VMM.cpp@ 7692

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1	/* $Id: VMM.cpp 7616 2008-03-28 08:47:21Z vboxsync $ */
2	/** @file
3	* VMM - The Virtual Machine Monitor Core.
4	*/
5
6	/*
7	* Copyright (C) 2006-2007 innotek GmbH
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	//#define NO_SUPCALLR0VMM
19
20	/** @page pg_vmm VMM - The Virtual Machine Monitor
21	*
22	* !Revise this! It's already incorrect!
23	*
24	* The Virtual Machine Monitor (VMM) is the core of the virtual machine. It
25	* manages the alternate reality; controlling the virtualization, managing
26	* resources, tracking CPU state, it's resources and so on...
27	*
28	* We will split the VMM into smaller entities:
29	*
30	* - Virtual Machine Core Monitor (VMCM), which purpose it is to
31	* provide ring and world switching, that including routing
32	* interrupts to the host OS and traps to the appropriate trap
33	* handlers. It will implement an external interface for
34	* managing trap handlers.
35	*
36	* - CPU Monitor (CM), tracking the state of the CPU (in the alternate
37	* reality) and implementing external interfaces to read and change
38	* the state.
39	*
40	* - Memory Monitor (MM), which purpose it is to virtualize physical
41	* pages, segment descriptor tables, interrupt descriptor tables, task
42	* segments, and keep track of all memory providing external interfaces
43	* to access content and map pages. (Internally splitt into smaller entities!)
44	*
45	* - IO Monitor (IOM), which virtualizes in and out I/O operations. It
46	* interacts with the MM to implement memory mapped I/O. External
47	* interfaces for adding and removing I/O ranges are implemented.
48	*
49	* - External Interrupt Monitor (EIM), which purpose it is to manage
50	* interrupts generated by virtual devices. This monitor provides
51	* an interfaces for raising interrupts which is accessible at any
52	* time and from all thread.
53	* <p>
54	* A subentity of the EIM is the vitual Programmable Interrupt
55	* Controller Device (VPICD), and perhaps a virtual I/O Advanced
56	* Programmable Interrupt Controller Device (VAPICD).
57	*
58	* - Direct Memory Access Monitor (DMAM), which purpose it is to support
59	* virtual device using the DMA controller. Interfaces must be as the
60	* EIM interfaces independent and threadable.
61	* <p>
62	* A subentity of the DMAM is a virtual DMA Controller Device (VDMACD).
63	*
64	*
65	* Entities working on a higher level:
66	*
67	* - Device Manager (DM), which is a support facility for virtualized
68	* hardware. This provides generic facilities for efficient device
69	* virtualization. It will manage device attaching and detaching
70	* conversing with EIM and IOM.
71	*
72	* - Debugger Facility (DBGF) provides the basic features for
73	* debugging the alternate reality execution.
74	*
75	*
76	*
77	* @section pg_vmm_s_use_cases Use Cases
78	*
79	* @subsection pg_vmm_s_use_case_boot Bootstrap
80	*
81	* - Basic Init:
82	* - Init SUPDRV.
83	*
84	* - Init Virtual Machine Instance:
85	* - Load settings.
86	* - Check resource requirements (memory, com, stuff).
87	*
88	* - Init Host Ring 3 part:
89	* - Init Core code.
90	* - Load Pluggable Components.
91	* - Init Pluggable Components.
92	*
93	* - Init Host Ring 0 part:
94	* - Load Core (core = core components like VMM, RMI, CA, and so on) code.
95	* - Init Core code.
96	* - Load Pluggable Component code.
97	* - Init Pluggable Component code.
98	*
99	* - Allocate first chunk of memory and pin it down. This block of memory
100	* will fit the following pieces:
101	* - Virtual Machine Instance data. (Config, CPU state, VMM state, ++)
102	* (This is available from everywhere (at different addresses though)).
103	* - VMM Guest Context code.
104	* - Pluggable devices Guest Context code.
105	* - Page tables (directory and everything) for the VMM Guest
106	*
107	* - Setup Guest (Ring 0) part:
108	* - Setup initial page tables (i.e. directory all the stuff).
109	* - Load Core Guest Context code.
110	* - Load Pluggable Devices Guest Context code.
111	*
112	*
113	*/
114
115
116	/*******************************************************************************
117	* Header Files *
118	*******************************************************************************/
119	#define LOG_GROUP LOG_GROUP_VMM
120	#include <VBox/vmm.h>
121	#include <VBox/vmapi.h>
122	#include <VBox/pgm.h>
123	#include <VBox/cfgm.h>
124	#include <VBox/pdmqueue.h>
125	#include <VBox/pdmapi.h>
126	#include <VBox/cpum.h>
127	#include <VBox/mm.h>
128	#include <VBox/iom.h>
129	#include <VBox/trpm.h>
130	#include <VBox/selm.h>
131	#include <VBox/em.h>
132	#include <VBox/sup.h>
133	#include <VBox/dbgf.h>
134	#include <VBox/csam.h>
135	#include <VBox/patm.h>
136	#include <VBox/rem.h>
137	#include <VBox/ssm.h>
138	#include <VBox/tm.h>
139	#include "VMMInternal.h"
140	#include "VMMSwitcher/VMMSwitcher.h"
141	#include <VBox/vm.h>
142	#include <VBox/err.h>
143	#include <VBox/param.h>
144	#include <VBox/version.h>
145	#include <VBox/x86.h>
146	#include <VBox/hwaccm.h>
147	#include <iprt/assert.h>
148	#include <iprt/alloc.h>
149	#include <iprt/asm.h>
150	#include <iprt/time.h>
151	#include <iprt/stream.h>
152	#include <iprt/string.h>
153	#include <iprt/stdarg.h>
154	#include <iprt/ctype.h>
155
156
157
158	/** The saved state version. */
159	#define VMM_SAVED_STATE_VERSION 3
160
161
162	/*******************************************************************************
163	* Internal Functions *
164	*******************************************************************************/
165	static DECLCALLBACK(int) vmmR3Save(PVM pVM, PSSMHANDLE pSSM);
166	static DECLCALLBACK(int) vmmR3Load(PVM pVM, PSSMHANDLE pSSM, uint32_t u32Version);
167	static DECLCALLBACK(void) vmmR3YieldEMT(PVM pVM, PTMTIMER pTimer, void *pvUser);
168	static int vmmR3ServiceCallHostRequest(PVM pVM);
169	static DECLCALLBACK(void) vmmR3InfoFF(PVM pVM, PCDBGFINFOHLP pHlp, const char *pszArgs);
170
171
172	/*******************************************************************************
173	* Global Variables *
174	*******************************************************************************/
175	/** Array of switcher defininitions.
176	* The type and index shall match!
177	*/
178	static PVMMSWITCHERDEF s_apSwitchers[VMMSWITCHER_MAX] =
179	{
180	NULL, /* invalid entry */
181	#ifndef RT_ARCH_AMD64
182	&vmmR3Switcher32BitTo32Bit_Def,
183	&vmmR3Switcher32BitToPAE_Def,
184	NULL, //&vmmR3Switcher32BitToAMD64_Def,
185	&vmmR3SwitcherPAETo32Bit_Def,
186	&vmmR3SwitcherPAEToPAE_Def,
187	NULL, //&vmmR3SwitcherPAEToAMD64_Def,
188	# ifdef VBOX_WITH_HYBIRD_32BIT_KERNEL
189	&vmmR3SwitcherAMD64ToPAE_Def,
190	# else
191	NULL, //&vmmR3SwitcherAMD64ToPAE_Def,
192	# endif
193	NULL //&vmmR3SwitcherAMD64ToAMD64_Def,
194	#else
195	NULL, //&vmmR3Switcher32BitTo32Bit_Def,
196	NULL, //&vmmR3Switcher32BitToPAE_Def,
197	NULL, //&vmmR3Switcher32BitToAMD64_Def,
198	NULL, //&vmmR3SwitcherPAETo32Bit_Def,
199	NULL, //&vmmR3SwitcherPAEToPAE_Def,
200	NULL, //&vmmR3SwitcherPAEToAMD64_Def,
201	&vmmR3SwitcherAMD64ToPAE_Def,
202	NULL //&vmmR3SwitcherAMD64ToAMD64_Def,
203	#endif
204	};
205
206
207
208	/**
209	* Initiates the core code.
210	*
211	* This is core per VM code which might need fixups and/or for ease of use
212	* are put on linear contiguous backing.
213	*
214	* @returns VBox status code.
215	* @param pVM Pointer to VM structure.
216	*/
217	static int vmmR3InitCoreCode(PVM pVM)
218	{
219	/*
220	* Calc the size.
221	*/
222	unsigned cbCoreCode = 0;
223	for (unsigned iSwitcher = 0; iSwitcher < ELEMENTS(s_apSwitchers); iSwitcher++)
224	{
225	pVM->vmm.s.aoffSwitchers[iSwitcher] = cbCoreCode;
226	PVMMSWITCHERDEF pSwitcher = s_apSwitchers[iSwitcher];
227	if (pSwitcher)
228	{
229	AssertRelease((unsigned)pSwitcher->enmType == iSwitcher);
230	cbCoreCode += RT_ALIGN_32(pSwitcher->cbCode + 1, 32);
231	}
232	}
233
234	/*
235	* Allocate continguous pages for switchers and deal with
236	* conflicts in the intermediate mapping of the code.
237	*/
238	pVM->vmm.s.cbCoreCode = RT_ALIGN_32(cbCoreCode, PAGE_SIZE);
239	pVM->vmm.s.pvHCCoreCodeR3 = SUPContAlloc2(pVM->vmm.s.cbCoreCode >> PAGE_SHIFT, &pVM->vmm.s.pvHCCoreCodeR0, &pVM->vmm.s.HCPhysCoreCode);
240	int rc = VERR_NO_MEMORY;
241	if (pVM->vmm.s.pvHCCoreCodeR3)
242	{
243	rc = PGMR3MapIntermediate(pVM, pVM->vmm.s.pvHCCoreCodeR0, pVM->vmm.s.HCPhysCoreCode, cbCoreCode);
244	if (rc == VERR_PGM_MAPPINGS_FIX_CONFLICT)
245	{
246	/* try more allocations. */
247	struct
248	{
249	RTR0PTR pvR0;
250	void *pvR3;
251	RTHCPHYS HCPhys;
252	RTUINT cb;
253	} aBadTries[16];
254	unsigned i = 0;
255	do
256	{
257	aBadTries[i].pvR3 = pVM->vmm.s.pvHCCoreCodeR3;
258	aBadTries[i].pvR0 = pVM->vmm.s.pvHCCoreCodeR0;
259	aBadTries[i].HCPhys = pVM->vmm.s.HCPhysCoreCode;
260	i++;
261	pVM->vmm.s.pvHCCoreCodeR0 = NIL_RTR0PTR;
262	pVM->vmm.s.HCPhysCoreCode = NIL_RTHCPHYS;
263	pVM->vmm.s.pvHCCoreCodeR3 = SUPContAlloc2(pVM->vmm.s.cbCoreCode >> PAGE_SHIFT, &pVM->vmm.s.pvHCCoreCodeR0, &pVM->vmm.s.HCPhysCoreCode);
264	if (!pVM->vmm.s.pvHCCoreCodeR3)
265	break;
266	rc = PGMR3MapIntermediate(pVM, pVM->vmm.s.pvHCCoreCodeR0, pVM->vmm.s.HCPhysCoreCode, cbCoreCode);
267	} while ( rc == VERR_PGM_MAPPINGS_FIX_CONFLICT
268	&& i < ELEMENTS(aBadTries) - 1);
269
270	/* cleanup */
271	if (VBOX_FAILURE(rc))
272	{
273	aBadTries[i].pvR3 = pVM->vmm.s.pvHCCoreCodeR3;
274	aBadTries[i].pvR0 = pVM->vmm.s.pvHCCoreCodeR0;
275	aBadTries[i].HCPhys = pVM->vmm.s.HCPhysCoreCode;
276	aBadTries[i].cb = pVM->vmm.s.cbCoreCode;
277	i++;
278	LogRel(("Failed to allocated and map core code: rc=%Vrc\n", rc));
279	}
280	while (i-- > 0)
281	{
282	LogRel(("Core code alloc attempt #%d: pvR3=%p pvR0=%p HCPhys=%VHp\n",
283	i, aBadTries[i].pvR3, aBadTries[i].pvR0, aBadTries[i].HCPhys));
284	SUPContFree(aBadTries[i].pvR3, aBadTries[i].cb >> PAGE_SHIFT);
285	}
286	}
287	}
288	if (VBOX_SUCCESS(rc))
289	{
290	/*
291	* copy the code.
292	*/
293	for (unsigned iSwitcher = 0; iSwitcher < ELEMENTS(s_apSwitchers); iSwitcher++)
294	{
295	PVMMSWITCHERDEF pSwitcher = s_apSwitchers[iSwitcher];
296	if (pSwitcher)
297	memcpy((uint8_t *)pVM->vmm.s.pvHCCoreCodeR3 + pVM->vmm.s.aoffSwitchers[iSwitcher],
298	pSwitcher->pvCode, pSwitcher->cbCode);
299	}
300
301	/*
302	* Map the code into the GC address space.
303	*/
304	rc = MMR3HyperMapHCPhys(pVM, pVM->vmm.s.pvHCCoreCodeR3, pVM->vmm.s.HCPhysCoreCode, cbCoreCode, "Core Code", &pVM->vmm.s.pvGCCoreCode);
305	if (VBOX_SUCCESS(rc))
306	{
307	MMR3HyperReserve(pVM, PAGE_SIZE, "fence", NULL);
308	LogRel(("CoreCode: R3=%VHv R0=%VHv GC=%VGv Phys=%VHp cb=%#x\n",
309	pVM->vmm.s.pvHCCoreCodeR3, pVM->vmm.s.pvHCCoreCodeR0, pVM->vmm.s.pvGCCoreCode, pVM->vmm.s.HCPhysCoreCode, pVM->vmm.s.cbCoreCode));
310
311	/*
312	* Finally, PGM probably have selected a switcher already but we need
313	* to do get the addresses so we'll reselect it.
314	* This may legally fail so, we're ignoring the rc.
315	*/
316	VMMR3SelectSwitcher(pVM, pVM->vmm.s.enmSwitcher);
317	return rc;
318	}
319
320	/* shit */
321	AssertMsgFailed(("PGMR3Map(,%VGv, %VGp, %#x, 0) failed with rc=%Vrc\n", pVM->vmm.s.pvGCCoreCode, pVM->vmm.s.HCPhysCoreCode, cbCoreCode, rc));
322	SUPContFree(pVM->vmm.s.pvHCCoreCodeR3, pVM->vmm.s.cbCoreCode >> PAGE_SHIFT);
323	}
324	else
325	VMSetError(pVM, rc, RT_SRC_POS,
326	N_("Failed to allocate %d bytes of contiguous memory for the world switcher code"),
327	cbCoreCode);
328
329	pVM->vmm.s.pvHCCoreCodeR3 = NULL;
330	pVM->vmm.s.pvHCCoreCodeR0 = NIL_RTR0PTR;
331	pVM->vmm.s.pvGCCoreCode = 0;
332	return rc;
333	}
334
335
336	/**
337	* Initializes the VMM.
338	*
339	* @returns VBox status code.
340	* @param pVM The VM to operate on.
341	*/
342	VMMR3DECL(int) VMMR3Init(PVM pVM)
343	{
344	LogFlow(("VMMR3Init\n"));
345
346	/*
347	* Assert alignment, sizes and order.
348	*/
349	AssertMsg(pVM->vmm.s.offVM == 0, ("Already initialized!\n"));
350	AssertMsg(sizeof(pVM->vmm.padding) >= sizeof(pVM->vmm.s),
351	("pVM->vmm.padding is too small! vmm.padding %d while vmm.s is %d\n",
352	sizeof(pVM->vmm.padding), sizeof(pVM->vmm.s)));
353
354	/*
355	* Init basic VM VMM members.
356	*/
357	pVM->vmm.s.offVM = RT_OFFSETOF(VM, vmm);
358	int rc = CFGMR3QueryU32(CFGMR3GetRoot(pVM), "YieldEMTInterval", &pVM->vmm.s.cYieldEveryMillies);
359	if (rc == VERR_CFGM_VALUE_NOT_FOUND)
360	pVM->vmm.s.cYieldEveryMillies = 23; /* Value arrived at after experimenting with the grub boot prompt. */
361	//pVM->vmm.s.cYieldEveryMillies = 8; //debugging
362	else
363	AssertMsgRCReturn(rc, ("Configuration error. Failed to query \"YieldEMTInterval\", rc=%Vrc\n", rc), rc);
364
365	/* GC switchers are enabled by default. Turned off by HWACCM. */
366	pVM->vmm.s.fSwitcherDisabled = false;
367
368	/*
369	* Register the saved state data unit.
370	*/
371	rc = SSMR3RegisterInternal(pVM, "vmm", 1, VMM_SAVED_STATE_VERSION, VMM_STACK_SIZE + sizeof(RTGCPTR),
372	NULL, vmmR3Save, NULL,
373	NULL, vmmR3Load, NULL);
374	if (VBOX_FAILURE(rc))
375	return rc;
376
377	/*
378	* Register the Ring-0 VM handle with the session for fast ioctl calls.
