qemu/target/i386/hvf/x86_emu.c
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   1/*
   2 * Copyright (C) 2016 Veertu Inc,
   3 * Copyright (C) 2017 Google Inc,
   4 *
   5 * This program is free software; you can redistribute it and/or
   6 * modify it under the terms of the GNU Lesser General Public
   7 * License as published by the Free Software Foundation; either
   8 * version 2.1 of the License, or (at your option) any later version.
   9 *
  10 * This program is distributed in the hope that it will be useful,
  11 * but WITHOUT ANY WARRANTY; without even the implied warranty of
  12 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
  13 * Lesser General Public License for more details.
  14 *
  15 * You should have received a copy of the GNU Lesser General Public
  16 * License along with this program; if not, see <http://www.gnu.org/licenses/>.
  17 */
  18
  19/////////////////////////////////////////////////////////////////////////
  20//
  21//  Copyright (C) 2001-2012  The Bochs Project
  22//
  23//  This library is free software; you can redistribute it and/or
  24//  modify it under the terms of the GNU Lesser General Public
  25//  License as published by the Free Software Foundation; either
  26//  version 2.1 of the License, or (at your option) any later version.
  27//
  28//  This library is distributed in the hope that it will be useful,
  29//  but WITHOUT ANY WARRANTY; without even the implied warranty of
  30//  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
  31//  Lesser General Public License for more details.
  32//
  33//  You should have received a copy of the GNU Lesser General Public
  34//  License along with this library; if not, write to the Free Software
  35//  Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA B 02110-1301 USA
  36/////////////////////////////////////////////////////////////////////////
  37
  38#include "qemu/osdep.h"
  39#include "panic.h"
  40#include "qemu-common.h"
  41#include "x86_decode.h"
  42#include "x86.h"
  43#include "x86_emu.h"
  44#include "x86_mmu.h"
  45#include "x86_flags.h"
  46#include "vmcs.h"
  47#include "vmx.h"
  48
  49void hvf_handle_io(struct CPUState *cpu, uint16_t port, void *data,
  50                   int direction, int size, uint32_t count);
  51
  52#define EXEC_2OP_FLAGS_CMD(env, decode, cmd, FLAGS_FUNC, save_res) \
  53{                                                       \
  54    fetch_operands(env, decode, 2, true, true, false);  \
  55    switch (decode->operand_size) {                     \
  56    case 1:                                         \
  57    {                                               \
  58        uint8_t v1 = (uint8_t)decode->op[0].val;    \
  59        uint8_t v2 = (uint8_t)decode->op[1].val;    \
  60        uint8_t diff = v1 cmd v2;                   \
  61        if (save_res) {                              \
  62            write_val_ext(env, decode->op[0].ptr, diff, 1);  \
  63        } \
  64        FLAGS_FUNC##8(env, v1, v2, diff);           \
  65        break;                                      \
  66    }                                               \
  67    case 2:                                        \
  68    {                                               \
  69        uint16_t v1 = (uint16_t)decode->op[0].val;  \
  70        uint16_t v2 = (uint16_t)decode->op[1].val;  \
  71        uint16_t diff = v1 cmd v2;                  \
  72        if (save_res) {                              \
  73            write_val_ext(env, decode->op[0].ptr, diff, 2); \
  74        } \
  75        FLAGS_FUNC##16(env, v1, v2, diff);          \
  76        break;                                      \
  77    }                                               \
  78    case 4:                                        \
  79    {                                               \
  80        uint32_t v1 = (uint32_t)decode->op[0].val;  \
  81        uint32_t v2 = (uint32_t)decode->op[1].val;  \
  82        uint32_t diff = v1 cmd v2;                  \
  83        if (save_res) {                              \
  84            write_val_ext(env, decode->op[0].ptr, diff, 4); \
  85        } \
  86        FLAGS_FUNC##32(env, v1, v2, diff);          \
  87        break;                                      \
  88    }                                               \
  89    default:                                        \
  90        VM_PANIC("bad size\n");                    \
  91    }                                                   \
  92}                                                       \
  93
  94target_ulong read_reg(CPUX86State *env, int reg, int size)
  95{
  96    switch (size) {
  97    case 1:
  98        return x86_reg(env, reg)->lx;
  99    case 2:
 100        return x86_reg(env, reg)->rx;
 101    case 4:
 102        return x86_reg(env, reg)->erx;
 103    case 8:
 104        return x86_reg(env, reg)->rrx;
 105    default:
 106        abort();
 107    }
 108    return 0;
 109}
 110
 111void write_reg(CPUX86State *env, int reg, target_ulong val, int size)
 112{
 113    switch (size) {
 114    case 1:
 115        x86_reg(env, reg)->lx = val;
 116        break;
 117    case 2:
 118        x86_reg(env, reg)->rx = val;
 119        break;
 120    case 4:
 121        x86_reg(env, reg)->rrx = (uint32_t)val;
 122        break;
 123    case 8:
 124        x86_reg(env, reg)->rrx = val;
 125        break;
 126    default:
 127        abort();
 128    }
 129}
 130
 131target_ulong read_val_from_reg(target_ulong reg_ptr, int size)
 132{
 133    target_ulong val;
 134    
 135    switch (size) {
 136    case 1:
 137        val = *(uint8_t *)reg_ptr;
 138        break;
 139    case 2:
 140        val = *(uint16_t *)reg_ptr;
 141        break;
 142    case 4:
 143        val = *(uint32_t *)reg_ptr;
 144        break;
 145    case 8:
 146        val = *(uint64_t *)reg_ptr;
 147        break;
 148    default:
 149        abort();
 150    }
 151    return val;
 152}
 153
 154void write_val_to_reg(target_ulong reg_ptr, target_ulong val, int size)
 155{
 156    switch (size) {
 157    case 1:
 158        *(uint8_t *)reg_ptr = val;
 159        break;
