/* $Id: IEMAllCImplStrInstr.cpp.h 39970 2012-02-02 21:29:12Z vboxsync $ */ /** @file * IEM - String Instruction Implementation Code Template. */ /* * Copyright (C) 2011 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. */ /******************************************************************************* * Defined Constants And Macros * *******************************************************************************/ #if OP_SIZE == 8 # define OP_rAX al #elif OP_SIZE == 16 # define OP_rAX ax #elif OP_SIZE == 32 # define OP_rAX eax #elif OP_SIZE == 64 # define OP_rAX rax #else # error "Bad OP_SIZE." #endif #define OP_TYPE RT_CONCAT3(uint,OP_SIZE,_t) #if ADDR_SIZE == 16 # define ADDR_rDI di # define ADDR_rSI si # define ADDR_rCX cx # define ADDR2_TYPE uint32_t #elif ADDR_SIZE == 32 # define ADDR_rDI edi # define ADDR_rSI esi # define ADDR_rCX ecx # define ADDR2_TYPE uint32_t #elif ADDR_SIZE == 64 # define ADDR_rDI rdi # define ADDR_rSI rsi # define ADDR_rCX rcx # define ADDR2_TYPE uint64_t #else # error "Bad ADDR_SIZE." #endif #define ADDR_TYPE RT_CONCAT3(uint,ADDR_SIZE,_t) /** * Implements 'REPE CMPS'. */ IEM_CIMPL_DEF_1(RT_CONCAT4(iemCImpl_repe_cmps_op,OP_SIZE,_addr,ADDR_SIZE), uint8_t, iEffSeg) { PCPUMCTX pCtx = pIemCpu->CTX_SUFF(pCtx); /* * Setup. */ ADDR_TYPE uCounterReg = pCtx->ADDR_rCX; if (uCounterReg == 0) { iemRegAddToRip(pIemCpu, cbInstr); return VINF_SUCCESS; } PCCPUMSELREGHID pSrc1Hid = iemSRegGetHid(pIemCpu, iEffSeg); VBOXSTRICTRC rcStrict = iemMemSegCheckReadAccessEx(pIemCpu, pSrc1Hid, iEffSeg); if (rcStrict != VINF_SUCCESS) return rcStrict; rcStrict = iemMemSegCheckReadAccessEx(pIemCpu, &pCtx->esHid, X86_SREG_ES); if (rcStrict != VINF_SUCCESS) return rcStrict; int8_t const cbIncr = pCtx->eflags.Bits.u1DF ? -(OP_SIZE / 8) : (OP_SIZE / 8); ADDR_TYPE uSrc1AddrReg = pCtx->ADDR_rSI; ADDR_TYPE uSrc2AddrReg = pCtx->ADDR_rDI; uint32_t uEFlags = pCtx->eflags.u; /* * The loop. */ do { /* * Do segmentation and virtual page stuff. */ #if ADDR_SIZE != 64 ADDR2_TYPE uVirtSrc1Addr = (uint32_t)pSrc1Hid->u64Base + uSrc1AddrReg; ADDR2_TYPE uVirtSrc2Addr = (uint32_t)pCtx->esHid.u64Base + uSrc2AddrReg; #else uint64_t uVirtSrc1Addr = uSrc1AddrReg; uint64_t uVirtSrc2Addr = uSrc2AddrReg; #endif uint32_t cLeftSrc1Page = (PAGE_SIZE - (uVirtSrc1Addr & PAGE_OFFSET_MASK)) / (OP_SIZE / 8); if (cLeftSrc1Page > uCounterReg) cLeftSrc1Page = uCounterReg; uint32_t cLeftSrc2Page = (PAGE_SIZE - (uVirtSrc2Addr & PAGE_OFFSET_MASK)) / (OP_SIZE / 8); uint32_t cLeftPage = RT_MIN(cLeftSrc1Page, cLeftSrc2Page); if ( cLeftPage > 0 /* can be null if unaligned, do one fallback round. */ && cbIncr > 0 /** @todo Implement reverse direction string ops. */ #if ADDR_SIZE != 64 && uSrc1AddrReg < pSrc1Hid->u32Limit && uSrc1AddrReg + (cLeftPage * (OP_SIZE / 8)) <= pSrc1Hid->u32Limit && uSrc2AddrReg < pCtx->esHid.u32Limit && uSrc2AddrReg + (cLeftPage * (OP_SIZE / 8)) <= pCtx->esHid.u32Limit #endif ) { RTGCPHYS GCPhysSrc1Mem; rcStrict = iemMemPageTranslateAndCheckAccess(pIemCpu, uVirtSrc1Addr, IEM_ACCESS_DATA_R, &GCPhysSrc1Mem); if (rcStrict != VINF_SUCCESS) return rcStrict; RTGCPHYS GCPhysSrc2Mem; rcStrict = iemMemPageTranslateAndCheckAccess(pIemCpu, uVirtSrc2Addr, IEM_ACCESS_DATA_R, &GCPhysSrc2Mem); if (rcStrict != VINF_SUCCESS) return rcStrict; /* * If we can map the page without trouble, do a block processing * until the end of the current page. */ OP_TYPE const *puSrc2Mem; rcStrict = iemMemPageMap(pIemCpu, GCPhysSrc2Mem, IEM_ACCESS_DATA_R, (void **)&puSrc2Mem); if (rcStrict == VINF_SUCCESS) { OP_TYPE const *puSrc1Mem; rcStrict = iemMemPageMap(pIemCpu, GCPhysSrc1Mem, IEM_ACCESS_DATA_R, (void **)&puSrc1Mem); if (rcStrict == VINF_SUCCESS) { if (!memcmp(puSrc2Mem, puSrc1Mem, cLeftPage * (OP_SIZE / 8))) { /* All matches, only compare the last itme to get the right eflags. */ RT_CONCAT(iemAImpl_cmp_u,OP_SIZE)((OP_TYPE *)&puSrc1Mem[cLeftPage-1], puSrc2Mem[cLeftPage-1], &uEFlags); uSrc1AddrReg += cLeftPage * cbIncr; uSrc2AddrReg += cLeftPage * cbIncr; uCounterReg -= cLeftPage; } else { /* Some mismatch, compare each item (and keep volatile memory in mind). */ uint32_t off = 0; do { RT_CONCAT(iemAImpl_cmp_u,OP_SIZE)((OP_TYPE *)&puSrc1Mem[off], puSrc2Mem[off], &uEFlags); off++; } while ( off < cLeftPage && (uEFlags & X86_EFL_ZF)); uSrc1AddrReg += cbIncr * off; uSrc2AddrReg += cbIncr * off; uCounterReg -= off; } /* Update the registers before looping. */ pCtx->ADDR_rCX = uCounterReg; pCtx->ADDR_rSI = uSrc1AddrReg; pCtx->ADDR_rDI = uSrc2AddrReg; pCtx->eflags.u = uEFlags; iemMemPageUnmap(pIemCpu, GCPhysSrc1Mem, IEM_ACCESS_DATA_R, puSrc1Mem); iemMemPageUnmap(pIemCpu, GCPhysSrc2Mem, IEM_ACCESS_DATA_R, puSrc2Mem); continue; } } iemMemPageUnmap(pIemCpu, GCPhysSrc2Mem, IEM_ACCESS_DATA_R, puSrc2Mem); } /* * Fallback - slow processing till the end of the current page. * In the cross page boundrary case we will end up here with cLeftPage * as 0, we execute one loop then. */ do { OP_TYPE uValue1; rcStrict = RT_CONCAT(iemMemFetchDataU,OP_SIZE)(pIemCpu, &uValue1, iEffSeg, uSrc1AddrReg); if (rcStrict != VINF_SUCCESS) return rcStrict; OP_TYPE uValue2; rcStrict = RT_CONCAT(iemMemFetchDataU,OP_SIZE)(pIemCpu, &uValue2, X86_SREG_ES, uSrc2AddrReg); if (rcStrict != VINF_SUCCESS) return rcStrict; RT_CONCAT(iemAImpl_cmp_u,OP_SIZE)(&uValue1, uValue2, &uEFlags); pCtx->ADDR_rSI = uSrc1AddrReg += cbIncr; pCtx->ADDR_rDI = uSrc2AddrReg += cbIncr; pCtx->ADDR_rCX = --uCounterReg; pCtx->eflags.u = uEFlags; cLeftPage--; } while ( (int32_t)cLeftPage > 0 && (uEFlags & X86_EFL_ZF)); } while ( uCounterReg != 0 && (uEFlags & X86_EFL_ZF)); /* * Done. */ iemRegAddToRip(pIemCpu, cbInstr); return VINF_SUCCESS; } /** * Implements 'REPNE CMPS'. */ IEM_CIMPL_DEF_1(RT_CONCAT4(iemCImpl_repne_cmps_op,OP_SIZE,_addr,ADDR_SIZE), uint8_t, iEffSeg) { PCPUMCTX pCtx = pIemCpu->CTX_SUFF(pCtx); /* * Setup. */ ADDR_TYPE uCounterReg = pCtx->ADDR_rCX; if (uCounterReg == 0) { iemRegAddToRip(pIemCpu, cbInstr); return VINF_SUCCESS; } PCCPUMSELREGHID pSrc1Hid = iemSRegGetHid(pIemCpu, iEffSeg); VBOXSTRICTRC rcStrict = iemMemSegCheckReadAccessEx(pIemCpu, pSrc1Hid, iEffSeg); if (rcStrict != VINF_SUCCESS) return rcStrict; rcStrict = iemMemSegCheckReadAccessEx(pIemCpu, &pCtx->esHid, X86_SREG_ES); if (rcStrict != VINF_SUCCESS) return rcStrict; int8_t const cbIncr = pCtx->eflags.Bits.u1DF ? -(OP_SIZE / 8) : (OP_SIZE / 8); ADDR_TYPE uSrc1AddrReg = pCtx->ADDR_rSI; ADDR_TYPE uSrc2AddrReg = pCtx->ADDR_rDI; uint32_t uEFlags = pCtx->eflags.u; /* * The loop. */ do { /* * Do segmentation and virtual page stuff. */ #if ADDR_SIZE != 64 ADDR2_TYPE uVirtSrc1Addr = (uint32_t)pSrc1Hid->u64Base + uSrc1AddrReg; ADDR2_TYPE uVirtSrc2Addr = (uint32_t)pCtx->esHid.u64Base + uSrc2AddrReg; #else uint64_t uVirtSrc1Addr = uSrc1AddrReg; uint64_t uVirtSrc2Addr = uSrc2AddrReg; #endif uint32_t cLeftSrc1Page = (PAGE_SIZE - (uVirtSrc1Addr & PAGE_OFFSET_MASK)) / (OP_SIZE / 8); if (cLeftSrc1Page > uCounterReg) cLeftSrc1Page = uCounterReg; uint32_t cLeftSrc2Page = (PAGE_SIZE - (uVirtSrc2Addr & PAGE_OFFSET_MASK)) / (OP_SIZE / 8); uint32_t cLeftPage = RT_MIN(cLeftSrc1Page, cLeftSrc2Page); if ( cLeftPage > 0 /* can be null if unaligned, do one fallback round. */ && cbIncr > 0 /** @todo Implement reverse direction string ops. */ #if ADDR_SIZE != 64 && uSrc1AddrReg < pSrc1Hid->u32Limit && uSrc1AddrReg + (cLeftPage * (OP_SIZE / 8)) <= pSrc1Hid->u32Limit && uSrc2AddrReg < pCtx->esHid.u32Limit && uSrc2AddrReg + (cLeftPage * (OP_SIZE / 8)) <= pCtx->esHid.u32Limit #endif ) { RTGCPHYS GCPhysSrc1Mem; rcStrict = iemMemPageTranslateAndCheckAccess(pIemCpu, uVirtSrc1Addr, IEM_ACCESS_DATA_R, &GCPhysSrc1Mem); if (rcStrict != VINF_SUCCESS) return rcStrict; RTGCPHYS GCPhysSrc2Mem; rcStrict = iemMemPageTranslateAndCheckAccess(pIemCpu, uVirtSrc2Addr, IEM_ACCESS_DATA_R, &GCPhysSrc2Mem); if (rcStrict != VINF_SUCCESS) return rcStrict; /* * If we can map the page without trouble, do a block processing * until the end of the current page. */ OP_TYPE const *puSrc2Mem; rcStrict = iemMemPageMap(pIemCpu, GCPhysSrc2Mem, IEM_ACCESS_DATA_R, (void **)&puSrc2Mem); if (rcStrict == VINF_SUCCESS) { OP_TYPE const *puSrc1Mem; rcStrict = iemMemPageMap(pIemCpu, GCPhysSrc1Mem, IEM_ACCESS_DATA_R, (void **)&puSrc1Mem); if (rcStrict == VINF_SUCCESS) { if (memcmp(puSrc2Mem, puSrc1Mem, cLeftPage * (OP_SIZE / 8))) { /* All matches, only compare the last item to get the right eflags. */ RT_CONCAT(iemAImpl_cmp_u,OP_SIZE)((OP_TYPE *)&puSrc1Mem[cLeftPage-1], puSrc2Mem[cLeftPage-1], &uEFlags); uSrc1AddrReg += cLeftPage * cbIncr; uSrc2AddrReg += cLeftPage * cbIncr; uCounterReg -= cLeftPage; } else { /* Some mismatch, compare each item (and keep volatile memory in mind). */ uint32_t off = 0; do { RT_CONCAT(iemAImpl_cmp_u,OP_SIZE)((OP_TYPE *)&puSrc1Mem[off], puSrc2Mem[off], &uEFlags); off++; } while ( off < cLeftPage && !