/* $Id: IEMAllInstructions.cpp.h 76553 2019-01-01 01:45:53Z vboxsync $ */ /** @file * IEM - Instruction Decoding and Emulation. */ /* * Copyright (C) 2011-2019 Oracle Corporation * * This file is part of VirtualBox Open Source Edition (OSE), as * available from http://www.virtualbox.org. This file is free software; * you can redistribute it and/or modify it under the terms of the GNU * General Public License (GPL) as published by the Free Software * Foundation, in version 2 as it comes in the "COPYING" file of the * VirtualBox OSE distribution. VirtualBox OSE is distributed in the * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind. */ /******************************************************************************* * Global Variables * *******************************************************************************/ extern const PFNIEMOP g_apfnOneByteMap[256]; /* not static since we need to forward declare it. */ #ifdef _MSC_VER # pragma warning(push) # pragma warning(disable: 4702) /* Unreachable code like return in iemOp_Grp6_lldt. */ #endif /** * Common worker for instructions like ADD, AND, OR, ++ with a byte * memory/register as the destination. * * @param pImpl Pointer to the instruction implementation (assembly). */ FNIEMOP_DEF_1(iemOpHlpBinaryOperator_rm_r8, PCIEMOPBINSIZES, pImpl) { uint8_t bRm; IEM_OPCODE_GET_NEXT_U8(&bRm); /* * If rm is denoting a register, no more instruction bytes. */ if ((bRm & X86_MODRM_MOD_MASK) == (3 << X86_MODRM_MOD_SHIFT)) { IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX(); IEM_MC_BEGIN(3, 0); IEM_MC_ARG(uint8_t *, pu8Dst, 0); IEM_MC_ARG(uint8_t, u8Src, 1); IEM_MC_ARG(uint32_t *, pEFlags, 2); IEM_MC_FETCH_GREG_U8(u8Src, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg); IEM_MC_REF_GREG_U8(pu8Dst, (bRm & X86_MODRM_RM_MASK) | pVCpu->iem.s.uRexB); IEM_MC_REF_EFLAGS(pEFlags); IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU8, pu8Dst, u8Src, pEFlags); IEM_MC_ADVANCE_RIP(); IEM_MC_END(); } else { /* * We're accessing memory. * Note! We're putting the eflags on the stack here so we can commit them * after the memory. */ uint32_t const fAccess = pImpl->pfnLockedU8 ? IEM_ACCESS_DATA_RW : IEM_ACCESS_DATA_R; /* CMP,TEST */ IEM_MC_BEGIN(3, 2); IEM_MC_ARG(uint8_t *, pu8Dst, 0); IEM_MC_ARG(uint8_t, u8Src, 1); IEM_MC_ARG_LOCAL_EFLAGS(pEFlags, EFlags, 2); IEM_MC_LOCAL(RTGCPTR, GCPtrEffDst); IEM_MC_CALC_RM_EFF_ADDR(GCPtrEffDst, bRm, 0); if (!pImpl->pfnLockedU8) IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX(); IEM_MC_MEM_MAP(pu8Dst, fAccess, pVCpu->iem.s.iEffSeg, GCPtrEffDst, 0 /*arg*/); IEM_MC_FETCH_GREG_U8(u8Src, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg); IEM_MC_FETCH_EFLAGS(EFlags); if (!