VirtualBox

source: vbox/trunk/src/VBox/VMM/VMMAll/IEMAllInstructions.cpp.h@ 84823

Last change on this file since 84823 was 82968, checked in by vboxsync, 5 years ago

Copyright year updates by scm.

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1/* $Id: IEMAllInstructions.cpp.h 82968 2020-02-04 10:35:17Z vboxsync $ */
2/** @file
3 * IEM - Instruction Decoding and Emulation.
4 */
5
6/*
7 * Copyright (C) 2011-2020 Oracle Corporation
8 *
9 * This file is part of VirtualBox Open Source Edition (OSE), as
10 * available from http://www.virtualbox.org. This file is free software;
11 * you can redistribute it and/or modify it under the terms of the GNU
12 * General Public License (GPL) as published by the Free Software
13 * Foundation, in version 2 as it comes in the "COPYING" file of the
14 * VirtualBox OSE distribution. VirtualBox OSE is distributed in the
15 * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind.
16 */
17
18
19/*******************************************************************************
20* Global Variables *
21*******************************************************************************/
22extern const PFNIEMOP g_apfnOneByteMap[256]; /* not static since we need to forward declare it. */
23
24#ifdef _MSC_VER
25# pragma warning(push)
26# pragma warning(disable: 4702) /* Unreachable code like return in iemOp_Grp6_lldt. */
27#endif
28
29
30/**
31 * Common worker for instructions like ADD, AND, OR, ++ with a byte
32 * memory/register as the destination.
33 *
34 * @param pImpl Pointer to the instruction implementation (assembly).
35 */
36FNIEMOP_DEF_1(iemOpHlpBinaryOperator_rm_r8, PCIEMOPBINSIZES, pImpl)
37{
38 uint8_t bRm; IEM_OPCODE_GET_NEXT_U8(&bRm);
39
40 /*
41 * If rm is denoting a register, no more instruction bytes.
42 */
43 if ((bRm & X86_MODRM_MOD_MASK) == (3 << X86_MODRM_MOD_SHIFT))
44 {
45 IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX();
46
47 IEM_MC_BEGIN(3, 0);
48 IEM_MC_ARG(uint8_t *, pu8Dst, 0);
49 IEM_MC_ARG(uint8_t, u8Src, 1);
50 IEM_MC_ARG(uint32_t *, pEFlags, 2);
51
52 IEM_MC_FETCH_GREG_U8(u8Src, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg);
53 IEM_MC_REF_GREG_U8(pu8Dst, (bRm & X86_MODRM_RM_MASK) | pVCpu->iem.s.uRexB);
54 IEM_MC_REF_EFLAGS(pEFlags);
55 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU8, pu8Dst, u8Src, pEFlags);
56
57 IEM_MC_ADVANCE_RIP();
58 IEM_MC_END();
59 }
60 else
61 {
62 /*
63 * We're accessing memory.
64 * Note! We're putting the eflags on the stack here so we can commit them
65 * after the memory.
66 */
67 uint32_t const fAccess = pImpl->pfnLockedU8 ? IEM_ACCESS_DATA_RW : IEM_ACCESS_DATA_R; /* CMP,TEST */
68 IEM_MC_BEGIN(3, 2);
69 IEM_MC_ARG(uint8_t *, pu8Dst, 0);
70 IEM_MC_ARG(uint8_t, u8Src, 1);
71 IEM_MC_ARG_LOCAL_EFLAGS(pEFlags, EFlags, 2);
72 IEM_MC_LOCAL(RTGCPTR, GCPtrEffDst);
73
74 IEM_MC_CALC_RM_EFF_ADDR(GCPtrEffDst, bRm, 0);
75 if (!pImpl->pfnLockedU8)
76 IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX();
77 IEM_MC_MEM_MAP(pu8Dst, fAccess, pVCpu->iem.s.iEffSeg, GCPtrEffDst, 0 /*arg*/);
78 IEM_MC_FETCH_GREG_U8(u8Src, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg);
79 IEM_MC_FETCH_EFLAGS(EFlags);
80 if (!(pVCpu->iem.s.fPrefixes & IEM_OP_PRF_LOCK))
81 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU8, pu8Dst, u8Src, pEFlags);
82 else
83 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnLockedU8, pu8Dst, u8Src, pEFlags);
84
85 IEM_MC_MEM_COMMIT_AND_UNMAP(pu8Dst, fAccess);
86 IEM_MC_COMMIT_EFLAGS(EFlags);
87 IEM_MC_ADVANCE_RIP();
88 IEM_MC_END();
89 }
90 return VINF_SUCCESS;
91}
92
93
94/**
95 * Common worker for word/dword/qword instructions like ADD, AND, OR, ++ with
96 * memory/register as the destination.
97 *
98 * @param pImpl Pointer to the instruction implementation (assembly).
