VBoxRecompiler.c@ 45727

Last change on this file since 45727 was 45727, checked in by vboxsync, 12 years ago
REM/VBoxRecompiler: Fixed translating pending events to TRPM on REMR3StateBack() for traps.
Property svn:eol-style set to `native` Property svn:keywords set to `Author Date Id Revision`
File size: 183.0 KB

Line
1	/* $Id: VBoxRecompiler.c 45727 2013-04-25 11:15:38Z vboxsync $ */
2	/** @file
3	* VBox Recompiler - QEMU.
4	*/
5
6	/*
7	* Copyright (C) 2006-2013 Oracle Corporation
8	*
9	* This file is part of VirtualBox Open Source Edition (OSE), as
10	* available from http://www.virtualbox.org. This file is free software;
11	* you can redistribute it and/or modify it under the terms of the GNU
12	* General Public License (GPL) as published by the Free Software
13	* Foundation, in version 2 as it comes in the "COPYING" file of the
14	* VirtualBox OSE distribution. VirtualBox OSE is distributed in the
15	* hope that it will be useful, but WITHOUT ANY WARRANTY of any kind.
16	*/
17
18
19	/*******************************************************************************
20	* Header Files *
21	*******************************************************************************/
22	#define LOG_GROUP LOG_GROUP_REM
23	#include <stdio.h> /* FILE */
24	#include "osdep.h"
25	#include "config.h"
26	#include "cpu.h"
27	#include "exec-all.h"
28	#include "ioport.h"
29
30	#include <VBox/vmm/rem.h>
31	#include <VBox/vmm/vmapi.h>
32	#include <VBox/vmm/tm.h>
33	#include <VBox/vmm/ssm.h>
34	#include <VBox/vmm/em.h>
35	#include <VBox/vmm/trpm.h>
36	#include <VBox/vmm/iom.h>
37	#include <VBox/vmm/mm.h>
38	#include <VBox/vmm/pgm.h>
39	#include <VBox/vmm/pdm.h>
40	#include <VBox/vmm/dbgf.h>
41	#include <VBox/dbg.h>
42	#include <VBox/vmm/hm.h>
43	#include <VBox/vmm/patm.h>
44	#include <VBox/vmm/csam.h>
45	#include "REMInternal.h"
46	#include <VBox/vmm/vm.h>
47	#include <VBox/vmm/uvm.h>
48	#include <VBox/param.h>
49	#include <VBox/err.h>
50
51	#include <VBox/log.h>
52	#include <iprt/semaphore.h>
53	#include <iprt/asm.h>
54	#include <iprt/assert.h>
55	#include <iprt/thread.h>
56	#include <iprt/string.h>
57
58	/* Don't wanna include everything. */
59	extern void cpu_exec_init_all(uintptr_t tb_size);
60	extern void cpu_x86_update_cr3(CPUX86State *env, target_ulong new_cr3);
61	extern void cpu_x86_update_cr0(CPUX86State *env, uint32_t new_cr0);
62	extern void cpu_x86_update_cr4(CPUX86State *env, uint32_t new_cr4);
63	extern void tlb_flush_page(CPUX86State *env, target_ulong addr);
64	extern void tlb_flush(CPUX86State *env, int flush_global);
65	extern void sync_seg(CPUX86State *env1, int seg_reg, int selector);
66	extern void sync_ldtr(CPUX86State *env1, int selector);
67
68	#ifdef VBOX_STRICT
69	ram_addr_t get_phys_page_offset(target_ulong addr);
70	#endif
71
72
73	/*******************************************************************************
74	* Defined Constants And Macros *
75	*******************************************************************************/
76
77	/** Copy 80-bit fpu register at pSrc to pDst.
78	* This is probably faster than calling memcpy.
79	*/
80	#define REM_COPY_FPU_REG(pDst, pSrc) \
81	do { (PX86FPUMMX)(pDst) = (const X86FPUMMX *)(pSrc); } while (0)
82
83	/** How remR3RunLoggingStep operates. */
84	#define REM_USE_QEMU_SINGLE_STEP_FOR_LOGGING
85
86
87	/*******************************************************************************
88	* Internal Functions *
89	*******************************************************************************/
90	static DECLCALLBACK(int) remR3Save(PVM pVM, PSSMHANDLE pSSM);
91	static DECLCALLBACK(int) remR3Load(PVM pVM, PSSMHANDLE pSSM, uint32_t uVersion, uint32_t uPass);
92	static void remR3StateUpdate(PVM pVM, PVMCPU pVCpu);
93	static int remR3InitPhysRamSizeAndDirtyMap(PVM pVM, bool fGuarded);
94
95	static uint32_t remR3MMIOReadU8(void *pvEnv, target_phys_addr_t GCPhys);
96	static uint32_t remR3MMIOReadU16(void *pvEnv, target_phys_addr_t GCPhys);
97	static uint32_t remR3MMIOReadU32(void *pvEnv, target_phys_addr_t GCPhys);
98	static void remR3MMIOWriteU8(void *pvEnv, target_phys_addr_t GCPhys, uint32_t u32);
99	static void remR3MMIOWriteU16(void *pvEnv, target_phys_addr_t GCPhys, uint32_t u32);
100	static void remR3MMIOWriteU32(void *pvEnv, target_phys_addr_t GCPhys, uint32_t u32);
101
102	static uint32_t remR3HandlerReadU8(void *pvVM, target_phys_addr_t GCPhys);
103	static uint32_t remR3HandlerReadU16(void *pvVM, target_phys_addr_t GCPhys);
104	static uint32_t remR3HandlerReadU32(void *pvVM, target_phys_addr_t GCPhys);
105	static void remR3HandlerWriteU8(void *pvVM, target_phys_addr_t GCPhys, uint32_t u32);
106	static void remR3HandlerWriteU16(void *pvVM, target_phys_addr_t GCPhys, uint32_t u32);
107	static void remR3HandlerWriteU32(void *pvVM, target_phys_addr_t GCPhys, uint32_t u32);
108
109	static void remR3NotifyHandlerPhysicalDeregister(PVM pVM, PGMPHYSHANDLERTYPE enmType, RTGCPHYS GCPhys, RTGCPHYS cb, bool fHasHCHandler, bool fRestoreAsRAM);
110	static void remR3NotifyHandlerPhysicalRegister(PVM pVM, PGMPHYSHANDLERTYPE enmType, RTGCPHYS GCPhys, RTGCPHYS cb, bool fHasHCHandler);
111	static void remR3NotifyHandlerPhysicalModify(PVM pVM, PGMPHYSHANDLERTYPE enmType, RTGCPHYS GCPhysOld, RTGCPHYS GCPhysNew, RTGCPHYS cb, bool fHasHCHandler, bool fRestoreAsRAM);
112
113	/*******************************************************************************
114	* Global Variables *
115	*******************************************************************************/
116
117	/** @todo Move stats to REM::s some rainy day we have nothing do to. */
118	#ifdef VBOX_WITH_STATISTICS
119	static STAMPROFILEADV gStatExecuteSingleInstr;
120	static STAMPROFILEADV gStatCompilationQEmu;
121	static STAMPROFILEADV gStatRunCodeQEmu;
122	static STAMPROFILEADV gStatTotalTimeQEmu;
123	static STAMPROFILEADV gStatTimers;
124	static STAMPROFILEADV gStatTBLookup;
125	static STAMPROFILEADV gStatIRQ;
126	static STAMPROFILEADV gStatRawCheck;
127	static STAMPROFILEADV gStatMemRead;
128	static STAMPROFILEADV gStatMemWrite;
129	static STAMPROFILE gStatGCPhys2HCVirt;
130	static STAMCOUNTER gStatCpuGetTSC;
131	static STAMCOUNTER gStatRefuseTFInhibit;
132	static STAMCOUNTER gStatRefuseVM86;
133	static STAMCOUNTER gStatRefusePaging;
134	static STAMCOUNTER gStatRefusePAE;
135	static STAMCOUNTER gStatRefuseIOPLNot0;
136	static STAMCOUNTER gStatRefuseIF0;
137	static STAMCOUNTER gStatRefuseCode16;
138	static STAMCOUNTER gStatRefuseWP0;
139	static STAMCOUNTER gStatRefuseRing1or2;
140	static STAMCOUNTER gStatRefuseCanExecute;
141	static STAMCOUNTER gaStatRefuseStale[6];
142	static STAMCOUNTER gStatREMGDTChange;
143	static STAMCOUNTER gStatREMIDTChange;
144	static STAMCOUNTER gStatREMLDTRChange;
145	static STAMCOUNTER gStatREMTRChange;
146	static STAMCOUNTER gStatSelOutOfSync[6];
147	static STAMCOUNTER gStatSelOutOfSyncStateBack[6];
148	static STAMCOUNTER gStatFlushTBs;
149	#endif
150	/* in exec.c */
151	extern uint32_t tlb_flush_count;
152	extern uint32_t tb_flush_count;
153	extern uint32_t tb_phys_invalidate_count;
154
155	/*
156	* Global stuff.
157	*/
158
159	/** MMIO read callbacks. */
160	CPUReadMemoryFunc *g_apfnMMIORead[3] =
161	{
162	remR3MMIOReadU8,
163	remR3MMIOReadU16,
164	remR3MMIOReadU32
165	};
166
167	/** MMIO write callbacks. */
168	CPUWriteMemoryFunc *g_apfnMMIOWrite[3] =
169	{
170	remR3MMIOWriteU8,
171	remR3MMIOWriteU16,
172	remR3MMIOWriteU32
173	};
174
175	/** Handler read callbacks. */
176	CPUReadMemoryFunc *g_apfnHandlerRead[3] =
177	{
178	remR3HandlerReadU8,
179	remR3HandlerReadU16,
180	remR3HandlerReadU32
181	};
182
183	/** Handler write callbacks. */
184	CPUWriteMemoryFunc *g_apfnHandlerWrite[3] =
185	{
186	remR3HandlerWriteU8,
187	remR3HandlerWriteU16,
188	remR3HandlerWriteU32
189	};
190
191
192	#if defined(VBOX_WITH_DEBUGGER) && !(defined(RT_OS_WINDOWS) && defined(RT_ARCH_AMD64))
193	/*
194	* Debugger commands.
195	*/
196	static FNDBGCCMD remR3CmdDisasEnableStepping;;
197
198	/** '.remstep' arguments. */
199	static const DBGCVARDESC g_aArgRemStep[] =
200	{
201	/* cTimesMin, cTimesMax, enmCategory, fFlags, pszName, pszDescription */
202	{ 0, ~0U, DBGCVAR_CAT_NUMBER, 0, "on/off", "Boolean value/mnemonic indicating the new state." },
203	};
204
205	/** Command descriptors. */
206	static const DBGCCMD g_aCmds[] =
207	{
208	{
209	.pszCmd ="remstep",
210	.cArgsMin = 0,
211	.cArgsMax = 1,
212	.paArgDescs = &g_aArgRemStep[0],
213	.cArgDescs = RT_ELEMENTS(g_aArgRemStep),
214	.fFlags = 0,
215	.pfnHandler = remR3CmdDisasEnableStepping,
216	.pszSyntax = "[on/off]",
217	.pszDescription = "Enable or disable the single stepping with logged disassembly. "
218	"If no arguments show the current state."
219	}
220	};
221	#endif
222
223	/** Prologue code, must be in lower 4G to simplify jumps to/from generated code.
224	* @todo huh??? That cannot be the case on the mac... So, this
225	* point is probably not valid any longer. */
226	uint8_t *code_gen_prologue;
227
228
229	/*******************************************************************************
230	* Internal Functions *
231	*******************************************************************************/
232	void remAbort(int rc, const char *pszTip);
233	extern int testmath(void);
234
235	/* Put them here to avoid unused variable warning. */
236	AssertCompile(RT_SIZEOFMEMB(VM, rem.padding) >= RT_SIZEOFMEMB(VM, rem.s));
237	#if !defined(IPRT_NO_CRT) && (defined(RT_OS_LINUX) \|\| defined(RT_OS_DARWIN) \|\| defined(RT_OS_WINDOWS))
238	//AssertCompileMemberSize(REM, Env, REM_ENV_SIZE);
239	/* Why did this have to be identical?? */
240	AssertCompile(RT_SIZEOFMEMB(REM, Env) <= REM_ENV_SIZE);
241	#else
242	AssertCompile(RT_SIZEOFMEMB(REM, Env) <= REM_ENV_SIZE);
243	#endif
244
245
246	/**
247	* Initializes the REM.
248	*
249	* @returns VBox status code.
250	* @param pVM The VM to operate on.
251	*/
252	REMR3DECL(int) REMR3Init(PVM pVM)
253	{
254	PREMHANDLERNOTIFICATION pCur;
255	uint32_t u32Dummy;
256	int rc;
257	unsigned i;
258
259	#ifdef VBOX_ENABLE_VBOXREM64
260	LogRel(("Using 64-bit aware REM\n"));
261	#endif
262
263	/*
264	* Assert sanity.
265	*/
266	AssertReleaseMsg(sizeof(pVM->rem.padding) >= sizeof(pVM->rem.s), ("%#x >= %#x; sizeof(Env)=%#x\n", sizeof(pVM->rem.padding), sizeof(pVM->rem.s), sizeof(pVM->rem.s.Env)));
267	AssertReleaseMsg(sizeof(pVM->rem.s.Env) <= REM_ENV_SIZE, ("%#x == %#x\n", sizeof(pVM->rem.s.Env), REM_ENV_SIZE));
268	AssertReleaseMsg(!(RT_OFFSETOF(VM, rem) & 31), ("off=%#x\n", RT_OFFSETOF(VM, rem)));
269	#if 0 /* just an annoyance at the moment. */
270	#if defined(DEBUG) && !defined(RT_OS_SOLARIS) && !defined(RT_OS_FREEBSD) /// @todo fix the solaris and freebsd math stuff.
271	Assert(!testmath());
272	#endif
273	#endif
274
275	/*
276	* Init some internal data members.
277	*/
278	pVM->rem.s.offVM = RT_OFFSETOF(VM, rem.s);
279	pVM->rem.s.Env.pVM = pVM;
280	#ifdef CPU_RAW_MODE_INIT
281	pVM->rem.s.state \|= CPU_RAW_MODE_INIT;
282	#endif
283
284	/*
285	* Initialize the REM critical section.
286	*
287	* Note: This is not a 100% safe solution as updating the internal memory state while another VCPU
288	* is executing code could be dangerous. Taking the REM lock is not an option due to the danger of
289	* deadlocks. (mostly pgm vs rem locking)
290	*/
291	rc = PDMR3CritSectInit(pVM, &pVM->rem.s.CritSectRegister, RT_SRC_POS, "REM-Register");
292	AssertRCReturn(rc, rc);
293
294	/* ctx. */
295	pVM->rem.s.pCtx = NULL; /* set when executing code. */
296	AssertMsg(MMR3PhysGetRamSize(pVM) == 0, ("Init order has changed! REM depends on notification about ALL physical memory registrations\n"));
297
298	/* ignore all notifications */
299	ASMAtomicIncU32(&pVM->rem.s.cIgnoreAll);
300
301	code_gen_prologue = RTMemExecAlloc(_1K);
302	AssertLogRelReturn(code_gen_prologue, VERR_NO_MEMORY);
303
304	cpu_exec_init_all(0);
305
306	/*
307	* Init the recompiler.
308	*/
309	if (!cpu_x86_init(&pVM->rem.s.Env, "vbox"))
310	{
311	AssertMsgFailed(("cpu_x86_init failed - impossible!\n"));
312	return VERR_GENERAL_FAILURE;
313	}
314	PVMCPU pVCpu = VMMGetCpu(pVM);
315	CPUMGetGuestCpuId(pVCpu, 1, &u32Dummy, &u32Dummy, &pVM->rem.s.Env.cpuid_ext_features, &pVM->rem.s.Env.cpuid_features);
316	CPUMGetGuestCpuId(pVCpu, 0x80000001, &u32Dummy, &u32Dummy, &pVM->rem.s.Env.cpuid_ext3_features, &pVM->rem.s.Env.cpuid_ext2_features);
317
318	EMRemLock(pVM);
319	cpu_reset(&pVM->rem.s.Env);
320	EMRemUnlock(pVM);
321
322	/* allocate code buffer for single instruction emulation. */
323	pVM->rem.s.Env.cbCodeBuffer = 4096;
324	pVM->rem.s.Env.pvCodeBuffer = RTMemExecAlloc(pVM->rem.s.Env.cbCodeBuffer);
325	AssertMsgReturn(pVM->rem.s.Env.pvCodeBuffer, ("Failed to allocate code buffer!\n"), VERR_NO_MEMORY);
326
327	/* Finally, set the cpu_single_env global. */
328	cpu_single_env = &pVM->rem.s.Env;
329
330	/* Nothing is pending by default */
331	pVM->rem.s.u32PendingInterrupt = REM_NO_PENDING_IRQ;
332
333	/*
334	* Register ram types.
335	*/
336	pVM->rem.s.iMMIOMemType = cpu_register_io_memory(g_apfnMMIORead, g_apfnMMIOWrite, &pVM->rem.s.Env);
337	AssertReleaseMsg(pVM->rem.s.iMMIOMemType >= 0, ("pVM->rem.s.iMMIOMemType=%d\n", pVM->rem.s.iMMIOMemType));
338	pVM->rem.s.iHandlerMemType = cpu_register_io_memory(g_apfnHandlerRead, g_apfnHandlerWrite, pVM);
339	AssertReleaseMsg(pVM->rem.s.iHandlerMemType >= 0, ("pVM->rem.s.iHandlerMemType=%d\n", pVM->rem.s.iHandlerMemType));
340	Log2(("REM: iMMIOMemType=%d iHandlerMemType=%d\n", pVM->rem.s.iMMIOMemType, pVM->rem.s.iHandlerMemType));
341
342	/* stop ignoring. */
343	ASMAtomicDecU32(&pVM->rem.s.cIgnoreAll);
344
345	/*
346	* Register the saved state data unit.
347	*/
348	rc = SSMR3RegisterInternal(pVM, "rem", 1, REM_SAVED_STATE_VERSION, sizeof(uint32_t) * 10,
349	NULL, NULL, NULL,
350	NULL, remR3Save, NULL,
351	NULL, remR3Load, NULL);
352	if (RT_FAILURE(rc))
353	return rc;
354
355	#if defined(VBOX_WITH_DEBUGGER) && !(defined(RT_OS_WINDOWS) && defined(RT_ARCH_AMD64))
356	/*
357	* Debugger commands.
358	*/
359	static bool fRegisteredCmds = false;
360	if (!fRegisteredCmds)
361	{
362	int rc = DBGCRegisterCommands(&g_aCmds[0], RT_ELEMENTS(g_aCmds));
363	if (RT_SUCCESS(rc))
364	fRegisteredCmds = true;
365	}
366	#endif
367
368	#ifdef VBOX_WITH_STATISTICS
369	/*
370	* Statistics.
371	*/
372	STAM_REG(pVM, &gStatExecuteSingleInstr, STAMTYPE_PROFILE, "/PROF/REM/SingleInstr",STAMUNIT_TICKS_PER_CALL, "Profiling single instruction emulation.");
373	STAM_REG(pVM, &gStatCompilationQEmu, STAMTYPE_PROFILE, "/PROF/REM/Compile", STAMUNIT_TICKS_PER_CALL, "Profiling QEmu compilation.");
374	STAM_REG(pVM, &gStatRunCodeQEmu, STAMTYPE_PROFILE, "/PROF/REM/Runcode", STAMUNIT_TICKS_PER_CALL, "Profiling QEmu code execution.");
375	STAM_REG(pVM, &gStatTotalTimeQEmu, STAMTYPE_PROFILE, "/PROF/REM/Emulate", STAMUNIT_TICKS_PER_CALL, "Profiling code emulation.");
376	STAM_REG(pVM, &gStatTimers, STAMTYPE_PROFILE, "/PROF/REM/Timers", STAMUNIT_TICKS_PER_CALL, "Profiling timer queue processing.");
377	STAM_REG(pVM, &gStatTBLookup, STAMTYPE_PROFILE, "/PROF/REM/TBLookup", STAMUNIT_TICKS_PER_CALL, "Profiling translation block lookup.");
378	STAM_REG(pVM, &gStatIRQ, STAMTYPE_PROFILE, "/PROF/REM/IRQ", STAMUNIT_TICKS_PER_CALL, "Profiling IRQ delivery.");
379	STAM_REG(pVM, &gStatRawCheck, STAMTYPE_PROFILE, "/PROF/REM/RawCheck", STAMUNIT_TICKS_PER_CALL, "Profiling remR3CanExecuteRaw calls.");
380	STAM_REG(pVM, &gStatMemRead, STAMTYPE_PROFILE, "/PROF/REM/MemRead", STAMUNIT_TICKS_PER_CALL, "Profiling memory access.");
381	STAM_REG(pVM, &gStatMemWrite, STAMTYPE_PROFILE, "/PROF/REM/MemWrite", STAMUNIT_TICKS_PER_CALL, "Profiling memory access.");
382	STAM_REG(pVM, &gStatGCPhys2HCVirt, STAMTYPE_PROFILE, "/PROF/REM/GCPhys2HCVirt", STAMUNIT_TICKS_PER_CALL, "Profiling memory conversion (PGMR3PhysTlbGCPhys2Ptr).");
383
384	STAM_REG(pVM, &gStatCpuGetTSC, STAMTYPE_COUNTER, "/REM/CpuGetTSC", STAMUNIT_OCCURENCES, "cpu_get_tsc calls");
385
386	STAM_REG(pVM, &gStatRefuseTFInhibit, STAMTYPE_COUNTER, "/REM/Refuse/TFInibit", STAMUNIT_OCCURENCES, "Raw mode refused because of TF or irq inhibit");
387	STAM_REG(pVM, &gStatRefuseVM86, STAMTYPE_COUNTER, "/REM/Refuse/VM86", STAMUNIT_OCCURENCES, "Raw mode refused because of VM86");
388	STAM_REG(pVM, &gStatRefusePaging, STAMTYPE_COUNTER, "/REM/Refuse/Paging", STAMUNIT_OCCURENCES, "Raw mode refused because of disabled paging/pm");
389	STAM_REG(pVM, &gStatRefusePAE, STAMTYPE_COUNTER, "/REM/Refuse/PAE", STAMUNIT_OCCURENCES, "Raw mode refused because of PAE");
390	STAM_REG(pVM, &gStatRefuseIOPLNot0, STAMTYPE_COUNTER, "/REM/Refuse/IOPLNot0", STAMUNIT_OCCURENCES, "Raw mode refused because of IOPL != 0");
391	STAM_REG(pVM, &gStatRefuseIF0, STAMTYPE_COUNTER, "/REM/Refuse/IF0", STAMUNIT_OCCURENCES, "Raw mode refused because of IF=0");
392	STAM_REG(pVM, &gStatRefuseCode16, STAMTYPE_COUNTER, "/REM/Refuse/Code16", STAMUNIT_OCCURENCES, "Raw mode refused because of 16 bit code");
393	STAM_REG(pVM, &gStatRefuseWP0, STAMTYPE_COUNTER, "/REM/Refuse/WP0", STAMUNIT_OCCURENCES, "Raw mode refused because of WP=0");
394	STAM_REG(pVM, &gStatRefuseRing1or2, STAMTYPE_COUNTER, "/REM/Refuse/Ring1or2", STAMUNIT_OCCURENCES, "Raw mode refused because of ring 1/2 execution");
395	STAM_REG(pVM, &gStatRefuseCanExecute, STAMTYPE_COUNTER, "/REM/Refuse/CanExecuteRaw", STAMUNIT_OCCURENCES, "Raw mode refused because of cCanExecuteRaw");
396	STAM_REG(pVM, &gaStatRefuseStale[R_ES], STAMTYPE_COUNTER, "/REM/Refuse/StaleES", STAMUNIT_OCCURENCES, "Raw mode refused because of stale ES");
397	STAM_REG(pVM, &gaStatRefuseStale[R_CS], STAMTYPE_COUNTER, "/REM/Refuse/StaleCS", STAMUNIT_OCCURENCES, "Raw mode refused because of stale CS");
398	STAM_REG(pVM, &gaStatRefuseStale[R_SS], STAMTYPE_COUNTER, "/REM/Refuse/StaleSS", STAMUNIT_OCCURENCES, "Raw mode refused because of stale SS");
399	STAM_REG(pVM, &gaStatRefuseStale[R_DS], STAMTYPE_COUNTER, "/REM/Refuse/StaleDS", STAMUNIT_OCCURENCES, "Raw mode refused because of stale DS");
400	STAM_REG(pVM, &gaStatRefuseStale[R_FS], STAMTYPE_COUNTER, "/REM/Refuse/StaleFS", STAMUNIT_OCCURENCES, "Raw mode refused because of stale FS");
401	STAM_REG(pVM, &gaStatRefuseStale[R_GS], STAMTYPE_COUNTER, "/REM/Refuse/StaleGS", STAMUNIT_OCCURENCES, "Raw mode refused because of stale GS");
402	STAM_REG(pVM, &gStatFlushTBs, STAMTYPE_COUNTER, "/REM/FlushTB", STAMUNIT_OCCURENCES, "Number of TB flushes");
403
404	STAM_REG(pVM, &gStatREMGDTChange, STAMTYPE_COUNTER, "/REM/Change/GDTBase", STAMUNIT_OCCURENCES, "GDT base changes");
405	STAM_REG(pVM, &gStatREMLDTRChange, STAMTYPE_COUNTER, "/REM/Change/LDTR", STAMUNIT_OCCURENCES, "LDTR changes");
406	STAM_REG(pVM, &gStatREMIDTChange, STAMTYPE_COUNTER, "/REM/Change/IDTBase", STAMUNIT_OCCURENCES, "IDT base changes");
407	STAM_REG(pVM, &gStatREMTRChange, STAMTYPE_COUNTER, "/REM/Change/TR", STAMUNIT_OCCURENCES, "TR selector changes");
408
409	STAM_REG(pVM, &gStatSelOutOfSync[0], STAMTYPE_COUNTER, "/REM/State/SelOutOfSync/ES", STAMUNIT_OCCURENCES, "ES out of sync");
410	STAM_REG(pVM, &gStatSelOutOfSync[1], STAMTYPE_COUNTER, "/REM/State/SelOutOfSync/CS", STAMUNIT_OCCURENCES, "CS out of sync");
411	STAM_REG(pVM, &gStatSelOutOfSync[2], STAMTYPE_COUNTER, "/REM/State/SelOutOfSync/SS", STAMUNIT_OCCURENCES, "SS out of sync");
412	STAM_REG(pVM, &gStatSelOutOfSync[3], STAMTYPE_COUNTER, "/REM/State/SelOutOfSync/DS", STAMUNIT_OCCURENCES, "DS out of sync");
413	STAM_REG(pVM, &gStatSelOutOfSync[4], STAMTYPE_COUNTER, "/REM/State/SelOutOfSync/FS", STAMUNIT_OCCURENCES, "FS out of sync");
414	STAM_REG(pVM, &gStatSelOutOfSync[5], STAMTYPE_COUNTER, "/REM/State/SelOutOfSync/GS", STAMUNIT_OCCURENCES, "GS out of sync");
415
416	STAM_REG(pVM, &gStatSelOutOfSyncStateBack[0], STAMTYPE_COUNTER, "/REM/StateBack/SelOutOfSync/ES", STAMUNIT_OCCURENCES, "ES out of sync");
417	STAM_REG(pVM, &gStatSelOutOfSyncStateBack[1], STAMTYPE_COUNTER, "/REM/StateBack/SelOutOfSync/CS", STAMUNIT_OCCURENCES, "CS out of sync");
418	STAM_REG(pVM, &gStatSelOutOfSyncStateBack[2], STAMTYPE_COUNTER, "/REM/StateBack/SelOutOfSync/SS", STAMUNIT_OCCURENCES, "SS out of sync");
419	STAM_REG(pVM, &gStatSelOutOfSyncStateBack[3], STAMTYPE_COUNTER, "/REM/StateBack/SelOutOfSync/DS", STAMUNIT_OCCURENCES, "DS out of sync");
420	STAM_REG(pVM, &gStatSelOutOfSyncStateBack[4], STAMTYPE_COUNTER, "/REM/StateBack/SelOutOfSync/FS", STAMUNIT_OCCURENCES, "FS out of sync");
421	STAM_REG(pVM, &gStatSelOutOfSyncStateBack[5], STAMTYPE_COUNTER, "/REM/StateBack/SelOutOfSync/GS", STAMUNIT_OCCURENCES, "GS out of sync");
422
423	STAM_REG(pVM, &pVM->rem.s.Env.StatTbFlush, STAMTYPE_PROFILE, "/REM/TbFlush", STAMUNIT_TICKS_PER_CALL, "profiling tb_flush().");
424	#endif /* VBOX_WITH_STATISTICS */
425	AssertCompileMemberAlignment(CPUX86State, StatTbFlush, 4);
426	AssertCompileMemberAlignment(CPUX86State, StatTbFlush, 8);
427
428	STAM_REL_REG(pVM, &tb_flush_count, STAMTYPE_U32_RESET, "/REM/TbFlushCount", STAMUNIT_OCCURENCES, "tb_flush() calls");
429	STAM_REL_REG(pVM, &tb_phys_invalidate_count, STAMTYPE_U32_RESET, "/REM/TbPhysInvldCount", STAMUNIT_OCCURENCES, "tb_phys_invalidate() calls");
430	STAM_REL_REG(pVM, &tlb_flush_count, STAMTYPE_U32_RESET, "/REM/TlbFlushCount", STAMUNIT_OCCURENCES, "tlb_flush() calls");
431
432
433	#ifdef DEBUG_ALL_LOGGING
434	loglevel = ~0;
435	#endif
436
437	/*
438	* Init the handler notification lists.
439	*/
440	pVM->rem.s.idxPendingList = UINT32_MAX;
441	pVM->rem.s.idxFreeList = 0;
442
443	for (i = 0 ; i < RT_ELEMENTS(pVM->rem.s.aHandlerNotifications); i++)
444	{
445	pCur = &pVM->rem.s.aHandlerNotifications[i];
446	pCur->idxNext = i + 1;
447	pCur->idxSelf = i;
448	}
449	pCur->idxNext = UINT32_MAX; /* the last record. */
450
451	return rc;
452	}
453
454
455	/**
456	* Finalizes the REM initialization.
457	*
458	* This is called after all components, devices and drivers has
459	* been initialized. Its main purpose it to finish the RAM related
460	* initialization.
461	*
462	* @returns VBox status code.
463	*
464	* @param pVM The VM handle.
465	*/
466	REMR3DECL(int) REMR3InitFinalize(PVM pVM)
467	{
468	int rc;
469
470	/*
471	* Ram size & dirty bit map.
472	*/
473	Assert(!pVM->rem.s.fGCPhysLastRamFixed);
474	pVM->rem.s.fGCPhysLastRamFixed = true;
475	#ifdef RT_STRICT
476	rc = remR3InitPhysRamSizeAndDirtyMap(pVM, true /* fGuarded */);
477	#else
478	rc = remR3InitPhysRamSizeAndDirtyMap(pVM, false /* fGuarded */);
479	#endif
480	return rc;
481	}
482
483	/**
484	* Initializes ram_list.phys_dirty and ram_list.phys_dirty_size.
485	*
486	* @returns VBox status code.
487	* @param pVM The VM handle.
488	* @param fGuarded Whether to guard the map.
489	*/
490	static int remR3InitPhysRamSizeAndDirtyMap(PVM pVM, bool fGuarded)
491	{
492	int rc = VINF_SUCCESS;
493	RTGCPHYS cb;
494
495	AssertLogRelReturn(QLIST_EMPTY(&ram_list.blocks), VERR_INTERNAL_ERROR_2);
496
497	cb = pVM->rem.s.GCPhysLastRam + 1;
498	AssertLogRelMsgReturn(cb > pVM->rem.s.GCPhysLastRam,
499	("GCPhysLastRam=%RGp - out of range\n", pVM->rem.s.GCPhysLastRam),
500	VERR_OUT_OF_RANGE);
501
502	ram_list.phys_dirty_size = cb >> PAGE_SHIFT;
503	AssertMsg(((RTGCPHYS)ram_list.phys_dirty_size << PAGE_SHIFT) == cb, ("%RGp\n", cb));
504
505	if (!fGuarded)
506	{
507	ram_list.phys_dirty = MMR3HeapAlloc(pVM, MM_TAG_REM, ram_list.phys_dirty_size);
508	AssertLogRelMsgReturn(ram_list.phys_dirty, ("Failed to allocate %u bytes of dirty page map bytes\n", ram_list.phys_dirty_size), VERR_NO_MEMORY);
509	}
510	else
511	{
512	/*
513	* Fill it up the nearest 4GB RAM and leave at least _64KB of guard after it.