(pVCpu->iem.s.fPrefixes & IEM_OP_PRF_LOCK)) IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU8, pu8Dst, u8Src, pEFlags); else IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnLockedU8, pu8Dst, u8Src, pEFlags); IEM_MC_MEM_COMMIT_AND_UNMAP(pu8Dst, fAccess); IEM_MC_COMMIT_EFLAGS(EFlags); IEM_MC_ADVANCE_RIP(); IEM_MC_END(); } return VINF_SUCCESS; } /** * Common worker for word/dword/qword instructions like ADD, AND, OR, ++ with * memory/register as the destination. * * @param pImpl Pointer to the instruction implementation (assembly). */ FNIEMOP_DEF_1(iemOpHlpBinaryOperator_rm_rv, PCIEMOPBINSIZES, pImpl) { uint8_t bRm; IEM_OPCODE_GET_NEXT_U8(&bRm); /* * If rm is denoting a register, no more instruction bytes. */ if ((bRm & X86_MODRM_MOD_MASK) == (3 << X86_MODRM_MOD_SHIFT)) { IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX(); switch (pVCpu->iem.s.enmEffOpSize) { case IEMMODE_16BIT: IEM_MC_BEGIN(3, 0); IEM_MC_ARG(uint16_t *, pu16Dst, 0); IEM_MC_ARG(uint16_t, u16Src, 1); IEM_MC_ARG(uint32_t *, pEFlags, 2); IEM_MC_FETCH_GREG_U16(u16Src, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg); IEM_MC_REF_GREG_U16(pu16Dst, (bRm & X86_MODRM_RM_MASK) | pVCpu->iem.s.uRexB); IEM_MC_REF_EFLAGS(pEFlags); IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU16, pu16Dst, u16Src, pEFlags); IEM_MC_ADVANCE_RIP(); IEM_MC_END(); break; case IEMMODE_32BIT: IEM_MC_BEGIN(3, 0); IEM_MC_ARG(uint32_t *, pu32Dst, 0); IEM_MC_ARG(uint32_t, u32Src, 1); IEM_MC_ARG(uint32_t *, pEFlags, 2); IEM_MC_FETCH_GREG_U32(u32Src, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg); IEM_MC_REF_GREG_U32(pu32Dst, (bRm & X86_MODRM_RM_MASK) | pVCpu->iem.s.uRexB); IEM_MC_REF_EFLAGS(pEFlags); IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU32, pu32Dst, u32Src, pEFlags); if (pImpl != &g_iemAImpl_test) IEM_MC_CLEAR_HIGH_GREG_U64_BY_REF(pu32Dst); IEM_MC_ADVANCE_RIP(); IEM_MC_END(); break; case IEMMODE_64BIT: IEM_MC_BEGIN(3, 0); IEM_MC_ARG(uint64_t *, pu64Dst, 0); IEM_MC_ARG(uint64_t, u64Src, 1); IEM_MC_ARG(uint32_t *, pEFlags, 2); IEM_MC_FETCH_GREG_U64(u64Src, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg); IEM_MC_REF_GREG_U64(pu64Dst, (bRm & X86_MODRM_RM_MASK) | pVCpu->iem.s.uRexB); IEM_MC_REF_EFLAGS(pEFlags); IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU64, pu64Dst, u64Src, pEFlags); IEM_MC_ADVANCE_RIP(); IEM_MC_END(); break; } } else { /* * We're accessing memory. * Note! We're putting the eflags on the stack here so we can commit them * after the memory. */ uint32_t const fAccess = pImpl->pfnLockedU8 ? IEM_ACCESS_DATA_RW : IEM_ACCESS_DATA_R /* CMP,TEST */; switch (pVCpu->iem.s.enmEffOpSize) { case IEMMODE_16BIT: IEM_MC_BEGIN(3, 2); IEM_MC_ARG(uint16_t *, pu16Dst, 0); IEM_MC_ARG(uint16_t, u16Src, 1); IEM_MC_ARG_LOCAL_EFLAGS(pEFlags, EFlags, 2); IEM_MC_LOCAL(RTGCPTR, GCPtrEffDst); IEM_MC_CALC_RM_EFF_ADDR(GCPtrEffDst, bRm, 0); if (!pImpl->pfnLockedU16) IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX(); IEM_MC_MEM_MAP(pu16Dst, fAccess, pVCpu->iem.s.iEffSeg, GCPtrEffDst, 0 /*arg*/); IEM_MC_FETCH_GREG_U16(u16Src, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg); IEM_MC_FETCH_EFLAGS(EFlags); if (!