(uEFlags & X86_EFL_ZF)); uSrc1AddrReg += cbIncr * off; uSrc2AddrReg += cbIncr * off; uCounterReg -= off; } /* Update the registers before looping. */ pCtx->ADDR_rCX = uCounterReg; pCtx->ADDR_rSI = uSrc1AddrReg; pCtx->ADDR_rDI = uSrc2AddrReg; pCtx->eflags.u = uEFlags; iemMemPageUnmap(pIemCpu, GCPhysSrc1Mem, IEM_ACCESS_DATA_R, puSrc1Mem); iemMemPageUnmap(pIemCpu, GCPhysSrc2Mem, IEM_ACCESS_DATA_R, puSrc2Mem); continue; } iemMemPageUnmap(pIemCpu, GCPhysSrc2Mem, IEM_ACCESS_DATA_R, puSrc2Mem); } } /* * Fallback - slow processing till the end of the current page. * In the cross page boundrary case we will end up here with cLeftPage * as 0, we execute one loop then. */ do { OP_TYPE uValue1; rcStrict = RT_CONCAT(iemMemFetchDataU,OP_SIZE)(pIemCpu, &uValue1, iEffSeg, uSrc1AddrReg); if (rcStrict != VINF_SUCCESS) return rcStrict; OP_TYPE uValue2; rcStrict = RT_CONCAT(iemMemFetchDataU,OP_SIZE)(pIemCpu, &uValue2, X86_SREG_ES, uSrc2AddrReg); if (rcStrict != VINF_SUCCESS) return rcStrict; RT_CONCAT(iemAImpl_cmp_u,OP_SIZE)(&uValue1, uValue2, &uEFlags); pCtx->ADDR_rSI = uSrc1AddrReg += cbIncr; pCtx->ADDR_rDI = uSrc2AddrReg += cbIncr; pCtx->ADDR_rCX = --uCounterReg; pCtx->eflags.u = uEFlags; cLeftPage--; } while ( (int32_t)cLeftPage > 0 && !(uEFlags & X86_EFL_ZF)); } while ( uCounterReg != 0 && !(uEFlags & X86_EFL_ZF)); /* * Done. */ iemRegAddToRip(pIemCpu, cbInstr); return VINF_SUCCESS; } /** * Implements 'REPE SCAS'. */ IEM_CIMPL_DEF_0(RT_CONCAT4(iemCImpl_repe_scas_,OP_rAX,_m,ADDR_SIZE)) { PCPUMCTX pCtx = pIemCpu->CTX_SUFF(pCtx); /* * Setup. */ ADDR_TYPE uCounterReg = pCtx->ADDR_rCX; if (uCounterReg == 0) { iemRegAddToRip(pIemCpu, cbInstr); return VINF_SUCCESS; } VBOXSTRICTRC rcStrict = iemMemSegCheckReadAccessEx(pIemCpu, &pCtx->esHid, X86_SREG_ES); if (rcStrict != VINF_SUCCESS) return rcStrict; int8_t const cbIncr = pCtx->eflags.Bits.u1DF ? -(OP_SIZE / 8) : (OP_SIZE / 8); OP_TYPE const uValueReg = pCtx->OP_rAX; ADDR_TYPE uAddrReg = pCtx->ADDR_rDI; uint32_t uEFlags = pCtx->eflags.u; /* * The loop. */ do { /* * Do segmentation and virtual page stuff. */ #if ADDR_SIZE != 64 ADDR2_TYPE uVirtAddr = (uint32_t)pCtx->esHid.u64Base + uAddrReg; #else uint64_t uVirtAddr = uAddrReg; #endif uint32_t cLeftPage = (PAGE_SIZE - (uVirtAddr & PAGE_OFFSET_MASK)) / (OP_SIZE / 8); if (cLeftPage > uCounterReg) cLeftPage = uCounterReg; if ( cLeftPage > 0 /* can be null if unaligned, do one fallback round. */ && cbIncr > 0 /** @todo Implement reverse direction string ops. */ #if ADDR_SIZE != 64 && uAddrReg < pCtx->esHid.u32Limit && uAddrReg + (cLeftPage * (OP_SIZE / 8)) <= pCtx->esHid.u32Limit #endif ) { RTGCPHYS GCPhysMem; rcStrict = iemMemPageTranslateAndCheckAccess(pIemCpu, uVirtAddr, IEM_ACCESS_DATA_R, &GCPhysMem); if (rcStrict != VINF_SUCCESS) return rcStrict; /* * If we can map the page without trouble, do a block processing * until the end of the current page. */ OP_TYPE const *puMem; rcStrict = iemMemPageMap(pIemCpu, GCPhysMem, IEM_ACCESS_DATA_R, (void **)&puMem); if (rcStrict == VINF_SUCCESS) { /* Search till we find a mismatching item. */ OP_TYPE uTmpValue; bool fQuit; uint32_t i = 0; do { uTmpValue = puMem[i++]; fQuit = uTmpValue != uValueReg; } while (i < cLeftPage && !fQuit); /* Update the regs. */ RT_CONCAT(iemAImpl_cmp_u,OP_SIZE)((OP_TYPE *)&uValueReg, uTmpValue, &uEFlags); pCtx->ADDR_rCX = uCounterReg -= i; pCtx->ADDR_rDI = uAddrReg += i * cbIncr; pCtx->eflags.u = uEFlags; Assert(!(uEFlags & X86_EFL_ZF) == (i < cLeftPage)); iemMemPageUnmap(pIemCpu, GCPhysMem, IEM_ACCESS_DATA_R, puMem); if (fQuit) break; /* If unaligned, we drop thru and do the page crossing access below. Otherwise, do the next page. */ if (!(uVirtAddr & (OP_SIZE - 1))) continue; if (uCounterReg == 0) break; cLeftPage = 0; } } /* * Fallback - slow processing till the end of the current page. * In the cross page boundrary case we will end up here with cLeftPage * as 0, we execute one loop then. */ do { OP_TYPE uTmpValue; rcStrict = RT_CONCAT(iemMemFetchDataU,OP_SIZE)(pIemCpu, &uTmpValue, X86_SREG_ES, uAddrReg); if (rcStrict != VINF_SUCCESS) return rcStrict; RT_CONCAT(iemAImpl_cmp_u,OP_SIZE)((OP_TYPE *)&uValueReg, uTmpValue, &uEFlags); pCtx->ADDR_rDI = uAddrReg += cbIncr; pCtx->ADDR_rCX = --uCounterReg; pCtx->eflags.u = uEFlags; cLeftPage--; } while ( (int32_t)cLeftPage > 0 && (uEFlags & X86_EFL_ZF)); } while ( uCounterReg != 0 && (uEFlags & X86_EFL_ZF)); /* * Done. */ iemRegAddToRip(pIemCpu, cbInstr); return VINF_SUCCESS; } /** * Implements 'REPNE SCAS'. */ IEM_CIMPL_DEF_0(RT_CONCAT4(iemCImpl_repne_scas_,OP_rAX,_m,ADDR_SIZE)) { PCPUMCTX pCtx = pIemCpu->CTX_SUFF(pCtx); /* * Setup. */ ADDR_TYPE uCounterReg = pCtx->ADDR_rCX; if (uCounterReg == 0) { iemRegAddToRip(pIemCpu, cbInstr); return VINF_SUCCESS; } VBOXSTRICTRC rcStrict = iemMemSegCheckReadAccessEx(pIemCpu, &pCtx->esHid, X86_SREG_ES); if (rcStrict != VINF_SUCCESS) return rcStrict; int8_t const cbIncr = pCtx->eflags.Bits.u1DF ? -(OP_SIZE / 8) : (OP_SIZE / 8); OP_TYPE const uValueReg = pCtx->OP_rAX; ADDR_TYPE uAddrReg = pCtx->ADDR_rDI; uint32_t uEFlags = pCtx->eflags.u; /* * The loop. */ do { /* * Do segmentation and virtual page stuff. */ #if ADDR_SIZE != 64 ADDR2_TYPE uVirtAddr = (uint32_t)pCtx->esHid.u64Base + uAddrReg; #else uint64_t uVirtAddr = uAddrReg; #endif uint32_t cLeftPage = (PAGE_SIZE - (uVirtAddr & PAGE_OFFSET_MASK)) / (OP_SIZE / 8); if (cLeftPage > uCounterReg) cLeftPage = uCounterReg; if ( cLeftPage > 0 /* can be null if unaligned, do one fallback round. */ && cbIncr > 0 /** @todo Implement reverse direction string ops. */ #if ADDR_SIZE != 64 && uAddrReg < pCtx->esHid.u32Limit && uAddrReg + (cLeftPage * (OP_SIZE / 8)) <= pCtx->esHid.u32Limit #endif ) { RTGCPHYS GCPhysMem; rcStrict = iemMemPageTranslateAndCheckAccess(pIemCpu, uVirtAddr, IEM_ACCESS_DATA_R, &GCPhysMem); if (rcStrict != VINF_SUCCESS) return rcStrict; /* * If we can map the page without trouble, do a block processing * until the end of the current page. */ OP_TYPE const *puMem; rcStrict = iemMemPageMap(pIemCpu, GCPhysMem, IEM_ACCESS_DATA_R, (void **)&puMem); if (rcStrict == VINF_SUCCESS) { /* Search till we find a mismatching item. */ OP_TYPE uTmpValue; bool fQuit; uint32_t i = 0; do { uTmpValue = puMem[i++]; fQuit = uTmpValue == uValueReg; } while (i < cLeftPage && !fQuit); /* Update the regs. */ RT_CONCAT(iemAImpl_cmp_u,OP_SIZE)((OP_TYPE *)&uValueReg, uTmpValue, &uEFlags); pCtx->ADDR_rCX = uCounterReg -= i; pCtx->ADDR_rDI = uAddrReg += i * cbIncr; pCtx->eflags.u = uEFlags; Assert((!(uEFlags & X86_EFL_ZF) != (i < cLeftPage)) || (i == cLeftPage)); iemMemPageUnmap(pIemCpu, GCPhysMem, IEM_ACCESS_DATA_R, puMem); if (fQuit) break; /* If unaligned, we drop thru and do the page crossing access below. Otherwise, do the next page. */ if (!(uVirtAddr & (OP_SIZE - 1))) continue; if (uCounterReg == 0) break; cLeftPage = 0; } } /* * Fallback - slow processing till the end of the current page. * In the cross page boundrary case we will end up here with cLeftPage * as 0, we execute one loop then. */ do { OP_TYPE uTmpValue; rcStrict = RT_CONCAT(iemMemFetchDataU,OP_SIZE)(pIemCpu, &uTmpValue, X86_SREG_ES, uAddrReg); if (rcStrict != VINF_SUCCESS) return rcStrict; RT_CONCAT(iemAImpl_cmp_u,OP_SIZE)((OP_TYPE *)&uValueReg, uTmpValue, &uEFlags); pCtx->ADDR_rDI = uAddrReg += cbIncr; pCtx->ADDR_rCX = --uCounterReg; pCtx->eflags.u = uEFlags; cLeftPage--; } while ( (int32_t)cLeftPage > 0 && !(uEFlags & X86_EFL_ZF)); } while ( uCounterReg != 0 && !(uEFlags & X86_EFL_ZF)); /* * Done. */ iemRegAddToRip(pIemCpu, cbInstr); return VINF_SUCCESS; } /** * Implements 'REP MOVS'. */ IEM_CIMPL_DEF_1(RT_CONCAT4(iemCImpl_rep_movs_op,OP_SIZE,_addr,ADDR_SIZE), uint8_t, iEffSeg) { PCPUMCTX pCtx = pIemCpu->CTX_SUFF(pCtx); /* * Setup. */ ADDR_TYPE uCounterReg = pCtx->ADDR_rCX; if (uCounterReg == 0) { iemRegAddToRip(pIemCpu, cbInstr); return VINF_SUCCESS; } PCCPUMSELREGHID pSrcHid = iemSRegGetHid(pIemCpu, iEffSeg); VBOXSTRICTRC rcStrict = iemMemSegCheckReadAccessEx(pIemCpu, pSrcHid, iEffSeg); if (rcStrict != VINF_SUCCESS) return rcStrict; rcStrict = iemMemSegCheckWriteAccessEx(pIemCpu, &pCtx->esHid, X86_SREG_ES); if (rcStrict != VINF_SUCCESS) return rcStrict; int8_t const cbIncr = pCtx->eflags.Bits.u1DF ? -(OP_SIZE / 8) : (OP_SIZE / 8); ADDR_TYPE uSrcAddrReg = pCtx->ADDR_rSI; ADDR_TYPE uDstAddrReg = pCtx->ADDR_rDI; /* * The loop. */ do { /* * Do segmentation and virtual page stuff. */ #if ADDR_SIZE != 64 ADDR2_TYPE uVirtSrcAddr = (uint32_t)pSrcHid->u64Base + uSrcAddrReg; ADDR2_TYPE uVirtDstAddr = (uint32_t)pCtx->esHid.u64Base + uDstAddrReg; #else uint64_t uVirtSrcAddr = uSrcAddrReg; uint64_t uVirtDstAddr = uDstAddrReg; #endif uint32_t cLeftSrcPage = (PAGE_SIZE - (uVirtSrcAddr & PAGE_OFFSET_MASK)) / (OP_SIZE / 8); if (cLeftSrcPage > uCounterReg) cLeftSrcPage = uCounterReg; uint32_t cLeftDstPage = (PAGE_SIZE - (uVirtDstAddr & PAGE_OFFSET_MASK)) / (OP_SIZE / 8); uint32_t cLeftPage = RT_MIN(cLeftSrcPage, cLeftDstPage); if ( cLeftPage > 0 /* can be null if unaligned, do one fallback round. */ && cbIncr > 0 /** @todo Implement reverse direction string ops. */ #if ADDR_SIZE != 64 && uSrcAddrReg < pSrcHid->u32Limit && uSrcAddrReg + (cLeftPage * (OP_SIZE / 8)) <= pSrcHid->u32Limit && uDstAddrReg < pCtx->esHid.u32Limit && uDstAddrReg + (cLeftPage * (OP_SIZE / 8)) <= pCtx->esHid.u32Limit #endif ) { RTGCPHYS GCPhysSrcMem; rcStrict = iemMemPageTranslateAndCheckAccess(pIemCpu, uVirtSrcAddr, IEM_ACCESS_DATA_R, &GCPhysSrcMem); if (rcStrict != VINF_SUCCESS) return rcStrict; RTGCPHYS GCPhysDstMem; rcStrict = iemMemPageTranslateAndCheckAccess(pIemCpu, uVirtDstAddr, IEM_ACCESS_DATA_W, &GCPhysDstMem); if (rcStrict != VINF_SUCCESS) return rcStrict; /* * If we can map the page without trouble, do a block processing * until the end of the current page. */ OP_TYPE *puDstMem; rcStrict = iemMemPageMap(pIemCpu, GCPhysDstMem, IEM_ACCESS_DATA_W, (void **)&puDstMem); if (rcStrict == VINF_SUCCESS) { OP_TYPE const *puSrcMem; rcStrict = iemMemPageMap(pIemCpu, GCPhysSrcMem, IEM_ACCESS_DATA_R, (void **)&puSrcMem); if (rcStrict == VINF_SUCCESS) { /* Perform the operation. */ memcpy(puDstMem, puSrcMem, cLeftPage * (OP_SIZE / 8)); /* Update the registers. */ pCtx->ADDR_rSI = uSrcAddrReg += cLeftPage * cbIncr; pCtx->ADDR_rDI = uDstAddrReg += cLeftPage * cbIncr; pCtx->ADDR_rCX = uCounterReg -= cLeftPage; iemMemPageUnmap(pIemCpu, GCPhysSrcMem, IEM_ACCESS_DATA_R, puSrcMem); iemMemPageUnmap(pIemCpu, GCPhysDstMem, IEM_ACCESS_DATA_W, puDstMem); continue; } iemMemPageUnmap(pIemCpu, GCPhysDstMem, IEM_ACCESS_DATA_W, puDstMem); } } /* * Fallback - slow processing till the end of the current page. * In the cross page boundrary case we will end up here with cLeftPage * as 0, we execute one loop then. */ do { OP_TYPE uValue; rcStrict = RT_CONCAT(iemMemFetchDataU,OP_SIZE)(pIemCpu, &uValue, iEffSeg, uSrcAddrReg); if (rcStrict != VINF_SUCCESS) return rcStrict; rcStrict = RT_CONCAT(iemMemStoreDataU,OP_SIZE)(pIemCpu, X86_SREG_ES, uDstAddrReg, uValue); if (rcStrict != VINF_SUCCESS) return rcStrict; pCtx->ADDR_rSI = uSrcAddrReg += cbIncr; pCtx->ADDR_rDI = uDstAddrReg += cbIncr; pCtx->ADDR_rCX = --uCounterReg; cLeftPage--; } while ((int32_t)cLeftPage > 0); } while (uCounterReg != 0); /* * Done. */ iemRegAddToRip(pIemCpu, cbInstr); return VINF_SUCCESS; } /** * Implements 'REP STOS'. */ IEM_CIMPL_DEF_0(RT_CONCAT4(iemCImpl_stos_,OP_rAX,_m,ADDR_SIZE)) { PCPUMCTX pCtx = pIemCpu->CTX_SUFF(pCtx); /* * Setup. */ ADDR_TYPE uCounterReg = pCtx->ADDR_rCX; if (uCounterReg == 0) { iemRegAddToRip(pIemCpu, cbInstr); return VINF_SUCCESS; } VBOXSTRICTRC rcStrict = iemMemSegCheckWriteAccessEx(pIemCpu, &pCtx->esHid, X86_SREG_ES); if (rcStrict != VINF_SUCCESS) return rcStrict; int8_t const cbIncr = pCtx->eflags.Bits.u1DF ? -(OP_SIZE / 8) : (OP_SIZE / 8); OP_TYPE const uValue = pCtx->OP_rAX; ADDR_TYPE uAddrReg = pCtx->ADDR_rDI; /* * The loop. */ do { /* * Do segmentation and virtual page stuff. */ #if ADDR_SIZE != 64 ADDR2_TYPE uVirtAddr = (uint32_t)pCtx->esHid.u64Base + uAddrReg; #else uint64_t uVirtAddr = uAddrReg; #endif uint32_t cLeftPage = (PAGE_SIZE - (uVirtAddr & PAGE_OFFSET_MASK)) / (OP_SIZE / 8); if (cLeftPage > uCounterReg) cLeftPage = uCounterReg; if ( cLeftPage > 0 /* can be null if unaligned, do one fallback round. */ && cbIncr > 0 /** @todo Implement reverse direction string ops. */ #if ADDR_SIZE != 64 && uAddrReg < pCtx->esHid.u32Limit && uAddrReg + (cLeftPage * (OP_SIZE / 8)) <= pCtx->esHid.u32Limit #endif ) { RTGCPHYS GCPhysMem; rcStrict = iemMemPageTranslateAndCheckAccess(pIemCpu, uVirtAddr, IEM_ACCESS_DATA_W, &GCPhysMem); if (rcStrict != VINF_SUCCESS) return rcStrict; /* * If we can map the page without trouble, do a block processing * until the end of the current page. */ OP_TYPE *puMem; rcStrict = iemMemPageMap(pIemCpu, GCPhysMem, IEM_ACCESS_DATA_W, (void **)&puMem); if (rcStrict == VINF_SUCCESS) { /* Update the regs first so we can loop on cLeftPage. */ pCtx->ADDR_rCX = uCounterReg -= cLeftPage; pCtx->ADDR_rDI = uAddrReg += cLeftPage * cbIncr; /* Do the memsetting. */ #if OP_SIZE == 8 memset(puMem, uValue, cLeftPage); /*#elif OP_SIZE == 32 ASMMemFill32(puMem, cLeftPage * (OP_SIZE / 8), uValue);*/ #else while (cLeftPage-- > 0) *puMem++ = uValue; #endif iemMemPageUnmap(pIemCpu, GCPhysMem, IEM_ACCESS_DATA_W, puMem); /* If unaligned, we drop thru and do the page crossing access below. Otherwise, do the next page. */ if (!(uVirtAddr & (OP_SIZE - 1))) continue; if (uCounterReg == 0) break; cLeftPage = 0; } } /* * Fallback - slow processing till the end of the current page. * In the cross page boundrary case we will end up here with cLeftPage * as 0, we execute one loop then. */ do { rcStrict = RT_CONCAT(iemMemStoreDataU,OP_SIZE)(pIemCpu, X86_SREG_ES, uAddrReg, uValue); if (rcStrict != VINF_SUCCESS) return rcStrict; pCtx->ADDR_rDI = uAddrReg += cbIncr; pCtx->ADDR_rCX = --uCounterReg; cLeftPage--; } while ((int32_t)cLeftPage > 0); } while (uCounterReg != 0); /* * Done. */ iemRegAddToRip(pIemCpu, cbInstr); return VINF_SUCCESS; } /** * Implements 'REP LODS'. */ IEM_CIMPL_DEF_1(RT_CONCAT4(iemCImpl_lods_,OP_rAX,_m,ADDR_SIZE), int8_t, iEffSeg) { PCPUMCTX