ 1594 case 30: /* rld* */ 1595 mb = ((word >> 6) & 0x1f) | (word & 0x20); 1596 val = regs->gpr[rd]; 1597 if ((word & 0x10) == 0) { 1598 sh = rb | ((word & 2) << 4); 1599 val = ROTATE(val, sh); 1600 switch ((word >> 2) & 3) { 1601 case 0: /* rldicl */ 1602 val &= MASK64_L(mb); 1603 break; 1604 case 1: /* rldicr */ 1605 val &= MASK64_R(mb); 1606 break; 1607 case 2: /* rldic */ 1608 val &= MASK64(mb, 63 - sh); 1609 break; 1610 case 3: /* rldimi */ 1611 imm = MASK64(mb, 63 - sh); 1612 val = (regs->gpr[ra] & ~imm) | 1613 (val & imm); 1614 } 1615 op->val = val; 1616 goto logical_done; 1617 } else { 1618 sh = regs->gpr[rb] & 0x3f; 1619 val = ROTATE(val, sh); 1620 switch ((word >> 1) & 7) { 1621 case 0: /* rldcl */ 1622 op->val = val & MASK64_L(mb); 1623 goto logical_done; 1624 case 1: /* rldcr */ 1625 op->val = val & MASK64_R(mb); 1626 goto logical_done; 1627 } 1628 } 1629#endif 1630 op->type = UNKNOWN; /* illegal instruction */ 1631 return 0; 1632 1633 case 31: 1634 /* isel occupies 32 minor opcodes */ 1635 if (((word >> 1) & 0x1f) == 15) { 1636 mb = (word >> 6) & 0x1f; /* bc field */ 1637 val = (regs->ccr >> (31 - mb)) & 1; 1638 val2 = (ra) ? regs->gpr[ra] : 0; 1639 1640 op->val = (val) ? val2 : regs->gpr[rb]; 1641 goto compute_done; 1642 } 1643 1644 switch ((word >> 1) & 0x3ff) { 1645 case 4: /* tw */ 1646 if (rd == 0x1f || 1647 (rd & trap_compare((int)regs->gpr[ra], 1648 (int)regs->gpr[rb]))) 1649 goto trap; 1650 return 1; 1651#ifdef __powerpc64__ 1652 case 68: /* td */ 1653 if (rd & trap_compare(regs->gpr[ra], regs->gpr[rb])) 1654 goto trap; 1655 return 1; 1656#endif 1657 case 83: /* mfmsr */ 1658 if (regs->msr & MSR_PR) 1659 goto priv; 1660 op->type = MFMSR; 1661 op->reg = rd; 1662 return 0; 1663 case 146: /* mtmsr */ 1664 if (regs->msr & MSR_PR) 1665 goto priv; 1666 op->type = MTMSR; 1667 op->reg = rd; 1668 op->val = 0xffffffff & ~(MSR_ME | MSR_LE); 1669 return 0; 1670#ifdef CONFIG_PPC64 1671 case 178: /* mtmsrd */ 1672 if (regs->msr & MSR_PR) 1673 goto priv; 1674 op->type = MTMSR; 1675 op->reg = rd; 1676 /* only MSR_EE and MSR_RI get changed if bit 15 set */ 1677 /* mtmsrd doesn't change MSR_HV, MSR_ME or MSR_LE */ 1678 imm = (word & 0x10000)? 0x8002: 0xefffffffffffeffeUL; 1679 op->val = imm; 1680 return 0; 1681#endif 1682 1683 case 19: /* mfcr */ 1684 imm = 0xffffffffUL; 1685 if ((word >> 20) & 1) { 1686 imm = 0xf0000000UL; 1687 for (sh = 0; sh < 8; ++sh) { 1688 if (word & (0x80000 >> sh)) 1689 break; 1690 imm >>= 4; 1691 } 1692 } 1693 op->val = regs->ccr & imm; 1694 goto compute_done; 1695 1696 case 144: /* mtcrf */ 1697 op->type = COMPUTE + SETCC; 1698 imm = 0xf0000000UL; 1699 val = regs->gpr[rd]; 1700 op->ccval = regs->ccr; 1701 for (sh = 0; sh < 8; ++sh) { 1702 if (word & (0x80000 >> sh)) 1703 op->ccval = (op->ccval & ~imm) | 1704 (val & imm); 1705 imm >>= 4; 1706 } 1707 return 1; 1708 1709 case 339: /* mfspr */ 1710 spr = ((word >> 16) & 0x1f) | ((word >> 6) & 0x3e0); 1711 op->type = MFSPR; 1712 op->reg = rd; 1713 op->spr = spr; 1714 if (spr == SPRN_XER || spr == SPRN_LR || 1715 spr == SPRN_CTR) 1716 return 1; 1717 return 0; 1718 1719 case 467: /* mtspr */ 1720 spr = ((word >> 16) & 0x1f) | ((word >> 6) & 0x3e0); 1721 op->type = MTSPR; 1722 op->val = regs->gpr[rd]; 1723 op->spr = spr; 1724 if (spr == SPRN_XER || spr == SPRN_LR || 1725 spr == SPRN_CTR) 1726 return 1; 1727 return 0; 1728 1729/* 1730 * Compare instructions 1731 */ 1732 case 0: /* cmp */ 1733 val = regs->gpr[ra]; 1734 val2 = regs->gpr[rb]; 1735#ifdef __powerpc64__ 1736 if ((rd & 1) == 0) { 1737 /* word (32-bit) compare */ 1738 val = (int) val; 1739 val2 = (int) val2; 1740 } 1741#endif 1742 do_cmp_signed(regs, op, val, val2, rd >> 2); 1743 return 1; 1744 1745 case 32: /* cmpl */ 1746 val = regs->gpr[ra]; 1747 val2 = regs->gpr[rb]; 1748#ifdef __powerpc64__ 1749 if ((rd & 1) == 0) { 1750 /* word (32-bit) compare */ 1751 val = (unsigned int) val; 1752 val2 = (unsigned int) val2; 1753 } 1754#endif 1755 do_cmp_unsigned(regs, op, val, val2, rd >> 2); 1756 return 1; 1757 1758 case 508: /* cmpb */ 1759 do_cmpb(regs, op, regs->gpr[rd], regs->gpr[rb]); 1760 goto logical_done_nocc; 1761 1762/* 1763 * Arithmetic instructions 1764 */ 1765 case 8: /* subfc */ 1766 add_with_carry(regs, op, rd, ~regs->gpr[ra], 1767 regs->gpr[rb], 1); 1768 goto arith_done; 1769#ifdef __powerpc64__ 1770 case 9: /* mulhdu */ 1771 asm("mulhdu %0,%1,%2" : "=r" (op->val) : 1772 "r" (regs->gpr[ra]), "r" (regs->gpr[rb])); 1773 goto arith_done; 1774#endif 1775 case 10: /* addc */ 1776 add_with_carry(regs, op, rd, regs->gpr[ra], 1777 regs->gpr[rb], 0); 1778 goto arith_done; 1779 1780 case 11: /* mulhwu */ 1781 asm("mulhwu %0,%1,%2" : "=r" (op->val) : 1782 "r" (regs->gpr[ra]), "r" (regs->gpr[rb])); 1783 goto arith_done; 1784 1785 case 40: /* subf */ 1786 op->val = regs->gpr[rb] - regs->gpr[ra]; 1787 goto arith_done; 1788#ifdef __powerpc64__ 1789 case 73: /* mulhd */ 1790 asm("mulhd %0,%1,%2" : "=r" (op->val) : 1791 "r" (regs->gpr[ra]), "r" (regs->gpr[rb])); 1792 goto arith_done; 1793#endif 1794 case 75: /* mulhw */ 1795 asm("mulhw %0,%1,%2" : "=r" (op->val) : 1796 "r" (regs->gpr[ra]), "r" (regs->gpr[rb])); 1797 goto arith_done; 1798 1799 case 104: /* neg */ 1800 op->val = -regs->gpr[ra]; 1801 goto arith_done; 1802 1803 case 136: /* subfe */ 1804 add_with_carry(regs, op, rd, ~regs->gpr[ra], 1805 regs->gpr[rb], regs->xer & XER_CA); 1806 goto arith_done; 1807 1808 case 138: /* adde */ 1809 add_with_carry(regs, op, rd, regs->gpr[ra], 1810 regs->gpr[rb], regs->xer & XER_CA); 1811 goto arith_done; 1812 1813 case 200: /* subfze */ 1814 add_with_carry(regs, op, rd, ~regs->gpr[ra], 0L, 1815 regs->xer & XER_CA); 1816 goto arith_done; 1817 1818 case 202: /* addze */ 1819 add_with_carry(regs, op, rd, regs->gpr[ra], 0L, 1820 regs->xer & XER_CA); 1821 goto arith_done; 1822 1823 case 232: /* subfme */ 1824 add_with_carry(regs, op, rd, ~regs->gpr[ra], -1L, 1825 regs->xer & XER_CA); 1826 goto arith_done; 1827#ifdef __powerpc64__ 1828 case 233: /* mulld */ 1829 op->val = regs->gpr[ra] * regs->gpr[rb]; 1830 goto arith_done; 1831#endif 1832 case 234: /* addme */ 1833 add_with_carry(regs, op, rd, regs->gpr[ra], -1L, 