379	*/
380	rc = SUPSetVMForFastIOCtl(pVM->pVMR0);
381	if (VBOX_FAILURE(rc))
382	return rc;
383
384	/*
385	* Init core code.
386	*/
387	rc = vmmR3InitCoreCode(pVM);
388	if (VBOX_SUCCESS(rc))
389	{
390	/*
391	* Allocate & init VMM GC stack.
392	* The stack pages are also used by the VMM R0 when VMMR0CallHost is invoked.
393	* (The page protection is modifed during R3 init completion.)
394	*/
395	#ifdef VBOX_STRICT_VMM_STACK
396	rc = MMHyperAlloc(pVM, VMM_STACK_SIZE + PAGE_SIZE + PAGE_SIZE, PAGE_SIZE, MM_TAG_VMM, (void **)&pVM->vmm.s.pbHCStack);
397	#else
398	rc = MMHyperAlloc(pVM, VMM_STACK_SIZE, PAGE_SIZE, MM_TAG_VMM, (void **)&pVM->vmm.s.pbHCStack);
399	#endif
400	if (VBOX_SUCCESS(rc))
401	{
402	/* Set HC and GC stack pointers to top of stack. */
403	pVM->vmm.s.CallHostR0JmpBuf.pvSavedStack = (RTR0PTR)pVM->vmm.s.pbHCStack;
404	pVM->vmm.s.pbGCStack = MMHyperHC2GC(pVM, pVM->vmm.s.pbHCStack);
405	pVM->vmm.s.pbGCStackBottom = pVM->vmm.s.pbGCStack + VMM_STACK_SIZE;
406	AssertRelease(pVM->vmm.s.pbGCStack);
407
408	/* Set hypervisor eip. */
409	CPUMSetHyperESP(pVM, pVM->vmm.s.pbGCStack);
410
411	/*
412	* Allocate GC & R0 Logger instances (they are finalized in the relocator).
413	*/
414	#ifdef LOG_ENABLED
415	PRTLOGGER pLogger = RTLogDefaultInstance();
416	if (pLogger)
417	{
418	pVM->vmm.s.cbLoggerGC = RT_OFFSETOF(RTLOGGERGC, afGroups[pLogger->cGroups]);
419	rc = MMHyperAlloc(pVM, pVM->vmm.s.cbLoggerGC, 0, MM_TAG_VMM, (void **)&pVM->vmm.s.pLoggerHC);
420	if (VBOX_SUCCESS(rc))
421	{
422	pVM->vmm.s.pLoggerGC = MMHyperHC2GC(pVM, pVM->vmm.s.pLoggerHC);
423
424	/*
425	* Ring-0 logging isn't 100% safe yet (thread id reuse / process exit cleanup), so
426	* you have to sign up here by adding your defined(DEBUG_<userid>) to the #if.
427	*
428	* If you want to log in non-debug modes, you'll have to remember to change SUPDRvShared.c
429	* to not stub all the log functions.
430	*
431	* You might also wish to enable the AssertMsg1/2 overrides in VMMR0.cpp when enabling this.
432	*/
433	# if defined(DEBUG_sandervl) \|\| defined(DEBUG_frank)
434	rc = MMHyperAlloc(pVM, RT_OFFSETOF(VMMR0LOGGER, Logger.afGroups[pLogger->cGroups]),
435	0, MM_TAG_VMM, (void **)&pVM->vmm.s.pR0Logger);
436	if (VBOX_SUCCESS(rc))
437	{
438	pVM->vmm.s.pR0Logger->pVM = pVM;
439	//pVM->vmm.s.pR0Logger->fCreated = false;
440	pVM->vmm.s.pR0Logger->cbLogger = RT_OFFSETOF(RTLOGGER, afGroups[pLogger->cGroups]);
441	}
442	# endif
443	}
444	}
445	#endif /* LOG_ENABLED */
446
447	#ifdef VBOX_WITH_GC_AND_R0_RELEASE_LOG
448	/*
449	* Allocate GC Release Logger instances (finalized in the relocator).
450	*/
451	if (VBOX_SUCCESS(rc))
452	{
453	PRTLOGGER pRelLogger = RTLogRelDefaultInstance();
454	if (pRelLogger)
455	{
456	pVM->vmm.s.cbRelLoggerGC = RT_OFFSETOF(RTLOGGERGC, afGroups[pRelLogger->cGroups]);
457	rc = MMHyperAlloc(pVM, pVM->vmm.s.cbRelLoggerGC, 0, MM_TAG_VMM, (void **)&pVM->vmm.s.pRelLoggerHC);
458	if (VBOX_SUCCESS(rc))
459	pVM->vmm.s.pRelLoggerGC = MMHyperHC2GC(pVM, pVM->vmm.s.pRelLoggerHC);
460	}
461	}
462	#endif /* VBOX_WITH_GC_AND_R0_RELEASE_LOG */
463
464	#ifdef VBOX_WITH_NMI
465	/*
466	* Allocate mapping for the host APIC.
467	*/
468	if (VBOX_SUCCESS(rc))
469	{
470	rc = MMR3HyperReserve(pVM, PAGE_SIZE, "Host APIC", &pVM->vmm.s.GCPtrApicBase);
471	AssertRC(rc);
472	}
473	#endif
474	if (VBOX_SUCCESS(rc))
475	{
476	rc = RTCritSectInit(&pVM->vmm.s.CritSectVMLock);
477	if (VBOX_SUCCESS(rc))
478	{
479	/*
480	* Debug info.
481	*/
482	DBGFR3InfoRegisterInternal(pVM, "ff", "Displays the current Forced actions Flags.", vmmR3InfoFF);
483
484	/*
485	* Statistics.
486	*/
487	STAM_REG(pVM, &pVM->vmm.s.StatRunGC, STAMTYPE_COUNTER, "/VMM/RunGC", STAMUNIT_OCCURENCES, "Number of context switches.");
488	STAM_REG(pVM, &pVM->vmm.s.StatGCRetNormal, STAMTYPE_COUNTER, "/VMM/GCRet/Normal", STAMUNIT_OCCURENCES, "Number of VINF_SUCCESS returns.");
489	STAM_REG(pVM, &pVM->vmm.s.StatGCRetInterrupt, STAMTYPE_COUNTER, "/VMM/GCRet/Interrupt", STAMUNIT_OCCURENCES, "Number of VINF_EM_RAW_INTERRUPT returns.");
490	STAM_REG(pVM, &pVM->vmm.s.StatGCRetInterruptHyper, STAMTYPE_COUNTER, "/VMM/GCRet/InterruptHyper", STAMUNIT_OCCURENCES, "Number of VINF_EM_RAW_INTERRUPT_HYPER returns.");
491	STAM_REG(pVM, &pVM->vmm.s.StatGCRetGuestTrap, STAMTYPE_COUNTER, "/VMM/GCRet/GuestTrap", STAMUNIT_OCCURENCES, "Number of VINF_EM_RAW_GUEST_TRAP returns.");
492	STAM_REG(pVM, &pVM->vmm.s.StatGCRetRingSwitch, STAMTYPE_COUNTER, "/VMM/GCRet/RingSwitch", STAMUNIT_OCCURENCES, "Number of VINF_EM_RAW_RING_SWITCH returns.");
493	STAM_REG(pVM, &pVM->vmm.s.StatGCRetRingSwitchInt, STAMTYPE_COUNTER, "/VMM/GCRet/RingSwitchInt", STAMUNIT_OCCURENCES, "Number of VINF_EM_RAW_RING_SWITCH_INT returns.");
494	STAM_REG(pVM, &pVM->vmm.s.StatGCRetExceptionPrivilege, STAMTYPE_COUNTER, "/VMM/GCRet/ExceptionPrivilege", STAMUNIT_OCCURENCES, "Number of VINF_EM_RAW_EXCEPTION_PRIVILEGED returns.");
495	STAM_REG(pVM, &pVM->vmm.s.StatGCRetStaleSelector, STAMTYPE_COUNTER, "/VMM/GCRet/StaleSelector", STAMUNIT_OCCURENCES, "Number of VINF_EM_RAW_STALE_SELECTOR returns.");
496	STAM_REG(pVM, &pVM->vmm.s.StatGCRetIRETTrap, STAMTYPE_COUNTER, "/VMM/GCRet/IRETTrap", STAMUNIT_OCCURENCES, "Number of VINF_EM_RAW_IRET_TRAP returns.");
497	STAM_REG(pVM, &pVM->vmm.s.StatGCRetEmulate, STAMTYPE_COUNTER, "/VMM/GCRet/Emulate", STAMUNIT_OCCURENCES, "Number of VINF_EM_EXECUTE_INSTRUCTION returns.");
498	STAM_REG(pVM, &pVM->vmm.s.StatGCRetPatchEmulate, STAMTYPE_COUNTER, "/VMM/GCRet/PatchEmulate", STAMUNIT_OCCURENCES, "Number of VINF_PATCH_EMULATE_INSTR returns.");
499	STAM_REG(pVM, &pVM->vmm.s.StatGCRetIORead, STAMTYPE_COUNTER, "/VMM/GCRet/IORead", STAMUNIT_OCCURENCES, "Number of VINF_IOM_HC_IOPORT_READ returns.");
500	STAM_REG(pVM, &pVM->vmm.s.StatGCRetIOWrite, STAMTYPE_COUNTER, "/VMM/GCRet/IOWrite", STAMUNIT_OCCURENCES, "Number of VINF_IOM_HC_IOPORT_WRITE returns.");
501	STAM_REG(pVM, &pVM->vmm.s.StatGCRetMMIORead, STAMTYPE_COUNTER, "/VMM/GCRet/MMIORead", STAMUNIT_OCCURENCES, "Number of VINF_IOM_HC_MMIO_READ returns.");
502	STAM_REG(pVM, &pVM->vmm.s.StatGCRetMMIOWrite, STAMTYPE_COUNTER, "/VMM/GCRet/MMIOWrite", STAMUNIT_OCCURENCES, "Number of VINF_IOM_HC_MMIO_WRITE returns.");
503	STAM_REG(pVM, &pVM->vmm.s.StatGCRetMMIOReadWrite, STAMTYPE_COUNTER, "/VMM/GCRet/MMIOReadWrite", STAMUNIT_OCCURENCES, "Number of VINF_IOM_HC_MMIO_READ_WRITE returns.");
504	STAM_REG(pVM, &pVM->vmm.s.StatGCRetMMIOPatchRead, STAMTYPE_COUNTER, "/VMM/GCRet/MMIOPatchRead", STAMUNIT_OCCURENCES, "Number of VINF_IOM_HC_MMIO_PATCH_READ returns.");
505	STAM_REG(pVM, &pVM->vmm.s.StatGCRetMMIOPatchWrite, STAMTYPE_COUNTER, "/VMM/GCRet/MMIOPatchWrite", STAMUNIT_OCCURENCES, "Number of VINF_IOM_HC_MMIO_PATCH_WRITE returns.");
506	STAM_REG(pVM, &pVM->vmm.s.StatGCRetLDTFault, STAMTYPE_COUNTER, "/VMM/GCRet/LDTFault", STAMUNIT_OCCURENCES, "Number of VINF_EM_EXECUTE_INSTRUCTION_GDT_FAULT returns.");
507	STAM_REG(pVM, &pVM->vmm.s.StatGCRetGDTFault, STAMTYPE_COUNTER, "/VMM/GCRet/GDTFault", STAMUNIT_OCCURENCES, "Number of VINF_EM_EXECUTE_INSTRUCTION_LDT_FAULT returns.");
508	STAM_REG(pVM, &pVM->vmm.s.StatGCRetIDTFault, STAMTYPE_COUNTER, "/VMM/GCRet/IDTFault", STAMUNIT_OCCURENCES, "Number of VINF_EM_EXECUTE_INSTRUCTION_IDT_FAULT returns.");
509	STAM_REG(pVM, &pVM->vmm.s.StatGCRetTSSFault, STAMTYPE_COUNTER, "/VMM/GCRet/TSSFault", STAMUNIT_OCCURENCES, "Number of VINF_EM_EXECUTE_INSTRUCTION_TSS_FAULT returns.");
510	STAM_REG(pVM, &pVM->vmm.s.StatGCRetPDFault, STAMTYPE_COUNTER, "/VMM/GCRet/PDFault", STAMUNIT_OCCURENCES, "Number of VINF_EM_EXECUTE_INSTRUCTION_PD_FAULT returns.");
511	STAM_REG(pVM, &pVM->vmm.s.StatGCRetCSAMTask, STAMTYPE_COUNTER, "/VMM/GCRet/CSAMTask", STAMUNIT_OCCURENCES, "Number of VINF_CSAM_PENDING_ACTION returns.");
512	STAM_REG(pVM, &pVM->vmm.s.StatGCRetSyncCR3, STAMTYPE_COUNTER, "/VMM/GCRet/SyncCR", STAMUNIT_OCCURENCES, "Number of VINF_PGM_SYNC_CR3 returns.");
513	STAM_REG(pVM, &pVM->vmm.s.StatGCRetMisc, STAMTYPE_COUNTER, "/VMM/GCRet/Misc", STAMUNIT_OCCURENCES, "Number of misc returns.");
514	STAM_REG(pVM, &pVM->vmm.s.StatGCRetPatchInt3, STAMTYPE_COUNTER, "/VMM/GCRet/PatchInt3", STAMUNIT_OCCURENCES, "Number of VINF_PATM_PATCH_INT3 returns.");
515	STAM_REG(pVM, &pVM->vmm.s.StatGCRetPatchPF, STAMTYPE_COUNTER, "/VMM/GCRet/PatchPF", STAMUNIT_OCCURENCES, "Number of VINF_PATM_PATCH_TRAP_PF returns.");
516	STAM_REG(pVM, &pVM->vmm.s.StatGCRetPatchGP, STAMTYPE_COUNTER, "/VMM/GCRet/PatchGP", STAMUNIT_OCCURENCES, "Number of VINF_PATM_PATCH_TRAP_GP returns.");
517	STAM_REG(pVM, &pVM->vmm.s.StatGCRetPatchIretIRQ, STAMTYPE_COUNTER, "/VMM/GCRet/PatchIret", STAMUNIT_OCCURENCES, "Number of VINF_PATM_PENDING_IRQ_AFTER_IRET returns.");
518	STAM_REG(pVM, &pVM->vmm.s.StatGCRetPageOverflow, STAMTYPE_COUNTER, "/VMM/GCRet/InvlpgOverflow", STAMUNIT_OCCURENCES, "Number of VERR_REM_FLUSHED_PAGES_OVERFLOW returns.");
519	STAM_REG(pVM, &pVM->vmm.s.StatGCRetRescheduleREM, STAMTYPE_COUNTER, "/VMM/GCRet/ScheduleREM", STAMUNIT_OCCURENCES, "Number of VINF_EM_RESCHEDULE_REM returns.");
520	STAM_REG(pVM, &pVM->vmm.s.StatGCRetToR3, STAMTYPE_COUNTER, "/VMM/GCRet/ToR3", STAMUNIT_OCCURENCES, "Number of VINF_EM_RAW_TO_R3 returns.");
521	STAM_REG(pVM, &pVM->vmm.s.StatGCRetTimerPending, STAMTYPE_COUNTER, "/VMM/GCRet/TimerPending", STAMUNIT_OCCURENCES, "Number of VINF_EM_RAW_TIMER_PENDING returns.");
522	STAM_REG(pVM, &pVM->vmm.s.StatGCRetInterruptPending, STAMTYPE_COUNTER, "/VMM/GCRet/InterruptPending", STAMUNIT_OCCURENCES, "Number of VINF_EM_RAW_INTERRUPT_PENDING returns.");
523	STAM_REG(pVM, &pVM->vmm.s.StatGCRetCallHost, STAMTYPE_COUNTER, "/VMM/GCRet/CallHost/Misc", STAMUNIT_OCCURENCES, "Number of VINF_VMM_CALL_HOST returns.");
524	STAM_REG(pVM, &pVM->vmm.s.StatGCRetPGMGrowRAM, STAMTYPE_COUNTER, "/VMM/GCRet/CallHost/GrowRAM", STAMUNIT_OCCURENCES, "Number of VINF_VMM_CALL_HOST returns.");
525	STAM_REG(pVM, &pVM->vmm.s.StatGCRetPDMLock, STAMTYPE_COUNTER, "/VMM/GCRet/CallHost/PDMLock", STAMUNIT_OCCURENCES, "Number of VINF_VMM_CALL_HOST returns.");
526	STAM_REG(pVM, &pVM->vmm.s.StatGCRetLogFlush, STAMTYPE_COUNTER, "/VMM/GCRet/CallHost/LogFlush", STAMUNIT_OCCURENCES, "Number of VINF_VMM_CALL_HOST returns.");
527	STAM_REG(pVM, &pVM->vmm.s.StatGCRetPDMQueueFlush, STAMTYPE_COUNTER, "/VMM/GCRet/CallHost/QueueFlush", STAMUNIT_OCCURENCES, "Number of VINF_VMM_CALL_HOST returns.");
528	STAM_REG(pVM, &pVM->vmm.s.StatGCRetPGMPoolGrow, STAMTYPE_COUNTER, "/VMM/GCRet/CallHost/PGMPoolGrow",STAMUNIT_OCCURENCES, "Number of VINF_VMM_CALL_HOST returns.");
529	STAM_REG(pVM, &pVM->vmm.s.StatGCRetRemReplay, STAMTYPE_COUNTER, "/VMM/GCRet/CallHost/REMReplay", STAMUNIT_OCCURENCES, "Number of VINF_VMM_CALL_HOST returns.");
530	STAM_REG(pVM, &pVM->vmm.s.StatGCRetVMSetError, STAMTYPE_COUNTER, "/VMM/GCRet/CallHost/VMSetError", STAMUNIT_OCCURENCES, "Number of VINF_VMM_CALL_HOST returns.");
531	STAM_REG(pVM, &pVM->vmm.s.StatGCRetPGMLock, STAMTYPE_COUNTER, "/VMM/GCRet/CallHost/PGMLock", STAMUNIT_OCCURENCES, "Number of VINF_VMM_CALL_HOST returns.");
532	STAM_REG(pVM, &pVM->vmm.s.StatGCRetPATMDuplicateFn, STAMTYPE_COUNTER, "/VMM/GCRet/PATMDuplicateFn", STAMUNIT_OCCURENCES, "Number of VINF_PATM_DUPLICATE_FUNCTION returns.");
533	STAM_REG(pVM, &pVM->vmm.s.StatGCRetPGMChangeMode, STAMTYPE_COUNTER, "/VMM/GCRet/PGMChangeMode", STAMUNIT_OCCURENCES, "Number of VINF_PGM_CHANGE_MODE returns.");
534	STAM_REG(pVM, &pVM->vmm.s.StatGCRetEmulHlt, STAMTYPE_COUNTER, "/VMM/GCRet/EmulHlt", STAMUNIT_OCCURENCES, "Number of VINF_EM_RAW_EMULATE_INSTR_HLT returns.");
535	STAM_REG(pVM, &pVM->vmm.s.StatGCRetPendingRequest, STAMTYPE_COUNTER, "/VMM/GCRet/PendingRequest", STAMUNIT_OCCURENCES, "Number of VINF_EM_PENDING_REQUEST returns.");
536
537	return VINF_SUCCESS;
538	}
539	AssertRC(rc);
540	}
541	}
542	/** @todo: Need failure cleanup. */
543
544	//more todo in here?