 160    case 2:
 161        *(uint16_t *)reg_ptr = val;
 162        break;
 163    case 4:
 164        *(uint64_t *)reg_ptr = (uint32_t)val;
 165        break;
 166    case 8:
 167        *(uint64_t *)reg_ptr = val;
 168        break;
 169    default:
 170        abort();
 171    }
 172}
 173
 174static bool is_host_reg(struct CPUX86State *env, target_ulong ptr)
 175{
 176    return (ptr - (target_ulong)&env->regs[0]) < sizeof(env->regs);
 177}
 178
 179void write_val_ext(struct CPUX86State *env, target_ulong ptr, target_ulong val, int size)
 180{
 181    if (is_host_reg(env, ptr)) {
 182        write_val_to_reg(ptr, val, size);
 183        return;
 184    }
 185    vmx_write_mem(env_cpu(env), ptr, &val, size);
 186}
 187
 188uint8_t *read_mmio(struct CPUX86State *env, target_ulong ptr, int bytes)
 189{
 190    vmx_read_mem(env_cpu(env), env->hvf_mmio_buf, ptr, bytes);
 191    return env->hvf_mmio_buf;
 192}
 193
 194
 195target_ulong read_val_ext(struct CPUX86State *env, target_ulong ptr, int size)
 196{
 197    target_ulong val;
 198    uint8_t *mmio_ptr;
 199
 200    if (is_host_reg(env, ptr)) {
 201        return read_val_from_reg(ptr, size);
 202    }
 203
 204    mmio_ptr = read_mmio(env, ptr, size);
 205    switch (size) {
 206    case 1:
 207        val = *(uint8_t *)mmio_ptr;
 208        break;
 209    case 2:
 210        val = *(uint16_t *)mmio_ptr;
 211        break;
 212    case 4:
 213        val = *(uint32_t *)mmio_ptr;
 214        break;
 215    case 8:
 216        val = *(uint64_t *)mmio_ptr;
 217        break;
 218    default:
 219        VM_PANIC("bad size\n");
 220        break;
 221    }
 222    return val;
 223}
 224
 225static void fetch_operands(struct CPUX86State *env, struct x86_decode *decode,
 226                           int n, bool val_op0, bool val_op1, bool val_op2)
 227{
 228    int i;
 229    bool calc_val[3] = {val_op0, val_op1, val_op2};
 230
 231    for (i = 0; i < n; i++) {
 232        switch (decode->op[i].type) {
 233        case X86_VAR_IMMEDIATE:
 234            break;
 235        case X86_VAR_REG:
 236            VM_PANIC_ON(!decode->op[i].ptr);
 237            if (calc_val[i]) {
 238                decode->op[i].val = read_val_from_reg(decode->op[i].ptr,
 239                                                      decode->operand_size);
 240            }
 241            break;
 242        case X86_VAR_RM:
 243            calc_modrm_operand(env, decode, &decode->op[i]);
 244            if (calc_val[i]) {
 245                decode->op[i].val = read_val_ext(env, decode->op[i].ptr,
 246                                                 decode->operand_size);
 247            }
 248            break;
 249        case X86_VAR_OFFSET:
 250            decode->op[i].ptr = decode_linear_addr(env, decode,
 251                                                   decode->op[i].ptr,
 252                                                   R_DS);
 253            if (calc_val[i]) {
 254                decode->op[i].val = read_val_ext(env, decode->op[i].ptr,
 255                                                 decode->operand_size);
 256            }
 257            break;
 258        default:
 259            break;
 260        }
 261    }
 262}
 263
 264static void exec_mov(struct CPUX86State *env, struct x86_decode *decode)
 265{
 266    fetch_operands(env, decode, 2, false, true, false);
 267    write_val_ext(env, decode->op[0].ptr, decode->op[1].val,
 268                  decode->operand_size);
 269
 270    env->eip += decode->len;
 271}
 272
 273static void exec_add(struct CPUX86State *env, struct x86_decode *decode)
 274{
 275    EXEC_2OP_FLAGS_CMD(env, decode, +, SET_FLAGS_OSZAPC_ADD, true);
 276    env->eip += decode->len;
 277}
 278
 279static void exec_or(struct CPUX86State *env, struct x86_decode *decode)
 280{
 281    EXEC_2OP_FLAGS_CMD(env, decode, |, SET_FLAGS_OSZAPC_LOGIC, true);
 282    env->eip += decode->len;
 283}
 284
 285static void exec_adc(struct CPUX86State *env, struct x86_decode *decode)
 286{
 287    EXEC_2OP_FLAGS_CMD(env, decode, +get_CF(env)+, SET_FLAGS_OSZAPC_ADD, true);
 288    env->eip += decode->len;
 289}
 290
 291static void exec_sbb(struct CPUX86State *env, struct x86_decode *decode)
 292{
 293    EXEC_2OP_FLAGS_CMD(env, decode, -get_CF(env)-, SET_FLAGS_OSZAPC_SUB, true);
 294    env->eip += decode->len;
 295}
 296
 297static void exec_and(struct CPUX86State *env, struct x86_decode *decode)
 298{
 299    EXEC_2OP_FLAGS_CMD(env, decode, &, SET_FLAGS_OSZAPC_LOGIC, true);
 300    env->eip += decode->len;
 301}
 302
 303static void exec_sub(struct CPUX86State *env, struct x86_decode *decode)
 304{
 305    EXEC_2OP_FLAGS_CMD(env, decode, -, SET_FLAGS_OSZAPC_SUB, true);
 306    env->eip += decode->len;
 307}
 308
 309static void exec_xor(struct CPUX86State *env, struct x86_decode *decode)
 310{
 311    EXEC_2OP_FLAGS_CMD(env, decode, ^, SET_FLAGS_OSZAPC_LOGIC, true);
 312    env->eip += decode->len;
 313}
 314
 315static void exec_neg(struct CPUX86State *env, struct x86_decode *decode)
 316{
 317    /*EXEC_2OP_FLAGS_CMD(env, decode, -, SET_FLAGS_OSZAPC_SUB, false);*/
 318    int32_t val;
 319    fetch_operands(env, decode, 2, true, true, false);
 320
 321    val = 0 - sign(decode->op[1].val, decode->operand_size);
 322    write_val_ext(env, decode->op[1].ptr, val, decode->operand_size);
 323
 324    if (4 == decode->operand_size) {
 325        SET_FLAGS_OSZAPC_SUB32(env, 0, 0 - val, val);
 326    } else if (2 == decode->operand_size) {
 327        SET_FLAGS_OSZAPC_SUB16(env, 0, 0 - val, val);
 328    } else if (1 == decode->operand_size) {
 329        SET_FLAGS_OSZAPC_SUB8(env, 0, 0 - val, val);
 330    } else {
 331        VM_PANIC("bad op size\n");
 332    }
 333
 334    /*lflags_to_rflags(env);*/
 335    env->eip += decode->len;
 336}
 337
 338static void exec_cmp(struct CPUX86State *env, struct x86_decode *decode)
 339{
 340    EXEC_2OP_FLAGS_CMD(env, decode, -, SET_FLAGS_OSZAPC_SUB, false);
 341    env->eip += decode->len;
 342}
 343
 344static void exec_inc(struct CPUX86State *env, struct x86_decode *decode)
 345{
 346    decode->op[1].type = X86_VAR_IMMEDIATE;
 347    decode->op[1].val = 0;
 348