1834 regs->xer & XER_CA); 1835 goto arith_done; 1836 1837 case 235: /* mullw */ 1838 op->val = (long)(int) regs->gpr[ra] * 1839 (int) regs->gpr[rb]; 1840 1841 goto arith_done; 1842#ifdef __powerpc64__ 1843 case 265: /* modud */ 1844 if (!cpu_has_feature(CPU_FTR_ARCH_300)) 1845 return -1; 1846 op->val = regs->gpr[ra] % regs->gpr[rb]; 1847 goto compute_done; 1848#endif 1849 case 266: /* add */ 1850 op->val = regs->gpr[ra] + regs->gpr[rb]; 1851 goto arith_done; 1852 1853 case 267: /* moduw */ 1854 if (!cpu_has_feature(CPU_FTR_ARCH_300)) 1855 return -1; 1856 op->val = (unsigned int) regs->gpr[ra] % 1857 (unsigned int) regs->gpr[rb]; 1858 goto compute_done; 1859#ifdef __powerpc64__ 1860 case 457: /* divdu */ 1861 op->val = regs->gpr[ra] / regs->gpr[rb]; 1862 goto arith_done; 1863#endif 1864 case 459: /* divwu */ 1865 op->val = (unsigned int) regs->gpr[ra] / 1866 (unsigned int) regs->gpr[rb]; 1867 goto arith_done; 1868#ifdef __powerpc64__ 1869 case 489: /* divd */ 1870 op->val = (long int) regs->gpr[ra] / 1871 (long int) regs->gpr[rb]; 1872 goto arith_done; 1873#endif 1874 case 491: /* divw */ 1875 op->val = (int) regs->gpr[ra] / 1876 (int) regs->gpr[rb]; 1877 goto arith_done; 1878#ifdef __powerpc64__ 1879 case 425: /* divde[.] */ 1880 asm volatile(PPC_DIVDE(%0, %1, %2) : 1881 "=r" (op->val) : "r" (regs->gpr[ra]), 1882 "r" (regs->gpr[rb])); 1883 goto arith_done; 1884 case 393: /* divdeu[.] */ 1885 asm volatile(PPC_DIVDEU(%0, %1, %2) : 1886 "=r" (op->val) : "r" (regs->gpr[ra]), 1887 "r" (regs->gpr[rb])); 1888 goto arith_done; 1889#endif 1890 case 755: /* darn */ 1891 if (!cpu_has_feature(CPU_FTR_ARCH_300)) 1892 return -1; 1893 switch (ra & 0x3) { 1894 case 0: 1895 /* 32-bit conditioned */ 1896 asm volatile(PPC_DARN(%0, 0) : "=r" (op->val)); 1897 goto compute_done; 1898 1899 case 1: 1900 /* 64-bit conditioned */ 1901 asm volatile(PPC_DARN(%0, 1) : "=r" (op->val)); 1902 goto compute_done; 1903 1904 case 2: 1905 /* 64-bit raw */ 1906 asm volatile(PPC_DARN(%0, 2) : "=r" (op->val)); 1907 goto compute_done; 1908 } 1909 1910 return -1; 1911#ifdef __powerpc64__ 1912 case 777: /* modsd */ 1913 if (!cpu_has_feature(CPU_FTR_ARCH_300)) 1914 return -1; 1915 op->val = (long int) regs->gpr[ra] % 1916 (long int) regs->gpr[rb]; 1917 goto compute_done; 1918#endif 1919 case 779: /* modsw */ 1920 if (!cpu_has_feature(CPU_FTR_ARCH_300)) 1921 return -1; 1922 op->val = (int) regs->gpr[ra] % 1923 (int) regs->gpr[rb]; 1924 goto compute_done; 1925 1926 1927/* 1928 * Logical instructions 1929 */ 1930 case 26: /* cntlzw */ 1931 val = (unsigned int) regs->gpr[rd]; 1932 op->val = ( val ? __builtin_clz(val) : 32 ); 1933 goto logical_done; 1934#ifdef __powerpc64__ 1935 case 58: /* cntlzd */ 1936 val = regs->gpr[rd]; 1937 op->val = ( val ? __builtin_clzl(val) : 64 ); 1938 goto logical_done; 1939#endif 1940 case 28: /* and */ 1941 op->val = regs->gpr[rd] & regs->gpr[rb]; 1942 goto logical_done; 1943 1944 case 60: /* andc */ 1945 op->val = regs->gpr[rd] & ~regs->gpr[rb]; 1946 goto logical_done; 1947 1948 case 122: /* popcntb */ 1949 do_popcnt(regs, op, regs->gpr[rd], 8); 1950 goto logical_done_nocc; 1951 1952 case 124: /* nor */ 1953 op->val = ~(regs->gpr[rd] | regs->gpr[rb]); 1954 goto logical_done; 1955 1956 case 154: /* prtyw */ 1957 do_prty(regs, op, regs->gpr[rd], 32); 1958 goto logical_done_nocc; 1959 1960 case 186: /* prtyd */ 1961 do_prty(regs, op, regs->gpr[rd], 64); 1962 goto logical_done_nocc; 1963#ifdef CONFIG_PPC64 1964 case 252: /* bpermd */ 1965 do_bpermd(regs, op, regs->gpr[rd], regs->gpr[rb]); 1966 goto logical_done_nocc; 1967#endif 1968 case 284: /* xor */ 1969 op->val = ~(regs->gpr[rd] ^ regs->gpr[rb]); 1970 goto logical_done; 1971 1972 case 316: /* xor */ 1973 op->val = regs->gpr[rd] ^ regs->gpr[rb]; 1974 goto logical_done; 1975 1976 case 378: /* popcntw */ 1977 do_popcnt(regs, op, regs->gpr[rd], 32); 1978 goto logical_done_nocc; 1979 1980 case 412: /* orc */ 1981 op->val = regs->gpr[rd] | ~regs->gpr[rb]; 1982 goto logical_done; 1983 1984 case 444: /* or */ 1985 op->val = regs->gpr[rd] | regs->gpr[rb]; 1986 goto logical_done; 1987 1988 case 476: /* nand */ 1989 op->val = ~(regs->gpr[rd] & regs->gpr[rb]); 1990 goto logical_done; 1991#ifdef CONFIG_PPC64 1992 case 506: /* popcntd */ 1993 do_popcnt(regs, op, regs->gpr[rd], 64); 1994 goto logical_done_nocc; 1995#endif 1996 case 538: /* cnttzw */ 1997 if (!cpu_has_feature(CPU_FTR_ARCH_300)) 1998 return -1; 1999 val = (unsigned int) regs->gpr[rd]; 2000 op->val = (val ? __builtin_ctz(val) : 32); 2001 goto logical_done; 2002#ifdef __powerpc64__ 2003 case 570: /* cnttzd */ 2004 if (!cpu_has_feature(CPU_FTR_ARCH_300)) 2005 return -1; 2006 val = regs->gpr[rd]; 2007 op->val = (val ? __builtin_ctzl(val) : 64); 2008 goto logical_done; 2009#endif 2010 case 922: /* extsh */ 2011 op->val = (signed short) regs->gpr[rd]; 2012 goto logical_done; 2013 2014 case 954: /* extsb */ 2015 op->val = (signed char) regs->gpr[rd]; 2016 goto logical_done; 2017#ifdef __powerpc64__ 2018 case 986: /* extsw */ 2019 op->val = (signed int) regs->gpr[rd]; 2020 goto logical_done; 2021#endif 2022 2023/* 2024 * Shift instructions 2025 */ 2026 case 24: /* slw */ 2027 sh = regs->gpr[rb] & 0x3f; 2028 if (sh < 32) 2029 op->val = (regs->gpr[rd] << sh) & 0xffffffffUL; 2030 else 2031 op->val = 0; 2032 goto logical_done; 2033 2034 case 536: /* srw */ 2035 sh = regs->gpr[rb] & 0x3f; 2036 if (sh < 32) 2037 op->val = (regs->gpr[rd] & 0xffffffffUL) >> sh; 2038 else 2039 op->val = 0; 2040 goto logical_done; 2041 2042 case 792: /* sraw */ 2043 op->type = COMPUTE + SETREG + SETXER; 2044 sh = regs->gpr[rb] & 0x3f; 2045 ival = (signed int) regs->gpr[rd]; 2046 op->val = ival >> (sh < 32 ? sh : 31); 2047 op->xerval = regs->xer; 2048 if (ival < 0 && (sh >= 32 || (ival & ((1ul << sh) - 1)) != 0)) 2049 op->xerval |= XER_CA; 2050 else 2051 op->xerval &= ~XER_CA; 2052 set_ca32(op, op->xerval & XER_CA); 2053 goto logical_done; 2054 2055 case 824: /* srawi */ 2056 op->type = COMPUTE + SETREG + SETXER; 2057 sh = rb; 2058 ival = (signed int) regs->gpr[rd]; 2059 op->val = ival >> sh; 2060 op->xerval = regs->xer; 2061 if (ival < 0 && (ival & ((1ul << sh) - 1)) != 0) 2062 op->xerval |= XER_CA; 2063 else 2064 op->xerval &= ~XER_CA; 2065 set_ca32(op, op->xerval & XER_CA); 2066 goto logical_done; 2067 2068#ifdef __powerpc64__ 2069 case 27: /* sld */ 2070 sh = regs->gpr[rb] & 0x7f; 2071 if (sh < 64) 2072 op->val = regs->gpr[rd] << sh; 2073 else 2074 op->val = 0; 2075 goto logical_done; 2076 2077 case 539: /* srd */ 2078 sh = regs->gpr[rb] & 0x7f; 2079 if (sh < 64) 2080 op->val = regs->gpr[rd] >> sh; 2081 else 2082 op->val = 0; 2083 goto logical_done; 2084 2085 case 794: /* srad */ 2086 op->type = COMPUTE + SETREG + SETXER; 2087 sh = regs->gpr[rb] & 0x7f; 2088 ival = (signed long int) regs->gpr[rd]; 2089 op->val = ival >> (sh < 64 ? sh : 63); 2090 op->xerval = regs->xer; 2091 if (ival < 0 && (sh >= 64 || (ival & ((1ul << sh) - 1)) != 0)) 2092 op->xerval |= XER_CA; 2093 else 2094 op->xerval &= ~XER_CA; 2095 set_ca32(op, op->xerval & XER_CA); 2096 goto logical_done; 2097 2098 case 826: /* sradi with sh_5 = 0 */ 2099 case 827: /* sradi with sh_5 = 1 */ 2100 op->type = COMPUTE + SETREG + SETXER; 2101 sh = rb | ((word & 2) << 4); 2102 ival = (signed long int) regs->gpr[rd]; 2103 op->val = ival >> sh; 2104 op->xerval = regs->xer; 2105 if (ival < 0 && (ival & ((1ul << sh) - 1)) != 0) 2106 op->xerval |= XER_CA; 2107 else 2108 op->xerval &= ~XER_CA; 2109 set_ca32(op, op->xerval & XER_CA); 2110 goto logical_done; 2111 2112 case 890: /* extswsli with sh_5 = 0 */ 2113 case 891: /* extswsli with sh_5 = 1 */ 2114 if (!cpu_has_feature(CPU_FTR_ARCH_300)) 2115 return -1; 2116 op->type = COMPUTE + SETREG; 2117 sh = rb | ((word & 2) << 4); 2118 val = (signed int) regs->gpr[rd]; 2119 if (sh) 2120 op->val = ROTATE(val, sh) & MASK64(0, 63 - sh); 2121 else 2122 op->val = val; 2123 goto logical_done; 2124 2125#endif /* __powerpc64__ */ 2126 2127/* 2128 * Cache instructions 2129 */ 2130 case 54: /* dcbst */ 2131 op->type = MKOP(CACHEOP, DCBST, 0); 2132 op->ea = xform_ea(word, regs); 2133 return 0; 2134 2135 case 86: /* dcbf */ 2136 op->type = MKOP(CACHEOP, DCBF, 0); 2137 op->ea = xform_ea(word, regs); 2138 return 0; 2139 2140 case 246: /* dcbtst */ 2141 op->type = MKOP(CACHEOP, DCBTST, 0); 2142 op->ea = xform_ea(word, regs); 2143 op->reg = rd; 2144 return 0; 2145 2146 case 278: /* dcbt */ 2147 op->type = MKOP(CACHEOP, DCBTST, 0); 2148 op->ea = xform_ea(word, regs); 2149 op->reg = rd; 2150 return 0; 2151 2152 case 982: /* icbi */ 2153 op->type = MKOP(CACHEOP, ICBI, 0); 2154 op->ea = xform_ea(word, regs); 2155 return 0; 2156 2157 case 1014: /* dcbz */ 2158 op->type = MKOP(CACHEOP, DCBZ, 0); 2159 op->ea = xform_ea(word, regs); 2160 return 0; 2161 } 2162 break; 2163 } 2164 2165/* 2166 * Loads and stores. 2167 */ 2168 op->type = UNKNOWN; 2169 op->update_reg = ra; 2170 op->reg = rd; 2171 op->val = regs->gpr[rd]; 2172 u = (word >> 20) & UPDATE; 2173 op->vsx_flags = 0; 2174 2175 switch (opcode) { 2176 case 31: 2177 u = word & UPDATE; 2178 op->ea = xform_ea(word, regs); 2179 switch ((word >> 1) & 0x3ff) { 2180 case 20: /* lwarx */ 2181 op->type = MKOP(LARX, 0, 4); 2182 break; 2183 2184 case 150: /* stwcx. */ 2185 op->type = MKOP(STCX, 0, 4); 2186 break; 2187 2188#ifdef __powerpc64__ 2189 case 84: /* ldarx */ 2190 op->type = MKOP(LARX, 0, 8); 2191 break; 2192 2193 case 214: /* stdcx. */ 2194 op->type = MKOP(STCX, 0, 8); 2195 break; 2196 2197 case 52: /* lbarx */ 2198 op->type = MKOP(LARX, 0, 1); 2199 break; 2200 2201 case 694: /* stbcx. */ 2202 op->type = MKOP(STCX, 0, 1); 2203 break; 2204 2205 case 116: /* lharx */ 2206 op->type = MKOP(LARX, 0, 2); 2207 break; 2208 2209 case 726: /* sthcx. */ 2210 op->type = MKOP(STCX, 0, 2); 2211 break; 2212 2213 case 276: /* lqarx */ 2214 if (!((rd & 1) || rd == ra || rd == rb)) 2215 op->type = MKOP(LARX, 0, 16); 2216 break; 2217 2218 case 182: /* stqcx. */ 2219 if (!(rd & 1)) 2220 op->type = MKOP(STCX, 0, 16); 2221 break; 2222#endif 2223 2224 case 23: /* lwzx */ 2225 case 55: /* lwzux */ 2226 op->type = MKOP(LOAD, u, 4); 2227 break; 2228 2229 case 87: /* lbzx */ 2230 case 119: /* lbzux */ 2231 op->type = MKOP(LOAD, u, 1); 2232 break; 2233 2234#ifdef CONFIG_ALTIVEC 2235 /* 2236 * Note: for the load/store vector element instructions, 2237 * bits of the EA say which field of the VMX register to use. 2238 */ 2239 case 7: /* lvebx */ 2240 op->type = MKOP(LOAD_VMX, 0, 1); 2241 op->element_size = 1; 2242 break; 2243 2244 case 39: /* lvehx */ 2245 op->type = MKOP(LOAD_VMX, 0, 2); 2246 op->element_size = 2; 2247 break; 2248 2249 case 71: /* lvewx */ 2250 op->type = MKOP(LOAD_VMX, 0, 4); 2251 op->element_size = 4; 2252 break; 2253 2254 case 103: /* lvx */ 2255 case 359: /* lvxl */ 2256 op->type = MKOP(LOAD_VMX, 0, 16); 2257 op->element_size = 16; 2258 break; 2259 2260 case 135: /* stvebx */ 2261 op->type = MKOP(STORE_VMX, 0, 1); 2262 op->element_size = 1; 2263 break; 2264 2265 case 167: /* stvehx */ 2266 op->type = MKOP(STORE_VMX, 0, 2); 2267 op->element_size = 2; 2268 break; 2269 2270 case 199: /* stvewx */ 2271 op->type = MKOP(STORE_VMX, 0, 4); 2272 op->element_size = 4; 2273 break; 2274 2275 case 231: /* stvx */ 2276 case 487: /* stvxl */ 2277 op->type = MKOP(STORE_VMX, 0, 16); 2278 break; 2279#endif /* CONFIG_ALTIVEC */ 2280 2281#ifdef __powerpc64__ 2282 case 21: /* ldx */ 2283 case 53: /* ldux */ 2284 op->type = MKOP(LOAD, u, 8); 2285 break; 2286 2287 case 149: /* stdx */ 2288 case 181: /* stdux */ 2289 op->type = MKOP(STORE, u, 8); 2290 break; 2291#endif 2292 2293 case 151: /* stwx */ 2294 case 183: /* stwux */ 2295 op->type = MKOP(STORE, u, 4); 2296 break; 2297 2298 case 215: /* stbx */ 2299 case 247: /* stbux */ 2300 op->type = MKOP(STORE, u, 1); 2301 break; 2302 2303 case 279: /* lhzx */ 2304 case 311: /* lhzux */ 2305 op->type = MKOP(LOAD, u, 2); 2306 break; 2307 2308#ifdef __powerpc64__ 2309 case 341: /* lwax */ 2310 case 373: /* lwaux */ 2311 op->type = MKOP(LOAD, SIGNEXT | u, 4); 2312 break; 2313#endif 2314 2315 case 343: /* lhax */ 2316 case 375: /* lhaux */ 2317 op->type = MKOP(LOAD, SIGNEXT | u, 2); 2318 break; 2319 2320 case 407: /* sthx */ 2321 case 439: /* sthux */ 2322 op->type = MKOP(STORE, u, 2); 2323 break; 2324 2325#ifdef __powerpc64__ 2326 case 