545	//if (VBOX_SUCCESS(rc))
546	//{
547	//}
548	//int rc2 = vmmR3TermCoreCode(pVM);
549	//AssertRC(rc2));
550	}
551
552	return rc;
553	}
554
555
556	/**
557	* Ring-3 init finalizing.
558	*
559	* @returns VBox status code.
560	* @param pVM The VM handle.
561	*/
562	VMMR3DECL(int) VMMR3InitFinalize(PVM pVM)
563	{
564	#ifdef VBOX_STRICT_VMM_STACK
565	/*
566	* Two inaccessible pages at each sides of the stack to catch over/under-flows.
567	*/
568	memset(pVM->vmm.s.pbHCStack - PAGE_SIZE, 0xcc, PAGE_SIZE);
569	PGMMapSetPage(pVM, MMHyperHC2GC(pVM, pVM->vmm.s.pbHCStack - PAGE_SIZE), PAGE_SIZE, 0);
570	RTMemProtect(pVM->vmm.s.pbHCStack - PAGE_SIZE, PAGE_SIZE, RTMEM_PROT_NONE);
571
572	memset(pVM->vmm.s.pbHCStack + VMM_STACK_SIZE, 0xcc, PAGE_SIZE);
573	PGMMapSetPage(pVM, MMHyperHC2GC(pVM, pVM->vmm.s.pbHCStack + VMM_STACK_SIZE), PAGE_SIZE, 0);
574	RTMemProtect(pVM->vmm.s.pbHCStack + VMM_STACK_SIZE, PAGE_SIZE, RTMEM_PROT_NONE);
575	#endif
576
577	/*
578	* Set page attributes to r/w for stack pages.
579	*/
580	int rc = PGMMapSetPage(pVM, pVM->vmm.s.pbGCStack, VMM_STACK_SIZE, X86_PTE_P \| X86_PTE_A \| X86_PTE_D \| X86_PTE_RW);
581	AssertRC(rc);
582	if (VBOX_SUCCESS(rc))
583	{
584	/*
585	* Create the EMT yield timer.
586	*/
587	rc = TMR3TimerCreateInternal(pVM, TMCLOCK_REAL, vmmR3YieldEMT, NULL, "EMT Yielder", &pVM->vmm.s.pYieldTimer);
588	if (VBOX_SUCCESS(rc))
589	rc = TMTimerSetMillies(pVM->vmm.s.pYieldTimer, pVM->vmm.s.cYieldEveryMillies);
590	}
591	#ifdef VBOX_WITH_NMI
592	/*
593	* Map the host APIC into GC - This may be host os specific!
594	*/
595	if (VBOX_SUCCESS(rc))
596	rc = PGMMap(pVM, pVM->vmm.s.GCPtrApicBase, 0xfee00000, PAGE_SIZE,
597	X86_PTE_P \| X86_PTE_RW \| X86_PTE_PWT \| X86_PTE_PCD \| X86_PTE_A \| X86_PTE_D);
598	#endif
599	return rc;
600	}
601
602
603	/**
604	* Initializes the R0 VMM.
605	*
606	* @returns VBox status code.
607	* @param pVM The VM to operate on.
608	*/
609	VMMR3DECL(int) VMMR3InitR0(PVM pVM)
610	{
611	int rc;
612
613	/*
614	* Initialize the ring-0 logger if we haven't done so yet.
615	*/
616	if ( pVM->vmm.s.pR0Logger
617	&& !pVM->vmm.s.pR0Logger->fCreated)
618	{
619	rc = VMMR3UpdateLoggers(pVM);
620	if (VBOX_FAILURE(rc))
621	return rc;
622	}
623
624	/*
625	* Call Ring-0 entry with init code.
626	*/
627	for (;;)
628	{
629	#ifdef NO_SUPCALLR0VMM
630	//rc = VERR_GENERAL_FAILURE;
631	rc = VINF_SUCCESS;
632	#else
633	rc = SUPCallVMMR0Ex(pVM->pVMR0, VMMR0_DO_VMMR0_INIT, VBOX_VERSION, NULL);
634	#endif
635	if ( pVM->vmm.s.pR0Logger
636	&& pVM->vmm.s.pR0Logger->Logger.offScratch > 0)
637	RTLogFlushToLogger(&pVM->vmm.s.pR0Logger->Logger, NULL);
638	if (rc != VINF_VMM_CALL_HOST)
639	break;
640	rc = vmmR3ServiceCallHostRequest(pVM);
641	if (VBOX_FAILURE(rc) \|\| (rc >= VINF_EM_FIRST && rc <= VINF_EM_LAST))
642	break;
643	/* Resume R0 */
644	}
645
646	if (VBOX_FAILURE(rc) \|\| (rc >= VINF_EM_FIRST && rc <= VINF_EM_LAST))
647	{
648	LogRel(("R0 init failed, rc=%Vra\n", rc));
649	if (VBOX_SUCCESS(rc))
650	rc = VERR_INTERNAL_ERROR;
651	}
652	return rc;
653	}
654
655
656	/**
657	* Initializes the GC VMM.
658	*
659	* @returns VBox status code.
660	* @param pVM The VM to operate on.
661	*/
662	VMMR3DECL(int) VMMR3InitGC(PVM pVM)
663	{
664	/* In VMX mode, there's no need to init GC. */
665	if (pVM->vmm.s.fSwitcherDisabled)
666	return VINF_SUCCESS;
667
668	/*
669	* Call VMMGCInit():
670	* -# resolve the address.
671	* -# setup stackframe and EIP to use the trampoline.
672	* -# do a generic hypervisor call.
673	*/
674	RTGCPTR GCPtrEP;
675	int rc = PDMR3GetSymbolGC(pVM, VMMGC_MAIN_MODULE_NAME, "VMMGCEntry", &GCPtrEP);
676	if (VBOX_SUCCESS(rc))
677	{
678	CPUMHyperSetCtxCore(pVM, NULL);
679	CPUMSetHyperESP(pVM, pVM->vmm.s.pbGCStackBottom); /* Clear the stack. */
680	uint64_t u64TS = RTTimeProgramStartNanoTS();
681	#if GC_ARCH_BITS == 32
682	CPUMPushHyper(pVM, (uint32_t)(u64TS >> 32)); /* Param 3: The program startup TS - Hi. */
683	CPUMPushHyper(pVM, (uint32_t)u64TS); /* Param 3: The program startup TS - Lo. */
684	#else /* 64-bit GC */
685	CPUMPushHyper(pVM, u64TS); /* Param 3: The program startup TS. */
686	#endif
687	CPUMPushHyper(pVM, VBOX_VERSION); /* Param 2: Version argument. */
688	CPUMPushHyper(pVM, VMMGC_DO_VMMGC_INIT); /* Param 1: Operation. */
689	CPUMPushHyper(pVM, pVM->pVMGC); /* Param 0: pVM */
690	CPUMPushHyper(pVM, 3 * sizeof(RTGCPTR)); /* trampoline param: stacksize. */
691	CPUMPushHyper(pVM, GCPtrEP); /* Call EIP. */
692	CPUMSetHyperEIP(pVM, pVM->vmm.s.pfnGCCallTrampoline);
693
694	for (;;)
695	{
696	#ifdef NO_SUPCALLR0VMM
697	//rc = VERR_GENERAL_FAILURE;
698	rc = VINF_SUCCESS;
699	#else
700	rc = SUPCallVMMR0(pVM->pVMR0, VMMR0_DO_CALL_HYPERVISOR, NULL);
701	#endif
702	#ifdef LOG_ENABLED
703	PRTLOGGERGC pLogger = pVM->vmm.s.pLoggerHC;
704	if ( pLogger
705	&& pLogger->offScratch > 0)
706	RTLogFlushGC(NULL, pLogger);
707	#endif
708	#ifdef VBOX_WITH_GC_AND_R0_RELEASE_LOG
709	PRTLOGGERGC pRelLogger = pVM->vmm.s.pRelLoggerHC;
710	if (RT_UNLIKELY(pRelLogger && pRelLogger->offScratch > 0))
711	RTLogFlushGC(RTLogRelDefaultInstance(), pRelLogger);
712	#endif
713	if (rc != VINF_VMM_CALL_HOST)
714	break;
715	rc = vmmR3ServiceCallHostRequest(pVM);
716	if (VBOX_FAILURE(rc) \|\| (rc >= VINF_EM_FIRST && rc <= VINF_EM_LAST))
717	break;
718	}
719
720	if (VBOX_FAILURE(rc) \|\| (rc >= VINF_EM_FIRST && rc <= VINF_EM_LAST))
721	{
722	VMMR3FatalDump(pVM, rc);
723	if (rc >= VINF_EM_FIRST && rc <= VINF_EM_LAST)
724	rc = VERR_INTERNAL_ERROR;
725	}
726	AssertRC(rc);
727	}
728	return rc;
729	}
730
731
732	/**
733	* Terminate the VMM bits.
734	*
735	* @returns VINF_SUCCESS.
736	* @param pVM The VM handle.
737	*/
738	VMMR3DECL(int) VMMR3Term(PVM pVM)
739	{
740	/*
741	* Call Ring-0 entry with termination code.
742	*/
743	int rc;
744	for (;;)
745	{
746	#ifdef NO_SUPCALLR0VMM
747	//rc = VERR_GENERAL_FAILURE;
748	rc = VINF_SUCCESS;
749	#else
750	rc = SUPCallVMMR0Ex(pVM->pVMR0, VMMR0_DO_VMMR0_TERM, VBOX_VERSION, NULL);
751	#endif
752	if ( pVM->vmm.s.pR0Logger
753	&& pVM->vmm.s.pR0Logger->Logger.offScratch > 0)
754	RTLogFlushToLogger(&pVM->vmm.s.pR0Logger->Logger, NULL);
755	if (rc != VINF_VMM_CALL_HOST)
756	break;
757	rc = vmmR3ServiceCallHostRequest(pVM);
758	if (VBOX_FAILURE(rc) \|\| (rc >= VINF_EM_FIRST && rc <= VINF_EM_LAST))
759	break;
760	/* Resume R0 */
761	}
762	if (VBOX_FAILURE(rc) \|\| (rc >= VINF_EM_FIRST && rc <= VINF_EM_LAST))
763	{
764	LogRel(("VMMR3Term: R0 term failed, rc=%Vra. (warning)\n", rc));
765	if (VBOX_SUCCESS(rc))
766	rc = VERR_INTERNAL_ERROR;
767	}
768
769	#ifdef VBOX_STRICT_VMM_STACK
770	/*
771	* Make the two stack guard pages present again.
772	*/
773	RTMemProtect(pVM->vmm.s.pbHCStack - PAGE_SIZE, PAGE_SIZE, RTMEM_PROT_READ \| RTMEM_PROT_WRITE);
774	RTMemProtect(pVM->vmm.s.pbHCStack + VMM_STACK_SIZE, PAGE_SIZE, RTMEM_PROT_READ \| RTMEM_PROT_WRITE);
775	#endif
776	return rc;
777	}
778
779
780	/**
781	* Applies relocations to data and code managed by this
782	* component. This function will be called at init and
783	* whenever the VMM need to relocate it self inside the GC.
784	*
785	* The VMM will need to apply relocations to the core code.
786	*
787	* @param pVM The VM handle.
788	* @param offDelta The relocation delta.
789	*/
790	VMMR3DECL(void) VMMR3Relocate(PVM pVM, RTGCINTPTR offDelta)
791	{
792	LogFlow(("VMMR3Relocate: offDelta=%VGv\n", offDelta));
793
794	/*
795	* Recalc the GC address.
796	*/
797	pVM->vmm.s.pvGCCoreCode = MMHyperHC2GC(pVM, pVM->vmm.s.pvHCCoreCodeR3);
798
799	/*
800	* The stack.
801	*/
802	CPUMSetHyperESP(pVM, CPUMGetHyperESP(pVM) + offDelta);
803	pVM->vmm.s.pbGCStack = MMHyperHC2GC(pVM, pVM->vmm.s.pbHCStack);
804	pVM->vmm.s.pbGCStackBottom = pVM->vmm.s.pbGCStack + VMM_STACK_SIZE;
805
806	/*
807	* All the switchers.
808	*/
809	for (unsigned iSwitcher = 0; iSwitcher < ELEMENTS(s_apSwitchers); iSwitcher++)
810	{
811	PVMMSWITCHERDEF pSwitcher = s_apSwitchers[iSwitcher];
812	if (pSwitcher && pSwitcher->pfnRelocate)
813	{
814	unsigned off = pVM->vmm.s.aoffSwitchers[iSwitcher];
815	pSwitcher->pfnRelocate(pVM,
816	pSwitcher,
817	(uint8_t *)pVM->vmm.s.pvHCCoreCodeR0 + off,
818	(uint8_t *)pVM->vmm.s.pvHCCoreCodeR3 + off,
819	pVM->vmm.s.pvGCCoreCode + off,
820	pVM->vmm.s.HCPhysCoreCode + off);
821	}
822	}
823
824	/*
825	* Recalc the GC address for the current switcher.
826	*/
827	PVMMSWITCHERDEF pSwitcher = s_apSwitchers[pVM->vmm.s.enmSwitcher];
828	RTGCPTR GCPtr = pVM->vmm.s.pvGCCoreCode + pVM->vmm.s.aoffSwitchers[pVM->vmm.s.enmSwitcher];
829	pVM->vmm.s.pfnGCGuestToHost = GCPtr + pSwitcher->offGCGuestToHost;
830	pVM->vmm.s.pfnGCCallTrampoline = GCPtr + pSwitcher->offGCCallTrampoline;
831	pVM->pfnVMMGCGuestToHostAsm = GCPtr + pSwitcher->offGCGuestToHostAsm;
832	pVM->pfnVMMGCGuestToHostAsmHyperCtx = GCPtr + pSwitcher->offGCGuestToHostAsmHyperCtx;
833	pVM->pfnVMMGCGuestToHostAsmGuestCtx = GCPtr + pSwitcher->offGCGuestToHostAsmGuestCtx;
834
835	/*
836	* Get other GC entry points.
837	*/
838	int rc = PDMR3GetSymbolGC(pVM, VMMGC_MAIN_MODULE_NAME, "CPUMGCResumeGuest", &pVM->vmm.s.pfnCPUMGCResumeGuest);
839	AssertReleaseMsgRC(rc, ("CPUMGCResumeGuest not found! rc=%Vra\n", rc));
840
841	rc = PDMR3GetSymbolGC(pVM, VMMGC_MAIN_MODULE_NAME, "CPUMGCResumeGuestV86", &pVM->vmm.s.pfnCPUMGCResumeGuestV86);
842	AssertReleaseMsgRC(rc, ("CPUMGCResumeGuestV86 not found! rc=%Vra\n", rc));
843
844	/*
845	* Update the logger.
846	*/
847	VMMR3UpdateLoggers(pVM);
848	}
849
850
851	/**
852	* Updates the settings for the GC and R0 loggers.