 349    EXEC_2OP_FLAGS_CMD(env, decode, +1+, SET_FLAGS_OSZAP_ADD, true);
 350
 351    env->eip += decode->len;
 352}
 353
 354static void exec_dec(struct CPUX86State *env, struct x86_decode *decode)
 355{
 356    decode->op[1].type = X86_VAR_IMMEDIATE;
 357    decode->op[1].val = 0;
 358
 359    EXEC_2OP_FLAGS_CMD(env, decode, -1-, SET_FLAGS_OSZAP_SUB, true);
 360    env->eip += decode->len;
 361}
 362
 363static void exec_tst(struct CPUX86State *env, struct x86_decode *decode)
 364{
 365    EXEC_2OP_FLAGS_CMD(env, decode, &, SET_FLAGS_OSZAPC_LOGIC, false);
 366    env->eip += decode->len;
 367}
 368
 369static void exec_not(struct CPUX86State *env, struct x86_decode *decode)
 370{
 371    fetch_operands(env, decode, 1, true, false, false);
 372
 373    write_val_ext(env, decode->op[0].ptr, ~decode->op[0].val,
 374                  decode->operand_size);
 375    env->eip += decode->len;
 376}
 377
 378void exec_movzx(struct CPUX86State *env, struct x86_decode *decode)
 379{
 380    int src_op_size;
 381    int op_size = decode->operand_size;
 382
 383    fetch_operands(env, decode, 1, false, false, false);
 384
 385    if (0xb6 == decode->opcode[1]) {
 386        src_op_size = 1;
 387    } else {
 388        src_op_size = 2;
 389    }
 390    decode->operand_size = src_op_size;
 391    calc_modrm_operand(env, decode, &decode->op[1]);
 392    decode->op[1].val = read_val_ext(env, decode->op[1].ptr, src_op_size);
 393    write_val_ext(env, decode->op[0].ptr, decode->op[1].val, op_size);
 394
 395    env->eip += decode->len;
 396}
 397
 398static void exec_out(struct CPUX86State *env, struct x86_decode *decode)
 399{
 400    switch (decode->opcode[0]) {
 401    case 0xe6:
 402        hvf_handle_io(env_cpu(env), decode->op[0].val, &AL(env), 1, 1, 1);
 403        break;
 404    case 0xe7:
 405        hvf_handle_io(env_cpu(env), decode->op[0].val, &RAX(env), 1,
 406                      decode->operand_size, 1);
 407        break;
 408    case 0xee:
 409        hvf_handle_io(env_cpu(env), DX(env), &AL(env), 1, 1, 1);
 410        break;
 411    case 0xef:
 412        hvf_handle_io(env_cpu(env), DX(env), &RAX(env), 1,
 413                      decode->operand_size, 1);
 414        break;
 415    default:
 416        VM_PANIC("Bad out opcode\n");
 417        break;
 418    }
 419    env->eip += decode->len;
 420}
 421
 422static void exec_in(struct CPUX86State *env, struct x86_decode *decode)
 423{
 424    target_ulong val = 0;
 425    switch (decode->opcode[0]) {
 426    case 0xe4:
 427        hvf_handle_io(env_cpu(env), decode->op[0].val, &AL(env), 0, 1, 1);
 428        break;
 429    case 0xe5:
 430        hvf_handle_io(env_cpu(env), decode->op[0].val, &val, 0,
 431                      decode->operand_size, 1);
 432        if (decode->operand_size == 2) {
 433            AX(env) = val;
 434        } else {
 435            RAX(env) = (uint32_t)val;
 436        }
 437        break;
 438    case 0xec:
 439        hvf_handle_io(env_cpu(env), DX(env), &AL(env), 0, 1, 1);
 440        break;
 441    case 0xed:
 442        hvf_handle_io(env_cpu(env), DX(env), &val, 0, decode->operand_size, 1);
 443        if (decode->operand_size == 2) {
 444            AX(env) = val;
 445        } else {
 446            RAX(env) = (uint32_t)val;
 447        }
 448
 449        break;
 450    default:
 451        VM_PANIC("Bad in opcode\n");
 452        break;
 453    }
 454
 455    env->eip += decode->len;
 456}
 457
 458static inline void string_increment_reg(struct CPUX86State *env, int reg,
 459                                        struct x86_decode *decode)
 460{
 461    target_ulong val = read_reg(env, reg, decode->addressing_size);
 462    if (env->eflags & DF_MASK) {
 463        val -= decode->operand_size;
 464    } else {
 465        val += decode->operand_size;
 466    }
 467    write_reg(env, reg, val, decode->addressing_size);
 468}
 469
 470static inline void string_rep(struct CPUX86State *env, struct x86_decode *decode,
 471                              void (*func)(struct CPUX86State *env,
 472                                           struct x86_decode *ins), int rep)
 473{
 474    target_ulong rcx = read_reg(env, R_ECX, decode->addressing_size);
 475    while (rcx--) {
 476        func(env, decode);
 477        write_reg(env, R_ECX, rcx, decode->addressing_size);
 478        if ((PREFIX_REP == rep) && !get_ZF(env)) {
 479            break;
 480        }
 481        if ((PREFIX_REPN == rep) && get_ZF(env)) {
 482            break;
 483        }
 484    }
 485}
 486
 487static void exec_ins_single(struct CPUX86State *env, struct x86_decode *decode)
 488{
 489    target_ulong addr = linear_addr_size(env_cpu(env), RDI(env),
 490                                         decode->addressing_size, R_ES);
 491
 492    hvf_handle_io(env_cpu(env), DX(env), env->hvf_mmio_buf, 0,
 493                  decode->operand_size, 1);
 494    vmx_write_mem(env_cpu(env), addr, env->hvf_mmio_buf,
 495                  decode->operand_size);
 496
 497    string_increment_reg(env, R_EDI, decode);
 498}
 499
 500static void exec_ins(struct CPUX86State *env, struct x86_decode *decode)
 501{
 502    if (decode->rep) {
 503        string_rep(env, decode, exec_ins_single, 0);
 504    } else {
 505        exec_ins_single(env, decode);
 506    }
 507
 508    env->eip += decode->len;
 509}
 510
 511static void exec_outs_single(struct CPUX86State *env, struct x86_decode *decode)
 512{
 513    target_ulong addr = decode_linear_addr(env, decode, RSI(env), R_DS);
 514
 515    vmx_read_mem(env_cpu(env), env->hvf_mmio_buf, addr,
 516                 decode->operand_size);
 517    hvf_handle_io(env_cpu(env), DX(env), env->hvf_mmio_buf, 1,
 518                  decode->operand_size, 1);
 519
 520    string_increment_reg(env, R_ESI, decode);
 521}
 522
 523static void exec_outs(struct CPUX86State *env, struct x86_decode *decode)
 524{
 525    if (decode->rep) {
 526        string_rep(env, decode, exec_outs_single, 0);
 527    } else {
 528        exec_outs_single(env, decode);
 529    }
 530
 531    env->eip += decode->len;
 532}
 533
 534static void exec_movs_single(struct CPUX86State *env, struct x86_decode *decode)
 535{
 536    target_ulong src_addr;