532: /* ldbrx */ 2327 op->type = MKOP(LOAD, BYTEREV, 8); 2328 break; 2329 2330#endif 2331 case 533: /* lswx */ 2332 op->type = MKOP(LOAD_MULTI, 0, regs->xer & 0x7f); 2333 break; 2334 2335 case 534: /* lwbrx */ 2336 op->type = MKOP(LOAD, BYTEREV, 4); 2337 break; 2338 2339 case 597: /* lswi */ 2340 if (rb == 0) 2341 rb = 32; /* # bytes to load */ 2342 op->type = MKOP(LOAD_MULTI, 0, rb); 2343 op->ea = ra ? regs->gpr[ra] : 0; 2344 break; 2345 2346#ifdef CONFIG_PPC_FPU 2347 case 535: /* lfsx */ 2348 case 567: /* lfsux */ 2349 op->type = MKOP(LOAD_FP, u | FPCONV, 4); 2350 break; 2351 2352 case 599: /* lfdx */ 2353 case 631: /* lfdux */ 2354 op->type = MKOP(LOAD_FP, u, 8); 2355 break; 2356 2357 case 663: /* stfsx */ 2358 case 695: /* stfsux */ 2359 op->type = MKOP(STORE_FP, u | FPCONV, 4); 2360 break; 2361 2362 case 727: /* stfdx */ 2363 case 759: /* stfdux */ 2364 op->type = MKOP(STORE_FP, u, 8); 2365 break; 2366 2367#ifdef __powerpc64__ 2368 case 791: /* lfdpx */ 2369 op->type = MKOP(LOAD_FP, 0, 16); 2370 break; 2371 2372 case 855: /* lfiwax */ 2373 op->type = MKOP(LOAD_FP, SIGNEXT, 4); 2374 break; 2375 2376 case 887: /* lfiwzx */ 2377 op->type = MKOP(LOAD_FP, 0, 4); 2378 break; 2379 2380 case 919: /* stfdpx */ 2381 op->type = MKOP(STORE_FP, 0, 16); 2382 break; 2383 2384 case 983: /* stfiwx */ 2385 op->type = MKOP(STORE_FP, 0, 4); 2386 break; 2387#endif /* __powerpc64 */ 2388#endif /* CONFIG_PPC_FPU */ 2389 2390#ifdef __powerpc64__ 2391 case 660: /* stdbrx */ 2392 op->type = MKOP(STORE, BYTEREV, 8); 2393 op->val = byterev_8(regs->gpr[rd]); 2394 break; 2395 2396#endif 2397 case 661: /* stswx */ 2398 op->type = MKOP(STORE_MULTI, 0, regs->xer & 0x7f); 2399 break; 2400 2401 case 662: /* stwbrx */ 2402 op->type = MKOP(STORE, BYTEREV, 4); 2403 op->val = byterev_4(regs->gpr[rd]); 2404 break; 2405 2406 case 725: /* stswi */ 2407 if (rb == 0) 2408 rb = 32; /* # bytes to store */ 2409 op->type = MKOP(STORE_MULTI, 0, rb); 2410 op->ea = ra ? regs->gpr[ra] : 0; 2411 break; 2412 2413 case 790: /* lhbrx */ 2414 op->type = MKOP(LOAD, BYTEREV, 2); 2415 break; 2416 2417 case 918: /* sthbrx */ 2418 op->type = MKOP(STORE, BYTEREV, 2); 2419 op->val = byterev_2(regs->gpr[rd]); 2420 break; 2421 2422#ifdef CONFIG_VSX 2423 case 12: /* lxsiwzx */ 2424 op->reg = rd | ((word & 1) << 5); 2425 op->type = MKOP(LOAD_VSX, 0, 4); 2426 op->element_size = 8; 2427 break; 2428 2429 case 76: /* lxsiwax */ 2430 op->reg = rd | ((word & 1) << 5); 2431 op->type = MKOP(LOAD_VSX, SIGNEXT, 4); 2432 op->element_size = 8; 2433 break; 2434 2435 case 140: /* stxsiwx */ 2436 op->reg = rd | ((word & 1) << 5); 2437 op->type = MKOP(STORE_VSX, 0, 4); 2438 op->element_size = 8; 2439 break; 2440 2441 case 268: /* lxvx */ 2442 op->reg = rd | ((word & 1) << 5); 2443 op->type = MKOP(LOAD_VSX, 0, 16); 2444 op->element_size = 16; 2445 op->vsx_flags = VSX_CHECK_VEC; 2446 break; 2447 2448 case 269: /* lxvl */ 2449 case 301: { /* lxvll */ 2450 int nb; 2451 op->reg = rd | ((word & 1) << 5); 2452 op->ea = ra ? regs->gpr[ra] : 0; 2453 nb = regs->gpr[rb] & 0xff; 2454 if (nb > 16) 2455 nb = 16; 2456 op->type = MKOP(LOAD_VSX, 0, nb); 2457 op->element_size = 16; 2458 op->vsx_flags = ((word & 0x20) ? VSX_LDLEFT : 0) | 2459 VSX_CHECK_VEC; 2460 break; 2461 } 2462 case 332: /* lxvdsx */ 2463 op->reg = rd | ((word & 1) << 5); 2464 op->type = MKOP(LOAD_VSX, 0, 8); 2465 op->element_size = 8; 2466 op->vsx_flags = VSX_SPLAT; 2467 break; 2468 2469 case 333: /* lxvpx */ 2470 if (!cpu_has_feature(CPU_FTR_ARCH_31)) 2471 return -1; 2472 op->reg = VSX_REGISTER_XTP(rd); 2473 op->type = MKOP(LOAD_VSX, 0, 32); 2474 op->element_size = 32; 2475 break; 2476 2477 case 364: /* lxvwsx */ 2478 op->reg = rd | ((word & 1) << 5); 2479 op->type = MKOP(LOAD_VSX, 0, 4); 2480 op->element_size = 4; 2481 op->vsx_flags = VSX_SPLAT | VSX_CHECK_VEC; 2482 break; 2483 2484 case 396: /* stxvx */ 2485 op->reg = rd | ((word & 1) << 5); 2486 op->type = MKOP(STORE_VSX, 0, 16); 2487 op->element_size = 16; 2488 op->vsx_flags = VSX_CHECK_VEC; 2489 break; 2490 2491 case 397: /* stxvl */ 2492 case 429: { /* stxvll */ 2493 int nb; 2494 op->reg = rd | ((word & 1) << 5); 2495 op->ea = ra ? regs->gpr[ra] : 0; 2496 nb = regs->gpr[rb] & 0xff; 2497 if (nb > 16) 2498 nb = 16; 2499 op->type = MKOP(STORE_VSX, 0, nb); 2500 op->element_size = 16; 2501 op->vsx_flags = ((word & 0x20) ? VSX_LDLEFT : 0) | 2502 VSX_CHECK_VEC; 2503 break; 2504 } 2505 case 461: /* stxvpx */ 2506 if (!cpu_has_feature(CPU_FTR_ARCH_31)) 2507 return -1; 2508 op->reg = VSX_REGISTER_XTP(rd); 2509 op->type = MKOP(STORE_VSX, 0, 32); 2510 op->element_size = 32; 2511 break; 2512 case 524: /* lxsspx */ 2513 op->reg = rd | ((word & 1) << 5); 2514 op->type = MKOP(LOAD_VSX, 0, 4); 2515 op->element_size = 8; 2516 op->vsx_flags = VSX_FPCONV; 2517 break; 2518 2519 case 588: /* lxsdx */ 2520 op->reg = rd | ((word & 1) << 5); 2521 op->type = MKOP(LOAD_VSX, 0, 8); 2522 op->element_size = 8; 2523 break; 2524 2525 case 652: /* stxsspx */ 2526 op->reg = rd | ((word & 1) << 5); 2527 op->type = MKOP(STORE_VSX, 0, 4); 2528 op->element_size = 8; 2529 op->vsx_flags = VSX_FPCONV; 2530 break; 2531 2532 case 716: /* stxsdx */ 2533 op->reg = rd | ((word & 1) << 5); 2534 op->type = MKOP(STORE_VSX, 0, 8); 2535 op->element_size = 8; 2536 break; 2537 2538 case 780: /* lxvw4x */ 2539 op->reg = rd | ((word & 1) << 5); 2540 op->type = MKOP(LOAD_VSX, 0, 16); 2541 op->element_size = 4; 2542 break; 2543 2544 case 781: /* lxsibzx */ 2545 op->reg = rd | ((word & 1) << 5); 2546 op->type = MKOP(LOAD_VSX, 0, 1); 2547 op->element_size = 8; 2548 op->vsx_flags = VSX_CHECK_VEC; 2549 break; 2550 2551 case 812: /* lxvh8x */ 2552 op->reg = rd | ((word & 1) << 5); 2553 op->type = MKOP(LOAD_VSX, 0, 16); 2554 op->element_size = 2; 2555 op->vsx_flags = VSX_CHECK_VEC; 2556 break; 2557 2558 case 813: /* lxsihzx */ 2559 op->reg = rd | ((word & 1) << 5); 2560 op->type = MKOP(LOAD_VSX, 0, 2); 2561 op->element_size = 8; 2562 op->vsx_flags = VSX_CHECK_VEC; 2563 break; 2564 2565 case 844: /* lxvd2x */ 2566 op->reg = rd | ((word & 1) << 5); 2567 op->type = MKOP(LOAD_VSX, 0, 16); 2568 op->element_size = 8; 2569 break; 2570 2571 case 