CPUMAllRegs.cpp@ 5662

Last change on this file since 5662 was 5389, checked in by vboxsync, 17 years ago
Fully deal with CR0.EM/TS/MP changes in GC.
Property svn:eol-style set to `native` Property svn:keywords set to `Id`
File size: 41.7 KB

Line
1	/* $Id: CPUMAllRegs.cpp 5389 2007-10-19 16:45:07Z vboxsync $ */
2	/** @file
3	* CPUM - CPU Monitor(/Manager) - Gets and Sets.
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 as published by the Free Software Foundation,
13	* in version 2 as it comes in the "COPYING" file of the VirtualBox OSE
14	* distribution. VirtualBox OSE is distributed in the hope that it will
15	* be useful, but WITHOUT ANY WARRANTY of any kind.
16	*/
17
18
19	/*******************************************************************************
20	* Header Files *
21	*******************************************************************************/
22	#define LOG_GROUP LOG_GROUP_CPUM
23	#include <VBox/cpum.h>
24	#include <VBox/patm.h>
25	#include <VBox/dbgf.h>
26	#include <VBox/mm.h>
27	#include "CPUMInternal.h"
28	#include <VBox/vm.h>
29	#include <VBox/err.h>
30	#include <VBox/dis.h>
31	#include <VBox/log.h>
32	#include <iprt/assert.h>
33	#include <iprt/asm.h>
34
35
36
37	/** Disable stack frame pointer generation here. */
38	#if defined(_MSC_VER) && !defined(DEBUG)
39	# pragma optimize("y", off)
40	#endif
41
42
43	/**
44	* Sets or resets an alternative hypervisor context core.
45	*
46	* This is called when we get a hypervisor trap set switch the context
47	* core with the trap frame on the stack. It is called again to reset
48	* back to the default context core when resuming hypervisor execution.
49	*
50	* @param pVM The VM handle.
51	* @param pCtxCore Pointer to the alternative context core or NULL
52	* to go back to the default context core.
53	*/
54	CPUMDECL(void) CPUMHyperSetCtxCore(PVM pVM, PCPUMCTXCORE pCtxCore)
55	{
56	LogFlow(("CPUMHyperSetCtxCore: %p/%p/%p -> %p\n", pVM->cpum.s.CTXALLSUFF(pHyperCore), pCtxCore));
57	if (!pCtxCore)
58	{
59	pCtxCore = CPUMCTX2CORE(&pVM->cpum.s.Hyper);
60	pVM->cpum.s.pHyperCoreR3 = (R3PTRTYPE(PCPUMCTXCORE))VM_R3_ADDR(pVM, pCtxCore);
61	pVM->cpum.s.pHyperCoreR0 = (R0PTRTYPE(PCPUMCTXCORE))VM_R0_ADDR(pVM, pCtxCore);
62	pVM->cpum.s.pHyperCoreGC = (GCPTRTYPE(PCPUMCTXCORE))VM_GUEST_ADDR(pVM, pCtxCore);
63	}
64	else
65	{
66	pVM->cpum.s.pHyperCoreR3 = (R3PTRTYPE(PCPUMCTXCORE))MMHyperCCToR3(pVM, pCtxCore);
67	pVM->cpum.s.pHyperCoreR0 = (R0PTRTYPE(PCPUMCTXCORE))MMHyperCCToR0(pVM, pCtxCore);
68	pVM->cpum.s.pHyperCoreGC = (GCPTRTYPE(PCPUMCTXCORE))MMHyperCCToGC(pVM, pCtxCore);
69	}
70	}
71
72
73	/**
74	* Gets the pointer to the internal CPUMCTXCORE structure for the hypervisor.
75	* This is only for reading in order to save a few calls.
76	*
77	* @param pVM Handle to the virtual machine.
78	*/
79	CPUMDECL(PCCPUMCTXCORE) CPUMGetHyperCtxCore(PVM pVM)
80	{
81	return pVM->cpum.s.CTXALLSUFF(pHyperCore);
82	}
83
84
85	/**
86	* Queries the pointer to the internal CPUMCTX structure for the hypervisor.
87	*
88	* @returns VBox status code.
89	* @param pVM Handle to the virtual machine.
90	* @param ppCtx Receives the hyper CPUMCTX pointer when successful.
91	*
92	* @deprecated This will not (and has never) given the right picture of the
93	* hypervisor register state. With CPUMHyperSetCtxCore() this is
94	* getting much worse. So, use the individual functions for getting
95	* and esp. setting the hypervisor registers.
96	*/
97	CPUMDECL(int) CPUMQueryHyperCtxPtr(PVM pVM, PCPUMCTX *ppCtx)
98	{
99	*ppCtx = &pVM->cpum.s.Hyper;
100	return VINF_SUCCESS;
101	}
102
103	CPUMDECL(void) CPUMSetHyperGDTR(PVM pVM, uint32_t addr, uint16_t limit)
104	{
105	pVM->cpum.s.Hyper.gdtr.cbGdt = limit;
106	pVM->cpum.s.Hyper.gdtr.pGdt = addr;
107	pVM->cpum.s.Hyper.gdtrPadding = 0;
108	pVM->cpum.s.Hyper.gdtrPadding64 = 0;
109	}
110
111	CPUMDECL(void) CPUMSetHyperIDTR(PVM pVM, uint32_t addr, uint16_t limit)
112	{
113	pVM->cpum.s.Hyper.idtr.cbIdt = limit;
114	pVM->cpum.s.Hyper.idtr.pIdt = addr;
115	pVM->cpum.s.Hyper.idtrPadding = 0;
116	pVM->cpum.s.Hyper.idtrPadding64 = 0;
117	}
118
119	CPUMDECL(void) CPUMSetHyperCR3(PVM pVM, uint32_t cr3)
120	{
121	pVM->cpum.s.Hyper.cr3 = cr3;
122	}
123
124	CPUMDECL(void) CPUMSetHyperCS(PVM pVM, RTSEL SelCS)
125	{
126	pVM->cpum.s.CTXALLSUFF(pHyperCore)->cs = SelCS;
127	}
128
129	CPUMDECL(void) CPUMSetHyperDS(PVM pVM, RTSEL SelDS)
130	{
131	pVM->cpum.s.CTXALLSUFF(pHyperCore)->ds = SelDS;
132	}
133
134	CPUMDECL(void) CPUMSetHyperES(PVM pVM, RTSEL SelES)
135	{
136	pVM->cpum.s.CTXALLSUFF(pHyperCore)->es = SelES;
137	}
138
139	CPUMDECL(void) CPUMSetHyperFS(PVM pVM, RTSEL SelFS)
140	{
141	pVM->cpum.s.CTXALLSUFF(pHyperCore)->fs = SelFS;
142	}
143
144	CPUMDECL(void) CPUMSetHyperGS(PVM pVM, RTSEL SelGS)
145	{
146	pVM->cpum.s.CTXALLSUFF(pHyperCore)->gs = SelGS;
147	}
148
149	CPUMDECL(void) CPUMSetHyperSS(PVM pVM, RTSEL SelSS)
150	{
151	pVM->cpum.s.CTXALLSUFF(pHyperCore)->ss = SelSS;
152	}
153
154	CPUMDECL(void) CPUMSetHyperESP(PVM pVM, uint32_t u32ESP)
155	{
156	pVM->cpum.s.CTXALLSUFF(pHyperCore)->esp = u32ESP;
157	}
158
159	CPUMDECL(int) CPUMSetHyperEFlags(PVM pVM, uint32_t Efl)
160	{
161	pVM->cpum.s.CTXALLSUFF(pHyperCore)->eflags.u32 = Efl;
162	return VINF_SUCCESS;
163	}
164
165	CPUMDECL(void) CPUMSetHyperEIP(PVM pVM, uint32_t u32EIP)
166	{
167	pVM->cpum.s.CTXALLSUFF(pHyperCore)->eip = u32EIP;
168	}
169
170	CPUMDECL(void) CPUMSetHyperTR(PVM pVM, RTSEL SelTR)
171	{
