/* $Id: DisasmCore.cpp 82968 2020-02-04 10:35:17Z vboxsync $ */ /** @file * VBox Disassembler - Core Components. */ /* * Copyright (C) 2006-2020 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. */ /********************************************************************************************************************************* * Header Files * *********************************************************************************************************************************/ #define LOG_GROUP LOG_GROUP_DIS #include #include #include #include #include #include #include #include #include "DisasmInternal.h" /********************************************************************************************************************************* * Defined Constants And Macros * *********************************************************************************************************************************/ /** This must be less or equal to DISSTATE::abInstr. * See Vol3A/Table 6-2 and Vol3B/Section22.25 for instance. */ #define DIS_MAX_INSTR_LENGTH 15 /** Whether we can do unaligned access. */ #if defined(RT_ARCH_X86) || defined(RT_ARCH_AMD64) # define DIS_HOST_UNALIGNED_ACCESS_OK #endif /********************************************************************************************************************************* * Internal Functions * *********************************************************************************************************************************/ /** @name Parsers * @{ */ static FNDISPARSE ParseIllegal; static FNDISPARSE ParseModRM; static FNDISPARSE ParseModRM_SizeOnly; static FNDISPARSE UseModRM; static FNDISPARSE ParseImmByte; static FNDISPARSE ParseImmByte_SizeOnly; static FNDISPARSE ParseImmByteSX; static FNDISPARSE ParseImmByteSX_SizeOnly; static FNDISPARSE ParseImmBRel; static FNDISPARSE ParseImmBRel_SizeOnly; static FNDISPARSE ParseImmUshort; static FNDISPARSE ParseImmUshort_SizeOnly; static FNDISPARSE ParseImmV; static FNDISPARSE ParseImmV_SizeOnly; static FNDISPARSE ParseImmVRel; static FNDISPARSE ParseImmVRel_SizeOnly; static FNDISPARSE ParseImmZ; static FNDISPARSE ParseImmZ_SizeOnly; static FNDISPARSE ParseImmAddr; static FNDISPARSE ParseImmAddr_SizeOnly; static FNDISPARSE ParseImmAddrF; static FNDISPARSE ParseImmAddrF_SizeOnly; static FNDISPARSE ParseFixedReg; static FNDISPARSE ParseImmUlong; static FNDISPARSE ParseImmUlong_SizeOnly; static FNDISPARSE ParseImmQword; static FNDISPARSE ParseImmQword_SizeOnly; static FNDISPARSE ParseInvOpModRm; static FNDISPARSE ParseTwoByteEsc; static FNDISPARSE ParseThreeByteEsc4; static FNDISPARSE ParseThreeByteEsc5; static FNDISPARSE ParseGrp1; static FNDISPARSE ParseShiftGrp2; static FNDISPARSE ParseGrp3; static FNDISPARSE ParseGrp4; static FNDISPARSE ParseGrp5; static FNDISPARSE Parse3DNow; static FNDISPARSE ParseGrp6; static FNDISPARSE ParseGrp7; static FNDISPARSE ParseGrp8; static FNDISPARSE ParseGrp9; static FNDISPARSE ParseGrp10; static FNDISPARSE ParseGrp12; static FNDISPARSE ParseGrp13; static FNDISPARSE ParseGrp14; static FNDISPARSE ParseGrp15; static FNDISPARSE ParseGrp16; static FNDISPARSE ParseModFence; static FNDISPARSE ParseNopPause; static FNDISPARSE ParseVex2b; static FNDISPARSE ParseVex3b; static FNDISPARSE ParseVexDest; static FNDISPARSE ParseYv; static FNDISPARSE ParseYb; static FNDISPARSE ParseXv; static FNDISPARSE ParseXb; /** Floating point parsing */ static FNDISPARSE ParseEscFP; /** @} */ /********************************************************************************************************************************* * Global Variables * *********************************************************************************************************************************/ /** Parser opcode table for full disassembly. */ static PFNDISPARSE const g_apfnFullDisasm[IDX_ParseMax] = { ParseIllegal, ParseModRM, UseModRM, ParseImmByte, ParseImmBRel, ParseImmUshort, ParseImmV, ParseImmVRel, ParseImmAddr, ParseFixedReg, ParseImmUlong, ParseImmQword, ParseTwoByteEsc, ParseGrp1, ParseShiftGrp2, ParseGrp3, ParseGrp4, ParseGrp5, Parse3DNow, ParseGrp6, ParseGrp7, ParseGrp8, ParseGrp9, ParseGrp10, ParseGrp12, ParseGrp13, ParseGrp14, ParseGrp15, ParseGrp16, ParseModFence, ParseYv, ParseYb, ParseXv, ParseXb, ParseEscFP, ParseNopPause, ParseImmByteSX, ParseImmZ, ParseThreeByteEsc4, ParseThreeByteEsc5, ParseImmAddrF, ParseInvOpModRm, ParseVex2b, ParseVex3b, ParseVexDest }; /** Parser opcode table for only calculating instruction size. */ static PFNDISPARSE const g_apfnCalcSize[IDX_ParseMax] = { ParseIllegal, ParseModRM_SizeOnly, UseModRM, ParseImmByte_SizeOnly, ParseImmBRel_SizeOnly, ParseImmUshort_SizeOnly, ParseImmV_SizeOnly, ParseImmVRel_SizeOnly, ParseImmAddr_SizeOnly, ParseFixedReg, ParseImmUlong_SizeOnly, ParseImmQword_SizeOnly, ParseTwoByteEsc, ParseGrp1, ParseShiftGrp2, ParseGrp3, ParseGrp4, ParseGrp5, Parse3DNow, ParseGrp6, ParseGrp7, ParseGrp8, ParseGrp9, ParseGrp10, ParseGrp12, ParseGrp13, ParseGrp14, ParseGrp15, ParseGrp16, ParseModFence, ParseYv, ParseYb, ParseXv, ParseXb, ParseEscFP, ParseNopPause, ParseImmByteSX_SizeOnly, ParseImmZ_SizeOnly, ParseThreeByteEsc4, ParseThreeByteEsc5, ParseImmAddrF_SizeOnly, ParseInvOpModRm, ParseVex2b, ParseVex3b, ParseVexDest }; /******************************************************************************************************************************** * * * Read functions for getting the opcode bytes * * ********************************************************************************************************************************/ /** * @interface_method_impl{FNDISREADBYTES, The default byte reader callber.} */ static DECLCALLBACK(int) disReadBytesDefault(PDISSTATE pDis, uint8_t offInstr, uint8_t cbMinRead, uint8_t cbMaxRead) { #ifdef IN_RING0 RT_NOREF_PV(cbMinRead); AssertMsgFailed(("disReadWord with no read callback in ring 0!!\n")); RT_BZERO(&pDis->abInstr[offInstr], cbMaxRead); pDis->cbCachedInstr = offInstr + cbMaxRead; return VERR_DIS_NO_READ_CALLBACK; #else uint8_t const *pbSrc = (uint8_t const *)(uintptr_t)pDis->uInstrAddr + offInstr; size_t cbLeftOnPage = (uintptr_t)pbSrc & PAGE_OFFSET_MASK; uint8_t cbToRead = cbLeftOnPage >= cbMaxRead ? cbMaxRead : cbLeftOnPage <= cbMinRead ? cbMinRead : (uint8_t)cbLeftOnPage; memcpy(&pDis->abInstr[offInstr], pbSrc, cbToRead); pDis->cbCachedInstr = offInstr + cbToRead; return VINF_SUCCESS; #endif } /** * Read more bytes into the DISSTATE::abInstr buffer, advance * DISSTATE::cbCachedInstr. * * Will set DISSTATE::rc on failure, but still advance cbCachedInstr. * * The caller shall fend off reads beyond the DISSTATE::abInstr buffer. * * @param pDis The disassembler state. * @param offInstr The offset of the read request. * @param cbMin The size of the read request that needs to be * satisfied. */ DECL_NO_INLINE(static, void) disReadMore(PDISSTATE pDis, uint8_t offInstr, uint8_t cbMin) { Assert(cbMin + offInstr <= sizeof(pDis->abInstr)); /* * Adjust the incoming request to not overlap with bytes that has already * been read and to make sure we don't leave unread gaps. */ if (offInstr < pDis->cbCachedInstr) { Assert(offInstr + cbMin > pDis->cbCachedInstr); cbMin -= pDis->cbCachedInstr - offInstr; offInstr = pDis->cbCachedInstr; } else if (offInstr > pDis->cbCachedInstr) { cbMin += offInstr - pDis->cbCachedInstr; offInstr = pDis->cbCachedInstr; } /* * Do the read. * (No need to zero anything on failure as abInstr is already zeroed by the * DISInstrEx API.) */ int rc = pDis->pfnReadBytes(pDis, offInstr, cbMin, sizeof(pDis->abInstr) - offInstr); if (RT_SUCCESS(rc)) { Assert(pDis->cbCachedInstr >= offInstr + cbMin); Assert(pDis->cbCachedInstr <= sizeof(pDis->abInstr)); } else { Log(("disReadMore failed with rc=%Rrc!!\n", rc)); pDis->rc = rc; } } /** * Function for handling a 8-bit cache miss. * * @returns The requested byte. * @param pDis The disassembler state. * @param offInstr The offset of the byte relative to the * instruction. */ DECL_NO_INLINE(static, uint8_t) disReadByteSlow(PDISSTATE pDis, size_t offInstr) { if (RT_UNLIKELY(offInstr >= DIS_MAX_INSTR_LENGTH)) { Log(("disReadByte: too long instruction...\n")); pDis->rc = VERR_DIS_TOO_LONG_INSTR; RTINTPTR cbLeft = sizeof(pDis->abInstr) - offInstr; if (cbLeft > 0) return pDis->abInstr[offInstr]; return 0; } disReadMore(pDis, (uint8_t)offInstr, 1); return pDis->abInstr[offInstr]; } /** * Read a byte (8-bit) instruction. * * @returns The requested byte. * @param pDis The disassembler state. * @param uAddress The address. */ DECLINLINE(uint8_t) disReadByte(PDISSTATE pDis, size_t offInstr) { if (RT_UNLIKELY(offInstr >= pDis->cbCachedInstr)) return disReadByteSlow(pDis, offInstr); return pDis->abInstr[offInstr]; } /** * Function for handling a 16-bit cache miss. * * @returns The requested word. * @param pDis The disassembler state. * @param offInstr The offset of the word relative to the * instruction. */ DECL_NO_INLINE(static, uint16_t) disReadWordSlow(PDISSTATE pDis, size_t offInstr) { if (RT_UNLIKELY(offInstr + 2 > DIS_MAX_INSTR_LENGTH)) { Log(("disReadWord: too long instruction...\n")); pDis->rc = VERR_DIS_TOO_LONG_INSTR; RTINTPTR cbLeft = sizeof(pDis->abInstr) - offInstr; switch (cbLeft) { case 1: return pDis->abInstr[offInstr]; default: if (cbLeft >= 2) return RT_MAKE_U16(pDis->abInstr[offInstr], pDis->abInstr[offInstr + 1]); return 0; } } disReadMore(pDis, (uint8_t)offInstr, 2); #ifdef DIS_HOST_UNALIGNED_ACCESS_OK return *(uint16_t const *)&pDis->abInstr[offInstr]; #else return RT_MAKE_U16(pDis->abInstr[offInstr], pDis->abInstr[offInstr + 1]); #endif } /** * Read a word (16-bit) instruction. * * @returns The requested word. * @param pDis The disassembler state. * @param offInstr The offset of the qword relative to the * instruction. */ DECLINLINE(uint16_t) disReadWord(PDISSTATE pDis, size_t offInstr) { if (RT_UNLIKELY(offInstr + 2 > pDis->cbCachedInstr)) return disReadWordSlow(pDis, offInstr); #ifdef DIS_HOST_UNALIGNED_ACCESS_OK return *(uint16_t const *)&pDis->abInstr[offInstr]; #else return RT_MAKE_U16(pDis->abInstr[offInstr], pDis->abInstr[offInstr + 1]); #endif } /** * Function for handling a 32-bit cache miss. * * @returns The requested dword. * @param pDis The disassembler state. * @param offInstr The offset of the dword relative to the * instruction. */ DECL_NO_INLINE(static, uint32_t) disReadDWordSlow(PDISSTATE pDis, size_t offInstr) { if (RT_UNLIKELY(offInstr + 4 > DIS_MAX_INSTR_LENGTH)) { Log(("disReadDWord: too long instruction...