876: /* lxvb16x */ 2572 op->reg = rd | ((word & 1) << 5); 2573 op->type = MKOP(LOAD_VSX, 0, 16); 2574 op->element_size = 1; 2575 op->vsx_flags = VSX_CHECK_VEC; 2576 break; 2577 2578 case 908: /* stxvw4x */ 2579 op->reg = rd | ((word & 1) << 5); 2580 op->type = MKOP(STORE_VSX, 0, 16); 2581 op->element_size = 4; 2582 break; 2583 2584 case 909: /* stxsibx */ 2585 op->reg = rd | ((word & 1) << 5); 2586 op->type = MKOP(STORE_VSX, 0, 1); 2587 op->element_size = 8; 2588 op->vsx_flags = VSX_CHECK_VEC; 2589 break; 2590 2591 case 940: /* stxvh8x */ 2592 op->reg = rd | ((word & 1) << 5); 2593 op->type = MKOP(STORE_VSX, 0, 16); 2594 op->element_size = 2; 2595 op->vsx_flags = VSX_CHECK_VEC; 2596 break; 2597 2598 case 941: /* stxsihx */ 2599 op->reg = rd | ((word & 1) << 5); 2600 op->type = MKOP(STORE_VSX, 0, 2); 2601 op->element_size = 8; 2602 op->vsx_flags = VSX_CHECK_VEC; 2603 break; 2604 2605 case 972: /* stxvd2x */ 2606 op->reg = rd | ((word & 1) << 5); 2607 op->type = MKOP(STORE_VSX, 0, 16); 2608 op->element_size = 8; 2609 break; 2610 2611 case 1004: /* stxvb16x */ 2612 op->reg = rd | ((word & 1) << 5); 2613 op->type = MKOP(STORE_VSX, 0, 16); 2614 op->element_size = 1; 2615 op->vsx_flags = VSX_CHECK_VEC; 2616 break; 2617 2618#endif /* CONFIG_VSX */ 2619 } 2620 break; 2621 2622 case 32: /* lwz */ 2623 case 33: /* lwzu */ 2624 op->type = MKOP(LOAD, u, 4); 2625 op->ea = dform_ea(word, regs); 2626 break; 2627 2628 case 34: /* lbz */ 2629 case 35: /* lbzu */ 2630 op->type = MKOP(LOAD, u, 1); 2631 op->ea = dform_ea(word, regs); 2632 break; 2633 2634 case 36: /* stw */ 2635 case 37: /* stwu */ 2636 op->type = MKOP(STORE, u, 4); 2637 op->ea = dform_ea(word, regs); 2638 break; 2639 2640 case 38: /* stb */ 2641 case 39: /* stbu */ 2642 op->type = MKOP(STORE, u, 1); 2643 op->ea = dform_ea(word, regs); 2644 break; 2645 2646 case 40: /* lhz */ 2647 case 41: /* lhzu */ 2648 op->type = MKOP(LOAD, u, 2); 2649 op->ea = dform_ea(word, regs); 2650 break; 2651 2652 case 42: /* lha */ 2653 case 43: /* lhau */ 2654 op->type = MKOP(LOAD, SIGNEXT | u, 2); 2655 op->ea = dform_ea(word, regs); 2656 break; 2657 2658 case 44: /* sth */ 2659 case 45: /* sthu */ 2660 op->type = MKOP(STORE, u, 2); 2661 op->ea = dform_ea(word, regs); 2662 break; 2663 2664 case 46: /* lmw */ 2665 if (ra >= rd) 2666 break; /* invalid form, ra in range to load */ 2667 op->type = MKOP(LOAD_MULTI, 0, 4 * (32 - rd)); 2668 op->ea = dform_ea(word, regs); 2669 break; 2670 2671 case 47: /* stmw */ 2672 op->type = MKOP(STORE_MULTI, 0, 4 * (32 - rd)); 2673 op->ea = dform_ea(word, regs); 2674 break; 2675 2676#ifdef CONFIG_PPC_FPU 2677 case 48: /* lfs */ 2678 case 49: /* lfsu */ 2679 op->type = MKOP(LOAD_FP, u | FPCONV, 4); 2680 op->ea = dform_ea(word, regs); 2681 break; 2682 2683 case 50: /* lfd */ 2684 case 51: /* lfdu */ 2685 op->type = MKOP(LOAD_FP, u, 8); 2686 op->ea = dform_ea(word, regs); 2687 break; 2688 2689 case 52: /* stfs */ 2690 case 53: /* stfsu */ 2691 op->type = MKOP(STORE_FP, u | FPCONV, 4); 2692 op->ea = dform_ea(word, regs); 2693 break; 2694 2695 case 54: /* stfd */ 2696 case 55: /* stfdu */ 2697 op->type = MKOP(STORE_FP, u, 8); 2698 op->ea = dform_ea(word, regs); 2699 break; 2700#endif 2701 2702#ifdef __powerpc64__ 2703 case 56: /* lq */ 2704 if (!((rd & 1) || (rd == ra))) 2705 op->type = MKOP(LOAD, 0, 16); 2706 op->ea = dqform_ea(word, regs); 2707 break; 2708#endif 2709 2710#ifdef CONFIG_VSX 2711 case 57: /* lfdp, lxsd, lxssp */ 2712 op->ea = dsform_ea(word, regs); 2713 switch (word & 3) { 2714 case 0: /* lfdp */ 2715 if (rd & 1) 2716 break; /* reg must be even */ 2717 op->type = MKOP(LOAD_FP, 0, 16); 2718 break; 2719 case 2: /* lxsd */ 2720 op->reg = rd + 32; 2721 op->type = MKOP(LOAD_VSX, 0, 8); 2722 op->element_size = 8; 2723 op->vsx_flags = VSX_CHECK_VEC; 2724 break; 2725 case 3: /* lxssp */ 2726 op->reg = rd + 32; 2727 op->type = MKOP(LOAD_VSX, 0, 4); 2728 op->element_size = 8; 2729 op->vsx_flags = VSX_FPCONV | VSX_CHECK_VEC; 2730 break; 2731 } 2732 break; 2733#endif /* CONFIG_VSX */ 2734 2735#ifdef __powerpc64__ 2736 case 58: /* ld[u], lwa */ 2737 op->ea = dsform_ea(word, regs); 2738 switch (word & 3) { 2739 case 0: /* ld */ 2740 op->type = MKOP(LOAD, 0, 8); 2741 break; 2742 case 1: /* ldu */ 2743 op->type = MKOP(LOAD, UPDATE, 8); 2744 break; 2745 case 2: /* lwa */ 2746 op->type = MKOP(LOAD, SIGNEXT, 4); 2747 break; 2748 } 2749 break; 2750#endif 2751 2752#ifdef CONFIG_VSX 2753 case 6: 2754 if (!cpu_has_feature(CPU_FTR_ARCH_31)) 2755 return -1; 2756 op->ea = dqform_ea(word, regs); 2757 op->reg = VSX_REGISTER_XTP(rd); 2758 op->element_size = 32; 2759 switch (word & 0xf) { 2760 case 0: /* lxvp */ 2761 op->type = MKOP(LOAD_VSX, 0, 32); 2762 break; 2763 case 1: /* stxvp */ 2764 op->type = MKOP(STORE_VSX, 0, 32); 2765 break; 2766 } 2767 break; 2768 2769 case 61: /* stfdp, lxv, stxsd, stxssp, stxv */ 2770 switch (word & 7) { 2771 case 0: /* stfdp with LSB of DS field = 0 */ 2772 case 4: /* stfdp with LSB of DS field = 1 */ 2773 op->ea = dsform_ea(word, regs); 2774 op->type = MKOP(STORE_FP, 0, 16); 2775 break; 2776 2777 case 1: /* lxv */ 2778 op->ea = dqform_ea(word, regs); 2779 if (word & 8) 2780 op->reg = rd + 32; 2781 op->type = MKOP(LOAD_VSX, 0, 16); 2782 op->element_size = 16; 2783 op->vsx_flags = VSX_CHECK_VEC; 2784 break; 2785 2786 case 2: /* stxsd with LSB of DS field = 0 */ 2787 case 6: /* stxsd with LSB of DS field = 1 */ 2788 op->ea = dsform_ea(word, regs); 2789 op->reg = rd + 32; 2790 op->type = MKOP(STORE_VSX, 0, 8); 2791 op->element_size = 8; 2792 op->vsx_flags = VSX_CHECK_VEC; 2793 break; 2794 2795 case 3: /* stxssp with LSB of DS field = 0 */ 2796 case 7: /* stxssp with LSB of DS field = 1 */ 2797 op->ea = dsform_ea(word, regs); 2798 op->reg = rd + 32; 2799 op->type = MKOP(STORE_VSX, 0, 4); 2800 op->element_size = 8; 2801 op->vsx_flags = VSX_FPCONV | VSX_CHECK_VEC; 2802 break; 2803 2804 case 5: /* stxv */ 2805 op->ea = dqform_ea(word, regs); 2806 if (word & 8) 2807 op->reg = rd + 32; 2808 op->type = MKOP(STORE_VSX, 0, 16); 2809 op->element_size = 16; 2810 op->vsx_flags = VSX_CHECK_VEC; 2811 break; 2812 } 2813 break; 2814#endif /* CONFIG_VSX */ 2815 2816#ifdef __powerpc64__ 2817 case 62: /* std[u] */ 2818 op->ea = dsform_ea(word, regs); 2819 switch (word & 3) { 2820 case 0: /* std */ 2821 op->type = MKOP(STORE, 0, 8); 2822 break; 2823 case 1: /* stdu */ 2824 op->type = MKOP(STORE, UPDATE, 8); 2825 break; 2826 case 2: /* stq */ 2827 if (!