172	pVM->cpum.s.Hyper.tr = SelTR;
173	}
174
175	CPUMDECL(void) CPUMSetHyperLDTR(PVM pVM, RTSEL SelLDTR)
176	{
177	pVM->cpum.s.Hyper.ldtr = SelLDTR;
178	}
179
180	CPUMDECL(void) CPUMSetHyperDR0(PVM pVM, RTGCUINTREG uDr0)
181	{
182	pVM->cpum.s.Hyper.dr0 = uDr0;
183	/** @todo in GC we must load it! */
184	}
185
186	CPUMDECL(void) CPUMSetHyperDR1(PVM pVM, RTGCUINTREG uDr1)
187	{
188	pVM->cpum.s.Hyper.dr1 = uDr1;
189	/** @todo in GC we must load it! */
190	}
191
192	CPUMDECL(void) CPUMSetHyperDR2(PVM pVM, RTGCUINTREG uDr2)
193	{
194	pVM->cpum.s.Hyper.dr2 = uDr2;
195	/** @todo in GC we must load it! */
196	}
197
198	CPUMDECL(void) CPUMSetHyperDR3(PVM pVM, RTGCUINTREG uDr3)
199	{
200	pVM->cpum.s.Hyper.dr3 = uDr3;
201	/** @todo in GC we must load it! */
202	}
203
204	CPUMDECL(void) CPUMSetHyperDR6(PVM pVM, RTGCUINTREG uDr6)
205	{
206	pVM->cpum.s.Hyper.dr6 = uDr6;
207	/** @todo in GC we must load it! */
208	}
209
210	CPUMDECL(void) CPUMSetHyperDR7(PVM pVM, RTGCUINTREG uDr7)
211	{
212	pVM->cpum.s.Hyper.dr7 = uDr7;
213	/** @todo in GC we must load it! */
214	}
215
216
217	CPUMDECL(RTSEL) CPUMGetHyperCS(PVM pVM)
218	{
219	return pVM->cpum.s.CTXALLSUFF(pHyperCore)->cs;
220	}
221
222	CPUMDECL(RTSEL) CPUMGetHyperDS(PVM pVM)
223	{
224	return pVM->cpum.s.CTXALLSUFF(pHyperCore)->ds;
225	}
226
227	CPUMDECL(RTSEL) CPUMGetHyperES(PVM pVM)
228	{
229	return pVM->cpum.s.CTXALLSUFF(pHyperCore)->es;
230	}
231
232	CPUMDECL(RTSEL) CPUMGetHyperFS(PVM pVM)
233	{
234	return pVM->cpum.s.CTXALLSUFF(pHyperCore)->fs;
235	}
236
237	CPUMDECL(RTSEL) CPUMGetHyperGS(PVM pVM)
238	{
239	return pVM->cpum.s.CTXALLSUFF(pHyperCore)->gs;
240	}
241
242	CPUMDECL(RTSEL) CPUMGetHyperSS(PVM pVM)
243	{
244	return pVM->cpum.s.CTXALLSUFF(pHyperCore)->ss;
245	}
246
247	#if 0 /* these are not correct. */
248
249	CPUMDECL(uint32_t) CPUMGetHyperCR0(PVM pVM)
250	{
251	return pVM->cpum.s.Hyper.cr0;
252	}
253
254	CPUMDECL(uint32_t) CPUMGetHyperCR2(PVM pVM)
255	{
256	return pVM->cpum.s.Hyper.cr2;
257	}
258
259	CPUMDECL(uint32_t) CPUMGetHyperCR3(PVM pVM)
260	{
261	return pVM->cpum.s.Hyper.cr3;
262	}
263
264	CPUMDECL(uint32_t) CPUMGetHyperCR4(PVM pVM)
265	{
266	return pVM->cpum.s.Hyper.cr4;
267	}
268
269	#endif /* not correct */
270
271	CPUMDECL(uint32_t) CPUMGetHyperEAX(PVM pVM)
272	{
273	return pVM->cpum.s.CTXALLSUFF(pHyperCore)->eax;
274	}
275
276	CPUMDECL(uint32_t) CPUMGetHyperEBX(PVM pVM)
277	{
278	return pVM->cpum.s.CTXALLSUFF(pHyperCore)->ebx;
279	}
280
281	CPUMDECL(uint32_t) CPUMGetHyperECX(PVM pVM)
282	{
283	return pVM->cpum.s.CTXALLSUFF(pHyperCore)->ecx;
284	}
285
286	CPUMDECL(uint32_t) CPUMGetHyperEDX(PVM pVM)
287	{
288	return pVM->cpum.s.CTXALLSUFF(pHyperCore)->edx;
289	}
290
291	CPUMDECL(uint32_t) CPUMGetHyperESI(PVM pVM)
292	{
293	return pVM->cpum.s.CTXALLSUFF(pHyperCore)->esi;
294	}
295
296	CPUMDECL(uint32_t) CPUMGetHyperEDI(PVM pVM)
297	{
298	return pVM->cpum.s.CTXALLSUFF(pHyperCore)->edi;
299	}
300
301	CPUMDECL(uint32_t) CPUMGetHyperEBP(PVM pVM)
302	{
303	return pVM->cpum.s.CTXALLSUFF(pHyperCore)->ebp;
304	}
305
306	CPUMDECL(uint32_t) CPUMGetHyperESP(PVM pVM)
307	{
308	return pVM->cpum.s.CTXALLSUFF(pHyperCore)->esp;
309	}
310
311	CPUMDECL(uint32_t) CPUMGetHyperEFlags(PVM pVM)
312	{
313	return pVM->cpum.s.CTXALLSUFF(pHyperCore)->eflags.u32;
314	}
315
316	CPUMDECL(uint32_t) CPUMGetHyperEIP(PVM pVM)
317	{
318	return pVM->cpum.s.CTXALLSUFF(pHyperCore)->eip;
319	}
320
321	CPUMDECL(uint32_t) CPUMGetHyperIDTR(PVM pVM, uint16_t *pcbLimit)
322	{
323	if (pcbLimit)
324	*pcbLimit = pVM->cpum.s.Hyper.idtr.cbIdt;
325	return pVM->cpum.s.Hyper.idtr.pIdt;
326	}
327
328	CPUMDECL(uint32_t) CPUMGetHyperGDTR(PVM pVM, uint16_t *pcbLimit)
329	{
330	if (pcbLimit)
331	*pcbLimit = pVM->cpum.s.Hyper.gdtr.cbGdt;
332	return pVM->cpum.s.Hyper.gdtr.pGdt;
333	}
334
335	CPUMDECL(RTSEL) CPUMGetHyperLDTR(PVM pVM)
336	{
337	return pVM->cpum.s.Hyper.ldtr;
338	}
339
340	CPUMDECL(RTGCUINTREG) CPUMGetHyperDR0(PVM pVM)
341	{
342	return pVM->cpum.s.Hyper.dr0;
343	}
344
345	CPUMDECL(RTGCUINTREG) CPUMGetHyperDR1(PVM pVM)
346	{
347	return pVM->cpum.s.Hyper.dr1;
348	}
349
350	CPUMDECL(RTGCUINTREG) CPUMGetHyperDR2(PVM pVM)
351	{
352	return pVM->cpum.s.Hyper.dr2;
353	}
354
355	CPUMDECL(RTGCUINTREG) CPUMGetHyperDR3(PVM pVM)
356	{
357	return pVM->cpum.s.Hyper.dr3;
358	}
359
360	CPUMDECL(RTGCUINTREG) CPUMGetHyperDR6(PVM pVM)
361	{
362	return pVM->cpum.s.Hyper.dr6;
363	}
364
365	CPUMDECL(RTGCUINTREG) CPUMGetHyperDR7(PVM pVM)
366	{
367	return pVM->cpum.s.Hyper.dr7;
368	}
369
370
371	/**
372	* Gets the pointer to the internal CPUMCTXCORE structure.
373	* This is only for reading in order to save a few calls.
374	*
375	* @param pVM Handle to the virtual machine.
376	*/
377	CPUMDECL(PCCPUMCTXCORE) CPUMGetGuestCtxCore(PVM pVM)
378	{
379	return CPUMCTX2CORE(&pVM->cpum.s.Guest);
380	}
381
382
383	/**
384	* Sets the guest context core registers.
385	*
386	* @param pVM Handle to the virtual machine.
387	* @param pCtxCore The new context core values.
388	*/
389	CPUMDECL(void) CPUMSetGuestCtxCore(PVM pVM, PCCPUMCTXCORE pCtxCore)
390	{
391	/** @todo #1410 requires selectors to be checked. */
392
393	PCPUMCTXCORE pCtxCoreDst CPUMCTX2CORE(&pVM->cpum.s.Guest);
394	pCtxCoreDst = pCtxCore;
395	}
396
397
398	/**
399	* Queries the pointer to the internal CPUMCTX structure
400	*
401	* @returns VBox status code.
402	* @param pVM Handle to the virtual machine.
403	* @param ppCtx Receives the CPUMCTX pointer when successful.