\n")); pDis->rc = VERR_DIS_TOO_LONG_INSTR; RTINTPTR cbLeft = sizeof(pDis->abInstr) - offInstr; switch (cbLeft) { case 1: return RT_MAKE_U32_FROM_U8(pDis->abInstr[offInstr], 0, 0, 0); case 2: return RT_MAKE_U32_FROM_U8(pDis->abInstr[offInstr], pDis->abInstr[offInstr + 1], 0, 0); case 3: return RT_MAKE_U32_FROM_U8(pDis->abInstr[offInstr], pDis->abInstr[offInstr + 1], pDis->abInstr[offInstr + 2], 0); default: if (cbLeft >= 4) return RT_MAKE_U32_FROM_U8(pDis->abInstr[offInstr ], pDis->abInstr[offInstr + 1], pDis->abInstr[offInstr + 2], pDis->abInstr[offInstr + 3]); return 0; } } disReadMore(pDis, (uint8_t)offInstr, 4); #ifdef DIS_HOST_UNALIGNED_ACCESS_OK return *(uint32_t const *)&pDis->abInstr[offInstr]; #else return RT_MAKE_U32_FROM_U8(pDis->abInstr[offInstr ], pDis->abInstr[offInstr + 1], pDis->abInstr[offInstr + 2], pDis->abInstr[offInstr + 3]); #endif } /** * Read a dword (32-bit) instruction. * * @returns The requested dword. * @param pDis The disassembler state. * @param offInstr The offset of the qword relative to the * instruction. */ DECLINLINE(uint32_t) disReadDWord(PDISSTATE pDis, size_t offInstr) { if (RT_UNLIKELY(offInstr + 4 > pDis->cbCachedInstr)) return disReadDWordSlow(pDis, offInstr); #ifdef DIS_HOST_UNALIGNED_ACCESS_OK return *(uint32_t const *)&pDis->abInstr[offInstr]; #else return RT_MAKE_U32_FROM_U8(pDis->abInstr[offInstr ], pDis->abInstr[offInstr + 1], pDis->abInstr[offInstr + 2], pDis->abInstr[offInstr + 3]); #endif } /** * Function for handling a 64-bit cache miss. * * @returns The requested qword. * @param pDis The disassembler state. * @param offInstr The offset of the qword relative to the * instruction. */ DECL_NO_INLINE(static, uint64_t) disReadQWordSlow(PDISSTATE pDis, size_t offInstr) { if (RT_UNLIKELY(offInstr + 8 > DIS_MAX_INSTR_LENGTH)) { Log(("disReadQWord: too long instruction...\n")); pDis->rc = VERR_DIS_TOO_LONG_INSTR; RTINTPTR cbLeft = sizeof(pDis->abInstr) - offInstr; switch (cbLeft) { case 1: return RT_MAKE_U64_FROM_U8(pDis->abInstr[offInstr], 0, 0, 0, 0, 0, 0, 0); case 2: return RT_MAKE_U64_FROM_U8(pDis->abInstr[offInstr], pDis->abInstr[offInstr + 1], 0, 0, 0, 0, 0, 0); case 3: return RT_MAKE_U64_FROM_U8(pDis->abInstr[offInstr ], pDis->abInstr[offInstr + 1], pDis->abInstr[offInstr + 2], 0, 0, 0, 0, 0); case 4: return RT_MAKE_U64_FROM_U8(pDis->abInstr[offInstr ], pDis->abInstr[offInstr + 1], pDis->abInstr[offInstr + 2], pDis->abInstr[offInstr + 3], 0, 0, 0, 0); case 5: return RT_MAKE_U64_FROM_U8(pDis->abInstr[offInstr ], pDis->abInstr[offInstr + 1], pDis->abInstr[offInstr + 2], pDis->abInstr[offInstr + 3], pDis->abInstr[offInstr + 4], 0, 0, 0); case 6: return RT_MAKE_U64_FROM_U8(pDis->abInstr[offInstr ], pDis->abInstr[offInstr + 1], pDis->abInstr[offInstr + 2], pDis->abInstr[offInstr + 3], pDis->abInstr[offInstr + 4], pDis->abInstr[offInstr + 5], 0, 0); case 7: return RT_MAKE_U64_FROM_U8(pDis->abInstr[offInstr ], pDis->abInstr[offInstr + 1], pDis->abInstr[offInstr + 2], pDis->abInstr[offInstr + 3], pDis->abInstr[offInstr + 4], pDis->abInstr[offInstr + 5], pDis->abInstr[offInstr + 6], 0); default: if (cbLeft >= 8) return RT_MAKE_U64_FROM_U8(pDis->abInstr[offInstr ], pDis->abInstr[offInstr + 1], pDis->abInstr[offInstr + 2], pDis->abInstr[offInstr + 3], pDis->abInstr[offInstr + 4], pDis->abInstr[offInstr + 5], pDis->abInstr[offInstr + 6], pDis->abInstr[offInstr + 7]); return 0; } } disReadMore(pDis, (uint8_t)offInstr, 8); #ifdef DIS_HOST_UNALIGNED_ACCESS_OK return *(uint64_t const *)&pDis->abInstr[offInstr]; #else return RT_MAKE_U64_FROM_U8(pDis->abInstr[offInstr ], pDis->abInstr[offInstr + 1], pDis->abInstr[offInstr + 2], pDis->abInstr[offInstr + 3], pDis->abInstr[offInstr + 4], pDis->abInstr[offInstr + 5], pDis->abInstr[offInstr + 6], pDis->abInstr[offInstr + 7]); #endif } /** * Read a qword (64-bit) instruction. * * @returns The requested qword. * @param pDis The disassembler state. * @param uAddress The address. */ DECLINLINE(uint64_t) disReadQWord(PDISSTATE pDis, size_t offInstr) { if (RT_UNLIKELY(offInstr + 8 > pDis->cbCachedInstr)) return disReadQWordSlow(pDis, offInstr); #ifdef DIS_HOST_UNALIGNED_ACCESS_OK return *(uint64_t const *)&pDis->abInstr[offInstr]; #else return RT_MAKE_U64_FROM_U8(pDis->abInstr[offInstr ], pDis->abInstr[offInstr + 1], pDis->abInstr[offInstr + 2], pDis->abInstr[offInstr + 3], pDis->abInstr[offInstr + 4], pDis->abInstr[offInstr + 5], pDis->abInstr[offInstr + 6], pDis->abInstr[offInstr + 7]); #endif } //***************************************************************************** //***************************************************************************** static size_t disParseInstruction(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis) { Assert(pOp); Assert(pDis); // Store the opcode format string for disasmPrintf pDis->pCurInstr = pOp; /* * Apply filter to instruction type to determine if a full disassembly is required. * Note! Multibyte opcodes are always marked harmless until the final byte. */ bool fFiltered; if ((pOp->fOpType & pDis->fFilter) == 0) { fFiltered = true; pDis->pfnDisasmFnTable = g_apfnCalcSize; } else { /* Not filtered out -> full disassembly */ fFiltered = false; pDis->pfnDisasmFnTable = g_apfnFullDisasm; } // Should contain the parameter type on input pDis->Param1.fParam = pOp->fParam1; pDis->Param2.fParam = pOp->fParam2; pDis->Param3.fParam = pOp->fParam3; pDis->Param4.fParam = pOp->fParam4; /* Correct the operand size if the instruction is marked as forced or default 64 bits */ if (pDis->uCpuMode == DISCPUMODE_64BIT) { if (pOp->fOpType & DISOPTYPE_FORCED_64_OP_SIZE) pDis->uOpMode = DISCPUMODE_64BIT; else if ( (pOp->fOpType & DISOPTYPE_DEFAULT_64_OP_SIZE) && !(pDis->fPrefix & DISPREFIX_OPSIZE)) pDis->uOpMode = DISCPUMODE_64BIT; } else if (pOp->fOpType & DISOPTYPE_FORCED_32_OP_SIZE_X86) { /* Forced 32 bits operand size for certain instructions (mov crx, mov drx). */ Assert(pDis->uCpuMode != DISCPUMODE_64BIT); pDis->uOpMode = DISCPUMODE_32BIT; } if (pOp->idxParse1 != IDX_ParseNop) { offInstr = pDis->pfnDisasmFnTable[pOp->idxParse1](offInstr, pOp, pDis, &pDis->Param1); if (fFiltered == false) pDis->Param1.cb = DISGetParamSize(pDis, &pDis->Param1); } if (pOp->idxParse2 != IDX_ParseNop) { offInstr = pDis->pfnDisasmFnTable[pOp->idxParse2](offInstr, pOp, pDis, &pDis->Param2); if (fFiltered == false) pDis->Param2.cb = DISGetParamSize(pDis, &pDis->Param2); } if (pOp->idxParse3 != IDX_ParseNop) { offInstr = pDis->pfnDisasmFnTable[pOp->idxParse3](offInstr, pOp, pDis, &pDis->Param3); if (fFiltered == false) pDis->Param3.cb = DISGetParamSize(pDis, &pDis->Param3); } if (pOp->idxParse4 != IDX_ParseNop) { offInstr = pDis->pfnDisasmFnTable[pOp->idxParse4](offInstr, pOp, pDis, &pDis->Param4); if (fFiltered == false) pDis->Param4.cb = DISGetParamSize(pDis, &pDis->Param4); } // else simple one byte instruction return offInstr; } //***************************************************************************** /* Floating point opcode parsing */ //***************************************************************************** static size_t ParseEscFP(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { PCDISOPCODE fpop; RT_NOREF_PV(pOp); uint8_t ModRM = disReadByte(pDis, offInstr); uint8_t index = pDis->bOpCode - 0xD8; if (ModRM <= 0xBF) { fpop = &(g_apMapX86_FP_Low[index])[MODRM_REG(ModRM)]; pDis->pCurInstr = fpop; // Should contain the parameter type on input pDis->Param1.fParam = fpop->fParam1; pDis->Param2.fParam = fpop->fParam2; } else { fpop = &(g_apMapX86_FP_High[index])[ModRM - 0xC0]; pDis->pCurInstr = fpop; } /* * Apply filter to instruction type to determine if a full disassembly is required. * @note Multibyte opcodes are always marked harmless until the final byte. */ if ((fpop->fOpType & pDis->fFilter) == 0) pDis->pfnDisasmFnTable = g_apfnCalcSize; else /* Not filtered out -> full disassembly */ pDis->pfnDisasmFnTable = g_apfnFullDisasm; /* Correct the operand size if the instruction is marked as forced or default 64 bits */ if (pDis->uCpuMode == DISCPUMODE_64BIT) { /* Note: redundant, but just in case this ever changes */ if (fpop->fOpType & DISOPTYPE_FORCED_64_OP_SIZE) pDis->uOpMode = DISCPUMODE_64BIT; else if ( (fpop->fOpType & DISOPTYPE_DEFAULT_64_OP_SIZE) && !(pDis->fPrefix & DISPREFIX_OPSIZE)) pDis->uOpMode = DISCPUMODE_64BIT; } // Little hack to make sure the ModRM byte is included in the returned size if (fpop->idxParse1 != IDX_ParseModRM && fpop->idxParse2 != IDX_ParseModRM) offInstr++; //ModRM byte if (fpop->idxParse1 != IDX_ParseNop) offInstr = pDis->pfnDisasmFnTable[fpop->idxParse1](offInstr, fpop, pDis, pParam); if (fpop->idxParse2 != IDX_ParseNop) offInstr = pDis->pfnDisasmFnTable[fpop->idxParse2](offInstr, fpop, pDis, pParam); return offInstr; } /******************************************************************************************************************************** * * * SIB byte: (not 16-bit mode) * 7 - 6 5 - 3 2-0 * Scale Index Base * * ********************************************************************************************************************************/ static void UseSIB(PDISSTATE pDis, PDISOPPARAM pParam) { unsigned scale = pDis->SIB.Bits.Scale; unsigned base = pDis->SIB.Bits.Base; unsigned index = pDis->SIB.Bits.Index; unsigned regtype, vregtype; /* There's no way to distinguish between SIB and VSIB * and having special parameter to parse explicitly VSIB * is not an options since only one instruction (gather) * supports it currently. May be changed in the future. */ if (pDis->uAddrMode == DISCPUMODE_32BIT) regtype = DISUSE_REG_GEN32; else regtype = DISUSE_REG_GEN64; if (pDis->pCurInstr->uOpcode == OP_GATHER) vregtype = (VEXREG_IS256B(pDis->bVexDestReg) ? DISUSE_REG_YMM : DISUSE_REG_XMM); else vregtype = regtype; if (index != 4) { pParam->fUse |= DISUSE_INDEX | vregtype; pParam->Index.idxGenReg = index; if (scale != 0) { pParam->fUse |= DISUSE_SCALE; pParam->uScale = (1<ModRM.Bits.Mod == 0) { // [scaled index] + disp32 if (pDis->uAddrMode == DISCPUMODE_32BIT) { pParam->fUse |= DISUSE_DISPLACEMENT32; pParam->uDisp.i32 = pDis->i32SibDisp; } else { /* sign-extend to 64 bits */ pParam->fUse |= DISUSE_DISPLACEMENT64; pParam->uDisp.i64 = pDis->i32SibDisp; } } else { pParam->fUse |= DISUSE_BASE | regtype; pParam->Base.idxGenReg = base; } return; /* Already fetched everything in ParseSIB; no size returned */ } static size_t ParseSIB(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); RT_NOREF_PV(pParam); uint8_t SIB = disReadByte(pDis, offInstr); offInstr++; pDis->SIB.Bits.Base = SIB_BASE(SIB); pDis->SIB.Bits.Index = SIB_INDEX(SIB); pDis->SIB.Bits.Scale = SIB_SCALE(SIB); if (pDis->fPrefix & DISPREFIX_REX) { /* REX.B extends the Base field if not scaled index + disp32 */ if (!(pDis->SIB.Bits.Base == 5 && pDis->ModRM.Bits.Mod == 0)) pDis->SIB.Bits.Base |= (!!(pDis->fRexPrefix & DISPREFIX_REX_FLAGS_B)) << 3; pDis->SIB.Bits.Index |= (!!