 537    target_ulong dst_addr;
 538    target_ulong val;
 539
 540    src_addr = decode_linear_addr(env, decode, RSI(env), R_DS);
 541    dst_addr = linear_addr_size(env_cpu(env), RDI(env),
 542                                decode->addressing_size, R_ES);
 543
 544    val = read_val_ext(env, src_addr, decode->operand_size);
 545    write_val_ext(env, dst_addr, val, decode->operand_size);
 546
 547    string_increment_reg(env, R_ESI, decode);
 548    string_increment_reg(env, R_EDI, decode);
 549}
 550
 551static void exec_movs(struct CPUX86State *env, struct x86_decode *decode)
 552{
 553    if (decode->rep) {
 554        string_rep(env, decode, exec_movs_single, 0);
 555    } else {
 556        exec_movs_single(env, decode);
 557    }
 558
 559    env->eip += decode->len;
 560}
 561
 562static void exec_cmps_single(struct CPUX86State *env, struct x86_decode *decode)
 563{
 564    target_ulong src_addr;
 565    target_ulong dst_addr;
 566
 567    src_addr = decode_linear_addr(env, decode, RSI(env), R_DS);
 568    dst_addr = linear_addr_size(env_cpu(env), RDI(env),
 569                                decode->addressing_size, R_ES);
 570
 571    decode->op[0].type = X86_VAR_IMMEDIATE;
 572    decode->op[0].val = read_val_ext(env, src_addr, decode->operand_size);
 573    decode->op[1].type = X86_VAR_IMMEDIATE;
 574    decode->op[1].val = read_val_ext(env, dst_addr, decode->operand_size);
 575
 576    EXEC_2OP_FLAGS_CMD(env, decode, -, SET_FLAGS_OSZAPC_SUB, false);
 577
 578    string_increment_reg(env, R_ESI, decode);
 579    string_increment_reg(env, R_EDI, decode);
 580}
 581
 582static void exec_cmps(struct CPUX86State *env, struct x86_decode *decode)
 583{
 584    if (decode->rep) {
 585        string_rep(env, decode, exec_cmps_single, decode->rep);
 586    } else {
 587        exec_cmps_single(env, decode);
 588    }
 589    env->eip += decode->len;
 590}
 591
 592
 593static void exec_stos_single(struct CPUX86State *env, struct x86_decode *decode)
 594{
 595    target_ulong addr;
 596    target_ulong val;
 597
 598    addr = linear_addr_size(env_cpu(env), RDI(env),
 599                            decode->addressing_size, R_ES);
 600    val = read_reg(env, R_EAX, decode->operand_size);
 601    vmx_write_mem(env_cpu(env), addr, &val, decode->operand_size);
 602
 603    string_increment_reg(env, R_EDI, decode);
 604}
 605
 606
 607static void exec_stos(struct CPUX86State *env, struct x86_decode *decode)
 608{
 609    if (decode->rep) {
 610        string_rep(env, decode, exec_stos_single, 0);
 611    } else {
 612        exec_stos_single(env, decode);
 613    }
 614
 615    env->eip += decode->len;
 616}
 617
 618static void exec_scas_single(struct CPUX86State *env, struct x86_decode *decode)
 619{
 620    target_ulong addr;
 621
 622    addr = linear_addr_size(env_cpu(env), RDI(env),
 623                            decode->addressing_size, R_ES);
 624    decode->op[1].type = X86_VAR_IMMEDIATE;
 625    vmx_read_mem(env_cpu(env), &decode->op[1].val, addr, decode->operand_size);
 626
 627    EXEC_2OP_FLAGS_CMD(env, decode, -, SET_FLAGS_OSZAPC_SUB, false);
 628    string_increment_reg(env, R_EDI, decode);
 629}
 630
 631static void exec_scas(struct CPUX86State *env, struct x86_decode *decode)
 632{
 633    decode->op[0].type = X86_VAR_REG;
 634    decode->op[0].reg = R_EAX;
 635    if (decode->rep) {
 636        string_rep(env, decode, exec_scas_single, decode->rep);
 637    } else {
 638        exec_scas_single(env, decode);
 639    }
 640
 641    env->eip += decode->len;
 642}
 643
 644static void exec_lods_single(struct CPUX86State *env, struct x86_decode *decode)
 645{
 646    target_ulong addr;
 647    target_ulong val = 0;
 648
 649    addr = decode_linear_addr(env, decode, RSI(env), R_DS);
 650    vmx_read_mem(env_cpu(env), &val, addr,  decode->operand_size);
 651    write_reg(env, R_EAX, val, decode->operand_size);
 652
 653    string_increment_reg(env, R_ESI, decode);
 654}
 655
 656static void exec_lods(struct CPUX86State *env, struct x86_decode *decode)
 657{
 658    if (decode->rep) {
 659        string_rep(env, decode, exec_lods_single, 0);
 660    } else {
 661        exec_lods_single(env, decode);
 662    }
 663
 664    env->eip += decode->len;
 665}
 666
 667void simulate_rdmsr(struct CPUState *cpu)
 668{
 669    X86CPU *x86_cpu = X86_CPU(cpu);
 670    CPUX86State *env = &x86_cpu->env;
 671    CPUState *cs = env_cpu(env);
 672    uint32_t msr = ECX(env);
 673    uint64_t val = 0;
 674
 675    switch (msr) {
 676    case MSR_IA32_TSC:
 677        val = rdtscp() + rvmcs(cpu->hvf->fd, VMCS_TSC_OFFSET);
 678        break;
 679    case MSR_IA32_APICBASE:
 680        val = cpu_get_apic_base(X86_CPU(cpu)->apic_state);
 681        break;
 682    case MSR_IA32_UCODE_REV:
 683        val = x86_cpu->ucode_rev;
 684        break;
 685    case MSR_EFER:
 686        val = rvmcs(cpu->hvf->fd, VMCS_GUEST_IA32_EFER);
 687        break;
 688    case MSR_FSBASE:
 689        val = rvmcs(cpu->hvf->fd, VMCS_GUEST_FS_BASE);
 690        break;
 691    case MSR_GSBASE:
 692        val = rvmcs(cpu->hvf->fd, VMCS_GUEST_GS_BASE);
 693        break;
 694    case MSR_KERNELGSBASE:
 695        val = rvmcs(cpu->hvf->fd, VMCS_HOST_FS_BASE);
 696        break;
 697    case MSR_STAR:
 698        abort();
 699        break;
 700    case MSR_LSTAR:
 701        abort();
 702        break;
 703    case MSR_CSTAR:
 704        abort();
 705        break;
 706    case MSR_IA32_MISC_ENABLE:
 707        val = env->msr_ia32_misc_enable;
 708        break;
 709    case MSR_MTRRphysBase(0):
 710    case MSR_MTRRphysBase(1):
 711    case MSR_MTRRphysBase(2):
 712    case MSR_MTRRphysBase(3):
 713    case MSR_MTRRphysBase(4):
 714    case MSR_MTRRphysBase(5):
 715    case MSR_MTRRphysBase(6):
 716    case MSR_MTRRphysBase(7):
 717        val = env->mtrr_var[(ECX(env) - MSR_MTRRphysBase(0)) / 2].base;
 718        break;
 719    case MSR_MTRRphysMask(0):
 720    case MSR_MTRRphysMask(1):
 721    case MSR_MTRRphysMask(2):
 722    case MSR_MTRRphysMask(3):
 723    case MSR_MTRRphysMask(4):
 724    case MSR_MTRRphysMask(5):
 725    case MSR_MTRRphysMask(6):
 726    case MSR_MTRRphysMask(7):