(rd & 1)) 2828 op->type = MKOP(STORE, 0, 16); 2829 break; 2830 } 2831 break; 2832 case 1: /* Prefixed instructions */ 2833 if (!cpu_has_feature(CPU_FTR_ARCH_31)) 2834 return -1; 2835 2836 prefix_r = GET_PREFIX_R(word); 2837 ra = GET_PREFIX_RA(suffix); 2838 op->update_reg = ra; 2839 rd = (suffix >> 21) & 0x1f; 2840 op->reg = rd; 2841 op->val = regs->gpr[rd]; 2842 2843 suffixopcode = get_op(suffix); 2844 prefixtype = (word >> 24) & 0x3; 2845 switch (prefixtype) { 2846 case 0: /* Type 00 Eight-Byte Load/Store */ 2847 if (prefix_r && ra) 2848 break; 2849 op->ea = mlsd_8lsd_ea(word, suffix, regs); 2850 switch (suffixopcode) { 2851 case 41: /* plwa */ 2852 op->type = MKOP(LOAD, PREFIXED | SIGNEXT, 4); 2853 break; 2854#ifdef CONFIG_VSX 2855 case 42: /* plxsd */ 2856 op->reg = rd + 32; 2857 op->type = MKOP(LOAD_VSX, PREFIXED, 8); 2858 op->element_size = 8; 2859 op->vsx_flags = VSX_CHECK_VEC; 2860 break; 2861 case 43: /* plxssp */ 2862 op->reg = rd + 32; 2863 op->type = MKOP(LOAD_VSX, PREFIXED, 4); 2864 op->element_size = 8; 2865 op->vsx_flags = VSX_FPCONV | VSX_CHECK_VEC; 2866 break; 2867 case 46: /* pstxsd */ 2868 op->reg = rd + 32; 2869 op->type = MKOP(STORE_VSX, PREFIXED, 8); 2870 op->element_size = 8; 2871 op->vsx_flags = VSX_CHECK_VEC; 2872 break; 2873 case 47: /* pstxssp */ 2874 op->reg = rd + 32; 2875 op->type = MKOP(STORE_VSX, PREFIXED, 4); 2876 op->element_size = 8; 2877 op->vsx_flags = VSX_FPCONV | VSX_CHECK_VEC; 2878 break; 2879 case 51: /* plxv1 */ 2880 op->reg += 32; 2881 fallthrough; 2882 case 50: /* plxv0 */ 2883 op->type = MKOP(LOAD_VSX, PREFIXED, 16); 2884 op->element_size = 16; 2885 op->vsx_flags = VSX_CHECK_VEC; 2886 break; 2887 case 55: /* pstxv1 */ 2888 op->reg = rd + 32; 2889 fallthrough; 2890 case 54: /* pstxv0 */ 2891 op->type = MKOP(STORE_VSX, PREFIXED, 16); 2892 op->element_size = 16; 2893 op->vsx_flags = VSX_CHECK_VEC; 2894 break; 2895#endif /* CONFIG_VSX */ 2896 case 56: /* plq */ 2897 op->type = MKOP(LOAD, PREFIXED, 16); 2898 break; 2899 case 57: /* pld */ 2900 op->type = MKOP(LOAD, PREFIXED, 8); 2901 break; 2902#ifdef CONFIG_VSX 2903 case 58: /* plxvp */ 2904 op->reg = VSX_REGISTER_XTP(rd); 2905 op->type = MKOP(LOAD_VSX, PREFIXED, 32); 2906 op->element_size = 32; 2907 break; 2908#endif /* CONFIG_VSX */ 2909 case 60: /* pstq */ 2910 op->type = MKOP(STORE, PREFIXED, 16); 2911 break; 2912 case 61: /* pstd */ 2913 op->type = MKOP(STORE, PREFIXED, 8); 2914 break; 2915#ifdef CONFIG_VSX 2916 case 62: /* pstxvp */ 2917 op->reg = VSX_REGISTER_XTP(rd); 2918 op->type = MKOP(STORE_VSX, PREFIXED, 32); 2919 op->element_size = 32; 2920 break; 2921#endif /* CONFIG_VSX */ 2922 } 2923 break; 2924 case 1: /* Type 01 Eight-Byte Register-to-Register */ 2925 break; 2926 case 2: /* Type 10 Modified Load/Store */ 2927 if (prefix_r && ra) 2928 break; 2929 op->ea = mlsd_8lsd_ea(word, suffix, regs); 2930 switch (suffixopcode) { 2931 case 32: /* plwz */ 2932 op->type = MKOP(LOAD, PREFIXED, 4); 2933 break; 2934 case 34: /* plbz */ 2935 op->type = MKOP(LOAD, PREFIXED, 1); 2936 break; 2937 case 36: /* pstw */ 2938 op->type = MKOP(STORE, PREFIXED, 4); 2939 break; 2940 case 38: /* pstb */ 2941 op->type = MKOP(STORE, PREFIXED, 1); 2942 break; 2943 case 40: /* plhz */ 2944 op->type = MKOP(LOAD, PREFIXED, 2); 2945 break; 2946 case 42: /* plha */ 2947 op->type = MKOP(LOAD, PREFIXED | SIGNEXT, 2); 2948 break; 2949 case 44: /* psth */ 2950 op->type = MKOP(STORE, PREFIXED, 2); 2951 break; 2952 case 48: /* plfs */ 2953 op->type = MKOP(LOAD_FP, PREFIXED | FPCONV, 4); 2954 break; 2955 case 50: /* plfd */ 2956 op->type = MKOP(LOAD_FP, PREFIXED, 8); 2957 break; 2958 case 52: /* pstfs */ 2959 op->type = MKOP(STORE_FP, PREFIXED | FPCONV, 4); 2960 break; 2961 case 54: /* pstfd */ 2962 op->type = MKOP(STORE_FP, PREFIXED, 8); 2963 break; 2964 } 2965 break; 2966 case 3: /* Type 11 Modified Register-to-Register */ 2967 break; 2968 } 2969#endif /* __powerpc64__ */ 2970 2971 } 2972 2973#ifdef CONFIG_VSX 2974 if ((GETTYPE(op->type) == LOAD_VSX || 2975 GETTYPE(op->type) == STORE_VSX) && 2976 !cpu_has_feature(CPU_FTR_VSX)) { 2977 return -1; 2978 } 2979#endif /* CONFIG_VSX */ 2980 2981 return 0; 2982 2983 logical_done: 2984 if (word & 1) 2985 set_cr0(regs, op); 2986 logical_done_nocc: 2987 op->reg = ra; 2988 op->type |= SETREG; 2989 return 1; 2990 2991 arith_done: 2992 if (word & 1) 2993 set_cr0(regs, op); 2994 compute_done: 2995 op->reg = rd; 2996 op->type |= SETREG; 2997 return 1; 2998 2999 priv: 3000 op->type = INTERRUPT | 0x700; 3001 op->val = SRR1_PROGPRIV; 3002 return 0; 3003 3004 trap: 3005 op->type = INTERRUPT | 0x700; 3006 op->val = SRR1_PROGTRAP; 3007 return 0; 3008} 3009EXPORT_SYMBOL_GPL(analyse_instr); 3010NOKPROBE_SYMBOL(analyse_instr); 3011 3012/* 3013 * For PPC32 we always use stwu with r1 to change the stack pointer. 3014 * So this emulated store may corrupt the exception frame, now we 3015 * have to provide the exception frame trampoline, which is pushed 3016 * below the kprobed function stack. So we only update gpr[1] but 3017 * don't emulate the real store operation. We will do real store 3018 * operation safely in exception return code by checking this flag. 3019 */ 3020static nokprobe_inline int handle_stack_update(unsigned long ea, struct pt_regs *regs) 3021{ 3022#ifdef CONFIG_PPC32 3023 /* 3024 * Check if we will touch kernel stack overflow 3025 */ 3026 if (ea - STACK_INT_FRAME_SIZE <= current->thread.ksp_limit) { 3027 printk(KERN_CRIT "Can't kprobe this since kernel stack would overflow.\n"); 3028 return -EINVAL; 3029 } 3030#endif /* CONFIG_PPC32 */ 3031 /* 3032 * Check if we already set since that means we'll 3033 * lose the previous value. 