(pVCpu->iem.s.fPrefixes & IEM_OP_PRF_LOCK)) IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU16, pu16Dst, u16Src, pEFlags); else IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnLockedU16, pu16Dst, u16Src, pEFlags); IEM_MC_MEM_COMMIT_AND_UNMAP(pu16Dst, fAccess); IEM_MC_COMMIT_EFLAGS(EFlags); IEM_MC_ADVANCE_RIP(); IEM_MC_END(); break; case IEMMODE_32BIT: IEM_MC_BEGIN(3, 2); IEM_MC_ARG(uint32_t *, pu32Dst, 0); IEM_MC_ARG(uint32_t, u32Src, 1); IEM_MC_ARG_LOCAL_EFLAGS(pEFlags, EFlags, 2); IEM_MC_LOCAL(RTGCPTR, GCPtrEffDst); IEM_MC_CALC_RM_EFF_ADDR(GCPtrEffDst, bRm, 0); if (!pImpl->pfnLockedU32) IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX(); IEM_MC_MEM_MAP(pu32Dst, fAccess, pVCpu->iem.s.iEffSeg, GCPtrEffDst, 0 /*arg*/); IEM_MC_FETCH_GREG_U32(u32Src, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg); IEM_MC_FETCH_EFLAGS(EFlags); if (!(pVCpu->iem.s.fPrefixes & IEM_OP_PRF_LOCK)) IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU32, pu32Dst, u32Src, pEFlags); else IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnLockedU32, pu32Dst, u32Src, pEFlags); IEM_MC_MEM_COMMIT_AND_UNMAP(pu32Dst, fAccess); IEM_MC_COMMIT_EFLAGS(EFlags); IEM_MC_ADVANCE_RIP(); IEM_MC_END(); break; case IEMMODE_64BIT: IEM_MC_BEGIN(3, 2); IEM_MC_ARG(uint64_t *, pu64Dst, 0); IEM_MC_ARG(uint64_t, u64Src, 1); IEM_MC_ARG_LOCAL_EFLAGS(pEFlags, EFlags, 2); IEM_MC_LOCAL(RTGCPTR, GCPtrEffDst); IEM_MC_CALC_RM_EFF_ADDR(GCPtrEffDst, bRm, 0); if (!pImpl->pfnLockedU64) IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX(); IEM_MC_MEM_MAP(pu64Dst, fAccess, pVCpu->iem.s.iEffSeg, GCPtrEffDst, 0 /*arg*/); IEM_MC_FETCH_GREG_U64(u64Src, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg); IEM_MC_FETCH_EFLAGS(EFlags); if (!(pVCpu->iem.s.fPrefixes & IEM_OP_PRF_LOCK)) IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU64, pu64Dst, u64Src, pEFlags); else IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnLockedU64, pu64Dst, u64Src, pEFlags); IEM_MC_MEM_COMMIT_AND_UNMAP(pu64Dst, fAccess); IEM_MC_COMMIT_EFLAGS(EFlags); IEM_MC_ADVANCE_RIP(); IEM_MC_END(); break; } } return VINF_SUCCESS; } /** * Common worker for byte instructions like ADD, AND, OR, ++ with a register as * the destination. * * @param pImpl Pointer to the instruction implementation (assembly). */ FNIEMOP_DEF_1(iemOpHlpBinaryOperator_r8_rm, PCIEMOPBINSIZES, pImpl) { uint8_t bRm; IEM_OPCODE_GET_NEXT_U8(&bRm); /* * If rm is denoting a register, no more instruction bytes. */ if ((bRm & X86_MODRM_MOD_MASK) == (3 << X86_MODRM_MOD_SHIFT)) { IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX(); IEM_MC_BEGIN(3, 