514	*/
515	uint32_t cbBitmapAligned = RT_ALIGN_32(ram_list.phys_dirty_size, PAGE_SIZE);
516	uint32_t cbBitmapFull = RT_ALIGN_32(ram_list.phys_dirty_size, (_4G >> PAGE_SHIFT));
517	if (cbBitmapFull == cbBitmapAligned)
518	cbBitmapFull += _4G >> PAGE_SHIFT;
519	else if (cbBitmapFull - cbBitmapAligned < _64K)
520	cbBitmapFull += _64K;
521
522	ram_list.phys_dirty = RTMemPageAlloc(cbBitmapFull);
523	AssertLogRelMsgReturn(ram_list.phys_dirty, ("Failed to allocate %u bytes of dirty page map bytes\n", cbBitmapFull), VERR_NO_MEMORY);
524
525	rc = RTMemProtect(ram_list.phys_dirty + cbBitmapAligned, cbBitmapFull - cbBitmapAligned, RTMEM_PROT_NONE);
526	if (RT_FAILURE(rc))
527	{
528	RTMemPageFree(ram_list.phys_dirty, cbBitmapFull);
529	AssertLogRelRCReturn(rc, rc);
530	}
531
532	ram_list.phys_dirty += cbBitmapAligned - ram_list.phys_dirty_size;
533	}
534
535	/* initialize it. */
536	memset(ram_list.phys_dirty, 0xff, ram_list.phys_dirty_size);
537	return rc;
538	}
539
540
541	/**
542	* Terminates the REM.
543	*
544	* Termination means cleaning up and freeing all resources,
545	* the VM it self is at this point powered off or suspended.
546	*
547	* @returns VBox status code.
548	* @param pVM The VM to operate on.
549	*/
550	REMR3DECL(int) REMR3Term(PVM pVM)
551	{
552	#ifdef VBOX_WITH_STATISTICS
553	/*
554	* Statistics.
555	*/
556	STAM_DEREG(pVM, &gStatExecuteSingleInstr);
557	STAM_DEREG(pVM, &gStatCompilationQEmu);
558	STAM_DEREG(pVM, &gStatRunCodeQEmu);
559	STAM_DEREG(pVM, &gStatTotalTimeQEmu);
560	STAM_DEREG(pVM, &gStatTimers);
561	STAM_DEREG(pVM, &gStatTBLookup);
562	STAM_DEREG(pVM, &gStatIRQ);
563	STAM_DEREG(pVM, &gStatRawCheck);
564	STAM_DEREG(pVM, &gStatMemRead);
565	STAM_DEREG(pVM, &gStatMemWrite);
566	STAM_DEREG(pVM, &gStatGCPhys2HCVirt);
567
568	STAM_DEREG(pVM, &gStatCpuGetTSC);
569
570	STAM_DEREG(pVM, &gStatRefuseTFInhibit);
571	STAM_DEREG(pVM, &gStatRefuseVM86);
572	STAM_DEREG(pVM, &gStatRefusePaging);
573	STAM_DEREG(pVM, &gStatRefusePAE);
574	STAM_DEREG(pVM, &gStatRefuseIOPLNot0);
575	STAM_DEREG(pVM, &gStatRefuseIF0);
576	STAM_DEREG(pVM, &gStatRefuseCode16);
577	STAM_DEREG(pVM, &gStatRefuseWP0);
578	STAM_DEREG(pVM, &gStatRefuseRing1or2);
579	STAM_DEREG(pVM, &gStatRefuseCanExecute);
580	STAM_DEREG(pVM, &gaStatRefuseStale[0]);
581	STAM_DEREG(pVM, &gaStatRefuseStale[1]);
582	STAM_DEREG(pVM, &gaStatRefuseStale[2]);
583	STAM_DEREG(pVM, &gaStatRefuseStale[3]);
584	STAM_DEREG(pVM, &gaStatRefuseStale[4]);
585	STAM_DEREG(pVM, &gaStatRefuseStale[5]);
586	STAM_DEREG(pVM, &gStatFlushTBs);
587
588	STAM_DEREG(pVM, &gStatREMGDTChange);
589	STAM_DEREG(pVM, &gStatREMLDTRChange);
590	STAM_DEREG(pVM, &gStatREMIDTChange);
591	STAM_DEREG(pVM, &gStatREMTRChange);
592
593	STAM_DEREG(pVM, &gStatSelOutOfSync[0]);
594	STAM_DEREG(pVM, &gStatSelOutOfSync[1]);
595	STAM_DEREG(pVM, &gStatSelOutOfSync[2]);
596	STAM_DEREG(pVM, &gStatSelOutOfSync[3]);
597	STAM_DEREG(pVM, &gStatSelOutOfSync[4]);
598	STAM_DEREG(pVM, &gStatSelOutOfSync[5]);
599
600	STAM_DEREG(pVM, &gStatSelOutOfSyncStateBack[0]);
601	STAM_DEREG(pVM, &gStatSelOutOfSyncStateBack[1]);
602	STAM_DEREG(pVM, &gStatSelOutOfSyncStateBack[2]);
603	STAM_DEREG(pVM, &gStatSelOutOfSyncStateBack[3]);
604	STAM_DEREG(pVM, &gStatSelOutOfSyncStateBack[4]);
605	STAM_DEREG(pVM, &gStatSelOutOfSyncStateBack[5]);
606
607	STAM_DEREG(pVM, &pVM->rem.s.Env.StatTbFlush);
608	#endif /* VBOX_WITH_STATISTICS */
609
610	STAM_REL_DEREG(pVM, &tb_flush_count);
611	STAM_REL_DEREG(pVM, &tb_phys_invalidate_count);
612	STAM_REL_DEREG(pVM, &tlb_flush_count);
613
614	return VINF_SUCCESS;
615	}
616
617
618	/**
619	* The VM is being reset.
620	*
621	* For the REM component this means to call the cpu_reset() and
622	* reinitialize some state variables.
623	*
624	* @param pVM VM handle.
625	*/
626	REMR3DECL(void) REMR3Reset(PVM pVM)
627	{
628	EMRemLock(pVM); /* Only pro forma, we're in a rendezvous. */
629
630	/*
631	* Reset the REM cpu.
632	*/
633	Assert(pVM->rem.s.cIgnoreAll == 0);
634	ASMAtomicIncU32(&pVM->rem.s.cIgnoreAll);
635	cpu_reset(&pVM->rem.s.Env);
636	pVM->rem.s.cInvalidatedPages = 0;
637	ASMAtomicDecU32(&pVM->rem.s.cIgnoreAll);
638	Assert(pVM->rem.s.cIgnoreAll == 0);
639
640	/* Clear raw ring 0 init state */
641	pVM->rem.s.Env.state &= ~CPU_RAW_RING0;
642
643	/* Flush the TBs the next time we execute code here. */
644	pVM->rem.s.fFlushTBs = true;
645
646	EMRemUnlock(pVM);
647	}
648
649
650	/**
651	* Execute state save operation.
652	*
653	* @returns VBox status code.
654	* @param pVM VM Handle.
655	* @param pSSM SSM operation handle.
656	*/
657	static DECLCALLBACK(int) remR3Save(PVM pVM, PSSMHANDLE pSSM)
658	{
659	PREM pRem = &pVM->rem.s;
660
661	/*
662	* Save the required CPU Env bits.
663	* (Not much because we're never in REM when doing the save.)
664	*/
665	LogFlow(("remR3Save:\n"));
666	Assert(!pRem->fInREM);
667	SSMR3PutU32(pSSM, pRem->Env.hflags);
668	SSMR3PutU32(pSSM, ~0); /* separator */
669
670	/* Remember if we've entered raw mode (vital for ring 1 checks in e.g. iret emulation). */
671	SSMR3PutU32(pSSM, !!(pRem->Env.state & CPU_RAW_RING0));
672	SSMR3PutU32(pSSM, pVM->rem.s.u32PendingInterrupt);
673
674	return SSMR3PutU32(pSSM, ~0); /* terminator */
675	}
676
677
678	/**
679	* Execute state load operation.
680	*
681	* @returns VBox status code.
682	* @param pVM VM Handle.
683	* @param pSSM SSM operation handle.
684	* @param uVersion Data layout version.
685	* @param uPass The data pass.
686	*/
687	static DECLCALLBACK(int) remR3Load(PVM pVM, PSSMHANDLE pSSM, uint32_t uVersion, uint32_t uPass)
688	{
689	uint32_t u32Dummy;
690	uint32_t fRawRing0 = false;
691	uint32_t u32Sep;
692	uint32_t i;
693	int rc;
694	PREM pRem;
695
696	LogFlow(("remR3Load:\n"));
697	Assert(uPass == SSM_PASS_FINAL); NOREF(uPass);
698
699	/*
700	* Validate version.
701	*/
702	if ( uVersion != REM_SAVED_STATE_VERSION
703	&& uVersion != REM_SAVED_STATE_VERSION_VER1_6)
704	{
705	AssertMsgFailed(("remR3Load: Invalid version uVersion=%d!\n", uVersion));
706	return VERR_SSM_UNSUPPORTED_DATA_UNIT_VERSION;
707	}
708
709	/*
710	* Do a reset to be on the safe side...
711	*/
712	REMR3Reset(pVM);
713
714	/*
715	* Ignore all ignorable notifications.
716	* (Not doing this will cause serious trouble.)
717	*/
718	ASMAtomicIncU32(&pVM->rem.s.cIgnoreAll);
719
720	/*
721	* Load the required CPU Env bits.
722	* (Not much because we're never in REM when doing the save.)
723	*/
724	pRem = &pVM->rem.s;
725	Assert(!pRem->fInREM);
726	SSMR3GetU32(pSSM, &pRem->Env.hflags);
727	if (uVersion == REM_SAVED_STATE_VERSION_VER1_6)
728	{
729	/* Redundant REM CPU state has to be loaded, but can be ignored. */
730	CPUX86State_Ver16 temp;
731	SSMR3GetMem(pSSM, &temp, RT_OFFSETOF(CPUX86State_Ver16, jmp_env));
732	}
733
734	rc = SSMR3GetU32(pSSM, &u32Sep); /* separator */
735	if (RT_FAILURE(rc))
736	return rc;
737	if (u32Sep != ~0U)
738	{
739	AssertMsgFailed(("u32Sep=%#x\n", u32Sep));
740	return VERR_SSM_DATA_UNIT_FORMAT_CHANGED;
741	}
742
743	/* Remember if we've entered raw mode (vital for ring 1 checks in e.g. iret emulation). */
744	SSMR3GetUInt(pSSM, &fRawRing0);
745	if (fRawRing0)
746	pRem->Env.state \|= CPU_RAW_RING0;
747
748	if (uVersion == REM_SAVED_STATE_VERSION_VER1_6)
749	{
750	/*
751	* Load the REM stuff.
752	*/
753	/** @todo r=bird: We should just drop all these items, restoring doesn't make
754	* sense. */
755	rc = SSMR3GetU32(pSSM, (uint32_t *)&pRem->cInvalidatedPages);
756	if (RT_FAILURE(rc))
757	return rc;
758	if (pRem->cInvalidatedPages > RT_ELEMENTS(pRem->aGCPtrInvalidatedPages))
759	{
760	AssertMsgFailed(("cInvalidatedPages=%#x\n", pRem->cInvalidatedPages));
761	return VERR_SSM_DATA_UNIT_FORMAT_CHANGED;
762	}
763	for (i = 0; i < pRem->cInvalidatedPages; i++)
764	SSMR3GetGCPtr(pSSM, &pRem->aGCPtrInvalidatedPages[i]);
765	}
766
767	rc = SSMR3GetUInt(pSSM, &pVM->rem.s.u32PendingInterrupt);
768	if (RT_FAILURE(rc))
769	return rc;
770
771	/* check the terminator. */
772	rc = SSMR3GetU32(pSSM, &u32Sep);
773	if (RT_FAILURE(rc))
774	return rc;
775	if (u32Sep != ~0U)
776	{
777	AssertMsgFailed(("u32Sep=%#x (term)\n", u32Sep));
778	return VERR_SSM_DATA_UNIT_FORMAT_CHANGED;
779	}
780
781	/*
782	* Get the CPUID features.
783	*/
784	PVMCPU pVCpu = VMMGetCpu(pVM);
785	CPUMGetGuestCpuId(pVCpu, 1, &u32Dummy, &u32Dummy, &pVM->rem.s.Env.cpuid_ext_features, &pVM->rem.s.Env.cpuid_features);
786	CPUMGetGuestCpuId(pVCpu, 0x80000001, &u32Dummy, &u32Dummy, &u32Dummy, &pVM->rem.s.Env.cpuid_ext2_features);
787
788	/*
789	* Stop ignoring ignorable notifications.
790	*/
791	ASMAtomicDecU32(&pVM->rem.s.cIgnoreAll);
792
793	/*
794	* Sync the whole CPU state when executing code in the recompiler.
795	*/
796	for (i = 0; i < pVM->cCpus; i++)
797	{
798	PVMCPU pVCpu = &pVM->aCpus[i];
799	CPUMSetChangedFlags(pVCpu, CPUM_CHANGED_ALL);
800	}
801	return VINF_SUCCESS;
802	}
803
804
805
806	#undef LOG_GROUP
807	#define LOG_GROUP LOG_GROUP_REM_RUN
808
809	/**
810	* Single steps an instruction in recompiled mode.
811	*
812	* Before calling this function the REM state needs to be in sync with
813	* the VM. Call REMR3State() to perform the sync. It's only necessary
814	* (and permitted) to sync at the first call to REMR3Step()/REMR3Run()
815	* and after calling REMR3StateBack().
816	*
817	* @returns VBox status code.
818	*
819	* @param pVM VM Handle.
820	* @param pVCpu VMCPU Handle.
821	*/
822	REMR3DECL(int) REMR3Step(PVM pVM, PVMCPU pVCpu)
823	{
824	int rc, interrupt_request;
825	RTGCPTR GCPtrPC;
826	bool fBp;
827
828	/*
829	* Lock the REM - we don't wanna have anyone interrupting us
830	* while stepping - and enabled single stepping. We also ignore
831	* pending interrupts and suchlike.
832	*/
833	interrupt_request = pVM->rem.s.Env.interrupt_request;
834	Assert(!(interrupt_request & ~(CPU_INTERRUPT_HARD \| CPU_INTERRUPT_EXITTB \| CPU_INTERRUPT_TIMER \| CPU_INTERRUPT_EXTERNAL_HARD \| CPU_INTERRUPT_EXTERNAL_EXIT \| CPU_INTERRUPT_EXTERNAL_FLUSH_TLB \| CPU_INTERRUPT_EXTERNAL_TIMER)));
835	pVM->rem.s.Env.interrupt_request = 0;
836	cpu_single_step(&pVM->rem.s.Env, 1);
837
838	/*
839	* If we're standing at a breakpoint, that have to be disabled before we start stepping.
840	*/
841	GCPtrPC = pVM->rem.s.Env.eip + pVM->rem.s.Env.segs[R_CS].base;
842	fBp = !cpu_breakpoint_remove(&pVM->rem.s.Env, GCPtrPC, BP_GDB);
843
844	/*
845	* Execute and handle the return code.
846	* We execute without enabling the cpu tick, so on success we'll
847	* just flip it on and off to make sure it moves
848	*/
849	rc = cpu_exec(&pVM->rem.s.Env);
850	if (rc == EXCP_DEBUG)
851	{
852	TMR3NotifyResume(pVM, pVCpu);
853	TMR3NotifySuspend(pVM, pVCpu);
854	rc = VINF_EM_DBG_STEPPED;
855	}
856	else
857	{
858	switch (rc)
859	{
860	case EXCP_INTERRUPT: rc = VINF_SUCCESS; break;
861	case EXCP_HLT:
862	case EXCP_HALTED: rc = VINF_EM_HALT; break;
863	case EXCP_RC:
864	rc = pVM->rem.s.rc;
865	pVM->rem.s.rc = VERR_INTERNAL_ERROR;
866	break;
867	case EXCP_EXECUTE_RAW:
868	case EXCP_EXECUTE_HM:
869	/** @todo: is it correct? No! */
870	rc = VINF_SUCCESS;
871	break;
872	default:
873	AssertReleaseMsgFailed(("This really shouldn't happen, rc=%d!\n", rc));
874	rc = VERR_INTERNAL_ERROR;
875	break;
876	}
877	}
878
879	/*
880	* Restore the stuff we changed to prevent interruption.
881	* Unlock the REM.
882	*/
883	if (fBp)
884	{
885	int rc2 = cpu_breakpoint_insert(&pVM->rem.s.Env, GCPtrPC, BP_GDB, NULL);
886	Assert(rc2 == 0); NOREF(rc2);
887	}
888	cpu_single_step(&pVM->rem.s.Env, 0);
889	pVM->rem.s.Env.interrupt_request = interrupt_request;
890
891	return rc;
892	}
893
894
895	/**
896	* Set a breakpoint using the REM facilities.
897	*
898	* @returns VBox status code.
899	* @param pVM The VM handle.
900	* @param Address The breakpoint address.
901	* @thread The emulation thread.
902	*/
903	REMR3DECL(int) REMR3BreakpointSet(PVM pVM, RTGCUINTPTR Address)
904	{
905	VM_ASSERT_EMT(pVM);
906	if (!cpu_breakpoint_insert(&pVM->rem.s.Env, Address, BP_GDB, NULL))
907	{
908	LogFlow(("REMR3BreakpointSet: Address=%RGv\n", Address));
909	return VINF_SUCCESS;
910	}
911	LogFlow(("REMR3BreakpointSet: Address=%RGv - failed!\n", Address));
912	return VERR_REM_NO_MORE_BP_SLOTS;
913	}
914
915
916	/**
917	* Clears a breakpoint set by REMR3BreakpointSet().
918	*
919	* @returns VBox status code.
920	* @param pVM The VM handle.
921	* @param Address The breakpoint address.
922	* @thread The emulation thread.
923	*/
924	REMR3DECL(int) REMR3BreakpointClear(PVM pVM, RTGCUINTPTR Address)
925	{
926	VM_ASSERT_EMT(pVM);
927	if (!cpu_breakpoint_remove(&pVM->rem.s.Env, Address, BP_GDB))
928	{
929	LogFlow(("REMR3BreakpointClear: Address=%RGv\n", Address));
930	return VINF_SUCCESS;
931	}
932	LogFlow(("REMR3BreakpointClear: Address=%RGv - not found!\n", Address));
933	return VERR_REM_BP_NOT_FOUND;
934	}
935
936
937	/**
938	* Emulate an instruction.
939	*
940	* This function executes one instruction without letting anyone
941	* interrupt it. This is intended for being called while being in
942	* raw mode and thus will take care of all the state syncing between
943	* REM and the rest.
944	*
945	* @returns VBox status code.
946	* @param pVM VM handle.
947	* @param pVCpu VMCPU Handle.
948	*/
949	REMR3DECL(int) REMR3EmulateInstruction(PVM pVM, PVMCPU pVCpu)
950	{
951	bool fFlushTBs;
952
953	int rc, rc2;
954	Log2(("REMR3EmulateInstruction: (cs:eip=%04x:%08x)\n", CPUMGetGuestCS(pVCpu), CPUMGetGuestEIP(pVCpu)));
955
956	/* Make sure this flag is set; we might never execute remR3CanExecuteRaw in the AMD-V case.
957	* CPU_RAW_HM makes sure we never execute interrupt handlers in the recompiler.
958	*/
959	if (HMIsEnabled(pVM))
960	pVM->rem.s.Env.state \|= CPU_RAW_HM;
961
962	/* Skip the TB flush as that's rather expensive and not necessary for single instruction emulation. */
963	fFlushTBs = pVM->rem.s.fFlushTBs;
964	pVM->rem.s.fFlushTBs = false;
965
966	/*
967	* Sync the state and enable single instruction / single stepping.
968	*/
969	rc = REMR3State(pVM, pVCpu);
970	pVM->rem.s.fFlushTBs = fFlushTBs;
971	if (RT_SUCCESS(rc))
972	{
973	int interrupt_request = pVM->rem.s.Env.interrupt_request;
974	Assert(!(interrupt_request & ~(CPU_INTERRUPT_HARD \| CPU_INTERRUPT_EXITTB \| CPU_INTERRUPT_TIMER \| CPU_INTERRUPT_EXTERNAL_HARD \| CPU_INTERRUPT_EXTERNAL_EXIT \| CPU_INTERRUPT_EXTERNAL_FLUSH_TLB \| CPU_INTERRUPT_EXTERNAL_TIMER)));
975	#ifdef REM_USE_QEMU_SINGLE_STEP_FOR_LOGGING
976	cpu_single_step(&pVM->rem.s.Env, 0);
977	#endif
978	Assert(!pVM->rem.s.Env.singlestep_enabled);
979
980	/*
981	* Now we set the execute single instruction flag and enter the cpu_exec loop.
982	*/
983	TMNotifyStartOfExecution(pVCpu);
984	pVM->rem.s.Env.interrupt_request = CPU_INTERRUPT_SINGLE_INSTR;
985	rc = cpu_exec(&pVM->rem.s.Env);
986	TMNotifyEndOfExecution(pVCpu);
987	switch (rc)
988	{
989	/*
990	* Executed without anything out of the way happening.
991	*/
992	case EXCP_SINGLE_INSTR:
993	rc = VINF_EM_RESCHEDULE;
994	Log2(("REMR3EmulateInstruction: cpu_exec -> EXCP_SINGLE_INSTR\n"));
995	break;
996
997	/*
998	* If we take a trap or start servicing a pending interrupt, we might end up here.
999	* (Timer thread or some other thread wishing EMT's attention.)
1000	*/
1001	case EXCP_INTERRUPT:
1002	Log2(("REMR3EmulateInstruction: cpu_exec -> EXCP_INTERRUPT\n"));
1003	rc = VINF_EM_RESCHEDULE;
1004	break;
1005
1006	/*
1007	* Single step, we assume!
1008	* If there was a breakpoint there we're fucked now.
1009	*/
1010	case EXCP_DEBUG:
1011	if (pVM->rem.s.Env.watchpoint_hit)
1012	{
1013	/** @todo deal with watchpoints */
1014	Log2(("REMR3EmulateInstruction: cpu_exec -> EXCP_DEBUG rc=%Rrc !watchpoint_hit!\n", rc));
1015	rc = VINF_EM_DBG_BREAKPOINT;
1016	}
1017	else
1018	{
1019	CPUBreakpoint *pBP;
1020	RTGCPTR GCPtrPC = pVM->rem.s.Env.eip + pVM->rem.s.Env.segs[R_CS].base;
1021	QTAILQ_FOREACH(pBP, &pVM->rem.s.Env.breakpoints, entry)
1022	if (pBP->pc == GCPtrPC)
1023	break;
1024	rc = pBP ? VINF_EM_DBG_BREAKPOINT : VINF_EM_DBG_STEPPED;
1025	Log2(("REMR3EmulateInstruction: cpu_exec -> EXCP_DEBUG rc=%Rrc pBP=%p GCPtrPC=%RGv\n", rc, pBP, GCPtrPC));
1026	}
1027	break;
1028
1029	/*
1030	* hlt instruction.
1031	*/
1032	case EXCP_HLT:
1033	Log2(("REMR3EmulateInstruction: cpu_exec -> EXCP_HLT\n"));
1034	rc = VINF_EM_HALT;
1035	break;
1036
1037	/*
1038	* The VM has halted.
1039	*/
1040	case EXCP_HALTED:
1041	Log2(("REMR3EmulateInstruction: cpu_exec -> EXCP_HALTED\n"));
1042	rc = VINF_EM_HALT;
1043	break;
1044
1045	/*
1046	* Switch to RAW-mode.
1047	*/
1048	case EXCP_EXECUTE_RAW:
1049	Log2(("REMR3EmulateInstruction: cpu_exec -> EXCP_EXECUTE_RAW\n"));
1050	rc = VINF_EM_RESCHEDULE_RAW;
1051	break;
1052
1053	/*
1054	* Switch to hardware accelerated RAW-mode.
1055	*/
1056	case EXCP_EXECUTE_HM:
1057	Log2(("REMR3EmulateInstruction: cpu_exec -> EXCP_EXECUTE_HM\n"));
1058	rc = VINF_EM_RESCHEDULE_HM;
1059	break;
1060
1061	/*
1062	* An EM RC was raised (VMR3Reset/Suspend/PowerOff/some-fatal-error).
1063	*/
1064	case EXCP_RC:
1065	Log2(("REMR3EmulateInstruction: cpu_exec -> EXCP_RC\n"));
1066	rc = pVM->rem.s.rc;
1067	pVM->rem.s.rc = VERR_INTERNAL_ERROR;
1068	break;
1069
1070	/*
1071	* Figure out the rest when they arrive....
1072	*/
1073	default:
1074	AssertMsgFailed(("rc=%d\n", rc));
1075	Log2(("REMR3EmulateInstruction: cpu_exec -> %d\n", rc));
1076	rc = VINF_EM_RESCHEDULE;
1077	break;
1078	}
1079
1080	/*
1081	* Switch back the state.
1082	*/
1083	pVM->rem.s.Env.interrupt_request = interrupt_request;
1084	rc2 = REMR3StateBack(pVM, pVCpu);
1085	AssertRC(rc2);
1086	}
1087
1088	Log2(("REMR3EmulateInstruction: returns %Rrc (cs:eip=%04x:%RGv)\n",
1089	rc, pVM->rem.s.Env.segs[R_CS].selector, (RTGCPTR)pVM->rem.s.Env.eip));
1090	return rc;
1091	}
1092
1093
1094	/**
1095	* Used by REMR3Run to handle the case where CPU_EMULATE_SINGLE_STEP is set.
1096	*
1097	* @returns VBox status code.
1098	*
1099	* @param pVM The VM handle.
1100	* @param pVCpu The Virtual CPU handle.
1101	*/
1102	static int remR3RunLoggingStep(PVM pVM, PVMCPU pVCpu)
1103	{
1104	int rc;
1105
1106	Assert(pVM->rem.s.fInREM);
1107	#ifdef REM_USE_QEMU_SINGLE_STEP_FOR_LOGGING
1108	cpu_single_step(&pVM->rem.s.Env, 1);
1109	#else
1110	Assert(!pVM->rem.s.Env.singlestep_enabled);
1111	#endif
1112
1113	/*
1114	* Now we set the execute single instruction flag and enter the cpu_exec loop.
1115	*/
1116	for (;;)
1117	{
1118	char szBuf[256];
1119
1120	/*
1121	* Log the current registers state and instruction.
1122	*/
1123	remR3StateUpdate(pVM, pVCpu);
1124	DBGFR3Info(pVM->pUVM, "cpumguest", NULL, NULL);
1125	szBuf[0] = '\0';
1126	rc = DBGFR3DisasInstrEx(pVM->pUVM,
1127	pVCpu->idCpu,
1128	0, /* Sel */
1129	0, /* GCPtr */
1130	DBGF_DISAS_FLAGS_CURRENT_GUEST
1131	\| DBGF_DISAS_FLAGS_DEFAULT_MODE,
1132	szBuf,
1133	sizeof(szBuf),
1134	NULL);
1135	if (RT_FAILURE(rc))
1136	RTStrPrintf(szBuf, sizeof(szBuf), "DBGFR3DisasInstrEx failed with rc=%Rrc\n", rc);
1137	RTLogPrintf("CPU%d: %s\n", pVCpu->idCpu, szBuf);
1138
1139	/*
1140	* Execute the instruction.
1141	*/
1142	TMNotifyStartOfExecution(pVCpu);
1143
1144	if ( pVM->rem.s.Env.exception_index < 0
1145	\|\| pVM->rem.s.Env.exception_index > 256)
1146	pVM->rem.s.Env.exception_index = -1; /** @todo We need to do similar stuff elsewhere, I think. */
1147
1148	#ifdef REM_USE_QEMU_SINGLE_STEP_FOR_LOGGING
1149	pVM->rem.s.Env.interrupt_request = 0;
1150	#else
1151	pVM->rem.s.Env.interrupt_request = CPU_INTERRUPT_SINGLE_INSTR;
1152	#endif
1153	if ( VMCPU_FF_ISPENDING(pVCpu, VMCPU_FF_INTERRUPT_APIC \| VMCPU_FF_INTERRUPT_PIC)
1154	\|\| pVM->rem.s.u32PendingInterrupt != REM_NO_PENDING_IRQ)
1155	pVM->rem.s.Env.interrupt_request \|= CPU_INTERRUPT_HARD;
1156	RTLogPrintf("remR3RunLoggingStep: interrupt_request=%#x halted=%d exception_index=%#x\n", rc,
1157	pVM->rem.s.Env.interrupt_request,
1158	pVM->rem.s.Env.halted,
1159	pVM->rem.s.Env.exception_index
1160	);
1161
1162	rc = cpu_exec(&pVM->rem.s.Env);
1163
1164	RTLogPrintf("remR3RunLoggingStep: cpu_exec -> %#x interrupt_request=%#x halted=%d exception_index=%#x\n", rc,
1165	pVM->rem.s.Env.interrupt_request,
1166	pVM->rem.s.Env.halted,
1167	pVM->rem.s.Env.exception_index
1168	);
1169
1170	TMNotifyEndOfExecution(pVCpu);
1171
1172	switch (rc)
1173	{
1174	#ifndef REM_USE_QEMU_SINGLE_STEP_FOR_LOGGING
1175	/*
1176	* The normal exit.
1177	*/
1178	case EXCP_SINGLE_INSTR:
1179	if ( !VM_FF_ISPENDING(pVM, VM_FF_ALL_REM_MASK)
1180	&& !VMCPU_FF_ISPENDING(pVCpu, VMCPU_FF_ALL_REM_MASK))
1181	continue;
1182	RTLogPrintf("remR3RunLoggingStep: rc=VINF_SUCCESS w/ FFs (%#x/%#x)\n",
1183	pVM->fGlobalForcedActions, pVCpu->fLocalForcedActions);
1184	rc = VINF_SUCCESS;
1185	break;
1186
1187	#else
1188	/*
1189	* The normal exit, check for breakpoints at PC just to be sure.
1190	*/
1191	#endif
1192	case EXCP_DEBUG:
1193	if (pVM->rem.s.Env.watchpoint_hit)
1194	{
1195	/** @todo deal with watchpoints */
1196	Log2(("remR3RunLoggingStep: cpu_exec -> EXCP_DEBUG rc=%Rrc !watchpoint_hit!\n", rc));
1197	rc = VINF_EM_DBG_BREAKPOINT;
1198	}
1199	else
1200	{
1201	CPUBreakpoint *pBP;
1202	RTGCPTR GCPtrPC = pVM->rem.s.Env.eip + pVM->rem.s.Env.segs[R_CS].base;
1203	QTAILQ_FOREACH(pBP, &pVM->rem.s.Env.breakpoints, entry)
1204	if (pBP->pc == GCPtrPC)
1205	break;
1206	rc = pBP ? VINF_EM_DBG_BREAKPOINT : VINF_EM_DBG_STEPPED;
1207	Log2(("remR3RunLoggingStep: cpu_exec -> EXCP_DEBUG rc=%Rrc pBP=%p GCPtrPC=%RGv\n", rc, pBP, GCPtrPC));
1208	}
1209	#ifdef REM_USE_QEMU_SINGLE_STEP_FOR_LOGGING
1210	if (rc == VINF_EM_DBG_STEPPED)
1211	{
1212	if ( !VM_FF_ISPENDING(pVM, VM_FF_ALL_REM_MASK)
1213	&& !VMCPU_FF_ISPENDING(pVCpu, VMCPU_FF_ALL_REM_MASK))
1214	continue;
1215
1216	RTLogPrintf("remR3RunLoggingStep: rc=VINF_SUCCESS w/ FFs (%#x/%#x)\n",
1217	pVM->fGlobalForcedActions, pVCpu->fLocalForcedActions);
1218	rc = VINF_SUCCESS;
1219	}
1220	#endif
1221	break;
1222
1223	/*
1224	* If we take a trap or start servicing a pending interrupt, we might end up here.
1225	* (Timer thread or some other thread wishing EMT's attention.)
1226	*/
1227	case EXCP_INTERRUPT:
1228	RTLogPrintf("remR3RunLoggingStep: cpu_exec -> EXCP_INTERRUPT rc=VINF_SUCCESS\n");
1229	rc = VINF_SUCCESS;
1230	break;
1231
1232	/*
1233	* hlt instruction.
1234	*/
1235	case EXCP_HLT:
1236	RTLogPrintf("remR3RunLoggingStep: cpu_exec -> EXCP_HLT rc=VINF_EM_HALT\n");
1237	rc = VINF_EM_HALT;
1238	break;
1239
1240	/*
1241	* The VM has halted.
1242	*/
1243	case EXCP_HALTED:
1244	RTLogPrintf("remR3RunLoggingStep: cpu_exec -> EXCP_HALTED rc=VINF_EM_HALT\n");
1245	rc = VINF_EM_HALT;
1246	break;
1247
1248	/*
1249	* Switch to RAW-mode.
1250	*/
1251	case EXCP_EXECUTE_RAW:
1252	RTLogPrintf("remR3RunLoggingStep: cpu_exec -> EXCP_EXECUTE_RAW rc=VINF_EM_RESCHEDULE_RAW\n");
1253	rc = VINF_EM_RESCHEDULE_RAW;
1254	break;
1255
1256	/*
1257	* Switch to hardware accelerated RAW-mode.
1258	*/
1259	case EXCP_EXECUTE_HM:
1260	RTLogPrintf("remR3RunLoggingStep: cpu_exec -> EXCP_EXECUTE_HM rc=VINF_EM_RESCHEDULE_HM\n");
1261	rc = VINF_EM_RESCHEDULE_HM;
1262	break;
1263
1264	/*
1265	* An EM RC was raised (VMR3Reset/Suspend/PowerOff/some-fatal-error).