404	*/
405	CPUMDECL(int) CPUMQueryGuestCtxPtr(PVM pVM, PCPUMCTX *ppCtx)
406	{
407	*ppCtx = &pVM->cpum.s.Guest;
408	return VINF_SUCCESS;
409	}
410
411
412	CPUMDECL(int) CPUMSetGuestGDTR(PVM pVM, uint32_t addr, uint16_t limit)
413	{
414	pVM->cpum.s.Guest.gdtr.cbGdt = limit;
415	pVM->cpum.s.Guest.gdtr.pGdt = addr;
416	pVM->cpum.s.fChanged \|= CPUM_CHANGED_GDTR;
417	return VINF_SUCCESS;
418	}
419
420	CPUMDECL(int) CPUMSetGuestIDTR(PVM pVM, uint32_t addr, uint16_t limit)
421	{
422	pVM->cpum.s.Guest.idtr.cbIdt = limit;
423	pVM->cpum.s.Guest.idtr.pIdt = addr;
424	pVM->cpum.s.fChanged \|= CPUM_CHANGED_IDTR;
425	return VINF_SUCCESS;
426	}
427
428	CPUMDECL(int) CPUMSetGuestTR(PVM pVM, uint16_t tr)
429	{
430	pVM->cpum.s.Guest.tr = tr;
431	pVM->cpum.s.fChanged \|= CPUM_CHANGED_TR;
432	return VINF_SUCCESS;
433	}
434
435	CPUMDECL(int) CPUMSetGuestLDTR(PVM pVM, uint16_t ldtr)
436	{
437	pVM->cpum.s.Guest.ldtr = ldtr;
438	pVM->cpum.s.fChanged \|= CPUM_CHANGED_LDTR;
439	return VINF_SUCCESS;
440	}
441
442
443	/**
444	* Set the guest CR0.
445	*
446	* When called in GC, the hyper CR0 may be updated if that is
447	* required. The caller only has to take special action if AM,
448	* WP, PG or PE changes.
449	*
450	* @returns VINF_SUCCESS (consider it void).
451	* @param pVM Pointer to the shared VM structure.
452	* @param cr0 The new CR0 value.
453	*/
454	CPUMDECL(int) CPUMSetGuestCR0(PVM pVM, uint32_t cr0)
455	{
456	#ifdef IN_GC
457	/*
458	* Check if we need to change hypervisor CR0 because
459	* of math stuff.
460	*/
461	if ( (cr0 & (X86_CR0_TS \| X86_CR0_EM \| X86_CR0_MP))
462	!= (pVM->cpum.s.Guest.cr0 & (X86_CR0_TS \| X86_CR0_EM \| X86_CR0_MP)))
463	{
464	if (!(pVM->cpum.s.fUseFlags & CPUM_USED_FPU))
465	{
466	/*
467	* We haven't saved the host FPU state yet, so TS and MT are both set
468	* and EM should be reflecting the guest EM (it always does this).
469	*/
470	if ((cr0 & X86_CR0_EM) != (pVM->cpum.s.Guest.cr0 & X86_CR0_EM))
471	{
472	uint32_t HyperCR0 = ASMGetCR0();
473	AssertMsg((HyperCR0 & (X86_CR0_TS \| X86_CR0_MP)) == (X86_CR0_TS \| X86_CR0_MP), ("%#x\n", HyperCR0));
474	AssertMsg((HyperCR0 & X86_CR0_EM) == (pVM->cpum.s.Guest.cr0 & X86_CR0_EM), ("%#x\n", HyperCR0));
475	HyperCR0 &= ~X86_CR0_EM;
476	HyperCR0 \|= cr0 & X86_CR0_EM;
477	Log(("CPUM New HyperCR0=%#x\n", HyperCR0));
478	ASMSetCR0(HyperCR0);
479	}
480	#ifdef VBOX_STRICT
481	else
482	{
483	uint32_t HyperCR0 = ASMGetCR0();
484	AssertMsg((HyperCR0 & (X86_CR0_TS \| X86_CR0_MP)) == (X86_CR0_TS \| X86_CR0_MP), ("%#x\n", HyperCR0));
485	AssertMsg((HyperCR0 & X86_CR0_EM) == (pVM->cpum.s.Guest.cr0 & X86_CR0_EM), ("%#x\n", HyperCR0));
486	}
487	#endif
488	}
489	else
490	{
491	/*
492	* Already saved the state, so we're just mirroring
493	* the guest flags.
494	*/
495	uint32_t HyperCR0 = ASMGetCR0();
496	AssertMsg( (HyperCR0 & (X86_CR0_TS \| X86_CR0_EM \| X86_CR0_MP))
497	== (pVM->cpum.s.Guest.cr0 & (X86_CR0_TS \| X86_CR0_EM \| X86_CR0_MP)),
498	("%#x %#x\n", HyperCR0, pVM->cpum.s.Guest.cr0));
499	HyperCR0 &= ~(X86_CR0_TS \| X86_CR0_EM \| X86_CR0_MP);
500	HyperCR0 \|= cr0 & (X86_CR0_TS \| X86_CR0_EM \| X86_CR0_MP);
501	Log(("CPUM New HyperCR0=%#x\n", HyperCR0));
502	ASMSetCR0(HyperCR0);
503	}
504	}
505	#endif
506
507	/*
508	* Check for changes causing TLB flushes (for REM).
509	* The caller is responsible for calling PGM when appropriate.
510	*/
511	if ( (cr0 & (X86_CR0_PG \| X86_CR0_WP \| X86_CR0_PE))
512	!= (pVM->cpum.s.Guest.cr0 & (X86_CR0_PG \| X86_CR0_WP \| X86_CR0_PE)))
513	pVM->cpum.s.fChanged \|= CPUM_CHANGED_GLOBAL_TLB_FLUSH;
514	pVM->cpum.s.fChanged \|= CPUM_CHANGED_CR0;
515
516	pVM->cpum.s.Guest.cr0 = cr0 \| X86_CR0_ET;
517	return VINF_SUCCESS;
518	}
519
520	CPUMDECL(int) CPUMSetGuestCR2(PVM pVM, uint32_t cr2)
521	{
522	pVM->cpum.s.Guest.cr2 = cr2;
523	return VINF_SUCCESS;
524	}
525
526	CPUMDECL(int) CPUMSetGuestCR3(PVM pVM, uint32_t cr3)
527	{
528	pVM->cpum.s.Guest.cr3 = cr3;
529	pVM->cpum.s.fChanged \|= CPUM_CHANGED_CR3;
530	return VINF_SUCCESS;
531	}
532
533	CPUMDECL(int) CPUMSetGuestCR4(PVM pVM, uint32_t cr4)
534	{
535	if ( (cr4 & (X86_CR4_PGE \| X86_CR4_PAE \| X86_CR4_PSE))
536	!= (pVM->cpum.s.Guest.cr4 & (X86_CR4_PGE \| X86_CR4_PAE \| X86_CR4_PSE)))
537	pVM->cpum.s.fChanged \|= CPUM_CHANGED_GLOBAL_TLB_FLUSH;
538	pVM->cpum.s.fChanged \|= CPUM_CHANGED_CR4;
539	if (!CPUMSupportsFXSR(pVM))
540	cr4 &= ~X86_CR4_OSFSXR;
541	pVM->cpum.s.Guest.cr4 = cr4;
542	return VINF_SUCCESS;
543	}
544
545	CPUMDECL(int) CPUMSetGuestEFlags(PVM pVM, uint32_t eflags)
546	{
547	pVM->cpum.s.Guest.eflags.u32 = eflags;
548	return VINF_SUCCESS;
549	}
550
551	CPUMDECL(int) CPUMSetGuestEIP(PVM pVM, uint32_t eip)
552	{
553	pVM->cpum.s.Guest.eip = eip;
554	return VINF_SUCCESS;
555	}
556
557	CPUMDECL(int) CPUMSetGuestEAX(PVM pVM, uint32_t eax)
558	{
559	pVM->cpum.s.Guest.eax = eax;
560	return VINF_SUCCESS;
561	}
562
563	CPUMDECL(int) CPUMSetGuestEBX(PVM pVM, uint32_t ebx)
564	{
565	pVM->cpum.s.Guest.ebx = ebx;
566	return VINF_SUCCESS;
567	}
568
569	CPUMDECL(int) CPUMSetGuestECX(PVM pVM, uint32_t ecx)
570	{
571	pVM->cpum.s.Guest.ecx = ecx;
572	return VINF_SUCCESS;
573	}
574
575	CPUMDECL(int) CPUMSetGuestEDX(PVM pVM, uint32_t edx)
576	{
577	pVM->cpum.s.Guest.edx = edx;
578	return VINF_SUCCESS;
579	}
580
581	CPUMDECL(int) CPUMSetGuestESP(PVM pVM, uint32_t esp)
582	{
583	pVM->cpum.s.Guest.esp = esp;
584	return VINF_SUCCESS;
585	}
586
587	CPUMDECL(int) CPUMSetGuestEBP(PVM pVM, uint32_t ebp)
588	{
589	pVM->cpum.s.Guest.ebp = ebp;