99 */
100FNIEMOP_DEF_1(iemOpHlpBinaryOperator_rm_rv, PCIEMOPBINSIZES, pImpl)
101{
102 uint8_t bRm; IEM_OPCODE_GET_NEXT_U8(&bRm);
103
104 /*
105 * If rm is denoting a register, no more instruction bytes.
106 */
107 if ((bRm & X86_MODRM_MOD_MASK) == (3 << X86_MODRM_MOD_SHIFT))
108 {
109 IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX();
110
111 switch (pVCpu->iem.s.enmEffOpSize)
112 {
113 case IEMMODE_16BIT:
114 IEM_MC_BEGIN(3, 0);
115 IEM_MC_ARG(uint16_t *, pu16Dst, 0);
116 IEM_MC_ARG(uint16_t, u16Src, 1);
117 IEM_MC_ARG(uint32_t *, pEFlags, 2);
118
119 IEM_MC_FETCH_GREG_U16(u16Src, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg);
120 IEM_MC_REF_GREG_U16(pu16Dst, (bRm & X86_MODRM_RM_MASK) | pVCpu->iem.s.uRexB);
121 IEM_MC_REF_EFLAGS(pEFlags);
122 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU16, pu16Dst, u16Src, pEFlags);
123
124 IEM_MC_ADVANCE_RIP();
125 IEM_MC_END();
126 break;
127
128 case IEMMODE_32BIT:
129 IEM_MC_BEGIN(3, 0);
130 IEM_MC_ARG(uint32_t *, pu32Dst, 0);
131 IEM_MC_ARG(uint32_t, u32Src, 1);
132 IEM_MC_ARG(uint32_t *, pEFlags, 2);
133
134 IEM_MC_FETCH_GREG_U32(u32Src, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg);
135 IEM_MC_REF_GREG_U32(pu32Dst, (bRm & X86_MODRM_RM_MASK) | pVCpu->iem.s.uRexB);
136 IEM_MC_REF_EFLAGS(pEFlags);
137 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU32, pu32Dst, u32Src, pEFlags);
138
139 if (pImpl != &g_iemAImpl_test)
140 IEM_MC_CLEAR_HIGH_GREG_U64_BY_REF(pu32Dst);
141 IEM_MC_ADVANCE_RIP();
142 IEM_MC_END();
143 break;
144
145 case IEMMODE_64BIT:
146 IEM_MC_BEGIN(3, 0);
147 IEM_MC_ARG(uint64_t *, pu64Dst, 0);
148 IEM_MC_ARG(uint64_t, u64Src, 1);
149 IEM_MC_ARG(uint32_t *, pEFlags, 2);
150
151 IEM_MC_FETCH_GREG_U64(u64Src, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg);
152 IEM_MC_REF_GREG_U64(pu64Dst, (bRm & X86_MODRM_RM_MASK) | pVCpu->iem.s.uRexB);
153 IEM_MC_REF_EFLAGS(pEFlags);
154 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU64, pu64Dst, u64Src, pEFlags);
155
156 IEM_MC_ADVANCE_RIP();
157 IEM_MC_END();
158 break;
159 }
160 }
161 else
162 {
163 /*
164 * We're accessing memory.
165 * Note! We're putting the eflags on the stack here so we can commit them
166 * after the memory.
167 */
168 uint32_t const fAccess = pImpl->pfnLockedU8 ? IEM_ACCESS_DATA_RW : IEM_ACCESS_DATA_R /* CMP,TEST */;
169 switch (pVCpu->iem.s.enmEffOpSize)
170 {
171 case IEMMODE_16BIT:
172 IEM_MC_BEGIN(3, 2);
173 IEM_MC_ARG(uint16_t *, pu16Dst, 0);
174 IEM_MC_ARG(uint16_t, u16Src, 1);
175 IEM_MC_ARG_LOCAL_EFLAGS(pEFlags, EFlags, 2);
176 IEM_MC_LOCAL(RTGCPTR, GCPtrEffDst);
177
178 IEM_MC_CALC_RM_EFF_ADDR(GCPtrEffDst, bRm, 0);
179 if (!pImpl->pfnLockedU16)
180 IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX();
181 IEM_MC_MEM_MAP(pu16Dst, fAccess, pVCpu->iem.s.iEffSeg, GCPtrEffDst, 0 /*arg*/);
182 IEM_MC_FETCH_GREG_U16(u16Src, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg);
183 IEM_MC_FETCH_EFLAGS(EFlags);
184 if (!(pVCpu->iem.s.fPrefixes & IEM_OP_PRF_LOCK))
185 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU16, pu16Dst, u16Src, pEFlags);
186 else
187 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnLockedU16, pu16Dst, u16Src, pEFlags);
188