0); IEM_MC_ARG(uint8_t *, pu8Dst, 0); IEM_MC_ARG(uint8_t, u8Src, 1); IEM_MC_ARG(uint32_t *, pEFlags, 2); IEM_MC_FETCH_GREG_U8(u8Src, (bRm & X86_MODRM_RM_MASK) | pVCpu->iem.s.uRexB); IEM_MC_REF_GREG_U8(pu8Dst, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg); IEM_MC_REF_EFLAGS(pEFlags); IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU8, pu8Dst, u8Src, pEFlags); IEM_MC_ADVANCE_RIP(); IEM_MC_END(); } else { /* * We're accessing memory. */ IEM_MC_BEGIN(3, 1); IEM_MC_ARG(uint8_t *, pu8Dst, 0); IEM_MC_ARG(uint8_t, u8Src, 1); IEM_MC_ARG(uint32_t *, pEFlags, 2); IEM_MC_LOCAL(RTGCPTR, GCPtrEffDst); IEM_MC_CALC_RM_EFF_ADDR(GCPtrEffDst, bRm, 0); IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX(); IEM_MC_FETCH_MEM_U8(u8Src, pVCpu->iem.s.iEffSeg, GCPtrEffDst); IEM_MC_REF_GREG_U8(pu8Dst, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg); IEM_MC_REF_EFLAGS(pEFlags); IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU8, pu8Dst, u8Src, pEFlags); IEM_MC_ADVANCE_RIP(); IEM_MC_END(); } return VINF_SUCCESS; } /** * Common worker for word/dword/qword instructions like ADD, AND, OR, ++ with a * register as the destination. * * @param pImpl Pointer to the instruction implementation (assembly). */ FNIEMOP_DEF_1(iemOpHlpBinaryOperator_rv_rm, PCIEMOPBINSIZES, pImpl) { uint8_t bRm; IEM_OPCODE_GET_NEXT_U8(&bRm); /* * If rm is denoting a register, no more instruction bytes. */ if ((bRm & X86_MODRM_MOD_MASK) == (3 << X86_MODRM_MOD_SHIFT)) { IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX(); switch (pVCpu->iem.s.enmEffOpSize) { case IEMMODE_16BIT: IEM_MC_BEGIN(3, 0); IEM_MC_ARG(uint16_t *, pu16Dst, 0); IEM_MC_ARG(uint16_t, u16Src, 1); IEM_MC_ARG(uint32_t *, pEFlags, 2); IEM_MC_FETCH_GREG_U16(u16Src, (bRm & X86_MODRM_RM_MASK) | pVCpu->iem.s.uRexB); IEM_MC_REF_GREG_U16(pu16Dst, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg); IEM_MC_REF_EFLAGS(pEFlags); IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU16, pu16Dst, u16Src, pEFlags); IEM_MC_ADVANCE_RIP(); IEM_MC_END(); break; case IEMMODE_32BIT: IEM_MC_BEGIN(3, 0); IEM_MC_ARG(uint32_t *, pu32Dst, 0); IEM_MC_ARG(uint32_t, u32Src, 1); IEM_MC_ARG(uint32_t *, pEFlags, 2); IEM_MC_FETCH_GREG_U32(u32Src, (bRm & X86_MODRM_RM_MASK) | pVCpu->iem.s.uRexB); IEM_MC_REF_GREG_U32(pu32Dst, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg); IEM_MC_REF_EFLAGS(pEFlags); IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU32, pu32Dst, u32Src, pEFlags); IEM_MC_CLEAR_HIGH_GREG_U64_BY_REF(pu32Dst); IEM_MC_ADVANCE_RIP(); IEM_MC_END(); break; case IEMMODE_64BIT: IEM_MC_BEGIN(3, 0); IEM_MC_ARG(uint64_t *, pu64Dst, 0); IEM_MC_ARG(uint64_t, u64Src, 1); IEM_MC_ARG(uint32_t *, pEFlags, 2); IEM_MC_FETCH_GREG_U64(u64Src, (bRm & X86_MODRM_RM_MASK) | pVCpu->iem.s.uRexB); IEM_MC_REF_GREG_U64(pu64Dst, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg); IEM_MC_REF_EFLAGS(pEFlags); IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU64, pu64Dst, u64Src, pEFlags); IEM_MC_ADVANCE_RIP(); IEM_MC_END(); break; } } else { /* * We're accessing memory. */ switch (pVCpu->iem.s.enmEffOpSize) { case IEMMODE_16BIT: IEM_MC_BEGIN(3, 1); IEM_MC_ARG(uint16_t *, pu16Dst, 0); IEM_MC_ARG(uint16_t, u16Src, 1); IEM_MC_ARG(uint32_t *, pEFlags, 2); IEM_MC_LOCAL(RTGCPTR, GCPtrEffDst); IEM_MC_CALC_RM_EFF_ADDR(GCPtrEffDst, bRm, 0); IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX(); IEM_MC_FETCH_MEM_U16(u16Src, pVCpu->iem.s.iEffSeg, GCPtrEffDst); IEM_MC_REF_GREG_U16(pu16Dst, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg); IEM_MC_REF_EFLAGS(pEFlags); IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU16, pu16Dst, u16Src, pEFlags); IEM_MC_ADVANCE_RIP(); IEM_MC_END(); break; case IEMMODE_32BIT: IEM_MC_BEGIN(3, 1); IEM_MC_ARG(uint32_t *, pu32Dst, 0); IEM_MC_ARG(uint32_t, u32Src, 1); IEM_MC_ARG(uint32_t *, pEFlags, 2); IEM_MC_LOCAL(RTGCPTR, GCPtrEffDst); IEM_MC_CALC_RM_EFF_ADDR(GCPtrEffDst, bRm, 0); IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX(); IEM_MC_FETCH_MEM_U32(u32Src, pVCpu->iem.s.iEffSeg, GCPtrEffDst); IEM_MC_REF_GREG_U32(pu32Dst, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg); IEM_MC_REF_EFLAGS(pEFlags); IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU32, pu32Dst, u32Src, pEFlags); IEM_MC_CLEAR_HIGH_GREG_U64_BY_REF(pu32Dst); IEM_MC_ADVANCE_RIP(); IEM_MC_END(); break; case IEMMODE_64BIT: IEM_MC_BEGIN(3, 1); IEM_MC_ARG(uint64_t *, pu64Dst, 0); IEM_MC_ARG(uint64_t, u64Src, 1); IEM_MC_ARG(uint32_t *, pEFlags, 2); IEM_MC_LOCAL(RTGCPTR, GCPtrEffDst); IEM_MC_CALC_RM_EFF_ADDR(GCPtrEffDst, bRm, 0); IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX(); IEM_MC_FETCH_MEM_U64(u64Src, pVCpu->iem.s.iEffSeg, GCPtrEffDst); IEM_MC_REF_GREG_U64(pu64Dst, ((bRm >> X86_MODRM_REG_SHIFT) & X86_MODRM_REG_SMASK) | pVCpu->iem.s.uRexReg); IEM_MC_REF_EFLAGS(pEFlags); IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU64, pu64Dst, u64Src, pEFlags); IEM_MC_ADVANCE_RIP(); IEM_MC_END(); break; } } return VINF_SUCCESS; } /** * Common worker for instructions like ADD, AND, OR, ++ with working on AL with * a byte immediate. * * @param pImpl Pointer to the instruction implementation (assembly). */ FNIEMOP_DEF_1(iemOpHlpBinaryOperator_AL_Ib, PCIEMOPBINSIZES, pImpl) { uint8_t u8Imm; IEM_OPCODE_GET_NEXT_U8(&u8Imm); IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX(); IEM_MC_BEGIN(3, 0); IEM_MC_ARG(uint8_t *, pu8Dst, 0); IEM_MC_ARG_CONST(uint8_t, u8Src,/*=*/ u8Imm, 1); IEM_MC_ARG(uint32_t *, pEFlags, 2); IEM_MC_REF_GREG_U8(pu8Dst, X86_GREG_xAX); IEM_MC_REF_EFLAGS(pEFlags); IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU8, pu8Dst, u8Src, pEFlags); IEM_MC_ADVANCE_RIP(); IEM_MC_END(); return