853	*
854	* @returns VBox status code.
855	* @param pVM The VM handle.
856	*/
857	VMMR3DECL(int) VMMR3UpdateLoggers(PVM pVM)
858	{
859	/*
860	* Simply clone the logger instance (for GC).
861	*/
862	int rc = VINF_SUCCESS;
863	RTGCPTR GCPtrLoggerFlush = 0;
864
865	if (pVM->vmm.s.pLoggerHC
866	#ifdef VBOX_WITH_GC_AND_R0_RELEASE_LOG
867	\|\| pVM->vmm.s.pRelLoggerHC
868	#endif
869	)
870	{
871	rc = PDMR3GetSymbolGC(pVM, VMMGC_MAIN_MODULE_NAME, "vmmGCLoggerFlush", &GCPtrLoggerFlush);
872	AssertReleaseMsgRC(rc, ("vmmGCLoggerFlush not found! rc=%Vra\n", rc));
873	}
874
875	if (pVM->vmm.s.pLoggerHC)
876	{
877	RTGCPTR GCPtrLoggerWrapper = 0;
878	rc = PDMR3GetSymbolGC(pVM, VMMGC_MAIN_MODULE_NAME, "vmmGCLoggerWrapper", &GCPtrLoggerWrapper);
879	AssertReleaseMsgRC(rc, ("vmmGCLoggerWrapper not found! rc=%Vra\n", rc));
880	pVM->vmm.s.pLoggerGC = MMHyperHC2GC(pVM, pVM->vmm.s.pLoggerHC);
881	rc = RTLogCloneGC(NULL /* default */, pVM->vmm.s.pLoggerHC, pVM->vmm.s.cbLoggerGC,
882	GCPtrLoggerWrapper, GCPtrLoggerFlush, RTLOGFLAGS_BUFFERED);
883	AssertReleaseMsgRC(rc, ("RTLogCloneGC failed! rc=%Vra\n", rc));
884	}
885
886	#ifdef VBOX_WITH_GC_AND_R0_RELEASE_LOG
887	if (pVM->vmm.s.pRelLoggerHC)
888	{
889	RTGCPTR GCPtrLoggerWrapper = 0;
890	rc = PDMR3GetSymbolGC(pVM, VMMGC_MAIN_MODULE_NAME, "vmmGCRelLoggerWrapper", &GCPtrLoggerWrapper);
891	AssertReleaseMsgRC(rc, ("vmmGCRelLoggerWrapper not found! rc=%Vra\n", rc));
892	pVM->vmm.s.pRelLoggerGC = MMHyperHC2GC(pVM, pVM->vmm.s.pRelLoggerHC);
893	rc = RTLogCloneGC(RTLogRelDefaultInstance(), pVM->vmm.s.pRelLoggerHC, pVM->vmm.s.cbRelLoggerGC,
894	GCPtrLoggerWrapper, GCPtrLoggerFlush, RTLOGFLAGS_BUFFERED);
895	AssertReleaseMsgRC(rc, ("RTLogCloneGC failed! rc=%Vra\n", rc));
896	}
897	#endif /* VBOX_WITH_GC_AND_R0_RELEASE_LOG */
898
899	/*
900	* For the ring-0 EMT logger, we use a per-thread logger
901	* instance in ring-0. Only initialize it once.
902	*/
903	PVMMR0LOGGER pR0Logger = pVM->vmm.s.pR0Logger;
904	if (pR0Logger)
905	{
906	if (!pR0Logger->fCreated)
907	{
908	RTR0PTR pfnLoggerWrapper = NIL_RTR0PTR;
909	rc = PDMR3GetSymbolR0(pVM, VMMR0_MAIN_MODULE_NAME, "vmmR0LoggerWrapper", &pfnLoggerWrapper);
910	AssertReleaseMsgRCReturn(rc, ("VMMLoggerWrapper not found! rc=%Vra\n", rc), rc);
911
912	RTR0PTR pfnLoggerFlush = NIL_RTR0PTR;
913	rc = PDMR3GetSymbolR0(pVM, VMMR0_MAIN_MODULE_NAME, "vmmR0LoggerFlush", &pfnLoggerFlush);
914	AssertReleaseMsgRCReturn(rc, ("VMMLoggerFlush not found! rc=%Vra\n", rc), rc);
915
916	rc = RTLogCreateForR0(&pR0Logger->Logger, pR0Logger->cbLogger,
917	(PFNRTLOGGER )&pfnLoggerWrapper, (PFNRTLOGFLUSH )&pfnLoggerFlush,
918	RTLOGFLAGS_BUFFERED, RTLOGDEST_DUMMY);
919	AssertReleaseMsgRCReturn(rc, ("RTLogCloneGC failed! rc=%Vra\n", rc), rc);
920	pR0Logger->fCreated = true;
921	}
922
923	rc = RTLogCopyGroupsAndFlags(&pR0Logger->Logger, NULL /* default */, RTLOGFLAGS_BUFFERED, 0);
924	AssertRC(rc);
925	}
926
927	return rc;
928	}
929
930
931	/**
932	* Generic switch code relocator.
933	*
934	* @param pVM The VM handle.
935	* @param pSwitcher The switcher definition.
936	* @param pu8CodeR3 Pointer to the core code block for the switcher, ring-3 mapping.
937	* @param pu8CodeR0 Pointer to the core code block for the switcher, ring-0 mapping.
938	* @param GCPtrCode The guest context address corresponding to pu8Code.
939	* @param u32IDCode The identity mapped (ID) address corresponding to pu8Code.
940	* @param SelCS The hypervisor CS selector.
941	* @param SelDS The hypervisor DS selector.
942	* @param SelTSS The hypervisor TSS selector.
943	* @param GCPtrGDT The GC address of the hypervisor GDT.
944	* @param SelCS64 The 64-bit mode hypervisor CS selector.
945	*/
946	static void vmmR3SwitcherGenericRelocate(PVM pVM, PVMMSWITCHERDEF pSwitcher, uint8_t pu8CodeR0, uint8_t pu8CodeR3, RTGCPTR GCPtrCode, uint32_t u32IDCode,
947	RTSEL SelCS, RTSEL SelDS, RTSEL SelTSS, RTGCPTR GCPtrGDT, RTSEL SelCS64)
948	{
949	union
950	{
951	const uint8_t *pu8;
952	const uint16_t *pu16;
953	const uint32_t *pu32;
954	const uint64_t *pu64;
955	const void *pv;
956	uintptr_t u;
957	} u;
958	u.pv = pSwitcher->pvFixups;
959
960	/*
961	* Process fixups.
962	*/
963	uint8_t u8;
964	while ((u8 = *u.pu8++) != FIX_THE_END)
965	{
966	/*
967	* Get the source (where to write the fixup).
968	*/
969	uint32_t offSrc = *u.pu32++;
970	Assert(offSrc < pSwitcher->cbCode);
971	union
972	{
973	uint8_t *pu8;
974	uint16_t *pu16;
975	uint32_t *pu32;
976	uint64_t *pu64;
977	uintptr_t u;
978	} uSrc;
979	uSrc.pu8 = pu8CodeR3 + offSrc;
980
981	/* The fixup target and method depends on the type. */
982	switch (u8)
983	{
984	/*
985	* 32-bit relative, source in HC and target in GC.
986	*/
987	case FIX_HC_2_GC_NEAR_REL:
988	{
989	Assert(offSrc - pSwitcher->offHCCode0 < pSwitcher->cbHCCode0 \|\| offSrc - pSwitcher->offHCCode1 < pSwitcher->cbHCCode1);
990	uint32_t offTrg = *u.pu32++;
991	Assert(offTrg - pSwitcher->offGCCode < pSwitcher->cbGCCode);
992	*uSrc.pu32 = (uint32_t)((GCPtrCode + offTrg) - (uSrc.u + 4));
993	break;
994	}
995
996	/*
997	* 32-bit relative, source in HC and target in ID.
998	*/
999	case FIX_HC_2_ID_NEAR_REL:
1000	{
1001	Assert(offSrc - pSwitcher->offHCCode0 < pSwitcher->cbHCCode0 \|\| offSrc - pSwitcher->offHCCode1 < pSwitcher->cbHCCode1);
1002	uint32_t offTrg = *u.pu32++;
1003	Assert(offTrg - pSwitcher->offIDCode0 < pSwitcher->cbIDCode0 \|\| offTrg - pSwitcher->offIDCode1 < pSwitcher->cbIDCode1);
1004	*uSrc.pu32 = (uint32_t)((u32IDCode + offTrg) - (uSrc.u + 4));
1005	break;
1006	}
1007
1008	/*
1009	* 32-bit relative, source in GC and target in HC.
1010	*/
1011	case FIX_GC_2_HC_NEAR_REL:
1012	{
1013	Assert(offSrc - pSwitcher->offGCCode < pSwitcher->cbGCCode);
1014	uint32_t offTrg = *u.pu32++;
1015	Assert(offTrg - pSwitcher->offHCCode0 < pSwitcher->cbHCCode0 \|\| offTrg - pSwitcher->offHCCode1 < pSwitcher->cbHCCode1);
1016	*uSrc.pu32 = (uint32_t)(((uintptr_t)pu8CodeR0 + offTrg) - (GCPtrCode + offSrc + 4));
1017	break;
1018	}
1019
1020	/*
1021	* 32-bit relative, source in GC and target in ID.
1022	*/
1023	case FIX_GC_2_ID_NEAR_REL:
1024	{
1025	Assert(offSrc - pSwitcher->offGCCode < pSwitcher->cbGCCode);
1026	uint32_t offTrg = *u.pu32++;
1027	Assert(offTrg - pSwitcher->offIDCode0 < pSwitcher->cbIDCode0 \|\| offTrg - pSwitcher->offIDCode1 < pSwitcher->cbIDCode1);
1028	*uSrc.pu32 = (uint32_t)((u32IDCode + offTrg) - (GCPtrCode + offSrc + 4));
1029	break;
1030	}
1031
1032	/*
1033	* 32-bit relative, source in ID and target in HC.
1034	*/
1035	case FIX_ID_2_HC_NEAR_REL:
1036	{
1037	Assert(offSrc - pSwitcher->offIDCode0 < pSwitcher->cbIDCode0 \|\| offSrc - pSwitcher->offIDCode1 < pSwitcher->cbIDCode1);
1038	uint32_t offTrg = *u.pu32++;
1039	Assert(offTrg - pSwitcher->offHCCode0 < pSwitcher->cbHCCode0 \|\| offTrg - pSwitcher->offHCCode1 < pSwitcher->cbHCCode1);
1040	*uSrc.pu32 = (uint32_t)(((uintptr_t)pu8CodeR0 + offTrg) - (u32IDCode + offSrc + 4));
1041	break;
1042	}
1043
1044	/*
1045	* 32-bit relative, source in ID and target in HC.
1046	*/
1047	case FIX_ID_2_GC_NEAR_REL:
1048	{
1049	Assert(offSrc - pSwitcher->offIDCode0 < pSwitcher->cbIDCode0 \|\| offSrc - pSwitcher->offIDCode1 < pSwitcher->cbIDCode1);
1050	uint32_t offTrg = *u.pu32++;
1051	Assert(offTrg - pSwitcher->offGCCode < pSwitcher->cbGCCode);
1052	*uSrc.pu32 = (uint32_t)((GCPtrCode + offTrg) - (u32IDCode + offSrc + 4));
1053	break;
1054	}
1055
1056	/*
1057	* 16:32 far jump, target in GC.
1058	*/
1059	case FIX_GC_FAR32:
1060	{
1061	uint32_t offTrg = *u.pu32++;
1062	Assert(offTrg - pSwitcher->offGCCode < pSwitcher->cbGCCode);
1063	*uSrc.pu32++ = (uint32_t)(GCPtrCode + offTrg);
1064	*uSrc.pu16++ = SelCS;
1065	break;
1066	}
1067
1068	/*
1069	* Make 32-bit GC pointer given CPUM offset.
1070	*/
1071	case FIX_GC_CPUM_OFF:
1072	{
1073	uint32_t offCPUM = *u.pu32++;
1074	Assert(offCPUM < sizeof(pVM->cpum));
1075	*uSrc.pu32 = (uint32_t)(VM_GUEST_ADDR(pVM, &pVM->cpum) + offCPUM);
1076	break;
1077	}
1078
1079	/*
1080	* Make 32-bit GC pointer given VM offset.
1081	*/
1082	case FIX_GC_VM_OFF:
1083	{
1084	uint32_t offVM = *u.pu32++;
1085	Assert(offVM < sizeof(VM));
1086	*uSrc.pu32 = (uint32_t)(VM_GUEST_ADDR(pVM, pVM) + offVM);
1087	break;
1088	}
1089
1090	/*
1091	* Make 32-bit HC pointer given CPUM offset.
1092	*/
1093	case FIX_HC_CPUM_OFF:
1094	{
1095	uint32_t offCPUM = *u.pu32++;
1096	Assert(offCPUM < sizeof(pVM->cpum));
1097	*uSrc.pu32 = (uint32_t)pVM->pVMR0 + RT_OFFSETOF(VM, cpum) + offCPUM;
1098	break;
1099	}
1100
1101	/*
1102	* Make 32-bit R0 pointer given VM offset.
1103	*/
1104	case FIX_HC_VM_OFF:
1105	{
1106	uint32_t offVM = *u.pu32++;
1107	Assert(offVM < sizeof(VM));
1108	*uSrc.pu32 = (uint32_t)pVM->pVMR0 + offVM;
1109	break;
1110	}
1111
1112	/*
1113	* Store the 32-Bit CR3 (32-bit) for the intermediate memory context.
1114	*/
1115	case FIX_INTER_32BIT_CR3:
1116	{
1117
1118	*uSrc.pu32 = PGMGetInter32BitCR3(pVM);
1119	break;
1120	}
1121
1122	/*
1123	* Store the PAE CR3 (32-bit) for the intermediate memory context.
1124	*/
1125	case FIX_INTER_PAE_CR3:
1126	{
1127
1128	*uSrc.pu32 = PGMGetInterPaeCR3(pVM);
1129	break;
1130	}
1131
1132	/*
1133	* Store the AMD64 CR3 (32-bit) for the intermediate memory context.
1134	*/
1135	case FIX_INTER_AMD64_CR3:
1136	{
1137
1138	*uSrc.pu32 = PGMGetInterAmd64CR3(pVM);
1139	break;
1140	}
1141
1142	/*
1143	* Store the 32-Bit CR3 (32-bit) for the hypervisor (shadow) memory context.
1144	*/
1145	case FIX_HYPER_32BIT_CR3:
1146	{
1147
1148	*uSrc.pu32 = PGMGetHyper32BitCR3(pVM);
1149	break;
1150	}
1151
1152	/*
1153	* Store the PAE CR3 (32-bit) for the hypervisor (shadow) memory context.
1154	*/
1155	case FIX_HYPER_PAE_CR3:
1156	{
1157
1158	*uSrc.pu32 = PGMGetHyperPaeCR3(pVM);
1159	break;
1160	}
1161
1162	/*
1163	* Store the AMD64 CR3 (32-bit) for the hypervisor (shadow) memory context.
1164	*/
1165	case FIX_HYPER_AMD64_CR3:
1166	{
1167
1168	*uSrc.pu32 = PGMGetHyperAmd64CR3(pVM);
1169	break;
1170	}
1171
1172	/*
1173	* Store Hypervisor CS (16-bit).
1174	*/
1175	case FIX_HYPER_CS:
1176	{
1177	*uSrc.pu16 = SelCS;
1178	break;
1179	}
1180
1181	/*
1182	* Store Hypervisor DS (16-bit).
1183	*/
1184	case FIX_HYPER_DS:
1185	{
1186	*uSrc.pu16 = SelDS;
1187	break;
1188	}
1189
1190	/*
1191	* Store Hypervisor TSS (16-bit).
1192	*/
1193	case FIX_HYPER_TSS:
1194	{
1195	*uSrc.pu16 = SelTSS;
1196	break;
1197	}
1198
1199	/*
1200	* Store the 32-bit GC address of the 2nd dword of the TSS descriptor (in the GDT).
1201	*/
1202	case FIX_GC_TSS_GDTE_DW2:
1203	{
1204	RTGCPTR GCPtr = GCPtrGDT + (SelTSS & ~7) + 4;
1205	*uSrc.pu32 = (uint32_t)GCPtr;
1206	break;
1207	}
1208
1209
1210	///@todo case FIX_CR4_MASK:
1211	///@todo case FIX_CR4_OSFSXR:
1212
1213	/*
1214	* Insert relative jump to specified target it FXSAVE/FXRSTOR isn't supported by the cpu.
1215	*/
1216	case FIX_NO_FXSAVE_JMP:
1217	{
1218	uint32_t offTrg = *u.pu32++;
1219	Assert(offTrg < pSwitcher->cbCode);
1220	if (!CPUMSupportsFXSR(pVM))
1221	{
1222	uSrc.pu8++ = 0xe9; / jmp rel32 */
1223	*uSrc.pu32++ = offTrg - (offSrc + 5);
1224	}
1225	else
1226	{
1227	uSrc.pu8++ = ((uint8_t *)pSwitcher->pvCode + offSrc);
1228	uSrc.pu32++ = (uint32_t )((uint8_t )pSwitcher->pvCode + offSrc + 1);
1229	}
1230	break;
1231	}
1232
1233	/*
1234	* Insert relative jump to specified target it SYSENTER isn't used by the host.