189 IEM_MC_MEM_COMMIT_AND_UNMAP(pu16Dst, fAccess);
190 IEM_MC_COMMIT_EFLAGS(EFlags);
191 IEM_MC_ADVANCE_RIP();
192 IEM_MC_END();
193 break;
194
195 case IEMMODE_32BIT:
196 IEM_MC_BEGIN(3, 2);
197 IEM_MC_ARG(uint32_t *, pu32Dst, 0);
198 IEM_MC_ARG(uint32_t, u32Src, 1);
199 IEM_MC_ARG_LOCAL_EFLAGS(pEFlags, EFlags, 2);
200 IEM_MC_LOCAL(RTGCPTR, GCPtrEffDst);
201
202 IEM_MC_CALC_RM_EFF_ADDR(GCPtrEffDst, bRm, 0);
203 if (!pImpl->pfnLockedU32)
204 IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX();
205 IEM_MC_MEM_MAP(pu32Dst, fAccess, pVCpu->iem.s.iEffSeg, GCPtrEffDst, 0 /*arg*/);
206 IEM_MC_FETCH_GREG_U32(u32Src, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg);
207 IEM_MC_FETCH_EFLAGS(EFlags);
208 if (!(pVCpu->iem.s.fPrefixes & IEM_OP_PRF_LOCK))
209 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU32, pu32Dst, u32Src, pEFlags);
210 else
211 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnLockedU32, pu32Dst, u32Src, pEFlags);
212
213 IEM_MC_MEM_COMMIT_AND_UNMAP(pu32Dst, fAccess);
214 IEM_MC_COMMIT_EFLAGS(EFlags);
215 IEM_MC_ADVANCE_RIP();
216 IEM_MC_END();
217 break;
218
219 case IEMMODE_64BIT:
220 IEM_MC_BEGIN(3, 2);
221 IEM_MC_ARG(uint64_t *, pu64Dst, 0);
222 IEM_MC_ARG(uint64_t, u64Src, 1);
223 IEM_MC_ARG_LOCAL_EFLAGS(pEFlags, EFlags, 2);
224 IEM_MC_LOCAL(RTGCPTR, GCPtrEffDst);
225
226 IEM_MC_CALC_RM_EFF_ADDR(GCPtrEffDst, bRm, 0);
227 if (!pImpl->pfnLockedU64)
228 IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX();
229 IEM_MC_MEM_MAP(pu64Dst, fAccess, pVCpu->iem.s.iEffSeg, GCPtrEffDst, 0 /*arg*/);
230 IEM_MC_FETCH_GREG_U64(u64Src, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg);
231 IEM_MC_FETCH_EFLAGS(EFlags);
232 if (!(pVCpu->iem.s.fPrefixes & IEM_OP_PRF_LOCK))
233 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU64, pu64Dst, u64Src, pEFlags);
234 else
235 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnLockedU64, pu64Dst, u64Src, pEFlags);
236
237 IEM_MC_MEM_COMMIT_AND_UNMAP(pu64Dst, fAccess);
238 IEM_MC_COMMIT_EFLAGS(EFlags);
239 IEM_MC_ADVANCE_RIP();
240 IEM_MC_END();
241 break;
242 }
243 }
244 return VINF_SUCCESS;
245}
246
247
248/**
249 * Common worker for byte instructions like ADD, AND, OR, ++ with a register as
250 * the destination.
251 *
252 * @param pImpl Pointer to the instruction implementation (assembly).
253 */
254FNIEMOP_DEF_1(iemOpHlpBinaryOperator_r8_rm, PCIEMOPBINSIZES, pImpl)
255{
256 uint8_t bRm; IEM_OPCODE_GET_NEXT_U8(&bRm);
257
258 /*
259 * If rm is denoting a register, no more instruction bytes.
260 */
261 if ((bRm & X86_MODRM_MOD_MASK) == (3 << X86_MODRM_MOD_SHIFT))
262 {
263 IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX();
264 IEM_MC_BEGIN(3, 0);
265 IEM_MC_ARG(uint8_t *, pu8Dst, 0);
266 IEM_MC_ARG(uint8_t, u8Src, 1);
267 IEM_MC_ARG(uint32_t *, pEFlags, 2);
268
269 IEM_MC_FETCH_GREG_U8(u8Src, (bRm & X86_MODRM_RM_MASK) | pVCpu->iem.s.uRexB);
270 IEM_MC_REF_GREG_U8(pu8Dst, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg);
271 IEM_MC_REF_EFLAGS(pEFlags);
272 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU8, pu8Dst, u8Src, pEFlags);
273
274 IEM_MC_ADVANCE_RIP();
275 IEM_MC_END();
276 }
277 else
278 {
279 /*
280 * We're accessing memory.