 727        val = env->mtrr_var[(ECX(env) - MSR_MTRRphysMask(0)) / 2].mask;
 728        break;
 729    case MSR_MTRRfix64K_00000:
 730        val = env->mtrr_fixed[0];
 731        break;
 732    case MSR_MTRRfix16K_80000:
 733    case MSR_MTRRfix16K_A0000:
 734        val = env->mtrr_fixed[ECX(env) - MSR_MTRRfix16K_80000 + 1];
 735        break;
 736    case MSR_MTRRfix4K_C0000:
 737    case MSR_MTRRfix4K_C8000:
 738    case MSR_MTRRfix4K_D0000:
 739    case MSR_MTRRfix4K_D8000:
 740    case MSR_MTRRfix4K_E0000:
 741    case MSR_MTRRfix4K_E8000:
 742    case MSR_MTRRfix4K_F0000:
 743    case MSR_MTRRfix4K_F8000:
 744        val = env->mtrr_fixed[ECX(env) - MSR_MTRRfix4K_C0000 + 3];
 745        break;
 746    case MSR_MTRRdefType:
 747        val = env->mtrr_deftype;
 748        break;
 749    case MSR_CORE_THREAD_COUNT:
 750        val = cs->nr_threads * cs->nr_cores; /* thread count, bits 15..0 */
 751        val |= ((uint32_t)cs->nr_cores << 16); /* core count, bits 31..16 */
 752        break;
 753    default:
 754        /* fprintf(stderr, "%s: unknown msr 0x%x\n", __func__, msr); */
 755        val = 0;
 756        break;
 757    }
 758
 759    RAX(env) = (uint32_t)val;
 760    RDX(env) = (uint32_t)(val >> 32);
 761}
 762
 763static void exec_rdmsr(struct CPUX86State *env, struct x86_decode *decode)
 764{
 765    simulate_rdmsr(env_cpu(env));
 766    env->eip += decode->len;
 767}
 768
 769void simulate_wrmsr(struct CPUState *cpu)
 770{
 771    X86CPU *x86_cpu = X86_CPU(cpu);
 772    CPUX86State *env = &x86_cpu->env;
 773    uint32_t msr = ECX(env);
 774    uint64_t data = ((uint64_t)EDX(env) << 32) | EAX(env);
 775
 776    switch (msr) {
 777    case MSR_IA32_TSC:
 778        break;
 779    case MSR_IA32_APICBASE:
 780        cpu_set_apic_base(X86_CPU(cpu)->apic_state, data);
 781        break;
 782    case MSR_FSBASE:
 783        wvmcs(cpu->hvf->fd, VMCS_GUEST_FS_BASE, data);
 784        break;
 785    case MSR_GSBASE:
 786        wvmcs(cpu->hvf->fd, VMCS_GUEST_GS_BASE, data);
 787        break;
 788    case MSR_KERNELGSBASE:
 789        wvmcs(cpu->hvf->fd, VMCS_HOST_FS_BASE, data);
 790        break;
 791    case MSR_STAR:
 792        abort();
 793        break;
 794    case MSR_LSTAR:
 795        abort();
 796        break;
 797    case MSR_CSTAR:
 798        abort();
 799        break;
 800    case MSR_EFER:
 801        /*printf("new efer %llx\n", EFER(cpu));*/
 802        wvmcs(cpu->hvf->fd, VMCS_GUEST_IA32_EFER, data);
 803        if (data & MSR_EFER_NXE) {
 804            hv_vcpu_invalidate_tlb(cpu->hvf->fd);
 805        }
 806        break;
 807    case MSR_MTRRphysBase(0):
 808    case MSR_MTRRphysBase(1):
 809    case MSR_MTRRphysBase(2):
 810    case MSR_MTRRphysBase(3):
 811    case MSR_MTRRphysBase(4):
 812    case MSR_MTRRphysBase(5):
 813    case MSR_MTRRphysBase(6):
 814    case MSR_MTRRphysBase(7):
 815        env->mtrr_var[(ECX(env) - MSR_MTRRphysBase(0)) / 2].base = data;
 816        break;
 817    case MSR_MTRRphysMask(0):
 818    case MSR_MTRRphysMask(1):
 819    case MSR_MTRRphysMask(2):
 820    case MSR_MTRRphysMask(3):
 821    case MSR_MTRRphysMask(4):
 822    case MSR_MTRRphysMask(5):
 823    case MSR_MTRRphysMask(6):
 824    case MSR_MTRRphysMask(7):
 825        env->mtrr_var[(ECX(env) - MSR_MTRRphysMask(0)) / 2].mask = data;
 826        break;
 827    case MSR_MTRRfix64K_00000:
 828        env->mtrr_fixed[ECX(env) - MSR_MTRRfix64K_00000] = data;
 829        break;
 830    case MSR_MTRRfix16K_80000:
 831    case MSR_MTRRfix16K_A0000:
 832        env->mtrr_fixed[ECX(env) - MSR_MTRRfix16K_80000 + 1] = data;
 833        break;
 834    case MSR_MTRRfix4K_C0000:
 835    case MSR_MTRRfix4K_C8000:
 836    case MSR_MTRRfix4K_D0000:
 837    case MSR_MTRRfix4K_D8000:
 838    case MSR_MTRRfix4K_E0000:
 839    case MSR_MTRRfix4K_E8000:
 840    case MSR_MTRRfix4K_F0000:
 841    case MSR_MTRRfix4K_F8000:
 842        env->mtrr_fixed[ECX(env) - MSR_MTRRfix4K_C0000 + 3] = data;
 843        break;
 844    case MSR_MTRRdefType:
 845        env->mtrr_deftype = data;
 846        break;
 847    default:
 848        break;
 849    }
 850
 851    /* Related to support known hypervisor interface */
 852    /* if (g_hypervisor_iface)
 853         g_hypervisor_iface->wrmsr_handler(cpu, msr, data);
 854
 855    printf("write msr %llx\n", RCX(cpu));*/
 856}
 857
 858static void exec_wrmsr(struct CPUX86State *env, struct x86_decode *decode)
 859{
 860    simulate_wrmsr(env_cpu(env));
 861    env->eip += decode->len;
 862}
 863
 864/*
 865 * flag:
 866 * 0 - bt, 1 - btc, 2 - bts, 3 - btr
 867 */
 868static void do_bt(struct CPUX86State *env, struct x86_decode *decode, int flag)
 869{
 870    int32_t displacement;
 871    uint8_t index;
 872    bool cf;
 873    int mask = (4 == decode->operand_size) ? 0x1f : 0xf;
 874
 875    VM_PANIC_ON(decode->rex.rex);
 876
 877    fetch_operands(env, decode, 2, false, true, false);
 878    index = decode->op[1].val & mask;
 879
 880    if (decode->op[0].type != X86_VAR_REG) {
 881        if (4 == decode->operand_size) {
 882            displacement = ((int32_t) (decode->op[1].val & 0xffffffe0)) / 32;
 883            decode->op[0].ptr += 4 * displacement;
 884        } else if (2 == decode->operand_size) {
 885            displacement = ((int16_t) (decode->op[1].val & 0xfff0)) / 16;
 886            decode->op[0].ptr += 2 * displacement;
 887        } else {
 888            VM_PANIC("bt 64bit\n");
 889        }
 890    }
 891    decode->op[0].val = read_val_ext(env, decode->op[0].ptr,
 892                                     decode->operand_size);
 893    cf = (decode->op[0].val >> index) & 0x01;
 894
 895    switch (flag) {
 896    case 0:
 897        set_CF(env, cf);
 898        return;
 899    case 1:
 900        decode->op[0].val ^= (1u << index);
 901        break;
 902    case 2:
 903        decode->op[0].val |= (1u << index);
 904        break;
 905    case 3:
 906        decode->op[0].val &= ~(1u << index);
 907        break;
 908    }
 909    write_val_ext(env, decode->op[0].ptr, decode->op[0].val,
 910                  decode->operand_size);
 911    set_CF(env, cf);
 912}
 913
 914static void exec_bt(struct CPUX86State *env, struct x86_decode *decode)
 915{