590	return VINF_SUCCESS;
591	}
592
593	CPUMDECL(int) CPUMSetGuestESI(PVM pVM, uint32_t esi)
594	{
595	pVM->cpum.s.Guest.esi = esi;
596	return VINF_SUCCESS;
597	}
598
599	CPUMDECL(int) CPUMSetGuestEDI(PVM pVM, uint32_t edi)
600	{
601	pVM->cpum.s.Guest.edi = edi;
602	return VINF_SUCCESS;
603	}
604
605	CPUMDECL(int) CPUMSetGuestSS(PVM pVM, uint16_t ss)
606	{
607	pVM->cpum.s.Guest.ss = ss;
608	return VINF_SUCCESS;
609	}
610
611	CPUMDECL(int) CPUMSetGuestCS(PVM pVM, uint16_t cs)
612	{
613	pVM->cpum.s.Guest.cs = cs;
614	return VINF_SUCCESS;
615	}
616
617	CPUMDECL(int) CPUMSetGuestDS(PVM pVM, uint16_t ds)
618	{
619	pVM->cpum.s.Guest.ds = ds;
620	return VINF_SUCCESS;
621	}
622
623	CPUMDECL(int) CPUMSetGuestES(PVM pVM, uint16_t es)
624	{
625	pVM->cpum.s.Guest.es = es;
626	return VINF_SUCCESS;
627	}
628
629	CPUMDECL(int) CPUMSetGuestFS(PVM pVM, uint16_t fs)
630	{
631	pVM->cpum.s.Guest.fs = fs;
632	return VINF_SUCCESS;
633	}
634
635	CPUMDECL(int) CPUMSetGuestGS(PVM pVM, uint16_t gs)
636	{
637	pVM->cpum.s.Guest.gs = gs;
638	return VINF_SUCCESS;
639	}
640
641
642	CPUMDECL(uint32_t) CPUMGetGuestIDTR(PVM pVM, uint16_t *pcbLimit)
643	{
644	if (pcbLimit)
645	*pcbLimit = pVM->cpum.s.Guest.idtr.cbIdt;
646	return pVM->cpum.s.Guest.idtr.pIdt;
647	}
648
649	CPUMDECL(RTSEL) CPUMGetGuestTR(PVM pVM)
650	{
651	return pVM->cpum.s.Guest.tr;
652	}
653
654	CPUMDECL(RTSEL) CPUMGetGuestCS(PVM pVM)
655	{
656	return pVM->cpum.s.Guest.cs;
657	}
658
659	CPUMDECL(RTSEL) CPUMGetGuestDS(PVM pVM)
660	{
661	return pVM->cpum.s.Guest.ds;
662	}
663
664	CPUMDECL(RTSEL) CPUMGetGuestES(PVM pVM)
665	{
666	return pVM->cpum.s.Guest.es;
667	}
668
669	CPUMDECL(RTSEL) CPUMGetGuestFS(PVM pVM)
670	{
671	return pVM->cpum.s.Guest.fs;
672	}
673
674	CPUMDECL(RTSEL) CPUMGetGuestGS(PVM pVM)
675	{
676	return pVM->cpum.s.Guest.gs;
677	}
678
679	CPUMDECL(RTSEL) CPUMGetGuestSS(PVM pVM)
680	{
681	return pVM->cpum.s.Guest.ss;
682	}
683
684	CPUMDECL(RTSEL) CPUMGetGuestLDTR(PVM pVM)
685	{
686	return pVM->cpum.s.Guest.ldtr;
687	}
688
689
690	CPUMDECL(uint32_t) CPUMGetGuestCR0(PVM pVM)
691	{
692	return pVM->cpum.s.Guest.cr0;
693	}
694
695	CPUMDECL(uint32_t) CPUMGetGuestCR2(PVM pVM)
696	{
697	return pVM->cpum.s.Guest.cr2;
698	}
699
700	CPUMDECL(uint32_t) CPUMGetGuestCR3(PVM pVM)
701	{
702	return pVM->cpum.s.Guest.cr3;
703	}
704
705	CPUMDECL(uint32_t) CPUMGetGuestCR4(PVM pVM)
706	{
707	return pVM->cpum.s.Guest.cr4;
708	}
709
710	CPUMDECL(void) CPUMGetGuestGDTR(PVM pVM, PVBOXGDTR pGDTR)
711	{
712	*pGDTR = pVM->cpum.s.Guest.gdtr;
713	}
714
715	CPUMDECL(uint32_t) CPUMGetGuestEIP(PVM pVM)
716	{
717	return pVM->cpum.s.Guest.eip;
718	}
719
720	CPUMDECL(uint32_t) CPUMGetGuestEAX(PVM pVM)
721	{
722	return pVM->cpum.s.Guest.eax;
723	}
724
725	CPUMDECL(uint32_t) CPUMGetGuestEBX(PVM pVM)
726	{
727	return pVM->cpum.s.Guest.ebx;
728	}
729
730	CPUMDECL(uint32_t) CPUMGetGuestECX(PVM pVM)
731	{
732	return pVM->cpum.s.Guest.ecx;
733	}
734
735	CPUMDECL(uint32_t) CPUMGetGuestEDX(PVM pVM)
736	{
737	return pVM->cpum.s.Guest.edx;
738	}
739
740	CPUMDECL(uint32_t) CPUMGetGuestESI(PVM pVM)
741	{
742	return pVM->cpum.s.Guest.esi;
743	}
744
745	CPUMDECL(uint32_t) CPUMGetGuestEDI(PVM pVM)
746	{
747	return pVM->cpum.s.Guest.edi;
748	}
749
750	CPUMDECL(uint32_t) CPUMGetGuestESP(PVM pVM)
751	{
752	return pVM->cpum.s.Guest.esp;
753	}
754
755	CPUMDECL(uint32_t) CPUMGetGuestEBP(PVM pVM)
756	{
757	return pVM->cpum.s.Guest.ebp;
758	}
759
760	CPUMDECL(uint32_t) CPUMGetGuestEFlags(PVM pVM)
761	{
762	return pVM->cpum.s.Guest.eflags.u32;
763	}
764
765	CPUMDECL(CPUMSELREGHID *) CPUMGetGuestTRHid(PVM pVM)
766	{
767	return &pVM->cpum.s.Guest.trHid;
768	}
769
770	//@todo: crx should be an array
771	CPUMDECL(int) CPUMGetGuestCRx(PVM pVM, uint32_t iReg, uint32_t *pValue)
772	{
773	switch (iReg)
774	{
775	case USE_REG_CR0:
776	*pValue = pVM->cpum.s.Guest.cr0;
777	break;
778	case USE_REG_CR2:
779	*pValue = pVM->cpum.s.Guest.cr2;
780	break;
781	case USE_REG_CR3:
782	*pValue = pVM->cpum.s.Guest.cr3;
783	break;
784	case USE_REG_CR4:
785	*pValue = pVM->cpum.s.Guest.cr4;
786	break;
787	default:
788	return VERR_INVALID_PARAMETER;
789	}
790	return VINF_SUCCESS;
791	}
792
793	CPUMDECL(RTUINTREG) CPUMGetGuestDR0(PVM pVM)
794	{
795	return pVM->cpum.s.Guest.dr0;
796	}
797
798	CPUMDECL(RTUINTREG) CPUMGetGuestDR1(PVM pVM)
799	{
800	return pVM->cpum.s.Guest.dr1;
801	}
802
803	CPUMDECL(RTUINTREG) CPUMGetGuestDR2(PVM pVM)
804	{
805	return pVM->cpum.s.Guest.dr2;
806	}
807
808	CPUMDECL(RTUINTREG) CPUMGetGuestDR3(PVM pVM)
809	{
810	return pVM->cpum.s.Guest.dr3;
811	}
812
813	CPUMDECL(RTUINTREG) CPUMGetGuestDR6(PVM pVM)
814	{
815	return pVM->cpum.s.Guest.dr6;
816	}
817
818	CPUMDECL(RTUINTREG) CPUMGetGuestDR7(PVM pVM)
819	{
820	return pVM->cpum.s.Guest.dr7;
821	}
822
823	/** @todo drx should be an array */
824	CPUMDECL(int) CPUMGetGuestDRx(PVM pVM, uint32_t iReg, uint32_t *pValue)
825	{
826	switch (iReg)
827	{
828	case USE_REG_DR0:
829	*pValue = pVM->cpum.s.Guest.dr0;
830	break;
831	case USE_REG_DR1:
832	*pValue = pVM->cpum.s.Guest.dr1;
833	break;
834	case USE_REG_DR2:
835	*pValue = pVM->cpum.s.Guest.dr2;
836	break;
837	case USE_REG_DR3:
838	*pValue = pVM->cpum.s.Guest.dr3;
839	break;
840	case USE_REG_DR4:
841	case USE_REG_DR6:
842	*pValue = pVM->cpum.s.Guest.dr6;
843	break;
844	case USE_REG_DR5:
845	case USE_REG_DR7:
846	*pValue = pVM->cpum.s.Guest.dr7;
847	break;
848
849	default:
850	return VERR_INVALID_PARAMETER;
851	}
852	return VINF_SUCCESS;
853	}
854
855	/**
856	* Gets a CpuId leaf.