281 */
282 IEM_MC_BEGIN(3, 1);
283 IEM_MC_ARG(uint8_t *, pu8Dst, 0);
284 IEM_MC_ARG(uint8_t, u8Src, 1);
285 IEM_MC_ARG(uint32_t *, pEFlags, 2);
286 IEM_MC_LOCAL(RTGCPTR, GCPtrEffDst);
287
288 IEM_MC_CALC_RM_EFF_ADDR(GCPtrEffDst, bRm, 0);
289 IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX();
290 IEM_MC_FETCH_MEM_U8(u8Src, pVCpu->iem.s.iEffSeg, GCPtrEffDst);
291 IEM_MC_REF_GREG_U8(pu8Dst, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg);
292 IEM_MC_REF_EFLAGS(pEFlags);
293 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU8, pu8Dst, u8Src, pEFlags);
294
295 IEM_MC_ADVANCE_RIP();
296 IEM_MC_END();
297 }
298 return VINF_SUCCESS;
299}
300
301
302/**
303 * Common worker for word/dword/qword instructions like ADD, AND, OR, ++ with a
304 * register as the destination.
305 *
306 * @param pImpl Pointer to the instruction implementation (assembly).
307 */
308FNIEMOP_DEF_1(iemOpHlpBinaryOperator_rv_rm, PCIEMOPBINSIZES, pImpl)
309{
310 uint8_t bRm; IEM_OPCODE_GET_NEXT_U8(&bRm);
311
312 /*
313 * If rm is denoting a register, no more instruction bytes.
314 */
315 if ((bRm & X86_MODRM_MOD_MASK) == (3 << X86_MODRM_MOD_SHIFT))
316 {
317 IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX();
318 switch (pVCpu->iem.s.enmEffOpSize)
319 {
320 case IEMMODE_16BIT:
321 IEM_MC_BEGIN(3, 0);
322 IEM_MC_ARG(uint16_t *, pu16Dst, 0);
323 IEM_MC_ARG(uint16_t, u16Src, 1);
324 IEM_MC_ARG(uint32_t *, pEFlags, 2);
325
326 IEM_MC_FETCH_GREG_U16(u16Src, (bRm & X86_MODRM_RM_MASK) | pVCpu->iem.s.uRexB);
327 IEM_MC_REF_GREG_U16(pu16Dst, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg);
328 IEM_MC_REF_EFLAGS(pEFlags);
329 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU16, pu16Dst, u16Src, pEFlags);
330
331 IEM_MC_ADVANCE_RIP();
332 IEM_MC_END();
333 break;
334
335 case IEMMODE_32BIT:
336 IEM_MC_BEGIN(3, 0);
337 IEM_MC_ARG(uint32_t *, pu32Dst, 0);
338 IEM_MC_ARG(uint32_t, u32Src, 1);
339 IEM_MC_ARG(uint32_t *, pEFlags, 2);
340
341 IEM_MC_FETCH_GREG_U32(u32Src, (bRm & X86_MODRM_RM_MASK) | pVCpu->iem.s.uRexB);
342 IEM_MC_REF_GREG_U32(pu32Dst, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg);
343 IEM_MC_REF_EFLAGS(pEFlags);
344 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU32, pu32Dst, u32Src, pEFlags);
345
346 IEM_MC_CLEAR_HIGH_GREG_U64_BY_REF(pu32Dst);
347 IEM_MC_ADVANCE_RIP();
348 IEM_MC_END();
349 break;
350
351 case IEMMODE_64BIT:
352 IEM_MC_BEGIN(3, 0);
353 IEM_MC_ARG(uint64_t *, pu64Dst, 0);
354 IEM_MC_ARG(uint64_t, u64Src, 1);
355 IEM_MC_ARG(uint32_t *, pEFlags, 2);
356
357 IEM_MC_FETCH_GREG_U64(u64Src, (bRm & X86_MODRM_RM_MASK) | pVCpu->iem.s.uRexB);
358 IEM_MC_REF_GREG_U64(pu64Dst, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg);
359 IEM_MC_REF_EFLAGS(pEFlags);
360 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU64, pu64Dst, u64Src, pEFlags);
361
362 IEM_MC_ADVANCE_RIP();
363 IEM_MC_END();
364 break;
365 }
366 }
367 else
368 {
369 /*
370 * We're accessing memory.