1235	*/
1236	case FIX_NO_SYSENTER_JMP:
1237	{
1238	uint32_t offTrg = *u.pu32++;
1239	Assert(offTrg < pSwitcher->cbCode);
1240	if (!CPUMIsHostUsingSysEnter(pVM))
1241	{
1242	uSrc.pu8++ = 0xe9; / jmp rel32 */
1243	*uSrc.pu32++ = offTrg - (offSrc + 5);
1244	}
1245	else
1246	{
1247	uSrc.pu8++ = ((uint8_t *)pSwitcher->pvCode + offSrc);
1248	uSrc.pu32++ = (uint32_t )((uint8_t )pSwitcher->pvCode + offSrc + 1);
1249	}
1250	break;
1251	}
1252
1253	/*
1254	* Insert relative jump to specified target it SYSENTER isn't used by the host.
1255	*/
1256	case FIX_NO_SYSCALL_JMP:
1257	{
1258	uint32_t offTrg = *u.pu32++;
1259	Assert(offTrg < pSwitcher->cbCode);
1260	if (!CPUMIsHostUsingSysEnter(pVM))
1261	{
1262	uSrc.pu8++ = 0xe9; / jmp rel32 */
1263	*uSrc.pu32++ = offTrg - (offSrc + 5);
1264	}
1265	else
1266	{
1267	uSrc.pu8++ = ((uint8_t *)pSwitcher->pvCode + offSrc);
1268	uSrc.pu32++ = (uint32_t )((uint8_t )pSwitcher->pvCode + offSrc + 1);
1269	}
1270	break;
1271	}
1272
1273	/*
1274	* 32-bit HC pointer fixup to (HC) target within the code (32-bit offset).
1275	*/
1276	case FIX_HC_32BIT:
1277	{
1278	uint32_t offTrg = *u.pu32++;
1279	Assert(offSrc < pSwitcher->cbCode);
1280	Assert(offTrg - pSwitcher->offHCCode0 < pSwitcher->cbHCCode0 \|\| offTrg - pSwitcher->offHCCode1 < pSwitcher->cbHCCode1);
1281	*uSrc.pu32 = (uintptr_t)pu8CodeR0 + offTrg;
1282	break;
1283	}
1284
1285	#if defined(RT_ARCH_AMD64) \|\| defined(VBOX_WITH_HYBIRD_32BIT_KERNEL)
1286	/*
1287	* 64-bit HC pointer fixup to (HC) target within the code (32-bit offset).
1288	*/
1289	case FIX_HC_64BIT:
1290	{
1291	uint32_t offTrg = *u.pu32++;
1292	Assert(offSrc < pSwitcher->cbCode);
1293	Assert(offTrg - pSwitcher->offHCCode0 < pSwitcher->cbHCCode0 \|\| offTrg - pSwitcher->offHCCode1 < pSwitcher->cbHCCode1);
1294	*uSrc.pu64 = (uintptr_t)pu8CodeR0 + offTrg;
1295	break;
1296	}
1297
1298	/*
1299	* 64-bit HC Code Selector (no argument).
1300	*/
1301	case FIX_HC_64BIT_CS:
1302	{
1303	Assert(offSrc < pSwitcher->cbCode);
1304	#if defined(RT_OS_DARWIN) && defined(VBOX_WITH_HYBIRD_32BIT_KERNEL)
1305	uSrc.pu16 = 0x80; / KERNEL64_CS from i386/seg.h */
1306	#else
1307	AssertFatalMsgFailed(("FIX_HC_64BIT_CS not implemented for this host\n"));
1308	#endif
1309	break;
1310	}
1311
1312	/*
1313	* 64-bit HC pointer to the CPUM instance data (no argument).
1314	*/
1315	case FIX_HC_64BIT_CPUM:
1316	{
1317	Assert(offSrc < pSwitcher->cbCode);
1318	*uSrc.pu64 = pVM->pVMR0 + RT_OFFSETOF(VM, cpum);
1319	break;
1320	}
1321	#endif
1322
1323	/*
1324	* 32-bit ID pointer to (ID) target within the code (32-bit offset).
1325	*/
1326	case FIX_ID_32BIT:
1327	{
1328	uint32_t offTrg = *u.pu32++;
1329	Assert(offSrc < pSwitcher->cbCode);
1330	Assert(offTrg - pSwitcher->offIDCode0 < pSwitcher->cbIDCode0 \|\| offTrg - pSwitcher->offIDCode1 < pSwitcher->cbIDCode1);
1331	*uSrc.pu32 = u32IDCode + offTrg;
1332	break;
1333	}
1334
1335	/*
1336	* 64-bit ID pointer to (ID) target within the code (32-bit offset).
1337	*/
1338	case FIX_ID_64BIT:
1339	{
1340	uint32_t offTrg = *u.pu32++;
1341	Assert(offSrc < pSwitcher->cbCode);
1342	Assert(offTrg - pSwitcher->offIDCode0 < pSwitcher->cbIDCode0 \|\| offTrg - pSwitcher->offIDCode1 < pSwitcher->cbIDCode1);
1343	*uSrc.pu64 = u32IDCode + offTrg;
1344	break;
1345	}
1346
1347	/*
1348	* Far 16:32 ID pointer to 64-bit mode (ID) target within the code (32-bit offset).
1349	*/
1350	case FIX_ID_FAR32_TO_64BIT_MODE:
1351	{
1352	uint32_t offTrg = *u.pu32++;
1353	Assert(offSrc < pSwitcher->cbCode);
1354	Assert(offTrg - pSwitcher->offIDCode0 < pSwitcher->cbIDCode0 \|\| offTrg - pSwitcher->offIDCode1 < pSwitcher->cbIDCode1);
1355	*uSrc.pu32++ = u32IDCode + offTrg;
1356	*uSrc.pu16 = SelCS64;
1357	AssertRelease(SelCS64);
1358	break;
1359	}
1360
1361	#ifdef VBOX_WITH_NMI
1362	/*
1363	* 32-bit address to the APIC base.
1364	*/
1365	case FIX_GC_APIC_BASE_32BIT:
1366	{
1367	*uSrc.pu32 = pVM->vmm.s.GCPtrApicBase;
1368	break;
1369	}
1370	#endif
1371
1372	default:
1373	AssertReleaseMsgFailed(("Unknown fixup %d in switcher %s\n", u8, pSwitcher->pszDesc));
1374	break;
1375	}
1376	}
1377
1378	#ifdef LOG_ENABLED
1379	/*
1380	* If Log2 is enabled disassemble the switcher code.
1381	*
1382	* The switcher code have 1-2 HC parts, 1 GC part and 0-2 ID parts.
1383	*/
1384	if (LogIs2Enabled())
1385	{
1386	RTLogPrintf("* Disassembly of switcher %d '%s' %#x bytes *\n"
1387	" pu8CodeR0 = %p\n"
1388	" pu8CodeR3 = %p\n"
1389	" GCPtrCode = %VGv\n"
1390	" u32IDCode = %08x\n"
1391	" pVMGC = %VGv\n"
1392	" pCPUMGC = %VGv\n"
1393	" pVMHC = %p\n"
1394	" pCPUMHC = %p\n"
1395	" GCPtrGDT = %VGv\n"
1396	" InterCR3s = %08x, %08x, %08x (32-Bit, PAE, AMD64)\n"
1397	" HyperCR3s = %08x, %08x, %08x (32-Bit, PAE, AMD64)\n"
1398	" SelCS = %04x\n"
1399	" SelDS = %04x\n"
1400	" SelCS64 = %04x\n"
1401	" SelTSS = %04x\n",
1402	pSwitcher->enmType, pSwitcher->pszDesc, pSwitcher->cbCode,
1403	pu8CodeR0, pu8CodeR3, GCPtrCode, u32IDCode, VM_GUEST_ADDR(pVM, pVM),
1404	VM_GUEST_ADDR(pVM, &pVM->cpum), pVM, &pVM->cpum,
1405	GCPtrGDT,
1406	PGMGetHyper32BitCR3(pVM), PGMGetHyperPaeCR3(pVM), PGMGetHyperAmd64CR3(pVM),
1407	PGMGetInter32BitCR3(pVM), PGMGetInterPaeCR3(pVM), PGMGetInterAmd64CR3(pVM),
1408	SelCS, SelDS, SelCS64, SelTSS);
1409
1410	uint32_t offCode = 0;
1411	while (offCode < pSwitcher->cbCode)
1412	{
1413	/*
1414	* Figure out where this is.
1415	*/
1416	const char *pszDesc = NULL;
1417	RTUINTPTR uBase;
1418	uint32_t cbCode;
1419	if (offCode - pSwitcher->offHCCode0 < pSwitcher->cbHCCode0)
1420	{
1421	pszDesc = "HCCode0";
1422	uBase = (RTUINTPTR)pu8CodeR0;
1423	offCode = pSwitcher->offHCCode0;
1424	cbCode = pSwitcher->cbHCCode0;
1425	}
1426	else if (offCode - pSwitcher->offHCCode1 < pSwitcher->cbHCCode1)
1427	{
1428	pszDesc = "HCCode1";
1429	uBase = (RTUINTPTR)pu8CodeR0;
1430	offCode = pSwitcher->offHCCode1;
1431	cbCode = pSwitcher->cbHCCode1;
1432	}
1433	else if (offCode - pSwitcher->offGCCode < pSwitcher->cbGCCode)
1434	{
1435	pszDesc = "GCCode";
1436	uBase = GCPtrCode;
1437	offCode = pSwitcher->offGCCode;
1438	cbCode = pSwitcher->cbGCCode;
1439	}
1440	else if (offCode - pSwitcher->offIDCode0 < pSwitcher->cbIDCode0)
1441	{
1442	pszDesc = "IDCode0";
1443	uBase = u32IDCode;
1444	offCode = pSwitcher->offIDCode0;
1445	cbCode = pSwitcher->cbIDCode0;
1446	}
1447	else if (offCode - pSwitcher->offIDCode1 < pSwitcher->cbIDCode1)
1448	{
1449	pszDesc = "IDCode1";
1450	uBase = u32IDCode;
1451	offCode = pSwitcher->offIDCode1;
1452	cbCode = pSwitcher->cbIDCode1;
1453	}
1454	else
1455	{
1456	RTLogPrintf(" %04x: %02x '%c' (nowhere)\n",
1457	offCode, pu8CodeR3[offCode], isprint(pu8CodeR3[offCode]) ? pu8CodeR3[offCode] : ' ');
1458	offCode++;
1459	continue;
1460	}
1461
1462	/*
1463	* Disassemble it.
1464	*/
1465	RTLogPrintf(" %s: offCode=%#x cbCode=%#x\n", pszDesc, offCode, cbCode);
1466	DISCPUSTATE Cpu;
1467
1468	memset(&Cpu, 0, sizeof(Cpu));
1469	Cpu.mode = CPUMODE_32BIT;
1470	while (cbCode > 0)
1471	{
1472	/* try label it */
1473	if (pSwitcher->offR0HostToGuest == offCode)
1474	RTLogPrintf(" *R0HostToGuest:\n");
1475	if (pSwitcher->offGCGuestToHost == offCode)
1476	RTLogPrintf(" *GCGuestToHost:\n");
1477	if (pSwitcher->offGCCallTrampoline == offCode)
1478	RTLogPrintf(" *GCCallTrampoline:\n");
1479	if (pSwitcher->offGCGuestToHostAsm == offCode)
1480	RTLogPrintf(" *GCGuestToHostAsm:\n");
1481	if (pSwitcher->offGCGuestToHostAsmHyperCtx == offCode)
1482	RTLogPrintf(" *GCGuestToHostAsmHyperCtx:\n");
1483	if (pSwitcher->offGCGuestToHostAsmGuestCtx == offCode)
1484	RTLogPrintf(" *GCGuestToHostAsmGuestCtx:\n");
1485
1486	/* disas */
1487	uint32_t cbInstr = 0;
1488	char szDisas[256];
1489	if (RT_SUCCESS(DISInstr(&Cpu, (RTUINTPTR)pu8CodeR3 + offCode, uBase - (RTUINTPTR)pu8CodeR3, &cbInstr, szDisas)))
1490	RTLogPrintf(" %04x: %s", offCode, szDisas); //for whatever reason szDisas includes '\n'.
1491	else
1492	{
1493	RTLogPrintf(" %04x: %02x '%c'\n",
1494	offCode, pu8CodeR3[offCode], isprint(pu8CodeR3[offCode]) ? pu8CodeR3[offCode] : ' ');
1495	cbInstr = 1;
1496	}
1497	offCode += cbInstr;
1498	cbCode -= RT_MIN(cbInstr, cbCode);
1499	}
1500	}
1501	}
1502	#endif
1503	}
1504
1505
1506	/**
1507	* Relocator for the 32-Bit to 32-Bit world switcher.
1508	*/
1509	DECLCALLBACK(void) vmmR3Switcher32BitTo32Bit_Relocate(PVM pVM, PVMMSWITCHERDEF pSwitcher, uint8_t pu8CodeR0, uint8_t pu8CodeR3, RTGCPTR GCPtrCode, uint32_t u32IDCode)
1510	{
1511	vmmR3SwitcherGenericRelocate(pVM, pSwitcher, pu8CodeR0, pu8CodeR3, GCPtrCode, u32IDCode,
1512	SELMGetHyperCS(pVM), SELMGetHyperDS(pVM), SELMGetHyperTSS(pVM), SELMGetHyperGDT(pVM), 0);
1513	}
1514
1515
1516	/**
1517	* Relocator for the 32-Bit to PAE world switcher.
1518	*/
1519	DECLCALLBACK(void) vmmR3Switcher32BitToPAE_Relocate(PVM pVM, PVMMSWITCHERDEF pSwitcher, uint8_t pu8CodeR0, uint8_t pu8CodeR3, RTGCPTR GCPtrCode, uint32_t u32IDCode)
1520	{
1521	vmmR3SwitcherGenericRelocate(pVM, pSwitcher, pu8CodeR0, pu8CodeR3, GCPtrCode, u32IDCode,
1522	SELMGetHyperCS(pVM), SELMGetHyperDS(pVM), SELMGetHyperTSS(pVM), SELMGetHyperGDT(pVM), 0);
1523	}
1524
1525
1526	/**
1527	* Relocator for the PAE to 32-Bit world switcher.
1528	*/
1529	DECLCALLBACK(void) vmmR3SwitcherPAETo32Bit_Relocate(PVM pVM, PVMMSWITCHERDEF pSwitcher, uint8_t pu8CodeR0, uint8_t pu8CodeR3, RTGCPTR GCPtrCode, uint32_t u32IDCode)
1530	{
1531	vmmR3SwitcherGenericRelocate(pVM, pSwitcher, pu8CodeR0, pu8CodeR3, GCPtrCode, u32IDCode,
1532	SELMGetHyperCS(pVM), SELMGetHyperDS(pVM), SELMGetHyperTSS(pVM), SELMGetHyperGDT(pVM), 0);
1533	}
1534
1535
1536	/**
1537	* Relocator for the PAE to PAE world switcher.
1538	*/
1539	DECLCALLBACK(void) vmmR3SwitcherPAEToPAE_Relocate(PVM pVM, PVMMSWITCHERDEF pSwitcher, uint8_t pu8CodeR0, uint8_t pu8CodeR3, RTGCPTR GCPtrCode, uint32_t u32IDCode)
1540	{
1541	vmmR3SwitcherGenericRelocate(pVM, pSwitcher, pu8CodeR0, pu8CodeR3, GCPtrCode, u32IDCode,
1542	SELMGetHyperCS(pVM), SELMGetHyperDS(pVM), SELMGetHyperTSS(pVM), SELMGetHyperGDT(pVM), 0);
1543	}
1544
1545
1546	/**
1547	* Relocator for the AMD64 to PAE world switcher.
1548	*/
1549	DECLCALLBACK(void) vmmR3SwitcherAMD64ToPAE_Relocate(PVM pVM, PVMMSWITCHERDEF pSwitcher, uint8_t pu8CodeR0, uint8_t pu8CodeR3, RTGCPTR GCPtrCode, uint32_t u32IDCode)
1550	{
1551	vmmR3SwitcherGenericRelocate(pVM, pSwitcher, pu8CodeR0, pu8CodeR3, GCPtrCode, u32IDCode,
1552	SELMGetHyperCS(pVM), SELMGetHyperDS(pVM), SELMGetHyperTSS(pVM), SELMGetHyperGDT(pVM), SELMGetHyperCS64(pVM));
1553	}
1554
1555
1556	/**
1557	* Gets the pointer to g_szRTAssertMsg1 in GC.
1558	* @returns Pointer to VMMGC::g_szRTAssertMsg1.
1559	* Returns NULL if not present.
1560	* @param pVM The VM handle.