pCtx = pIemCpu->CTX_SUFF(pCtx); /* * Setup. */ ADDR_TYPE uCounterReg = pCtx->ADDR_rCX; if (uCounterReg == 0) { iemRegAddToRip(pIemCpu, cbInstr); return VINF_SUCCESS; } PCCPUMSELREGHID pSrcHid = iemSRegGetHid(pIemCpu, iEffSeg); VBOXSTRICTRC rcStrict = iemMemSegCheckReadAccessEx(pIemCpu, pSrcHid, iEffSeg); if (rcStrict != VINF_SUCCESS) return rcStrict; int8_t const cbIncr = pCtx->eflags.Bits.u1DF ? -(OP_SIZE / 8) : (OP_SIZE / 8); ADDR_TYPE uAddrReg = pCtx->ADDR_rSI; /* * The loop. */ do { /* * Do segmentation and virtual page stuff. */ #if ADDR_SIZE != 64 ADDR2_TYPE uVirtAddr = (uint32_t)pSrcHid->u64Base + uAddrReg; #else uint64_t uVirtAddr = uAddrReg; #endif uint32_t cLeftPage = (PAGE_SIZE - (uVirtAddr & PAGE_OFFSET_MASK)) / (OP_SIZE / 8); if (cLeftPage > uCounterReg) cLeftPage = uCounterReg; if ( cLeftPage > 0 /* can be null if unaligned, do one fallback round. */ && cbIncr > 0 /** @todo Implement reverse direction string ops. */ #if ADDR_SIZE != 64 && uAddrReg < pSrcHid->u32Limit && uAddrReg + (cLeftPage * (OP_SIZE / 8)) <= pSrcHid->u32Limit #endif ) { RTGCPHYS GCPhysMem; rcStrict = iemMemPageTranslateAndCheckAccess(pIemCpu, uVirtAddr, IEM_ACCESS_DATA_R, &GCPhysMem); if (rcStrict != VINF_SUCCESS) return rcStrict; /* * If we can map the page without trouble, we can get away with * just reading the last value on the page. */ OP_TYPE const *puMem; rcStrict = iemMemPageMap(pIemCpu, GCPhysMem, IEM_ACCESS_DATA_R, (void **)&puMem); if (rcStrict == VINF_SUCCESS) { /* Only get the last byte, the rest doesn't matter in direct access mode. */ #if OP_SIZE == 32 pCtx->rax = puMem[cLeftPage - 1]; #else pCtx->OP_rAX = puMem[cLeftPage - 1]; #endif pCtx->ADDR_rCX = uCounterReg -= cLeftPage; pCtx->ADDR_rSI = uAddrReg += cLeftPage * cbIncr; iemMemPageUnmap(pIemCpu, GCPhysMem, IEM_ACCESS_DATA_R, puMem); /* If unaligned, we drop thru and do the page crossing access below. Otherwise, do the next page. */ if (!(uVirtAddr & (OP_SIZE - 1))) continue; if (uCounterReg == 0) break; cLeftPage = 0; } } /* * Fallback - slow processing till the end of the current page. * In the cross page boundrary case we will end up here with cLeftPage * as 0, we execute one loop then. */ do { OP_TYPE uTmpValue; rcStrict = RT_CONCAT(iemMemFetchDataU,OP_SIZE)(pIemCpu, &uTmpValue, iEffSeg, uAddrReg); if (rcStrict != VINF_SUCCESS) return rcStrict; #if OP_SIZE == 32 pCtx->rax = uTmpValue; #else pCtx->OP_rAX = uTmpValue; #endif pCtx->ADDR_rSI = uAddrReg += cbIncr; pCtx->ADDR_rCX = --uCounterReg; cLeftPage--; } while ((int32_t)cLeftPage > 0); if (rcStrict != VINF_SUCCESS) break; } while (uCounterReg != 0); /* * Done. */ iemRegAddToRip(pIemCpu, cbInstr); return VINF_SUCCESS; } #if OP_SIZE != 64 /** * Implements 'INS' (no rep) */ IEM_CIMPL_DEF_0(RT_CONCAT4(iemCImpl_ins_op,OP_SIZE,_addr,ADDR_SIZE)) { PVM pVM = IEMCPU_TO_VM(pIemCpu); PCPUMCTX pCtx = pIemCpu->CTX_SUFF(pCtx); VBOXSTRICTRC rcStrict; /* * ASSUMES the #GP for I/O permission is taken first, then any #GP for * segmentation and finally any #PF due to virtual address translation. * ASSUMES nothing is read from the I/O port before traps are taken. */ rcStrict = iemHlpCheckPortIOPermission(pIemCpu, pCtx, pCtx->dx, OP_SIZE / 8); if (rcStrict != VINF_SUCCESS) return rcStrict; OP_TYPE *puMem; rcStrict = iemMemMap(pIemCpu, (void **)&puMem, OP_SIZE / 8, X86_SREG_ES, pCtx->ADDR_rDI, IEM_ACCESS_DATA_W); if (rcStrict != VINF_SUCCESS) return rcStrict; uint32_t u32Value; if (!IEM_VERIFICATION_ENABLED(pIemCpu)) rcStrict = IOMIOPortRead(pVM, pCtx->dx, &u32Value, OP_SIZE / 8); else rcStrict = iemVerifyFakeIOPortRead(pIemCpu, pCtx->dx, &u32Value, OP_SIZE / 8); if (IOM_SUCCESS(rcStrict)) { VBOXSTRICTRC rcStrict2 = iemMemCommitAndUnmap(pIemCpu, puMem, IEM_ACCESS_DATA_W); if (RT_LIKELY(rcStrict2 == VINF_SUCCESS)) { if (!pCtx->eflags.Bits.u1DF) pCtx->ADDR_rDI += OP_SIZE / 8; else pCtx->ADDR_rDI -= OP_SIZE / 8; iemRegAddToRip(pIemCpu, cbInstr); } /* iemMemMap already check permissions, so this may only be real errors or access handlers medling. The access handler case is going to cause misbehavior if the instruction is re-interpreted or smth. So, we fail with an internal error here instead. */ else AssertLogRelFailedReturn(VERR_IEM_IPE_1); } return rcStrict; } /** * Implements 'REP INS'. */ IEM_CIMPL_DEF_0(RT_CONCAT4(iemCImpl_rep_ins_op,OP_SIZE,_addr,ADDR_SIZE)) { PVM pVM = IEMCPU_TO_VM(pIemCpu); PCPUMCTX pCtx = pIemCpu->CTX_SUFF(pCtx); /* * Setup. */ uint16_t const u16Port = pCtx->dx; VBOXSTRICTRC rcStrict = iemHlpCheckPortIOPermission(pIemCpu, pCtx, u16Port, OP_SIZE / 8); if (rcStrict != VINF_SUCCESS) return rcStrict; ADDR_TYPE uCounterReg = pCtx->ADDR_rCX; if (uCounterReg == 0) { iemRegAddToRip(pIemCpu, cbInstr); return VINF_SUCCESS; } rcStrict = iemMemSegCheckWriteAccessEx(pIemCpu, &pCtx->esHid, X86_SREG_ES); if (rcStrict != VINF_SUCCESS) return rcStrict; int8_t const cbIncr = pCtx->eflags.Bits.u1DF ? -(OP_SIZE / 8) : (OP_SIZE / 8); ADDR_TYPE uAddrReg = pCtx->ADDR_rDI; /* * The loop. */ do { /* * Do segmentation and virtual page stuff. */ #if ADDR_SIZE != 64 ADDR2_TYPE uVirtAddr = (uint32_t)pCtx->esHid.u64Base + uAddrReg; #else uint64_t uVirtAddr = uAddrReg; #endif uint32_t cLeftPage = (PAGE_SIZE - (uVirtAddr & PAGE_OFFSET_MASK)) / (OP_SIZE / 8); if (cLeftPage > uCounterReg) cLeftPage = uCounterReg; if ( cLeftPage > 0 /* can be null if unaligned, do one fallback round. */ && cbIncr > 0 /** @todo Implement reverse direction string ops. */ #if ADDR_SIZE != 64 && uAddrReg < pCtx->esHid.u32Limit && uAddrReg + (cLeftPage * (OP_SIZE / 8)) <= pCtx->esHid.u32Limit #endif ) { RTGCPHYS GCPhysMem; rcStrict = iemMemPageTranslateAndCheckAccess(pIemCpu, uVirtAddr, IEM_ACCESS_DATA_W, &GCPhysMem); if (rcStrict != VINF_SUCCESS) return rcStrict; /* * If we can map the page without trouble, we would've liked to use * an string I/O method to do the work, but the current IOM * interface doesn't match our current approach. So, do a regular * loop instead. */ /** @todo Change the I/O manager interface to make use of * mapped buffers instead of leaving those bits to the * device implementation? */ OP_TYPE *puMem; rcStrict = iemMemPageMap(pIemCpu, GCPhysMem, IEM_ACCESS_DATA_W, (void **)&puMem); if (rcStrict == VINF_SUCCESS) { uint32_t off = 0; while (off < cLeftPage) { uint32_t u32Value; if (!IEM_VERIFICATION_ENABLED(pIemCpu)) rcStrict = IOMIOPortRead(pVM, u16Port, &u32Value, OP_SIZE / 8); else rcStrict = iemVerifyFakeIOPortRead(pIemCpu, u16Port, &u32Value, OP_SIZE / 8); if (IOM_SUCCESS(rcStrict)) { puMem[off] = (OP_TYPE)u32Value; pCtx->ADDR_rDI = uAddrReg += cbIncr; pCtx->ADDR_rCX = --uCounterReg; } if (rcStrict != VINF_SUCCESS) { /** @todo massage rc */ if (uCounterReg == 0) iemRegAddToRip(pIemCpu, cbInstr); iemMemPageUnmap(pIemCpu, GCPhysMem, IEM_ACCESS_DATA_W, puMem); return rcStrict; } off++; } iemMemPageUnmap(pIemCpu, GCPhysMem, IEM_ACCESS_DATA_W, puMem); /* If unaligned, we drop thru and do the page crossing access below. Otherwise, do the next page. */ if (!(uVirtAddr & (OP_SIZE - 1))) continue; if (uCounterReg == 0) break; cLeftPage = 0; } } /* * Fallback - slow processing till the end of the current page. * In the cross page boundrary case we will end up here with cLeftPage * as 0, we execute one loop then. * * Note! We ASSUME the CPU will raise #PF or #GP before access the * I/O port, otherwise it wouldn't really be restartable. */ /** @todo investigate what the CPU actually does with \#PF/\#GP * during INS. */ do { OP_TYPE *puMem; rcStrict = iemMemMap(pIemCpu, (void **)&puMem, OP_SIZE / 8, X86_SREG_ES, uAddrReg, IEM_ACCESS_DATA_W); if (rcStrict != VINF_SUCCESS) return rcStrict; uint32_t u32Value; if (!IEM_VERIFICATION_ENABLED(pIemCpu)) rcStrict = IOMIOPortRead(pVM, u16Port, &u32Value, OP_SIZE / 8); else rcStrict = iemVerifyFakeIOPortRead(pIemCpu, u16Port, &u32Value, OP_SIZE / 8); if (!IOM_SUCCESS(rcStrict)) return rcStrict; *puMem = (OP_TYPE)u32Value; VBOXSTRICTRC rcStrict2 = iemMemCommitAndUnmap(pIemCpu, puMem, IEM_ACCESS_DATA_W); AssertLogRelReturn(rcStrict2 == VINF_SUCCESS, VERR_IEM_IPE_1); /* See non-rep version. */ pCtx->ADDR_rDI = uAddrReg += cbIncr; pCtx->ADDR_rCX = --uCounterReg; cLeftPage--; if (rcStrict != VINF_SUCCESS) { /** @todo massage IOM status codes! */ if (uCounterReg == 0) iemRegAddToRip(pIemCpu, cbInstr); return rcStrict; } } while ((int32_t)cLeftPage > 0); } while (uCounterReg != 0); /* * Done. */ iemRegAddToRip(pIemCpu, cbInstr); return VINF_SUCCESS; } /** * Implements 'OUTS' (no rep) */ IEM_CIMPL_DEF_1(RT_CONCAT4(iemCImpl_outs_op,OP_SIZE,_addr,ADDR_SIZE), uint8_t, iEffSeg) { PVM pVM = IEMCPU_TO_VM(pIemCpu); PCPUMCTX pCtx = pIemCpu->CTX_SUFF(pCtx); VBOXSTRICTRC rcStrict; /* * ASSUMES the #GP for I/O permission is taken first, then any #GP for * segmentation and finally any #PF due to virtual address translation. * ASSUMES nothing is read from the I/O port before traps are taken. */ rcStrict = iemHlpCheckPortIOPermission(pIemCpu, pCtx, pCtx->dx, OP_SIZE / 8); if (rcStrict != VINF_SUCCESS) return rcStrict; OP_TYPE uValue; rcStrict = RT_CONCAT(iemMemFetchDataU,OP_SIZE)(pIemCpu, &uValue, iEffSeg, pCtx->ADDR_rSI); if (rcStrict == VINF_SUCCESS) { if (!IEM_VERIFICATION_ENABLED(pIemCpu)) rcStrict = IOMIOPortWrite(pVM, pCtx->dx, uValue, OP_SIZE / 8); else rcStrict = iemVerifyFakeIOPortWrite(pIemCpu, pCtx->dx, uValue, OP_SIZE / 8); if (IOM_SUCCESS(rcStrict)) { if (!pCtx->eflags.Bits.u1DF) pCtx->ADDR_rSI += OP_SIZE / 8; else pCtx->ADDR_rSI -= OP_SIZE / 8; iemRegAddToRip(pIemCpu, cbInstr); /** @todo massage IOM status codes. */ } } return rcStrict; } /** * Implements 'REP OUTS'. */ IEM_CIMPL_DEF_1(RT_CONCAT4(iemCImpl_rep_outs_op,OP_SIZE,_addr,ADDR_SIZE), uint8_t, iEffSeg) { PVM pVM = IEMCPU_TO_VM(pIemCpu); PCPUMCTX pCtx = pIemCpu->CTX_SUFF(pCtx); /* * Setup. */ uint16_t const u16Port = pCtx->dx; VBOXSTRICTRC rcStrict = iemHlpCheckPortIOPermission(pIemCpu, pCtx, u16Port, OP_SIZE / 8); if (rcStrict != VINF_SUCCESS) return rcStrict; ADDR_TYPE uCounterReg = pCtx->ADDR_rCX; if (uCounterReg == 0) { iemRegAddToRip(pIemCpu, cbInstr); return VINF_SUCCESS; } PCCPUMSELREGHID pHid = iemSRegGetHid(pIemCpu, iEffSeg); rcStrict = iemMemSegCheckReadAccessEx(pIemCpu, pHid, iEffSeg); if (rcStrict != VINF_SUCCESS) return rcStrict; int8_t const cbIncr = pCtx->eflags.Bits.u1DF ? -(OP_SIZE / 8) : (OP_SIZE / 8); ADDR_TYPE uAddrReg = pCtx->ADDR_rSI; /* * The loop. */ do { /* * Do segmentation and virtual page stuff. */ #if ADDR_SIZE != 64 ADDR2_TYPE uVirtAddr = (uint32_t)pHid->u64Base + uAddrReg; #else uint64_t uVirtAddr = uAddrReg; #endif uint32_t cLeftPage = (PAGE_SIZE - (uVirtAddr & PAGE_OFFSET_MASK)) / (OP_SIZE / 8); if (cLeftPage > uCounterReg) cLeftPage = uCounterReg; if ( cLeftPage > 0 /* can be null if unaligned, do one fallback round. */ && cbIncr > 0 /** @todo Implement reverse direction string ops. */ #if ADDR_SIZE != 64 && uAddrReg < pHid->u32Limit && uAddrReg + (cLeftPage * (OP_SIZE / 8)) <= pHid->u32Limit #endif ) { RTGCPHYS GCPhysMem; rcStrict = iemMemPageTranslateAndCheckAccess(pIemCpu, uVirtAddr, IEM_ACCESS_DATA_R, &GCPhysMem); if (rcStrict != VINF_SUCCESS) return rcStrict; /* * If we can map the page without trouble, we would've liked to use * an string I/O method to do the work, but the current IOM * interface doesn't match our current approach. So, do a regular * loop instead. */ /** @todo Change the I/O manager interface to make use of * mapped buffers instead of leaving those bits to the * device implementation? */ OP_TYPE const *puMem; rcStrict = iemMemPageMap(pIemCpu, GCPhysMem, IEM_ACCESS_DATA_R, (void **)&puMem); if (rcStrict == VINF_SUCCESS) { uint32_t off = 0; while (off < cLeftPage) { uint32_t u32Value = *puMem++; if (!IEM_VERIFICATION_ENABLED(pIemCpu)) rcStrict = IOMIOPortWrite(pVM, u16Port, u32Value, OP_SIZE / 8); else rcStrict = iemVerifyFakeIOPortWrite(pIemCpu, u16Port, u32Value, OP_SIZE / 8); if (IOM_SUCCESS(rcStrict)) { pCtx->ADDR_rSI = uAddrReg += cbIncr; pCtx->ADDR_rCX = --uCounterReg; } if (rcStrict != VINF_SUCCESS) { /** @todo massage IOM rc */ if (uCounterReg == 0) iemRegAddToRip(pIemCpu, cbInstr); iemMemPageUnmap(pIemCpu, GCPhysMem, IEM_ACCESS_DATA_R, puMem); return rcStrict; } off++; } iemMemPageUnmap(pIemCpu, GCPhysMem, IEM_ACCESS_DATA_R, puMem); /* If unaligned, we drop thru and do the page crossing access below. Otherwise, do the next page. */ if (!(uVirtAddr & (OP_SIZE - 1))) continue; if (uCounterReg == 0) break; cLeftPage = 0; } } /* * Fallback - slow processing till the end of the current page. * In the cross page boundrary case we will end up here with cLeftPage * as 0, we execute one loop then. * * Note! We ASSUME the CPU will raise #PF or #GP before access the * I/O port, otherwise it wouldn't really be restartable. */ /** @todo investigate what the CPU actually does with \#PF/\#GP * during INS. */ do { OP_TYPE uValue; rcStrict = RT_CONCAT(iemMemFetchDataU,OP_SIZE)(pIemCpu, &uValue, iEffSeg, uAddrReg); if (rcStrict != VINF_SUCCESS) return rcStrict; if (!IEM_VERIFICATION_ENABLED(pIemCpu)) rcStrict = IOMIOPortWrite(pVM, u16Port, uValue, OP_SIZE / 8); else rcStrict = iemVerifyFakeIOPortWrite(pIemCpu, u16Port, uValue, OP_SIZE / 8); if (IOM_SUCCESS(rcStrict)) { pCtx->ADDR_rSI = uAddrReg += cbIncr; pCtx->ADDR_rCX = --uCounterReg; cLeftPage--; } if (rcStrict != VINF_SUCCESS) { /** @todo massage IOM status codes! */ if (uCounterReg == 0) iemRegAddToRip(pIemCpu, cbInstr); return rcStrict; } } while ((int32_t)cLeftPage > 0); } while (uCounterReg != 0); /* * Done. */ iemRegAddToRip(pIemCpu, cbInstr); return VINF_SUCCESS; } #endif /* OP_SIZE != 64-bit */ #undef OP_rAX #undef OP_SIZE #undef ADDR_SIZE #undef ADDR_rDI #undef ADDR_rSI #undef ADDR_rCX #undef ADDR_rIP #undef ADDR2_TYPE #undef ADDR_TYPE #undef ADDR2_TYPE