1266	*/
1267	case EXCP_RC:
1268	RTLogPrintf("remR3RunLoggingStep: cpu_exec -> EXCP_RC rc=%Rrc\n", pVM->rem.s.rc);
1269	rc = pVM->rem.s.rc;
1270	pVM->rem.s.rc = VERR_INTERNAL_ERROR;
1271	break;
1272
1273	/*
1274	* Figure out the rest when they arrive....
1275	*/
1276	default:
1277	AssertMsgFailed(("rc=%d\n", rc));
1278	RTLogPrintf("remR3RunLoggingStep: cpu_exec -> %d rc=VINF_EM_RESCHEDULE\n", rc);
1279	rc = VINF_EM_RESCHEDULE;
1280	break;
1281	}
1282	break;
1283	}
1284
1285	#ifdef REM_USE_QEMU_SINGLE_STEP_FOR_LOGGING
1286	// cpu_single_step(&pVM->rem.s.Env, 0);
1287	#else
1288	pVM->rem.s.Env.interrupt_request &= ~(CPU_INTERRUPT_SINGLE_INSTR \| CPU_INTERRUPT_SINGLE_INSTR_IN_FLIGHT);
1289	#endif
1290	return rc;
1291	}
1292
1293
1294	/**
1295	* Runs code in recompiled mode.
1296	*
1297	* Before calling this function the REM state needs to be in sync with
1298	* the VM. Call REMR3State() to perform the sync. It's only necessary
1299	* (and permitted) to sync at the first call to REMR3Step()/REMR3Run()
1300	* and after calling REMR3StateBack().
1301	*
1302	* @returns VBox status code.
1303	*
1304	* @param pVM VM Handle.
1305	* @param pVCpu VMCPU Handle.
1306	*/
1307	REMR3DECL(int) REMR3Run(PVM pVM, PVMCPU pVCpu)
1308	{
1309	int rc;
1310
1311	if (RT_UNLIKELY(pVM->rem.s.Env.state & CPU_EMULATE_SINGLE_STEP))
1312	return remR3RunLoggingStep(pVM, pVCpu);
1313
1314	Assert(pVM->rem.s.fInREM);
1315	Log2(("REMR3Run: (cs:eip=%04x:%RGv)\n", pVM->rem.s.Env.segs[R_CS].selector, (RTGCPTR)pVM->rem.s.Env.eip));
1316
1317	TMNotifyStartOfExecution(pVCpu);
1318	rc = cpu_exec(&pVM->rem.s.Env);
1319	TMNotifyEndOfExecution(pVCpu);
1320	switch (rc)
1321	{
1322	/*
1323	* This happens when the execution was interrupted
1324	* by an external event, like pending timers.
1325	*/
1326	case EXCP_INTERRUPT:
1327	Log2(("REMR3Run: cpu_exec -> EXCP_INTERRUPT\n"));
1328	rc = VINF_SUCCESS;
1329	break;
1330
1331	/*
1332	* hlt instruction.
1333	*/
1334	case EXCP_HLT:
1335	Log2(("REMR3Run: cpu_exec -> EXCP_HLT\n"));
1336	rc = VINF_EM_HALT;
1337	break;
1338
1339	/*
1340	* The VM has halted.
1341	*/
1342	case EXCP_HALTED:
1343	Log2(("REMR3Run: cpu_exec -> EXCP_HALTED\n"));
1344	rc = VINF_EM_HALT;
1345	break;
1346
1347	/*
1348	* Breakpoint/single step.
1349	*/
1350	case EXCP_DEBUG:
1351	if (pVM->rem.s.Env.watchpoint_hit)
1352	{
1353	/** @todo deal with watchpoints */
1354	Log2(("REMR3Run: cpu_exec -> EXCP_DEBUG rc=%Rrc !watchpoint_hit!\n", rc));
1355	rc = VINF_EM_DBG_BREAKPOINT;
1356	}
1357	else
1358	{
1359	CPUBreakpoint *pBP;
1360	RTGCPTR GCPtrPC = pVM->rem.s.Env.eip + pVM->rem.s.Env.segs[R_CS].base;
1361	QTAILQ_FOREACH(pBP, &pVM->rem.s.Env.breakpoints, entry)
1362	if (pBP->pc == GCPtrPC)
1363	break;
1364	rc = pBP ? VINF_EM_DBG_BREAKPOINT : VINF_EM_DBG_STEPPED;
1365	Log2(("REMR3Run: cpu_exec -> EXCP_DEBUG rc=%Rrc pBP=%p GCPtrPC=%RGv\n", rc, pBP, GCPtrPC));
1366	}
1367	break;
1368
1369	/*
1370	* Switch to RAW-mode.
1371	*/
1372	case EXCP_EXECUTE_RAW:
1373	Log2(("REMR3Run: cpu_exec -> EXCP_EXECUTE_RAW pc=%RGv\n", pVM->rem.s.Env.eip));
1374	rc = VINF_EM_RESCHEDULE_RAW;
1375	break;
1376
1377	/*
1378	* Switch to hardware accelerated RAW-mode.
1379	*/
1380	case EXCP_EXECUTE_HM:
1381	Log2(("REMR3Run: cpu_exec -> EXCP_EXECUTE_HM\n"));
1382	rc = VINF_EM_RESCHEDULE_HM;
1383	break;
1384
1385	/*
1386	* An EM RC was raised (VMR3Reset/Suspend/PowerOff/some-fatal-error).
1387	*/
1388	case EXCP_RC:
1389	Log2(("REMR3Run: cpu_exec -> EXCP_RC rc=%Rrc\n", pVM->rem.s.rc));
1390	rc = pVM->rem.s.rc;
1391	pVM->rem.s.rc = VERR_INTERNAL_ERROR;
1392	break;
1393
1394	/*
1395	* Figure out the rest when they arrive....
1396	*/
1397	default:
1398	AssertMsgFailed(("rc=%d\n", rc));
1399	Log2(("REMR3Run: cpu_exec -> %d\n", rc));
1400	rc = VINF_SUCCESS;
1401	break;
1402	}
1403
1404	Log2(("REMR3Run: returns %Rrc (cs:eip=%04x:%RGv)\n", rc, pVM->rem.s.Env.segs[R_CS].selector, (RTGCPTR)pVM->rem.s.Env.eip));
1405	return rc;
1406	}
1407
1408
1409	/**
1410	* Check if the cpu state is suitable for Raw execution.
1411	*
1412	* @returns true if RAW/HWACC mode is ok, false if we should stay in REM.
1413	*
1414	* @param env The CPU env struct.
1415	* @param eip The EIP to check this for (might differ from env->eip).
1416	* @param fFlags hflags OR'ed with IOPL, TF and VM from eflags.
1417	* @param piException Stores EXCP_EXECUTE_RAW/HWACC in case raw mode is supported in this context
1418	*
1419	* @remark This function must be kept in perfect sync with the scheduler in EM.cpp!
1420	*/
1421	bool remR3CanExecuteRaw(CPUX86State env, RTGCPTR eip, unsigned fFlags, int piException)
1422	{
1423	/* !!! THIS MUST BE IN SYNC WITH emR3Reschedule !!! */
1424	/* !!! THIS MUST BE IN SYNC WITH emR3Reschedule !!! */
1425	/* !!! THIS MUST BE IN SYNC WITH emR3Reschedule !!! */
1426	uint32_t u32CR0;
1427
1428	#ifdef IEM_VERIFICATION_MODE
1429	return false;
1430	#endif
1431
1432	/* Update counter. */
1433	env->pVM->rem.s.cCanExecuteRaw++;
1434
1435	/* Never when single stepping+logging guest code. */
1436	if (env->state & CPU_EMULATE_SINGLE_STEP)
1437	return false;
1438
1439	if (HMIsEnabled(env->pVM))
1440	{
1441	CPUMCTX Ctx;
1442
1443	env->state \|= CPU_RAW_HM;
1444
1445	/*
1446	* The simple check first...
1447	*/
1448	if (!EMIsHwVirtExecutionEnabled(env->pVM))
1449	return false;
1450
1451	/*
1452	* Create partial context for HMR3CanExecuteGuest
1453	*/
1454	Ctx.cr0 = env->cr[0];
1455	Ctx.cr3 = env->cr[3];
1456	Ctx.cr4 = env->cr[4];
1457
1458	Ctx.tr.Sel = env->tr.selector;
1459	Ctx.tr.ValidSel = env->tr.selector;
1460	Ctx.tr.fFlags = CPUMSELREG_FLAGS_VALID;
1461	Ctx.tr.u64Base = env->tr.base;
1462	Ctx.tr.u32Limit = env->tr.limit;
1463	Ctx.tr.Attr.u = (env->tr.flags >> 8) & 0xF0FF;
1464
1465	Ctx.ldtr.Sel = env->ldt.selector;
1466	Ctx.ldtr.ValidSel = env->ldt.selector;
1467	Ctx.ldtr.fFlags = CPUMSELREG_FLAGS_VALID;
1468	Ctx.ldtr.u64Base = env->ldt.base;
1469	Ctx.ldtr.u32Limit = env->ldt.limit;
1470	Ctx.ldtr.Attr.u = (env->ldt.flags >> 8) & 0xF0FF;
1471
1472	Ctx.idtr.cbIdt = env->idt.limit;
1473	Ctx.idtr.pIdt = env->idt.base;
1474
1475	Ctx.gdtr.cbGdt = env->gdt.limit;
1476	Ctx.gdtr.pGdt = env->gdt.base;
1477
1478	Ctx.rsp = env->regs[R_ESP];
1479	Ctx.rip = env->eip;
1480
1481	Ctx.eflags.u32 = env->eflags;
1482
1483	Ctx.cs.Sel = env->segs[R_CS].selector;
1484	Ctx.cs.ValidSel = env->segs[R_CS].selector;
1485	Ctx.cs.fFlags = CPUMSELREG_FLAGS_VALID;
1486	Ctx.cs.u64Base = env->segs[R_CS].base;
1487	Ctx.cs.u32Limit = env->segs[R_CS].limit;
1488	Ctx.cs.Attr.u = (env->segs[R_CS].flags >> 8) & 0xF0FF;
1489
1490	Ctx.ds.Sel = env->segs[R_DS].selector;
1491	Ctx.ds.ValidSel = env->segs[R_DS].selector;
1492	Ctx.ds.fFlags = CPUMSELREG_FLAGS_VALID;
1493	Ctx.ds.u64Base = env->segs[R_DS].base;
1494	Ctx.ds.u32Limit = env->segs[R_DS].limit;
1495	Ctx.ds.Attr.u = (env->segs[R_DS].flags >> 8) & 0xF0FF;
1496
1497	Ctx.es.Sel = env->segs[R_ES].selector;
1498	Ctx.es.ValidSel = env->segs[R_ES].selector;
1499	Ctx.es.fFlags = CPUMSELREG_FLAGS_VALID;
1500	Ctx.es.u64Base = env->segs[R_ES].base;
1501	Ctx.es.u32Limit = env->segs[R_ES].limit;
1502	Ctx.es.Attr.u = (env->segs[R_ES].flags >> 8) & 0xF0FF;
1503
1504	Ctx.fs.Sel = env->segs[R_FS].selector;
1505	Ctx.fs.ValidSel = env->segs[R_FS].selector;
1506	Ctx.fs.fFlags = CPUMSELREG_FLAGS_VALID;
1507	Ctx.fs.u64Base = env->segs[R_FS].base;
1508	Ctx.fs.u32Limit = env->segs[R_FS].limit;
1509	Ctx.fs.Attr.u = (env->segs[R_FS].flags >> 8) & 0xF0FF;
1510
1511	Ctx.gs.Sel = env->segs[R_GS].selector;
1512	Ctx.gs.ValidSel = env->segs[R_GS].selector;
1513	Ctx.gs.fFlags = CPUMSELREG_FLAGS_VALID;
1514	Ctx.gs.u64Base = env->segs[R_GS].base;
1515	Ctx.gs.u32Limit = env->segs[R_GS].limit;
1516	Ctx.gs.Attr.u = (env->segs[R_GS].flags >> 8) & 0xF0FF;
1517
1518	Ctx.ss.Sel = env->segs[R_SS].selector;
1519	Ctx.ss.ValidSel = env->segs[R_SS].selector;
1520	Ctx.ss.fFlags = CPUMSELREG_FLAGS_VALID;
1521	Ctx.ss.u64Base = env->segs[R_SS].base;
1522	Ctx.ss.u32Limit = env->segs[R_SS].limit;
1523	Ctx.ss.Attr.u = (env->segs[R_SS].flags >> 8) & 0xF0FF;
1524
1525	Ctx.msrEFER = env->efer;
1526
1527	/* Hardware accelerated raw-mode:
1528	*
1529	* Typically only 32-bits protected mode, with paging enabled, code is allowed here.
1530	*/
1531	if (HMR3CanExecuteGuest(env->pVM, &Ctx) == true)
1532	{
1533	*piException = EXCP_EXECUTE_HM;
1534	return true;
1535	}
1536	return false;
1537	}
1538
1539	/*
1540	* Here we only support 16 & 32 bits protected mode ring 3 code that has no IO privileges
1541	* or 32 bits protected mode ring 0 code
1542	*
1543	* The tests are ordered by the likelihood of being true during normal execution.
1544	*/
1545	if (fFlags & (HF_TF_MASK \| HF_INHIBIT_IRQ_MASK))
1546	{
1547	STAM_COUNTER_INC(&gStatRefuseTFInhibit);
1548	Log2(("raw mode refused: fFlags=%#x\n", fFlags));
1549	return false;
1550	}
1551
1552	#ifndef VBOX_RAW_V86
1553	if (fFlags & VM_MASK) {
1554	STAM_COUNTER_INC(&gStatRefuseVM86);
1555	Log2(("raw mode refused: VM_MASK\n"));
1556	return false;
1557	}
1558	#endif
1559
1560	if (env->state & CPU_EMULATE_SINGLE_INSTR)
1561	{
1562	#ifndef DEBUG_bird
1563	Log2(("raw mode refused: CPU_EMULATE_SINGLE_INSTR\n"));
1564	#endif
1565	return false;
1566	}
1567
1568	if (env->singlestep_enabled)
1569	{
1570	//Log2(("raw mode refused: Single step\n"));
1571	return false;
1572	}
1573
1574	if (!QTAILQ_EMPTY(&env->breakpoints))
1575	{
1576	//Log2(("raw mode refused: Breakpoints\n"));
1577	return false;
1578	}
1579
1580	if (!QTAILQ_EMPTY(&env->watchpoints))
1581	{
1582	//Log2(("raw mode refused: Watchpoints\n"));
1583	return false;
1584	}
1585
1586	u32CR0 = env->cr[0];
1587	if ((u32CR0 & (X86_CR0_PG \| X86_CR0_PE)) != (X86_CR0_PG \| X86_CR0_PE))
1588	{
1589	STAM_COUNTER_INC(&gStatRefusePaging);
1590	//Log2(("raw mode refused: %s%s%s\n", (u32CR0 & X86_CR0_PG) ? "" : " !PG", (u32CR0 & X86_CR0_PE) ? "" : " !PE", (u32CR0 & X86_CR0_AM) ? "" : " !AM"));
1591	return false;
1592	}
1593
1594	if (env->cr[4] & CR4_PAE_MASK)
1595	{
1596	if (!(env->cpuid_features & X86_CPUID_FEATURE_EDX_PAE))
1597	{
1598	STAM_COUNTER_INC(&gStatRefusePAE);
1599	return false;
1600	}
1601	}
1602
1603	if (((fFlags >> HF_CPL_SHIFT) & 3) == 3)
1604	{
1605	if (!EMIsRawRing3Enabled(env->pVM))
1606	return false;
1607
1608	if (!(env->eflags & IF_MASK))
1609	{
1610	STAM_COUNTER_INC(&gStatRefuseIF0);
1611	Log2(("raw mode refused: IF (RawR3)\n"));
1612	return false;
1613	}
1614
1615	if (!(u32CR0 & CR0_WP_MASK) && EMIsRawRing0Enabled(env->pVM))
1616	{
1617	STAM_COUNTER_INC(&gStatRefuseWP0);
1618	Log2(("raw mode refused: CR0.WP + RawR0\n"));
1619	return false;
1620	}
1621	}
1622	else
1623	{
1624	if (!EMIsRawRing0Enabled(env->pVM))
1625	return false;
1626
1627	// Let's start with pure 32 bits ring 0 code first
1628	if ((fFlags & (HF_SS32_MASK \| HF_CS32_MASK)) != (HF_SS32_MASK \| HF_CS32_MASK))
1629	{
1630	STAM_COUNTER_INC(&gStatRefuseCode16);
1631	Log2(("raw r0 mode refused: HF_[S\|C]S32_MASK fFlags=%#x\n", fFlags));
1632	return false;
1633	}
1634
1635	if (EMIsRawRing1Enabled(env->pVM))
1636	{
1637	/* Only ring 0 and 1 supervisor code. */
1638	if (((fFlags >> HF_CPL_SHIFT) & 3) == 2) /* ring 1 code is moved into ring 2, so we can't support ring-2 in that case. */
1639	{
1640	Log2(("raw r0 mode refused: CPL %d\n", (fFlags >> HF_CPL_SHIFT) & 3));
1641	return false;
1642	}
1643	}
1644	/* Only R0. */
1645	else if (((fFlags >> HF_CPL_SHIFT) & 3) != 0)
1646	{
1647	STAM_COUNTER_INC(&gStatRefuseRing1or2);
1648	Log2(("raw r0 mode refused: CPL %d\n", ((fFlags >> HF_CPL_SHIFT) & 3) ));
1649	return false;
1650	}
1651
1652	if (!(u32CR0 & CR0_WP_MASK))
1653	{
1654	STAM_COUNTER_INC(&gStatRefuseWP0);
1655	Log2(("raw r0 mode refused: CR0.WP=0!\n"));
1656	return false;
1657	}
1658
1659	#ifdef VBOX_WITH_RAW_MODE
1660	if (PATMIsPatchGCAddr(env->pVM, eip))
1661	{
1662	Log2(("raw r0 mode forced: patch code\n"));
1663	*piException = EXCP_EXECUTE_RAW;
1664	return true;
1665	}
1666	#endif
1667
1668	#if !defined(VBOX_ALLOW_IF0) && !defined(VBOX_RUN_INTERRUPT_GATE_HANDLERS)
1669	if (!(env->eflags & IF_MASK))
1670	{
1671	STAM_COUNTER_INC(&gStatRefuseIF0);
1672	////Log2(("R0: IF=0 VIF=%d %08X\n", eip, *env->pVMeflags));
1673	//Log2(("RR0: Interrupts turned off; fall back to emulation\n"));
1674	return false;
1675	}
1676	#endif
1677
1678	#ifndef VBOX_WITH_RAW_RING1
1679	if (((env->eflags >> IOPL_SHIFT) & 3) != 0)
1680	{
1681	Log2(("raw r0 mode refused: IOPL %d\n", ((env->eflags >> IOPL_SHIFT) & 3)));
1682	return false;
1683	}
1684	#endif
1685	env->state \|= CPU_RAW_RING0;
1686	}
1687
1688	/*
1689	* Don't reschedule the first time we're called, because there might be
1690	* special reasons why we're here that is not covered by the above checks.
1691	*/
1692	if (env->pVM->rem.s.cCanExecuteRaw == 1)
1693	{
1694	Log2(("raw mode refused: first scheduling\n"));
1695	STAM_COUNTER_INC(&gStatRefuseCanExecute);
1696	return false;
1697	}
1698
1699	/*
1700	* Stale hidden selectors means raw-mode is unsafe (being very careful).
1701	*/
1702	if (env->segs[R_CS].fVBoxFlags & CPUMSELREG_FLAGS_STALE)
1703	{
1704	Log2(("raw mode refused: stale CS (%#x)\n", env->segs[R_CS].selector));
1705	STAM_COUNTER_INC(&gaStatRefuseStale[R_CS]);
1706	return false;
1707	}
1708	if (env->segs[R_SS].fVBoxFlags & CPUMSELREG_FLAGS_STALE)
1709	{
1710	Log2(("raw mode refused: stale SS (%#x)\n", env->segs[R_SS].selector));
1711	STAM_COUNTER_INC(&gaStatRefuseStale[R_SS]);
1712	return false;
1713	}
1714	if (env->segs[R_DS].fVBoxFlags & CPUMSELREG_FLAGS_STALE)
1715	{
1716	Log2(("raw mode refused: stale DS (%#x)\n", env->segs[R_DS].selector));
1717	STAM_COUNTER_INC(&gaStatRefuseStale[R_DS]);
1718	return false;
1719	}
1720	if (env->segs[R_ES].fVBoxFlags & CPUMSELREG_FLAGS_STALE)
1721	{
1722	Log2(("raw mode refused: stale ES (%#x)\n", env->segs[R_ES].selector));
1723	STAM_COUNTER_INC(&gaStatRefuseStale[R_ES]);
1724	return false;
1725	}
1726	if (env->segs[R_FS].fVBoxFlags & CPUMSELREG_FLAGS_STALE)
1727	{
1728	Log2(("raw mode refused: stale FS (%#x)\n", env->segs[R_FS].selector));
1729	STAM_COUNTER_INC(&gaStatRefuseStale[R_FS]);
1730	return false;
1731	}
1732	if (env->segs[R_GS].fVBoxFlags & CPUMSELREG_FLAGS_STALE)
1733	{
1734	Log2(("raw mode refused: stale GS (%#x)\n", env->segs[R_GS].selector));
1735	STAM_COUNTER_INC(&gaStatRefuseStale[R_GS]);
1736	return false;
1737	}
1738
1739	/* Assert(env->pVCpu && PGMPhysIsA20Enabled(env->pVCpu));*/
1740	*piException = EXCP_EXECUTE_RAW;
1741	return true;
1742	}
1743
1744
1745	#ifdef VBOX_WITH_RAW_MODE
1746	/**
1747	* Fetches a code byte.
1748	*
1749	* @returns Success indicator (bool) for ease of use.
1750	* @param env The CPU environment structure.
1751	* @param GCPtrInstr Where to fetch code.
1752	* @param pu8Byte Where to store the byte on success
1753	*/
1754	bool remR3GetOpcode(CPUX86State env, RTGCPTR GCPtrInstr, uint8_t pu8Byte)
1755	{
1756	int rc = PATMR3QueryOpcode(env->pVM, GCPtrInstr, pu8Byte);
1757	if (RT_SUCCESS(rc))
1758	return true;
1759	return false;
1760	}
1761	#endif /* VBOX_WITH_RAW_MODE */
1762
1763
1764	/**
1765	* Flush (or invalidate if you like) page table/dir entry.
1766	*
1767	* (invlpg instruction; tlb_flush_page)
1768	*
1769	* @param env Pointer to cpu environment.
1770	* @param GCPtr The virtual address which page table/dir entry should be invalidated.
1771	*/
1772	void remR3FlushPage(CPUX86State *env, RTGCPTR GCPtr)
1773	{
1774	PVM pVM = env->pVM;
1775	PCPUMCTX pCtx;
1776	int rc;
1777
1778	Assert(EMRemIsLockOwner(env->pVM));
1779
1780	/*
1781	* When we're replaying invlpg instructions or restoring a saved
1782	* state we disable this path.
1783	*/
1784	if (pVM->rem.s.fIgnoreInvlPg \|\| pVM->rem.s.cIgnoreAll)
1785	return;
1786	LogFlow(("remR3FlushPage: GCPtr=%RGv\n", GCPtr));
1787	Assert(pVM->rem.s.fInREM \|\| pVM->rem.s.fInStateSync);
1788
1789	//RAWEx_ProfileStop(env, STATS_QEMU_TOTAL);
1790
1791	/*
1792	* Update the control registers before calling PGMFlushPage.
1793	*/
1794	pCtx = (PCPUMCTX)pVM->rem.s.pCtx;
1795	Assert(pCtx);
1796	pCtx->cr0 = env->cr[0];
1797	pCtx->cr3 = env->cr[3];
1798	#ifdef VBOX_WITH_RAW_MODE
1799	if (((env->cr[4] ^ pCtx->cr4) & X86_CR4_VME) && !HMIsEnabled(pVM))
1800	VMCPU_FF_SET(env->pVCpu, VMCPU_FF_SELM_SYNC_TSS);
1801	#endif
1802	pCtx->cr4 = env->cr[4];
1803
1804	/*
1805	* Let PGM do the rest.
1806	*/
1807	Assert(env->pVCpu);
1808	rc = PGMInvalidatePage(env->pVCpu, GCPtr);
1809	if (RT_FAILURE(rc))
1810	{
1811	AssertMsgFailed(("remR3FlushPage %RGv failed with %d!!\n", GCPtr, rc));
1812	VMCPU_FF_SET(env->pVCpu, VMCPU_FF_PGM_SYNC_CR3);
1813	}
1814	//RAWEx_ProfileStart(env, STATS_QEMU_TOTAL);
1815	}
1816
1817
1818	#ifndef REM_PHYS_ADDR_IN_TLB
1819	/** Wrapper for PGMR3PhysTlbGCPhys2Ptr. */
1820	void remR3TlbGCPhys2Ptr(CPUX86State env1, target_ulong physAddr, int fWritable)
1821	{
1822	void *pv;
1823	int rc;
1824
1825
1826	/* Address must be aligned enough to fiddle with lower bits */
1827	Assert((physAddr & 0x3) == 0);
1828	/AssertMsg((env1->a20_mask & physAddr) == physAddr, ("%llx\n", (uint64_t)physAddr));/
1829
1830	STAM_PROFILE_START(&gStatGCPhys2HCVirt, a);
1831	rc = PGMR3PhysTlbGCPhys2Ptr(env1->pVM, physAddr, true /fWritable/, &pv);
1832	STAM_PROFILE_STOP(&gStatGCPhys2HCVirt, a);
1833	Assert( rc == VINF_SUCCESS
1834	\|\| rc == VINF_PGM_PHYS_TLB_CATCH_WRITE
1835	\|\| rc == VERR_PGM_PHYS_TLB_CATCH_ALL
1836	\|\| rc == VERR_PGM_PHYS_TLB_UNASSIGNED);
1837	if (RT_FAILURE(rc))
1838	return (void *)1;
1839	if (rc == VINF_PGM_PHYS_TLB_CATCH_WRITE)
1840	return (void *)((uintptr_t)pv \| 2);
1841	return pv;
1842	}
1843	#endif /* REM_PHYS_ADDR_IN_TLB */
1844
1845
1846	/**
1847	* Called from tlb_protect_code in order to write monitor a code page.
1848	*
1849	* @param env Pointer to the CPU environment.
1850	* @param GCPtr Code page to monitor
1851	*/
1852	void remR3ProtectCode(CPUX86State *env, RTGCPTR GCPtr)
1853	{
1854	#ifdef VBOX_REM_PROTECT_PAGES_FROM_SMC
1855	Assert(env->pVM->rem.s.fInREM);
1856	if ( (env->cr[0] & X86_CR0_PG) /* paging must be enabled */
1857	&& !(env->state & CPU_EMULATE_SINGLE_INSTR) /* ignore during single instruction execution */
1858	&& (((env->hflags >> HF_CPL_SHIFT) & 3) == 0) /* supervisor mode only */
1859	&& !(env->eflags & VM_MASK) /* no V86 mode */
1860	&& !HMIsEnabled(env->pVM))
1861	CSAMR3MonitorPage(env->pVM, GCPtr, CSAM_TAG_REM);
1862	#endif
1863	}
1864
1865
1866	/**
1867	* Called from tlb_unprotect_code in order to clear write monitoring for a code page.
1868	*
1869	* @param env Pointer to the CPU environment.
1870	* @param GCPtr Code page to monitor
1871	*/
1872	void remR3UnprotectCode(CPUX86State *env, RTGCPTR GCPtr)
1873	{
1874	Assert(env->pVM->rem.s.fInREM);
1875	#ifdef VBOX_REM_PROTECT_PAGES_FROM_SMC
1876	if ( (env->cr[0] & X86_CR0_PG) /* paging must be enabled */
1877	&& !(env->state & CPU_EMULATE_SINGLE_INSTR) /* ignore during single instruction execution */
1878	&& (((env->hflags >> HF_CPL_SHIFT) & 3) == 0) /* supervisor mode only */
1879	&& !(env->eflags & VM_MASK) /* no V86 mode */
1880	&& !HMIsEnabled(env->pVM))
1881	CSAMR3UnmonitorPage(env->pVM, GCPtr, CSAM_TAG_REM);
1882	#endif
1883	}
1884
1885
1886	/**
1887	* Called when the CPU is initialized, any of the CRx registers are changed or
1888	* when the A20 line is modified.
1889	*
1890	* @param env Pointer to the CPU environment.
1891	* @param fGlobal Set if the flush is global.
1892	*/
1893	void remR3FlushTLB(CPUX86State *env, bool fGlobal)
1894	{
1895	PVM pVM = env->pVM;
1896	PCPUMCTX pCtx;
1897	Assert(EMRemIsLockOwner(pVM));
1898
1899	/*
1900	* When we're replaying invlpg instructions or restoring a saved
1901	* state we disable this path.
1902	*/
1903	if (pVM->rem.s.fIgnoreCR3Load \|\| pVM->rem.s.cIgnoreAll)
1904	return;
1905	Assert(pVM->rem.s.fInREM);
1906
1907	/*
1908	* The caller doesn't check cr4, so we have to do that for ourselves.
1909	*/
1910	if (!fGlobal && !(env->cr[4] & X86_CR4_PGE))
1911	fGlobal = true;
1912	Log(("remR3FlushTLB: CR0=%08RX64 CR3=%08RX64 CR4=%08RX64 %s\n", (uint64_t)env->cr[0], (uint64_t)env->cr[3], (uint64_t)env->cr[4], fGlobal ? " global" : ""));
1913
1914	/*
1915	* Update the control registers before calling PGMR3FlushTLB.
1916	*/
1917	pCtx = (PCPUMCTX)pVM->rem.s.pCtx;
1918	Assert(pCtx);
1919	pCtx->cr0 = env->cr[0];
1920	pCtx->cr3 = env->cr[3];
1921	#ifdef VBOX_WITH_RAW_MODE
1922	if (((env->cr[4] ^ pCtx->cr4) & X86_CR4_VME) && !HMIsEnabled(pVM))
1923	VMCPU_FF_SET(env->pVCpu, VMCPU_FF_SELM_SYNC_TSS);
1924	#endif
1925	pCtx->cr4 = env->cr[4];
1926
1927	/*
1928	* Let PGM do the rest.
1929	*/
1930	Assert(env->pVCpu);
1931	PGMFlushTLB(env->pVCpu, env->cr[3], fGlobal);
1932	}
1933
1934
1935	/**
1936	* Called when any of the cr0, cr4 or efer registers is updated.
1937	*
1938	* @param env Pointer to the CPU environment.
1939	*/
1940	void remR3ChangeCpuMode(CPUX86State *env)
1941	{
1942	PVM pVM = env->pVM;
1943	uint64_t efer;
1944	PCPUMCTX pCtx;
1945	int rc;
1946
1947	/*
1948	* When we're replaying loads or restoring a saved
1949	* state this path is disabled.
1950	*/
1951	if (pVM->rem.s.fIgnoreCpuMode \|\| pVM->rem.s.cIgnoreAll)
1952	return;
1953	Assert(pVM->rem.s.fInREM);
1954
1955	/*
1956	* Update the control registers before calling PGMChangeMode()
1957	* as it may need to map whatever cr3 is pointing to.
1958	*/
1959	pCtx = (PCPUMCTX)pVM->rem.s.pCtx;
1960	Assert(pCtx);
1961	pCtx->cr0 = env->cr[0];
1962	pCtx->cr3 = env->cr[3];
1963	#ifdef VBOX_WITH_RAW_MODE
1964	if (((env->cr[4] ^ pCtx->cr4) & X86_CR4_VME) && !HMIsEnabled(pVM))
1965	VMCPU_FF_SET(env->pVCpu, VMCPU_FF_SELM_SYNC_TSS);
1966	#endif
1967	pCtx->cr4 = env->cr[4];
1968	#ifdef TARGET_X86_64
1969	efer = env->efer;
1970	pCtx->msrEFER = efer;
1971	#else
1972	efer = 0;
1973	#endif
1974	Assert(env->pVCpu);
1975	rc = PGMChangeMode(env->pVCpu, env->cr[0], env->cr[4], efer);
1976	if (rc != VINF_SUCCESS)
1977	{
1978	if (rc >= VINF_EM_FIRST && rc <= VINF_EM_LAST)
1979	{
1980	Log(("PGMChangeMode(, %RX64, %RX64, %RX64) -> %Rrc -> remR3RaiseRC\n", env->cr[0], env->cr[4], efer, rc));
1981	remR3RaiseRC(env->pVM, rc);
1982	}
1983	else
1984	cpu_abort(env, "PGMChangeMode(, %RX64, %RX64, %RX64) -> %Rrc\n", env->cr[0], env->cr[4], efer, rc);
1985	}
1986	}
1987
1988
1989	/**
1990	* Called from compiled code to run dma.
1991	*
1992	* @param env Pointer to the CPU environment.