1561	*/
1562	VMMR3DECL(const char *) VMMR3GetGCAssertMsg1(PVM pVM)
1563	{
1564	RTGCPTR GCPtr;
1565	int rc = PDMR3GetSymbolGC(pVM, NULL, "g_szRTAssertMsg1", &GCPtr);
1566	if (VBOX_SUCCESS(rc))
1567	return (const char *)MMHyperGC2HC(pVM, GCPtr);
1568	return NULL;
1569	}
1570
1571
1572	/**
1573	* Gets the pointer to g_szRTAssertMsg2 in GC.
1574	* @returns Pointer to VMMGC::g_szRTAssertMsg2.
1575	* Returns NULL if not present.
1576	* @param pVM The VM handle.
1577	*/
1578	VMMR3DECL(const char *) VMMR3GetGCAssertMsg2(PVM pVM)
1579	{
1580	RTGCPTR GCPtr;
1581	int rc = PDMR3GetSymbolGC(pVM, NULL, "g_szRTAssertMsg2", &GCPtr);
1582	if (VBOX_SUCCESS(rc))
1583	return (const char *)MMHyperGC2HC(pVM, GCPtr);
1584	return NULL;
1585	}
1586
1587
1588	/**
1589	* Execute state save operation.
1590	*
1591	* @returns VBox status code.
1592	* @param pVM VM Handle.
1593	* @param pSSM SSM operation handle.
1594	*/
1595	static DECLCALLBACK(int) vmmR3Save(PVM pVM, PSSMHANDLE pSSM)
1596	{
1597	LogFlow(("vmmR3Save:\n"));
1598
1599	/*
1600	* The hypervisor stack.
1601	*/
1602	SSMR3PutGCPtr(pSSM, pVM->vmm.s.pbGCStackBottom);
1603	RTGCPTR GCPtrESP = CPUMGetHyperESP(pVM);
1604	Assert(pVM->vmm.s.pbGCStackBottom - GCPtrESP <= VMM_STACK_SIZE);
1605	SSMR3PutGCPtr(pSSM, GCPtrESP);
1606	SSMR3PutMem(pSSM, pVM->vmm.s.pbHCStack, VMM_STACK_SIZE);
1607	return SSMR3PutU32(pSSM, ~0); /* terminator */
1608	}
1609
1610
1611	/**
1612	* Execute state load operation.
1613	*
1614	* @returns VBox status code.
1615	* @param pVM VM Handle.
1616	* @param pSSM SSM operation handle.
1617	* @param u32Version Data layout version.
1618	*/
1619	static DECLCALLBACK(int) vmmR3Load(PVM pVM, PSSMHANDLE pSSM, uint32_t u32Version)
1620	{
1621	LogFlow(("vmmR3Load:\n"));
1622
1623	/*
1624	* Validate version.
1625	*/
1626	if (u32Version != VMM_SAVED_STATE_VERSION)
1627	{
1628	Log(("vmmR3Load: Invalid version u32Version=%d!\n", u32Version));
1629	return VERR_SSM_UNSUPPORTED_DATA_UNIT_VERSION;
1630	}
1631
1632	/*
1633	* Check that the stack is in the same place, or that it's fearly empty.
1634	*/
1635	RTGCPTR GCPtrStackBottom;
1636	SSMR3GetGCPtr(pSSM, &GCPtrStackBottom);
1637	RTGCPTR GCPtrESP;
1638	int rc = SSMR3GetGCPtr(pSSM, &GCPtrESP);
1639	if (VBOX_FAILURE(rc))
1640	return rc;
1641	if ( GCPtrStackBottom == pVM->vmm.s.pbGCStackBottom
1642	\|\| (GCPtrStackBottom - GCPtrESP < 32)) /** @todo This will break if we start preemting the hypervisor. */
1643	{
1644	/*
1645	* We must set the ESP because the CPUM load + PGM load relocations will render
1646	* the ESP in CPUM fatally invalid.
1647	*/
1648	CPUMSetHyperESP(pVM, GCPtrESP);
1649
1650	/* restore the stack. */
1651	SSMR3GetMem(pSSM, pVM->vmm.s.pbHCStack, VMM_STACK_SIZE);
1652
1653	/* terminator */
1654	uint32_t u32;
1655	rc = SSMR3GetU32(pSSM, &u32);
1656	if (VBOX_FAILURE(rc))
1657	return rc;
1658	if (u32 != ~0U)
1659	{
1660	AssertMsgFailed(("u32=%#x\n", u32));
1661	return VERR_SSM_DATA_UNIT_FORMAT_CHANGED;
1662	}
1663	return VINF_SUCCESS;
1664	}
1665
1666	LogRel(("The stack is not in the same place and it's not empty! GCPtrStackBottom=%VGv pbGCStackBottom=%VGv ESP=%VGv\n",
1667	GCPtrStackBottom, pVM->vmm.s.pbGCStackBottom, GCPtrESP));
1668	if (SSMR3HandleGetAfter(pSSM) == SSMAFTER_DEBUG_IT)
1669	return VINF_SUCCESS; /* ignore this */
1670	AssertFailed();
1671	return VERR_SSM_LOAD_CONFIG_MISMATCH;
1672	}
1673
1674
1675	/**
1676	* Selects the switcher to be used for switching to GC.
1677	*
1678	* @returns VBox status code.
1679	* @param pVM VM handle.
1680	* @param enmSwitcher The new switcher.
1681	* @remark This function may be called before the VMM is initialized.
1682	*/
1683	VMMR3DECL(int) VMMR3SelectSwitcher(PVM pVM, VMMSWITCHER enmSwitcher)
1684	{
1685	/*
1686	* Validate input.
1687	*/
1688	if ( enmSwitcher < VMMSWITCHER_INVALID
1689	\|\| enmSwitcher >= VMMSWITCHER_MAX)
1690	{
1691	AssertMsgFailed(("Invalid input enmSwitcher=%d\n", enmSwitcher));
1692	return VERR_INVALID_PARAMETER;
1693	}
1694
1695	/*
1696	* Select the new switcher.
1697	*/
1698	PVMMSWITCHERDEF pSwitcher = s_apSwitchers[enmSwitcher];
1699	if (pSwitcher)
1700	{
1701	Log(("VMMR3SelectSwitcher: enmSwitcher %d -> %d %s\n", pVM->vmm.s.enmSwitcher, enmSwitcher, pSwitcher->pszDesc));
1702	pVM->vmm.s.enmSwitcher = enmSwitcher;
1703
1704	RTR0PTR pbCodeR0 = (RTR0PTR)pVM->vmm.s.pvHCCoreCodeR0 + pVM->vmm.s.aoffSwitchers[enmSwitcher]; /** @todo fix the pvHCCoreCodeR0 type */
1705	pVM->vmm.s.pfnR0HostToGuest = pbCodeR0 + pSwitcher->offR0HostToGuest;
1706
1707	RTGCPTR GCPtr = pVM->vmm.s.pvGCCoreCode + pVM->vmm.s.aoffSwitchers[enmSwitcher];
1708	pVM->vmm.s.pfnGCGuestToHost = GCPtr + pSwitcher->offGCGuestToHost;
1709	pVM->vmm.s.pfnGCCallTrampoline = GCPtr + pSwitcher->offGCCallTrampoline;
1710	pVM->pfnVMMGCGuestToHostAsm = GCPtr + pSwitcher->offGCGuestToHostAsm;
1711	pVM->pfnVMMGCGuestToHostAsmHyperCtx = GCPtr + pSwitcher->offGCGuestToHostAsmHyperCtx;
1712	pVM->pfnVMMGCGuestToHostAsmGuestCtx = GCPtr + pSwitcher->offGCGuestToHostAsmGuestCtx;
1713	return VINF_SUCCESS;
1714	}
1715	return VERR_NOT_IMPLEMENTED;
1716	}
1717
1718	/**
1719	* Disable the switcher logic permanently.
1720	*
1721	* @returns VBox status code.
1722	* @param pVM VM handle.
1723	*/
1724	VMMR3DECL(int) VMMR3DisableSwitcher(PVM pVM)
1725	{
1726	/** @todo r=bird: I would suggest that we create a dummy switcher which just does something like:
1727	* @code
1728	* mov eax, VERR_INTERNAL_ERROR
1729	* ret
1730	* @endcode
1731	* And then check for fSwitcherDisabled in VMMR3SelectSwitcher() in order to prevent it from being removed.
1732	*/
1733	pVM->vmm.s.fSwitcherDisabled = true;
1734	return VINF_SUCCESS;
1735	}
1736
1737
1738	/**
1739	* Resolve a builtin GC symbol.
1740	* Called by PDM when loading or relocating GC modules.
1741	*
1742	* @returns VBox status
1743	* @param pVM VM Handle.
1744	* @param pszSymbol Symbol to resolv
1745	* @param pGCPtrValue Where to store the symbol value.
1746	* @remark This has to work before VMMR3Relocate() is called.
1747	*/
1748	VMMR3DECL(int) VMMR3GetImportGC(PVM pVM, const char *pszSymbol, PRTGCPTR pGCPtrValue)
1749	{
1750	if (!strcmp(pszSymbol, "g_Logger"))
1751	{
1752	if (pVM->vmm.s.pLoggerHC)
1753	pVM->vmm.s.pLoggerGC = MMHyperHC2GC(pVM, pVM->vmm.s.pLoggerHC);
1754	*pGCPtrValue = pVM->vmm.s.pLoggerGC;
1755	}
1756	else if (!strcmp(pszSymbol, "g_RelLogger"))
1757	{
1758	#ifdef VBOX_WITH_GC_AND_R0_RELEASE_LOG
1759	if (pVM->vmm.s.pRelLoggerHC)
1760	pVM->vmm.s.pRelLoggerGC = MMHyperHC2GC(pVM, pVM->vmm.s.pRelLoggerHC);
1761	*pGCPtrValue = pVM->vmm.s.pRelLoggerGC;
1762	#else
1763	*pGCPtrValue = NIL_RTGCPTR;
1764	#endif
1765	}
1766	else
1767	return VERR_SYMBOL_NOT_FOUND;
1768	return VINF_SUCCESS;
1769	}
1770
1771
1772	/**
1773	* Suspends the the CPU yielder.
1774	*
1775	* @param pVM The VM handle.
1776	*/
1777	VMMR3DECL(void) VMMR3YieldSuspend(PVM pVM)
1778	{
1779	if (!pVM->vmm.s.cYieldResumeMillies)
1780	{
1781	uint64_t u64Now = TMTimerGet(pVM->vmm.s.pYieldTimer);
1782	uint64_t u64Expire = TMTimerGetExpire(pVM->vmm.s.pYieldTimer);
1783	if (u64Now >= u64Expire \|\| u64Expire == ~(uint64_t)0)
1784	pVM->vmm.s.cYieldResumeMillies = pVM->vmm.s.cYieldEveryMillies;
1785	else
1786	pVM->vmm.s.cYieldResumeMillies = TMTimerToMilli(pVM->vmm.s.pYieldTimer, u64Expire - u64Now);
1787	TMTimerStop(pVM->vmm.s.pYieldTimer);
1788	}
1789	pVM->vmm.s.u64LastYield = RTTimeNanoTS();
1790	}
1791
1792
1793	/**
1794	* Stops the the CPU yielder.
1795	*
1796	* @param pVM The VM handle.
1797	*/
1798	VMMR3DECL(void) VMMR3YieldStop(PVM pVM)
1799	{
1800	if (!pVM->vmm.s.cYieldResumeMillies)
1801	TMTimerStop(pVM->vmm.s.pYieldTimer);
1802	pVM->vmm.s.cYieldResumeMillies = pVM->vmm.s.cYieldEveryMillies;
1803	pVM->vmm.s.u64LastYield = RTTimeNanoTS();
1804	}
1805
1806
1807	/**
1808	* Resumes the CPU yielder when it has been a suspended or stopped.
1809	*
1810	* @param pVM The VM handle.
1811	*/
1812	VMMR3DECL(void) VMMR3YieldResume(PVM pVM)
1813	{
1814	if (pVM->vmm.s.cYieldResumeMillies)
1815	{
1816	TMTimerSetMillies(pVM->vmm.s.pYieldTimer, pVM->vmm.s.cYieldResumeMillies);
1817	pVM->vmm.s.cYieldResumeMillies = 0;
1818	}
1819	}
1820
1821
1822	/**
1823	* Internal timer callback function.
1824	*
1825	* @param pVM The VM.
1826	* @param pTimer The timer handle.
1827	* @param pvUser User argument specified upon timer creation.
1828	*/
1829	static DECLCALLBACK(void) vmmR3YieldEMT(PVM pVM, PTMTIMER pTimer, void *pvUser)
1830	{
1831	/*
1832	* This really needs some careful tuning. While we shouldn't be too gready since
1833	* that'll cause the rest of the system to stop up, we shouldn't be too nice either
1834	* because that'll cause us to stop up.
1835	*
1836	* The current logic is to use the default interval when there is no lag worth
1837	* mentioning, but when we start accumulating lag we don't bother yielding at all.
1838	*
1839	* (This depends on the TMCLOCK_VIRTUAL_SYNC to be scheduled before TMCLOCK_REAL
1840	* so the lag is up to date.)
1841	*/
1842	const uint64_t u64Lag = TMVirtualSyncGetLag(pVM);
1843	if ( u64Lag < 50000000 /* 50ms */
1844	\|\| ( u64Lag < 1000000000 /* 1s */
1845	&& RTTimeNanoTS() - pVM->vmm.s.u64LastYield < 500000000 /* 500 ms */)
1846	)
1847	{
1848	uint64_t u64Elapsed = RTTimeNanoTS();
1849	pVM->vmm.s.u64LastYield = u64Elapsed;
1850
1851	RTThreadYield();
1852
1853	#ifdef LOG_ENABLED
1854	u64Elapsed = RTTimeNanoTS() - u64Elapsed;
1855	Log(("vmmR3YieldEMT: %RI64 ns\n", u64Elapsed));
1856	#endif
1857	}
1858	TMTimerSetMillies(pTimer, pVM->vmm.s.cYieldEveryMillies);
1859	}
1860
1861
1862	/**
1863	* Acquire global VM lock.
1864	*
1865	* @returns VBox status code
1866	* @param pVM The VM to operate on.
1867	*/
1868	VMMR3DECL(int) VMMR3Lock(PVM pVM)
1869	{
1870	return RTCritSectEnter(&pVM->vmm.s.CritSectVMLock);
1871	}
1872
1873
1874	/**
1875	* Release global VM lock.
1876	*
1877	* @returns VBox status code
1878	* @param pVM The VM to operate on.
1879	*/
1880	VMMR3DECL(int) VMMR3Unlock(PVM pVM)
1881	{
1882	return RTCritSectLeave(&pVM->vmm.s.CritSectVMLock);
1883	}
1884
1885
1886	/**
1887	* Return global VM lock owner.
1888	*
1889	* @returns Thread id of owner.
1890	* @returns NIL_RTTHREAD if no owner.
1891	* @param pVM The VM to operate on.
1892	*/
1893	VMMR3DECL(RTNATIVETHREAD) VMMR3LockGetOwner(PVM pVM)
1894	{
1895	return RTCritSectGetOwner(&pVM->vmm.s.CritSectVMLock);
1896	}
1897
1898
1899	/**
1900	* Checks if the current thread is the owner of the global VM lock.
1901	*
1902	* @returns true if owner.
1903	* @returns false if not owner.
1904	* @param pVM The VM to operate on.
1905	*/
1906	VMMR3DECL(bool) VMMR3LockIsOwner(PVM pVM)
1907	{
1908	return RTCritSectIsOwner(&pVM->vmm.s.CritSectVMLock);
1909	}
1910
1911
1912	/**
1913	* Executes guest code.
1914	*
1915	* @param pVM VM handle.
1916	*/
1917	VMMR3DECL(int) VMMR3RawRunGC(PVM pVM)
1918	{
1919	Log2(("VMMR3RawRunGC: (cs:eip=%04x:%08x)\n", CPUMGetGuestCS(pVM), CPUMGetGuestEIP(pVM)));
1920
1921	/*
1922	* Set the EIP and ESP.
1923	*/
1924	CPUMSetHyperEIP(pVM, CPUMGetGuestEFlags(pVM) & X86_EFL_VM
1925	? pVM->vmm.s.pfnCPUMGCResumeGuestV86
1926	: pVM->vmm.s.pfnCPUMGCResumeGuest);
1927	CPUMSetHyperESP(pVM, pVM->vmm.s.pbGCStackBottom);
1928
1929	/*
1930	* We hide log flushes (outer) and hypervisor interrupts (inner).
1931	*/
1932	for (;;)
1933	{
1934	int rc;
1935	do
1936	{
1937	#ifdef NO_SUPCALLR0VMM
1938	rc = VERR_GENERAL_FAILURE;
1939	#else
1940	rc = SUPCallVMMR0(pVM->pVMR0, VMMR0_DO_RAW_RUN, NULL);
1941	#endif
1942	} while (rc == VINF_EM_RAW_INTERRUPT_HYPER);
1943
1944	/*
1945	* Flush the logs.