3034 */ 3035 WARN_ON(test_thread_flag(TIF_EMULATE_STACK_STORE)); 3036 set_thread_flag(TIF_EMULATE_STACK_STORE); 3037 return 0; 3038} 3039 3040static nokprobe_inline void do_signext(unsigned long *valp, int size) 3041{ 3042 switch (size) { 3043 case 2: 3044 *valp = (signed short) *valp; 3045 break; 3046 case 4: 3047 *valp = (signed int) *valp; 3048 break; 3049 } 3050} 3051 3052static nokprobe_inline void do_byterev(unsigned long *valp, int size) 3053{ 3054 switch (size) { 3055 case 2: 3056 *valp = byterev_2(*valp); 3057 break; 3058 case 4: 3059 *valp = byterev_4(*valp); 3060 break; 3061#ifdef __powerpc64__ 3062 case 8: 3063 *valp = byterev_8(*valp); 3064 break; 3065#endif 3066 } 3067} 3068 3069/* 3070 * Emulate an instruction that can be executed just by updating 3071 * fields in *regs. 3072 */ 3073void emulate_update_regs(struct pt_regs *regs, struct instruction_op *op) 3074{ 3075 unsigned long next_pc; 3076 3077 next_pc = truncate_if_32bit(regs->msr, regs->nip + GETLENGTH(op->type)); 3078 switch (GETTYPE(op->type)) { 3079 case COMPUTE: 3080 if (op->type & SETREG) 3081 regs->gpr[op->reg] = op->val; 3082 if (op->type & SETCC) 3083 regs->ccr = op->ccval; 3084 if (op->type & SETXER) 3085 regs->xer = op->xerval; 3086 break; 3087 3088 case BRANCH: 3089 if (op->type & SETLK) 3090 regs->link = next_pc; 3091 if (op->type & BRTAKEN) 3092 next_pc = op->val; 3093 if (op->type & DECCTR) 3094 --regs->ctr; 3095 break; 3096 3097 case BARRIER: 3098 switch (op->type & BARRIER_MASK) { 3099 case BARRIER_SYNC: 3100 mb(); 3101 break; 3102 case BARRIER_ISYNC: 3103 isync(); 3104 break; 3105 case BARRIER_EIEIO: 3106 eieio(); 3107 break; 3108 case BARRIER_LWSYNC: 3109 asm volatile("lwsync" : : : "memory"); 3110 break; 3111 case BARRIER_PTESYNC: 3112 asm volatile("ptesync" : : : "memory"); 3113 break; 3114 } 3115 break; 3116 3117 case MFSPR: 3118 switch (op->spr) { 3119 case SPRN_XER: 3120 regs->gpr[op->reg] = regs->xer & 0xffffffffUL; 3121 break; 3122 case SPRN_LR: 3123 regs->gpr[op->reg] = regs->link; 3124 break; 3125 case SPRN_CTR: 3126 regs->gpr[op->reg] = regs->ctr; 3127 break; 3128 default: 3129 WARN_ON_ONCE(1); 3130 } 3131 break; 3132 3133 case MTSPR: 3134 switch (op->spr) { 3135 case SPRN_XER: 3136 regs->xer = op->val & 0xffffffffUL; 3137 break; 3138 case SPRN_LR: 3139 regs->link = op->val; 3140 break; 3141 case SPRN_CTR: 3142 regs->ctr = op->val; 3143 break; 3144 default: 3145 WARN_ON_ONCE(1); 3146 } 3147 break; 3148 3149 default: 3150 WARN_ON_ONCE(1); 3151 } 3152 regs->nip = next_pc; 3153} 3154NOKPROBE_SYMBOL(emulate_update_regs); 3155 3156/* 3157 * Emulate a previously-analysed load or store instruction. 3158 * Return values are: 3159 * 0 = instruction emulated successfully 3160 * -EFAULT = address out of range or access faulted (regs->dar 3161 * contains the faulting address) 3162 * -EACCES = misaligned access, instruction requires alignment 3163 * -EINVAL = unknown operation in *op 3164 */ 3165int emulate_loadstore(struct pt_regs *regs, struct instruction_op *op) 3166{ 3167 int err, size, type; 3168 int i, rd, nb; 3169 unsigned int cr; 3170 unsigned long val; 3171 unsigned long ea; 3172 bool cross_endian; 3173 3174 err = 0; 3175 size = GETSIZE(op->type); 3176 type = GETTYPE(op->type); 3177 cross_endian = (regs->msr & MSR_LE) != (MSR_KERNEL & MSR_LE); 3178 ea = truncate_if_32bit(regs->msr, op->ea); 3179 3180 switch (type) { 3181 case LARX: 3182 if (ea & (size - 1)) 3183 return -EACCES; /* can't handle misaligned */ 3184 if (!address_ok(regs, ea, size)) 3185 return -EFAULT; 3186 err = 0; 3187 val = 0; 3188 switch (size) { 3189#ifdef __powerpc64__ 3190 case 1: 3191 __get_user_asmx(val, ea, err, "lbarx"); 3192 break; 3193 case 2: 3194 __get_user_asmx(val, ea, err, "lharx"); 3195 break; 3196#endif 3197 case 4: 3198 __get_user_asmx(val, ea, err, "lwarx"); 3199 break; 3200#ifdef __powerpc64__ 3201 case 8: 3202 __get_user_asmx(val, ea, err, "ldarx"); 3203 break; 3204 case 16: 3205 err = do_lqarx(ea, &regs->gpr[op->reg]); 3206 break; 3207#endif 3208 default: 3209 return -EINVAL; 3210 } 3211 if (err) { 3212 regs->dar = ea; 3213 break; 3214 } 3215 if (size < 16) 3216 regs->gpr[op->reg] = val; 3217 break; 3218 3219 case STCX: 3220 if (ea & (size - 1)) 3221 return -EACCES; /* can't handle misaligned */ 3222 if (!address_ok(regs, ea, size)) 3223 return -EFAULT; 3224 err = 0; 3225 switch (size) { 3226#ifdef __powerpc64__ 3227 case 1: 3228 __put_user_asmx(op->val, ea, err, "stbcx.", cr); 3229 break; 3230 case 2: 3231 __put_user_asmx(op->val, ea, err, "stbcx.", cr); 3232 break; 3233#endif 3234 case 4: 3235 __put_user_asmx(op->val, ea, err, "stwcx.", cr); 3236 break; 3237#ifdef __powerpc64__ 3238 case 8: 3239 __put_user_asmx(op->val, ea, err, "stdcx.", cr); 3240 break; 3241 case 16: 3242 err = do_stqcx(ea, regs->gpr[op->reg], 3243 regs->gpr[op->reg + 1], &cr); 3244 break; 3245#endif 3246 default: 3247 return -EINVAL; 3248 } 3249 if (!err) 3250 regs->ccr = (regs->ccr & 0x0fffffff) | 3251 (cr & 0xe0000000) | 3252 ((regs->xer >> 3) & 0x10000000); 3253 else 3254 regs->dar = ea; 3255 break; 3256 3257 case LOAD: 3258#ifdef __powerpc64__ 3259 if (size == 16) { 3260 err = emulate_lq(regs, ea, op->reg, cross_endian); 3261 break; 3262 } 3263#endif 3264 err = read_mem(&regs->gpr[op->reg], ea, size, regs); 3265 if (!err) { 3266 if (op->type & SIGNEXT) 3267 do_signext(&regs->gpr[op->reg], size); 3268 if ((op->type & BYTEREV) == (cross_endian ? 0 : BYTEREV)) 3269 do_byterev(&regs->gpr[op->reg], size); 3270 } 3271 break; 3272 3273#ifdef CONFIG_PPC_FPU 3274 case LOAD_FP: 3275 /* 3276 * If the instruction is in userspace, we can emulate it even 3277 * if the VMX state is not live, because we have the state 3278 * stored in the thread_struct. If the instruction is in 3279 * the kernel, we must not touch the state in the thread_struct. 3280 */ 3281 if (!(regs->msr & MSR_PR) && !(regs->msr & MSR_FP)) 3282 return 0; 3283 err = do_fp_load(op, ea, regs, cross_endian); 3284 break; 3285#endif 3286#ifdef CONFIG_ALTIVEC 3287 case LOAD_VMX: 3288 if (!(regs->msr & MSR_PR) && !(regs->msr & MSR_VEC)) 3289 return 0; 3290 err = do_vec_load(op->reg, ea, size, regs, cross_endian); 3291 break; 3292#endif 3293#ifdef CONFIG_VSX 3294 case LOAD_VSX: { 3295 unsigned long msrbit = MSR_VSX; 3296 3297 /* 3298 * Some VSX instructions check the MSR_VEC bit rather than MSR_VSX 3299 * when the target of the instruction is a vector register. 