371 */
372 switch (pVCpu->iem.s.enmEffOpSize)
373 {
374 case IEMMODE_16BIT:
375 IEM_MC_BEGIN(3, 1);
376 IEM_MC_ARG(uint16_t *, pu16Dst, 0);
377 IEM_MC_ARG(uint16_t, u16Src, 1);
378 IEM_MC_ARG(uint32_t *, pEFlags, 2);
379 IEM_MC_LOCAL(RTGCPTR, GCPtrEffDst);
380
381 IEM_MC_CALC_RM_EFF_ADDR(GCPtrEffDst, bRm, 0);
382 IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX();
383 IEM_MC_FETCH_MEM_U16(u16Src, pVCpu->iem.s.iEffSeg, GCPtrEffDst);
384 IEM_MC_REF_GREG_U16(pu16Dst, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg);
385 IEM_MC_REF_EFLAGS(pEFlags);
386 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU16, pu16Dst, u16Src, pEFlags);
387
388 IEM_MC_ADVANCE_RIP();
389 IEM_MC_END();
390 break;
391
392 case IEMMODE_32BIT:
393 IEM_MC_BEGIN(3, 1);
394 IEM_MC_ARG(uint32_t *, pu32Dst, 0);
395 IEM_MC_ARG(uint32_t, u32Src, 1);
396 IEM_MC_ARG(uint32_t *, pEFlags, 2);
397 IEM_MC_LOCAL(RTGCPTR, GCPtrEffDst);
398
399 IEM_MC_CALC_RM_EFF_ADDR(GCPtrEffDst, bRm, 0);
400 IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX();
401 IEM_MC_FETCH_MEM_U32(u32Src, pVCpu->iem.s.iEffSeg, GCPtrEffDst);
402 IEM_MC_REF_GREG_U32(pu32Dst, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg);
403 IEM_MC_REF_EFLAGS(pEFlags);
404 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU32, pu32Dst, u32Src, pEFlags);
405
406 IEM_MC_CLEAR_HIGH_GREG_U64_BY_REF(pu32Dst);
407 IEM_MC_ADVANCE_RIP();
408 IEM_MC_END();
409 break;
410
411 case IEMMODE_64BIT:
412 IEM_MC_BEGIN(3, 1);
413 IEM_MC_ARG(uint64_t *, pu64Dst, 0);
414 IEM_MC_ARG(uint64_t, u64Src, 1);
415 IEM_MC_ARG(uint32_t *, pEFlags, 2);
416 IEM_MC_LOCAL(RTGCPTR, GCPtrEffDst);
417
418 IEM_MC_CALC_RM_EFF_ADDR(GCPtrEffDst, bRm, 0);
419 IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX();
420 IEM_MC_FETCH_MEM_U64(u64Src, pVCpu->iem.s.iEffSeg, GCPtrEffDst);
421 IEM_MC_REF_GREG_U64(pu64Dst, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg);
422 IEM_MC_REF_EFLAGS(pEFlags);
423 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU64, pu64Dst, u64Src, pEFlags);
424
425 IEM_MC_ADVANCE_RIP();
426 IEM_MC_END();
427 break;
428 }
429 }
430 return VINF_SUCCESS;
431}
432
433
434/**
435 * Common worker for instructions like ADD, AND, OR, ++ with working on AL with
436 * a byte immediate.
437 *
438 * @param pImpl Pointer to the instruction implementation (assembly).
439 */
440FNIEMOP_DEF_1(iemOpHlpBinaryOperator_AL_Ib, PCIEMOPBINSIZES, pImpl)
441{
442 uint8_t u8Imm; IEM_OPCODE_GET_NEXT_U8(&u8Imm);
443 IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX();
444
445 IEM_MC_BEGIN(3, 0);
446 IEM_MC_ARG(uint8_t *, pu8Dst, 0);
447 IEM_MC_ARG_CONST(uint8_t, u8Src,/*=*/ u8Imm, 1);
448 IEM_MC_ARG(uint32_t *, pEFlags, 2);
449
450 IEM_MC_REF_GREG_U8(pu8Dst, X86_GREG_xAX);
451 IEM_MC_REF_EFLAGS(pEFlags);
452 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU8, pu8Dst, u8Src, pEFlags);
453
454 IEM_MC_ADVANCE_RIP();
455 IEM_MC_END();
456 return VINF_SUCCESS;
457}
458
459
460/**
461 * Common worker for instructions like ADD, AND, OR, ++ with working on
462 * AX/EAX/RAX with a word/dword immediate.
463 *
464 * @param pImpl Pointer to the instruction implementation (assembly).