1993	*/
1994	void remR3DmaRun(CPUX86State *env)
1995	{
1996	remR3ProfileStop(STATS_QEMU_RUN_EMULATED_CODE);
1997	PDMR3DmaRun(env->pVM);
1998	remR3ProfileStart(STATS_QEMU_RUN_EMULATED_CODE);
1999	}
2000
2001
2002	/**
2003	* Called from compiled code to schedule pending timers in VMM
2004	*
2005	* @param env Pointer to the CPU environment.
2006	*/
2007	void remR3TimersRun(CPUX86State *env)
2008	{
2009	LogFlow(("remR3TimersRun:\n"));
2010	LogIt(LOG_INSTANCE, RTLOGGRPFLAGS_LEVEL_5, LOG_GROUP_TM, ("remR3TimersRun\n"));
2011	remR3ProfileStop(STATS_QEMU_RUN_EMULATED_CODE);
2012	remR3ProfileStart(STATS_QEMU_RUN_TIMERS);
2013	TMR3TimerQueuesDo(env->pVM);
2014	remR3ProfileStop(STATS_QEMU_RUN_TIMERS);
2015	remR3ProfileStart(STATS_QEMU_RUN_EMULATED_CODE);
2016	}
2017
2018
2019	/**
2020	* Record trap occurrence
2021	*
2022	* @returns VBox status code
2023	* @param env Pointer to the CPU environment.
2024	* @param uTrap Trap nr
2025	* @param uErrorCode Error code
2026	* @param pvNextEIP Next EIP
2027	*/
2028	int remR3NotifyTrap(CPUX86State *env, uint32_t uTrap, uint32_t uErrorCode, RTGCPTR pvNextEIP)
2029	{
2030	PVM pVM = env->pVM;
2031	#ifdef VBOX_WITH_STATISTICS
2032	static STAMCOUNTER s_aStatTrap[255];
2033	static bool s_aRegisters[RT_ELEMENTS(s_aStatTrap)];
2034	#endif
2035
2036	#ifdef VBOX_WITH_STATISTICS
2037	if (uTrap < 255)
2038	{
2039	if (!s_aRegisters[uTrap])
2040	{
2041	char szStatName[64];
2042	s_aRegisters[uTrap] = true;
2043	RTStrPrintf(szStatName, sizeof(szStatName), "/REM/Trap/0x%02X", uTrap);
2044	STAM_REG(env->pVM, &s_aStatTrap[uTrap], STAMTYPE_COUNTER, szStatName, STAMUNIT_OCCURENCES, "Trap stats.");
2045	}
2046	STAM_COUNTER_INC(&s_aStatTrap[uTrap]);
2047	}
2048	#endif
2049	Log(("remR3NotifyTrap: uTrap=%x error=%x next_eip=%RGv eip=%RGv cr2=%RGv\n", uTrap, uErrorCode, pvNextEIP, (RTGCPTR)env->eip, (RTGCPTR)env->cr[2]));
2050	if( uTrap < 0x20
2051	&& (env->cr[0] & X86_CR0_PE)
2052	&& !(env->eflags & X86_EFL_VM))
2053	{
2054	#ifdef DEBUG
2055	remR3DisasInstr(env, 1, "remR3NotifyTrap: ");
2056	#endif
2057	if(pVM->rem.s.uPendingException == uTrap && ++pVM->rem.s.cPendingExceptions > 512)
2058	{
2059	LogRel(("VERR_REM_TOO_MANY_TRAPS -> uTrap=%x error=%x next_eip=%RGv eip=%RGv cr2=%RGv\n", uTrap, uErrorCode, pvNextEIP, (RTGCPTR)env->eip, (RTGCPTR)env->cr[2]));
2060	remR3RaiseRC(env->pVM, VERR_REM_TOO_MANY_TRAPS);
2061	return VERR_REM_TOO_MANY_TRAPS;
2062	}
2063	if(pVM->rem.s.uPendingException != uTrap \|\| pVM->rem.s.uPendingExcptEIP != env->eip \|\| pVM->rem.s.uPendingExcptCR2 != env->cr[2])
2064	{
2065	Log(("remR3NotifyTrap: uTrap=%#x set as pending\n", uTrap));
2066	pVM->rem.s.cPendingExceptions = 1;
2067	}
2068	pVM->rem.s.uPendingException = uTrap;
2069	pVM->rem.s.uPendingExcptEIP = env->eip;
2070	pVM->rem.s.uPendingExcptCR2 = env->cr[2];
2071	}
2072	else
2073	{
2074	pVM->rem.s.cPendingExceptions = 0;
2075	pVM->rem.s.uPendingException = uTrap;
2076	pVM->rem.s.uPendingExcptEIP = env->eip;
2077	pVM->rem.s.uPendingExcptCR2 = env->cr[2];
2078	}
2079	return VINF_SUCCESS;
2080	}
2081
2082
2083	/*
2084	* Clear current active trap
2085	*
2086	* @param pVM VM Handle.
2087	*/
2088	void remR3TrapClear(PVM pVM)
2089	{
2090	pVM->rem.s.cPendingExceptions = 0;
2091	pVM->rem.s.uPendingException = 0;
2092	pVM->rem.s.uPendingExcptEIP = 0;
2093	pVM->rem.s.uPendingExcptCR2 = 0;
2094	}
2095
2096
2097	/*
2098	* Record previous call instruction addresses
2099	*
2100	* @param env Pointer to the CPU environment.
2101	*/
2102	void remR3RecordCall(CPUX86State *env)
2103	{
2104	#ifdef VBOX_WITH_RAW_MODE
2105	CSAMR3RecordCallAddress(env->pVM, env->eip);
2106	#endif
2107	}
2108
2109
2110	/**
2111	* Syncs the internal REM state with the VM.
2112	*
2113	* This must be called before REMR3Run() is invoked whenever when the REM
2114	* state is not up to date. Calling it several times in a row is not
2115	* permitted.
2116	*
2117	* @returns VBox status code.
2118	*
2119	* @param pVM VM Handle.
2120	* @param pVCpu VMCPU Handle.
2121	*
2122	* @remark The caller has to check for important FFs before calling REMR3Run. REMR3State will
2123	* no do this since the majority of the callers don't want any unnecessary of events
2124	* pending that would immediately interrupt execution.
2125	*/
2126	REMR3DECL(int) REMR3State(PVM pVM, PVMCPU pVCpu)
2127	{
2128	register const CPUMCTX *pCtx;
2129	register unsigned fFlags;
2130	unsigned i;
2131	TRPMEVENT enmType;
2132	uint8_t u8TrapNo;
2133	uint32_t uCpl;
2134	int rc;
2135
2136	STAM_PROFILE_START(&pVM->rem.s.StatsState, a);
2137	Log2(("REMR3State:\n"));
2138
2139	pVM->rem.s.Env.pVCpu = pVCpu;
2140	pCtx = pVM->rem.s.pCtx = CPUMQueryGuestCtxPtr(pVCpu);
2141
2142	Assert(!pVM->rem.s.fInREM);
2143	pVM->rem.s.fInStateSync = true;
2144
2145	/*
2146	* If we have to flush TBs, do that immediately.
2147	*/
2148	if (pVM->rem.s.fFlushTBs)
2149	{
2150	STAM_COUNTER_INC(&gStatFlushTBs);
2151	tb_flush(&pVM->rem.s.Env);
2152	pVM->rem.s.fFlushTBs = false;
2153	}
2154
2155	/*
2156	* Copy the registers which require no special handling.
2157	*/
2158	#ifdef TARGET_X86_64
2159	/* Note that the high dwords of 64 bits registers are undefined in 32 bits mode and are undefined after a mode change. */
2160	Assert(R_EAX == 0);
2161	pVM->rem.s.Env.regs[R_EAX] = pCtx->rax;
2162	Assert(R_ECX == 1);
2163	pVM->rem.s.Env.regs[R_ECX] = pCtx->rcx;
2164	Assert(R_EDX == 2);
2165	pVM->rem.s.Env.regs[R_EDX] = pCtx->rdx;
2166	Assert(R_EBX == 3);
2167	pVM->rem.s.Env.regs[R_EBX] = pCtx->rbx;
2168	Assert(R_ESP == 4);
2169	pVM->rem.s.Env.regs[R_ESP] = pCtx->rsp;
2170	Assert(R_EBP == 5);
2171	pVM->rem.s.Env.regs[R_EBP] = pCtx->rbp;
2172	Assert(R_ESI == 6);
2173	pVM->rem.s.Env.regs[R_ESI] = pCtx->rsi;
2174	Assert(R_EDI == 7);
2175	pVM->rem.s.Env.regs[R_EDI] = pCtx->rdi;
2176	pVM->rem.s.Env.regs[8] = pCtx->r8;
2177	pVM->rem.s.Env.regs[9] = pCtx->r9;
2178	pVM->rem.s.Env.regs[10] = pCtx->r10;
2179	pVM->rem.s.Env.regs[11] = pCtx->r11;
2180	pVM->rem.s.Env.regs[12] = pCtx->r12;
2181	pVM->rem.s.Env.regs[13] = pCtx->r13;
2182	pVM->rem.s.Env.regs[14] = pCtx->r14;
2183	pVM->rem.s.Env.regs[15] = pCtx->r15;
2184
2185	pVM->rem.s.Env.eip = pCtx->rip;
2186
2187	pVM->rem.s.Env.eflags = pCtx->rflags.u64;
2188	#else
2189	Assert(R_EAX == 0);
2190	pVM->rem.s.Env.regs[R_EAX] = pCtx->eax;
2191	Assert(R_ECX == 1);
2192	pVM->rem.s.Env.regs[R_ECX] = pCtx->ecx;
2193	Assert(R_EDX == 2);
2194	pVM->rem.s.Env.regs[R_EDX] = pCtx->edx;
2195	Assert(R_EBX == 3);
2196	pVM->rem.s.Env.regs[R_EBX] = pCtx->ebx;
2197	Assert(R_ESP == 4);
2198	pVM->rem.s.Env.regs[R_ESP] = pCtx->esp;
2199	Assert(R_EBP == 5);
2200	pVM->rem.s.Env.regs[R_EBP] = pCtx->ebp;
2201	Assert(R_ESI == 6);
2202	pVM->rem.s.Env.regs[R_ESI] = pCtx->esi;
2203	Assert(R_EDI == 7);
2204	pVM->rem.s.Env.regs[R_EDI] = pCtx->edi;
2205	pVM->rem.s.Env.eip = pCtx->eip;
2206
2207	pVM->rem.s.Env.eflags = pCtx->eflags.u32;
2208	#endif
2209
2210	pVM->rem.s.Env.cr[2] = pCtx->cr2;
2211
2212	/** @todo we could probably benefit from using a CPUM_CHANGED_DRx flag too! */
2213	for (i=0;i<8;i++)
2214	pVM->rem.s.Env.dr[i] = pCtx->dr[i];
2215
2216	#ifdef HF_HALTED_MASK /** @todo remove me when we're up to date again. */
2217	/*
2218	* Clear the halted hidden flag (the interrupt waking up the CPU can
2219	* have been dispatched in raw mode).
2220	*/
2221	pVM->rem.s.Env.hflags &= ~HF_HALTED_MASK;
2222	#endif
2223
2224	/*
2225	* Replay invlpg? Only if we're not flushing the TLB.
2226	*/
2227	fFlags = CPUMR3RemEnter(pVCpu, &uCpl);
2228	LogFlow(("CPUMR3RemEnter %x %x\n", fFlags, uCpl));
2229	if (pVM->rem.s.cInvalidatedPages)
2230	{
2231	if (!(fFlags & CPUM_CHANGED_GLOBAL_TLB_FLUSH))
2232	{
2233	RTUINT i;
2234
2235	pVM->rem.s.fIgnoreCR3Load = true;
2236	pVM->rem.s.fIgnoreInvlPg = true;
2237	for (i = 0; i < pVM->rem.s.cInvalidatedPages; i++)
2238	{
2239	Log2(("REMR3State: invlpg %RGv\n", pVM->rem.s.aGCPtrInvalidatedPages[i]));
2240	tlb_flush_page(&pVM->rem.s.Env, pVM->rem.s.aGCPtrInvalidatedPages[i]);
2241	}
2242	pVM->rem.s.fIgnoreInvlPg = false;
2243	pVM->rem.s.fIgnoreCR3Load = false;
2244	}
2245	pVM->rem.s.cInvalidatedPages = 0;
2246	}
2247
2248	/* Replay notification changes. */
2249	REMR3ReplayHandlerNotifications(pVM);
2250
2251	/* Update MSRs; before CRx registers! */
2252	pVM->rem.s.Env.efer = pCtx->msrEFER;
2253	pVM->rem.s.Env.star = pCtx->msrSTAR;
2254	pVM->rem.s.Env.pat = pCtx->msrPAT;
2255	#ifdef TARGET_X86_64
2256	pVM->rem.s.Env.lstar = pCtx->msrLSTAR;
2257	pVM->rem.s.Env.cstar = pCtx->msrCSTAR;
2258	pVM->rem.s.Env.fmask = pCtx->msrSFMASK;
2259	pVM->rem.s.Env.kernelgsbase = pCtx->msrKERNELGSBASE;
2260
2261	/* Update the internal long mode activate flag according to the new EFER value. */
2262	if (pCtx->msrEFER & MSR_K6_EFER_LMA)
2263	pVM->rem.s.Env.hflags \|= HF_LMA_MASK;
2264	else
2265	pVM->rem.s.Env.hflags &= ~(HF_LMA_MASK \| HF_CS64_MASK);
2266	#endif
2267
2268	/* Update the inhibit IRQ mask. */
2269	pVM->rem.s.Env.hflags &= ~HF_INHIBIT_IRQ_MASK;
2270	if (VMCPU_FF_ISSET(pVCpu, VMCPU_FF_INHIBIT_INTERRUPTS))
2271	{
2272	RTGCPTR InhibitPC = EMGetInhibitInterruptsPC(pVCpu);
2273	if (InhibitPC == pCtx->rip)
2274	pVM->rem.s.Env.hflags \|= HF_INHIBIT_IRQ_MASK;
2275	else
2276	{
2277	Log(("Clearing VMCPU_FF_INHIBIT_INTERRUPTS at %RGv - successor %RGv (REM#1)\n", (RTGCPTR)pCtx->rip, InhibitPC));
2278	VMCPU_FF_CLEAR(pVCpu, VMCPU_FF_INHIBIT_INTERRUPTS);
2279	}
2280	}
2281
2282	/*
2283	* Sync the A20 gate.
2284	*/
2285	bool fA20State = PGMPhysIsA20Enabled(pVCpu);
2286	if (fA20State != RT_BOOL(pVM->rem.s.Env.a20_mask & RT_BIT(20)))
2287	{
2288	ASMAtomicIncU32(&pVM->rem.s.cIgnoreAll);
2289	cpu_x86_set_a20(&pVM->rem.s.Env, fA20State);
2290	ASMAtomicDecU32(&pVM->rem.s.cIgnoreAll);
2291	}
2292
2293	/*
2294	* Registers which are rarely changed and require special handling / order when changed.
2295	*/
2296	if (fFlags & ( CPUM_CHANGED_GLOBAL_TLB_FLUSH
2297	\| CPUM_CHANGED_CR4
2298	\| CPUM_CHANGED_CR0
2299	\| CPUM_CHANGED_CR3
2300	\| CPUM_CHANGED_GDTR
2301	\| CPUM_CHANGED_IDTR
2302	\| CPUM_CHANGED_SYSENTER_MSR
2303	\| CPUM_CHANGED_LDTR
2304	\| CPUM_CHANGED_CPUID
2305	\| CPUM_CHANGED_FPU_REM
2306	)
2307	)
2308	{
2309	if (fFlags & CPUM_CHANGED_GLOBAL_TLB_FLUSH)
2310	{
2311	pVM->rem.s.fIgnoreCR3Load = true;
2312	tlb_flush(&pVM->rem.s.Env, true);
2313	pVM->rem.s.fIgnoreCR3Load = false;
2314	}
2315
2316	/* CR4 before CR0! */
2317	if (fFlags & CPUM_CHANGED_CR4)
2318	{
2319	pVM->rem.s.fIgnoreCR3Load = true;
2320	pVM->rem.s.fIgnoreCpuMode = true;
2321	cpu_x86_update_cr4(&pVM->rem.s.Env, pCtx->cr4);
2322	pVM->rem.s.fIgnoreCpuMode = false;
2323	pVM->rem.s.fIgnoreCR3Load = false;
2324	}
2325
2326	if (fFlags & CPUM_CHANGED_CR0)
2327	{
2328	pVM->rem.s.fIgnoreCR3Load = true;
2329	pVM->rem.s.fIgnoreCpuMode = true;
2330	cpu_x86_update_cr0(&pVM->rem.s.Env, pCtx->cr0);
2331	pVM->rem.s.fIgnoreCpuMode = false;
2332	pVM->rem.s.fIgnoreCR3Load = false;
2333	}
2334
2335	if (fFlags & CPUM_CHANGED_CR3)
2336	{
2337	pVM->rem.s.fIgnoreCR3Load = true;
2338	cpu_x86_update_cr3(&pVM->rem.s.Env, pCtx->cr3);
2339	pVM->rem.s.fIgnoreCR3Load = false;
2340	}
2341
2342	if (fFlags & CPUM_CHANGED_GDTR)
2343	{
2344	pVM->rem.s.Env.gdt.base = pCtx->gdtr.pGdt;
2345	pVM->rem.s.Env.gdt.limit = pCtx->gdtr.cbGdt;
2346	}
2347
2348	if (fFlags & CPUM_CHANGED_IDTR)
2349	{
2350	pVM->rem.s.Env.idt.base = pCtx->idtr.pIdt;
2351	pVM->rem.s.Env.idt.limit = pCtx->idtr.cbIdt;
2352	}
2353
2354	if (fFlags & CPUM_CHANGED_SYSENTER_MSR)
2355	{
2356	pVM->rem.s.Env.sysenter_cs = pCtx->SysEnter.cs;
2357	pVM->rem.s.Env.sysenter_eip = pCtx->SysEnter.eip;
2358	pVM->rem.s.Env.sysenter_esp = pCtx->SysEnter.esp;
2359	}
2360
2361	if (fFlags & CPUM_CHANGED_LDTR)
2362	{
2363	if (pCtx->ldtr.fFlags & CPUMSELREG_FLAGS_VALID)
2364	{
2365	pVM->rem.s.Env.ldt.selector = pCtx->ldtr.Sel;
2366	pVM->rem.s.Env.ldt.newselector = 0;
2367	pVM->rem.s.Env.ldt.fVBoxFlags = pCtx->ldtr.fFlags;
2368	pVM->rem.s.Env.ldt.base = pCtx->ldtr.u64Base;
2369	pVM->rem.s.Env.ldt.limit = pCtx->ldtr.u32Limit;
2370	pVM->rem.s.Env.ldt.flags = (pCtx->ldtr.Attr.u << 8) & 0xFFFFFF;
2371	}
2372	else
2373	{
2374	AssertFailed(); /* Shouldn't happen, see cpumR3LoadExec. */
2375	sync_ldtr(&pVM->rem.s.Env, pCtx->ldtr.Sel);
2376	}
2377	}
2378
2379	if (fFlags & CPUM_CHANGED_CPUID)
2380	{
2381	uint32_t u32Dummy;
2382
2383	/*
2384	* Get the CPUID features.
2385	*/
2386	CPUMGetGuestCpuId(pVCpu, 1, &u32Dummy, &u32Dummy, &pVM->rem.s.Env.cpuid_ext_features, &pVM->rem.s.Env.cpuid_features);
2387	CPUMGetGuestCpuId(pVCpu, 0x80000001, &u32Dummy, &u32Dummy, &u32Dummy, &pVM->rem.s.Env.cpuid_ext2_features);
2388	}
2389
2390	/* Sync FPU state after CR4, CPUID and EFER (!). */
2391	if (fFlags & CPUM_CHANGED_FPU_REM)
2392	save_raw_fp_state(&pVM->rem.s.Env, (uint8_t )&pCtx->fpu); / 'save' is an excellent name. */
2393	}
2394
2395	/*
2396	* Sync TR unconditionally to make life simpler.
2397	*/
2398	pVM->rem.s.Env.tr.selector = pCtx->tr.Sel;
2399	pVM->rem.s.Env.tr.newselector = 0;
2400	pVM->rem.s.Env.tr.fVBoxFlags = pCtx->tr.fFlags;
2401	pVM->rem.s.Env.tr.base = pCtx->tr.u64Base;
2402	pVM->rem.s.Env.tr.limit = pCtx->tr.u32Limit;
2403	pVM->rem.s.Env.tr.flags = (pCtx->tr.Attr.u << 8) & 0xFFFFFF;
2404	/* Note! do_interrupt will fault if the busy flag is still set... */
2405	pVM->rem.s.Env.tr.flags &= ~DESC_TSS_BUSY_MASK;
2406
2407	/*
2408	* Update selector registers.
2409	*
2410	* This must be done after we've synced gdt, ldt and crX registers
2411	* since we're reading the GDT/LDT om sync_seg. This will happen with
2412	* saved state which takes a quick dip into rawmode for instance.
2413	*
2414	* CPL/Stack; Note first check this one as the CPL might have changed.
2415	* The wrong CPL can cause QEmu to raise an exception in sync_seg!!
2416	*/
2417	cpu_x86_set_cpl(&pVM->rem.s.Env, uCpl);
2418	/* Note! QEmu saves the 2nd dword of the descriptor; we should convert the attribute word back! */
2419	#define SYNC_IN_SREG(a_pEnv, a_SReg, a_pRemSReg, a_pVBoxSReg) \
2420	do \
2421	{ \
2422	if (CPUMSELREG_ARE_HIDDEN_PARTS_VALID(pVCpu, a_pVBoxSReg)) \
2423	{ \
2424	cpu_x86_load_seg_cache(a_pEnv, R_##a_SReg, \
2425	(a_pVBoxSReg)->Sel, \
2426	(a_pVBoxSReg)->u64Base, \
2427	(a_pVBoxSReg)->u32Limit, \
2428	((a_pVBoxSReg)->Attr.u << 8) & 0xFFFFFF); \
2429	(a_pRemSReg)->fVBoxFlags = (a_pVBoxSReg)->fFlags; \
2430	} \
2431	/* This only-reload-if-changed stuff is the old approach, we should ditch it. */ \
2432	else if ((a_pRemSReg)->selector != (a_pVBoxSReg)->Sel) \
2433	{ \
2434	Log2(("REMR3State: " #a_SReg " changed from %04x to %04x!\n", \
2435	(a_pRemSReg)->selector, (a_pVBoxSReg)->Sel)); \
2436	sync_seg(a_pEnv, R_##a_SReg, (a_pVBoxSReg)->Sel); \
2437	if ((a_pRemSReg)->newselector) \
2438	STAM_COUNTER_INC(&gStatSelOutOfSync[R_##a_SReg]); \
2439	} \
2440	else \
2441	(a_pRemSReg)->newselector = 0; \
2442	} while (0)
2443
2444	SYNC_IN_SREG(&pVM->rem.s.Env, CS, &pVM->rem.s.Env.segs[R_CS], &pCtx->cs);
2445	SYNC_IN_SREG(&pVM->rem.s.Env, SS, &pVM->rem.s.Env.segs[R_SS], &pCtx->ss);
2446	SYNC_IN_SREG(&pVM->rem.s.Env, DS, &pVM->rem.s.Env.segs[R_DS], &pCtx->ds);
2447	SYNC_IN_SREG(&pVM->rem.s.Env, ES, &pVM->rem.s.Env.segs[R_ES], &pCtx->es);
2448	SYNC_IN_SREG(&pVM->rem.s.Env, FS, &pVM->rem.s.Env.segs[R_FS], &pCtx->fs);
2449	SYNC_IN_SREG(&pVM->rem.s.Env, GS, &pVM->rem.s.Env.segs[R_GS], &pCtx->gs);
2450	/** @todo need to find a way to communicate potential GDT/LDT changes and thread switches. The selector might
2451	* be the same but not the base/limit. */
2452
2453	/*
2454	* Check for traps.
2455	*/
2456	pVM->rem.s.Env.exception_index = -1; /** @todo this won't work :/ */
2457	rc = TRPMQueryTrap(pVCpu, &u8TrapNo, &enmType);
2458	if (RT_SUCCESS(rc))
2459	{
2460	#ifdef DEBUG
2461	if (u8TrapNo == 0x80)
2462	{
2463	remR3DumpLnxSyscall(pVCpu);
2464	remR3DumpOBsdSyscall(pVCpu);
2465	}
2466	#endif
2467
2468	pVM->rem.s.Env.exception_index = u8TrapNo;
2469	if (enmType != TRPM_SOFTWARE_INT)
2470	{
2471	pVM->rem.s.Env.exception_is_int = 0;
2472	pVM->rem.s.Env.exception_next_eip = pVM->rem.s.Env.eip;
2473	}
2474	else
2475	{
2476	/*
2477	* The there are two 1 byte opcodes and one 2 byte opcode for software interrupts.
2478	* We ASSUME that there are no prefixes and sets the default to 2 byte, and checks
2479	* for int03 and into.
2480	*/
2481	pVM->rem.s.Env.exception_is_int = 1;
2482	pVM->rem.s.Env.exception_next_eip = pCtx->rip + 2;
2483	/* int 3 may be generated by one-byte 0xcc */
2484	if (u8TrapNo == 3)
2485	{
2486	if (read_byte(&pVM->rem.s.Env, pVM->rem.s.Env.segs[R_CS].base + pCtx->rip) == 0xcc)
2487	pVM->rem.s.Env.exception_next_eip = pCtx->rip + 1;
2488	}
2489	/* int 4 may be generated by one-byte 0xce */
2490	else if (u8TrapNo == 4)
2491	{
2492	if (read_byte(&pVM->rem.s.Env, pVM->rem.s.Env.segs[R_CS].base + pCtx->rip) == 0xce)
2493	pVM->rem.s.Env.exception_next_eip = pCtx->rip + 1;
2494	}
2495	}
2496
2497	/* get error code and cr2 if needed. */
2498	if (enmType == TRPM_TRAP)
2499	{
2500	switch (u8TrapNo)
2501	{
2502	case X86_XCPT_PF:
2503	pVM->rem.s.Env.cr[2] = TRPMGetFaultAddress(pVCpu);
2504	/* fallthru */
2505	case X86_XCPT_TS: case X86_XCPT_NP: case X86_XCPT_SS: case X86_XCPT_GP:
2506	pVM->rem.s.Env.error_code = TRPMGetErrorCode(pVCpu);
2507	break;
2508
2509	case X86_XCPT_AC: case X86_XCPT_DF:
2510	default:
2511	pVM->rem.s.Env.error_code = 0;
2512	break;
2513	}
2514	}
2515	else
2516	pVM->rem.s.Env.error_code = 0;
2517
2518	/*
2519	* We can now reset the active trap since the recompiler is gonna have a go at it.
2520	*/
2521	rc = TRPMResetTrap(pVCpu);
2522	AssertRC(rc);
2523	Log2(("REMR3State: trap=%02x errcd=%RGv cr2=%RGv nexteip=%RGv%s\n", pVM->rem.s.Env.exception_index, (RTGCPTR)pVM->rem.s.Env.error_code,
2524	(RTGCPTR)pVM->rem.s.Env.cr[2], (RTGCPTR)pVM->rem.s.Env.exception_next_eip, pVM->rem.s.Env.exception_is_int ? " software" : ""));
2525	}
2526
2527	/*
2528	* Clear old interrupt request flags; Check for pending hardware interrupts.
2529	* (See @remark for why we don't check for other FFs.)
2530	*/
2531	pVM->rem.s.Env.interrupt_request &= ~(CPU_INTERRUPT_HARD \| CPU_INTERRUPT_EXITTB \| CPU_INTERRUPT_TIMER);
2532	if ( pVM->rem.s.u32PendingInterrupt != REM_NO_PENDING_IRQ
2533	\|\| VMCPU_FF_ISPENDING(pVCpu, VMCPU_FF_INTERRUPT_APIC \| VMCPU_FF_INTERRUPT_PIC))
2534	pVM->rem.s.Env.interrupt_request \|= CPU_INTERRUPT_HARD;
2535
2536	/*
2537	* We're now in REM mode.
2538	*/
2539	VMCPU_SET_STATE(pVCpu, VMCPUSTATE_STARTED_EXEC_REM);
2540	pVM->rem.s.fInREM = true;
2541	pVM->rem.s.fInStateSync = false;
2542	pVM->rem.s.cCanExecuteRaw = 0;
2543	STAM_PROFILE_STOP(&pVM->rem.s.StatsState, a);
2544	Log2(("REMR3State: returns VINF_SUCCESS\n"));
2545	return VINF_SUCCESS;
2546	}
2547
2548
2549	/**
2550	* Syncs back changes in the REM state to the the VM state.
2551	*
2552	* This must be called after invoking REMR3Run().
2553	* Calling it several times in a row is not permitted.
2554	*
2555	* @returns VBox status code.
2556	*
2557	* @param pVM VM Handle.
2558	* @param pVCpu VMCPU Handle.
2559	*/
2560	REMR3DECL(int) REMR3StateBack(PVM pVM, PVMCPU pVCpu)
2561	{
2562	register PCPUMCTX pCtx = pVM->rem.s.pCtx;
2563	Assert(pCtx);
2564	unsigned i;
2565
2566	STAM_PROFILE_START(&pVM->rem.s.StatsStateBack, a);
2567	Log2(("REMR3StateBack:\n"));
2568	Assert(pVM->rem.s.fInREM);
2569
2570	/*
2571	* Copy back the registers.
2572	* This is done in the order they are declared in the CPUMCTX structure.