857	*
858	* @param pVM The VM handle.
859	* @param iLeaf The CPUID leaf to get.
860	* @param pEax Where to store the EAX value.
861	* @param pEbx Where to store the EBX value.
862	* @param pEcx Where to store the ECX value.
863	* @param pEdx Where to store the EDX value.
864	*/
865	CPUMDECL(void) CPUMGetGuestCpuId(PVM pVM, uint32_t iLeaf, uint32_t pEax, uint32_t pEbx, uint32_t pEcx, uint32_t pEdx)
866	{
867	PCCPUMCPUID pCpuId;
868	if (iLeaf < ELEMENTS(pVM->cpum.s.aGuestCpuIdStd))
869	pCpuId = &pVM->cpum.s.aGuestCpuIdStd[iLeaf];
870	else if (iLeaf - UINT32_C(0x80000000) < RT_ELEMENTS(pVM->cpum.s.aGuestCpuIdExt))
871	pCpuId = &pVM->cpum.s.aGuestCpuIdExt[iLeaf - UINT32_C(0x80000000)];
872	else if (iLeaf - UINT32_C(0xc0000000) < RT_ELEMENTS(pVM->cpum.s.aGuestCpuIdCentaur))
873	pCpuId = &pVM->cpum.s.aGuestCpuIdCentaur[iLeaf - UINT32_C(0xc0000000)];
874	else
875	pCpuId = &pVM->cpum.s.GuestCpuIdDef;
876
877	*pEax = pCpuId->eax;
878	*pEbx = pCpuId->ebx;
879	*pEcx = pCpuId->ecx;
880	*pEdx = pCpuId->edx;
881	Log2(("CPUMGetGuestCpuId: iLeaf=%#010x %RX32 %RX32 %RX32 %RX32\n", iLeaf, pEax, pEbx, pEcx, pEdx));
882	}
883
884	/**
885	* Gets a pointer to the array of standard CPUID leafs.
886	*
887	* CPUMGetGuestCpuIdStdMax() give the size of the array.
888	*
889	* @returns Pointer to the standard CPUID leafs (read-only).
890	* @param pVM The VM handle.
891	* @remark Intended for PATM.
892	*/
893	CPUMDECL(GCPTRTYPE(PCCPUMCPUID)) CPUMGetGuestCpuIdStdGCPtr(PVM pVM)
894	{
895	return GCPTRTYPE(PCCPUMCPUID)VM_GUEST_ADDR(pVM, &pVM->cpum.s.aGuestCpuIdStd[0]);
896	}
897
898	/**
899	* Gets a pointer to the array of extended CPUID leafs.
900	*
901	* CPUMGetGuestCpuIdExtMax() give the size of the array.
902	*
903	* @returns Pointer to the extended CPUID leafs (read-only).
904	* @param pVM The VM handle.
905	* @remark Intended for PATM.
906	*/
907	CPUMDECL(GCPTRTYPE(PCCPUMCPUID)) CPUMGetGuestCpuIdExtGCPtr(PVM pVM)
908	{
909	return GCPTRTYPE(PCCPUMCPUID)VM_GUEST_ADDR(pVM, &pVM->cpum.s.aGuestCpuIdExt[0]);
910	}
911
912	/**
913	* Gets a pointer to the array of centaur CPUID leafs.
914	*
915	* CPUMGetGuestCpuIdCentaurMax() give the size of the array.
916	*
917	* @returns Pointer to the centaur CPUID leafs (read-only).
918	* @param pVM The VM handle.
919	* @remark Intended for PATM.
920	*/
921	CPUMDECL(GCPTRTYPE(PCCPUMCPUID)) CPUMGetGuestCpuIdCentaurGCPtr(PVM pVM)
922	{
923	return GCPTRTYPE(PCCPUMCPUID)VM_GUEST_ADDR(pVM, &pVM->cpum.s.aGuestCpuIdCentaur[0]);
924	}
925
926	/**
927	* Gets a pointer to the default CPUID leaf.
928	*
929	* @returns Pointer to the default CPUID leaf (read-only).
930	* @param pVM The VM handle.
931	* @remark Intended for PATM.
932	*/
933	CPUMDECL(GCPTRTYPE(PCCPUMCPUID)) CPUMGetGuestCpuIdDefGCPtr(PVM pVM)
934	{
935	return GCPTRTYPE(PCCPUMCPUID)VM_GUEST_ADDR(pVM, &pVM->cpum.s.GuestCpuIdDef);
936	}
937
938	/**
939	* Gets a number of standard CPUID leafs.
940	*
941	* @returns Number of leafs.
942	* @param pVM The VM handle.
943	* @remark Intended for PATM.
944	*/
945	CPUMDECL(uint32_t) CPUMGetGuestCpuIdStdMax(PVM pVM)
946	{
947	return RT_ELEMENTS(pVM->cpum.s.aGuestCpuIdStd);
948	}
949
950	/**
951	* Gets a number of extended CPUID leafs.
952	*
953	* @returns Number of leafs.
954	* @param pVM The VM handle.
955	* @remark Intended for PATM.
956	*/
957	CPUMDECL(uint32_t) CPUMGetGuestCpuIdExtMax(PVM pVM)
958	{
959	return RT_ELEMENTS(pVM->cpum.s.aGuestCpuIdExt);
960	}
961
962	/**
963	* Gets a number of centaur CPUID leafs.
964	*
965	* @returns Number of leafs.
966	* @param pVM The VM handle.
967	* @remark Intended for PATM.
968	*/
969	CPUMDECL(uint32_t) CPUMGetGuestCpuIdCentaurMax(PVM pVM)
970	{
971	return RT_ELEMENTS(pVM->cpum.s.aGuestCpuIdCentaur);
972	}
973
974	/**
975	* Sets a CPUID feature bit.
976	*
977	* @param pVM The VM Handle.
978	* @param enmFeature The feature to set.
979	*/
980	CPUMDECL(void) CPUMSetGuestCpuIdFeature(PVM pVM, CPUMCPUIDFEATURE enmFeature)
981	{
982	switch (enmFeature)
983	{
984	/*
985	* Set the APIC bit in both feature masks.
986	*/
987	case CPUMCPUIDFEATURE_APIC:
988	if (pVM->cpum.s.aGuestCpuIdStd[0].eax >= 1)
989	pVM->cpum.s.aGuestCpuIdStd[1].edx \|= X86_CPUID_FEATURE_EDX_APIC;
990	if ( pVM->cpum.s.aGuestCpuIdExt[0].eax >= 0x80000001
991	&& pVM->cpum.s.aGuestCpuIdExt[1].edx)
992	pVM->cpum.s.aGuestCpuIdExt[1].edx \|= X86_CPUID_AMD_FEATURE_EDX_APIC;
993	Log(("CPUMSetGuestCpuIdFeature: Enabled APIC\n"));
994	break;
995
996	/*
997	* Set the sysenter/sysexit bit in both feature masks.
998	* Assumes the caller knows what it's doing! (host must support these)
999	*/
1000	case CPUMCPUIDFEATURE_SEP:
1001	{
1002	uint32_t ulEdx, ulDummy;
1003
1004	ASMCpuId(1, &ulDummy, &ulDummy, &ulDummy, &ulEdx);
1005	if (!(ulEdx & X86_CPUID_FEATURE_EDX_SEP))
1006	{
1007	AssertMsgFailed(("ERROR: Can't turn on SEP when the host doesn't support it!!\n"));
1008	return;
1009	}
1010
1011	if (pVM->cpum.s.aGuestCpuIdStd[0].eax >= 1)
1012	pVM->cpum.s.aGuestCpuIdStd[1].edx \|= X86_CPUID_FEATURE_EDX_SEP;
1013	if ( pVM->cpum.s.aGuestCpuIdExt[0].eax >= 0x80000001
1014	&& pVM->cpum.s.aGuestCpuIdExt[1].edx)
1015	pVM->cpum.s.aGuestCpuIdExt[1].edx \|= X86_CPUID_AMD_FEATURE_EDX_SEP;
1016	Log(("CPUMSetGuestCpuIdFeature: Enabled sysenter/exit\n"));
1017	break;
1018	}
1019
1020	default:
1021	AssertMsgFailed(("enmFeature=%d\n", enmFeature));
1022	break;
1023	}
1024	}
1025
1026	/**
1027	* Clears a CPUID feature bit.
1028	*
1029	* @param pVM The VM Handle.
1030	* @param enmFeature The feature to clear.
1031	*/
1032	CPUMDECL(void) CPUMClearGuestCpuIdFeature(PVM pVM, CPUMCPUIDFEATURE enmFeature)
1033	{
1034	switch (enmFeature)
1035	{
1036	/*
1037	* Set the APIC bit in both feature masks.