465 */
466FNIEMOP_DEF_1(iemOpHlpBinaryOperator_rAX_Iz, PCIEMOPBINSIZES, pImpl)
467{
468 switch (pVCpu->iem.s.enmEffOpSize)
469 {
470 case IEMMODE_16BIT:
471 {
472 uint16_t u16Imm; IEM_OPCODE_GET_NEXT_U16(&u16Imm);
473 IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX();
474
475 IEM_MC_BEGIN(3, 0);
476 IEM_MC_ARG(uint16_t *, pu16Dst, 0);
477 IEM_MC_ARG_CONST(uint16_t, u16Src,/*=*/ u16Imm, 1);
478 IEM_MC_ARG(uint32_t *, pEFlags, 2);
479
480 IEM_MC_REF_GREG_U16(pu16Dst, X86_GREG_xAX);
481 IEM_MC_REF_EFLAGS(pEFlags);
482 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU16, pu16Dst, u16Src, pEFlags);
483
484 IEM_MC_ADVANCE_RIP();
485 IEM_MC_END();
486 return VINF_SUCCESS;
487 }
488
489 case IEMMODE_32BIT:
490 {
491 uint32_t u32Imm; IEM_OPCODE_GET_NEXT_U32(&u32Imm);
492 IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX();
493
494 IEM_MC_BEGIN(3, 0);
495 IEM_MC_ARG(uint32_t *, pu32Dst, 0);
496 IEM_MC_ARG_CONST(uint32_t, u32Src,/*=*/ u32Imm, 1);
497 IEM_MC_ARG(uint32_t *, pEFlags, 2);
498
499 IEM_MC_REF_GREG_U32(pu32Dst, X86_GREG_xAX);
500 IEM_MC_REF_EFLAGS(pEFlags);
501 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU32, pu32Dst, u32Src, pEFlags);
502
503 if (pImpl != &g_iemAImpl_test)
504 IEM_MC_CLEAR_HIGH_GREG_U64_BY_REF(pu32Dst);
505 IEM_MC_ADVANCE_RIP();
506 IEM_MC_END();
507 return VINF_SUCCESS;
508 }
509
510 case IEMMODE_64BIT:
511 {
512 uint64_t u64Imm; IEM_OPCODE_GET_NEXT_S32_SX_U64(&u64Imm);
513 IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX();
514
515 IEM_MC_BEGIN(3, 0);
516 IEM_MC_ARG(uint64_t *, pu64Dst, 0);
517 IEM_MC_ARG_CONST(uint64_t, u64Src,/*=*/ u64Imm, 1);
518 IEM_MC_ARG(uint32_t *, pEFlags, 2);
519
520 IEM_MC_REF_GREG_U64(pu64Dst, X86_GREG_xAX);
521 IEM_MC_REF_EFLAGS(pEFlags);
522 IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU64, pu64Dst, u64Src, pEFlags);
523
524 IEM_MC_ADVANCE_RIP();
525 IEM_MC_END();
526 return VINF_SUCCESS;
527 }
528
529 IEM_NOT_REACHED_DEFAULT_CASE_RET();
530 }
531}
532
533
534/** Opcodes 0xf1, 0xd6. */
535FNIEMOP_DEF(iemOp_Invalid)
536{
537 IEMOP_MNEMONIC(Invalid, "Invalid");
538 return IEMOP_RAISE_INVALID_OPCODE();
539}
540
541
542/** Invalid with RM byte . */
543FNIEMOPRM_DEF(iemOp_InvalidWithRM)
544{
545 RT_NOREF_PV(bRm);
546 IEMOP_MNEMONIC(InvalidWithRm, "InvalidWithRM");
547 return IEMOP_RAISE_INVALID_OPCODE();
548}
549
550
551/** Invalid with RM byte where intel decodes any additional address encoding
552 * bytes. */
553FNIEMOPRM_DEF(iemOp_InvalidWithRMNeedDecode)
554{
555 IEMOP_MNEMONIC(InvalidWithRMNeedDecode, "InvalidWithRMNeedDecode");
556 if (pVCpu->iem.s.enmCpuVendor == CPUMCPUVENDOR_INTEL)
557 {
558#ifndef TST_IEM_CHECK_MC
559 if ((bRm & X86_MODRM_MOD_MASK) != (3 << X86_MODRM_MOD_SHIFT))
560 {
561 RTGCPTR GCPtrEff;
562 VBOXSTRICTRC rcStrict = iemOpHlpCalcRmEffAddr(pVCpu, bRm, 0, &GCPtrEff);
563 if (rcStrict != VINF_SUCCESS)
564 return rcStrict;
565 }
566#endif
567 }
568 IEMOP_HLP_DONE_DECODING();
569 return IEMOP_RAISE_INVALID_OPCODE();
570}
571
572
573/** Invalid with RM byte where both AMD and Intel decodes any additional
574 * address encoding bytes. */
575FNIEMOPRM_DEF(iemOp_InvalidWithRMAllNeeded)
576{
577 IEMOP_MNEMONIC(InvalidWithRMAllNeeded, "InvalidWithRMAllNeeded");
578#ifndef TST_IEM_CHECK_MC
579 if ((bRm & X86_MODRM_MOD_MASK) != (3 << X86_MODRM_MOD_SHIFT))
580 {
581 RTGCPTR GCPtrEff;
582 VBOXSTRICTRC rcStrict = iemOpHlpCalcRmEffAddr(pVCpu, bRm, 0, &GCPtrEff);
583 if (rcStrict != VINF_SUCCESS)
584 return rcStrict;
585 }
586#endif
587 IEMOP_HLP_DONE_DECODING();
588 return IEMOP_RAISE_INVALID_OPCODE();
589}
590
591
592/** Invalid with RM byte where intel requires 8-byte immediate.