2573	*/
2574
2575	/** @todo FOP */
2576	/** @todo FPUIP */
2577	/** @todo CS */
2578	/** @todo FPUDP */
2579	/** @todo DS */
2580
2581	/** @todo check if FPU/XMM was actually used in the recompiler */
2582	restore_raw_fp_state(&pVM->rem.s.Env, (uint8_t *)&pCtx->fpu);
2583	//// dprintf2(("FPU state CW=%04X TT=%04X SW=%04X (%04X)\n", env->fpuc, env->fpstt, env->fpus, pVMCtx->fpu.FSW));
2584
2585	#ifdef TARGET_X86_64
2586	/* Note that the high dwords of 64 bits registers are undefined in 32 bits mode and are undefined after a mode change. */
2587	pCtx->rdi = pVM->rem.s.Env.regs[R_EDI];
2588	pCtx->rsi = pVM->rem.s.Env.regs[R_ESI];
2589	pCtx->rbp = pVM->rem.s.Env.regs[R_EBP];
2590	pCtx->rax = pVM->rem.s.Env.regs[R_EAX];
2591	pCtx->rbx = pVM->rem.s.Env.regs[R_EBX];
2592	pCtx->rdx = pVM->rem.s.Env.regs[R_EDX];
2593	pCtx->rcx = pVM->rem.s.Env.regs[R_ECX];
2594	pCtx->r8 = pVM->rem.s.Env.regs[8];
2595	pCtx->r9 = pVM->rem.s.Env.regs[9];
2596	pCtx->r10 = pVM->rem.s.Env.regs[10];
2597	pCtx->r11 = pVM->rem.s.Env.regs[11];
2598	pCtx->r12 = pVM->rem.s.Env.regs[12];
2599	pCtx->r13 = pVM->rem.s.Env.regs[13];
2600	pCtx->r14 = pVM->rem.s.Env.regs[14];
2601	pCtx->r15 = pVM->rem.s.Env.regs[15];
2602
2603	pCtx->rsp = pVM->rem.s.Env.regs[R_ESP];
2604
2605	#else
2606	pCtx->edi = pVM->rem.s.Env.regs[R_EDI];
2607	pCtx->esi = pVM->rem.s.Env.regs[R_ESI];
2608	pCtx->ebp = pVM->rem.s.Env.regs[R_EBP];
2609	pCtx->eax = pVM->rem.s.Env.regs[R_EAX];
2610	pCtx->ebx = pVM->rem.s.Env.regs[R_EBX];
2611	pCtx->edx = pVM->rem.s.Env.regs[R_EDX];
2612	pCtx->ecx = pVM->rem.s.Env.regs[R_ECX];
2613
2614	pCtx->esp = pVM->rem.s.Env.regs[R_ESP];
2615	#endif
2616
2617	#define SYNC_BACK_SREG(a_sreg, a_SREG) \
2618	do \
2619	{ \
2620	pCtx->a_sreg.Sel = pVM->rem.s.Env.segs[R_##a_SREG].selector; \
2621	if (!pVM->rem.s.Env.segs[R_SS].newselector) \
2622	{ \
2623	pCtx->a_sreg.ValidSel = pVM->rem.s.Env.segs[R_##a_SREG].selector; \
2624	pCtx->a_sreg.fFlags = CPUMSELREG_FLAGS_VALID; \
2625	pCtx->a_sreg.u64Base = pVM->rem.s.Env.segs[R_##a_SREG].base; \
2626	pCtx->a_sreg.u32Limit = pVM->rem.s.Env.segs[R_##a_SREG].limit; \
2627	/* Note! QEmu saves the 2nd dword of the descriptor; we should store the attribute word only! */ \
2628	pCtx->a_sreg.Attr.u = (pVM->rem.s.Env.segs[R_##a_SREG].flags >> 8) & 0xF0FF; \
2629	} \
2630	else \
2631	{ \
2632	pCtx->a_sreg.fFlags = 0; \
2633	STAM_COUNTER_INC(&gStatSelOutOfSyncStateBack[R_##a_SREG]); \
2634	} \
2635	} while (0)
2636
2637	SYNC_BACK_SREG(es, ES);
2638	SYNC_BACK_SREG(cs, CS);
2639	SYNC_BACK_SREG(ss, SS);
2640	SYNC_BACK_SREG(ds, DS);
2641	SYNC_BACK_SREG(fs, FS);
2642	SYNC_BACK_SREG(gs, GS);
2643
2644	#ifdef TARGET_X86_64
2645	pCtx->rip = pVM->rem.s.Env.eip;
2646	pCtx->rflags.u64 = pVM->rem.s.Env.eflags;
2647	#else
2648	pCtx->eip = pVM->rem.s.Env.eip;
2649	pCtx->eflags.u32 = pVM->rem.s.Env.eflags;
2650	#endif
2651
2652	pCtx->cr0 = pVM->rem.s.Env.cr[0];
2653	pCtx->cr2 = pVM->rem.s.Env.cr[2];
2654	pCtx->cr3 = pVM->rem.s.Env.cr[3];
2655	#ifdef VBOX_WITH_RAW_MODE
2656	if (((pVM->rem.s.Env.cr[4] ^ pCtx->cr4) & X86_CR4_VME) && !HMIsEnabled(pVM))
2657	VMCPU_FF_SET(pVCpu, VMCPU_FF_SELM_SYNC_TSS);
2658	#endif
2659	pCtx->cr4 = pVM->rem.s.Env.cr[4];
2660
2661	for (i = 0; i < 8; i++)
2662	pCtx->dr[i] = pVM->rem.s.Env.dr[i];
2663
2664	pCtx->gdtr.cbGdt = pVM->rem.s.Env.gdt.limit;
2665	if (pCtx->gdtr.pGdt != pVM->rem.s.Env.gdt.base)
2666	{
2667	pCtx->gdtr.pGdt = pVM->rem.s.Env.gdt.base;
2668	STAM_COUNTER_INC(&gStatREMGDTChange);
2669	#ifdef VBOX_WITH_RAW_MODE
2670	if (!HMIsEnabled(pVM))
2671	VMCPU_FF_SET(pVCpu, VMCPU_FF_SELM_SYNC_GDT);
2672	#endif
2673	}
2674
2675	pCtx->idtr.cbIdt = pVM->rem.s.Env.idt.limit;
2676	if (pCtx->idtr.pIdt != pVM->rem.s.Env.idt.base)
2677	{
2678	pCtx->idtr.pIdt = pVM->rem.s.Env.idt.base;
2679	STAM_COUNTER_INC(&gStatREMIDTChange);
2680	#ifdef VBOX_WITH_RAW_MODE
2681	VMCPU_FF_SET(pVCpu, VMCPU_FF_TRPM_SYNC_IDT);
2682	#endif
2683	}
2684
2685	if ( pCtx->ldtr.Sel != pVM->rem.s.Env.ldt.selector
2686	\|\| pCtx->ldtr.ValidSel != pVM->rem.s.Env.ldt.selector
2687	\|\| pCtx->ldtr.u64Base != pVM->rem.s.Env.ldt.base
2688	\|\| pCtx->ldtr.u32Limit != pVM->rem.s.Env.ldt.limit
2689	\|\| pCtx->ldtr.Attr.u != ((pVM->rem.s.Env.ldt.flags >> 8) & 0xF0FF)
2690	\|\| !(pCtx->ldtr.fFlags & CPUMSELREG_FLAGS_VALID)
2691	)
2692	{
2693	pCtx->ldtr.Sel = pVM->rem.s.Env.ldt.selector;
2694	pCtx->ldtr.ValidSel = pVM->rem.s.Env.ldt.selector;
2695	pCtx->ldtr.fFlags = CPUMSELREG_FLAGS_VALID;
2696	pCtx->ldtr.u64Base = pVM->rem.s.Env.ldt.base;
2697	pCtx->ldtr.u32Limit = pVM->rem.s.Env.ldt.limit;
2698	pCtx->ldtr.Attr.u = (pVM->rem.s.Env.ldt.flags >> 8) & 0xF0FF;
2699	STAM_COUNTER_INC(&gStatREMLDTRChange);
2700	#ifdef VBOX_WITH_RAW_MODE
2701	if (!HMIsEnabled(pVM))
2702	VMCPU_FF_SET(pVCpu, VMCPU_FF_SELM_SYNC_LDT);
2703	#endif
2704	}
2705
2706	if ( pCtx->tr.Sel != pVM->rem.s.Env.tr.selector
2707	\|\| pCtx->tr.ValidSel != pVM->rem.s.Env.tr.selector
2708	\|\| pCtx->tr.u64Base != pVM->rem.s.Env.tr.base
2709	\|\| pCtx->tr.u32Limit != pVM->rem.s.Env.tr.limit
2710	/* Qemu and AMD/Intel have different ideas about the busy flag ... */
2711	\|\| pCtx->tr.Attr.u != ( (pVM->rem.s.Env.tr.flags >> 8) & 0xF0FF
2712	? (pVM->rem.s.Env.tr.flags \| DESC_TSS_BUSY_MASK) >> 8
2713	: 0)
2714	\|\| !(pCtx->tr.fFlags & CPUMSELREG_FLAGS_VALID)
2715	)
2716	{
2717	Log(("REM: TR changed! %#x{%#llx,%#x,%#x} -> %#x{%llx,%#x,%#x}\n",
2718	pCtx->tr.Sel, pCtx->tr.u64Base, pCtx->tr.u32Limit, pCtx->tr.Attr.u,
2719	pVM->rem.s.Env.tr.selector, (uint64_t)pVM->rem.s.Env.tr.base, pVM->rem.s.Env.tr.limit,
2720	(pVM->rem.s.Env.tr.flags >> 8) & 0xF0FF ? (pVM->rem.s.Env.tr.flags \| DESC_TSS_BUSY_MASK) >> 8 : 0));
2721	pCtx->tr.Sel = pVM->rem.s.Env.tr.selector;
2722	pCtx->tr.ValidSel = pVM->rem.s.Env.tr.selector;
2723	pCtx->tr.fFlags = CPUMSELREG_FLAGS_VALID;
2724	pCtx->tr.u64Base = pVM->rem.s.Env.tr.base;
2725	pCtx->tr.u32Limit = pVM->rem.s.Env.tr.limit;
2726	pCtx->tr.Attr.u = (pVM->rem.s.Env.tr.flags >> 8) & 0xF0FF;
2727	if (pCtx->tr.Attr.u)
2728	pCtx->tr.Attr.u \|= DESC_TSS_BUSY_MASK >> 8;
2729	STAM_COUNTER_INC(&gStatREMTRChange);
2730	#ifdef VBOX_WITH_RAW_MODE
2731	if (!HMIsEnabled(pVM))
2732	VMCPU_FF_SET(pVCpu, VMCPU_FF_SELM_SYNC_TSS);
2733	#endif
2734	}
2735
2736	/* Sysenter MSR */
2737	pCtx->SysEnter.cs = pVM->rem.s.Env.sysenter_cs;
2738	pCtx->SysEnter.eip = pVM->rem.s.Env.sysenter_eip;
2739	pCtx->SysEnter.esp = pVM->rem.s.Env.sysenter_esp;
2740
2741	/* System MSRs. */
2742	pCtx->msrEFER = pVM->rem.s.Env.efer;
2743	pCtx->msrSTAR = pVM->rem.s.Env.star;
2744	pCtx->msrPAT = pVM->rem.s.Env.pat;
2745	#ifdef TARGET_X86_64
2746	pCtx->msrLSTAR = pVM->rem.s.Env.lstar;
2747	pCtx->msrCSTAR = pVM->rem.s.Env.cstar;
2748	pCtx->msrSFMASK = pVM->rem.s.Env.fmask;
2749	pCtx->msrKERNELGSBASE = pVM->rem.s.Env.kernelgsbase;
2750	#endif
2751
2752	/* Inhibit interrupt flag. */
2753	if (pVM->rem.s.Env.hflags & HF_INHIBIT_IRQ_MASK)
2754	{
2755	Log(("Settings VMCPU_FF_INHIBIT_INTERRUPTS at %RGv (REM)\n", (RTGCPTR)pCtx->rip));
2756	EMSetInhibitInterruptsPC(pVCpu, pCtx->rip);
2757	VMCPU_FF_SET(pVCpu, VMCPU_FF_INHIBIT_INTERRUPTS);
2758	}
2759	else if (VMCPU_FF_ISSET(pVCpu, VMCPU_FF_INHIBIT_INTERRUPTS))
2760	{
2761	Log(("Clearing VMCPU_FF_INHIBIT_INTERRUPTS at %RGv - successor %RGv (REM#2)\n", (RTGCPTR)pCtx->rip, EMGetInhibitInterruptsPC(pVCpu)));
2762	VMCPU_FF_CLEAR(pVCpu, VMCPU_FF_INHIBIT_INTERRUPTS);
2763	}
2764
2765	remR3TrapClear(pVM);
2766
2767	/*
2768	* Check for traps.
2769	*/
2770	if ( pVM->rem.s.Env.exception_index >= 0
2771	&& pVM->rem.s.Env.exception_index < 256)
2772	{
2773	/* This cannot be a hardware-interrupt because exception_index < EXCP_INTERRUPT. */
2774	int rc;
2775
2776	Log(("REMR3StateBack: Pending trap %x %d\n", pVM->rem.s.Env.exception_index, pVM->rem.s.Env.exception_is_int));
2777	TRPMEVENT enmType = pVM->rem.s.Env.exception_is_int ? TRPM_SOFTWARE_INT : TRPM_TRAP;
2778	rc = TRPMAssertTrap(pVCpu, pVM->rem.s.Env.exception_index, enmType);
2779	AssertRC(rc);
2780	if (enmType == TRPM_TRAP)
2781	{
2782	switch (pVM->rem.s.Env.exception_index)
2783	{
2784	case X86_XCPT_PF:
2785	TRPMSetFaultAddress(pVCpu, pCtx->cr2);
2786	/* fallthru */
2787	case X86_XCPT_TS: case X86_XCPT_NP: case X86_XCPT_SS: case X86_XCPT_GP:
2788	case X86_XCPT_AC: case X86_XCPT_DF: /* 0 */
2789	TRPMSetErrorCode(pVCpu, pVM->rem.s.Env.error_code);
2790	break;
2791	}
2792	}
2793	}
2794
2795	/*
2796	* We're not longer in REM mode.
2797	*/
2798	CPUMR3RemLeave(pVCpu,
2799	HMIsEnabled(pVM)
2800	\|\| ( pVM->rem.s.Env.segs[R_SS].newselector
2801	\| pVM->rem.s.Env.segs[R_GS].newselector
2802	\| pVM->rem.s.Env.segs[R_FS].newselector
2803	\| pVM->rem.s.Env.segs[R_ES].newselector
2804	\| pVM->rem.s.Env.segs[R_DS].newselector
2805	\| pVM->rem.s.Env.segs[R_CS].newselector) == 0
2806	);
2807	VMCPU_CMPXCHG_STATE(pVCpu, VMCPUSTATE_STARTED, VMCPUSTATE_STARTED_EXEC_REM);
2808	pVM->rem.s.fInREM = false;
2809	pVM->rem.s.pCtx = NULL;
2810	pVM->rem.s.Env.pVCpu = NULL;
2811	STAM_PROFILE_STOP(&pVM->rem.s.StatsStateBack, a);
2812	Log2(("REMR3StateBack: returns VINF_SUCCESS\n"));
2813	return VINF_SUCCESS;
2814	}
2815
2816
2817	/**
2818	* This is called by the disassembler when it wants to update the cpu state
2819	* before for instance doing a register dump.
2820	*/
2821	static void remR3StateUpdate(PVM pVM, PVMCPU pVCpu)
2822	{
2823	register PCPUMCTX pCtx = pVM->rem.s.pCtx;
2824	unsigned i;
2825
2826	Assert(pVM->rem.s.fInREM);
2827
2828	/*
2829	* Copy back the registers.
2830	* This is done in the order they are declared in the CPUMCTX structure.
2831	*/
2832
2833	/** @todo FOP */
2834	/** @todo FPUIP */
2835	/** @todo CS */
2836	/** @todo FPUDP */
2837	/** @todo DS */
2838	/** @todo Fix MXCSR support in QEMU so we don't overwrite MXCSR with 0 when we shouldn't! */
2839	pCtx->fpu.MXCSR = 0;
2840	pCtx->fpu.MXCSR_MASK = 0;
2841
2842	/** @todo check if FPU/XMM was actually used in the recompiler */
2843	restore_raw_fp_state(&pVM->rem.s.Env, (uint8_t *)&pCtx->fpu);
2844	//// dprintf2(("FPU state CW=%04X TT=%04X SW=%04X (%04X)\n", env->fpuc, env->fpstt, env->fpus, pVMCtx->fpu.FSW));
2845
2846	#ifdef TARGET_X86_64
2847	pCtx->rdi = pVM->rem.s.Env.regs[R_EDI];
2848	pCtx->rsi = pVM->rem.s.Env.regs[R_ESI];
2849	pCtx->rbp = pVM->rem.s.Env.regs[R_EBP];
2850	pCtx->rax = pVM->rem.s.Env.regs[R_EAX];
2851	pCtx->rbx = pVM->rem.s.Env.regs[R_EBX];
2852	pCtx->rdx = pVM->rem.s.Env.regs[R_EDX];
2853	pCtx->rcx = pVM->rem.s.Env.regs[R_ECX];
2854	pCtx->r8 = pVM->rem.s.Env.regs[8];
2855	pCtx->r9 = pVM->rem.s.Env.regs[9];
2856	pCtx->r10 = pVM->rem.s.Env.regs[10];
2857	pCtx->r11 = pVM->rem.s.Env.regs[11];
2858	pCtx->r12 = pVM->rem.s.Env.regs[12];
2859	pCtx->r13 = pVM->rem.s.Env.regs[13];
2860	pCtx->r14 = pVM->rem.s.Env.regs[14];
2861	pCtx->r15 = pVM->rem.s.Env.regs[15];
2862
2863	pCtx->rsp = pVM->rem.s.Env.regs[R_ESP];
2864	#else
2865	pCtx->edi = pVM->rem.s.Env.regs[R_EDI];
2866	pCtx->esi = pVM->rem.s.Env.regs[R_ESI];
2867	pCtx->ebp = pVM->rem.s.Env.regs[R_EBP];
2868	pCtx->eax = pVM->rem.s.Env.regs[R_EAX];
2869	pCtx->ebx = pVM->rem.s.Env.regs[R_EBX];
2870	pCtx->edx = pVM->rem.s.Env.regs[R_EDX];
2871	pCtx->ecx = pVM->rem.s.Env.regs[R_ECX];
2872
2873	pCtx->esp = pVM->rem.s.Env.regs[R_ESP];
2874	#endif
2875
2876	SYNC_BACK_SREG(es, ES);
2877	SYNC_BACK_SREG(cs, CS);
2878	SYNC_BACK_SREG(ss, SS);
2879	SYNC_BACK_SREG(ds, DS);
2880	SYNC_BACK_SREG(fs, FS);
2881	SYNC_BACK_SREG(gs, GS);
2882
2883	#ifdef TARGET_X86_64
2884	pCtx->rip = pVM->rem.s.Env.eip;
2885	pCtx->rflags.u64 = pVM->rem.s.Env.eflags;
2886	#else
2887	pCtx->eip = pVM->rem.s.Env.eip;
2888	pCtx->eflags.u32 = pVM->rem.s.Env.eflags;
2889	#endif
2890
2891	pCtx->cr0 = pVM->rem.s.Env.cr[0];
2892	pCtx->cr2 = pVM->rem.s.Env.cr[2];
2893	pCtx->cr3 = pVM->rem.s.Env.cr[3];
2894	#ifdef VBOX_WITH_RAW_MODE
2895	if (((pVM->rem.s.Env.cr[4] ^ pCtx->cr4) & X86_CR4_VME) && !HMIsEnabled(pVM))
2896	VMCPU_FF_SET(pVCpu, VMCPU_FF_SELM_SYNC_TSS);
2897	#endif
2898	pCtx->cr4 = pVM->rem.s.Env.cr[4];
2899
2900	for (i = 0; i < 8; i++)
2901	pCtx->dr[i] = pVM->rem.s.Env.dr[i];
2902
2903	pCtx->gdtr.cbGdt = pVM->rem.s.Env.gdt.limit;
2904	if (pCtx->gdtr.pGdt != (RTGCPTR)pVM->rem.s.Env.gdt.base)
2905	{
2906	pCtx->gdtr.pGdt = (RTGCPTR)pVM->rem.s.Env.gdt.base;
2907	STAM_COUNTER_INC(&gStatREMGDTChange);
2908	#ifdef VBOX_WITH_RAW_MODE
2909	if (!HMIsEnabled(pVM))
2910	VMCPU_FF_SET(pVCpu, VMCPU_FF_SELM_SYNC_GDT);
2911	#endif
2912	}
2913
2914	pCtx->idtr.cbIdt = pVM->rem.s.Env.idt.limit;
2915	if (pCtx->idtr.pIdt != (RTGCPTR)pVM->rem.s.Env.idt.base)
2916	{
2917	pCtx->idtr.pIdt = (RTGCPTR)pVM->rem.s.Env.idt.base;
2918	STAM_COUNTER_INC(&gStatREMIDTChange);
2919	#ifdef VBOX_WITH_RAW_MODE
2920	VMCPU_FF_SET(pVCpu, VMCPU_FF_TRPM_SYNC_IDT);
2921	#endif
2922	}
2923
2924	if ( pCtx->ldtr.Sel != pVM->rem.s.Env.ldt.selector
2925	\|\| pCtx->ldtr.ValidSel != pVM->rem.s.Env.ldt.selector
2926	\|\| pCtx->ldtr.u64Base != pVM->rem.s.Env.ldt.base
2927	\|\| pCtx->ldtr.u32Limit != pVM->rem.s.Env.ldt.limit
2928	\|\| pCtx->ldtr.Attr.u != ((pVM->rem.s.Env.ldt.flags >> 8) & 0xF0FF)
2929	\|\| !(pCtx->ldtr.fFlags & CPUMSELREG_FLAGS_VALID)
2930	)
2931	{
2932	pCtx->ldtr.Sel = pVM->rem.s.Env.ldt.selector;
2933	pCtx->ldtr.ValidSel = pVM->rem.s.Env.ldt.selector;
2934	pCtx->ldtr.fFlags = CPUMSELREG_FLAGS_VALID;
2935	pCtx->ldtr.u64Base = pVM->rem.s.Env.ldt.base;
2936	pCtx->ldtr.u32Limit = pVM->rem.s.Env.ldt.limit;
2937	pCtx->ldtr.Attr.u = (pVM->rem.s.Env.ldt.flags >> 8) & 0xF0FF;
2938	STAM_COUNTER_INC(&gStatREMLDTRChange);
2939	#ifdef VBOX_WITH_RAW_MODE
2940	if (!HMIsEnabled(pVM))
2941	VMCPU_FF_SET(pVCpu, VMCPU_FF_SELM_SYNC_LDT);
2942	#endif
2943	}
2944
2945	if ( pCtx->tr.Sel != pVM->rem.s.Env.tr.selector
2946	\|\| pCtx->tr.ValidSel != pVM->rem.s.Env.tr.selector
2947	\|\| pCtx->tr.u64Base != pVM->rem.s.Env.tr.base
2948	\|\| pCtx->tr.u32Limit != pVM->rem.s.Env.tr.limit
2949	/* Qemu and AMD/Intel have different ideas about the busy flag ... */
2950	\|\| pCtx->tr.Attr.u != ( (pVM->rem.s.Env.tr.flags >> 8) & 0xF0FF
2951	? (pVM->rem.s.Env.tr.flags \| DESC_TSS_BUSY_MASK) >> 8
2952	: 0)
2953	\|\| !(pCtx->tr.fFlags & CPUMSELREG_FLAGS_VALID)
2954	)
2955	{
2956	Log(("REM: TR changed! %#x{%#llx,%#x,%#x} -> %#x{%llx,%#x,%#x}\n",
2957	pCtx->tr.Sel, pCtx->tr.u64Base, pCtx->tr.u32Limit, pCtx->tr.Attr.u,
2958	pVM->rem.s.Env.tr.selector, (uint64_t)pVM->rem.s.Env.tr.base, pVM->rem.s.Env.tr.limit,
2959	(pVM->rem.s.Env.tr.flags >> 8) & 0xF0FF ? (pVM->rem.s.Env.tr.flags \| DESC_TSS_BUSY_MASK) >> 8 : 0));
2960	pCtx->tr.Sel = pVM->rem.s.Env.tr.selector;
2961	pCtx->tr.ValidSel = pVM->rem.s.Env.tr.selector;
2962	pCtx->tr.fFlags = CPUMSELREG_FLAGS_VALID;
2963	pCtx->tr.u64Base = pVM->rem.s.Env.tr.base;
2964	pCtx->tr.u32Limit = pVM->rem.s.Env.tr.limit;
2965	pCtx->tr.Attr.u = (pVM->rem.s.Env.tr.flags >> 8) & 0xF0FF;
2966	if (pCtx->tr.Attr.u)
2967	pCtx->tr.Attr.u \|= DESC_TSS_BUSY_MASK >> 8;
2968	STAM_COUNTER_INC(&gStatREMTRChange);
2969	#ifdef VBOX_WITH_RAW_MODE
2970	if (!HMIsEnabled(pVM))
2971	VMCPU_FF_SET(pVCpu, VMCPU_FF_SELM_SYNC_TSS);
2972	#endif
2973	}
2974
2975	/* Sysenter MSR */
2976	pCtx->SysEnter.cs = pVM->rem.s.Env.sysenter_cs;
2977	pCtx->SysEnter.eip = pVM->rem.s.Env.sysenter_eip;
2978	pCtx->SysEnter.esp = pVM->rem.s.Env.sysenter_esp;
2979
2980	/* System MSRs. */
2981	pCtx->msrEFER = pVM->rem.s.Env.efer;
2982	pCtx->msrSTAR = pVM->rem.s.Env.star;
2983	pCtx->msrPAT = pVM->rem.s.Env.pat;
2984	#ifdef TARGET_X86_64
2985	pCtx->msrLSTAR = pVM->rem.s.Env.lstar;
2986	pCtx->msrCSTAR = pVM->rem.s.Env.cstar;
2987	pCtx->msrSFMASK = pVM->rem.s.Env.fmask;
2988	pCtx->msrKERNELGSBASE = pVM->rem.s.Env.kernelgsbase;
2989	#endif
2990
2991	}
2992
2993
2994	/**
2995	* Update the VMM state information if we're currently in REM.
2996	*
2997	* This method is used by the DBGF and PDMDevice when there is any uncertainty of whether
2998	* we're currently executing in REM and the VMM state is invalid. This method will of
2999	* course check that we're executing in REM before syncing any data over to the VMM.
3000	*
3001	* @param pVM The VM handle.
3002	* @param pVCpu The VMCPU handle.
3003	*/
3004	REMR3DECL(void) REMR3StateUpdate(PVM pVM, PVMCPU pVCpu)
3005	{
3006	if (pVM->rem.s.fInREM)
3007	remR3StateUpdate(pVM, pVCpu);
3008	}
3009
3010
3011	#undef LOG_GROUP
3012	#define LOG_GROUP LOG_GROUP_REM
3013
3014
3015	/**
3016	* Notify the recompiler about Address Gate 20 state change.
3017	*
3018	* This notification is required since A20 gate changes are
3019	* initialized from a device driver and the VM might just as
3020	* well be in REM mode as in RAW mode.
3021	*
3022	* @param pVM VM handle.
3023	* @param pVCpu VMCPU handle.
3024	* @param fEnable True if the gate should be enabled.
3025	* False if the gate should be disabled.
3026	*/
3027	REMR3DECL(void) REMR3A20Set(PVM pVM, PVMCPU pVCpu, bool fEnable)
3028	{
3029	LogFlow(("REMR3A20Set: fEnable=%d\n", fEnable));
3030	VM_ASSERT_EMT(pVM);
3031
3032	/** @todo SMP and the A20 gate... */
3033	if (pVM->rem.s.Env.pVCpu == pVCpu)
3034	{
3035	ASMAtomicIncU32(&pVM->rem.s.cIgnoreAll);
3036	cpu_x86_set_a20(&pVM->rem.s.Env, fEnable);
3037	ASMAtomicDecU32(&pVM->rem.s.cIgnoreAll);
3038	}
3039	}
3040
3041
3042	/**
3043	* Replays the handler notification changes
3044	* Called in response to VM_FF_REM_HANDLER_NOTIFY from the RAW execution loop.
3045	*
3046	* @param pVM VM handle.
3047	*/
3048	REMR3DECL(void) REMR3ReplayHandlerNotifications(PVM pVM)
3049	{
3050	/*
3051	* Replay the flushes.
3052	*/
3053	LogFlow(("REMR3ReplayHandlerNotifications:\n"));
3054	VM_ASSERT_EMT(pVM);
3055
3056	/** @todo this isn't ensuring correct replay order. */
3057	if (VM_FF_TESTANDCLEAR(pVM, VM_FF_REM_HANDLER_NOTIFY))
3058	{
3059	uint32_t idxNext;
3060	uint32_t idxRevHead;
3061	uint32_t idxHead;
3062	#ifdef VBOX_STRICT
3063	int32_t c = 0;
3064	#endif
3065
3066	/* Lockless purging of pending notifications. */
3067	idxHead = ASMAtomicXchgU32(&pVM->rem.s.idxPendingList, UINT32_MAX);
3068	if (idxHead == UINT32_MAX)
3069	return;
3070	Assert(idxHead < RT_ELEMENTS(pVM->rem.s.aHandlerNotifications));
3071
3072	/*
3073	* Reverse the list to process it in FIFO order.
3074	*/
3075	idxRevHead = UINT32_MAX;
3076	do
3077	{
3078	/* Save the index of the next rec. */
3079	idxNext = pVM->rem.s.aHandlerNotifications[idxHead].idxNext;
3080	Assert(idxNext < RT_ELEMENTS(pVM->rem.s.aHandlerNotifications) \|\| idxNext == UINT32_MAX);
3081	/* Push the record onto the reversed list. */
3082	pVM->rem.s.aHandlerNotifications[idxHead].idxNext = idxRevHead;
3083	idxRevHead = idxHead;
3084	Assert(++c <= RT_ELEMENTS(pVM->rem.s.aHandlerNotifications));
3085	/* Advance. */
3086	idxHead = idxNext;
3087	} while (idxHead != UINT32_MAX);
3088
3089	/*
3090	* Loop thru the list, reinserting the record into the free list as they are
3091	* processed to avoid having other EMTs running out of entries while we're flushing.
3092	*/
3093	idxHead = idxRevHead;
3094	do
3095	{
3096	PREMHANDLERNOTIFICATION pCur = &pVM->rem.s.aHandlerNotifications[idxHead];
3097	uint32_t idxCur;
3098	Assert(--c >= 0);
3099
3100	switch (pCur->enmKind)
3101	{
3102	case REMHANDLERNOTIFICATIONKIND_PHYSICAL_REGISTER:
3103	remR3NotifyHandlerPhysicalRegister(pVM,
3104	pCur->u.PhysicalRegister.enmType,
3105	pCur->u.PhysicalRegister.GCPhys,
3106	pCur->u.PhysicalRegister.cb,
3107	pCur->u.PhysicalRegister.fHasHCHandler);
3108	break;
3109
3110	case REMHANDLERNOTIFICATIONKIND_PHYSICAL_DEREGISTER:
3111	remR3NotifyHandlerPhysicalDeregister(pVM,
3112	pCur->u.PhysicalDeregister.enmType,
3113	pCur->u.PhysicalDeregister.GCPhys,
3114	pCur->u.PhysicalDeregister.cb,
3115	pCur->u.PhysicalDeregister.fHasHCHandler,
3116	pCur->u.PhysicalDeregister.fRestoreAsRAM);
3117	break;
3118
3119	case REMHANDLERNOTIFICATIONKIND_PHYSICAL_MODIFY:
3120	remR3NotifyHandlerPhysicalModify(pVM,
3121	pCur->u.PhysicalModify.enmType,
3122	pCur->u.PhysicalModify.GCPhysOld,
3123	pCur->u.PhysicalModify.GCPhysNew,
3124	pCur->u.PhysicalModify.cb,
3125	pCur->u.PhysicalModify.fHasHCHandler,
3126	pCur->u.PhysicalModify.fRestoreAsRAM);
3127	break;
3128
3129	default:
3130	AssertReleaseMsgFailed(("enmKind=%d\n", pCur->enmKind));
3131	break;
3132	}
3133
3134	/*
3135	* Advance idxHead.
3136	*/
3137	idxCur = idxHead;
3138	idxHead = pCur->idxNext;
3139	Assert(idxHead < RT_ELEMENTS(pVM->rem.s.aHandlerNotifications) \|\| (idxHead == UINT32_MAX && c == 0));
3140
3141	/*
3142	* Put the record back into the free list.
3143	*/
3144	do
3145	{
3146	idxNext = ASMAtomicUoReadU32(&pVM->rem.s.idxFreeList);
3147	ASMAtomicWriteU32(&pCur->idxNext, idxNext);
3148	ASMCompilerBarrier();
3149	} while (!ASMAtomicCmpXchgU32(&pVM->rem.s.idxFreeList, idxCur, idxNext));
3150	} while (idxHead != UINT32_MAX);
3151
3152	#ifdef VBOX_STRICT
3153	if (pVM->cCpus == 1)
3154	{
3155	unsigned c;
3156	/* Check that all records are now on the free list. */
3157	for (c = 0, idxNext = pVM->rem.s.idxFreeList; idxNext != UINT32_MAX;
3158	idxNext = pVM->rem.s.aHandlerNotifications[idxNext].idxNext)
3159	c++;
3160	AssertReleaseMsg(c == RT_ELEMENTS(pVM->rem.s.aHandlerNotifications), ("%#x != %#x, idxFreeList=%#x\n", c, RT_ELEMENTS(pVM->rem.s.aHandlerNotifications), pVM->rem.s.idxFreeList));
3161	}
3162	#endif
3163	}
3164	}
3165
3166
3167	/**
3168	* Notify REM about changed code page.
3169	*
3170	* @returns VBox status code.
3171	* @param pVM VM handle.
3172	* @param pVCpu VMCPU handle.
3173	* @param pvCodePage Code page address
3174	*/
3175	REMR3DECL(int) REMR3NotifyCodePageChanged(PVM pVM, PVMCPU pVCpu, RTGCPTR pvCodePage)
3176	{
3177	#ifdef VBOX_REM_PROTECT_PAGES_FROM_SMC
3178	int rc;
3179	RTGCPHYS PhysGC;
3180	uint64_t flags;
3181
3182	VM_ASSERT_EMT(pVM);
3183
3184	/*
3185	* Get the physical page address.
3186	*/
3187	rc = PGMGstGetPage(pVM, pvCodePage, &flags, &PhysGC);
3188	if (rc == VINF_SUCCESS)
3189	{
3190	/*
3191	* Sync the required registers and flush the whole page.
3192	* (Easier to do the whole page than notifying it about each physical
3193	* byte that was changed.
3194	*/
3195	pVM->rem.s.Env.cr[0] = pVM->rem.s.pCtx->cr0;
3196	pVM->rem.s.Env.cr[2] = pVM->rem.s.pCtx->cr2;
3197	pVM->rem.s.Env.cr[3] = pVM->rem.s.pCtx->cr3;
3198	pVM->rem.s.Env.cr[4] = pVM->rem.s.pCtx->cr4;
3199
3200	tb_invalidate_phys_page_range(PhysGC, PhysGC + PAGE_SIZE - 1, 0);
3201	}
3202	#endif
3203	return VINF_SUCCESS;
3204	}
3205
3206
3207	/**
3208	* Notification about a successful MMR3PhysRegister() call.
3209	*
3210	* @param pVM VM handle.
3211	* @param GCPhys The physical address the RAM.
3212	* @param cb Size of the memory.
3213	* @param fFlags Flags of the REM_NOTIFY_PHYS_RAM_FLAGS_* defines.
3214	*/
3215	REMR3DECL(void) REMR3NotifyPhysRamRegister(PVM pVM, RTGCPHYS GCPhys, RTGCPHYS cb, unsigned fFlags)
3216	{
3217	Log(("REMR3NotifyPhysRamRegister: GCPhys=%RGp cb=%RGp fFlags=%#x\n", GCPhys, cb, fFlags));
3218	VM_ASSERT_EMT(pVM);
3219
3220	/*
3221	* Validate input - we trust the caller.