(pDis->fRexPrefix & DISPREFIX_REX_FLAGS_X)) << 3; } if ( pDis->SIB.Bits.Base == 5 && pDis->ModRM.Bits.Mod == 0) { /* Additional 32 bits displacement. No change in long mode. */ pDis->i32SibDisp = disReadDWord(pDis, offInstr); offInstr += 4; } return offInstr; } static size_t ParseSIB_SizeOnly(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); RT_NOREF_PV(pParam); uint8_t SIB = disReadByte(pDis, offInstr); offInstr++; pDis->SIB.Bits.Base = SIB_BASE(SIB); pDis->SIB.Bits.Index = SIB_INDEX(SIB); pDis->SIB.Bits.Scale = SIB_SCALE(SIB); if (pDis->fPrefix & DISPREFIX_REX) { /* REX.B extends the Base field. */ pDis->SIB.Bits.Base |= ((!!(pDis->fRexPrefix & DISPREFIX_REX_FLAGS_B)) << 3); /* REX.X extends the Index field. */ pDis->SIB.Bits.Index |= ((!!(pDis->fRexPrefix & DISPREFIX_REX_FLAGS_X)) << 3); } if ( pDis->SIB.Bits.Base == 5 && pDis->ModRM.Bits.Mod == 0) { /* Additional 32 bits displacement. No change in long mode. */ offInstr += 4; } return offInstr; } /******************************************************************************************************************************** * * * ModR/M byte: * 7 - 6 5 - 3 2-0 * Mod Reg/Opcode R/M * * ********************************************************************************************************************************/ static void disasmModRMReg(unsigned idx, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam, int fRegAddr) { RT_NOREF_PV(pOp); RT_NOREF_PV(pDis); #ifdef LOG_ENABLED unsigned type = OP_PARM_VTYPE(pParam->fParam); #endif unsigned subtype = OP_PARM_VSUBTYPE(pParam->fParam); if (fRegAddr) subtype = (pDis->uAddrMode == DISCPUMODE_64BIT) ? OP_PARM_q : OP_PARM_d; else if (subtype == OP_PARM_v || subtype == OP_PARM_NONE || subtype == OP_PARM_y) { switch (pDis->uOpMode) { case DISCPUMODE_32BIT: subtype = OP_PARM_d; break; case DISCPUMODE_64BIT: subtype = OP_PARM_q; break; case DISCPUMODE_16BIT: if (subtype != OP_PARM_y) subtype = OP_PARM_w; break; default: /* make gcc happy */ break; } } switch (subtype) { case OP_PARM_b: Assert(idx < (pDis->fPrefix & DISPREFIX_REX ? 16U : 8U)); /* AH, BH, CH & DH map to DIL, SIL, EBL & SPL when a rex prefix is present. */ /* Intel 64 and IA-32 Architectures Software Developer's Manual: 3.4.1.1 */ if ( (pDis->fPrefix & DISPREFIX_REX) && idx >= DISGREG_AH && idx <= DISGREG_BH) { idx += (DISGREG_SPL - DISGREG_AH); } pParam->fUse |= DISUSE_REG_GEN8; pParam->Base.idxGenReg = idx; break; case OP_PARM_w: Assert(idx < (pDis->fPrefix & DISPREFIX_REX ? 16U : 8U)); pParam->fUse |= DISUSE_REG_GEN16; pParam->Base.idxGenReg = idx; break; case OP_PARM_d: Assert(idx < (pDis->fPrefix & DISPREFIX_REX ? 16U : 8U)); pParam->fUse |= DISUSE_REG_GEN32; pParam->Base.idxGenReg = idx; break; case OP_PARM_q: pParam->fUse |= DISUSE_REG_GEN64; pParam->Base.idxGenReg = idx; break; default: Log(("disasmModRMReg %x:%x failed!!\n", type, subtype)); pDis->rc = VERR_DIS_INVALID_MODRM; break; } } static void disasmModRMReg16(unsigned idx, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { static const uint8_t s_auBaseModRMReg16[8] = { DISGREG_BX, DISGREG_BX, DISGREG_BP, DISGREG_BP, DISGREG_SI, DISGREG_DI, DISGREG_BP, DISGREG_BX }; RT_NOREF_PV(pDis); RT_NOREF_PV(pOp); pParam->fUse |= DISUSE_REG_GEN16; pParam->Base.idxGenReg = s_auBaseModRMReg16[idx]; if (idx < 4) { static const uint8_t s_auIndexModRMReg16[4] = { DISGREG_SI, DISGREG_DI, DISGREG_SI, DISGREG_DI }; pParam->fUse |= DISUSE_INDEX; pParam->Index.idxGenReg = s_auIndexModRMReg16[idx]; } } static void disasmModRMSReg(unsigned idx, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); if (idx >= DISSELREG_END) { Log(("disasmModRMSReg %d failed!!\n", idx)); pDis->rc = VERR_DIS_INVALID_PARAMETER; return; } pParam->fUse |= DISUSE_REG_SEG; pParam->Base.idxSegReg = (DISSELREG)idx; } static size_t UseModRM(size_t const offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { unsigned vtype = OP_PARM_VTYPE(pParam->fParam); uint8_t reg = pDis->ModRM.Bits.Reg; uint8_t mod = pDis->ModRM.Bits.Mod; uint8_t rm = pDis->ModRM.Bits.Rm; switch (vtype) { case OP_PARM_G: //general purpose register disasmModRMReg(reg, pOp, pDis, pParam, 0); return offInstr; default: if (IS_OP_PARM_RARE(vtype)) { switch (vtype) { case OP_PARM_C: //control register pParam->fUse |= DISUSE_REG_CR; if ( pDis->pCurInstr->uOpcode == OP_MOV_CR && pDis->uOpMode == DISCPUMODE_32BIT && (pDis->fPrefix & DISPREFIX_LOCK)) { pDis->fPrefix &= ~DISPREFIX_LOCK; pParam->Base.idxCtrlReg = DISCREG_CR8; } else pParam->Base.idxCtrlReg = reg; return offInstr; case OP_PARM_D: //debug register pParam->fUse |= DISUSE_REG_DBG; pParam->Base.idxDbgReg = reg; return offInstr; case OP_PARM_Q: //MMX or memory operand if (mod != 3) break; /* memory operand */ reg = rm; /* the RM field specifies the xmm register */ RT_FALL_THRU(); case OP_PARM_P: //MMX register reg &= 7; /* REX.R has no effect here */ pParam->fUse |= DISUSE_REG_MMX; pParam->Base.idxMmxReg = reg; return offInstr; case OP_PARM_S: //segment register reg &= 7; /* REX.R has no effect here */ disasmModRMSReg(reg, pOp, pDis, pParam); pParam->fUse |= DISUSE_REG_SEG; return offInstr; case OP_PARM_T: //test register reg &= 7; /* REX.R has no effect here */ pParam->fUse |= DISUSE_REG_TEST; pParam->Base.idxTestReg = reg; return offInstr; case OP_PARM_W: //XMM register or memory operand if (mod != 3) break; /* memory operand */ RT_FALL_THRU(); case OP_PARM_U: // XMM/YMM register reg = rm; /* the RM field specifies the xmm register */ RT_FALL_THRU(); case OP_PARM_V: //XMM register if (VEXREG_IS256B(pDis->bVexDestReg) && OP_PARM_VSUBTYPE(pParam->fParam) != OP_PARM_dq && OP_PARM_VSUBTYPE(pParam->fParam) != OP_PARM_q && OP_PARM_VSUBTYPE(pParam->fParam) != OP_PARM_d && OP_PARM_VSUBTYPE(pParam->fParam) != OP_PARM_w) { // Use YMM register if VEX.L is set. pParam->fUse |= DISUSE_REG_YMM; pParam->Base.idxYmmReg = reg; } else { pParam->fUse |= DISUSE_REG_XMM; pParam->Base.idxXmmReg = reg; } return offInstr; } } } /** @todo bound */ if (pDis->uAddrMode != DISCPUMODE_16BIT) { Assert(pDis->uAddrMode == DISCPUMODE_32BIT || pDis->uAddrMode == DISCPUMODE_64BIT); /* * Note: displacements in long mode are 8 or 32 bits and sign-extended to 64 bits */ switch (mod) { case 0: //effective address if (rm == 4) /* SIB byte follows ModRM */ UseSIB(pDis, pParam); else if (rm == 5) { /* 32 bits displacement */ if (pDis->uCpuMode != DISCPUMODE_64BIT) { pParam->fUse |= DISUSE_DISPLACEMENT32; pParam->uDisp.i32 = pDis->i32SibDisp; } else { pParam->fUse |= DISUSE_RIPDISPLACEMENT32; pParam->uDisp.i32 = pDis->i32SibDisp; } } else { //register address pParam->fUse |= DISUSE_BASE; disasmModRMReg(rm, pOp, pDis, pParam, 1); } break; case 1: //effective address + 8 bits displacement if (rm == 4) /* SIB byte follows ModRM */ UseSIB(pDis, pParam); else { pParam->fUse |= DISUSE_BASE; disasmModRMReg(rm, pOp, pDis, pParam, 1); } pParam->uDisp.i8 = pDis->i32SibDisp; pParam->fUse |= DISUSE_DISPLACEMENT8; break; case 2: //effective address + 32 bits displacement if (rm == 4) /* SIB byte follows ModRM */ UseSIB(pDis, pParam); else { pParam->fUse |= DISUSE_BASE; disasmModRMReg(rm, pOp, pDis, pParam, 1); } pParam->uDisp.i32 = pDis->i32SibDisp; pParam->fUse |= DISUSE_DISPLACEMENT32; break; case 3: //registers disasmModRMReg(rm, pOp, pDis, pParam, 0); break; } } else {//16 bits addressing mode switch (mod) { case 0: //effective address if (rm == 6) {//16 bits displacement pParam->uDisp.i16 = pDis->i32SibDisp; pParam->fUse |= DISUSE_DISPLACEMENT16; } else { pParam->fUse |= DISUSE_BASE; disasmModRMReg16(rm, pOp, pDis, pParam); } break; case 1: //effective address + 8 bits displacement disasmModRMReg16(rm, pOp, pDis, pParam); pParam->uDisp.i8 = pDis->i32SibDisp; pParam->fUse |= DISUSE_BASE | DISUSE_DISPLACEMENT8; break; case 2: //effective address + 16 bits displacement disasmModRMReg16(rm, pOp, pDis, pParam); pParam->uDisp.i16 = pDis->i32SibDisp; pParam->fUse |= DISUSE_BASE | DISUSE_DISPLACEMENT16; break; case 3: //registers disasmModRMReg(rm, pOp, pDis, pParam, 0); break; } } return offInstr; } //***************************************************************************** // Query the size of the ModRM parameters and fetch the immediate data (if any) //***************************************************************************** static size_t QueryModRM(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { uint8_t mod = pDis->ModRM.Bits.Mod; uint8_t rm = pDis->ModRM.Bits.Rm; if (pDis->uAddrMode != DISCPUMODE_16BIT) { Assert(pDis->uAddrMode == DISCPUMODE_32BIT || pDis->uAddrMode == DISCPUMODE_64BIT); /* * Note: displacements in long mode are 8 or 32 bits and sign-extended to 64 bits */ if (mod != 3 && rm == 4) /* SIB byte follows ModRM */ offInstr = ParseSIB(offInstr, pOp, pDis, pParam); switch (mod) { case 0: /* Effective address */ if (rm == 5) /* 32 bits displacement */ { pDis->i32SibDisp = disReadDWord(pDis, offInstr); offInstr += 4; } /* else register address */ break; case 1: /* Effective address + 8 bits displacement */ pDis->i32SibDisp = (int8_t)disReadByte(pDis, offInstr); offInstr++; break; case 2: /* Effective address + 32 bits displacement */ pDis->i32SibDisp = disReadDWord(pDis, offInstr); offInstr += 4; break; case 3: /* registers */ break; } } else { /* 16 bits mode */ switch (mod) { case 0: /* Effective address */ if (rm == 6) { pDis->i32SibDisp = disReadWord(pDis, offInstr); offInstr += 2; } /* else register address */ break; case 1: /* Effective address + 8 bits displacement */ pDis->i32SibDisp = (int8_t)disReadByte(pDis, offInstr); offInstr++; break; case 2: /* Effective address + 32 bits displacement */ pDis->i32SibDisp = (int16_t)disReadWord(pDis, offInstr); offInstr += 2; break; case 3: /* registers */ break; } } return offInstr; } //***************************************************************************** // Parse the ModRM parameters and fetch the immediate data (if any) //***************************************************************************** static size_t QueryModRM_SizeOnly(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { uint8_t mod = pDis->ModRM.Bits.Mod; uint8_t rm = pDis->ModRM.Bits.Rm; if (pDis->uAddrMode != DISCPUMODE_16BIT) { Assert(pDis->uAddrMode == DISCPUMODE_32BIT || pDis->uAddrMode == DISCPUMODE_64BIT); /* * Note: displacements in long mode are 8 or 32 bits and sign-extended to 64 bits */ if (mod != 3 && rm == 4) { /* SIB byte follows ModRM */ offInstr = ParseSIB_SizeOnly(offInstr, pOp, pDis, pParam); } switch (mod) { case 0: //effective address if (rm == 5) /* 32 bits displacement */ offInstr += 4; /* else register address */ break; case 1: /* Effective address + 8 bits displacement */ offInstr += 