1946	*/
1947	#ifdef LOG_ENABLED
1948	PRTLOGGERGC pLogger = pVM->vmm.s.pLoggerHC;
1949	if ( pLogger
1950	&& pLogger->offScratch > 0)
1951	RTLogFlushGC(NULL, pLogger);
1952	#endif
1953	#ifdef VBOX_WITH_GC_AND_R0_RELEASE_LOG
1954	PRTLOGGERGC pRelLogger = pVM->vmm.s.pRelLoggerHC;
1955	if (RT_UNLIKELY(pRelLogger && pRelLogger->offScratch > 0))
1956	RTLogFlushGC(RTLogRelDefaultInstance(), pRelLogger);
1957	#endif
1958	if (rc != VINF_VMM_CALL_HOST)
1959	{
1960	Log2(("VMMR3RawRunGC: returns %Vrc (cs:eip=%04x:%08x)\n", rc, CPUMGetGuestCS(pVM), CPUMGetGuestEIP(pVM)));
1961	return rc;
1962	}
1963	rc = vmmR3ServiceCallHostRequest(pVM);
1964	if (VBOX_FAILURE(rc))
1965	return rc;
1966	/* Resume GC */
1967	}
1968	}
1969
1970
1971	/**
1972	* Executes guest code (Intel VMX and AMD SVM).
1973	*
1974	* @param pVM VM handle.
1975	*/
1976	VMMR3DECL(int) VMMR3HwAccRunGC(PVM pVM)
1977	{
1978	Log2(("VMMR3HwAccRunGC: (cs:eip=%04x:%08x)\n", CPUMGetGuestCS(pVM), CPUMGetGuestEIP(pVM)));
1979
1980	for (;;)
1981	{
1982	int rc;
1983	do
1984	{
1985	#ifdef NO_SUPCALLR0VMM
1986	rc = VERR_GENERAL_FAILURE;
1987	#else
1988	rc = SUPCallVMMR0Fast(pVM->pVMR0, VMMR0_DO_HWACC_RUN);
1989	#endif
1990	} while (rc == VINF_EM_RAW_INTERRUPT_HYPER);
1991
1992	#ifdef LOG_ENABLED
1993	/*
1994	* Flush the log
1995	*/
1996	PVMMR0LOGGER pR0Logger = pVM->vmm.s.pR0Logger;
1997	if ( pR0Logger
1998	&& pR0Logger->Logger.offScratch > 0)
1999	RTLogFlushToLogger(&pR0Logger->Logger, NULL);
2000	#endif /* !LOG_ENABLED */
2001	if (rc != VINF_VMM_CALL_HOST)
2002	{
2003	Log2(("VMMR3HwAccRunGC: returns %Vrc (cs:eip=%04x:%08x)\n", rc, CPUMGetGuestCS(pVM), CPUMGetGuestEIP(pVM)));
2004	return rc;
2005	}
2006	rc = vmmR3ServiceCallHostRequest(pVM);
2007	if (VBOX_FAILURE(rc))
2008	return rc;
2009	/* Resume R0 */
2010	}
2011	}
2012
2013	/**
2014	* Calls GC a function.
2015	*
2016	* @param pVM The VM handle.
2017	* @param GCPtrEntry The GC function address.
2018	* @param cArgs The number of arguments in the ....
2019	* @param ... Arguments to the function.
2020	*/
2021	VMMR3DECL(int) VMMR3CallGC(PVM pVM, RTGCPTR GCPtrEntry, unsigned cArgs, ...)
2022	{
2023	va_list args;
2024	va_start(args, cArgs);
2025	int rc = VMMR3CallGCV(pVM, GCPtrEntry, cArgs, args);
2026	va_end(args);
2027	return rc;
2028	}
2029
2030
2031	/**
2032	* Calls GC a function.
2033	*
2034	* @param pVM The VM handle.
2035	* @param GCPtrEntry The GC function address.
2036	* @param cArgs The number of arguments in the ....
2037	* @param args Arguments to the function.
2038	*/
2039	VMMR3DECL(int) VMMR3CallGCV(PVM pVM, RTGCPTR GCPtrEntry, unsigned cArgs, va_list args)
2040	{
2041	Log2(("VMMR3CallGCV: GCPtrEntry=%VGv cArgs=%d\n", GCPtrEntry, cArgs));
2042
2043	/*
2044	* Setup the call frame using the trampoline.
2045	*/
2046	CPUMHyperSetCtxCore(pVM, NULL);
2047	memset(pVM->vmm.s.pbHCStack, 0xaa, VMM_STACK_SIZE); /* Clear the stack. */
2048	CPUMSetHyperESP(pVM, pVM->vmm.s.pbGCStackBottom - cArgs * sizeof(RTGCUINTPTR));
2049	PRTGCUINTPTR pFrame = (PRTGCUINTPTR)(pVM->vmm.s.pbHCStack + VMM_STACK_SIZE) - cArgs;
2050	int i = cArgs;
2051	while (i-- > 0)
2052	*pFrame++ = va_arg(args, RTGCUINTPTR);
2053
2054	CPUMPushHyper(pVM, cArgs * sizeof(RTGCUINTPTR)); /* stack frame size */
2055	CPUMPushHyper(pVM, GCPtrEntry); /* what to call */
2056	CPUMSetHyperEIP(pVM, pVM->vmm.s.pfnGCCallTrampoline);
2057
2058	/*
2059	* We hide log flushes (outer) and hypervisor interrupts (inner).
2060	*/
2061	for (;;)
2062	{
2063	int rc;
2064	do
2065	{
2066	#ifdef NO_SUPCALLR0VMM
2067	rc = VERR_GENERAL_FAILURE;
2068	#else
2069	rc = SUPCallVMMR0(pVM->pVMR0, VMMR0_DO_RAW_RUN, NULL);
2070	#endif
2071	} while (rc == VINF_EM_RAW_INTERRUPT_HYPER);
2072
2073	/*
2074	* Flush the logs.
2075	*/
2076	#ifdef LOG_ENABLED
2077	PRTLOGGERGC pLogger = pVM->vmm.s.pLoggerHC;
2078	if ( pLogger
2079	&& pLogger->offScratch > 0)
2080	RTLogFlushGC(NULL, pLogger);
2081	#endif
2082	#ifdef VBOX_WITH_GC_AND_R0_RELEASE_LOG
2083	PRTLOGGERGC pRelLogger = pVM->vmm.s.pRelLoggerHC;
2084	if (RT_UNLIKELY(pRelLogger && pRelLogger->offScratch > 0))
2085	RTLogFlushGC(RTLogRelDefaultInstance(), pRelLogger);
2086	#endif
2087	if (rc == VERR_TRPM_PANIC \|\| rc == VERR_TRPM_DONT_PANIC)
2088	VMMR3FatalDump(pVM, rc);
2089	if (rc != VINF_VMM_CALL_HOST)
2090	{
2091	Log2(("VMMR3CallGCV: returns %Vrc (cs:eip=%04x:%08x)\n", rc, CPUMGetGuestCS(pVM), CPUMGetGuestEIP(pVM)));
2092	return rc;
2093	}
2094	rc = vmmR3ServiceCallHostRequest(pVM);
2095	if (VBOX_FAILURE(rc))
2096	return rc;
2097	}
2098	}
2099
2100
2101	/**
2102	* Resumes executing hypervisor code when interrupted
2103	* by a queue flush or a debug event.
2104	*
2105	* @returns VBox status code.
2106	* @param pVM VM handle.
2107	*/
2108	VMMR3DECL(int) VMMR3ResumeHyper(PVM pVM)
2109	{
2110	Log(("VMMR3ResumeHyper: eip=%VGv esp=%VGv\n", CPUMGetHyperEIP(pVM), CPUMGetHyperESP(pVM)));
2111
2112	/*
2113	* We hide log flushes (outer) and hypervisor interrupts (inner).
2114	*/
2115	for (;;)
2116	{
2117	int rc;
2118	do
2119	{
2120	#ifdef NO_SUPCALLR0VMM
2121	rc = VERR_GENERAL_FAILURE;
2122	#else
2123	rc = SUPCallVMMR0(pVM->pVMR0, VMMR0_DO_RAW_RUN, NULL);
2124	#endif
2125	} while (rc == VINF_EM_RAW_INTERRUPT_HYPER);
2126
2127	/*
2128	* Flush the loggers,
2129	*/
2130	#ifdef LOG_ENABLED
2131	PRTLOGGERGC pLogger = pVM->vmm.s.pLoggerHC;
2132	if ( pLogger
2133	&& pLogger->offScratch > 0)
2134	RTLogFlushGC(NULL, pLogger);
2135	#endif
2136	#ifdef VBOX_WITH_GC_AND_R0_RELEASE_LOG
2137	PRTLOGGERGC pRelLogger = pVM->vmm.s.pRelLoggerHC;
2138	if (RT_UNLIKELY(pRelLogger && pRelLogger->offScratch > 0))
2139	RTLogFlushGC(RTLogRelDefaultInstance(), pRelLogger);
2140	#endif
2141	if (rc == VERR_TRPM_PANIC \|\| rc == VERR_TRPM_DONT_PANIC)
2142	VMMR3FatalDump(pVM, rc);
2143	if (rc != VINF_VMM_CALL_HOST)
2144	{
2145	Log(("VMMR3ResumeHyper: returns %Vrc\n", rc));
2146	return rc;
2147	}
2148	rc = vmmR3ServiceCallHostRequest(pVM);
2149	if (VBOX_FAILURE(rc))
2150	return rc;
2151	}
2152	}
2153
2154
2155	/**
2156	* Service a call to the ring-3 host code.
2157	*
2158	* @returns VBox status code.
2159	* @param pVM VM handle.
2160	* @remark Careful with critsects.
2161	*/
2162	static int vmmR3ServiceCallHostRequest(PVM pVM)
2163	{
2164	switch (pVM->vmm.s.enmCallHostOperation)
2165	{
2166	/*
2167	* Acquire the PDM lock.
2168	*/
2169	case VMMCALLHOST_PDM_LOCK:
2170	{
2171	pVM->vmm.s.rcCallHost = PDMR3LockCall(pVM);
2172	break;
2173	}
2174
2175	/*
2176	* Flush a PDM queue.
2177	*/
2178	case VMMCALLHOST_PDM_QUEUE_FLUSH:
2179	{
2180	PDMR3QueueFlushWorker(pVM, NULL);
2181	pVM->vmm.s.rcCallHost = VINF_SUCCESS;
2182	break;
2183	}
2184
2185	/*
2186	* Grow the PGM pool.
2187	*/
2188	case VMMCALLHOST_PGM_POOL_GROW:
2189	{
2190	pVM->vmm.s.rcCallHost = PGMR3PoolGrow(pVM);
2191	break;
2192	}
2193
2194	/*
2195	* Maps an page allocation chunk into ring-3 so ring-0 can use it.
2196	*/
2197	case VMMCALLHOST_PGM_MAP_CHUNK:
2198	{
2199	pVM->vmm.s.rcCallHost = PGMR3PhysChunkMap(pVM, pVM->vmm.s.u64CallHostArg);
2200	break;
2201	}
2202
2203	/*
2204	* Allocates more handy pages.
2205	*/
2206	case VMMCALLHOST_PGM_ALLOCATE_HANDY_PAGES:
2207	{
2208	pVM->vmm.s.rcCallHost = PGMR3PhysAllocateHandyPages(pVM);
2209	break;
2210	}
2211	#ifndef VBOX_WITH_NEW_PHYS_CODE
2212
2213	case VMMCALLHOST_PGM_RAM_GROW_RANGE:
2214	{
2215	const RTGCPHYS GCPhys = pVM->vmm.s.u64CallHostArg;
2216	pVM->vmm.s.rcCallHost = PGM3PhysGrowRange(pVM, &GCPhys);
2217	break;
2218	}
2219	#endif
2220
2221	/*
2222	* Acquire the PGM lock.
2223	*/
2224	case VMMCALLHOST_PGM_LOCK:
2225	{
2226	pVM->vmm.s.rcCallHost = PGMR3LockCall(pVM);
2227	break;
2228	}
2229
2230	/*
2231	* Flush REM handler notifications.
2232	*/
2233	case VMMCALLHOST_REM_REPLAY_HANDLER_NOTIFICATIONS:
2234	{
2235	REMR3ReplayHandlerNotifications(pVM);
2236	break;
2237	}
2238
2239	/*
2240	* This is a noop. We just take this route to avoid unnecessary
2241	* tests in the loops.
2242	*/
2243	case VMMCALLHOST_VMM_LOGGER_FLUSH:
2244	break;
2245
2246	/*
2247	* Set the VM error message.
2248	*/
2249	case VMMCALLHOST_VM_SET_ERROR:
2250	VMR3SetErrorWorker(pVM);
2251	break;
2252
2253	/*
2254	* Set the VM runtime error message.
2255	*/
2256	case VMMCALLHOST_VM_SET_RUNTIME_ERROR:
2257	VMR3SetRuntimeErrorWorker(pVM);
2258	break;
2259
2260	/*
2261	* Signal a ring 0 hypervisor assertion.
2262	* Cancel the longjmp operation that's in progress.
2263	*/
2264	case VMMCALLHOST_VM_R0_HYPER_ASSERTION:
2265	pVM->vmm.s.CallHostR0JmpBuf.fInRing3Call = false;
2266	#ifdef RT_ARCH_X86
2267	pVM->vmm.s.CallHostR0JmpBuf.eip = 0;
2268	#else
2269	pVM->vmm.s.CallHostR0JmpBuf.rip = 0;
2270	#endif
2271	return VINF_EM_DBG_HYPER_ASSERTION;
2272
2273	default:
2274	AssertMsgFailed(("enmCallHostOperation=%d\n", pVM->vmm.s.enmCallHostOperation));
2275	return VERR_INTERNAL_ERROR;
2276	}
2277
2278	pVM->vmm.s.enmCallHostOperation = VMMCALLHOST_INVALID;
2279	return VINF_SUCCESS;
2280	}
2281
2282
2283
2284	/**
2285	* Structure to pass to DBGFR3Info() and for doing all other
2286	* output during fatal dump.
2287	*/
2288	typedef struct VMMR3FATALDUMPINFOHLP
2289	{
2290	/** The helper core. */
2291	DBGFINFOHLP Core;
2292	/** The release logger instance. */
2293	PRTLOGGER pRelLogger;
2294	/** The saved release logger flags. */
2295	RTUINT fRelLoggerFlags;
2296	/** The logger instance. */
2297	PRTLOGGER pLogger;
2298	/** The saved logger flags. */
2299	RTUINT fLoggerFlags;
2300	/** The saved logger destination flags. */
2301	RTUINT fLoggerDestFlags;
2302	/** Whether to output to stderr or not. */
2303	bool fStdErr;
2304	} VMMR3FATALDUMPINFOHLP, *PVMMR3FATALDUMPINFOHLP;
2305	typedef const VMMR3FATALDUMPINFOHLP *PCVMMR3FATALDUMPINFOHLP;
2306
2307
2308	/**
2309	* Print formatted string.
2310	*
2311	* @param pHlp Pointer to this structure.
2312	* @param pszFormat The format string.
2313	* @param ... Arguments.
2314	*/
2315	static DECLCALLBACK(void) vmmR3FatalDumpInfoHlp_pfnPrintf(PCDBGFINFOHLP pHlp, const char *pszFormat, ...)
2316	{
2317	va_list args;
2318	va_start(args, pszFormat);
2319	pHlp->pfnPrintfV(pHlp, pszFormat, args);
2320	va_end(args);
2321	}
2322
2323
2324	/**
2325	* Print formatted string.
2326	*
2327	* @param pHlp Pointer to this structure.
2328	* @param pszFormat The format string.
2329	* @param args Argument list.
2330	*/
2331	static DECLCALLBACK(void) vmmR3FatalDumpInfoHlp_pfnPrintfV(PCDBGFINFOHLP pHlp, const char *pszFormat, va_list args)
2332	{
2333	PCVMMR3FATALDUMPINFOHLP pMyHlp = (PCVMMR3FATALDUMPINFOHLP)pHlp;
2334
2335	if (pMyHlp->pRelLogger)
2336	{
2337	va_list args2;
2338	va_copy(args2, args);
2339	RTLogLoggerV(pMyHlp->pRelLogger, pszFormat, args2);
2340	va_end(args2);
2341	}
2342	if (pMyHlp->pLogger)
2343	{
2344	va_list args2;
2345	va_copy(args2, args);
2346	RTLogLoggerV(pMyHlp->pLogger, pszFormat, args);
2347	va_end(args2);
2348	}
2349	if (pMyHlp->fStdErr)
2350	{
2351	va_list args2;
2352	va_copy(args2, args);
2353	RTStrmPrintfV(g_pStdErr, pszFormat, args);
2354	va_end(args2);
2355	}
2356	}
2357
2358
2359	/**
2360	* Initializes the fatal dump output helper.
2361	*
2362	* @param pHlp The structure to initialize.
2363	*/
2364	static void vmmR3FatalDumpInfoHlpInit(PVMMR3FATALDUMPINFOHLP pHlp)
2365	{
2366	memset(pHlp, 0, sizeof(*pHlp));
2367
2368	pHlp->Core.pfnPrintf = vmmR3FatalDumpInfoHlp_pfnPrintf;
2369	pHlp->Core.pfnPrintfV = vmmR3FatalDumpInfoHlp_pfnPrintfV;
2370
2371	/*
2372	* The loggers.