593 * Intel will also need SIB and displacement if bRm indicates memory. */
594FNIEMOPRM_DEF(iemOp_InvalidWithRMNeedImm8)
595{
596 IEMOP_MNEMONIC(InvalidWithRMNeedImm8, "InvalidWithRMNeedImm8");
597 if (pVCpu->iem.s.enmCpuVendor == CPUMCPUVENDOR_INTEL)
598 {
599#ifndef TST_IEM_CHECK_MC
600 if ((bRm & X86_MODRM_MOD_MASK) != (3 << X86_MODRM_MOD_SHIFT))
601 {
602 RTGCPTR GCPtrEff;
603 VBOXSTRICTRC rcStrict = iemOpHlpCalcRmEffAddr(pVCpu, bRm, 0, &GCPtrEff);
604 if (rcStrict != VINF_SUCCESS)
605 return rcStrict;
606 }
607#endif
608 uint8_t bImm8; IEM_OPCODE_GET_NEXT_U8(&bImm8); RT_NOREF(bRm);
609 }
610 IEMOP_HLP_DONE_DECODING();
611 return IEMOP_RAISE_INVALID_OPCODE();
612}
613
614
615/** Invalid with RM byte where intel requires 8-byte immediate.
616 * Both AMD and Intel also needs SIB and displacement according to bRm. */
617FNIEMOPRM_DEF(iemOp_InvalidWithRMAllNeedImm8)
618{
619 IEMOP_MNEMONIC(InvalidWithRMAllNeedImm8, "InvalidWithRMAllNeedImm8");
620#ifndef TST_IEM_CHECK_MC
621 if ((bRm & X86_MODRM_MOD_MASK) != (3 << X86_MODRM_MOD_SHIFT))
622 {
623 RTGCPTR GCPtrEff;
624 VBOXSTRICTRC rcStrict = iemOpHlpCalcRmEffAddr(pVCpu, bRm, 0, &GCPtrEff);
625 if (rcStrict != VINF_SUCCESS)
626 return rcStrict;
627 }
628#endif
629 uint8_t bImm8; IEM_OPCODE_GET_NEXT_U8(&bImm8); RT_NOREF(bRm);
630 IEMOP_HLP_DONE_DECODING();
631 return IEMOP_RAISE_INVALID_OPCODE();
632}
633
634
635/** Invalid opcode where intel requires Mod R/M sequence. */
636FNIEMOP_DEF(iemOp_InvalidNeedRM)
637{
638 IEMOP_MNEMONIC(InvalidNeedRM, "InvalidNeedRM");
639 if (pVCpu->iem.s.enmCpuVendor == CPUMCPUVENDOR_INTEL)
640 {
641 uint8_t bRm; IEM_OPCODE_GET_NEXT_U8(&bRm); RT_NOREF(bRm);
642#ifndef TST_IEM_CHECK_MC
643 if ((bRm & X86_MODRM_MOD_MASK) != (3 << X86_MODRM_MOD_SHIFT))
644 {
645 RTGCPTR GCPtrEff;
646 VBOXSTRICTRC rcStrict = iemOpHlpCalcRmEffAddr(pVCpu, bRm, 0, &GCPtrEff);
647 if (rcStrict != VINF_SUCCESS)
648 return rcStrict;
649 }
650#endif
651 }
652 IEMOP_HLP_DONE_DECODING();
653 return IEMOP_RAISE_INVALID_OPCODE();
654}
655
656
657/** Invalid opcode where both AMD and Intel requires Mod R/M sequence. */
658FNIEMOP_DEF(iemOp_InvalidAllNeedRM)
659{
660 IEMOP_MNEMONIC(InvalidAllNeedRM, "InvalidAllNeedRM");
661 uint8_t bRm; IEM_OPCODE_GET_NEXT_U8(&bRm); RT_NOREF(bRm);
662#ifndef TST_IEM_CHECK_MC
663 if ((bRm & X86_MODRM_MOD_MASK) != (3 << X86_MODRM_MOD_SHIFT))
664 {
665 RTGCPTR GCPtrEff;
666 VBOXSTRICTRC rcStrict = iemOpHlpCalcRmEffAddr(pVCpu, bRm, 0, &GCPtrEff);
667 if (rcStrict != VINF_SUCCESS)
668 return rcStrict;
669 }
670#endif
671 IEMOP_HLP_DONE_DECODING();
672 return IEMOP_RAISE_INVALID_OPCODE();
673}
674
675
676/** Invalid opcode where intel requires Mod R/M sequence and 8-byte
677 * immediate. */
678FNIEMOP_DEF(iemOp_InvalidNeedRMImm8)
679{
680 IEMOP_MNEMONIC(InvalidNeedRMImm8, "InvalidNeedRMImm8");
681 if (pVCpu->iem.s.enmCpuVendor == CPUMCPUVENDOR_INTEL)
682 {