1; break; case 2: /* Effective address + 32 bits displacement */ offInstr += 4; break; case 3: /* registers */ break; } } else { /* 16 bits mode */ switch (mod) { case 0: //effective address if (rm == 6) offInstr += 2; /* else register address */ break; case 1: /* Effective address + 8 bits displacement */ offInstr++; break; case 2: /* Effective address + 32 bits displacement */ offInstr += 2; break; case 3: /* registers */ break; } } return offInstr; } //***************************************************************************** //***************************************************************************** static size_t ParseIllegal(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); RT_NOREF_PV(pParam); RT_NOREF_PV(pDis); AssertFailed(); return offInstr; } //***************************************************************************** //***************************************************************************** static size_t ParseModRM(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { uint8_t ModRM = disReadByte(pDis, offInstr); offInstr++; pDis->ModRM.Bits.Rm = MODRM_RM(ModRM); pDis->ModRM.Bits.Mod = MODRM_MOD(ModRM); pDis->ModRM.Bits.Reg = MODRM_REG(ModRM); /* Disregard the mod bits for certain instructions (mov crx, mov drx). * * From the AMD manual: * This instruction is always treated as a register-to-register (MOD = 11) instruction, regardless of the * encoding of the MOD field in the MODR/M byte. */ if (pOp->fOpType & DISOPTYPE_MOD_FIXED_11) pDis->ModRM.Bits.Mod = 3; if (pDis->fPrefix & DISPREFIX_REX) { Assert(pDis->uCpuMode == DISCPUMODE_64BIT); /* REX.R extends the Reg field. */ pDis->ModRM.Bits.Reg |= ((!!(pDis->fRexPrefix & DISPREFIX_REX_FLAGS_R)) << 3); /* REX.B extends the Rm field if there is no SIB byte nor a 32 bits displacement */ if (!( pDis->ModRM.Bits.Mod != 3 && pDis->ModRM.Bits.Rm == 4) && !( pDis->ModRM.Bits.Mod == 0 && pDis->ModRM.Bits.Rm == 5)) { pDis->ModRM.Bits.Rm |= ((!!(pDis->fRexPrefix & DISPREFIX_REX_FLAGS_B)) << 3); } } offInstr = QueryModRM(offInstr, pOp, pDis, pParam); return UseModRM(offInstr, pOp, pDis, pParam); } //***************************************************************************** //***************************************************************************** static size_t ParseModRM_SizeOnly(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { uint8_t ModRM = disReadByte(pDis, offInstr); offInstr++; pDis->ModRM.Bits.Rm = MODRM_RM(ModRM); pDis->ModRM.Bits.Mod = MODRM_MOD(ModRM); pDis->ModRM.Bits.Reg = MODRM_REG(ModRM); /* Disregard the mod bits for certain instructions (mov crx, mov drx). * * From the AMD manual: * This instruction is always treated as a register-to-register (MOD = 11) instruction, regardless of the * encoding of the MOD field in the MODR/M byte. */ if (pOp->fOpType & DISOPTYPE_MOD_FIXED_11) pDis->ModRM.Bits.Mod = 3; if (pDis->fPrefix & DISPREFIX_REX) { Assert(pDis->uCpuMode == DISCPUMODE_64BIT); /* REX.R extends the Reg field. */ pDis->ModRM.Bits.Reg |= ((!!(pDis->fRexPrefix & DISPREFIX_REX_FLAGS_R)) << 3); /* REX.B extends the Rm field if there is no SIB byte nor a 32 bits displacement */ if (!( pDis->ModRM.Bits.Mod != 3 && pDis->ModRM.Bits.Rm == 4) && !( pDis->ModRM.Bits.Mod == 0 && pDis->ModRM.Bits.Rm == 5)) { pDis->ModRM.Bits.Rm |= ((!!(pDis->fRexPrefix & DISPREFIX_REX_FLAGS_B)) << 3); } } offInstr = QueryModRM_SizeOnly(offInstr, pOp, pDis, pParam); /* UseModRM is not necessary here; we're only interested in the opcode size */ return offInstr; } //***************************************************************************** //***************************************************************************** static size_t ParseModFence(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); RT_NOREF_PV(pParam); RT_NOREF_PV(pDis); /* Note! Only used in group 15, so we must account for the mod/rm byte. */ return offInstr + 1; } //***************************************************************************** //***************************************************************************** static size_t ParseImmByte(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); uint8_t byte = disReadByte(pDis, offInstr); if (pParam->fParam == OP_PARM_Lx) { pParam->fUse |= (VEXREG_IS256B(pDis->bVexDestReg) ? DISUSE_REG_YMM : DISUSE_REG_XMM); // Ignore MSB in 32-bit mode. if (pDis->uCpuMode == DISCPUMODE_32BIT) byte &= 0x7f; pParam->Base.idxXmmReg = byte >> 4; } else { pParam->uValue = byte; pParam->fUse |= DISUSE_IMMEDIATE8; pParam->cb = sizeof(uint8_t); } return offInstr + 1; } //***************************************************************************** //***************************************************************************** static size_t ParseImmByte_SizeOnly(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); RT_NOREF_PV(pParam); RT_NOREF_PV(pDis); return offInstr + 1; } //***************************************************************************** //***************************************************************************** static size_t ParseImmByteSX(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); if (pDis->uOpMode == DISCPUMODE_32BIT) { pParam->uValue = (uint32_t)(int8_t)disReadByte(pDis, offInstr); pParam->fUse |= DISUSE_IMMEDIATE32_SX8; pParam->cb = sizeof(uint32_t); } else if (pDis->uOpMode == DISCPUMODE_64BIT) { pParam->uValue = (uint64_t)(int8_t)disReadByte(pDis, offInstr); pParam->fUse |= DISUSE_IMMEDIATE64_SX8; pParam->cb = sizeof(uint64_t); } else { pParam->uValue = (uint16_t)(int8_t)disReadByte(pDis, offInstr); pParam->fUse |= DISUSE_IMMEDIATE16_SX8; pParam->cb = sizeof(uint16_t); } return offInstr + 1; } //***************************************************************************** //***************************************************************************** static size_t ParseImmByteSX_SizeOnly(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); RT_NOREF_PV(pParam); RT_NOREF_PV(pDis); return offInstr + 1; } //***************************************************************************** //***************************************************************************** static size_t ParseImmUshort(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); pParam->uValue = disReadWord(pDis, offInstr); pParam->fUse |= DISUSE_IMMEDIATE16; pParam->cb = sizeof(uint16_t); return offInstr + 2; } //***************************************************************************** //***************************************************************************** static size_t ParseImmUshort_SizeOnly(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); RT_NOREF_PV(pParam); RT_NOREF_PV(pDis); return offInstr + 2; } //***************************************************************************** //***************************************************************************** static size_t ParseImmUlong(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); pParam->uValue = disReadDWord(pDis, offInstr); pParam->fUse |= DISUSE_IMMEDIATE32; pParam->cb = sizeof(uint32_t); return offInstr + 4; } //***************************************************************************** //***************************************************************************** static size_t ParseImmUlong_SizeOnly(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); RT_NOREF_PV(pParam); RT_NOREF_PV(pDis); return offInstr + 4; } //***************************************************************************** //***************************************************************************** static size_t ParseImmQword(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); pParam->uValue = disReadQWord(pDis, offInstr); pParam->fUse |= DISUSE_IMMEDIATE64; pParam->cb = sizeof(uint64_t); return offInstr + 8; } //***************************************************************************** //***************************************************************************** static size_t ParseImmQword_SizeOnly(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(offInstr); RT_NOREF_PV(pOp); RT_NOREF_PV(pParam); RT_NOREF_PV(pDis); return offInstr + 8; } //***************************************************************************** //***************************************************************************** static size_t ParseImmV(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); if (pDis->uOpMode == DISCPUMODE_32BIT) { pParam->uValue = disReadDWord(pDis, offInstr); pParam->fUse |= DISUSE_IMMEDIATE32; pParam->cb = sizeof(uint32_t); return offInstr + 4; } if (pDis->uOpMode == DISCPUMODE_64BIT) { pParam->uValue = disReadQWord(pDis, offInstr); pParam->fUse |= DISUSE_IMMEDIATE64; pParam->cb = sizeof(uint64_t); return offInstr + 8; } pParam->uValue = disReadWord(pDis, offInstr); pParam->fUse |= DISUSE_IMMEDIATE16; pParam->cb = sizeof(uint16_t); return offInstr + 2; } //***************************************************************************** //***************************************************************************** static size_t ParseImmV_SizeOnly(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(offInstr); RT_NOREF_PV(pOp); RT_NOREF_PV(pParam); if (pDis->uOpMode == DISCPUMODE_32BIT) return offInstr + 4; if (pDis->uOpMode == DISCPUMODE_64BIT) return offInstr + 8; return offInstr + 2; } //***************************************************************************** //***************************************************************************** static size_t ParseImmZ(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); /* Word for 16-bit operand-size or doubleword for 32 or 64-bit operand-size. */ if (pDis->uOpMode == DISCPUMODE_16BIT) { pParam->uValue = disReadWord(pDis, offInstr); pParam->fUse |= DISUSE_IMMEDIATE16; pParam->cb = sizeof(uint16_t); return offInstr + 2; } /* 64 bits op mode means *sign* extend to 64 bits. */ if (pDis->uOpMode == DISCPUMODE_64BIT) { pParam->uValue = (uint64_t)(int32_t)disReadDWord(pDis, offInstr); pParam->fUse |= DISUSE_IMMEDIATE64; pParam->cb = sizeof(uint64_t); } else { pParam->uValue = disReadDWord(pDis, offInstr); pParam->fUse |= DISUSE_IMMEDIATE32; pParam->cb = sizeof(uint32_t); } return offInstr + 4; } //***************************************************************************** //***************************************************************************** static size_t ParseImmZ_SizeOnly(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(offInstr); RT_NOREF_PV(pOp); RT_NOREF_PV(pParam); /* Word for 16-bit operand-size or doubleword for 32 or 64-bit operand-size. */ if (pDis->uOpMode == DISCPUMODE_16BIT) return offInstr + 2; return offInstr + 4; } //***************************************************************************** // Relative