VINF_SUCCESS; } /** * Common worker for instructions like ADD, AND, OR, ++ with working on * AX/EAX/RAX with a word/dword immediate. * * @param pImpl Pointer to the instruction implementation (assembly). */ FNIEMOP_DEF_1(iemOpHlpBinaryOperator_rAX_Iz, PCIEMOPBINSIZES, pImpl) { switch (pVCpu->iem.s.enmEffOpSize) { case IEMMODE_16BIT: { uint16_t u16Imm; IEM_OPCODE_GET_NEXT_U16(&u16Imm); IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX(); IEM_MC_BEGIN(3, 0); IEM_MC_ARG(uint16_t *, pu16Dst, 0); IEM_MC_ARG_CONST(uint16_t, u16Src,/*=*/ u16Imm, 1); IEM_MC_ARG(uint32_t *, pEFlags, 2); IEM_MC_REF_GREG_U16(pu16Dst, X86_GREG_xAX); IEM_MC_REF_EFLAGS(pEFlags); IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU16, pu16Dst, u16Src, pEFlags); IEM_MC_ADVANCE_RIP(); IEM_MC_END(); return VINF_SUCCESS; } case IEMMODE_32BIT: { uint32_t u32Imm; IEM_OPCODE_GET_NEXT_U32(&u32Imm); IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX(); IEM_MC_BEGIN(3, 0); IEM_MC_ARG(uint32_t *, pu32Dst, 0); IEM_MC_ARG_CONST(uint32_t, u32Src,/*=*/ u32Imm, 1); IEM_MC_ARG(uint32_t *, pEFlags, 2); IEM_MC_REF_GREG_U32(pu32Dst, X86_GREG_xAX); IEM_MC_REF_EFLAGS(pEFlags); IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU32, pu32Dst, u32Src, pEFlags); if (pImpl != &g_iemAImpl_test) IEM_MC_CLEAR_HIGH_GREG_U64_BY_REF(pu32Dst); IEM_MC_ADVANCE_RIP(); IEM_MC_END(); return VINF_SUCCESS; } case IEMMODE_64BIT: { uint64_t u64Imm; IEM_OPCODE_GET_NEXT_S32_SX_U64(&u64Imm); IEMOP_HLP_DONE_DECODING_NO_LOCK_PREFIX(); IEM_MC_BEGIN(3, 0); IEM_MC_ARG(uint64_t *, pu64Dst, 0); IEM_MC_ARG_CONST(uint64_t, u64Src,/*=*/ u64Imm, 1); IEM_MC_ARG(uint32_t *, pEFlags, 2); IEM_MC_REF_GREG_U64(pu64Dst, X86_GREG_xAX); IEM_MC_REF_EFLAGS(pEFlags); IEM_MC_CALL_VOID_AIMPL_3(pImpl->pfnNormalU64, pu64Dst, u64Src, pEFlags); IEM_MC_ADVANCE_RIP(); IEM_MC_END(); return VINF_SUCCESS; } IEM_NOT_REACHED_DEFAULT_CASE_RET(); } } /** Opcodes 0xf1, 0xd6. */ FNIEMOP_DEF(iemOp_Invalid) { IEMOP_MNEMONIC(Invalid, "Invalid"); return IEMOP_RAISE_INVALID_OPCODE(); } /** Invalid with RM byte . */ FNIEMOPRM_DEF(iemOp_InvalidWithRM) { RT_NOREF_PV(bRm); IEMOP_MNEMONIC(InvalidWithRm, "InvalidWithRM"); return IEMOP_RAISE_INVALID_OPCODE(); } /** Invalid with RM byte where intel decodes any additional address encoding * bytes. */ FNIEMOPRM_DEF(iemOp_InvalidWithRMNeedDecode) { IEMOP_MNEMONIC(InvalidWithRMNeedDecode, "InvalidWithRMNeedDecode"); if (pVCpu->iem.s.enmCpuVendor == CPUMCPUVENDOR_INTEL) { #ifndef TST_IEM_CHECK_MC if ((bRm & X86_MODRM_MOD_MASK) != (3 << X86_MODRM_MOD_SHIFT)) { RTGCPTR GCPtrEff; VBOXSTRICTRC rcStrict = iemOpHlpCalcRmEffAddr(pVCpu, bRm, 0, &GCPtrEff); if (rcStrict != VINF_SUCCESS) return rcStrict; } #endif } IEMOP_HLP_DONE_DECODING(); return IEMOP_RAISE_INVALID_OPCODE(); } /** Invalid