 916    do_bt(env, decode, 0);
 917    env->eip += decode->len;
 918}
 919
 920static void exec_btc(struct CPUX86State *env, struct x86_decode *decode)
 921{
 922    do_bt(env, decode, 1);
 923    env->eip += decode->len;
 924}
 925
 926static void exec_btr(struct CPUX86State *env, struct x86_decode *decode)
 927{
 928    do_bt(env, decode, 3);
 929    env->eip += decode->len;
 930}
 931
 932static void exec_bts(struct CPUX86State *env, struct x86_decode *decode)
 933{
 934    do_bt(env, decode, 2);
 935    env->eip += decode->len;
 936}
 937
 938void exec_shl(struct CPUX86State *env, struct x86_decode *decode)
 939{
 940    uint8_t count;
 941    int of = 0, cf = 0;
 942
 943    fetch_operands(env, decode, 2, true, true, false);
 944
 945    count = decode->op[1].val;
 946    count &= 0x1f;      /* count is masked to 5 bits*/
 947    if (!count) {
 948        goto exit;
 949    }
 950
 951    switch (decode->operand_size) {
 952    case 1:
 953    {
 954        uint8_t res = 0;
 955        if (count <= 8) {
 956            res = (decode->op[0].val << count);
 957            cf = (decode->op[0].val >> (8 - count)) & 0x1;
 958            of = cf ^ (res >> 7);
 959        }
 960
 961        write_val_ext(env, decode->op[0].ptr, res, 1);
 962        SET_FLAGS_OSZAPC_LOGIC8(env, 0, 0, res);
 963        SET_FLAGS_OxxxxC(env, of, cf);
 964        break;
 965    }
 966    case 2:
 967    {
 968        uint16_t res = 0;
 969
 970        /* from bochs */
 971        if (count <= 16) {
 972            res = (decode->op[0].val << count);
 973            cf = (decode->op[0].val >> (16 - count)) & 0x1;
 974            of = cf ^ (res >> 15); /* of = cf ^ result15 */
 975        }
 976
 977        write_val_ext(env, decode->op[0].ptr, res, 2);
 978        SET_FLAGS_OSZAPC_LOGIC16(env, 0, 0, res);
 979        SET_FLAGS_OxxxxC(env, of, cf);
 980        break;
 981    }
 982    case 4:
 983    {
 984        uint32_t res = decode->op[0].val << count;
 985
 986        write_val_ext(env, decode->op[0].ptr, res, 4);
 987        SET_FLAGS_OSZAPC_LOGIC32(env, 0, 0, res);
 988        cf = (decode->op[0].val >> (32 - count)) & 0x1;
 989        of = cf ^ (res >> 31); /* of = cf ^ result31 */
 990        SET_FLAGS_OxxxxC(env, of, cf);
 991        break;
 992    }
 993    default:
 994        abort();
 995    }
 996
 997exit:
 998    /* lflags_to_rflags(env); */
 999    env->eip += decode->len;
1000}

1001
1002void exec_movsx(CPUX86State *env, struct x86_decode *decode)
1003{
1004    int src_op_size;
1005    int op_size = decode->operand_size;
1006
1007    fetch_operands(env, decode, 2, false, false, false);
1008
1009    if (0xbe == decode->opcode[1]) {
1010        src_op_size = 1;
1011    } else {
1012        src_op_size = 2;
1013    }
1014
1015    decode->operand_size = src_op_size;
1016    calc_modrm_operand(env, decode, &decode->op[1]);
1017    decode->op[1].val = sign(read_val_ext(env, decode->op[1].ptr, src_op_size),
1018                             src_op_size);
1019
1020    write_val_ext(env, decode->op[0].ptr, decode->op[1].val, op_size);
1021
1022    env->eip += decode->len;
1023}
1024
1025void exec_ror(struct CPUX86State *env, struct x86_decode *decode)
1026{
1027    uint8_t count;
1028
1029    fetch_operands(env, decode, 2, true, true, false);
1030    count = decode->op[1].val;
1031
1032    switch (decode->operand_size) {
1033    case 1:
1034    {
1035        uint32_t bit6, bit7;
1036        uint8_t res;
1037
1038        if ((count & 0x07) == 0) {
1039            if (count & 0x18) {
1040                bit6 = ((uint8_t)decode->op[0].val >> 6) & 1;
1041                bit7 = ((uint8_t)decode->op[0].val >> 7) & 1;
1042                SET_FLAGS_OxxxxC(env, bit6 ^ bit7, bit7);
1043             }
1044        } else {
1045            count &= 0x7; /* use only bottom 3 bits */
1046            res = ((uint8_t)decode->op[0].val >> count) |
1047                   ((uint8_t)decode->op[0].val << (8 - count));
1048            write_val_ext(env, decode->op[0].ptr, res, 1);
1049            bit6 = (res >> 6) & 1;
1050            bit7 = (res >> 7) & 1;
1051            /* set eflags: ROR count affects the following flags: C, O */
1052            SET_FLAGS_OxxxxC(env, bit6 ^ bit7, bit7);
1053        }
1054        break;
1055    }
1056    case 2:
1057    {
1058        uint32_t bit14, bit15;
1059        uint16_t res;
1060
1061        if ((count & 0x0f) == 0) {
1062            if (count & 0x10) {
1063                bit14 = ((uint16_t)decode->op[0].val >> 14) & 1;
1064                bit15 = ((uint16_t)decode->op[0].val >> 15) & 1;
1065                /* of = result14 ^ result15 */
1066                SET_FLAGS_OxxxxC(env, bit14 ^ bit15, bit15);
1067            }
1068        } else {
1069            count &= 0x0f;  /* use only 4 LSB's */
1070            res = ((uint16_t)decode->op[0].val >> count) |
1071                   ((uint16_t)decode->op[0].val << (16 - count));
1072            write_val_ext(env, decode->op[0].ptr, res, 2);
1073
1074            bit14 = (res >> 14) & 1;
1075            bit15 = (res >> 15) & 1;
1076            /* of = result14 ^ result15 */
1077            SET_FLAGS_OxxxxC(env, bit14 ^ bit15, bit15);
1078        }
1079        break;
1080    }
1081    case 4:
1082    {
1083        uint32_t bit31, bit30;
1084        uint32_t res;
1085
1086        count &= 0x1f;
1087        if (count) {
1088            res = ((uint32_t)decode->op[0].val >> count) |
1089                   ((uint32_t)decode->op[0].val << (32 - count));
1090            write_val_ext(env, decode->op[0].ptr, res, 4);
1091
1092            bit31 = (res >> 31) & 1;
1093            bit30 = (res >> 30) & 1;
1094            /* of = result30 ^ result31 */
1095            SET_FLAGS_OxxxxC(env, bit30 ^ bit31, bit31);
1096        }
1097        break;
1098        }
1099    }
1100    env->eip += decode->len;
1101}
1102
1103void exec_rol(struct CPUX86State *env, struct x86_decode *decode)
1104{
1105    uint8_t count;
1106
1107    fetch_operands(env, decode, 2, true, true, false);
1108    count = decode->op[1].val;
1109
1110    switch (decode->operand_size) {
1111    case 1:
1112    {
1113        uint32_t bit0, bit7;
1114        uint8_t res;
1115