2373	*/
2374	pHlp->pRelLogger = RTLogRelDefaultInstance();
2375	#ifndef LOG_ENABLED
2376	if (!pHlp->pRelLogger)
2377	#endif
2378	pHlp->pLogger = RTLogDefaultInstance();
2379
2380	if (pHlp->pRelLogger)
2381	{
2382	pHlp->fRelLoggerFlags = pHlp->pRelLogger->fFlags;
2383	pHlp->pRelLogger->fFlags &= ~(RTLOGFLAGS_BUFFERED \| RTLOGFLAGS_DISABLED);
2384	}
2385
2386	if (pHlp->pLogger)
2387	{
2388	pHlp->fLoggerFlags = pHlp->pLogger->fFlags;
2389	pHlp->fLoggerDestFlags = pHlp->pLogger->fDestFlags;
2390	pHlp->pLogger->fFlags &= ~(RTLOGFLAGS_BUFFERED \| RTLOGFLAGS_DISABLED);
2391	#ifndef DEBUG_sandervl
2392	pHlp->pLogger->fDestFlags \|= RTLOGDEST_DEBUGGER;
2393	#endif
2394	}
2395
2396	/*
2397	* Check if we need write to stderr.
2398	*/
2399	pHlp->fStdErr = (!pHlp->pRelLogger \|\| !(pHlp->pRelLogger->fDestFlags & (RTLOGDEST_STDOUT \| RTLOGDEST_STDERR)))
2400	&& (!pHlp->pLogger \|\| !(pHlp->pLogger->fDestFlags & (RTLOGDEST_STDOUT \| RTLOGDEST_STDERR)));
2401	}
2402
2403
2404	/**
2405	* Deletes the fatal dump output helper.
2406	*
2407	* @param pHlp The structure to delete.
2408	*/
2409	static void vmmR3FatalDumpInfoHlpDelete(PVMMR3FATALDUMPINFOHLP pHlp)
2410	{
2411	if (pHlp->pRelLogger)
2412	{
2413	RTLogFlush(pHlp->pRelLogger);
2414	pHlp->pRelLogger->fFlags = pHlp->fRelLoggerFlags;
2415	}
2416
2417	if (pHlp->pLogger)
2418	{
2419	RTLogFlush(pHlp->pLogger);
2420	pHlp->pLogger->fFlags = pHlp->fLoggerFlags;
2421	pHlp->pLogger->fDestFlags = pHlp->fLoggerDestFlags;
2422	}
2423	}
2424
2425
2426	/**
2427	* Dumps the VM state on a fatal error.
2428	*
2429	* @param pVM VM Handle.
2430	* @param rcErr VBox status code.
2431	*/
2432	VMMR3DECL(void) VMMR3FatalDump(PVM pVM, int rcErr)
2433	{
2434	/*
2435	* Create our output helper and sync it with the log settings.
2436	* This helper will be used for all the output.
2437	*/
2438	VMMR3FATALDUMPINFOHLP Hlp;
2439	PCDBGFINFOHLP pHlp = &Hlp.Core;
2440	vmmR3FatalDumpInfoHlpInit(&Hlp);
2441
2442	/*
2443	* Header.
2444	*/
2445	pHlp->pfnPrintf(pHlp,
2446	"!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!\n"
2447	"!!\n"
2448	"!! Guru Meditation %d (%Vrc)\n"
2449	"!!\n",
2450	rcErr, rcErr);
2451
2452	/*
2453	* Continue according to context.
2454	*/
2455	bool fDoneHyper = false;
2456	switch (rcErr)
2457	{
2458	/*
2459	* Hyper visor errors.
2460	*/
2461	case VINF_EM_DBG_HYPER_ASSERTION:
2462	pHlp->pfnPrintf(pHlp, "%s%s!!\n", VMMR3GetGCAssertMsg1(pVM), VMMR3GetGCAssertMsg2(pVM));
2463	/* fall thru */
2464	case VERR_TRPM_DONT_PANIC:
2465	case VERR_TRPM_PANIC:
2466	case VINF_EM_RAW_STALE_SELECTOR:
2467	case VINF_EM_RAW_IRET_TRAP:
2468	case VINF_EM_DBG_HYPER_BREAKPOINT:
2469	case VINF_EM_DBG_HYPER_STEPPED:
2470	{
2471	/* Trap? */
2472	uint32_t uEIP = CPUMGetHyperEIP(pVM);
2473	TRPMEVENT enmType;
2474	uint8_t u8TrapNo = 0xce;
2475	RTGCUINT uErrorCode = 0xdeadface;
2476	RTGCUINTPTR uCR2 = 0xdeadface;
2477	int rc2 = TRPMQueryTrapAll(pVM, &u8TrapNo, &enmType, &uErrorCode, &uCR2);
2478	if (VBOX_SUCCESS(rc2))
2479	pHlp->pfnPrintf(pHlp,
2480	"!! TRAP=%02x ERRCD=%VGv CR2=%VGv EIP=%VGv Type=%d\n",
2481	u8TrapNo, uErrorCode, uCR2, uEIP, enmType);
2482	else
2483	pHlp->pfnPrintf(pHlp,
2484	"!! EIP=%VGv NOTRAP\n",
2485	uEIP);
2486
2487	/*
2488	* Try figure out where eip is.
2489	*/
2490	/** @todo make query call for core code or move this function to VMM. */
2491	/* core code? */
2492	//if (uEIP - (RTGCUINTPTR)pVM->vmm.s.pvGCCoreCode < pVM->vmm.s.cbCoreCode)
2493	// pHlp->pfnPrintf(pHlp,
2494	// "!! EIP is in CoreCode, offset %#x\n",
2495	// uEIP - (RTGCUINTPTR)pVM->vmm.s.pvGCCoreCode);
2496	//else
2497	{ /* ask PDM */
2498	/** @todo ask DBGFR3Sym later. */
2499	char szModName[64];
2500	RTGCPTR GCPtrMod;
2501	char szNearSym1[260];
2502	RTGCPTR GCPtrNearSym1;
2503	char szNearSym2[260];
2504	RTGCPTR GCPtrNearSym2;
2505	int rc = PDMR3QueryModFromEIP(pVM, uEIP,
2506	&szModName[0], sizeof(szModName), &GCPtrMod,
2507	&szNearSym1[0], sizeof(szNearSym1), &GCPtrNearSym1,
2508	&szNearSym2[0], sizeof(szNearSym2), &GCPtrNearSym2);
2509	if (VBOX_SUCCESS(rc))
2510	{
2511	pHlp->pfnPrintf(pHlp,
2512	"!! EIP in %s (%p) at rva %x near symbols:\n"
2513	"!! %VGv rva %VGv off %08x %s\n"
2514	"!! %VGv rva %VGv off -%08x %s\n",
2515	szModName, GCPtrMod, (unsigned)(uEIP - GCPtrMod),
2516	GCPtrNearSym1, GCPtrNearSym1 - GCPtrMod, (unsigned)(uEIP - GCPtrNearSym1), szNearSym1,
2517	GCPtrNearSym2, GCPtrNearSym2 - GCPtrMod, (unsigned)(GCPtrNearSym2 - uEIP), szNearSym2);
2518	}
2519	else
2520	pHlp->pfnPrintf(pHlp,
2521	"!! EIP is not in any code known to VMM!\n");
2522	}
2523
2524	/* Disassemble the instruction. */
2525	char szInstr[256];
2526	rc2 = DBGFR3DisasInstrEx(pVM, 0, 0, DBGF_DISAS_FLAGS_CURRENT_HYPER, &szInstr[0], sizeof(szInstr), NULL);
2527	if (VBOX_SUCCESS(rc2))
2528	pHlp->pfnPrintf(pHlp,
2529	"!! %s\n", szInstr);
2530
2531	/* Dump the hypervisor cpu state. */
2532	pHlp->pfnPrintf(pHlp,
2533	"!!\n"
2534	"!!\n"
2535	"!!\n");
2536	rc2 = DBGFR3Info(pVM, "cpumhyper", "verbose", pHlp);
2537	fDoneHyper = true;
2538
2539	/* Callstack. */
2540	DBGFSTACKFRAME Frame = {0};
2541	rc2 = DBGFR3StackWalkBeginHyper(pVM, &Frame);
2542	if (VBOX_SUCCESS(rc2))
2543	{
2544	pHlp->pfnPrintf(pHlp,
2545	"!!\n"
2546	"!! Call Stack:\n"
2547	"!!\n"
2548	"EBP Ret EBP Ret CS:EIP Arg0 Arg1 Arg2 Arg3 CS:EIP Symbol [line]\n");
2549	do
2550	{
2551	pHlp->pfnPrintf(pHlp,
2552	"%08RX32 %08RX32 %04RX32:%08RX32 %08RX32 %08RX32 %08RX32 %08RX32",
2553	(uint32_t)Frame.AddrFrame.off,
2554	(uint32_t)Frame.AddrReturnFrame.off,
2555	(uint32_t)Frame.AddrReturnPC.Sel,
2556	(uint32_t)Frame.AddrReturnPC.off,
2557	Frame.Args.au32[0],
2558	Frame.Args.au32[1],
2559	Frame.Args.au32[2],
2560	Frame.Args.au32[3]);
2561	pHlp->pfnPrintf(pHlp, " %RTsel:%08RGv", Frame.AddrPC.Sel, Frame.AddrPC.off);
2562	if (Frame.pSymPC)
2563	{
2564	RTGCINTPTR offDisp = Frame.AddrPC.FlatPtr - Frame.pSymPC->Value;
2565	if (offDisp > 0)
2566	pHlp->pfnPrintf(pHlp, " %s+%llx", Frame.pSymPC->szName, (int64_t)offDisp);
2567	else if (offDisp < 0)
2568	pHlp->pfnPrintf(pHlp, " %s-%llx", Frame.pSymPC->szName, -(int64_t)offDisp);
2569	else
2570	pHlp->pfnPrintf(pHlp, " %s", Frame.pSymPC->szName);
2571	}
2572	if (Frame.pLinePC)
2573	pHlp->pfnPrintf(pHlp, " [%s @ 0i%d]", Frame.pLinePC->szFilename, Frame.pLinePC->uLineNo);
2574	pHlp->pfnPrintf(pHlp, "\n");
2575
2576	/* next */
2577	rc2 = DBGFR3StackWalkNext(pVM, &Frame);
2578	} while (VBOX_SUCCESS(rc2));
2579	DBGFR3StackWalkEnd(pVM, &Frame);
2580	}
2581
2582	/* raw stack */
2583	pHlp->pfnPrintf(pHlp,
2584	"!!\n"
2585	"!! Raw stack (mind the direction).\n"
2586	"!!\n"
2587	"%.*Vhxd\n",
2588	VMM_STACK_SIZE, (char *)pVM->vmm.s.pbHCStack);
2589	break;
2590	}
2591
2592	default:
2593	{
2594	break;
2595	}
2596
2597	} /* switch (rcErr) */
2598
2599
2600	/*
2601	* Generic info dumper loop.
2602	*/
2603	static struct
2604	{
2605	const char *pszInfo;
2606	const char *pszArgs;
2607	} const aInfo[] =
2608	{
2609	{ "mappings", NULL },
2610	{ "hma", NULL },
2611	{ "cpumguest", "verbose" },
2612	{ "cpumhyper", "verbose" },
2613	{ "cpumhost", "verbose" },
2614	{ "mode", "all" },
2615	{ "cpuid", "verbose" },
2616	{ "gdt", NULL },
2617	{ "ldt", NULL },
2618	//{ "tss", NULL },
2619	{ "ioport", NULL },
2620	{ "mmio", NULL },
2621	{ "phys", NULL },
2622	//{ "pgmpd", NULL }, - doesn't always work at init time...
2623	{ "timers", NULL },
2624	{ "activetimers", NULL },
2625	{ "handlers", "phys virt hyper stats" },
2626	{ "cfgm", NULL },
2627	};
2628	for (unsigned i = 0; i < ELEMENTS(aInfo); i++)
2629	{
2630	if (fDoneHyper && !strcmp(aInfo[i].pszInfo, "cpumhyper"))
2631	continue;
2632	pHlp->pfnPrintf(pHlp,
2633	"!!\n"
2634	"!! {%s, %s}\n"
2635	"!!\n",
2636	aInfo[i].pszInfo, aInfo[i].pszArgs);
2637	DBGFR3Info(pVM, aInfo[i].pszInfo, aInfo[i].pszArgs, pHlp);
2638	}
2639
2640	/* done */
2641	pHlp->pfnPrintf(pHlp,
2642	"!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!\n");
2643
2644
2645	/*
2646	* Delete the output instance (flushing and restoring of flags).
2647	*/
2648	vmmR3FatalDumpInfoHlpDelete(&Hlp);
2649	}
2650
2651
2652
2653	/**
2654	* Displays the Force action Flags.
2655	*
2656	* @param pVM The VM handle.
2657	* @param pHlp The output helpers.
2658	* @param pszArgs The additional arguments (ignored).
2659	*/
2660	static DECLCALLBACK(void) vmmR3InfoFF(PVM pVM, PCDBGFINFOHLP pHlp, const char *pszArgs)
2661	{
2662	const uint32_t fForcedActions = pVM->fForcedActions;
2663
2664	pHlp->pfnPrintf(pHlp, "Forced action Flags: %#RX32", fForcedActions);
2665
2666	/* show the flag mnemonics */
2667	int c = 0;
2668	uint32_t f = fForcedActions;
2669	#define PRINT_FLAG(flag) do { \
2670	if (f & (flag)) \
2671	{ \
2672	static const char *s_psz = #flag; \
2673	if (!(c % 6)) \
2674	pHlp->pfnPrintf(pHlp, "%s\n %s", c ? "," : "", s_psz + 6); \
2675	else \
2676	pHlp->pfnPrintf(pHlp, ", %s", s_psz + 6); \
2677	c++; \
2678	f &= ~(flag); \
2679	} \
2680	} while (0)
2681	PRINT_FLAG(VM_FF_INTERRUPT_APIC);
2682	PRINT_FLAG(VM_FF_INTERRUPT_PIC);
2683	PRINT_FLAG(VM_FF_TIMER);
2684	PRINT_FLAG(VM_FF_PDM_QUEUES);
2685	PRINT_FLAG(VM_FF_PDM_DMA);
2686	PRINT_FLAG(VM_FF_PDM_CRITSECT);
2687	PRINT_FLAG(VM_FF_DBGF);
2688	PRINT_FLAG(VM_FF_REQUEST);
2689	PRINT_FLAG(VM_FF_TERMINATE);
2690	PRINT_FLAG(VM_FF_RESET);
2691	PRINT_FLAG(VM_FF_PGM_SYNC_CR3);
2692	PRINT_FLAG(VM_FF_PGM_SYNC_CR3_NON_GLOBAL);
2693	PRINT_FLAG(VM_FF_TRPM_SYNC_IDT);
2694	PRINT_FLAG(VM_FF_SELM_SYNC_TSS);
2695	PRINT_FLAG(VM_FF_SELM_SYNC_GDT);
2696	PRINT_FLAG(VM_FF_SELM_SYNC_LDT);
2697	PRINT_FLAG(VM_FF_INHIBIT_INTERRUPTS);
2698	PRINT_FLAG(VM_FF_CSAM_SCAN_PAGE);
2699	PRINT_FLAG(VM_FF_CSAM_PENDING_ACTION);
2700	PRINT_FLAG(VM_FF_TO_R3);
2701	PRINT_FLAG(VM_FF_DEBUG_SUSPEND);
2702	if (f)
2703	pHlp->pfnPrintf(pHlp, "%s\n Unknown bits: %#RX32\n", c ? "," : "", f);
2704	else
2705	pHlp->pfnPrintf(pHlp, "\n");
2706	#undef PRINT_FLAG
2707
2708	/* the groups */
2709	c = 0;
2710	#define PRINT_GROUP(grp) do { \
2711	if (fForcedActions & (grp)) \
2712	{ \
2713	static const char *s_psz = #grp; \
2714	if (!(c % 5)) \
2715	pHlp->pfnPrintf(pHlp, "%s %s", c ? ",\n" : "Groups:\n", s_psz + 6); \
2716	else \
2717	pHlp->pfnPrintf(pHlp, ", %s", s_psz + 6); \
2718	c++; \
2719	} \
2720	} while (0)
2721	PRINT_GROUP(VM_FF_EXTERNAL_SUSPENDED_MASK);
2722	PRINT_GROUP(VM_FF_EXTERNAL_HALTED_MASK);
2723	PRINT_GROUP(VM_FF_HIGH_PRIORITY_PRE_MASK);
2724	PRINT_GROUP(VM_FF_HIGH_PRIORITY_PRE_RAW_MASK);
2725	PRINT_GROUP(VM_FF_HIGH_PRIORITY_POST_MASK);
2726	PRINT_GROUP(VM_FF_NORMAL_PRIORITY_POST_MASK);
2727	PRINT_GROUP(VM_FF_NORMAL_PRIORITY_MASK);
2728	PRINT_GROUP(VM_FF_RESUME_GUEST_MASK);
2729	PRINT_GROUP(VM_FF_ALL_BUT_RAW_MASK);
2730	if (c)
2731	pHlp->pfnPrintf(pHlp, "\n");
2732	#undef PRINT_GROUP
2733	}
2734

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source: vbox/trunk/src/VBox/VMM/VMM.cpp@ 7692

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