with RM byte where both AMD and Intel decodes any additional * address encoding bytes. */ FNIEMOPRM_DEF(iemOp_InvalidWithRMAllNeeded) { IEMOP_MNEMONIC(InvalidWithRMAllNeeded, "InvalidWithRMAllNeeded"); #ifndef TST_IEM_CHECK_MC if ((bRm & X86_MODRM_MOD_MASK) != (3 << X86_MODRM_MOD_SHIFT)) { RTGCPTR GCPtrEff; VBOXSTRICTRC rcStrict = iemOpHlpCalcRmEffAddr(pVCpu, bRm, 0, &GCPtrEff); if (rcStrict != VINF_SUCCESS) return rcStrict; } #endif IEMOP_HLP_DONE_DECODING(); return IEMOP_RAISE_INVALID_OPCODE(); } /** Invalid with RM byte where intel requires 8-byte immediate. * Intel will also need SIB and displacement if bRm indicates memory. */ FNIEMOPRM_DEF(iemOp_InvalidWithRMNeedImm8) { IEMOP_MNEMONIC(InvalidWithRMNeedImm8, "InvalidWithRMNeedImm8"); if (pVCpu->iem.s.enmCpuVendor == CPUMCPUVENDOR_INTEL) { #ifndef TST_IEM_CHECK_MC if ((bRm & X86_MODRM_MOD_MASK) != (3 << X86_MODRM_MOD_SHIFT)) { RTGCPTR GCPtrEff; VBOXSTRICTRC rcStrict = iemOpHlpCalcRmEffAddr(pVCpu, bRm, 0, &GCPtrEff); if (rcStrict != VINF_SUCCESS) return rcStrict; } #endif uint8_t bImm8; IEM_OPCODE_GET_NEXT_U8(&bImm8); RT_NOREF(bRm); } IEMOP_HLP_DONE_DECODING(); return IEMOP_RAISE_INVALID_OPCODE(); } /** Invalid with RM byte where intel requires 8-byte immediate. * Both AMD and Intel also needs SIB and displacement according to bRm. */ FNIEMOPRM_DEF(iemOp_InvalidWithRMAllNeedImm8) { IEMOP_MNEMONIC(InvalidWithRMAllNeedImm8, "InvalidWithRMAllNeedImm8"); #ifndef TST_IEM_CHECK_MC if ((bRm & X86_MODRM_MOD_MASK) != (3 << X86_MODRM_MOD_SHIFT)) { RTGCPTR GCPtrEff; VBOXSTRICTRC rcStrict = iemOpHlpCalcRmEffAddr(pVCpu, bRm, 0, &GCPtrEff); if (rcStrict != VINF_SUCCESS) return rcStrict; } #endif uint8_t bImm8; IEM_OPCODE_GET_NEXT_U8(&bImm8); RT_NOREF(bRm); IEMOP_HLP_DONE_DECODING(); return IEMOP_RAISE_INVALID_OPCODE(); } /** Invalid opcode where intel requires Mod R/M sequence. */ FNIEMOP_DEF(iemOp_InvalidNeedRM) { IEMOP_MNEMONIC(InvalidNeedRM, "InvalidNeedRM"); if (pVCpu->iem.s.enmCpuVendor == CPUMCPUVENDOR_INTEL) { uint8_t bRm; IEM_OPCODE_GET_NEXT_U8(&bRm); RT_NOREF(bRm); #ifndef TST_IEM_CHECK_MC if ((bRm & X86_MODRM_MOD_MASK) != (3 << X86_MODRM_MOD_SHIFT)) { RTGCPTR GCPtrEff; VBOXSTRICTRC rcStrict = iemOpHlpCalcRmEffAddr(pVCpu, bRm, 0, &GCPtrEff); if (rcStrict != VINF_SUCCESS) return rcStrict; } #endif } IEMOP_HLP_DONE_DECODING(); return IEMOP_RAISE_INVALID_OPCODE(); } /** Invalid opcode where both AMD and Intel requires Mod R/M sequence. */ FNIEMOP_DEF(iemOp_InvalidAllNeedRM) { IEMOP_MNEMONIC(InvalidAllNeedRM, "InvalidAllNeedRM"); uint8_t bRm; IEM_OPCODE_GET_NEXT_U8(&bRm); RT_NOREF(bRm); #ifndef TST_IEM_CHECK_MC if ((bRm & X86_MODRM_MOD_MASK) != (3 << X86_MODRM_MOD_SHIFT)) { RTGCPTR GCPtrEff; VBOXSTRICTRC rcStrict = iemOpHlpCalcRmEffAddr(pVCpu, bRm, 0, &GCPtrEff); if (rcStrict != VINF_SUCCESS) return rcStrict; } #endif