683 uint8_t bRm; IEM_OPCODE_GET_NEXT_U8(&bRm); RT_NOREF(bRm);
684#ifndef TST_IEM_CHECK_MC
685 if ((bRm & X86_MODRM_MOD_MASK) != (3 << X86_MODRM_MOD_SHIFT))
686 {
687 RTGCPTR GCPtrEff;
688 VBOXSTRICTRC rcStrict = iemOpHlpCalcRmEffAddr(pVCpu, bRm, 0, &GCPtrEff);
689 if (rcStrict != VINF_SUCCESS)
690 return rcStrict;
691 }
692#endif
693 uint8_t bImm; IEM_OPCODE_GET_NEXT_U8(&bImm); RT_NOREF(bImm);
694 }
695 IEMOP_HLP_DONE_DECODING();
696 return IEMOP_RAISE_INVALID_OPCODE();
697}
698
699
700/** Invalid opcode where intel requires a 3rd escape byte and a Mod R/M
701 * sequence. */
702FNIEMOP_DEF(iemOp_InvalidNeed3ByteEscRM)
703{
704 IEMOP_MNEMONIC(InvalidNeed3ByteEscRM, "InvalidNeed3ByteEscRM");
705 if (pVCpu->iem.s.enmCpuVendor == CPUMCPUVENDOR_INTEL)
706 {
707 uint8_t b3rd; IEM_OPCODE_GET_NEXT_U8(&b3rd); RT_NOREF(b3rd);
708 uint8_t bRm; IEM_OPCODE_GET_NEXT_U8(&bRm); RT_NOREF(bRm);
709#ifndef TST_IEM_CHECK_MC
710 if ((bRm & X86_MODRM_MOD_MASK) != (3 << X86_MODRM_MOD_SHIFT))
711 {
712 RTGCPTR GCPtrEff;
713 VBOXSTRICTRC rcStrict = iemOpHlpCalcRmEffAddr(pVCpu, bRm, 0, &GCPtrEff);
714 if (rcStrict != VINF_SUCCESS)
715 return rcStrict;
716 }
717#endif
718 }
719 IEMOP_HLP_DONE_DECODING();
720 return IEMOP_RAISE_INVALID_OPCODE();
721}
722
723
724/** Invalid opcode where intel requires a 3rd escape byte, Mod R/M sequence, and
725 * a 8-byte immediate. */
726FNIEMOP_DEF(iemOp_InvalidNeed3ByteEscRMImm8)
727{
728 IEMOP_MNEMONIC(InvalidNeed3ByteEscRMImm8, "InvalidNeed3ByteEscRMImm8");
729 if (pVCpu->iem.s.enmCpuVendor == CPUMCPUVENDOR_INTEL)
730 {
731 uint8_t b3rd; IEM_OPCODE_GET_NEXT_U8(&b3rd); RT_NOREF(b3rd);
732 uint8_t bRm; IEM_OPCODE_GET_NEXT_U8(&bRm); RT_NOREF(bRm);
733#ifndef TST_IEM_CHECK_MC
734 if ((bRm & X86_MODRM_MOD_MASK) != (3 << X86_MODRM_MOD_SHIFT))
735 {
736 RTGCPTR GCPtrEff;
737 VBOXSTRICTRC rcStrict = iemOpHlpCalcRmEffAddr(pVCpu, bRm, 1, &GCPtrEff);
738 if (rcStrict != VINF_SUCCESS)
739 return rcStrict;
740 }
741#endif
742 uint8_t bImm; IEM_OPCODE_GET_NEXT_U8(&bImm); RT_NOREF(bImm);
743 IEMOP_HLP_DONE_DECODING();
744 }
745 return IEMOP_RAISE_INVALID_OPCODE();
746}
747
748
749/** Repeats a_fn four times. For decoding tables. */
750#define IEMOP_X4(a_fn) a_fn, a_fn, a_fn, a_fn
751
752/*
753 * Include the tables.
754 */
755#ifdef IEM_WITH_3DNOW
756# include "IEMAllInstructions3DNow.cpp.h"
757#endif
758#ifdef IEM_WITH_THREE_0F_38
759# include "IEMAllInstructionsThree0f38.cpp.h"
760#endif
761#ifdef IEM_WITH_THREE_0F_3A
762# include "IEMAllInstructionsThree0f3a.cpp.h"
763#endif
764#include "IEMAllInstructionsTwoByte0f.cpp.h"
765#ifdef IEM_WITH_VEX
766# include "IEMAllInstructionsVexMap1.cpp.h"
767# include "IEMAllInstructionsVexMap2.cpp.h"
768# include "IEMAllInstructionsVexMap3.cpp.h"
769#endif
770#include "IEMAllInstructionsOneByte.cpp.h"
771
772
773#ifdef _MSC_VER
774# pragma warning(pop)
775#endif
776
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