1038	*/
1039	case CPUMCPUIDFEATURE_APIC:
1040	if (pVM->cpum.s.aGuestCpuIdStd[0].eax >= 1)
1041	pVM->cpum.s.aGuestCpuIdStd[1].edx &= ~X86_CPUID_FEATURE_EDX_APIC;
1042	if (pVM->cpum.s.aGuestCpuIdExt[0].eax >= 0x80000001)
1043	pVM->cpum.s.aGuestCpuIdExt[1].edx &= ~X86_CPUID_AMD_FEATURE_EDX_APIC;
1044	Log(("CPUMSetGuestCpuIdFeature: Disabled APIC\n"));
1045	break;
1046
1047	default:
1048	AssertMsgFailed(("enmFeature=%d\n", enmFeature));
1049	break;
1050	}
1051	}
1052
1053
1054
1055	CPUMDECL(int) CPUMSetGuestDR0(PVM pVM, RTGCUINTREG uDr0)
1056	{
1057	pVM->cpum.s.Guest.dr0 = uDr0;
1058	return CPUMRecalcHyperDRx(pVM);
1059	}
1060
1061	CPUMDECL(int) CPUMSetGuestDR1(PVM pVM, RTGCUINTREG uDr1)
1062	{
1063	pVM->cpum.s.Guest.dr1 = uDr1;
1064	return CPUMRecalcHyperDRx(pVM);
1065	}
1066
1067	CPUMDECL(int) CPUMSetGuestDR2(PVM pVM, RTGCUINTREG uDr2)
1068	{
1069	pVM->cpum.s.Guest.dr2 = uDr2;
1070	return CPUMRecalcHyperDRx(pVM);
1071	}
1072
1073	CPUMDECL(int) CPUMSetGuestDR3(PVM pVM, RTGCUINTREG uDr3)
1074	{
1075	pVM->cpum.s.Guest.dr3 = uDr3;
1076	return CPUMRecalcHyperDRx(pVM);
1077	}
1078
1079	CPUMDECL(int) CPUMSetGuestDR6(PVM pVM, RTGCUINTREG uDr6)
1080	{
1081	pVM->cpum.s.Guest.dr6 = uDr6;
1082	return CPUMRecalcHyperDRx(pVM);
1083	}
1084
1085	CPUMDECL(int) CPUMSetGuestDR7(PVM pVM, RTGCUINTREG uDr7)
1086	{
1087	pVM->cpum.s.Guest.dr7 = uDr7;
1088	return CPUMRecalcHyperDRx(pVM);
1089	}
1090
1091	/** @todo drx should be an array */
1092	CPUMDECL(int) CPUMSetGuestDRx(PVM pVM, uint32_t iReg, uint32_t Value)
1093	{
1094	switch (iReg)
1095	{
1096	case USE_REG_DR0:
1097	pVM->cpum.s.Guest.dr0 = Value;
1098	break;
1099	case USE_REG_DR1:
1100	pVM->cpum.s.Guest.dr1 = Value;
1101	break;
1102	case USE_REG_DR2:
1103	pVM->cpum.s.Guest.dr2 = Value;
1104	break;
1105	case USE_REG_DR3:
1106	pVM->cpum.s.Guest.dr3 = Value;
1107	break;
1108	case USE_REG_DR4:
1109	case USE_REG_DR6:
1110	pVM->cpum.s.Guest.dr6 = Value;
1111	break;
1112	case USE_REG_DR5:
1113	case USE_REG_DR7:
1114	pVM->cpum.s.Guest.dr7 = Value;
1115	break;
1116
1117	default:
1118	return VERR_INVALID_PARAMETER;
1119	}
1120	return CPUMRecalcHyperDRx(pVM);
1121	}
1122
1123
1124	/**
1125	* Recalculates the hypvervisor DRx register values based on
1126	* current guest registers and DBGF breakpoints.
1127	*
1128	* This is called whenever a guest DRx register is modified and when DBGF
1129	* sets a hardware breakpoint. In guest context this function will reload
1130	* any (hyper) DRx registers which comes out with a different value.
1131	*
1132	* @returns VINF_SUCCESS.
1133	* @param pVM The VM handle.
1134	*/
1135	CPUMDECL(int) CPUMRecalcHyperDRx(PVM pVM)
1136	{
1137	/*
1138	* Compare the DR7s first.
1139	*
1140	* We only care about the enabled flags. The GE and LE flags are always
1141	* set and we don't care if the guest doesn't set them. GD is virtualized
1142	* when we dispatch #DB, we never enable it.
1143	*/
1144	const RTGCUINTREG uDbgfDr7 = DBGFBpGetDR7(pVM);
1145	#ifdef CPUM_VIRTUALIZE_DRX
1146	const RTGCUINTREG uGstDr7 = CPUMGetGuestDR7(pVM);
1147	#else
1148	const RTGCUINTREG uGstDr7 = 0;
1149	#endif
1150	if ((uGstDr7 \| uDbgfDr7) & X86_DR7_ENABLED_MASK)
1151	{
1152	/*
1153	* Ok, something is enabled. Recalc each of the breakpoints.
1154	* Straight forward code, not optimized/minimized in any way.
1155	*/
1156	RTGCUINTREG uNewDr7 = X86_DR7_GE \| X86_DR7_LE \| X86_DR7_MB1_MASK;
1157
1158	/* bp 0 */
1159	RTGCUINTREG uNewDr0;
1160	if (uDbgfDr7 & (X86_DR7_L0 \| X86_DR7_G0))
1161	{
1162	uNewDr7 \|= uDbgfDr7 & (X86_DR7_L0 \| X86_DR7_G0 \| X86_DR7_RW0_MASK \| X86_DR7_LEN0_MASK);
1163	uNewDr0 = DBGFBpGetDR0(pVM);
1164	}
1165	else if (uGstDr7 & (X86_DR7_L0 \| X86_DR7_G0))
1166	{
1167	uNewDr7 \|= uGstDr7 & (X86_DR7_L0 \| X86_DR7_G0 \| X86_DR7_RW0_MASK \| X86_DR7_LEN0_MASK);
1168	uNewDr0 = CPUMGetGuestDR0(pVM);
1169	}
1170	else
1171	uNewDr0 = pVM->cpum.s.Hyper.dr0;
1172
1173	/* bp 1 */
1174	RTGCUINTREG uNewDr1;
1175	if (uDbgfDr7 & (X86_DR7_L1 \| X86_DR7_G1))
1176	{
1177	uNewDr7 \|= uDbgfDr7 & (X86_DR7_L1 \| X86_DR7_G1 \| X86_DR7_RW1_MASK \| X86_DR7_LEN1_MASK);
1178	uNewDr1 = DBGFBpGetDR1(pVM);
1179	}
1180	else if (uGstDr7 & (X86_DR7_L1 \| X86_DR7_G1))
1181	{
1182	uNewDr7 \|= uGstDr7 & (X86_DR7_L1 \| X86_DR7_G1 \| X86_DR7_RW1_MASK \| X86_DR7_LEN1_MASK);
1183	uNewDr1 = CPUMGetGuestDR1(pVM);
1184	}
1185	else
1186	uNewDr1 = pVM->cpum.s.Hyper.dr1;
1187
1188	/* bp 2 */
1189	RTGCUINTREG uNewDr2;
1190	if (uDbgfDr7 & (X86_DR7_L2 \| X86_DR7_G2))
1191	{
1192	uNewDr7 \|= uDbgfDr7 & (X86_DR7_L2 \| X86_DR7_G2 \| X86_DR7_RW2_MASK \| X86_DR7_LEN2_MASK);
1193	uNewDr2 = DBGFBpGetDR2(pVM);
1194	}
1195	else if (uGstDr7 & (X86_DR7_L2 \| X86_DR7_G2))
1196	{
1197	uNewDr7 \|= uGstDr7 & (X86_DR7_L2 \| X86_DR7_G2 \| X86_DR7_RW2_MASK \| X86_DR7_LEN2_MASK);
1198	uNewDr2 = CPUMGetGuestDR2(pVM);
1199	}
1200	else
1201	uNewDr2 = pVM->cpum.s.Hyper.dr2;
1202
1203	/* bp 3 */
1204	RTGCUINTREG uNewDr3;
1205	if (uDbgfDr7 & (X86_DR7_L3 \| X86_DR7_G3))
1206	{
1207	uNewDr7 \|= uDbgfDr7 & (X86_DR7_L3 \| X86_DR7_G3 \| X86_DR7_RW3_MASK \| X86_DR7_LEN3_MASK);
1208	uNewDr3 = DBGFBpGetDR3(pVM);
1209	}
1210	else if (uGstDr7 & (X86_DR7_L3 \| X86_DR7_G3))
1211	{
1212	uNewDr7 \|= uGstDr7 & (X86_DR7_L3 \| X86_DR7_G3 \| X86_DR7_RW3_MASK \| X86_DR7_LEN3_MASK);
1213	uNewDr3 = CPUMGetGuestDR3(pVM);
1214	}
1215	else
1216	uNewDr3 = pVM->cpum.s.Hyper.dr3;
1217
1218	/*
1219	* Apply the updates.