3222	*/
3223	Assert(RT_ALIGN_T(GCPhys, PAGE_SIZE, RTGCPHYS) == GCPhys);
3224	Assert(cb);
3225	Assert(RT_ALIGN_Z(cb, PAGE_SIZE) == cb);
3226	AssertMsg(fFlags == REM_NOTIFY_PHYS_RAM_FLAGS_RAM \|\| fFlags == REM_NOTIFY_PHYS_RAM_FLAGS_MMIO2, ("#x\n", fFlags));
3227
3228	/*
3229	* Base ram? Update GCPhysLastRam.
3230	*/
3231	if (fFlags & REM_NOTIFY_PHYS_RAM_FLAGS_RAM)
3232	{
3233	if (GCPhys + (cb - 1) > pVM->rem.s.GCPhysLastRam)
3234	{
3235	AssertReleaseMsg(!pVM->rem.s.fGCPhysLastRamFixed, ("GCPhys=%RGp cb=%RGp\n", GCPhys, cb));
3236	pVM->rem.s.GCPhysLastRam = GCPhys + (cb - 1);
3237	}
3238	}
3239
3240	/*
3241	* Register the ram.
3242	*/
3243	ASMAtomicIncU32(&pVM->rem.s.cIgnoreAll);
3244
3245	PDMCritSectEnter(&pVM->rem.s.CritSectRegister, VERR_SEM_BUSY);
3246	cpu_register_physical_memory_offset(GCPhys, cb, GCPhys, GCPhys);
3247	PDMCritSectLeave(&pVM->rem.s.CritSectRegister);
3248
3249	ASMAtomicDecU32(&pVM->rem.s.cIgnoreAll);
3250	}
3251
3252
3253	/**
3254	* Notification about a successful MMR3PhysRomRegister() call.
3255	*
3256	* @param pVM VM handle.
3257	* @param GCPhys The physical address of the ROM.
3258	* @param cb The size of the ROM.
3259	* @param pvCopy Pointer to the ROM copy.
3260	* @param fShadow Whether it's currently writable shadow ROM or normal readonly ROM.
3261	* This function will be called when ever the protection of the
3262	* shadow ROM changes (at reset and end of POST).
3263	*/
3264	REMR3DECL(void) REMR3NotifyPhysRomRegister(PVM pVM, RTGCPHYS GCPhys, RTUINT cb, void *pvCopy, bool fShadow)
3265	{
3266	Log(("REMR3NotifyPhysRomRegister: GCPhys=%RGp cb=%d fShadow=%RTbool\n", GCPhys, cb, fShadow));
3267	VM_ASSERT_EMT(pVM);
3268
3269	/*
3270	* Validate input - we trust the caller.
3271	*/
3272	Assert(RT_ALIGN_T(GCPhys, PAGE_SIZE, RTGCPHYS) == GCPhys);
3273	Assert(cb);
3274	Assert(RT_ALIGN_Z(cb, PAGE_SIZE) == cb);
3275
3276	/*
3277	* Register the rom.
3278	*/
3279	ASMAtomicIncU32(&pVM->rem.s.cIgnoreAll);
3280
3281	PDMCritSectEnter(&pVM->rem.s.CritSectRegister, VERR_SEM_BUSY);
3282	cpu_register_physical_memory_offset(GCPhys, cb, GCPhys \| (fShadow ? 0 : IO_MEM_ROM), GCPhys);
3283	PDMCritSectLeave(&pVM->rem.s.CritSectRegister);
3284
3285	ASMAtomicDecU32(&pVM->rem.s.cIgnoreAll);
3286	}
3287
3288
3289	/**
3290	* Notification about a successful memory deregistration or reservation.
3291	*
3292	* @param pVM VM Handle.
3293	* @param GCPhys Start physical address.
3294	* @param cb The size of the range.
3295	*/
3296	REMR3DECL(void) REMR3NotifyPhysRamDeregister(PVM pVM, RTGCPHYS GCPhys, RTUINT cb)
3297	{
3298	Log(("REMR3NotifyPhysRamDeregister: GCPhys=%RGp cb=%d\n", GCPhys, cb));
3299	VM_ASSERT_EMT(pVM);
3300
3301	/*
3302	* Validate input - we trust the caller.
3303	*/
3304	Assert(RT_ALIGN_T(GCPhys, PAGE_SIZE, RTGCPHYS) == GCPhys);
3305	Assert(cb);
3306	Assert(RT_ALIGN_Z(cb, PAGE_SIZE) == cb);
3307
3308	/*
3309	* Unassigning the memory.
3310	*/
3311	ASMAtomicIncU32(&pVM->rem.s.cIgnoreAll);
3312
3313	PDMCritSectEnter(&pVM->rem.s.CritSectRegister, VERR_SEM_BUSY);
3314	cpu_register_physical_memory_offset(GCPhys, cb, IO_MEM_UNASSIGNED, GCPhys);
3315	PDMCritSectLeave(&pVM->rem.s.CritSectRegister);
3316
3317	ASMAtomicDecU32(&pVM->rem.s.cIgnoreAll);
3318	}
3319
3320
3321	/**
3322	* Notification about a successful PGMR3HandlerPhysicalRegister() call.
3323	*
3324	* @param pVM VM Handle.
3325	* @param enmType Handler type.
3326	* @param GCPhys Handler range address.
3327	* @param cb Size of the handler range.
3328	* @param fHasHCHandler Set if the handler has a HC callback function.
3329	*
3330	* @remark MMR3PhysRomRegister assumes that this function will not apply the
3331	* Handler memory type to memory which has no HC handler.
3332	*/
3333	static void remR3NotifyHandlerPhysicalRegister(PVM pVM, PGMPHYSHANDLERTYPE enmType, RTGCPHYS GCPhys, RTGCPHYS cb, bool fHasHCHandler)
3334	{
3335	Log(("REMR3NotifyHandlerPhysicalRegister: enmType=%d GCPhys=%RGp cb=%RGp fHasHCHandler=%d\n",
3336	enmType, GCPhys, cb, fHasHCHandler));
3337
3338	VM_ASSERT_EMT(pVM);
3339	Assert(RT_ALIGN_T(GCPhys, PAGE_SIZE, RTGCPHYS) == GCPhys);
3340	Assert(RT_ALIGN_T(cb, PAGE_SIZE, RTGCPHYS) == cb);
3341
3342
3343	ASMAtomicIncU32(&pVM->rem.s.cIgnoreAll);
3344
3345	PDMCritSectEnter(&pVM->rem.s.CritSectRegister, VERR_SEM_BUSY);
3346	if (enmType == PGMPHYSHANDLERTYPE_MMIO)
3347	cpu_register_physical_memory_offset(GCPhys, cb, pVM->rem.s.iMMIOMemType, GCPhys);
3348	else if (fHasHCHandler)
3349	cpu_register_physical_memory_offset(GCPhys, cb, pVM->rem.s.iHandlerMemType, GCPhys);
3350	PDMCritSectLeave(&pVM->rem.s.CritSectRegister);
3351
3352	ASMAtomicDecU32(&pVM->rem.s.cIgnoreAll);
3353	}
3354
3355	/**
3356	* Notification about a successful PGMR3HandlerPhysicalRegister() call.
3357	*
3358	* @param pVM VM Handle.
3359	* @param enmType Handler type.
3360	* @param GCPhys Handler range address.
3361	* @param cb Size of the handler range.
3362	* @param fHasHCHandler Set if the handler has a HC callback function.
3363	*
3364	* @remark MMR3PhysRomRegister assumes that this function will not apply the
3365	* Handler memory type to memory which has no HC handler.
3366	*/
3367	REMR3DECL(void) REMR3NotifyHandlerPhysicalRegister(PVM pVM, PGMPHYSHANDLERTYPE enmType, RTGCPHYS GCPhys, RTGCPHYS cb, bool fHasHCHandler)
3368	{
3369	REMR3ReplayHandlerNotifications(pVM);
3370
3371	remR3NotifyHandlerPhysicalRegister(pVM, enmType, GCPhys, cb, fHasHCHandler);
3372	}
3373
3374	/**
3375	* Notification about a successful PGMR3HandlerPhysicalDeregister() operation.
3376	*
3377	* @param pVM VM Handle.
3378	* @param enmType Handler type.
3379	* @param GCPhys Handler range address.
3380	* @param cb Size of the handler range.
3381	* @param fHasHCHandler Set if the handler has a HC callback function.
3382	* @param fRestoreAsRAM Whether the to restore it as normal RAM or as unassigned memory.
3383	*/
3384	static void remR3NotifyHandlerPhysicalDeregister(PVM pVM, PGMPHYSHANDLERTYPE enmType, RTGCPHYS GCPhys, RTGCPHYS cb, bool fHasHCHandler, bool fRestoreAsRAM)
3385	{
3386	Log(("REMR3NotifyHandlerPhysicalDeregister: enmType=%d GCPhys=%RGp cb=%RGp fHasHCHandler=%RTbool fRestoreAsRAM=%RTbool RAM=%08x\n",
3387	enmType, GCPhys, cb, fHasHCHandler, fRestoreAsRAM, MMR3PhysGetRamSize(pVM)));
3388	VM_ASSERT_EMT(pVM);
3389
3390
3391	ASMAtomicIncU32(&pVM->rem.s.cIgnoreAll);
3392
3393	PDMCritSectEnter(&pVM->rem.s.CritSectRegister, VERR_SEM_BUSY);
3394	/** @todo this isn't right, MMIO can (in theory) be restored as RAM. */
3395	if (enmType == PGMPHYSHANDLERTYPE_MMIO)
3396	cpu_register_physical_memory_offset(GCPhys, cb, IO_MEM_UNASSIGNED, GCPhys);
3397	else if (fHasHCHandler)
3398	{
3399	if (!fRestoreAsRAM)
3400	{
3401	Assert(GCPhys > MMR3PhysGetRamSize(pVM));
3402	cpu_register_physical_memory_offset(GCPhys, cb, IO_MEM_UNASSIGNED, GCPhys);
3403	}
3404	else
3405	{
3406	Assert(RT_ALIGN_T(GCPhys, PAGE_SIZE, RTGCPHYS) == GCPhys);
3407	Assert(RT_ALIGN_T(cb, PAGE_SIZE, RTGCPHYS) == cb);
3408	cpu_register_physical_memory_offset(GCPhys, cb, GCPhys, GCPhys);
3409	}
3410	}
3411	PDMCritSectLeave(&pVM->rem.s.CritSectRegister);
3412
3413	ASMAtomicDecU32(&pVM->rem.s.cIgnoreAll);
3414	}
3415
3416	/**
3417	* Notification about a successful PGMR3HandlerPhysicalDeregister() operation.
3418	*
3419	* @param pVM VM Handle.
3420	* @param enmType Handler type.
3421	* @param GCPhys Handler range address.
3422	* @param cb Size of the handler range.
3423	* @param fHasHCHandler Set if the handler has a HC callback function.
3424	* @param fRestoreAsRAM Whether the to restore it as normal RAM or as unassigned memory.
3425	*/
3426	REMR3DECL(void) REMR3NotifyHandlerPhysicalDeregister(PVM pVM, PGMPHYSHANDLERTYPE enmType, RTGCPHYS GCPhys, RTGCPHYS cb, bool fHasHCHandler, bool fRestoreAsRAM)
3427	{
3428	REMR3ReplayHandlerNotifications(pVM);
3429	remR3NotifyHandlerPhysicalDeregister(pVM, enmType, GCPhys, cb, fHasHCHandler, fRestoreAsRAM);
3430	}
3431
3432
3433	/**
3434	* Notification about a successful PGMR3HandlerPhysicalModify() call.
3435	*
3436	* @param pVM VM Handle.
3437	* @param enmType Handler type.
3438	* @param GCPhysOld Old handler range address.
3439	* @param GCPhysNew New handler range address.
3440	* @param cb Size of the handler range.
3441	* @param fHasHCHandler Set if the handler has a HC callback function.
3442	* @param fRestoreAsRAM Whether the to restore it as normal RAM or as unassigned memory.
3443	*/
3444	static void remR3NotifyHandlerPhysicalModify(PVM pVM, PGMPHYSHANDLERTYPE enmType, RTGCPHYS GCPhysOld, RTGCPHYS GCPhysNew, RTGCPHYS cb, bool fHasHCHandler, bool fRestoreAsRAM)
3445	{
3446	Log(("REMR3NotifyHandlerPhysicalModify: enmType=%d GCPhysOld=%RGp GCPhysNew=%RGp cb=%RGp fHasHCHandler=%RTbool fRestoreAsRAM=%RTbool\n",
3447	enmType, GCPhysOld, GCPhysNew, cb, fHasHCHandler, fRestoreAsRAM));
3448	VM_ASSERT_EMT(pVM);
3449	AssertReleaseMsg(enmType != PGMPHYSHANDLERTYPE_MMIO, ("enmType=%d\n", enmType));
3450
3451	if (fHasHCHandler)
3452	{
3453	ASMAtomicIncU32(&pVM->rem.s.cIgnoreAll);
3454
3455	/*
3456	* Reset the old page.
3457	*/
3458	PDMCritSectEnter(&pVM->rem.s.CritSectRegister, VERR_SEM_BUSY);
3459	if (!fRestoreAsRAM)
3460	cpu_register_physical_memory_offset(GCPhysOld, cb, IO_MEM_UNASSIGNED, GCPhysOld);
3461	else
3462	{
3463	/* This is not perfect, but it'll do for PD monitoring... */
3464	Assert(cb == PAGE_SIZE);
3465	Assert(RT_ALIGN_T(GCPhysOld, PAGE_SIZE, RTGCPHYS) == GCPhysOld);
3466	cpu_register_physical_memory_offset(GCPhysOld, cb, GCPhysOld, GCPhysOld);
3467	}
3468
3469	/*
3470	* Update the new page.
3471	*/
3472	Assert(RT_ALIGN_T(GCPhysNew, PAGE_SIZE, RTGCPHYS) == GCPhysNew);
3473	Assert(RT_ALIGN_T(cb, PAGE_SIZE, RTGCPHYS) == cb);
3474	cpu_register_physical_memory_offset(GCPhysNew, cb, pVM->rem.s.iHandlerMemType, GCPhysNew);
3475	PDMCritSectLeave(&pVM->rem.s.CritSectRegister);
3476
3477	ASMAtomicDecU32(&pVM->rem.s.cIgnoreAll);
3478	}
3479	}
3480
3481	/**
3482	* Notification about a successful PGMR3HandlerPhysicalModify() call.
3483	*
3484	* @param pVM VM Handle.
3485	* @param enmType Handler type.
3486	* @param GCPhysOld Old handler range address.
3487	* @param GCPhysNew New handler range address.
3488	* @param cb Size of the handler range.
3489	* @param fHasHCHandler Set if the handler has a HC callback function.
3490	* @param fRestoreAsRAM Whether the to restore it as normal RAM or as unassigned memory.
3491	*/
3492	REMR3DECL(void) REMR3NotifyHandlerPhysicalModify(PVM pVM, PGMPHYSHANDLERTYPE enmType, RTGCPHYS GCPhysOld, RTGCPHYS GCPhysNew, RTGCPHYS cb, bool fHasHCHandler, bool fRestoreAsRAM)
3493	{
3494	REMR3ReplayHandlerNotifications(pVM);
3495
3496	remR3NotifyHandlerPhysicalModify(pVM, enmType, GCPhysOld, GCPhysNew, cb, fHasHCHandler, fRestoreAsRAM);
3497	}
3498
3499	/**
3500	* Checks if we're handling access to this page or not.
3501	*
3502	* @returns true if we're trapping access.
3503	* @returns false if we aren't.
3504	* @param pVM The VM handle.
3505	* @param GCPhys The physical address.
3506	*
3507	* @remark This function will only work correctly in VBOX_STRICT builds!
3508	*/
3509	REMR3DECL(bool) REMR3IsPageAccessHandled(PVM pVM, RTGCPHYS GCPhys)
3510	{
3511	#ifdef VBOX_STRICT
3512	ram_addr_t off;
3513	REMR3ReplayHandlerNotifications(pVM);
3514
3515	off = get_phys_page_offset(GCPhys);
3516	return (off & PAGE_OFFSET_MASK) == pVM->rem.s.iHandlerMemType
3517	\|\| (off & PAGE_OFFSET_MASK) == pVM->rem.s.iMMIOMemType
3518	\|\| (off & PAGE_OFFSET_MASK) == IO_MEM_ROM;
3519	#else
3520	return false;
3521	#endif
3522	}
3523
3524
3525	/**
3526	* Deals with a rare case in get_phys_addr_code where the code
3527	* is being monitored.
3528	*
3529	* It could also be an MMIO page, in which case we will raise a fatal error.
3530	*
3531	* @returns The physical address corresponding to addr.
3532	* @param env The cpu environment.
3533	* @param addr The virtual address.
3534	* @param pTLBEntry The TLB entry.
3535	*/
3536	target_ulong remR3PhysGetPhysicalAddressCode(CPUX86State *env,
3537	target_ulong addr,
3538	CPUTLBEntry *pTLBEntry,
3539	target_phys_addr_t ioTLBEntry)
3540	{
3541	PVM pVM = env->pVM;
3542
3543	if ((ioTLBEntry & ~TARGET_PAGE_MASK) == pVM->rem.s.iHandlerMemType)
3544	{
3545	/* If code memory is being monitored, appropriate IOTLB entry will have
3546	handler IO type, and addend will provide real physical address, no
3547	matter if we store VA in TLB or not, as handlers are always passed PA */
3548	target_ulong ret = (ioTLBEntry & TARGET_PAGE_MASK) + addr;
3549	return ret;
3550	}
3551	LogRel(("\nTrying to execute code with memory type addr_code=%RGv addend=%RGp at %RGv! (iHandlerMemType=%#x iMMIOMemType=%#x IOTLB=%RGp)\n"
3552	"*** handlers\n",
3553	(RTGCPTR)pTLBEntry->addr_code, (RTGCPHYS)pTLBEntry->addend, (RTGCPTR)addr, pVM->rem.s.iHandlerMemType, pVM->rem.s.iMMIOMemType, (RTGCPHYS)ioTLBEntry));
3554	DBGFR3Info(pVM->pUVM, "handlers", NULL, DBGFR3InfoLogRelHlp());
3555	LogRel(("*** mmio\n"));
3556	DBGFR3Info(pVM->pUVM, "mmio", NULL, DBGFR3InfoLogRelHlp());
3557	LogRel(("*** phys\n"));
3558	DBGFR3Info(pVM->pUVM, "phys", NULL, DBGFR3InfoLogRelHlp());
3559	cpu_abort(env, "Trying to execute code with memory type addr_code=%RGv addend=%RGp at %RGv. (iHandlerMemType=%#x iMMIOMemType=%#x)\n",
3560	(RTGCPTR)pTLBEntry->addr_code, (RTGCPHYS)pTLBEntry->addend, (RTGCPTR)addr, pVM->rem.s.iHandlerMemType, pVM->rem.s.iMMIOMemType);
3561	AssertFatalFailed();
3562	}
3563
3564	/**
3565	* Read guest RAM and ROM.
3566	*
3567	* @param SrcGCPhys The source address (guest physical).
3568	* @param pvDst The destination address.
3569	* @param cb Number of bytes
3570	*/
3571	void remR3PhysRead(RTGCPHYS SrcGCPhys, void *pvDst, unsigned cb)
3572	{
3573	STAM_PROFILE_ADV_START(&gStatMemRead, a);
3574	VBOX_CHECK_ADDR(SrcGCPhys);
3575	PGMPhysRead(cpu_single_env->pVM, SrcGCPhys, pvDst, cb);
3576	#ifdef VBOX_DEBUG_PHYS
3577	LogRel(("read(%d): %08x\n", cb, (uint32_t)SrcGCPhys));
3578	#endif
3579	STAM_PROFILE_ADV_STOP(&gStatMemRead, a);
3580	}
3581
3582
3583	/**
3584	* Read guest RAM and ROM, unsigned 8-bit.
3585	*
3586	* @param SrcGCPhys The source address (guest physical).
3587	*/
3588	RTCCUINTREG remR3PhysReadU8(RTGCPHYS SrcGCPhys)
3589	{
3590	uint8_t val;
3591	STAM_PROFILE_ADV_START(&gStatMemRead, a);
3592	VBOX_CHECK_ADDR(SrcGCPhys);
3593	val = PGMR3PhysReadU8(cpu_single_env->pVM, SrcGCPhys);
3594	STAM_PROFILE_ADV_STOP(&gStatMemRead, a);
3595	#ifdef VBOX_DEBUG_PHYS
3596	LogRel(("readu8: %x <- %08x\n", val, (uint32_t)SrcGCPhys));
3597	#endif
3598	return val;
3599	}
3600
3601
3602	/**
3603	* Read guest RAM and ROM, signed 8-bit.
3604	*
3605	* @param SrcGCPhys The source address (guest physical).
3606	*/
3607	RTCCINTREG remR3PhysReadS8(RTGCPHYS SrcGCPhys)
3608	{
3609	int8_t val;
3610	STAM_PROFILE_ADV_START(&gStatMemRead, a);
3611	VBOX_CHECK_ADDR(SrcGCPhys);
3612	val = PGMR3PhysReadU8(cpu_single_env->pVM, SrcGCPhys);
3613	STAM_PROFILE_ADV_STOP(&gStatMemRead, a);
3614	#ifdef VBOX_DEBUG_PHYS
3615	LogRel(("reads8: %x <- %08x\n", val, (uint32_t)SrcGCPhys));
3616	#endif
3617	return val;
3618	}
3619
3620
3621	/**
3622	* Read guest RAM and ROM, unsigned 16-bit.
3623	*
3624	* @param SrcGCPhys The source address (guest physical).
3625	*/
3626	RTCCUINTREG remR3PhysReadU16(RTGCPHYS SrcGCPhys)
3627	{
3628	uint16_t val;
3629	STAM_PROFILE_ADV_START(&gStatMemRead, a);
3630	VBOX_CHECK_ADDR(SrcGCPhys);
3631	val = PGMR3PhysReadU16(cpu_single_env->pVM, SrcGCPhys);
3632	STAM_PROFILE_ADV_STOP(&gStatMemRead, a);
3633	#ifdef VBOX_DEBUG_PHYS
3634	LogRel(("readu16: %x <- %08x\n", val, (uint32_t)SrcGCPhys));
3635	#endif
3636	return val;
3637	}
3638
3639
3640	/**
3641	* Read guest RAM and ROM, signed 16-bit.
3642	*
3643	* @param SrcGCPhys The source address (guest physical).
3644	*/
3645	RTCCINTREG remR3PhysReadS16(RTGCPHYS SrcGCPhys)
3646	{
3647	int16_t val;
3648	STAM_PROFILE_ADV_START(&gStatMemRead, a);
3649	VBOX_CHECK_ADDR(SrcGCPhys);
3650	val = PGMR3PhysReadU16(cpu_single_env->pVM, SrcGCPhys);
3651	STAM_PROFILE_ADV_STOP(&gStatMemRead, a);
3652	#ifdef VBOX_DEBUG_PHYS
3653	LogRel(("reads16: %x <- %08x\n", (uint16_t)val, (uint32_t)SrcGCPhys));
3654	#endif
3655	return val;
3656	}
3657
3658
3659	/**
3660	* Read guest RAM and ROM, unsigned 32-bit.
3661	*
3662	* @param SrcGCPhys The source address (guest physical).
3663	*/
3664	RTCCUINTREG remR3PhysReadU32(RTGCPHYS SrcGCPhys)
3665	{
3666	uint32_t val;
3667	STAM_PROFILE_ADV_START(&gStatMemRead, a);
3668	VBOX_CHECK_ADDR(SrcGCPhys);
3669	val = PGMR3PhysReadU32(cpu_single_env->pVM, SrcGCPhys);
3670	STAM_PROFILE_ADV_STOP(&gStatMemRead, a);
3671	#ifdef VBOX_DEBUG_PHYS
3672	LogRel(("readu32: %x <- %08x\n", val, (uint32_t)SrcGCPhys));
3673	#endif
3674	return val;
3675	}
3676
3677
3678	/**
3679	* Read guest RAM and ROM, signed 32-bit.
3680	*
3681	* @param SrcGCPhys The source address (guest physical).
3682	*/
3683	RTCCINTREG remR3PhysReadS32(RTGCPHYS SrcGCPhys)
3684	{
3685	int32_t val;
3686	STAM_PROFILE_ADV_START(&gStatMemRead, a);
3687	VBOX_CHECK_ADDR(SrcGCPhys);
3688	val = PGMR3PhysReadU32(cpu_single_env->pVM, SrcGCPhys);
3689	STAM_PROFILE_ADV_STOP(&gStatMemRead, a);
3690	#ifdef VBOX_DEBUG_PHYS
3691	LogRel(("reads32: %x <- %08x\n", val, (uint32_t)SrcGCPhys));
3692	#endif
3693	return val;
3694	}
3695
3696
3697	/**
3698	* Read guest RAM and ROM, unsigned 64-bit.
3699	*
3700	* @param SrcGCPhys The source address (guest physical).
3701	*/
3702	uint64_t remR3PhysReadU64(RTGCPHYS SrcGCPhys)
3703	{
3704	uint64_t val;
3705	STAM_PROFILE_ADV_START(&gStatMemRead, a);
3706	VBOX_CHECK_ADDR(SrcGCPhys);
3707	val = PGMR3PhysReadU64(cpu_single_env->pVM, SrcGCPhys);
3708	STAM_PROFILE_ADV_STOP(&gStatMemRead, a);
3709	#ifdef VBOX_DEBUG_PHYS
3710	LogRel(("readu64: %llx <- %08x\n", val, (uint32_t)SrcGCPhys));
3711	#endif
3712	return val;
3713	}
3714
3715
3716	/**
3717	* Read guest RAM and ROM, signed 64-bit.
3718	*
3719	* @param SrcGCPhys The source address (guest physical).
3720	*/
3721	int64_t remR3PhysReadS64(RTGCPHYS SrcGCPhys)
3722	{
3723	int64_t val;
3724	STAM_PROFILE_ADV_START(&gStatMemRead, a);
3725	VBOX_CHECK_ADDR(SrcGCPhys);
3726	val = PGMR3PhysReadU64(cpu_single_env->pVM, SrcGCPhys);
3727	STAM_PROFILE_ADV_STOP(&gStatMemRead, a);
3728	#ifdef VBOX_DEBUG_PHYS
3729	LogRel(("reads64: %llx <- %08x\n", val, (uint32_t)SrcGCPhys));
3730	#endif
3731	return val;
3732	}
3733
3734
3735	/**
3736	* Write guest RAM.
3737	*
3738	* @param DstGCPhys The destination address (guest physical).
3739	* @param pvSrc The source address.
3740	* @param cb Number of bytes to write
3741	*/
3742	void remR3PhysWrite(RTGCPHYS DstGCPhys, const void *pvSrc, unsigned cb)
3743	{
3744	STAM_PROFILE_ADV_START(&gStatMemWrite, a);
3745	VBOX_CHECK_ADDR(DstGCPhys);
3746	PGMPhysWrite(cpu_single_env->pVM, DstGCPhys, pvSrc, cb);
3747	STAM_PROFILE_ADV_STOP(&gStatMemWrite, a);
3748	#ifdef VBOX_DEBUG_PHYS
3749	LogRel(("write(%d): %08x\n", cb, (uint32_t)DstGCPhys));
3750	#endif
3751	}
3752
3753
3754	/**
3755	* Write guest RAM, unsigned 8-bit.
3756	*
3757	* @param DstGCPhys The destination address (guest physical).
3758	* @param val Value
3759	*/
3760	void remR3PhysWriteU8(RTGCPHYS DstGCPhys, uint8_t val)
3761	{
3762	STAM_PROFILE_ADV_START(&gStatMemWrite, a);
3763	VBOX_CHECK_ADDR(DstGCPhys);
3764	PGMR3PhysWriteU8(cpu_single_env->pVM, DstGCPhys, val);
3765	STAM_PROFILE_ADV_STOP(&gStatMemWrite, a);
3766	#ifdef VBOX_DEBUG_PHYS
3767	LogRel(("writeu8: %x -> %08x\n", val, (uint32_t)DstGCPhys));
3768	#endif
3769	}
3770
3771
3772	/**
3773	* Write guest RAM, unsigned 8-bit.
3774	*
3775	* @param DstGCPhys The destination address (guest physical).
3776	* @param val Value
3777	*/
3778	void remR3PhysWriteU16(RTGCPHYS DstGCPhys, uint16_t val)
3779	{
3780	STAM_PROFILE_ADV_START(&gStatMemWrite, a);
3781	VBOX_CHECK_ADDR(DstGCPhys);
3782	PGMR3PhysWriteU16(cpu_single_env->pVM, DstGCPhys, val);
3783	STAM_PROFILE_ADV_STOP(&gStatMemWrite, a);
3784	#ifdef VBOX_DEBUG_PHYS
3785	LogRel(("writeu16: %x -> %08x\n", val, (uint32_t)DstGCPhys));
3786	#endif
3787	}
3788
3789
3790	/**
3791	* Write guest RAM, unsigned 32-bit.
3792	*
3793	* @param DstGCPhys The destination address (guest physical).
3794	* @param val Value
3795	*/
3796	void remR3PhysWriteU32(RTGCPHYS DstGCPhys, uint32_t val)
3797	{
3798	STAM_PROFILE_ADV_START(&gStatMemWrite, a);
3799	VBOX_CHECK_ADDR(DstGCPhys);
3800	PGMR3PhysWriteU32(cpu_single_env->pVM, DstGCPhys, val);
3801	STAM_PROFILE_ADV_STOP(&gStatMemWrite, a);
3802	#ifdef VBOX_DEBUG_PHYS
3803	LogRel(("writeu32: %x -> %08x\n", val, (uint32_t)DstGCPhys));
3804	#endif
3805	}
3806
3807
3808	/**
3809	* Write guest RAM, unsigned 64-bit.
3810	*
3811	* @param DstGCPhys The destination address (guest physical).