displacement for branches (rel. to next instruction) //***************************************************************************** static size_t ParseImmBRel(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); pParam->uValue = disReadByte(pDis, offInstr); pParam->fUse |= DISUSE_IMMEDIATE8_REL; pParam->cb = sizeof(uint8_t); return offInstr + 1; } //***************************************************************************** // Relative displacement for branches (rel. to next instruction) //***************************************************************************** static size_t ParseImmBRel_SizeOnly(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(offInstr); RT_NOREF_PV(pOp); RT_NOREF_PV(pParam); RT_NOREF_PV(pDis); return offInstr + 1; } //***************************************************************************** // Relative displacement for branches (rel. to next instruction) //***************************************************************************** static size_t ParseImmVRel(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); if (pDis->uOpMode == DISCPUMODE_32BIT) { pParam->uValue = disReadDWord(pDis, offInstr); pParam->fUse |= DISUSE_IMMEDIATE32_REL; pParam->cb = sizeof(int32_t); return offInstr + 4; } if (pDis->uOpMode == DISCPUMODE_64BIT) { /* 32 bits relative immediate sign extended to 64 bits. */ pParam->uValue = (uint64_t)(int32_t)disReadDWord(pDis, offInstr); pParam->fUse |= DISUSE_IMMEDIATE64_REL; pParam->cb = sizeof(int64_t); return offInstr + 4; } pParam->uValue = disReadWord(pDis, offInstr); pParam->fUse |= DISUSE_IMMEDIATE16_REL; pParam->cb = sizeof(int16_t); return offInstr + 2; } //***************************************************************************** // Relative displacement for branches (rel. to next instruction) //***************************************************************************** static size_t ParseImmVRel_SizeOnly(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(offInstr); RT_NOREF_PV(pOp); RT_NOREF_PV(pParam); if (pDis->uOpMode == DISCPUMODE_16BIT) return offInstr + 2; /* Both 32 & 64 bits mode use 32 bits relative immediates. */ return offInstr + 4; } //***************************************************************************** //***************************************************************************** static size_t ParseImmAddr(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); if (pDis->uAddrMode == DISCPUMODE_32BIT) { if (OP_PARM_VSUBTYPE(pParam->fParam) == OP_PARM_p) { /* far 16:32 pointer */ pParam->uValue = disReadDWord(pDis, offInstr); *((uint32_t*)&pParam->uValue+1) = disReadWord(pDis, offInstr+sizeof(uint32_t)); pParam->fUse |= DISUSE_IMMEDIATE_ADDR_16_32; pParam->cb = sizeof(uint16_t) + sizeof(uint32_t); return offInstr + 4 + 2; } /* * near 32 bits pointer * * Note: used only in "mov al|ax|eax, [Addr]" and "mov [Addr], al|ax|eax" * so we treat it like displacement. */ pParam->uDisp.i32 = disReadDWord(pDis, offInstr); pParam->fUse |= DISUSE_DISPLACEMENT32; pParam->cb = sizeof(uint32_t); return offInstr + 4; } if (pDis->uAddrMode == DISCPUMODE_64BIT) { /* * near 64 bits pointer * * Note: used only in "mov al|ax|eax, [Addr]" and "mov [Addr], al|ax|eax" * so we treat it like displacement. */ Assert(OP_PARM_VSUBTYPE(pParam->fParam) != OP_PARM_p); pParam->uDisp.i64 = disReadQWord(pDis, offInstr); pParam->fUse |= DISUSE_DISPLACEMENT64; pParam->cb = sizeof(uint64_t); return offInstr + 8; } if (OP_PARM_VSUBTYPE(pParam->fParam) == OP_PARM_p) { /* far 16:16 pointer */ pParam->uValue = disReadDWord(pDis, offInstr); pParam->fUse |= DISUSE_IMMEDIATE_ADDR_16_16; pParam->cb = 2*sizeof(uint16_t); return offInstr + 4; } /* * near 16 bits pointer * * Note: used only in "mov al|ax|eax, [Addr]" and "mov [Addr], al|ax|eax" * so we treat it like displacement. */ pParam->uDisp.i16 = disReadWord(pDis, offInstr); pParam->fUse |= DISUSE_DISPLACEMENT16; pParam->cb = sizeof(uint16_t); return offInstr + 2; } //***************************************************************************** //***************************************************************************** static size_t ParseImmAddr_SizeOnly(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(offInstr); RT_NOREF_PV(pOp); if (pDis->uAddrMode == DISCPUMODE_32BIT) { if (OP_PARM_VSUBTYPE(pParam->fParam) == OP_PARM_p) return offInstr + 4 + 2; /* far 16:32 pointer */ return offInstr + 4; /* near 32 bits pointer */ } if (pDis->uAddrMode == DISCPUMODE_64BIT) { Assert(OP_PARM_VSUBTYPE(pParam->fParam) != OP_PARM_p); return offInstr + 8; } if (OP_PARM_VSUBTYPE(pParam->fParam) == OP_PARM_p) return offInstr + 4; /* far 16:16 pointer */ return offInstr + 2; /* near 16 bits pointer */ } //***************************************************************************** //***************************************************************************** static size_t ParseImmAddrF(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); // immediate far pointers - only 16:16 or 16:32; determined by operand, *not* address size! Assert(pDis->uOpMode == DISCPUMODE_16BIT || pDis->uOpMode == DISCPUMODE_32BIT); Assert(OP_PARM_VSUBTYPE(pParam->fParam) == OP_PARM_p); if (pDis->uOpMode == DISCPUMODE_32BIT) { // far 16:32 pointer pParam->uValue = disReadDWord(pDis, offInstr); *((uint32_t*)&pParam->uValue+1) = disReadWord(pDis, offInstr+sizeof(uint32_t)); pParam->fUse |= DISUSE_IMMEDIATE_ADDR_16_32; pParam->cb = sizeof(uint16_t) + sizeof(uint32_t); return offInstr + 4 + 2; } // far 16:16 pointer pParam->uValue = disReadDWord(pDis, offInstr); pParam->fUse |= DISUSE_IMMEDIATE_ADDR_16_16; pParam->cb = 2*sizeof(uint16_t); return offInstr + 2 + 2; } //***************************************************************************** //***************************************************************************** static size_t ParseImmAddrF_SizeOnly(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(offInstr); RT_NOREF_PV(pOp); // immediate far pointers - only 16:16 or 16:32 Assert(pDis->uOpMode == DISCPUMODE_16BIT || pDis->uOpMode == DISCPUMODE_32BIT); Assert(OP_PARM_VSUBTYPE(pParam->fParam) == OP_PARM_p); RT_NOREF_PV(pParam); if (pDis->uOpMode == DISCPUMODE_32BIT) return offInstr + 4 + 2; /* far 16:32 pointer */ return offInstr + 2 + 2; /* far 16:16 pointer */ } //***************************************************************************** //***************************************************************************** static size_t ParseFixedReg(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(offInstr); /* * Sets up flags for stored in OPC fixed registers. */ if (pParam->fParam == OP_PARM_NONE) { /* No parameter at all. */ return offInstr; } AssertCompile(OP_PARM_REG_GEN32_END < OP_PARM_REG_SEG_END); AssertCompile(OP_PARM_REG_SEG_END < OP_PARM_REG_GEN16_END); AssertCompile(OP_PARM_REG_GEN16_END < OP_PARM_REG_GEN8_END); AssertCompile(OP_PARM_REG_GEN8_END < OP_PARM_REG_FP_END); if (pParam->fParam <= OP_PARM_REG_GEN32_END) { /* 32-bit EAX..EDI registers. */ if (pDis->uOpMode == DISCPUMODE_32BIT) { /* Use 32-bit registers. */ pParam->Base.idxGenReg = pParam->fParam - OP_PARM_REG_GEN32_START; pParam->fUse |= DISUSE_REG_GEN32; pParam->cb = 4; } else if (pDis->uOpMode == DISCPUMODE_64BIT) { /* Use 64-bit registers. */ pParam->Base.idxGenReg = pParam->fParam - OP_PARM_REG_GEN32_START; pParam->fUse |= DISUSE_REG_GEN64; pParam->cb = 8; } else { /* Use 16-bit registers. */ pParam->Base.idxGenReg = pParam->fParam - OP_PARM_REG_GEN32_START; pParam->fUse |= DISUSE_REG_GEN16; pParam->cb = 2; pParam->fParam = pParam->fParam - OP_PARM_REG_GEN32_START + OP_PARM_REG_GEN16_START; } if ( (pOp->fOpType & DISOPTYPE_REXB_EXTENDS_OPREG) && pParam == &pDis->Param1 /* ugly assumption that it only applies to the first parameter */ && (pDis->fPrefix & DISPREFIX_REX) && (pDis->fRexPrefix & DISPREFIX_REX_FLAGS_B)) { Assert(pDis->uCpuMode == DISCPUMODE_64BIT); pParam->Base.idxGenReg += 8; } } else if (pParam->fParam <= OP_PARM_REG_SEG_END) { /* Segment ES..GS registers. */ pParam->Base.idxSegReg = (DISSELREG)(pParam->fParam - OP_PARM_REG_SEG_START); pParam->fUse |= DISUSE_REG_SEG; pParam->cb = 2; } else if (pParam->fParam <= OP_PARM_REG_GEN16_END) { /* 16-bit AX..DI registers. */ pParam->Base.idxGenReg = pParam->fParam - OP_PARM_REG_GEN16_START; pParam->fUse |= DISUSE_REG_GEN16; pParam->cb = 2; } else if (pParam->fParam <= OP_PARM_REG_GEN8_END) { /* 8-bit AL..DL, AH..DH registers. */ pParam->Base.idxGenReg = pParam->fParam - OP_PARM_REG_GEN8_START; pParam->fUse |= DISUSE_REG_GEN8; pParam->cb = 1; if ( pDis->uCpuMode == DISCPUMODE_64BIT && (pOp->fOpType & DISOPTYPE_REXB_EXTENDS_OPREG) && pParam == &pDis->Param1 /* ugly assumption that it only applies to the first parameter */ && (pDis->fPrefix & DISPREFIX_REX)) { if (pDis->fRexPrefix & DISPREFIX_REX_FLAGS_B) pParam->Base.idxGenReg += 8; /* least significant byte of R8-R15 */ else if ( pParam->Base.idxGenReg >= DISGREG_AH && pParam->Base.idxGenReg <= DISGREG_BH) pParam->Base.idxGenReg += DISGREG_SPL - DISGREG_AH; } } else if (pParam->fParam <= OP_PARM_REG_FP_END) { /* FPU registers. */ pParam->Base.idxFpuReg = pParam->fParam - OP_PARM_REG_FP_START; pParam->fUse |= DISUSE_REG_FP; pParam->cb = 10; } Assert(!