3300 */ 3301 if (op->reg >= 32 && (op->vsx_flags & VSX_CHECK_VEC)) 3302 msrbit = MSR_VEC; 3303 if (!(regs->msr & MSR_PR) && !(regs->msr & msrbit)) 3304 return 0; 3305 err = do_vsx_load(op, ea, regs, cross_endian); 3306 break; 3307 } 3308#endif 3309 case LOAD_MULTI: 3310 if (!address_ok(regs, ea, size)) 3311 return -EFAULT; 3312 rd = op->reg; 3313 for (i = 0; i < size; i += 4) { 3314 unsigned int v32 = 0; 3315 3316 nb = size - i; 3317 if (nb > 4) 3318 nb = 4; 3319 err = copy_mem_in((u8 *) &v32, ea, nb, regs); 3320 if (err) 3321 break; 3322 if (unlikely(cross_endian)) 3323 v32 = byterev_4(v32); 3324 regs->gpr[rd] = v32; 3325 ea += 4; 3326 /* reg number wraps from 31 to 0 for lsw[ix] */ 3327 rd = (rd + 1) & 0x1f; 3328 } 3329 break; 3330 3331 case STORE: 3332#ifdef __powerpc64__ 3333 if (size == 16) { 3334 err = emulate_stq(regs, ea, op->reg, cross_endian); 3335 break; 3336 } 3337#endif 3338 if ((op->type & UPDATE) && size == sizeof(long) && 3339 op->reg == 1 && op->update_reg == 1 && 3340 !(regs->msr & MSR_PR) && 3341 ea >= regs->gpr[1] - STACK_INT_FRAME_SIZE) { 3342 err = handle_stack_update(ea, regs); 3343 break; 3344 } 3345 if (unlikely(cross_endian)) 3346 do_byterev(&op->val, size); 3347 err = write_mem(op->val, ea, size, regs); 3348 break; 3349 3350#ifdef CONFIG_PPC_FPU 3351 case STORE_FP: 3352 if (!(regs->msr & MSR_PR) && !(regs->msr & MSR_FP)) 3353 return 0; 3354 err = do_fp_store(op, ea, regs, cross_endian); 3355 break; 3356#endif 3357#ifdef CONFIG_ALTIVEC 3358 case STORE_VMX: 3359 if (!(regs->msr & MSR_PR) && !(regs->msr & MSR_VEC)) 3360 return 0; 3361 err = do_vec_store(op->reg, ea, size, regs, cross_endian); 3362 break; 3363#endif 3364#ifdef CONFIG_VSX 3365 case STORE_VSX: { 3366 unsigned long msrbit = MSR_VSX; 3367 3368 /* 3369 * Some VSX instructions check the MSR_VEC bit rather than MSR_VSX 3370 * when the target of the instruction is a vector register. 3371 */ 3372 if (op->reg >= 32 && (op->vsx_flags & VSX_CHECK_VEC)) 3373 msrbit = MSR_VEC; 3374 if (!(regs->msr & MSR_PR) && !(regs->msr & msrbit)) 3375 return 0; 3376 err = do_vsx_store(op, ea, regs, cross_endian); 3377 break; 3378 } 3379#endif 3380 case STORE_MULTI: 3381 if (!address_ok(regs, ea, size)) 3382 return -EFAULT; 3383 rd = op->reg; 3384 for (i = 0; i < size; i += 4) { 3385 unsigned int v32 = regs->gpr[rd]; 3386 3387 nb = size - i; 3388 if (nb > 4) 3389 nb = 4; 3390 if (unlikely(cross_endian)) 3391 v32 = byterev_4(v32); 3392 err = copy_mem_out((u8 *) &v32, ea, nb, regs); 3393 if (err) 3394 break; 3395 ea += 4; 3396 /* reg number wraps from 31 to 0 for stsw[ix] */ 3397 rd = (rd + 1) & 0x1f; 3398 } 3399 break; 3400 3401 default: 3402 return -EINVAL; 3403 } 3404 3405 if (err) 3406 return err; 3407 3408 if (op->type & UPDATE) 3409 regs->gpr[op->update_reg] = op->ea; 3410 3411 return 0; 3412} 3413NOKPROBE_SYMBOL(emulate_loadstore); 3414 3415/* 3416 * Emulate instructions that cause a transfer of control, 3417 * loads and stores, and a few other instructions. 3418 * Returns 1 if the step was emulated, 0 if not, 3419 * or -1 if the instruction is one that should not be stepped, 3420 * such as an rfid, or a mtmsrd that would clear MSR_RI. 3421 */ 3422int emulate_step(struct pt_regs *regs, struct ppc_inst instr) 3423{ 3424 struct instruction_op op; 3425 int r, err, type; 3426 unsigned long val; 3427 unsigned long ea; 3428 3429 r = analyse_instr(&op, regs, instr); 3430 if (r < 0) 3431 return r; 3432 if (r > 0) { 3433 emulate_update_regs(regs, &op); 3434 return 1; 3435 } 3436 3437 err = 0; 3438 type = GETTYPE(op.type); 3439 3440 if (OP_IS_LOAD_STORE(type)) { 3441 err = emulate_loadstore(regs, &op); 3442 if (err) 3443 return 0; 3444 goto instr_done; 3445 } 3446 3447 switch (type) { 3448 case CACHEOP: 3449 ea = truncate_if_32bit(regs->msr, op.ea); 3450 if (!address_ok(regs, ea, 8)) 3451 return 0; 3452 switch (op.type & CACHEOP_MASK) { 3453 case DCBST: 3454 __cacheop_user_asmx(ea, err, "dcbst"); 3455 break; 3456 case DCBF: 3457 __cacheop_user_asmx(ea, err, "dcbf"); 3458 break; 3459 case DCBTST: 3460 if (op.reg == 0) 3461 prefetchw((void *) ea); 3462 break; 3463 case DCBT: 3464 if (op.reg == 0) 3465 prefetch((void *) ea); 3466 break; 3467 case ICBI: 3468 __cacheop_user_asmx(ea, err, "icbi"); 3469 break; 3470 case DCBZ: 3471 err = emulate_dcbz(ea, regs); 3472 break; 3473 } 3474 if (err) { 3475 regs->dar = ea; 3476 return 0; 3477 } 3478 goto instr_done; 3479 3480 case MFMSR: 3481 regs->gpr[op.reg] = regs->msr & MSR_MASK; 3482 goto instr_done; 3483 3484 case MTMSR: 3485 val = regs->gpr[op.reg]; 3486 if ((val & MSR_RI) == 0) 3487 /* can't step mtmsr[d] that would clear MSR_RI */ 3488 return -1; 3489 /* here op.val is the mask of bits to change */ 3490 regs->msr = (regs->msr & ~op.val) | (val & op.val); 3491 goto instr_done; 3492 3493#ifdef CONFIG_PPC64 3494 case SYSCALL: /* sc */ 3495 /* 3496 * N.B. this uses knowledge about how the syscall 3497 * entry code works. If that is changed, this will 3498 * need to be changed also. 3499 */ 3500 if (IS_ENABLED(CONFIG_PPC_FAST_ENDIAN_SWITCH) && 3501 cpu_has_feature(CPU_FTR_REAL_LE) && 3502 regs->gpr[0] == 0x1ebe) { 3503 regs->msr ^= MSR_LE; 3504 goto instr_done; 3505 } 3506 regs->gpr[9] = regs->gpr[13]; 3507 regs->gpr[10] = MSR_KERNEL; 3508 regs->gpr[11] = regs->nip + 4; 3509 regs->gpr[12] = regs->msr & MSR_MASK; 3510 regs->gpr[13] = (unsigned long) get_paca(); 3511 regs->nip = (unsigned long) &system_call_common; 3512 regs->msr = MSR_KERNEL; 3513 return 1; 3514 3515#ifdef CONFIG_PPC_BOOK3S_64 3516 case SYSCALL_VECTORED_0: /* scv 0 */ 3517 regs->gpr[9] = regs->gpr[13]; 3518 regs->gpr[10] = MSR_KERNEL; 3519 regs->gpr[11] = regs->nip + 4; 3520 regs->gpr[12] = regs->msr & MSR_MASK; 3521 regs->gpr[13] = (unsigned long) get_paca(); 3522 regs->nip = (unsigned long) &system_call_vectored_emulate; 3523 regs->msr = MSR_KERNEL; 3524 return 1; 3525#endif 3526 3527 case RFI: 3528 return -1; 3529#endif 3530 } 3531 return 0; 3532 3533 instr_done: 3534 regs->nip = truncate_if_32bit(regs->msr, regs->nip + GETLENGTH(op.type)); 3535 return 1; 3536} 3537NOKPROBE_SYMBOL(emulate_step);