1116        if ((count & 0x07) == 0) {
1117            if (count & 0x18) {
1118                bit0 = ((uint8_t)decode->op[0].val & 1);
1119                bit7 = ((uint8_t)decode->op[0].val >> 7);
1120                SET_FLAGS_OxxxxC(env, bit0 ^ bit7, bit0);
1121            }
1122        }  else {
1123            count &= 0x7; /* use only lowest 3 bits */
1124            res = ((uint8_t)decode->op[0].val << count) |
1125                   ((uint8_t)decode->op[0].val >> (8 - count));
1126
1127            write_val_ext(env, decode->op[0].ptr, res, 1);
1128            /* set eflags:
1129             * ROL count affects the following flags: C, O
1130             */
1131            bit0 = (res &  1);
1132            bit7 = (res >> 7);
1133            SET_FLAGS_OxxxxC(env, bit0 ^ bit7, bit0);
1134        }
1135        break;
1136    }
1137    case 2:
1138    {
1139        uint32_t bit0, bit15;
1140        uint16_t res;
1141
1142        if ((count & 0x0f) == 0) {
1143            if (count & 0x10) {
1144                bit0  = ((uint16_t)decode->op[0].val & 0x1);
1145                bit15 = ((uint16_t)decode->op[0].val >> 15);
1146                /* of = cf ^ result15 */
1147                SET_FLAGS_OxxxxC(env, bit0 ^ bit15, bit0);
1148            }
1149        } else {
1150            count &= 0x0f; /* only use bottom 4 bits */
1151            res = ((uint16_t)decode->op[0].val << count) |
1152                   ((uint16_t)decode->op[0].val >> (16 - count));
1153
1154            write_val_ext(env, decode->op[0].ptr, res, 2);
1155            bit0  = (res & 0x1);
1156            bit15 = (res >> 15);
1157            /* of = cf ^ result15 */
1158            SET_FLAGS_OxxxxC(env, bit0 ^ bit15, bit0);
1159        }
1160        break;
1161    }
1162    case 4:
1163    {
1164        uint32_t bit0, bit31;
1165        uint32_t res;
1166
1167        count &= 0x1f;
1168        if (count) {
1169            res = ((uint32_t)decode->op[0].val << count) |
1170                   ((uint32_t)decode->op[0].val >> (32 - count));
1171
1172            write_val_ext(env, decode->op[0].ptr, res, 4);
1173            bit0  = (res & 0x1);
1174            bit31 = (res >> 31);
1175            /* of = cf ^ result31 */
1176            SET_FLAGS_OxxxxC(env, bit0 ^ bit31, bit0);
1177        }
1178        break;
1179        }
1180    }
1181    env->eip += decode->len;
1182}
1183
1184
1185void exec_rcl(struct CPUX86State *env, struct x86_decode *decode)
1186{
1187    uint8_t count;
1188    int of = 0, cf = 0;
1189
1190    fetch_operands(env, decode, 2, true, true, false);
1191    count = decode->op[1].val & 0x1f;
1192
1193    switch (decode->operand_size) {
1194    case 1:
1195    {
1196        uint8_t op1_8 = decode->op[0].val;
1197        uint8_t res;
1198        count %= 9;
1199        if (!count) {
1200            break;
1201        }
1202
1203        if (1 == count) {
1204            res = (op1_8 << 1) | get_CF(env);
1205        } else {
1206            res = (op1_8 << count) | (get_CF(env) << (count - 1)) |
1207                   (op1_8 >> (9 - count));
1208        }
1209
1210        write_val_ext(env, decode->op[0].ptr, res, 1);
1211
1212        cf = (op1_8 >> (8 - count)) & 0x01;
1213        of = cf ^ (res >> 7); /* of = cf ^ result7 */
1214        SET_FLAGS_OxxxxC(env, of, cf);
1215        break;
1216    }
1217    case 2:
1218    {
1219        uint16_t res;
1220        uint16_t op1_16 = decode->op[0].val;
1221
1222        count %= 17;
1223        if (!count) {
1224            break;
1225        }
1226
1227        if (1 == count) {
1228            res = (op1_16 << 1) | get_CF(env);
1229        } else if (count == 16) {
1230            res = (get_CF(env) << 15) | (op1_16 >> 1);
1231        } else { /* 2..15 */
1232            res = (op1_16 << count) | (get_CF(env) << (count - 1)) |
1233                   (op1_16 >> (17 - count));
1234        }
1235
1236        write_val_ext(env, decode->op[0].ptr, res, 2);
1237
1238        cf = (op1_16 >> (16 - count)) & 0x1;
1239        of = cf ^ (res >> 15); /* of = cf ^ result15 */
1240        SET_FLAGS_OxxxxC(env, of, cf);
1241        break;
1242    }
1243    case 4:
1244    {
1245        uint32_t res;
1246        uint32_t op1_32 = decode->op[0].val;
1247
1248        if (!count) {
1249            break;
1250        }
1251
1252        if (1 == count) {
1253            res = (op1_32 << 1) | get_CF(env);
1254        } else {
1255            res = (op1_32 << count) | (get_CF(env) << (count - 1)) |
1256                   (op1_32 >> (33 - count));
1257        }
1258
1259        write_val_ext(env, decode->op[0].ptr, res, 4);
1260
1261        cf = (op1_32 >> (32 - count)) & 0x1;
1262        of = cf ^ (res >> 31); /* of = cf ^ result31 */
1263        SET_FLAGS_OxxxxC(env, of, cf);
1264        break;
1265        }
1266    }
1267    env->eip += decode->len;
1268}
1269
1270void exec_rcr(struct CPUX86State *env, struct x86_decode *decode)
1271{
1272    uint8_t count;
1273    int of = 0, cf = 0;
1274
1275    fetch_operands(env, decode, 2, true, true, false);
1276    count = decode->op[1].val & 0x1f;
1277
1278    switch (decode->operand_size) {
1279    case 1:
1280    {
1281        uint8_t op1_8 = decode->op[0].val;
1282        uint8_t res;
1283
1284        count %= 9;
1285        if (!count) {
1286            break;
1287        }
1288        res = (op1_8 >> count) | (get_CF(env) << (8 - count)) |
1289               (op1_8 << (9 - count));
1290
1291        write_val_ext(env, decode->op[0].ptr, res, 1);
1292
1293        cf = (op1_8 >> (count - 1)) & 0x1;
1294        of = (((res << 1) ^ res) >> 7) & 0x1; /* of = result6 ^ result7 */
1295        SET_FLAGS_OxxxxC(env, of, cf);
1296        break;
1297    }
1298    case 2:
1299    {
1300        uint16_t op1_16 = decode->op[0].val;
1301        uint16_t res;
1302
1303        count %= 17;
1304        if (!count) {
1305            break;
1306        }
1307        res = (op1_16 >> count) | (get_CF(env) << (16 - count)) |
1308               (op1_16 << (17 - count));
1309
1310        write_val_ext(env, decode->op[0].ptr, res, 2);
1311
1312        cf = (op1_16 >> (count - 1)) & 0x1;
1313        of = ((uint16_t)((res << 1) ^ res) >> 15) & 0x1; /* of = result15 ^