(pParam->fParam >= OP_PARM_REG_GEN64_START && pParam->fParam <= OP_PARM_REG_GEN64_END)); /* else - not supported for now registers. */ return offInstr; } //***************************************************************************** //***************************************************************************** static size_t ParseXv(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); pParam->fUse |= DISUSE_POINTER_DS_BASED; if (pDis->uAddrMode == DISCPUMODE_32BIT) { pParam->Base.idxGenReg = DISGREG_ESI; pParam->fUse |= DISUSE_REG_GEN32; } else if (pDis->uAddrMode == DISCPUMODE_64BIT) { pParam->Base.idxGenReg = DISGREG_RSI; pParam->fUse |= DISUSE_REG_GEN64; } else { pParam->Base.idxGenReg = DISGREG_SI; pParam->fUse |= DISUSE_REG_GEN16; } return offInstr; } //***************************************************************************** //***************************************************************************** static size_t ParseXb(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); pParam->fUse |= DISUSE_POINTER_DS_BASED; if (pDis->uAddrMode == DISCPUMODE_32BIT) { pParam->Base.idxGenReg = DISGREG_ESI; pParam->fUse |= DISUSE_REG_GEN32; } else if (pDis->uAddrMode == DISCPUMODE_64BIT) { pParam->Base.idxGenReg = DISGREG_RSI; pParam->fUse |= DISUSE_REG_GEN64; } else { pParam->Base.idxGenReg = DISGREG_SI; pParam->fUse |= DISUSE_REG_GEN16; } return offInstr; } //***************************************************************************** //***************************************************************************** static size_t ParseYv(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); pParam->fUse |= DISUSE_POINTER_ES_BASED; if (pDis->uAddrMode == DISCPUMODE_32BIT) { pParam->Base.idxGenReg = DISGREG_EDI; pParam->fUse |= DISUSE_REG_GEN32; } else if (pDis->uAddrMode == DISCPUMODE_64BIT) { pParam->Base.idxGenReg = DISGREG_RDI; pParam->fUse |= DISUSE_REG_GEN64; } else { pParam->Base.idxGenReg = DISGREG_DI; pParam->fUse |= DISUSE_REG_GEN16; } return offInstr; } //***************************************************************************** //***************************************************************************** static size_t ParseYb(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); pParam->fUse |= DISUSE_POINTER_ES_BASED; if (pDis->uAddrMode == DISCPUMODE_32BIT) { pParam->Base.idxGenReg = DISGREG_EDI; pParam->fUse |= DISUSE_REG_GEN32; } else if (pDis->uAddrMode == DISCPUMODE_64BIT) { pParam->Base.idxGenReg = DISGREG_RDI; pParam->fUse |= DISUSE_REG_GEN64; } else { pParam->Base.idxGenReg = DISGREG_DI; pParam->fUse |= DISUSE_REG_GEN16; } return offInstr; } //***************************************************************************** //***************************************************************************** static size_t ParseInvOpModRm(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); RT_NOREF_PV(pDis); RT_NOREF_PV(pParam); /* This is used to avoid a bunch of special hacks to get the ModRM byte included when encountering invalid opcodes in groups. */ return offInstr + 1; } //***************************************************************************** //***************************************************************************** static size_t ParseVexDest(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); unsigned type = OP_PARM_VTYPE(pParam->fParam); switch (type) { case OP_PARM_H: //XMM or YMM register if (VEXREG_IS256B(pDis->bVexDestReg)) { pParam->fUse |= DISUSE_REG_YMM; pParam->Base.idxYmmReg = (pDis->bVexDestReg >> 1) ^ 0xf; } else { pParam->fUse |= DISUSE_REG_XMM; pParam->Base.idxXmmReg = (pDis->bVexDestReg >> 1) ^ 0xf; } break; case OP_PARM_B: // Always OP_PARM_By. Change if it is not so. if ((pDis->fPrefix & DISPREFIX_REX) && (pDis->fRexPrefix & DISPREFIX_REX_FLAGS_W)) pParam->fUse |= DISUSE_REG_GEN64; else pParam->fUse |= DISUSE_REG_GEN32; /// @todo Check if the register number is correct pParam->Base.idxGenReg = (pDis->bVexDestReg >> 1) ^ 0xf; break; } return offInstr; } //***************************************************************************** //***************************************************************************** static size_t ParseTwoByteEsc(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); RT_NOREF_PV(pParam); /* 2nd byte */ pDis->bOpCode = disReadByte(pDis, offInstr); offInstr++; /* default to the non-prefixed table. */ PCDISOPCODE pOpcode = &g_aTwoByteMapX86[pDis->bOpCode]; /* Handle opcode table extensions that rely on the opsize, repe or repne prefix byte. */ /** @todo Should we take the first or last prefix byte in case of multiple prefix bytes??? */ if (pDis->bLastPrefix) { switch (pDis->bLastPrefix) { case OP_OPSIZE: /* 0x66 */ if (g_aTwoByteMapX86_PF66[pDis->bOpCode].uOpcode != OP_INVALID) { /* Table entry is valid, so use the extension table. */ pOpcode = &g_aTwoByteMapX86_PF66[pDis->bOpCode]; /* Cancel prefix changes. */ pDis->fPrefix &= ~DISPREFIX_OPSIZE; if (pDis->uCpuMode == DISCPUMODE_64BIT) { pDis->uOpMode = (pDis->fRexPrefix & DISPREFIX_REX_FLAGS_W ? DISCPUMODE_64BIT : DISCPUMODE_32BIT); } else pDis->uOpMode = pDis->uCpuMode; } break; case OP_REPNE: /* 0xF2 */ if (g_aTwoByteMapX86_PFF2[pDis->bOpCode].uOpcode != OP_INVALID) { /* Table entry is valid, so use the extension table. */ pOpcode = &g_aTwoByteMapX86_PFF2[pDis->bOpCode]; /* Cancel prefix changes. */ pDis->fPrefix &= ~DISPREFIX_REPNE; } break; case OP_REPE: /* 0xF3 */ if (g_aTwoByteMapX86_PFF3[pDis->bOpCode].uOpcode != OP_INVALID) { /* Table entry is valid, so use the extension table. */ pOpcode = &g_aTwoByteMapX86_PFF3[pDis->bOpCode]; /* Cancel prefix changes. */ pDis->fPrefix &= ~DISPREFIX_REP; } break; } } return disParseInstruction(offInstr, pOpcode, pDis); } //***************************************************************************** //***************************************************************************** static size_t ParseThreeByteEsc4(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); RT_NOREF_PV(pParam); /* 3rd byte */ pDis->bOpCode = disReadByte(pDis, offInstr); offInstr++; /* default to the non-prefixed table. */ PCDISOPCODE pOpcode; if (g_apThreeByteMapX86_0F38[pDis->bOpCode >> 4]) { pOpcode = g_apThreeByteMapX86_0F38[pDis->bOpCode >> 4]; pOpcode = &pOpcode[pDis->bOpCode & 0xf]; } else pOpcode = &g_InvalidOpcode[0]; /* Handle opcode table extensions that rely on the address, repne prefix byte. */ /** @todo Should we take the first or last prefix byte in case of multiple prefix bytes??? */ switch (pDis->bLastPrefix) { case OP_OPSIZE: /* 0x66 */ if (g_apThreeByteMapX86_660F38[pDis->bOpCode >> 4]) { pOpcode = g_apThreeByteMapX86_660F38[pDis->bOpCode >> 4]; pOpcode = &pOpcode[pDis->bOpCode & 0xf]; if (pOpcode->uOpcode != OP_INVALID) { /* Table entry is valid, so use the extension table. */ /* Cancel prefix changes. */ pDis->fPrefix &= ~DISPREFIX_OPSIZE; if (pDis->uCpuMode == DISCPUMODE_64BIT) { pDis->uOpMode = (pDis->fRexPrefix & DISPREFIX_REX_FLAGS_W ? DISCPUMODE_64BIT : DISCPUMODE_32BIT); } else pDis->uOpMode = pDis->uCpuMode; } } break; case OP_REPNE: /* 0xF2 */ if ((pDis->fPrefix & DISPREFIX_OPSIZE) && g_apThreeByteMapX86_66F20F38[pDis->bOpCode >> 4]) { /* 0x66F2 */ pOpcode = g_apThreeByteMapX86_66F20F38[pDis->bOpCode >> 4]; pOpcode = &pOpcode[pDis->bOpCode & 0xf]; if (pOpcode->uOpcode != OP_INVALID) { /* Table entry is valid, so use the extension table. */ /* Cancel prefix changes. */ pDis->fPrefix &= ~DISPREFIX_REPNE; pDis->fPrefix &= ~DISPREFIX_OPSIZE; if (pDis->uCpuMode == DISCPUMODE_64BIT) { pDis->uOpMode = (pDis->fRexPrefix & DISPREFIX_REX_FLAGS_W ? DISCPUMODE_64BIT : DISCPUMODE_32BIT); } else pDis->uOpMode = pDis->uCpuMode; } } else if (g_apThreeByteMapX86_F20F38[pDis->bOpCode >> 4]) { pOpcode = g_apThreeByteMapX86_F20F38[pDis->bOpCode >> 4]; pOpcode = &pOpcode[pDis->bOpCode & 0xf]; if (pOpcode->uOpcode != OP_INVALID) { /* Table entry is valid, so use the extension table. */ /* Cancel prefix changes. */ pDis->fPrefix &= ~DISPREFIX_REPNE; } } break; case OP_REPE: /* 0xF3 */ if (g_apThreeByteMapX86_F30F38[pDis->bOpCode >> 4]) { pOpcode = g_apThreeByteMapX86_F30F38[pDis->bOpCode >> 4]; pOpcode = &pOpcode[pDis->bOpCode & 0xf]; if (pOpcode->uOpcode != OP_INVALID) { /* Table entry is valid, so use the extension table. */ /* Cancel prefix changes. */ pDis->fPrefix &= ~DISPREFIX_REP; } } } return disParseInstruction(offInstr, pOpcode, pDis); } //***************************************************************************** //***************************************************************************** static size_t ParseThreeByteEsc5(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); RT_NOREF_PV(pParam); /* 3rd byte */ pDis->bOpCode = disReadByte(pDis, offInstr); offInstr++; /* default to the non-prefixed table. */ PCDISOPCODE pOpcode; if (g_apThreeByteMapX86_0F3A[pDis->bOpCode >> 4]) { pOpcode = g_apThreeByteMapX86_0F3A[pDis->bOpCode >> 4]; pOpcode = &pOpcode[pDis->bOpCode & 0xf]; } else pOpcode = &g_InvalidOpcode[0]; /** @todo Should we take the first or last prefix byte in case of multiple prefix bytes??? */ if (pDis->bLastPrefix == OP_OPSIZE && g_apThreeByteMapX86_660F3A[pDis->bOpCode >> 4]) { pOpcode = g_apThreeByteMapX86_660F3A[pDis->bOpCode >> 4]; pOpcode = &pOpcode[pDis->bOpCode & 0xf]; if (pOpcode->uOpcode != OP_INVALID) { /* Table entry is valid, so use the extension table. */ /* Cancel prefix changes. */ pDis->fPrefix &= ~DISPREFIX_OPSIZE; if (pDis->uCpuMode == DISCPUMODE_64BIT) { pDis->uOpMode = (pDis->fRexPrefix & DISPREFIX_REX_FLAGS_W ? DISCPUMODE_64BIT : DISCPUMODE_32BIT); } else pDis->uOpMode = pDis->uCpuMode; } } return disParseInstruction(offInstr, pOpcode, pDis); } //***************************************************************************** //***************************************************************************** static size_t ParseNopPause(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pParam); if (pDis->fPrefix & DISPREFIX_REP) { pOp = &g_aMapX86_NopPause[1]; /* PAUSE */ pDis->fPrefix &= ~DISPREFIX_REP; } else pOp = &g_aMapX86_NopPause[0]; /* NOP */ return disParseInstruction(offInstr, pOp, pDis); } //***************************************************************************** //***************************************************************************** static size_t ParseGrp1(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pParam); uint8_t modrm = disReadByte(pDis, offInstr); uint8_t reg = MODRM_REG(modrm); unsigned idx = (pDis->bOpCode - 0x80) * 8; pOp = &g_aMapX86_Group1[idx+reg]; return disParseInstruction(offInstr, pOp, pDis); } //***************************************************************************** //***************************************************************************** static size_t ParseShiftGrp2(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pParam); unsigned idx; switch (pDis->bOpCode) { case 0xC0: case 0xC1: idx = (pDis->bOpCode - 0xC0)*8; break; case 0xD0: case 0xD1: case 0xD2: case 0xD3: idx = (pDis->bOpCode - 0xD0 + 2)*8; break; default: Log(("ParseShiftGrp2: bOpCode=%#x\n", pDis->bOpCode)); pDis->rc = VERR_DIS_INVALID_OPCODE; return offInstr; } uint8_t modrm = disReadByte(pDis, offInstr); uint8_t reg = MODRM_REG(modrm); pOp = &g_aMapX86_Group2[idx+reg]; return disParseInstruction(offInstr, pOp, pDis); } //***************************************************************************** //***************************************************************************** static size_t ParseGrp3(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { unsigned idx = (pDis->bOpCode - 0xF6) * 8; RT_NOREF_PV(pParam); uint8_t modrm = disReadByte(pDis, offInstr); uint8_t reg = MODRM_REG(modrm); pOp = &g_aMapX86_Group3[idx+reg]; return disParseInstruction(offInstr, pOp, pDis); } //***************************************************************************** //***************************************************************************** static size_t ParseGrp4(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pParam); uint8_t modrm = disReadByte(pDis, offInstr); uint8_t reg = MODRM_REG(modrm); pOp = &g_aMapX86_Group4[reg]; return