IEMOP_HLP_DONE_DECODING(); return IEMOP_RAISE_INVALID_OPCODE(); } /** Invalid opcode where intel requires Mod R/M sequence and 8-byte * immediate. */ FNIEMOP_DEF(iemOp_InvalidNeedRMImm8) { IEMOP_MNEMONIC(InvalidNeedRMImm8, "InvalidNeedRMImm8"); if (pVCpu->iem.s.enmCpuVendor == CPUMCPUVENDOR_INTEL) { uint8_t bRm; IEM_OPCODE_GET_NEXT_U8(&bRm); RT_NOREF(bRm); #ifndef TST_IEM_CHECK_MC if ((bRm & X86_MODRM_MOD_MASK) != (3 << X86_MODRM_MOD_SHIFT)) { RTGCPTR GCPtrEff; VBOXSTRICTRC rcStrict = iemOpHlpCalcRmEffAddr(pVCpu, bRm, 0, &GCPtrEff); if (rcStrict != VINF_SUCCESS) return rcStrict; } #endif uint8_t bImm; IEM_OPCODE_GET_NEXT_U8(&bImm); RT_NOREF(bImm); } IEMOP_HLP_DONE_DECODING(); return IEMOP_RAISE_INVALID_OPCODE(); } /** Invalid opcode where intel requires a 3rd escape byte and a Mod R/M * sequence. */ FNIEMOP_DEF(iemOp_InvalidNeed3ByteEscRM) { IEMOP_MNEMONIC(InvalidNeed3ByteEscRM, "InvalidNeed3ByteEscRM"); if (pVCpu->iem.s.enmCpuVendor == CPUMCPUVENDOR_INTEL) { uint8_t b3rd; IEM_OPCODE_GET_NEXT_U8(&b3rd); RT_NOREF(b3rd); uint8_t bRm; IEM_OPCODE_GET_NEXT_U8(&bRm); RT_NOREF(bRm); #ifndef TST_IEM_CHECK_MC if ((bRm & X86_MODRM_MOD_MASK) != (3 << X86_MODRM_MOD_SHIFT)) { RTGCPTR GCPtrEff; VBOXSTRICTRC rcStrict = iemOpHlpCalcRmEffAddr(pVCpu, bRm, 0, &GCPtrEff); if (rcStrict != VINF_SUCCESS) return rcStrict; } #endif } IEMOP_HLP_DONE_DECODING(); return IEMOP_RAISE_INVALID_OPCODE(); } /** Invalid opcode where intel requires a 3rd escape byte, Mod R/M sequence, and * a 8-byte immediate. */ FNIEMOP_DEF(iemOp_InvalidNeed3ByteEscRMImm8) { IEMOP_MNEMONIC(InvalidNeed3ByteEscRMImm8, "InvalidNeed3ByteEscRMImm8"); if (pVCpu->iem.s.enmCpuVendor == CPUMCPUVENDOR_INTEL) { uint8_t b3rd; IEM_OPCODE_GET_NEXT_U8(&b3rd); RT_NOREF(b3rd); uint8_t bRm; IEM_OPCODE_GET_NEXT_U8(&bRm); RT_NOREF(bRm); #ifndef TST_IEM_CHECK_MC if ((bRm & X86_MODRM_MOD_MASK) != (3 << X86_MODRM_MOD_SHIFT)) { RTGCPTR GCPtrEff; VBOXSTRICTRC rcStrict = iemOpHlpCalcRmEffAddr(pVCpu, bRm, 1, &GCPtrEff); if (rcStrict != VINF_SUCCESS) return rcStrict; } #endif uint8_t bImm; IEM_OPCODE_GET_NEXT_U8(&bImm); RT_NOREF(bImm); IEMOP_HLP_DONE_DECODING(); } return IEMOP_RAISE_INVALID_OPCODE(); } /** Repeats a_fn four times. For decoding tables. */ #define IEMOP_X4(a_fn) a_fn, a_fn, a_fn, a_fn /* * Include the tables. */ #ifdef IEM_WITH_3DNOW # include "IEMAllInstructions3DNow.cpp.h" #endif #ifdef IEM_WITH_THREE_0F_38 # include "IEMAllInstructionsThree0f38.cpp.h" #endif #ifdef IEM_WITH_THREE_0F_3A # include "IEMAllInstructionsThree0f3a.cpp.h" #endif #include "IEMAllInstructionsTwoByte0f.cpp.h" #ifdef IEM_WITH_VEX # include "IEMAllInstructionsVexMap1.cpp.h" # include "IEMAllInstructionsVexMap2.cpp.h" # include "IEMAllInstructionsVexMap3.cpp.h" #endif #include "IEMAllInstructionsOneByte.cpp.h" #ifdef _MSC_VER # pragma warning(pop) #endif