1314                                                            result14 */
1315        SET_FLAGS_OxxxxC(env, of, cf);
1316        break;
1317    }
1318    case 4:
1319    {
1320        uint32_t res;
1321        uint32_t op1_32 = decode->op[0].val;
1322
1323        if (!count) {
1324            break;
1325        }
1326
1327        if (1 == count) {
1328            res = (op1_32 >> 1) | (get_CF(env) << 31);
1329        } else {
1330            res = (op1_32 >> count) | (get_CF(env) << (32 - count)) |
1331                   (op1_32 << (33 - count));
1332        }
1333
1334        write_val_ext(env, decode->op[0].ptr, res, 4);
1335
1336        cf = (op1_32 >> (count - 1)) & 0x1;
1337        of = ((res << 1) ^ res) >> 31; /* of = result30 ^ result31 */
1338        SET_FLAGS_OxxxxC(env, of, cf);
1339        break;
1340        }
1341    }
1342    env->eip += decode->len;
1343}
1344
1345static void exec_xchg(struct CPUX86State *env, struct x86_decode *decode)
1346{
1347    fetch_operands(env, decode, 2, true, true, false);
1348
1349    write_val_ext(env, decode->op[0].ptr, decode->op[1].val,
1350                  decode->operand_size);
1351    write_val_ext(env, decode->op[1].ptr, decode->op[0].val,
1352                  decode->operand_size);
1353
1354    env->eip += decode->len;
1355}
1356
1357static void exec_xadd(struct CPUX86State *env, struct x86_decode *decode)
1358{
1359    EXEC_2OP_FLAGS_CMD(env, decode, +, SET_FLAGS_OSZAPC_ADD, true);
1360    write_val_ext(env, decode->op[1].ptr, decode->op[0].val,
1361                  decode->operand_size);
1362
1363    env->eip += decode->len;
1364}
1365
1366static struct cmd_handler {
1367    enum x86_decode_cmd cmd;
1368    void (*handler)(struct CPUX86State *env, struct x86_decode *ins);
1369} handlers[] = {
1370    {X86_DECODE_CMD_INVL, NULL,},
1371    {X86_DECODE_CMD_MOV, exec_mov},
1372    {X86_DECODE_CMD_ADD, exec_add},
1373    {X86_DECODE_CMD_OR, exec_or},
1374    {X86_DECODE_CMD_ADC, exec_adc},
1375    {X86_DECODE_CMD_SBB, exec_sbb},
1376    {X86_DECODE_CMD_AND, exec_and},
1377    {X86_DECODE_CMD_SUB, exec_sub},
1378    {X86_DECODE_CMD_NEG, exec_neg},
1379    {X86_DECODE_CMD_XOR, exec_xor},
1380    {X86_DECODE_CMD_CMP, exec_cmp},
1381    {X86_DECODE_CMD_INC, exec_inc},
1382    {X86_DECODE_CMD_DEC, exec_dec},
1383    {X86_DECODE_CMD_TST, exec_tst},
1384    {X86_DECODE_CMD_NOT, exec_not},
1385    {X86_DECODE_CMD_MOVZX, exec_movzx},
1386    {X86_DECODE_CMD_OUT, exec_out},
1387    {X86_DECODE_CMD_IN, exec_in},
1388    {X86_DECODE_CMD_INS, exec_ins},
1389    {X86_DECODE_CMD_OUTS, exec_outs},
1390    {X86_DECODE_CMD_RDMSR, exec_rdmsr},
1391    {X86_DECODE_CMD_WRMSR, exec_wrmsr},
1392    {X86_DECODE_CMD_BT, exec_bt},
1393    {X86_DECODE_CMD_BTR, exec_btr},
1394    {X86_DECODE_CMD_BTC, exec_btc},
1395    {X86_DECODE_CMD_BTS, exec_bts},
1396    {X86_DECODE_CMD_SHL, exec_shl},
1397    {X86_DECODE_CMD_ROL, exec_rol},
1398    {X86_DECODE_CMD_ROR, exec_ror},
1399    {X86_DECODE_CMD_RCR, exec_rcr},
1400    {X86_DECODE_CMD_RCL, exec_rcl},
1401    /*{X86_DECODE_CMD_CPUID, exec_cpuid},*/
1402    {X86_DECODE_CMD_MOVS, exec_movs},
1403    {X86_DECODE_CMD_CMPS, exec_cmps},
1404    {X86_DECODE_CMD_STOS, exec_stos},
1405    {X86_DECODE_CMD_SCAS, exec_scas},
1406    {X86_DECODE_CMD_LODS, exec_lods},
1407    {X86_DECODE_CMD_MOVSX, exec_movsx},
1408    {X86_DECODE_CMD_XCHG, exec_xchg},
1409    {X86_DECODE_CMD_XADD, exec_xadd},
1410};
1411
1412static struct cmd_handler _cmd_handler[X86_DECODE_CMD_LAST];
1413
1414static void init_cmd_handler()
1415{
1416    int i;
1417    for (i = 0; i < ARRAY_SIZE(handlers); i++) {
1418        _cmd_handler[handlers[i].cmd] = handlers[i];
1419    }
1420}
1421
1422void load_regs(struct CPUState *cpu)
1423{
1424    X86CPU *x86_cpu = X86_CPU(cpu);
1425    CPUX86State *env = &x86_cpu->env;
1426
1427    int i = 0;
1428    RRX(env, R_EAX) = rreg(cpu->hvf->fd, HV_X86_RAX);
1429    RRX(env, R_EBX) = rreg(cpu->hvf->fd, HV_X86_RBX);
1430    RRX(env, R_ECX) = rreg(cpu->hvf->fd, HV_X86_RCX);
1431    RRX(env, R_EDX) = rreg(cpu->hvf->fd, HV_X86_RDX);
1432    RRX(env, R_ESI) = rreg(cpu->hvf->fd, HV_X86_RSI);
1433    RRX(env, R_EDI) = rreg(cpu->hvf->fd, HV_X86_RDI);
1434    RRX(env, R_ESP) = rreg(cpu->hvf->fd, HV_X86_RSP);
1435    RRX(env, R_EBP) = rreg(cpu->hvf->fd, HV_X86_RBP);
1436    for (i = 8; i < 16; i++) {
1437        RRX(env, i) = rreg(cpu->hvf->fd, HV_X86_RAX + i);
1438    }
1439
1440    env->eflags = rreg(cpu->hvf->fd, HV_X86_RFLAGS);
1441    rflags_to_lflags(env);
1442    env->eip = rreg(cpu->hvf->fd, HV_X86_RIP);
1443}
1444
1445void store_regs(struct CPUState *cpu)
1446{
1447    X86CPU *x86_cpu = X86_CPU(cpu);
1448    CPUX86State *env = &x86_cpu->env;
1449
1450    int i = 0;
1451    wreg(cpu->hvf->fd, HV_X86_RAX, RAX(env));
1452    wreg(cpu->hvf->fd, HV_X86_RBX, RBX(env));
1453    wreg(cpu->hvf->fd, HV_X86_RCX, RCX(env));
1454    wreg(cpu->hvf->fd, HV_X86_RDX, RDX(env));
1455    wreg(cpu->hvf->fd, HV_X86_RSI, RSI(env));
1456    wreg(cpu->hvf->fd, HV_X86_RDI, RDI(env));
1457    wreg(cpu->hvf->fd, HV_X86_RBP, RBP(env));
1458    wreg(cpu->hvf->fd, HV_X86_RSP, RSP(env));
1459    for (i = 8; i < 16; i++) {
1460        wreg(cpu->hvf->fd, HV_X86_RAX + i, RRX(env, i));
1461    }
1462
1463    lflags_to_rflags(env);
1464    wreg(cpu->hvf->fd, HV_X86_RFLAGS, env->eflags);
1465    macvm_set_rip(cpu, env->eip);
1466}
1467
1468bool exec_instruction(struct CPUX86State *env, struct x86_decode *ins)
1469{
1470    /*if (hvf_vcpu_id(cpu))
1471    printf("%d, %llx: exec_instruction %s\n", hvf_vcpu_id(cpu),  env->eip,
1472          decode_cmd_to_string(ins->cmd));*/
1473
1474    if (!_cmd_handler[ins->cmd].handler) {
1475        printf("Unimplemented handler (%llx) for %d (%x %x) \n", env->eip,
1476                ins->cmd, ins->opcode[0],
1477                ins->opcode_len > 1 ? ins->opcode[1] : 0);
1478        env->eip += ins->len;
1479        return true;
1480    }
1481
1482    _cmd_handler[ins->cmd].handler(env, ins);
1483    return true;
1484}
1485
1486void init_emu()
1487{
1488    init_cmd_handler();
1489}
1490
Hosted by Missing Link Electronics. The original LXR software by the LXR community, this experimental version by lxr@linux.no.