disParseInstruction(offInstr, pOp, pDis); } //***************************************************************************** //***************************************************************************** static size_t ParseGrp5(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pParam); uint8_t modrm = disReadByte(pDis, offInstr); uint8_t reg = MODRM_REG(modrm); pOp = &g_aMapX86_Group5[reg]; return disParseInstruction(offInstr, pOp, pDis); } //***************************************************************************** // 0xF 0xF [ModRM] [SIB] [displacement] imm8_opcode // It would appear the ModRM byte must always be present. How else can you // determine the offset of the imm8_opcode byte otherwise? // //***************************************************************************** static size_t Parse3DNow(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { /** @todo This code needs testing! Esp. wrt invalid opcodes. */ uint8_t ModRM = disReadByte(pDis, offInstr); pDis->ModRM.Bits.Rm = MODRM_RM(ModRM); pDis->ModRM.Bits.Mod = MODRM_MOD(ModRM); pDis->ModRM.Bits.Reg = MODRM_REG(ModRM); size_t offRet = QueryModRM(offInstr + 1, pOp, pDis, pParam); uint8_t opcode = disReadByte(pDis, offRet); offRet++; pOp = &g_aTwoByteMapX86_3DNow[opcode]; size_t offStrict = disParseInstruction(offInstr, pOp, pDis); AssertMsg(offStrict == offRet - 1 /* the imm8_opcode */ || pOp->uOpcode == OP_INVALID, ("offStrict=%#x offRet=%#x uOpCode=%u\n", offStrict, offRet, pOp->uOpcode)); RT_NOREF_PV(offStrict); return offRet; } //***************************************************************************** //***************************************************************************** static size_t ParseGrp6(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pParam); uint8_t modrm = disReadByte(pDis, offInstr); uint8_t reg = MODRM_REG(modrm); pOp = &g_aMapX86_Group6[reg]; return disParseInstruction(offInstr, pOp, pDis); } //***************************************************************************** //***************************************************************************** static size_t ParseGrp7(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pParam); uint8_t modrm = disReadByte(pDis, offInstr); uint8_t mod = MODRM_MOD(modrm); uint8_t reg = MODRM_REG(modrm); uint8_t rm = MODRM_RM(modrm); if (mod == 3 && rm == 0) pOp = &g_aMapX86_Group7_mod11_rm000[reg]; else if (mod == 3 && rm == 1) pOp = &g_aMapX86_Group7_mod11_rm001[reg]; else pOp = &g_aMapX86_Group7_mem[reg]; /* Cannot easily skip this hack because of monitor and vmcall! */ //little hack to make sure the ModRM byte is included in the returned size if (pOp->idxParse1 != IDX_ParseModRM && pOp->idxParse2 != IDX_ParseModRM) offInstr++; return disParseInstruction(offInstr, pOp, pDis); } //***************************************************************************** //***************************************************************************** static size_t ParseGrp8(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pParam); uint8_t modrm = disReadByte(pDis, offInstr); uint8_t reg = MODRM_REG(modrm); pOp = &g_aMapX86_Group8[reg]; return disParseInstruction(offInstr, pOp, pDis); } //***************************************************************************** //***************************************************************************** static size_t ParseGrp9(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pParam); uint8_t modrm = disReadByte(pDis, offInstr); uint8_t reg = MODRM_REG(modrm); pOp = &g_aMapX86_Group9[reg]; return disParseInstruction(offInstr, pOp, pDis); } //***************************************************************************** //***************************************************************************** static size_t ParseGrp10(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pParam); uint8_t modrm = disReadByte(pDis, offInstr); uint8_t reg = MODRM_REG(modrm); pOp = &g_aMapX86_Group10[reg]; return disParseInstruction(offInstr, pOp, pDis); } //***************************************************************************** //***************************************************************************** static size_t ParseGrp12(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pParam); uint8_t modrm = disReadByte(pDis, offInstr); uint8_t reg = MODRM_REG(modrm); if (pDis->fPrefix & DISPREFIX_OPSIZE) reg += 8; /* 2nd table */ pOp = &g_aMapX86_Group12[reg]; return disParseInstruction(offInstr, pOp, pDis); } //***************************************************************************** //***************************************************************************** static size_t ParseGrp13(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pParam); uint8_t modrm = disReadByte(pDis, offInstr); uint8_t reg = MODRM_REG(modrm); if (pDis->fPrefix & DISPREFIX_OPSIZE) reg += 8; /* 2nd table */ pOp = &g_aMapX86_Group13[reg]; return disParseInstruction(offInstr, pOp, pDis); } //***************************************************************************** //***************************************************************************** static size_t ParseGrp14(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pParam); uint8_t modrm = disReadByte(pDis, offInstr); uint8_t reg = MODRM_REG(modrm); if (pDis->fPrefix & DISPREFIX_OPSIZE) reg += 8; /* 2nd table */ pOp = &g_aMapX86_Group14[reg]; return disParseInstruction(offInstr, pOp, pDis); } //***************************************************************************** //***************************************************************************** static size_t ParseGrp15(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pParam); uint8_t modrm = disReadByte(pDis, offInstr); uint8_t mod = MODRM_MOD(modrm); uint8_t reg = MODRM_REG(modrm); uint8_t rm = MODRM_RM(modrm); if (mod == 3 && rm == 0) pOp = &g_aMapX86_Group15_mod11_rm000[reg]; else pOp = &g_aMapX86_Group15_mem[reg]; return disParseInstruction(offInstr, pOp, pDis); } //***************************************************************************** //***************************************************************************** static size_t ParseGrp16(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pParam); uint8_t modrm = disReadByte(pDis, offInstr); pOp = &g_aMapX86_Group16[MODRM_REG(modrm)]; return disParseInstruction(offInstr, pOp, pDis); } //***************************************************************************** //***************************************************************************** static size_t ParseVex2b(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); RT_NOREF_PV(pParam); PCDISOPCODE pOpCode = &g_InvalidOpcode[0]; uint8_t byte = disReadByte(pDis, offInstr++); pDis->bOpCode = disReadByte(pDis, offInstr++); pDis->bVexDestReg = VEX_2B2INT(byte); // VEX.R (equivalent to REX.R) if (pDis->uCpuMode == DISCPUMODE_64BIT && !(byte & 0x80)) { /* REX prefix byte */ pDis->fPrefix |= DISPREFIX_REX; pDis->fRexPrefix = DISPREFIX_REX_FLAGS_R; } switch(byte & 3) { case 0: pOpCode = g_aVexOpcodesMap[0] + pDis->bOpCode; break; // 0x66 prefix case 1: pOpCode = g_aVexOpcodesMap_66H[0] + pDis->bOpCode; break; // 0xF3 prefix case 2: pOpCode = g_aVexOpcodesMap_F3H[0] + pDis->bOpCode; break; // 0xF2 prefix case 3: pOpCode = g_aVexOpcodesMap_F2H[0] + pDis->bOpCode; break; default: break; } return disParseInstruction(offInstr, pOpCode, pDis); } //***************************************************************************** //***************************************************************************** static size_t ParseVex3b(size_t offInstr, PCDISOPCODE pOp, PDISSTATE pDis, PDISOPPARAM pParam) { RT_NOREF_PV(pOp); RT_NOREF_PV(pParam); PCDISOPCODE pOpCode = NULL; uint8_t byte1 = disReadByte(pDis, offInstr++); uint8_t byte2 = disReadByte(pDis, offInstr++); pDis->bOpCode = disReadByte(pDis, offInstr++); pDis->bVexDestReg = VEX_2B2INT(byte2); uint8_t implOpcode = (byte1 & 0x1f); // REX.RXB /** @todo Check this! was weird: ~(byte1 & 0xe0) */ if (pDis->uCpuMode == DISCPUMODE_64BIT && !(byte1 & 0xe0)) pDis->fRexPrefix |= (byte1 >> 5) ^ 7; // VEX.W pDis->bVexWFlag = !(byte2 & 0x80); if (pDis->fRexPrefix) pDis->fPrefix |= DISPREFIX_REX; switch(byte2 & 3) { case 0: if (implOpcode >= 1 && implOpcode <= 3) // Other values are #UD. { pOpCode = g_aVexOpcodesMap[implOpcode - 1]; if (pOpCode != NULL) { switch (implOpcode) { case 2: if (pDis->bOpCode >= 0xf0) pOpCode = &pOpCode[pDis->bOpCode - 0xf0]; else pOpCode = g_InvalidOpcode; break; default: pOpCode = &pOpCode[pDis->bOpCode]; } } } break; // 0x66 prefix case 1: if (implOpcode >= 1 && implOpcode <= 3) // Other values are #UD. { pOpCode = g_aVexOpcodesMap_66H[implOpcode - 1]; if (pOpCode != NULL) pOpCode = &pOpCode[pDis->bOpCode]; } break; // 0xF3 prefix case 2: if (implOpcode >= 1 && implOpcode <= 3) // Other values are #UD. { pOpCode = g_aVexOpcodesMap_F3H[implOpcode - 1]; if (pOpCode != NULL) { switch (implOpcode) { case 2: if (pDis->bOpCode >= 0xf0) pOpCode = &pOpCode[pDis->bOpCode - 0xf0]; else pOpCode = g_InvalidOpcode; break; default: pOpCode = &pOpCode[pDis->bOpCode]; } } } break; // 0xF2 prefix case 3: if (implOpcode >= 1 && implOpcode <= 3) // Other values are #UD. { pOpCode = g_aVexOpcodesMap_F2H[implOpcode - 1]; if (pOpCode != NULL) { switch (implOpcode) { case 2: if (pDis->bOpCode >= 0xf0) pOpCode = &pOpCode[pDis->bOpCode - 0xf0]; else pOpCode = g_InvalidOpcode; break; case 3: if (pDis->bOpCode != 0xf0) pOpCode = g_InvalidOpcode; break; default: pOpCode = &pOpCode[pDis->bOpCode]; } } } break; default: break; } if (pOpCode == NULL) pOpCode = g_InvalidOpcode; return disParseInstruction(offInstr, pOpCode, pDis); } /** * Validates the lock sequence. * * The AMD manual lists the following instructions: * ADC * ADD * AND * BTC * BTR * BTS * CMPXCHG * CMPXCHG8B * CMPXCHG16B * DEC * INC * NEG * NOT * OR * SBB * SUB * XADD * XCHG * XOR * * @param pDis Fully disassembled instruction. */ static void disValidateLockSequence(PDISSTATE pDis) { Assert(pDis->fPrefix & DISPREFIX_LOCK); /* * Filter out the valid lock sequences. */ switch (pDis->pCurInstr->uOpcode) { /* simple: no variations */ case OP_CMPXCHG8B: /* == OP_CMPXCHG16B? */ return; /* simple: /r - reject register destination. */ case OP_BTC: case OP_BTR: case OP_BTS: case OP_CMPXCHG: case OP_XADD: if (pDis->ModRM.Bits.Mod == 3) break; return; /* * Lots of variants but its sufficient to check that param 1 * is a memory operand. */ case OP_ADC: case OP_ADD: case OP_AND: case OP_DEC: case OP_INC: case OP_NEG: case OP_NOT: case OP_OR: case OP_SBB: case OP_SUB: case OP_XCHG: case OP_XOR: if (pDis->Param1.fUse & (DISUSE_BASE | DISUSE_INDEX | DISUSE_DISPLACEMENT64 | DISUSE_DISPLACEMENT32 | DISUSE_DISPLACEMENT16 | DISUSE_DISPLACEMENT8 | DISUSE_RIPDISPLACEMENT32)) return; break; default: break; } /* * Invalid lock sequence, make it a OP_ILLUD2. */ pDis->pCurInstr = &g_aTwoByteMapX86[11]; Assert(pDis->pCurInstr->uOpcode == OP_ILLUD2); } /** * Internal worker for DISInstrEx and DISInstrWithPrefetchedBytes. * * @returns VBox status code. * @param pDis Initialized disassembler state. * @param paOneByteMap The one byte opcode map to use. * @param pcbInstr Where to store the instruction size. Can be NULL. */ static int disInstrWorker(PDISSTATE pDis, PCDISOPCODE paOneByteMap, uint32_t *pcbInstr) { /* * Parse byte by byte. */ size_t offInstr = 0; for (;;) { uint8_t codebyte = disReadByte(pDis, offInstr++); uint8_t opcode = paOneByteMap[codebyte].uOpcode; /* Hardcoded assumption about OP_* values!! */ if (opcode <= OP_LAST_PREFIX) { /* The REX prefix must precede the opcode byte(s). Any other placement is ignored. */ if (opcode != OP_REX) { /* Last prefix byte (for SSE2 extension tables); don't include the REX prefix */ pDis->bLastPrefix = opcode; pDis->fPrefix &= ~DISPREFIX_REX; } switch (opcode) { case OP_INVALID: if (pcbInstr) *pcbInstr = (uint32_t)offInstr; return pDis->rc = VERR_DIS_INVALID_OPCODE; // segment override prefix byte case OP_SEG: pDis->idxSegPrefix = (DISSELREG)(paOneByteMap[codebyte].fParam1 - OP_PARM_REG_SEG_START); #if 0 /* Try be accurate in our reporting, shouldn't break anything... :-) */ /* Segment prefixes for CS, DS, ES and SS are ignored in long mode. */ if ( pDis->uCpuMode != DISCPUMODE_64BIT || pDis->idxSegPrefix >= DISSELREG_FS) pDis->fPrefix |= DISPREFIX_SEG; #else pDis->fPrefix |= DISPREFIX_SEG; #endif continue; //fetch the next byte // lock prefix byte case OP_LOCK: pDis->fPrefix |= DISPREFIX_LOCK; continue; //fetch the next byte // address size override prefix byte case OP_ADDRSIZE: pDis->fPrefix |= DISPREFIX_ADDRSIZE; if (pDis->uCpuMode == DISCPUMODE_16BIT) pDis->uAddrMode = DISCPUMODE_32BIT; else if (pDis->uCpuMode == DISCPUMODE_32BIT) pDis->uAddrMode = DISCPUMODE_16BIT; else pDis->uAddrMode = DISCPUMODE_32BIT; /* 64 bits */ continue; //fetch the next byte // operand size override prefix byte case OP_OPSIZE: pDis->fPrefix |= DISPREFIX_OPSIZE; if (pDis->uCpuMode == DISCPUMODE_16BIT) pDis->uOpMode = DISCPUMODE_32BIT; else pDis->uOpMode = DISCPUMODE_16BIT; /* for 32 and 64 bits mode (there is no 32 bits operand size override prefix) */ continue; //fetch the next byte // rep and repne are not really prefixes, but we'll treat them as such case OP_REPE: pDis->fPrefix |= DISPREFIX_REP; continue; //fetch the next byte case OP_REPNE: pDis->fPrefix |= DISPREFIX_REPNE; continue; //fetch the next byte case OP_REX: Assert(pDis->uCpuMode == DISCPUMODE_64BIT); /* REX prefix byte */ pDis->fPrefix |= DISPREFIX_REX; pDis->fRexPrefix = DISPREFIX_REX_OP_2_FLAGS(paOneByteMap[codebyte].fParam1); if (pDis->fRexPrefix & DISPREFIX_REX_FLAGS_W) pDis->uOpMode = DISCPUMODE_64BIT; /* overrides size prefix byte */ continue; //fetch the next byte default: break; } } /* Check if this is a VEX prefix. Not for 32-bit mode. */ if (pDis->uCpuMode != DISCPUMODE_64BIT && (opcode == OP_LES || opcode == OP_LDS) && (disReadByte(pDis, offInstr) & 0xc0) == 0xc0) { paOneByteMap = g_aOneByteMapX64; } /* first opcode byte. */ pDis->bOpCode = codebyte; pDis->cbPrefix = (uint8_t)offInstr - 1; offInstr = disParseInstruction(offInstr, &paOneByteMap[pDis->bOpCode], pDis); break; } pDis->cbInstr = (uint8_t)offInstr; if (pcbInstr) *pcbInstr = (uint32_t)offInstr; if (pDis->fPrefix & DISPREFIX_LOCK) disValidateLockSequence(pDis); return pDis->rc; } /** * Inlined worker that initializes the disassembler state. * * @returns The primary opcode map to use. * @param pDis The disassembler state. * @param uInstrAddr The instruction address. * @param enmCpuMode The CPU mode. * @param fFilter The instruction filter settings. * @param pfnReadBytes The byte reader, can be NULL. * @param pvUser The user data for the reader. */ DECL_FORCE_INLINE(PCDISOPCODE) disInitializeState(PDISSTATE pDis, RTUINTPTR uInstrAddr, DISCPUMODE enmCpuMode, uint32_t fFilter, PFNDISREADBYTES pfnReadBytes, void *pvUser) { RT_ZERO(*pDis); #ifdef VBOX_STRICT /* poison */ pDis->Param1.Base.idxGenReg = 0xc1; pDis->Param2.Base.idxGenReg = 0xc2; pDis->Param3.Base.idxGenReg = 0xc3; pDis->Param1.Index.idxGenReg = 0xc4; pDis->Param2.Index.idxGenReg = 0xc5; pDis->Param3.Index.idxGenReg = 0xc6; pDis->Param1.uDisp.u64 = UINT64_C(0xd1d1d1d1d1d1d1d1); pDis->Param2.uDisp.u64 = UINT64_C(0xd2d2d2d2d2d2d2d2); pDis->Param3.uDisp.u64 = UINT64_C(0xd3d3d3d3d3d3d3d3); pDis->Param1.uValue = UINT64_C(0xb1b1b1b1b1b1b1b1); pDis->Param2.uValue = UINT64_C(0xb2b2b2b2b2b2b2b2); pDis->Param3.uValue = UINT64_C(0xb3b3b3b3b3b3b3b3); pDis->Param1.uScale = 28; pDis->Param2.uScale = 29; pDis->Param3.uScale = 30; #endif pDis->fPrefix = DISPREFIX_NONE; pDis->idxSegPrefix = DISSELREG_DS; pDis->rc = VINF_SUCCESS; pDis->pfnDisasmFnTable = g_apfnFullDisasm; pDis->uInstrAddr = uInstrAddr; pDis->fFilter = fFilter; pDis->pfnReadBytes = pfnReadBytes ? pfnReadBytes : disReadBytesDefault; pDis->pvUser = pvUser; pDis->uCpuMode = enmCpuMode; PCDISOPCODE paOneByteMap; if (enmCpuMode == DISCPUMODE_64BIT) { pDis->uAddrMode = DISCPUMODE_64BIT; pDis->uOpMode = DISCPUMODE_32BIT; paOneByteMap = g_aOneByteMapX64; } else { pDis->uAddrMode = enmCpuMode; pDis->uOpMode = enmCpuMode; paOneByteMap = g_aOneByteMapX86; } return paOneByteMap; } /** * Reads some bytes into the cache. * * While this will set DISSTATE::rc on failure, the caller should disregard * this since that is what would happen if we didn't prefetch bytes prior to the * instruction parsing. * * @param pDis The disassembler state. */ DECL_FORCE_INLINE(void) disPrefetchBytes(PDISSTATE pDis) { /* * Read some bytes into the cache. (If this fail we continue as nothing * has gone wrong since this is what would happen if we didn't precharge * the cache here.) */ int rc = pDis->pfnReadBytes(pDis, 0, 1, sizeof(pDis->abInstr)); if (RT_SUCCESS(rc)) { Assert(pDis->cbCachedInstr >= 1); Assert(pDis->cbCachedInstr <= sizeof(pDis->abInstr)); } else { Log(("Initial read failed with rc=%Rrc!!\n", rc)); pDis->rc = rc; } } /** * Disassembles on instruction, details in @a pDis and length in @a pcbInstr. * * @returns VBox status code. * @param uInstrAddr Address of the instruction to decode. What this means * is left to the pfnReadBytes function. * @param enmCpuMode The CPU mode. DISCPUMODE_32BIT, DISCPUMODE_16BIT, or DISCPUMODE_64BIT. * @param pfnReadBytes Callback for reading instruction bytes. * @param fFilter Instruction type filter. * @param pvUser User argument for the instruction reader. (Ends up in pvUser.) * @param pDis Pointer to disassembler state (output). * @param pcbInstr Where to store the size of the instruction. (This * is also stored in PDISSTATE::cbInstr.) Optional. */ DISDECL(int) DISInstrEx(RTUINTPTR uInstrAddr, DISCPUMODE enmCpuMode, uint32_t fFilter, PFNDISREADBYTES pfnReadBytes, void *pvUser, PDISSTATE pDis, uint32_t *pcbInstr) { PCDISOPCODE paOneByteMap = disInitializeState(pDis, uInstrAddr, enmCpuMode, fFilter, pfnReadBytes, pvUser); disPrefetchBytes(pDis); return disInstrWorker(pDis, paOneByteMap, pcbInstr); } /** * Disassembles on instruction partially or fully from prefetched bytes, details * in @a pDis and length in @a pcbInstr. * * @returns VBox status code. * @param uInstrAddr Address of the instruction to decode. What this means * is left to the pfnReadBytes function. * @param enmCpuMode The CPU mode. DISCPUMODE_32BIT, DISCPUMODE_16BIT, or DISCPUMODE_64BIT. * @param pvPrefetched Pointer to the prefetched bytes. * @param cbPrefetched The number of valid bytes pointed to by @a * pbPrefetched. * @param pfnReadBytes Callback for reading instruction bytes. * @param fFilter Instruction type filter. * @param pvUser User argument for the instruction reader. (Ends up in pvUser.) * @param pDis Pointer to disassembler state (output). * @param pcbInstr Where to store the size of the instruction. (This * is also stored in PDISSTATE::cbInstr.) Optional. */ DISDECL(int) DISInstrWithPrefetchedBytes(RTUINTPTR uInstrAddr, DISCPUMODE enmCpuMode, uint32_t fFilter, void const *pvPrefetched, size_t cbPretched, PFNDISREADBYTES pfnReadBytes, void *pvUser, PDISSTATE pDis, uint32_t *pcbInstr) { PCDISOPCODE paOneByteMap = disInitializeState(pDis, uInstrAddr, enmCpuMode, fFilter, pfnReadBytes, pvUser); if (!cbPretched) disPrefetchBytes(pDis); else { if (cbPretched >= sizeof(pDis->abInstr)) { memcpy(pDis->abInstr, pvPrefetched, sizeof(pDis->abInstr)); pDis->cbCachedInstr = (uint8_t)sizeof(pDis->abInstr); } else { memcpy(pDis->abInstr, pvPrefetched, cbPretched); pDis->cbCachedInstr = (uint8_t)cbPretched; } } return disInstrWorker(pDis, paOneByteMap, pcbInstr); } /** * Parses one guest instruction. * * The result is found in pDis and pcbInstr. * * @returns VBox status code. * @param uInstrAddr Address of the instruction to decode. What this means * is left to the pfnReadBytes function. * @param enmCpuMode The CPU mode. DISCPUMODE_32BIT, DISCPUMODE_16BIT, or DISCPUMODE_64BIT. * @param pfnReadBytes Callback for reading instruction bytes. * @param pvUser User argument for the instruction reader. (Ends up in pvUser.) * @param pDis Pointer to disassembler state (output). * @param pcbInstr Where to store the size of the instruction. * NULL is allowed. This is also stored in * PDISSTATE::cbInstr. */ DISDECL(int) DISInstrWithReader(RTUINTPTR uInstrAddr, DISCPUMODE enmCpuMode, PFNDISREADBYTES pfnReadBytes, void *pvUser, PDISSTATE pDis, uint32_t *pcbInstr) { return DISInstrEx(uInstrAddr, enmCpuMode, DISOPTYPE_ALL, pfnReadBytes, pvUser, pDis, pcbInstr); } /** * Parses one guest instruction. * * The result is found in pDis and pcbInstr. * * @returns VBox status code. * @param pvInstr Address of the instruction to decode. This is a * real address in the current context that can be * accessed without faulting. (Consider * DISInstrWithReader if this isn't the case.) * @param enmCpuMode The CPU mode. DISCPUMODE_32BIT, DISCPUMODE_16BIT, or DISCPUMODE_64BIT. * @param pfnReadBytes Callback for reading instruction bytes. * @param pvUser User argument for the instruction reader. (Ends up in pvUser.) * @param pDis Pointer to disassembler state (output). * @param pcbInstr Where to store the size of the instruction. * NULL is allowed. This is also stored in * PDISSTATE::cbInstr. */ DISDECL(int) DISInstr(const void *pvInstr, DISCPUMODE enmCpuMode, PDISSTATE pDis, uint32_t *pcbInstr) { return DISInstrEx((uintptr_t)pvInstr, enmCpuMode, DISOPTYPE_ALL, NULL /*pfnReadBytes*/, NULL /*pvUser*/, pDis, pcbInstr); }