1220	*/
1221	#ifdef IN_GC
1222	if (!(pVM->cpum.s.fUseFlags & CPUM_USE_DEBUG_REGS))
1223	{
1224	/** @todo save host DBx registers. */
1225	}
1226	#endif
1227	pVM->cpum.s.fUseFlags \|= CPUM_USE_DEBUG_REGS;
1228	if (uNewDr3 != pVM->cpum.s.Hyper.dr3)
1229	CPUMSetHyperDR3(pVM, uNewDr3);
1230	if (uNewDr2 != pVM->cpum.s.Hyper.dr2)
1231	CPUMSetHyperDR2(pVM, uNewDr2);
1232	if (uNewDr1 != pVM->cpum.s.Hyper.dr1)
1233	CPUMSetHyperDR1(pVM, uNewDr1);
1234	if (uNewDr0 != pVM->cpum.s.Hyper.dr0)
1235	CPUMSetHyperDR0(pVM, uNewDr0);
1236	if (uNewDr7 != pVM->cpum.s.Hyper.dr7)
1237	CPUMSetHyperDR7(pVM, uNewDr7);
1238	}
1239	else
1240	{
1241	#ifdef IN_GC
1242	if (pVM->cpum.s.fUseFlags & CPUM_USE_DEBUG_REGS)
1243	{
1244	/** @todo restore host DBx registers. */
1245	}
1246	#endif
1247	pVM->cpum.s.fUseFlags &= ~CPUM_USE_DEBUG_REGS;
1248	}
1249	Log2(("CPUMRecalcHyperDRx: fUseFlags=%#x %RGr %RGr %RGr %RGr %RGr %RGr\n",
1250	pVM->cpum.s.fUseFlags, pVM->cpum.s.Hyper.dr0, pVM->cpum.s.Hyper.dr1,
1251	pVM->cpum.s.Hyper.dr2, pVM->cpum.s.Hyper.dr3, pVM->cpum.s.Hyper.dr6,
1252	pVM->cpum.s.Hyper.dr7));
1253
1254	return VINF_SUCCESS;
1255	}
1256
1257	#ifndef IN_RING0 /** @todo I don't think we need this in R0, so move it to CPUMAll.cpp? */
1258
1259	/**
1260	* Transforms the guest CPU state to raw-ring mode.
1261	*
1262	* This function will change the any of the cs and ss register with DPL=0 to DPL=1.
1263	*
1264	* @returns VBox status. (recompiler failure)
1265	* @param pVM VM handle.
1266	* @param pCtxCore The context core (for trap usage).
1267	* @see @ref pg_raw
1268	*/
1269	CPUMDECL(int) CPUMRawEnter(PVM pVM, PCPUMCTXCORE pCtxCore)
1270	{
1271	Assert(!pVM->cpum.s.fRawEntered);
1272	if (!pCtxCore)
1273	pCtxCore = CPUMCTX2CORE(&pVM->cpum.s.Guest);
1274
1275	/*
1276	* Are we in Ring-0?
1277	*/
1278	if ( pCtxCore->ss && (pCtxCore->ss & X86_SEL_RPL) == 0
1279	&& !pCtxCore->eflags.Bits.u1VM)
1280	{
1281	/*
1282	* Enter execution mode.
1283	*/
1284	PATMRawEnter(pVM, pCtxCore);
1285
1286	/*
1287	* Set CPL to Ring-1.
1288	*/
1289	pCtxCore->ss \|= 1;
1290	if (pCtxCore->cs && (pCtxCore->cs & X86_SEL_RPL) == 0)
1291	pCtxCore->cs \|= 1;
1292	}
1293	else
1294	{
1295	AssertMsg((pCtxCore->ss & X86_SEL_RPL) >= 2 \|\| pCtxCore->eflags.Bits.u1VM,
1296	("ring-1 code not supported\n"));
1297	/*
1298	* PATM takes care of IOPL and IF flags for Ring-3 and Ring-2 code as well.
1299	*/
1300	PATMRawEnter(pVM, pCtxCore);
1301	}
1302
1303	/*
1304	* Assert sanity.
1305	*/
1306	AssertMsg((pCtxCore->eflags.u32 & X86_EFL_IF), ("X86_EFL_IF is clear\n"));
1307	AssertReleaseMsg( pCtxCore->eflags.Bits.u2IOPL < (unsigned)(pCtxCore->ss & X86_SEL_RPL)
1308	\|\| pCtxCore->eflags.Bits.u1VM,
1309	("X86_EFL_IOPL=%d CPL=%d\n", pCtxCore->eflags.Bits.u2IOPL, pCtxCore->ss & X86_SEL_RPL));
1310	Assert((pVM->cpum.s.Guest.cr0 & (X86_CR0_PG \| X86_CR0_WP \| X86_CR0_PE)) == (X86_CR0_PG \| X86_CR0_PE \| X86_CR0_WP));
1311	pCtxCore->eflags.u32 \|= X86_EFL_IF; /* paranoia */
1312
1313	pVM->cpum.s.fRawEntered = true;
1314	return VINF_SUCCESS;
1315	}
1316
1317
1318	/**
1319	* Transforms the guest CPU state from raw-ring mode to correct values.
1320	*
1321	* This function will change any selector registers with DPL=1 to DPL=0.
1322	*
1323	* @returns Adjusted rc.
1324	* @param pVM VM handle.
1325	* @param rc Raw mode return code
1326	* @param pCtxCore The context core (for trap usage).
1327	* @see @ref pg_raw
1328	*/
1329	CPUMDECL(int) CPUMRawLeave(PVM pVM, PCPUMCTXCORE pCtxCore, int rc)
1330	{
1331	/*
1332	* Don't leave if we've already left (in GC).
1333	*/
1334	Assert(pVM->cpum.s.fRawEntered);
1335	if (!pVM->cpum.s.fRawEntered)
1336	return rc;
1337	pVM->cpum.s.fRawEntered = false;
1338
1339	PCPUMCTX pCtx = &pVM->cpum.s.Guest;
1340	if (!pCtxCore)
1341	pCtxCore = CPUMCTX2CORE(pCtx);
1342	Assert(pCtxCore->eflags.Bits.u1VM \|\| (pCtxCore->ss & X86_SEL_RPL));
1343	AssertMsg(pCtxCore->eflags.Bits.u1VM \|\| pCtxCore->eflags.Bits.u2IOPL < (unsigned)(pCtxCore->ss & X86_SEL_RPL),
1344	("X86_EFL_IOPL=%d CPL=%d\n", pCtxCore->eflags.Bits.u2IOPL, pCtxCore->ss & X86_SEL_RPL));
1345
1346	/*
1347	* Are we executing in raw ring-1?
1348	*/
1349	if ( (pCtxCore->ss & X86_SEL_RPL) == 1
1350	&& !pCtxCore->eflags.Bits.u1VM)
1351	{
1352	/*
1353	* Leave execution mode.
1354	*/
1355	PATMRawLeave(pVM, pCtxCore, rc);
1356	/* Not quite sure if this is really required, but shouldn't harm (too much anyways). */
1357	/** @todo See what happens if we remove this. */
1358	if ((pCtxCore->ds & X86_SEL_RPL) == 1)
1359	pCtxCore->ds &= ~X86_SEL_RPL;
1360	if ((pCtxCore->es & X86_SEL_RPL) == 1)
1361	pCtxCore->es &= ~X86_SEL_RPL;
1362	if ((pCtxCore->fs & X86_SEL_RPL) == 1)
1363	pCtxCore->fs &= ~X86_SEL_RPL;
1364	if ((pCtxCore->gs & X86_SEL_RPL) == 1)
1365	pCtxCore->gs &= ~X86_SEL_RPL;
1366
1367	/*
1368	* Ring-1 selector => Ring-0.
1369	*/
1370	pCtxCore->ss &= ~X86_SEL_RPL;
1371	if ((pCtxCore->cs & X86_SEL_RPL) == 1)
1372	pCtxCore->cs &= ~X86_SEL_RPL;
1373	}
1374	else
1375	{
1376	/*
1377	* PATM is taking care of the IOPL and IF flags for us.
1378	*/
1379	PATMRawLeave(pVM, pCtxCore, rc);
1380	if (!pCtxCore->eflags.Bits.u1VM)
1381	{
1382	/** @todo See what happens if we remove this. */
1383	if ((pCtxCore->ds & X86_SEL_RPL) == 1)
1384	pCtxCore->ds &= ~X86_SEL_RPL;
1385	if ((pCtxCore->es & X86_SEL_RPL) == 1)
1386	pCtxCore->es &= ~X86_SEL_RPL;
1387	if ((pCtxCore->fs & X86_SEL_RPL) == 1)
1388	pCtxCore->fs &= ~X86_SEL_RPL;
1389	if ((pCtxCore->gs & X86_SEL_RPL) == 1)
1390	pCtxCore->gs &= ~X86_SEL_RPL;
1391	}
1392	}
1393
1394	return rc;
1395	}
1396
1397	/**
1398	* Updates the EFLAGS while we're in raw-mode.