3812	* @param val Value
3813	*/
3814	void remR3PhysWriteU64(RTGCPHYS DstGCPhys, uint64_t val)
3815	{
3816	STAM_PROFILE_ADV_START(&gStatMemWrite, a);
3817	VBOX_CHECK_ADDR(DstGCPhys);
3818	PGMR3PhysWriteU64(cpu_single_env->pVM, DstGCPhys, val);
3819	STAM_PROFILE_ADV_STOP(&gStatMemWrite, a);
3820	#ifdef VBOX_DEBUG_PHYS
3821	LogRel(("writeu64: %llx -> %08x\n", val, (uint32_t)DstGCPhys));
3822	#endif
3823	}
3824
3825	#undef LOG_GROUP
3826	#define LOG_GROUP LOG_GROUP_REM_MMIO
3827
3828	/** Read MMIO memory. */
3829	static uint32_t remR3MMIOReadU8(void *pvEnv, target_phys_addr_t GCPhys)
3830	{
3831	CPUX86State env = (CPUX86State )pvEnv;
3832	uint32_t u32 = 0;
3833	int rc = IOMMMIORead(env->pVM, env->pVCpu, GCPhys, &u32, 1);
3834	AssertMsg(rc == VINF_SUCCESS, ("rc=%Rrc\n", rc)); NOREF(rc);
3835	Log2(("remR3MMIOReadU8: GCPhys=%RGp -> %02x\n", (RTGCPHYS)GCPhys, u32));
3836	return u32;
3837	}
3838
3839	/** Read MMIO memory. */
3840	static uint32_t remR3MMIOReadU16(void *pvEnv, target_phys_addr_t GCPhys)
3841	{
3842	CPUX86State env = (CPUX86State )pvEnv;
3843	uint32_t u32 = 0;
3844	int rc = IOMMMIORead(env->pVM, env->pVCpu, GCPhys, &u32, 2);
3845	AssertMsg(rc == VINF_SUCCESS, ("rc=%Rrc\n", rc)); NOREF(rc);
3846	Log2(("remR3MMIOReadU16: GCPhys=%RGp -> %04x\n", (RTGCPHYS)GCPhys, u32));
3847	return u32;
3848	}
3849
3850	/** Read MMIO memory. */
3851	static uint32_t remR3MMIOReadU32(void *pvEnv, target_phys_addr_t GCPhys)
3852	{
3853	CPUX86State env = (CPUX86State )pvEnv;
3854	uint32_t u32 = 0;
3855	int rc = IOMMMIORead(env->pVM, env->pVCpu, GCPhys, &u32, 4);
3856	AssertMsg(rc == VINF_SUCCESS, ("rc=%Rrc\n", rc)); NOREF(rc);
3857	Log2(("remR3MMIOReadU32: GCPhys=%RGp -> %08x\n", (RTGCPHYS)GCPhys, u32));
3858	return u32;
3859	}
3860
3861	/** Write to MMIO memory. */
3862	static void remR3MMIOWriteU8(void *pvEnv, target_phys_addr_t GCPhys, uint32_t u32)
3863	{
3864	CPUX86State env = (CPUX86State )pvEnv;
3865	int rc;
3866	Log2(("remR3MMIOWriteU8: GCPhys=%RGp u32=%#x\n", (RTGCPHYS)GCPhys, u32));
3867	rc = IOMMMIOWrite(env->pVM, env->pVCpu, GCPhys, u32, 1);
3868	AssertMsg(rc == VINF_SUCCESS, ("rc=%Rrc\n", rc)); NOREF(rc);
3869	}
3870
3871	/** Write to MMIO memory. */
3872	static void remR3MMIOWriteU16(void *pvEnv, target_phys_addr_t GCPhys, uint32_t u32)
3873	{
3874	CPUX86State env = (CPUX86State )pvEnv;
3875	int rc;
3876	Log2(("remR3MMIOWriteU16: GCPhys=%RGp u32=%#x\n", (RTGCPHYS)GCPhys, u32));
3877	rc = IOMMMIOWrite(env->pVM, env->pVCpu, GCPhys, u32, 2);
3878	AssertMsg(rc == VINF_SUCCESS, ("rc=%Rrc\n", rc)); NOREF(rc);
3879	}
3880
3881	/** Write to MMIO memory. */
3882	static void remR3MMIOWriteU32(void *pvEnv, target_phys_addr_t GCPhys, uint32_t u32)
3883	{
3884	CPUX86State env = (CPUX86State )pvEnv;
3885	int rc;
3886	Log2(("remR3MMIOWriteU32: GCPhys=%RGp u32=%#x\n", (RTGCPHYS)GCPhys, u32));
3887	rc = IOMMMIOWrite(env->pVM, env->pVCpu, GCPhys, u32, 4);
3888	AssertMsg(rc == VINF_SUCCESS, ("rc=%Rrc\n", rc)); NOREF(rc);
3889	}
3890
3891
3892	#undef LOG_GROUP
3893	#define LOG_GROUP LOG_GROUP_REM_HANDLER
3894
3895	/* !!!WARNING!!! This is extremely hackish right now, we assume it's only for LFB access! !!!WARNING!!! */
3896
3897	static uint32_t remR3HandlerReadU8(void *pvVM, target_phys_addr_t GCPhys)
3898	{
3899	uint8_t u8;
3900	Log2(("remR3HandlerReadU8: GCPhys=%RGp\n", (RTGCPHYS)GCPhys));
3901	PGMPhysRead((PVM)pvVM, GCPhys, &u8, sizeof(u8));
3902	return u8;
3903	}
3904
3905	static uint32_t remR3HandlerReadU16(void *pvVM, target_phys_addr_t GCPhys)
3906	{
3907	uint16_t u16;
3908	Log2(("remR3HandlerReadU16: GCPhys=%RGp\n", (RTGCPHYS)GCPhys));
3909	PGMPhysRead((PVM)pvVM, GCPhys, &u16, sizeof(u16));
3910	return u16;
3911	}
3912
3913	static uint32_t remR3HandlerReadU32(void *pvVM, target_phys_addr_t GCPhys)
3914	{
3915	uint32_t u32;
3916	Log2(("remR3HandlerReadU32: GCPhys=%RGp\n", (RTGCPHYS)GCPhys));
3917	PGMPhysRead((PVM)pvVM, GCPhys, &u32, sizeof(u32));
3918	return u32;
3919	}
3920
3921	static void remR3HandlerWriteU8(void *pvVM, target_phys_addr_t GCPhys, uint32_t u32)
3922	{
3923	Log2(("remR3HandlerWriteU8: GCPhys=%RGp u32=%#x\n", (RTGCPHYS)GCPhys, u32));
3924	PGMPhysWrite((PVM)pvVM, GCPhys, &u32, sizeof(uint8_t));
3925	}
3926
3927	static void remR3HandlerWriteU16(void *pvVM, target_phys_addr_t GCPhys, uint32_t u32)
3928	{
3929	Log2(("remR3HandlerWriteU16: GCPhys=%RGp u32=%#x\n", (RTGCPHYS)GCPhys, u32));
3930	PGMPhysWrite((PVM)pvVM, GCPhys, &u32, sizeof(uint16_t));
3931	}
3932
3933	static void remR3HandlerWriteU32(void *pvVM, target_phys_addr_t GCPhys, uint32_t u32)
3934	{
3935	Log2(("remR3HandlerWriteU32: GCPhys=%RGp u32=%#x\n", (RTGCPHYS)GCPhys, u32));
3936	PGMPhysWrite((PVM)pvVM, GCPhys, &u32, sizeof(uint32_t));
3937	}
3938
3939	/* -+- disassembly -+- */
3940
3941	#undef LOG_GROUP
3942	#define LOG_GROUP LOG_GROUP_REM_DISAS
3943
3944
3945	/**
3946	* Enables or disables singled stepped disassembly.
3947	*
3948	* @returns VBox status code.
3949	* @param pVM VM handle.
3950	* @param fEnable To enable set this flag, to disable clear it.
3951	*/
3952	static DECLCALLBACK(int) remR3DisasEnableStepping(PVM pVM, bool fEnable)
3953	{
3954	LogFlow(("remR3DisasEnableStepping: fEnable=%d\n", fEnable));
3955	VM_ASSERT_EMT(pVM);
3956
3957	if (fEnable)
3958	pVM->rem.s.Env.state \|= CPU_EMULATE_SINGLE_STEP;
3959	else
3960	pVM->rem.s.Env.state &= ~CPU_EMULATE_SINGLE_STEP;
3961	#ifdef REM_USE_QEMU_SINGLE_STEP_FOR_LOGGING
3962	cpu_single_step(&pVM->rem.s.Env, fEnable);
3963	#endif
3964	return VINF_SUCCESS;
3965	}
3966
3967
3968	/**
3969	* Enables or disables singled stepped disassembly.
3970	*
3971	* @returns VBox status code.
3972	* @param pVM VM handle.
3973	* @param fEnable To enable set this flag, to disable clear it.
3974	*/
3975	REMR3DECL(int) REMR3DisasEnableStepping(PVM pVM, bool fEnable)
3976	{
3977	int rc;
3978
3979	LogFlow(("REMR3DisasEnableStepping: fEnable=%d\n", fEnable));
3980	if (VM_IS_EMT(pVM))
3981	return remR3DisasEnableStepping(pVM, fEnable);
3982
3983	rc = VMR3ReqPriorityCallWait(pVM, VMCPUID_ANY, (PFNRT)remR3DisasEnableStepping, 2, pVM, fEnable);
3984	AssertRC(rc);
3985	return rc;
3986	}
3987
3988
3989	#if defined(VBOX_WITH_DEBUGGER) && !(defined(RT_OS_WINDOWS) && defined(RT_ARCH_AMD64))
3990	/**
3991	* External Debugger Command: .remstep [on\|off\|1\|0]
3992	*/
3993	static DECLCALLBACK(int) remR3CmdDisasEnableStepping(PCDBGCCMD pCmd, PDBGCCMDHLP pCmdHlp, PUVM pUVM, PCDBGCVAR paArgs, unsigned cArgs)
3994	{
3995	int rc;
3996	PVM pVM = pUVM->pVM;
3997
3998	if (cArgs == 0)
3999	/*
4000	* Print the current status.
4001	*/
4002	rc = DBGCCmdHlpPrintf(pCmdHlp, "DisasStepping is %s\n",
4003	pVM->rem.s.Env.state & CPU_EMULATE_SINGLE_STEP ? "enabled" : "disabled");
4004	else
4005	{
4006	/*
4007	* Convert the argument and change the mode.
4008	*/
4009	bool fEnable;
4010	rc = DBGCCmdHlpVarToBool(pCmdHlp, &paArgs[0], &fEnable);
4011	if (RT_SUCCESS(rc))
4012	{
4013	rc = REMR3DisasEnableStepping(pVM, fEnable);
4014	if (RT_SUCCESS(rc))
4015	rc = DBGCCmdHlpPrintf(pCmdHlp, "DisasStepping was %s\n", fEnable ? "enabled" : "disabled");
4016	else
4017	rc = DBGCCmdHlpFailRc(pCmdHlp, pCmd, rc, "REMR3DisasEnableStepping");
4018	}
4019	else
4020	rc = DBGCCmdHlpFailRc(pCmdHlp, pCmd, rc, "DBGCCmdHlpVarToBool");
4021	}
4022	return rc;
4023	}
4024	#endif /* VBOX_WITH_DEBUGGER && !win.amd64 */
4025
4026
4027	/**
4028	* Disassembles one instruction and prints it to the log.
4029	*
4030	* @returns Success indicator.
4031	* @param env Pointer to the recompiler CPU structure.
4032	* @param f32BitCode Indicates that whether or not the code should
4033	* be disassembled as 16 or 32 bit. If -1 the CS
4034	* selector will be inspected.
4035	* @param pszPrefix
4036	*/
4037	bool remR3DisasInstr(CPUX86State env, int f32BitCode, char pszPrefix)
4038	{
4039	PVM pVM = env->pVM;
4040	const bool fLog = LogIsEnabled();
4041	const bool fLog2 = LogIs2Enabled();
4042	int rc = VINF_SUCCESS;
4043
4044	/*
4045	* Don't bother if there ain't any log output to do.
4046	*/
4047	if (!fLog && !fLog2)
4048	return true;
4049
4050	/*
4051	* Update the state so DBGF reads the correct register values.
4052	*/
4053	remR3StateUpdate(pVM, env->pVCpu);
4054
4055	/*
4056	* Log registers if requested.
4057	*/
4058	if (fLog2)
4059	DBGFR3_INFO_LOG(pVM, "cpumguest", pszPrefix);
4060
4061	/*
4062	* Disassemble to log.
4063	*/
4064	if (fLog)
4065	{
4066	PVMCPU pVCpu = VMMGetCpu(pVM);
4067	char szBuf[256];
4068	szBuf[0] = '\0';
4069	int rc = DBGFR3DisasInstrEx(pVCpu->pVMR3->pUVM,
4070	pVCpu->idCpu,
4071	0, /* Sel */
4072	0, /* GCPtr */
4073	DBGF_DISAS_FLAGS_CURRENT_GUEST
4074	\| DBGF_DISAS_FLAGS_DEFAULT_MODE,
4075	szBuf,
4076	sizeof(szBuf),
4077	NULL);
4078	if (RT_FAILURE(rc))
4079	RTStrPrintf(szBuf, sizeof(szBuf), "DBGFR3DisasInstrEx failed with rc=%Rrc\n", rc);
4080	if (pszPrefix && *pszPrefix)
4081	RTLogPrintf("%s-CPU%d: %s\n", pszPrefix, pVCpu->idCpu, szBuf);
4082	else
4083	RTLogPrintf("CPU%d: %s\n", pVCpu->idCpu, szBuf);
4084	}
4085
4086	return RT_SUCCESS(rc);
4087	}
4088
4089
4090	/**
4091	* Disassemble recompiled code.
4092	*
4093	* @param phFileIgnored Ignored, logfile usually.
4094	* @param pvCode Pointer to the code block.
4095	* @param cb Size of the code block.
4096	*/
4097	void disas(FILE phFile, void pvCode, unsigned long cb)
4098	{
4099	if (LogIs2Enabled())
4100	{
4101	unsigned off = 0;
4102	char szOutput[256];
4103	DISCPUSTATE Cpu;
4104	#ifdef RT_ARCH_X86
4105	DISCPUMODE enmCpuMode = DISCPUMODE_32BIT;
4106	#else
4107	DISCPUMODE enmCpuMode = DISCPUMODE_64BIT;
4108	#endif
4109
4110	RTLogPrintf("Recompiled Code: %p %#lx (%ld) bytes\n", pvCode, cb, cb);
4111	while (off < cb)
4112	{
4113	uint32_t cbInstr;
4114	int rc = DISInstrToStr((uint8_t const *)pvCode + off, enmCpuMode,
4115	&Cpu, &cbInstr, szOutput, sizeof(szOutput));
4116	if (RT_SUCCESS(rc))
4117	RTLogPrintf("%s", szOutput);
4118	else
4119	{
4120	RTLogPrintf("disas error %Rrc\n", rc);
4121	cbInstr = 1;
4122	}
4123	off += cbInstr;
4124	}
4125	}
4126	}
4127
4128
4129	/**
4130	* Disassemble guest code.
4131	*
4132	* @param phFileIgnored Ignored, logfile usually.
4133	* @param uCode The guest address of the code to disassemble. (flat?)
4134	* @param cb Number of bytes to disassemble.
4135	* @param fFlags Flags, probably something which tells if this is 16, 32 or 64 bit code.
4136	*/
4137	void target_disas(FILE *phFile, target_ulong uCode, target_ulong cb, int fFlags)
4138	{
4139	if (LogIs2Enabled())
4140	{
4141	PVM pVM = cpu_single_env->pVM;
4142	PVMCPU pVCpu = cpu_single_env->pVCpu;
4143	RTSEL cs;
4144	RTGCUINTPTR eip;
4145
4146	Assert(pVCpu);
4147
4148	/*
4149	* Update the state so DBGF reads the correct register values (flags).
4150	*/
4151	remR3StateUpdate(pVM, pVCpu);
4152
4153	/*
4154	* Do the disassembling.
4155	*/
4156	RTLogPrintf("Guest Code: PC=%llx %llx bytes fFlags=%d\n", (uint64_t)uCode, (uint64_t)cb, fFlags);
4157	cs = cpu_single_env->segs[R_CS].selector;
4158	eip = uCode - cpu_single_env->segs[R_CS].base;
4159	for (;;)
4160	{
4161	char szBuf[256];
4162	uint32_t cbInstr;
4163	int rc = DBGFR3DisasInstrEx(pVM->pUVM,
4164	pVCpu->idCpu,
4165	cs,
4166	eip,
4167	DBGF_DISAS_FLAGS_DEFAULT_MODE,
4168	szBuf, sizeof(szBuf),
4169	&cbInstr);
4170	if (RT_SUCCESS(rc))
4171	RTLogPrintf("%llx %s\n", (uint64_t)uCode, szBuf);
4172	else
4173	{
4174	RTLogPrintf("%llx %04x:%llx: %s\n", (uint64_t)uCode, cs, (uint64_t)eip, szBuf);
4175	cbInstr = 1;
4176	}
4177
4178	/* next */
4179	if (cb <= cbInstr)
4180	break;
4181	cb -= cbInstr;
4182	uCode += cbInstr;
4183	eip += cbInstr;
4184	}
4185	}
4186	}
4187
4188
4189	/**
4190	* Looks up a guest symbol.
4191	*
4192	* @returns Pointer to symbol name. This is a static buffer.
4193	* @param orig_addr The address in question.
4194	*/
4195	const char *lookup_symbol(target_ulong orig_addr)
4196	{
4197	PVM pVM = cpu_single_env->pVM;
4198	RTGCINTPTR off = 0;
4199	RTDBGSYMBOL Sym;
4200	DBGFADDRESS Addr;
4201
4202	int rc = DBGFR3AsSymbolByAddr(pVM->pUVM, DBGF_AS_GLOBAL, DBGFR3AddrFromFlat(pVM->pUVM, &Addr, orig_addr),
4203	&off, &Sym, NULL /phMod/);
4204	if (RT_SUCCESS(rc))
4205	{
4206	static char szSym[sizeof(Sym.szName) + 48];
4207	if (!off)
4208	RTStrPrintf(szSym, sizeof(szSym), "%s\n", Sym.szName);
4209	else if (off > 0)
4210	RTStrPrintf(szSym, sizeof(szSym), "%s+%x\n", Sym.szName, off);
4211	else
4212	RTStrPrintf(szSym, sizeof(szSym), "%s-%x\n", Sym.szName, -off);
4213	return szSym;
4214	}
4215	return "<N/A>";
4216	}
4217
4218
4219	#undef LOG_GROUP
4220	#define LOG_GROUP LOG_GROUP_REM
4221
4222
4223	/* -+- FF notifications -+- */
4224
4225
4226	/**
4227	* Notification about a pending interrupt.
4228	*
4229	* @param pVM VM Handle.
4230	* @param pVCpu VMCPU Handle.
4231	* @param u8Interrupt Interrupt
4232	* @thread The emulation thread.
4233	*/
4234	REMR3DECL(void) REMR3NotifyPendingInterrupt(PVM pVM, PVMCPU pVCpu, uint8_t u8Interrupt)
4235	{
4236	Assert(pVM->rem.s.u32PendingInterrupt == REM_NO_PENDING_IRQ);
4237	pVM->rem.s.u32PendingInterrupt = u8Interrupt;
4238	}
4239
4240	/**
4241	* Notification about a pending interrupt.
4242	*
4243	* @returns Pending interrupt or REM_NO_PENDING_IRQ
4244	* @param pVM VM Handle.
4245	* @param pVCpu VMCPU Handle.
4246	* @thread The emulation thread.
4247	*/
4248	REMR3DECL(uint32_t) REMR3QueryPendingInterrupt(PVM pVM, PVMCPU pVCpu)
4249	{
4250	return pVM->rem.s.u32PendingInterrupt;
4251	}
4252
4253	/**
4254	* Notification about the interrupt FF being set.
4255	*
4256	* @param pVM VM Handle.
4257	* @param pVCpu VMCPU Handle.
4258	* @thread The emulation thread.
4259	*/
4260	REMR3DECL(void) REMR3NotifyInterruptSet(PVM pVM, PVMCPU pVCpu)
4261	{
4262	#ifndef IEM_VERIFICATION_MODE
4263	LogFlow(("REMR3NotifyInterruptSet: fInRem=%d interrupts %s\n", pVM->rem.s.fInREM,
4264	(pVM->rem.s.Env.eflags & IF_MASK) && !(pVM->rem.s.Env.hflags & HF_INHIBIT_IRQ_MASK) ? "enabled" : "disabled"));
4265	if (pVM->rem.s.fInREM)
4266	{
4267	ASMAtomicOrS32((int32_t volatile *)&cpu_single_env->interrupt_request,
4268	CPU_INTERRUPT_EXTERNAL_HARD);
4269	}
4270	#endif
4271	}
4272
4273
4274	/**
4275	* Notification about the interrupt FF being set.
4276	*
4277	* @param pVM VM Handle.
4278	* @param pVCpu VMCPU Handle.
4279	* @thread Any.
4280	*/
4281	REMR3DECL(void) REMR3NotifyInterruptClear(PVM pVM, PVMCPU pVCpu)
4282	{
4283	LogFlow(("REMR3NotifyInterruptClear:\n"));
4284	if (pVM->rem.s.fInREM)
4285	cpu_reset_interrupt(cpu_single_env, CPU_INTERRUPT_HARD);
4286	}
4287
4288
4289	/**
4290	* Notification about pending timer(s).
4291	*
4292	* @param pVM VM Handle.
4293	* @param pVCpuDst The target cpu for this notification.
4294	* TM will not broadcast pending timer events, but use
4295	* a dedicated EMT for them. So, only interrupt REM
4296	* execution if the given CPU is executing in REM.
4297	* @thread Any.
4298	*/
4299	REMR3DECL(void) REMR3NotifyTimerPending(PVM pVM, PVMCPU pVCpuDst)
4300	{
4301	#ifndef IEM_VERIFICATION_MODE
4302	#ifndef DEBUG_bird
4303	LogFlow(("REMR3NotifyTimerPending: fInRem=%d\n", pVM->rem.s.fInREM));
4304	#endif
4305	if (pVM->rem.s.fInREM)
4306	{
4307	if (pVM->rem.s.Env.pVCpu == pVCpuDst)
4308	{
4309	LogIt(LOG_INSTANCE, RTLOGGRPFLAGS_LEVEL_5, LOG_GROUP_TM, ("REMR3NotifyTimerPending: setting\n"));
4310	ASMAtomicOrS32((int32_t volatile *)&pVM->rem.s.Env.interrupt_request,
4311	CPU_INTERRUPT_EXTERNAL_TIMER);
4312	}
4313	else
4314	LogIt(LOG_INSTANCE, RTLOGGRPFLAGS_LEVEL_5, LOG_GROUP_TM, ("REMR3NotifyTimerPending: pVCpu:%p != pVCpuDst:%p\n", pVM->rem.s.Env.pVCpu, pVCpuDst));
4315	}
4316	else
4317	LogIt(LOG_INSTANCE, RTLOGGRPFLAGS_LEVEL_5, LOG_GROUP_TM, ("REMR3NotifyTimerPending: !fInREM; cpu state=%d\n", VMCPU_GET_STATE(pVCpuDst)));
4318	#endif
4319	}
4320
4321
4322	/**
4323	* Notification about pending DMA transfers.
4324	*
4325	* @param pVM VM Handle.
4326	* @thread Any.
4327	*/
4328	REMR3DECL(void) REMR3NotifyDmaPending(PVM pVM)
4329	{
4330	#ifndef IEM_VERIFICATION_MODE
4331	LogFlow(("REMR3NotifyDmaPending: fInRem=%d\n", pVM->rem.s.fInREM));
4332	if (pVM->rem.s.fInREM)
4333	{
4334	ASMAtomicOrS32((int32_t volatile *)&cpu_single_env->interrupt_request,
4335	CPU_INTERRUPT_EXTERNAL_DMA);
4336	}
4337	#endif
4338	}
4339
4340
4341	/**
4342	* Notification about pending timer(s).
4343	*
4344	* @param pVM VM Handle.
4345	* @thread Any.
4346	*/
4347	REMR3DECL(void) REMR3NotifyQueuePending(PVM pVM)
4348	{
4349	#ifndef IEM_VERIFICATION_MODE
4350	LogFlow(("REMR3NotifyQueuePending: fInRem=%d\n", pVM->rem.s.fInREM));
4351	if (pVM->rem.s.fInREM)
4352	{
4353	ASMAtomicOrS32((int32_t volatile *)&cpu_single_env->interrupt_request,
4354	CPU_INTERRUPT_EXTERNAL_EXIT);
4355	}
4356	#endif
4357	}
4358
4359
4360	/**
4361	* Notification about pending FF set by an external thread.
4362	*
4363	* @param pVM VM handle.
4364	* @thread Any.
4365	*/
4366	REMR3DECL(void) REMR3NotifyFF(PVM pVM)
4367	{
4368	#ifndef IEM_VERIFICATION_MODE
4369	LogFlow(("REMR3NotifyFF: fInRem=%d\n", pVM->rem.s.fInREM));
4370	if (pVM->rem.s.fInREM)
4371	{
4372	ASMAtomicOrS32((int32_t volatile *)&cpu_single_env->interrupt_request,
4373	CPU_INTERRUPT_EXTERNAL_EXIT);
4374	}
4375	#endif
4376	}
4377
4378
4379	#ifdef VBOX_WITH_STATISTICS
4380	void remR3ProfileStart(int statcode)
4381	{
4382	STAMPROFILEADV *pStat;
4383	switch(statcode)
4384	{
4385	case STATS_EMULATE_SINGLE_INSTR:
4386	pStat = &gStatExecuteSingleInstr;
4387	break;
4388	case STATS_QEMU_COMPILATION:
4389	pStat = &gStatCompilationQEmu;
4390	break;
4391	case STATS_QEMU_RUN_EMULATED_CODE:
4392	pStat = &gStatRunCodeQEmu;
4393	break;
4394	case STATS_QEMU_TOTAL:
4395	pStat = &gStatTotalTimeQEmu;
4396	break;
4397	case STATS_QEMU_RUN_TIMERS:
4398	pStat = &gStatTimers;
4399	break;
4400	case STATS_TLB_LOOKUP:
4401	pStat= &gStatTBLookup;
4402	break;
4403	case STATS_IRQ_HANDLING:
4404	pStat= &gStatIRQ;
4405	break;
4406	case STATS_RAW_CHECK:
4407	pStat = &gStatRawCheck;
4408	break;
4409
4410	default:
4411	AssertMsgFailed(("unknown stat %d\n", statcode));
4412	return;
4413	}
4414	STAM_PROFILE_ADV_START(pStat, a);
4415	}
4416
4417
4418	void remR3ProfileStop(int statcode)
4419	{
4420	STAMPROFILEADV *pStat;
4421	switch(statcode)
4422	{
4423	case STATS_EMULATE_SINGLE_INSTR:
4424	pStat = &gStatExecuteSingleInstr;
4425	break;
4426	case STATS_QEMU_COMPILATION:
4427	pStat = &gStatCompilationQEmu;
4428	break;
4429	case STATS_QEMU_RUN_EMULATED_CODE:
4430	pStat = &gStatRunCodeQEmu;
4431	break;
4432	case STATS_QEMU_TOTAL:
4433	pStat = &gStatTotalTimeQEmu;
4434	break;
4435	case STATS_QEMU_RUN_TIMERS:
4436	pStat = &gStatTimers;
4437	break;
4438	case STATS_TLB_LOOKUP:
4439	pStat= &gStatTBLookup;
4440	break;
4441	case STATS_IRQ_HANDLING:
4442	pStat= &gStatIRQ;
4443	break;
4444	case STATS_RAW_CHECK:
4445	pStat = &gStatRawCheck;
4446	break;
4447	default:
4448	AssertMsgFailed(("unknown stat %d\n", statcode));
4449	return;
4450	}
4451	STAM_PROFILE_ADV_STOP(pStat, a);
4452	}
4453	#endif
4454
4455	/**
4456	* Raise an RC, force rem exit.
4457	*
4458	* @param pVM VM handle.
4459	* @param rc The rc.
4460	*/
4461	void remR3RaiseRC(PVM pVM, int rc)
4462	{
4463	Log(("remR3RaiseRC: rc=%Rrc\n", rc));
4464	Assert(pVM->rem.s.fInREM);
4465	VM_ASSERT_EMT(pVM);
4466	pVM->rem.s.rc = rc;
4467	cpu_interrupt(&pVM->rem.s.Env, CPU_INTERRUPT_RC);
4468	}
4469
4470
4471	/* -+- timers -+- */
4472
4473	uint64_t cpu_get_tsc(CPUX86State *env)
4474	{
4475	STAM_COUNTER_INC(&gStatCpuGetTSC);
4476	return TMCpuTickGet(env->pVCpu);
4477	}
4478
4479
4480	/* -+- interrupts -+- */
4481
4482	void cpu_set_ferr(CPUX86State *env)
4483	{
4484	int rc = PDMIsaSetIrq(env->pVM, 13, 1, 0 /uTagSrc/);
4485	LogFlow(("cpu_set_ferr: rc=%d\n", rc)); NOREF(rc);
4486	}
4487
4488	int cpu_get_pic_interrupt(CPUX86State *env)
4489	{
4490	uint8_t u8Interrupt;
4491	int rc;
4492
4493	/* When we fail to forward interrupts directly in raw mode, we fall back to the recompiler.
4494	* In that case we can't call PDMGetInterrupt anymore, because it has already cleared the interrupt
4495	* with the (a)pic.
4496	*/
4497	/* Note! We assume we will go directly to the recompiler to handle the pending interrupt! */
4498	/** @todo r=bird: In the long run we should just do the interrupt handling in EM/CPUM/TRPM/somewhere and
4499	* if we cannot execute the interrupt handler in raw-mode just reschedule to REM. Once that is done we
4500	* remove this kludge. */
4501	if (env->pVM->rem.s.u32PendingInterrupt != REM_NO_PENDING_IRQ)
4502	{
4503	rc = VINF_SUCCESS;
4504	Assert(env->pVM->rem.s.u32PendingInterrupt <= 255);
4505	u8Interrupt = env->pVM->rem.s.u32PendingInterrupt;
4506	env->pVM->rem.s.u32PendingInterrupt = REM_NO_PENDING_IRQ;
4507	}
4508	else
4509	rc = PDMGetInterrupt(env->pVCpu, &u8Interrupt);
4510
4511	LogFlow(("cpu_get_pic_interrupt: u8Interrupt=%d rc=%Rrc pc=%04x:%08llx ~flags=%08llx\n",
4512	u8Interrupt, rc, env->segs[R_CS].selector, (uint64_t)env->eip, (uint64_t)env->eflags));
4513	if (RT_SUCCESS(rc))
4514	{
4515	if (VMCPU_FF_ISPENDING(env->pVCpu, VMCPU_FF_INTERRUPT_APIC \| VMCPU_FF_INTERRUPT_PIC))
4516	env->interrupt_request \|= CPU_INTERRUPT_HARD;
4517	return u8Interrupt;
4518	}
4519	return -1;
4520	}
4521
4522
4523	/* -+- local apic -+- */
4524
4525	#if 0 /* CPUMSetGuestMsr does this now. */
4526	void cpu_set_apic_base(CPUX86State *env, uint64_t val)
4527	{
4528	int rc = PDMApicSetBase(env->pVM, val);
4529	LogFlow(("cpu_set_apic_base: val=%#llx rc=%Rrc\n", val, rc)); NOREF(rc);
4530	}
4531	#endif
4532
4533	uint64_t cpu_get_apic_base(CPUX86State *env)
4534	{
4535	uint64_t u64;
4536	int rc = CPUMQueryGuestMsr(env->pVCpu, MSR_IA32_APICBASE, &u64);
4537	if (RT_SUCCESS(rc))
4538	{
4539	LogFlow(("cpu_get_apic_base: returns %#llx \n", u64));
4540	return u64;
4541	}
4542	LogFlow(("cpu_get_apic_base: returns 0 (rc=%Rrc)\n", rc));
4543	return 0;
4544	}
4545
4546	void cpu_set_apic_tpr(CPUX86State *env, uint8_t val)
4547	{
4548	int rc = PDMApicSetTPR(env->pVCpu, val << 4); /* cr8 bits 3-0 correspond to bits 7-4 of the task priority mmio register. */
4549	LogFlow(("cpu_set_apic_tpr: val=%#x rc=%Rrc\n", val, rc)); NOREF(rc);
4550	}
4551
4552	uint8_t cpu_get_apic_tpr(CPUX86State *env)
4553	{
4554	uint8_t u8;
4555	int rc = PDMApicGetTPR(env->pVCpu, &u8, NULL);
4556	if (RT_SUCCESS(rc))
4557	{
4558	LogFlow(("cpu_get_apic_tpr: returns %#x\n", u8));
4559	return u8 >> 4; /* cr8 bits 3-0 correspond to bits 7-4 of the task priority mmio register. */
4560	}
4561	LogFlow(("cpu_get_apic_tpr: returns 0 (rc=%Rrc)\n", rc));
4562	return 0;
4563	}
4564
4565	/**
4566	* Read an MSR.
4567	*
4568	* @retval 0 success.
4569	* @retval -1 failure, raise \#GP(0).
4570	* @param env The cpu state.
4571	* @param idMsr The MSR to read.
4572	* @param puValue Where to return the value.
4573	*/
4574	int cpu_rdmsr(CPUX86State env, uint32_t idMsr, uint64_t puValue)
4575	{
4576	Assert(env->pVCpu);
4577	return CPUMQueryGuestMsr(env->pVCpu, idMsr, puValue) == VINF_SUCCESS ? 0 : -1;
4578	}
4579
4580	/**
4581	* Write to an MSR.
4582	*
4583	* @retval 0 success.
4584	* @retval -1 failure, raise \#GP(0).
4585	* @param env The cpu state.
4586	* @param idMsr The MSR to read.
4587	* @param puValue Where to return the value.