1399	*
1400	* @param pVM The VM handle.
1401	* @param pCtxCore The context core.
1402	* @param eflags The new EFLAGS value.
1403	*/
1404	CPUMDECL(void) CPUMRawSetEFlags(PVM pVM, PCPUMCTXCORE pCtxCore, uint32_t eflags)
1405	{
1406	if (!pVM->cpum.s.fRawEntered)
1407	{
1408	pCtxCore->eflags.u32 = eflags;
1409	return;
1410	}
1411	PATMRawSetEFlags(pVM, pCtxCore, eflags);
1412	}
1413
1414	#endif /* !IN_RING0 */
1415
1416	/**
1417	* Gets the EFLAGS while we're in raw-mode.
1418	*
1419	* @returns The eflags.
1420	* @param pVM The VM handle.
1421	* @param pCtxCore The context core.
1422	*/
1423	CPUMDECL(uint32_t) CPUMRawGetEFlags(PVM pVM, PCPUMCTXCORE pCtxCore)
1424	{
1425	#ifdef IN_RING0
1426	return pCtxCore->eflags.u32;
1427	#else
1428	if (!pVM->cpum.s.fRawEntered)
1429	return pCtxCore->eflags.u32;
1430	return PATMRawGetEFlags(pVM, pCtxCore);
1431	#endif
1432	}
1433
1434
1435
1436
1437	/**
1438	* Gets and resets the changed flags (CPUM_CHANGED_*).
1439	* Only REM should call this function.
1440	*
1441	* @returns The changed flags.
1442	* @param pVM The VM handle.
1443	*/
1444	CPUMDECL(unsigned) CPUMGetAndClearChangedFlagsREM(PVM pVM)
1445	{
1446	unsigned fFlags = pVM->cpum.s.fChanged;
1447	pVM->cpum.s.fChanged = 0;
1448	/** @todo change the switcher to use the fChanged flags. */
1449	if (pVM->cpum.s.fUseFlags & CPUM_USED_FPU_SINCE_REM)
1450	{
1451	fFlags \|= CPUM_CHANGED_FPU_REM;
1452	pVM->cpum.s.fUseFlags &= ~CPUM_USED_FPU_SINCE_REM;
1453	}
1454	return fFlags;
1455	}
1456
1457	/**
1458	* Sets the specified changed flags (CPUM_CHANGED_*).
1459	*
1460	* @param pVM The VM handle.
1461	*/
1462	CPUMDECL(void) CPUMSetChangedFlags(PVM pVM, uint32_t fChangedFlags)
1463	{
1464	pVM->cpum.s.fChanged \|= fChangedFlags;
1465	}
1466
1467	/**
1468	* Checks if the CPU supports the FXSAVE and FXRSTOR instruction.
1469	* @returns true if supported.
1470	* @returns false if not supported.
1471	* @param pVM The VM handle.
1472	*/
1473	CPUMDECL(bool) CPUMSupportsFXSR(PVM pVM)
1474	{
1475	return pVM->cpum.s.CPUFeatures.edx.u1FXSR != 0;
1476	}
1477
1478
1479	/**
1480	* Checks if the host OS uses the SYSENTER / SYSEXIT instructions.
1481	* @returns true if used.
1482	* @returns false if not used.
1483	* @param pVM The VM handle.
1484	*/
1485	CPUMDECL(bool) CPUMIsHostUsingSysEnter(PVM pVM)
1486	{
1487	return (pVM->cpum.s.fUseFlags & CPUM_USE_SYSENTER) != 0;
1488	}
1489
1490
1491	/**
1492	* Checks if the host OS uses the SYSCALL / SYSRET instructions.
1493	* @returns true if used.
1494	* @returns false if not used.
1495	* @param pVM The VM handle.
1496	*/
1497	CPUMDECL(bool) CPUMIsHostUsingSysCall(PVM pVM)
1498	{
1499	return (pVM->cpum.s.fUseFlags & CPUM_USE_SYSCALL) != 0;
1500	}
1501
1502	/**
1503	* Lazily sync in the FPU/XMM state
1504	*
1505	* @returns VBox status code.
1506	* @param pVM VM handle.
1507	*/
1508	CPUMDECL(int) CPUMHandleLazyFPU(PVM pVM)
1509	{
1510	return CPUMHandleLazyFPUAsm(&pVM->cpum.s);
1511	}
1512
1513	/**
1514	* Restore host FPU/XMM state
1515	*
1516	* @returns VBox status code.
1517	* @param pVM VM handle.
1518	*/
1519	CPUMDECL(int) CPUMRestoreHostFPUState(PVM pVM)
1520	{
1521	Assert(pVM->cpum.s.CPUFeatures.edx.u1FXSR);
1522	return CPUMRestoreHostFPUStateAsm(&pVM->cpum.s);
1523	}
1524
1525	/**
1526	* Checks if we activated the FPU/XMM state of the guest OS
1527	* @returns true if we did.
1528	* @returns false if not.
1529	* @param pVM The VM handle.
1530	*/
1531	CPUMDECL(bool) CPUMIsGuestFPUStateActive(PVM pVM)
1532	{
1533	return (pVM->cpum.s.fUseFlags & CPUM_USED_FPU) != 0;
1534	}
1535
1536	/**
1537	* Deactivate the FPU/XMM state of the guest OS
1538	* @param pVM The VM handle.
1539	*/
1540	CPUMDECL(void) CPUMDeactivateGuestFPUState(PVM pVM)
1541	{
1542	pVM->cpum.s.fUseFlags &= ~CPUM_USED_FPU;
1543	}
1544
1545	/**
1546	* Checks if the hidden selector registers are valid
1547	* @returns true if they are.
1548	* @returns false if not.
1549	* @param pVM The VM handle.
1550	*/
1551	CPUMDECL(bool) CPUMAreHiddenSelRegsValid(PVM pVM)
1552	{
1553	return !!pVM->cpum.s.fValidHiddenSelRegs; /** @todo change fValidHiddenSelRegs to bool! */
1554	}
1555
1556	/**
1557	* Checks if the hidden selector registers are valid
1558	* @param pVM The VM handle.
1559	* @param fValid Valid or not
1560	*/
1561	CPUMDECL(void) CPUMSetHiddenSelRegsValid(PVM pVM, bool fValid)
1562	{
1563	pVM->cpum.s.fValidHiddenSelRegs = fValid;
1564	}
1565
1566	/**
1567	* Get the current privilege level of the guest.
1568	*
1569	* @returns cpl
1570	* @param pVM VM Handle.
1571	* @param pRegFrame Trap register frame.
1572	*/
1573	CPUMDECL(uint32_t) CPUMGetGuestCPL(PVM pVM, PCPUMCTXCORE pCtxCore)
1574	{
1575	uint32_t cpl;
1576
1577	if (CPUMAreHiddenSelRegsValid(pVM))
1578	cpl = pCtxCore->ssHid.Attr.n.u2Dpl;
1579	else if (RT_LIKELY(pVM->cpum.s.Guest.cr0 & X86_CR0_PE))
1580	{
1581	if (RT_LIKELY(!pCtxCore->eflags.Bits.u1VM))
1582	{
1583	cpl = (pCtxCore->ss & X86_SEL_RPL);
1584	#ifndef IN_RING0
1585	if (cpl == 1)
1586	cpl = 0;
1587	#endif
1588	}
1589	else
1590	cpl = 3;
1591	}
1592	else
1593	cpl = 0; /* real mode; cpl is zero */
1594
1595	return cpl;
1596	}
1597
1598
1599	/**
1600	* Gets the current guest CPU mode.
1601	*
1602	* If paging mode is what you need, check out PGMGetGuestMode().
1603	*
1604	* @returns The CPU mode.
1605	* @param pVM The VM handle.
1606	*/
1607	CPUMDECL(CPUMMODE) CPUMGetGuestMode(PVM pVM)
1608	{
1609	CPUMMODE enmMode;
1610	if (!(pVM->cpum.s.Guest.cr0 & X86_CR0_PE))
1611	enmMode = CPUMMODE_REAL;
1612	else //GUEST64 if (!(pVM->cpum.s.Guest.efer & MSR_K6_EFER_LMA)
1613	enmMode = CPUMMODE_PROTECTED;
1614	//GUEST64 else
1615	//GUEST64 enmMode = CPUMMODE_LONG;
1616
1617	return enmMode;
1618	}
1619

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source: vbox/trunk/src/VBox/VMM/VMMAll/CPUMAllRegs.cpp@ 5662

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