4588	*/
4589	int cpu_wrmsr(CPUX86State *env, uint32_t idMsr, uint64_t uValue)
4590	{
4591	Assert(env->pVCpu);
4592	return CPUMSetGuestMsr(env->pVCpu, idMsr, uValue) == VINF_SUCCESS ? 0 : -1;
4593	}
4594
4595	/* -+- I/O Ports -+- */
4596
4597	#undef LOG_GROUP
4598	#define LOG_GROUP LOG_GROUP_REM_IOPORT
4599
4600	void cpu_outb(CPUX86State *env, pio_addr_t addr, uint8_t val)
4601	{
4602	int rc;
4603
4604	if (addr != 0x80 && addr != 0x70 && addr != 0x61)
4605	Log2(("cpu_outb: addr=%#06x val=%#x\n", addr, val));
4606
4607	rc = IOMIOPortWrite(env->pVM, env->pVCpu, (RTIOPORT)addr, val, 1);
4608	if (RT_LIKELY(rc == VINF_SUCCESS))
4609	return;
4610	if (rc >= VINF_EM_FIRST && rc <= VINF_EM_LAST)
4611	{
4612	Log(("cpu_outb: addr=%#06x val=%#x -> %Rrc\n", addr, val, rc));
4613	remR3RaiseRC(env->pVM, rc);
4614	return;
4615	}
4616	remAbort(rc, __FUNCTION__);
4617	}
4618
4619	void cpu_outw(CPUX86State *env, pio_addr_t addr, uint16_t val)
4620	{
4621	//Log2(("cpu_outw: addr=%#06x val=%#x\n", addr, val));
4622	int rc = IOMIOPortWrite(env->pVM, env->pVCpu, (RTIOPORT)addr, val, 2);
4623	if (RT_LIKELY(rc == VINF_SUCCESS))
4624	return;
4625	if (rc >= VINF_EM_FIRST && rc <= VINF_EM_LAST)
4626	{
4627	Log(("cpu_outw: addr=%#06x val=%#x -> %Rrc\n", addr, val, rc));
4628	remR3RaiseRC(env->pVM, rc);
4629	return;
4630	}
4631	remAbort(rc, __FUNCTION__);
4632	}
4633
4634	void cpu_outl(CPUX86State *env, pio_addr_t addr, uint32_t val)
4635	{
4636	int rc;
4637	Log2(("cpu_outl: addr=%#06x val=%#x\n", addr, val));
4638	rc = IOMIOPortWrite(env->pVM, env->pVCpu, (RTIOPORT)addr, val, 4);
4639	if (RT_LIKELY(rc == VINF_SUCCESS))
4640	return;
4641	if (rc >= VINF_EM_FIRST && rc <= VINF_EM_LAST)
4642	{
4643	Log(("cpu_outl: addr=%#06x val=%#x -> %Rrc\n", addr, val, rc));
4644	remR3RaiseRC(env->pVM, rc);
4645	return;
4646	}
4647	remAbort(rc, __FUNCTION__);
4648	}
4649
4650	uint8_t cpu_inb(CPUX86State *env, pio_addr_t addr)
4651	{
4652	uint32_t u32 = 0;
4653	int rc = IOMIOPortRead(env->pVM, env->pVCpu, (RTIOPORT)addr, &u32, 1);
4654	if (RT_LIKELY(rc == VINF_SUCCESS))
4655	{
4656	if (/addr != 0x61 && /addr != 0x71)
4657	Log2(("cpu_inb: addr=%#06x -> %#x\n", addr, u32));
4658	return (uint8_t)u32;
4659	}
4660	if (rc >= VINF_EM_FIRST && rc <= VINF_EM_LAST)
4661	{
4662	Log(("cpu_inb: addr=%#06x -> %#x rc=%Rrc\n", addr, u32, rc));
4663	remR3RaiseRC(env->pVM, rc);
4664	return (uint8_t)u32;
4665	}
4666	remAbort(rc, __FUNCTION__);
4667	return UINT8_C(0xff);
4668	}
4669
4670	uint16_t cpu_inw(CPUX86State *env, pio_addr_t addr)
4671	{
4672	uint32_t u32 = 0;
4673	int rc = IOMIOPortRead(env->pVM, env->pVCpu, (RTIOPORT)addr, &u32, 2);
4674	if (RT_LIKELY(rc == VINF_SUCCESS))
4675	{
4676	Log2(("cpu_inw: addr=%#06x -> %#x\n", addr, u32));
4677	return (uint16_t)u32;
4678	}
4679	if (rc >= VINF_EM_FIRST && rc <= VINF_EM_LAST)
4680	{
4681	Log(("cpu_inw: addr=%#06x -> %#x rc=%Rrc\n", addr, u32, rc));
4682	remR3RaiseRC(env->pVM, rc);
4683	return (uint16_t)u32;
4684	}
4685	remAbort(rc, __FUNCTION__);
4686	return UINT16_C(0xffff);
4687	}
4688
4689	uint32_t cpu_inl(CPUX86State *env, pio_addr_t addr)
4690	{
4691	uint32_t u32 = 0;
4692	int rc = IOMIOPortRead(env->pVM, env->pVCpu, (RTIOPORT)addr, &u32, 4);
4693	if (RT_LIKELY(rc == VINF_SUCCESS))
4694	{
4695	//if (addr==0x01f0 && u32 == 0x6b6d)
4696	// loglevel = ~0;
4697	Log2(("cpu_inl: addr=%#06x -> %#x\n", addr, u32));
4698	return u32;
4699	}
4700	if (rc >= VINF_EM_FIRST && rc <= VINF_EM_LAST)
4701	{
4702	Log(("cpu_inl: addr=%#06x -> %#x rc=%Rrc\n", addr, u32, rc));
4703	remR3RaiseRC(env->pVM, rc);
4704	return u32;
4705	}
4706	remAbort(rc, __FUNCTION__);
4707	return UINT32_C(0xffffffff);
4708	}
4709
4710	#undef LOG_GROUP
4711	#define LOG_GROUP LOG_GROUP_REM
4712
4713
4714	/* -+- helpers and misc other interfaces -+- */
4715
4716	/**
4717	* Perform the CPUID instruction.
4718	*
4719	* @param env Pointer to the recompiler CPU structure.
4720	* @param idx The CPUID leaf (eax).
4721	* @param idxSub The CPUID sub-leaf (ecx) where applicable.
4722	* @param pvEAX Where to store eax.
4723	* @param pvEBX Where to store ebx.
4724	* @param pvECX Where to store ecx.
4725	* @param pvEDX Where to store edx.
4726	*/
4727	void cpu_x86_cpuid(CPUX86State *env, uint32_t idx, uint32_t idxSub,
4728	uint32_t pEAX, uint32_t pEBX, uint32_t pECX, uint32_t pEDX)
4729	{
4730	NOREF(idxSub);
4731	CPUMGetGuestCpuId(env->pVCpu, idx, pEAX, pEBX, pECX, pEDX);
4732	}
4733
4734
4735	#if 0 /* not used */
4736	/**
4737	* Interface for qemu hardware to report back fatal errors.
4738	*/
4739	void hw_error(const char *pszFormat, ...)
4740	{
4741	/*
4742	* Bitch about it.
4743	*/
4744	/** @todo Add support for nested arg lists in the LogPrintfV routine! I've code for
4745	* this in my Odin32 tree at home! */
4746	va_list args;
4747	va_start(args, pszFormat);
4748	RTLogPrintf("fatal error in virtual hardware:");
4749	RTLogPrintfV(pszFormat, args);
4750	va_end(args);
4751	AssertReleaseMsgFailed(("fatal error in virtual hardware: %s\n", pszFormat));
4752
4753	/*
4754	* If we're in REM context we'll sync back the state before 'jumping' to
4755	* the EMs failure handling.
4756	*/
4757	PVM pVM = cpu_single_env->pVM;
4758	if (pVM->rem.s.fInREM)
4759	REMR3StateBack(pVM);
4760	EMR3FatalError(pVM, VERR_REM_VIRTUAL_HARDWARE_ERROR);
4761	AssertMsgFailed(("EMR3FatalError returned!\n"));
4762	}
4763	#endif
4764
4765	/**
4766	* Interface for the qemu cpu to report unhandled situation
4767	* raising a fatal VM error.
4768	*/
4769	void cpu_abort(CPUX86State env, const char pszFormat, ...)
4770	{
4771	va_list va;
4772	PVM pVM;
4773	PVMCPU pVCpu;
4774	char szMsg[256];
4775
4776	/*
4777	* Bitch about it.
4778	*/
4779	RTLogFlags(NULL, "nodisabled nobuffered");
4780	RTLogFlush(NULL);
4781
4782	va_start(va, pszFormat);
4783	#if defined(RT_OS_WINDOWS) && ARCH_BITS == 64
4784	/* It's a bit complicated when mixing MSC and GCC on AMD64. This is a bit ugly, but it works. */
4785	unsigned cArgs = 0;
4786	uintptr_t auArgs[6] = {0,0,0,0,0,0};
4787	const char *psz = strchr(pszFormat, '%');
4788	while (psz && cArgs < 6)
4789	{
4790	auArgs[cArgs++] = va_arg(va, uintptr_t);
4791	psz = strchr(psz + 1, '%');
4792	}
4793	switch (cArgs)
4794	{
4795	case 1: RTStrPrintf(szMsg, sizeof(szMsg), pszFormat, auArgs[0]); break;
4796	case 2: RTStrPrintf(szMsg, sizeof(szMsg), pszFormat, auArgs[0], auArgs[1]); break;
4797	case 3: RTStrPrintf(szMsg, sizeof(szMsg), pszFormat, auArgs[0], auArgs[1], auArgs[2]); break;
4798	case 4: RTStrPrintf(szMsg, sizeof(szMsg), pszFormat, auArgs[0], auArgs[1], auArgs[2], auArgs[3]); break;
4799	case 5: RTStrPrintf(szMsg, sizeof(szMsg), pszFormat, auArgs[0], auArgs[1], auArgs[2], auArgs[3], auArgs[4]); break;
4800	case 6: RTStrPrintf(szMsg, sizeof(szMsg), pszFormat, auArgs[0], auArgs[1], auArgs[2], auArgs[3], auArgs[4], auArgs[5]); break;
4801	default:
4802	case 0: RTStrPrintf(szMsg, sizeof(szMsg), "%s", pszFormat); break;
4803	}
4804	#else
4805	RTStrPrintfV(szMsg, sizeof(szMsg), pszFormat, va);
4806	#endif
4807	va_end(va);
4808
4809	RTLogPrintf("fatal error in recompiler cpu: %s\n", szMsg);
4810	RTLogRelPrintf("fatal error in recompiler cpu: %s\n", szMsg);
4811
4812	/*
4813	* If we're in REM context we'll sync back the state before 'jumping' to
4814	* the EMs failure handling.
4815	*/
4816	pVM = cpu_single_env->pVM;
4817	pVCpu = cpu_single_env->pVCpu;
4818	Assert(pVCpu);
4819
4820	if (pVM->rem.s.fInREM)
4821	REMR3StateBack(pVM, pVCpu);
4822	EMR3FatalError(pVCpu, VERR_REM_VIRTUAL_CPU_ERROR);
4823	AssertMsgFailed(("EMR3FatalError returned!\n"));
4824	}
4825
4826
4827	/**
4828	* Aborts the VM.
4829	*
4830	* @param rc VBox error code.
4831	* @param pszTip Hint about why/when this happened.
4832	*/
4833	void remAbort(int rc, const char *pszTip)
4834	{
4835	PVM pVM;
4836	PVMCPU pVCpu;
4837
4838	/*
4839	* Bitch about it.
4840	*/
4841	RTLogPrintf("internal REM fatal error: rc=%Rrc %s\n", rc, pszTip);
4842	AssertReleaseMsgFailed(("internal REM fatal error: rc=%Rrc %s\n", rc, pszTip));
4843
4844	/*
4845	* Jump back to where we entered the recompiler.
4846	*/
4847	pVM = cpu_single_env->pVM;
4848	pVCpu = cpu_single_env->pVCpu;
4849	Assert(pVCpu);
4850
4851	if (pVM->rem.s.fInREM)
4852	REMR3StateBack(pVM, pVCpu);
4853
4854	EMR3FatalError(pVCpu, rc);
4855	AssertMsgFailed(("EMR3FatalError returned!\n"));
4856	}
4857
4858
4859	/**
4860	* Dumps a linux system call.
4861	* @param pVCpu VMCPU handle.
4862	*/
4863	void remR3DumpLnxSyscall(PVMCPU pVCpu)
4864	{
4865	static const char *apsz[] =
4866	{
4867	"sys_restart_syscall", /* 0 - old "setup()" system call, used for restarting */
4868	"sys_exit",
4869	"sys_fork",
4870	"sys_read",
4871	"sys_write",
4872	"sys_open", /* 5 */
4873	"sys_close",
4874	"sys_waitpid",
4875	"sys_creat",
4876	"sys_link",
4877	"sys_unlink", /* 10 */
4878	"sys_execve",
4879	"sys_chdir",
4880	"sys_time",
4881	"sys_mknod",
4882	"sys_chmod", /* 15 */
4883	"sys_lchown16",
4884	"sys_ni_syscall", /* old break syscall holder */
4885	"sys_stat",
4886	"sys_lseek",
4887	"sys_getpid", /* 20 */
4888	"sys_mount",
4889	"sys_oldumount",
4890	"sys_setuid16",
4891	"sys_getuid16",
4892	"sys_stime", /* 25 */
4893	"sys_ptrace",
4894	"sys_alarm",
4895	"sys_fstat",
4896	"sys_pause",
4897	"sys_utime", /* 30 */
4898	"sys_ni_syscall", /* old stty syscall holder */
4899	"sys_ni_syscall", /* old gtty syscall holder */
4900	"sys_access",
4901	"sys_nice",
4902	"sys_ni_syscall", /* 35 - old ftime syscall holder */
4903	"sys_sync",
4904	"sys_kill",
4905	"sys_rename",
4906	"sys_mkdir",
4907	"sys_rmdir", /* 40 */
4908	"sys_dup",
4909	"sys_pipe",
4910	"sys_times",
4911	"sys_ni_syscall", /* old prof syscall holder */
4912	"sys_brk", /* 45 */
4913	"sys_setgid16",
4914	"sys_getgid16",
4915	"sys_signal",
4916	"sys_geteuid16",
4917	"sys_getegid16", /* 50 */
4918	"sys_acct",
4919	"sys_umount", /* recycled never used phys() */
4920	"sys_ni_syscall", /* old lock syscall holder */
4921	"sys_ioctl",
4922	"sys_fcntl", /* 55 */
4923	"sys_ni_syscall", /* old mpx syscall holder */
4924	"sys_setpgid",
4925	"sys_ni_syscall", /* old ulimit syscall holder */
4926	"sys_olduname",
4927	"sys_umask", /* 60 */
4928	"sys_chroot",
4929	"sys_ustat",
4930	"sys_dup2",
4931	"sys_getppid",
4932	"sys_getpgrp", /* 65 */
4933	"sys_setsid",
4934	"sys_sigaction",
4935	"sys_sgetmask",
4936	"sys_ssetmask",
4937	"sys_setreuid16", /* 70 */
4938	"sys_setregid16",
4939	"sys_sigsuspend",
4940	"sys_sigpending",
4941	"sys_sethostname",
4942	"sys_setrlimit", /* 75 */
4943	"sys_old_getrlimit",
4944	"sys_getrusage",
4945	"sys_gettimeofday",
4946	"sys_settimeofday",
4947	"sys_getgroups16", /* 80 */
4948	"sys_setgroups16",
4949	"old_select",
4950	"sys_symlink",
4951	"sys_lstat",
4952	"sys_readlink", /* 85 */
4953	"sys_uselib",
4954	"sys_swapon",
4955	"sys_reboot",
4956	"old_readdir",
4957	"old_mmap", /* 90 */
4958	"sys_munmap",
4959	"sys_truncate",
4960	"sys_ftruncate",
4961	"sys_fchmod",
4962	"sys_fchown16", /* 95 */
4963	"sys_getpriority",
4964	"sys_setpriority",
4965	"sys_ni_syscall", /* old profil syscall holder */
4966	"sys_statfs",
4967	"sys_fstatfs", /* 100 */
4968	"sys_ioperm",
4969	"sys_socketcall",
4970	"sys_syslog",
4971	"sys_setitimer",
4972	"sys_getitimer", /* 105 */
4973	"sys_newstat",
4974	"sys_newlstat",
4975	"sys_newfstat",
4976	"sys_uname",
4977	"sys_iopl", /* 110 */
4978	"sys_vhangup",
4979	"sys_ni_syscall", /* old "idle" system call */
4980	"sys_vm86old",
4981	"sys_wait4",
4982	"sys_swapoff", /* 115 */
4983	"sys_sysinfo",
4984	"sys_ipc",
4985	"sys_fsync",
4986	"sys_sigreturn",
4987	"sys_clone", /* 120 */
4988	"sys_setdomainname",
4989	"sys_newuname",
4990	"sys_modify_ldt",
4991	"sys_adjtimex",
4992	"sys_mprotect", /* 125 */
4993	"sys_sigprocmask",
4994	"sys_ni_syscall", /* old "create_module" */
4995	"sys_init_module",
4996	"sys_delete_module",
4997	"sys_ni_syscall", /* 130: old "get_kernel_syms" */
4998	"sys_quotactl",
4999	"sys_getpgid",
5000	"sys_fchdir",
5001	"sys_bdflush",
5002	"sys_sysfs", /* 135 */
5003	"sys_personality",
5004	"sys_ni_syscall", /* reserved for afs_syscall */
5005	"sys_setfsuid16",
5006	"sys_setfsgid16",
5007	"sys_llseek", /* 140 */
5008	"sys_getdents",
5009	"sys_select",
5010	"sys_flock",
5011	"sys_msync",
5012	"sys_readv", /* 145 */
5013	"sys_writev",
5014	"sys_getsid",
5015	"sys_fdatasync",
5016	"sys_sysctl",
5017	"sys_mlock", /* 150 */
5018	"sys_munlock",
5019	"sys_mlockall",
5020	"sys_munlockall",
5021	"sys_sched_setparam",
5022	"sys_sched_getparam", /* 155 */
5023	"sys_sched_setscheduler",
5024	"sys_sched_getscheduler",
5025	"sys_sched_yield",
5026	"sys_sched_get_priority_max",
5027	"sys_sched_get_priority_min", /* 160 */
5028	"sys_sched_rr_get_interval",
5029	"sys_nanosleep",
5030	"sys_mremap",
5031	"sys_setresuid16",
5032	"sys_getresuid16", /* 165 */
5033	"sys_vm86",
5034	"sys_ni_syscall", /* Old sys_query_module */
5035	"sys_poll",
5036	"sys_nfsservctl",
5037	"sys_setresgid16", /* 170 */
5038	"sys_getresgid16",
5039	"sys_prctl",
5040	"sys_rt_sigreturn",
5041	"sys_rt_sigaction",
5042	"sys_rt_sigprocmask", /* 175 */
5043	"sys_rt_sigpending",
5044	"sys_rt_sigtimedwait",
5045	"sys_rt_sigqueueinfo",
5046	"sys_rt_sigsuspend",
5047	"sys_pread64", /* 180 */
5048	"sys_pwrite64",
5049	"sys_chown16",
5050	"sys_getcwd",
5051	"sys_capget",
5052	"sys_capset", /* 185 */
5053	"sys_sigaltstack",
5054	"sys_sendfile",
5055	"sys_ni_syscall", /* reserved for streams1 */
5056	"sys_ni_syscall", /* reserved for streams2 */
5057	"sys_vfork", /* 190 */
5058	"sys_getrlimit",
5059	"sys_mmap2",
5060	"sys_truncate64",
5061	"sys_ftruncate64",
5062	"sys_stat64", /* 195 */
5063	"sys_lstat64",
5064	"sys_fstat64",
5065	"sys_lchown",
5066	"sys_getuid",
5067	"sys_getgid", /* 200 */
5068	"sys_geteuid",
5069	"sys_getegid",
5070	"sys_setreuid",
5071	"sys_setregid",
5072	"sys_getgroups", /* 205 */
5073	"sys_setgroups",
5074	"sys_fchown",
5075	"sys_setresuid",
5076	"sys_getresuid",
5077	"sys_setresgid", /* 210 */
5078	"sys_getresgid",
5079	"sys_chown",
5080	"sys_setuid",
5081	"sys_setgid",
5082	"sys_setfsuid", /* 215 */
5083	"sys_setfsgid",
5084	"sys_pivot_root",
5085	"sys_mincore",
5086	"sys_madvise",
5087	"sys_getdents64", /* 220 */
5088	"sys_fcntl64",
5089	"sys_ni_syscall", /* reserved for TUX */
5090	"sys_ni_syscall",
5091	"sys_gettid",
5092	"sys_readahead", /* 225 */
5093	"sys_setxattr",
5094	"sys_lsetxattr",
5095	"sys_fsetxattr",
5096	"sys_getxattr",
5097	"sys_lgetxattr", /* 230 */
5098	"sys_fgetxattr",
5099	"sys_listxattr",
5100	"sys_llistxattr",
5101	"sys_flistxattr",
5102	"sys_removexattr", /* 235 */
5103	"sys_lremovexattr",
5104	"sys_fremovexattr",
5105	"sys_tkill",
5106	"sys_sendfile64",
5107	"sys_futex", /* 240 */
5108	"sys_sched_setaffinity",
5109	"sys_sched_getaffinity",
5110	"sys_set_thread_area",
5111	"sys_get_thread_area",
5112	"sys_io_setup", /* 245 */
5113	"sys_io_destroy",
5114	"sys_io_getevents",
5115	"sys_io_submit",
5116	"sys_io_cancel",
5117	"sys_fadvise64", /* 250 */
5118	"sys_ni_syscall",
5119	"sys_exit_group",
5120	"sys_lookup_dcookie",
5121	"sys_epoll_create",
5122	"sys_epoll_ctl", /* 255 */
5123	"sys_epoll_wait",
5124	"sys_remap_file_pages",
5125	"sys_set_tid_address",
5126	"sys_timer_create",
5127	"sys_timer_settime", /* 260 */
5128	"sys_timer_gettime",
5129	"sys_timer_getoverrun",
5130	"sys_timer_delete",
5131	"sys_clock_settime",
5132	"sys_clock_gettime", /* 265 */
5133	"sys_clock_getres",
5134	"sys_clock_nanosleep",
5135	"sys_statfs64",
5136	"sys_fstatfs64",
5137	"sys_tgkill", /* 270 */
5138	"sys_utimes",
5139	"sys_fadvise64_64",
5140	"sys_ni_syscall" /* sys_vserver */
5141	};
5142
5143	uint32_t uEAX = CPUMGetGuestEAX(pVCpu);
5144	switch (uEAX)
5145	{
5146	default:
5147	if (uEAX < RT_ELEMENTS(apsz))
5148	Log(("REM: linux syscall %3d: %s (eip=%08x ebx=%08x ecx=%08x edx=%08x esi=%08x edi=%08x ebp=%08x)\n",
5149	uEAX, apsz[uEAX], CPUMGetGuestEIP(pVCpu), CPUMGetGuestEBX(pVCpu), CPUMGetGuestECX(pVCpu),
5150	CPUMGetGuestEDX(pVCpu), CPUMGetGuestESI(pVCpu), CPUMGetGuestEDI(pVCpu), CPUMGetGuestEBP(pVCpu)));
5151	else
5152	Log(("eip=%08x: linux syscall %d (#%x) unknown\n", CPUMGetGuestEIP(pVCpu), uEAX, uEAX));
5153	break;
5154
5155	}
5156	}
5157
5158
5159	/**
5160	* Dumps an OpenBSD system call.
5161	* @param pVCpu VMCPU handle.
5162	*/
5163	void remR3DumpOBsdSyscall(PVMCPU pVCpu)
5164	{
5165	static const char *apsz[] =
5166	{
5167	"SYS_syscall", //0
5168	"SYS_exit", //1
5169	"SYS_fork", //2
5170	"SYS_read", //3
5171	"SYS_write", //4
5172	"SYS_open", //5
5173	"SYS_close", //6
5174	"SYS_wait4", //7
5175	"SYS_8",
5176	"SYS_link", //9
5177	"SYS_unlink", //10
5178	"SYS_11",
5179	"SYS_chdir", //12
5180	"SYS_fchdir", //13
5181	"SYS_mknod", //14
5182	"SYS_chmod", //15
5183	"SYS_chown", //16
5184	"SYS_break", //17
5185	"SYS_18",
5186	"SYS_19",
5187	"SYS_getpid", //20
5188	"SYS_mount", //21
5189	"SYS_unmount", //22
5190	"SYS_setuid", //23
5191	"SYS_getuid", //24
5192	"SYS_geteuid", //25
5193	"SYS_ptrace", //26
5194	"SYS_recvmsg", //27
5195	"SYS_sendmsg", //28
5196	"SYS_recvfrom", //29
5197	"SYS_accept", //30
5198	"SYS_getpeername", //31
5199	"SYS_getsockname", //32
5200	"SYS_access", //33
5201	"SYS_chflags", //34
5202	"SYS_fchflags", //35
5203	"SYS_sync", //36
5204	"SYS_kill", //37
5205	"SYS_38",
5206	"SYS_getppid", //39
5207	"SYS_40",
5208	"SYS_dup", //41
5209	"SYS_opipe", //42
5210	"SYS_getegid", //43
5211	"SYS_profil", //44
5212	"SYS_ktrace", //45
5213	"SYS_sigaction", //46
5214	"SYS_getgid", //47
5215	"SYS_sigprocmask", //48
5216	"SYS_getlogin", //49
5217	"SYS_setlogin", //50
5218	"SYS_acct", //51
5219	"SYS_sigpending", //52
5220	"SYS_osigaltstack", //53
5221	"SYS_ioctl", //54
5222	"SYS_reboot", //55
5223	"SYS_revoke", //56
5224	"SYS_symlink", //57
5225	"SYS_readlink", //58
5226	"SYS_execve", //59
5227	"SYS_umask", //60
5228	"SYS_chroot", //61
5229	"SYS_62",
5230	"SYS_63",
5231	"SYS_64",
5232	"SYS_65",
5233	"SYS_vfork", //66
5234	"SYS_67",
5235	"SYS_68",
5236	"SYS_sbrk", //69
5237	"SYS_sstk", //70
5238	"SYS_61",
5239	"SYS_vadvise", //72
5240	"SYS_munmap", //73
5241	"SYS_mprotect", //74
5242	"SYS_madvise", //75
5243	"SYS_76",
5244	"SYS_77",
5245	"SYS_mincore", //78
5246	"SYS_getgroups", //79
5247	"SYS_setgroups", //80
5248	"SYS_getpgrp", //81
5249	"SYS_setpgid", //82
5250	"SYS_setitimer", //83
5251	"SYS_84",
5252	"SYS_85",
5253	"SYS_getitimer", //86
5254	"SYS_87",
5255	"SYS_88",
5256	"SYS_89",
5257	"SYS_dup2", //90
5258	"SYS_91",
5259	"SYS_fcntl", //92
5260	"SYS_select", //93
5261	"SYS_94",
5262	"SYS_fsync", //95
5263	"SYS_setpriority", //96
5264	"SYS_socket", //97
5265	"SYS_connect", //98
5266	"SYS_99",
5267	"SYS_getpriority", //100
5268	"SYS_101",
5269	"SYS_102",
5270	"SYS_sigreturn", //103
5271	"SYS_bind", //104
5272	"SYS_setsockopt", //105
5273	"SYS_listen", //106
5274	"SYS_107",
5275	"SYS_108",
5276	"SYS_109",
5277	"SYS_110",
5278	"SYS_sigsuspend", //111
5279	"SYS_112",
5280	"SYS_113",
5281	"SYS_114",
5282	"SYS_115",
5283	"SYS_gettimeofday", //116
5284	"SYS_getrusage", //117
5285	"SYS_getsockopt", //118
5286	"SYS_119",
5287	"SYS_readv", //120
5288	"SYS_writev", //121
5289	"SYS_settimeofday", //122
5290	"SYS_fchown", //123
5291	"SYS_fchmod", //124
5292	"SYS_125",
5293	"SYS_setreuid", //126
5294	"SYS_setregid", //127
5295	"SYS_rename", //128
5296	"SYS_129",
5297	"SYS_130",
5298	"SYS_flock", //131
5299	"SYS_mkfifo", //132
5300	"SYS_sendto", //133
5301	"SYS_shutdown", //134
5302	"SYS_socketpair", //135
5303	"SYS_mkdir", //136
5304	"SYS_rmdir", //137
5305	"SYS_utimes", //138
5306	"SYS_139",
5307	"SYS_adjtime", //140
5308	"SYS_141",
5309	"SYS_142",
5310	"SYS_143",
5311	"SYS_144",
5312	"SYS_145",
5313	"SYS_146",
5314	"SYS_setsid", //147
5315	"SYS_quotactl", //148
5316	"SYS_149",
5317	"SYS_150",
5318	"SYS_151",
5319	"SYS_152",
5320	"SYS_153",
5321	"SYS_154",
5322	"SYS_nfssvc", //155
5323	"SYS_156",
5324	"SYS_157",
5325	"SYS_158",
5326	"SYS_159",
5327	"SYS_160",
5328	"SYS_getfh", //161
5329	"SYS_162",
5330	"SYS_163",
5331	"SYS_164",
5332	"SYS_sysarch", //165
5333	"SYS_166",
5334	"SYS_167",
5335	"SYS_168",
5336	"SYS_169",
5337	"SYS_170",
5338	"SYS_171",
5339	"SYS_172",
5340	"SYS_pread", //173
5341	"SYS_pwrite", //174
5342	"SYS_175",
5343	"SYS_176",
5344	"SYS_177",
5345	"SYS_178",
5346	"SYS_179",
5347	"SYS_180",
5348	"SYS_setgid", //181
5349	"SYS_setegid", //182
5350	"SYS_seteuid", //183
5351	"SYS_lfs_bmapv", //184
5352	"SYS_lfs_markv", //185
5353	"SYS_lfs_segclean", //186
5354	"SYS_lfs_segwait", //187
5355	"SYS_188",
5356	"SYS_189",
5357	"SYS_190",
5358	"SYS_pathconf", //191
5359	"SYS_fpathconf", //192
5360	"SYS_swapctl", //193
5361	"SYS_getrlimit", //194
5362	"SYS_setrlimit", //195
5363	"SYS_getdirentries", //196
5364	"SYS_mmap", //197
5365	"SYS___syscall", //198
5366	"SYS_lseek", //199
5367	"SYS_truncate", //200
5368	"SYS_ftruncate", //201
5369	"SYS___sysctl", //202
5370	"SYS_mlock", //203
5371	"SYS_munlock", //204
5372	"SYS_205",
5373	"SYS_futimes", //206
5374	"SYS_getpgid", //207
5375	"SYS_xfspioctl", //208
5376	"SYS_209",
5377	"SYS_210",
5378	"SYS_211",
5379	"SYS_212",
5380	"SYS_213",
5381	"SYS_214",
5382	"SYS_215",
5383	"SYS_216",
5384	"SYS_217",
5385	"SYS_218",
5386	"SYS_219",
5387	"SYS_220",
5388	"SYS_semget", //221
5389	"SYS_222",
5390	"SYS_223",
5391	"SYS_224",
5392	"SYS_msgget", //225
5393	"SYS_msgsnd", //226
5394	"SYS_msgrcv", //227
5395	"SYS_shmat", //228
5396	"SYS_229",
5397	"SYS_shmdt", //230
5398	"SYS_231",
5399	"SYS_clock_gettime", //232
5400	"SYS_clock_settime", //233
5401	"SYS_clock_getres", //234
5402	"SYS_235",
5403	"SYS_236",
5404	"SYS_237",
5405	"SYS_238",
5406	"SYS_239",
5407	"SYS_nanosleep", //240
5408	"SYS_241",
5409	"SYS_242",
5410	"SYS_243",
5411	"SYS_244",
5412	"SYS_245",
5413	"SYS_246",
5414	"SYS_247",
5415	"SYS_248",
5416	"SYS_249",
5417	"SYS_minherit", //250
5418	"SYS_rfork", //251
5419	"SYS_poll", //252
5420	"SYS_issetugid", //253
5421	"SYS_lchown", //254
5422	"SYS_getsid", //255
5423	"SYS_msync", //256
5424	"SYS_257",
5425	"SYS_258",
5426	"SYS_259",
5427	"SYS_getfsstat", //260
5428	"SYS_statfs", //261
5429	"SYS_fstatfs", //262
5430	"SYS_pipe", //263
5431	"SYS_fhopen", //264
5432	"SYS_265",
5433	"SYS_fhstatfs", //266
5434	"SYS_preadv", //267
5435	"SYS_pwritev", //268
5436	"SYS_kqueue", //269
5437	"SYS_kevent", //270
5438	"SYS_mlockall", //271
5439	"SYS_munlockall", //272
5440	"SYS_getpeereid", //273
5441	"SYS_274",
5442	"SYS_275",
5443	"SYS_276",
5444	"SYS_277",
5445	"SYS_278",
5446	"SYS_279",
5447	"SYS_280",
5448	"SYS_getresuid", //281
5449	"SYS_setresuid", //282
5450	"SYS_getresgid", //283
5451	"SYS_setresgid", //284
5452	"SYS_285",
5453	"SYS_mquery", //286
5454	"SYS_closefrom", //287
5455	"SYS_sigaltstack", //288
5456	"SYS_shmget", //289
5457	"SYS_semop", //290
5458	"SYS_stat", //291
5459	"SYS_fstat", //292
5460	"SYS_lstat", //293
5461	"SYS_fhstat", //294
5462	"SYS___semctl", //295
5463	"SYS_shmctl", //296
5464	"SYS_msgctl", //297
5465	"SYS_MAXSYSCALL", //298
5466	//299
5467	//300
5468	};
5469	uint32_t uEAX;
5470	if (!LogIsEnabled())
5471	return;
5472	uEAX = CPUMGetGuestEAX(pVCpu);
5473	switch (uEAX)
5474	{
5475	default:
5476	if (uEAX < RT_ELEMENTS(apsz))
5477	{
5478	uint32_t au32Args[8] = {0};
5479	PGMPhysSimpleReadGCPtr(pVCpu, au32Args, CPUMGetGuestESP(pVCpu), sizeof(au32Args));
5480	RTLogPrintf("REM: OpenBSD syscall %3d: %s (eip=%08x %08x %08x %08x %08x %08x %08x %08x %08x)\n",
5481	uEAX, apsz[uEAX], CPUMGetGuestEIP(pVCpu), au32Args[0], au32Args[1], au32Args[2], au32Args[3],
5482	au32Args[4], au32Args[5], au32Args[6], au32Args[7]);
5483	}
5484	else
5485	RTLogPrintf("eip=%08x: OpenBSD syscall %d (#%x) unknown!!\n", CPUMGetGuestEIP(pVCpu), uEAX, uEAX);
5486	break;
5487	}
5488	}
5489
5490
5491	#if defined(IPRT_NO_CRT) && defined(RT_OS_WINDOWS) && defined(RT_ARCH_X86)
5492	/**
5493	* The Dll main entry point (stub).
5494	*/
5495	bool __stdcall _DllMainCRTStartup(void hModule, uint32_t dwReason, void pvReserved)
5496	{
5497	return true;
5498	}
5499
5500	void memcpy(void dst, const void *src, size_t size)
5501	{
5502	uint8_tpbDst = dst, pbSrc = src;
5503	while (size-- > 0)
5504	pbDst++ = pbSrc++;
5505	return dst;
5506	}
5507
5508	#endif
5509
5510	void cpu_smm_update(CPUX86State *env)
5511	{
5512	}

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source: vbox/trunk/src/recompiler/VBoxRecompiler.c@ 45727

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