VirtualBox

source: vbox/trunk/src/VBox/VMM/VMMR3/NEMR3Native-win.cpp@ 99051

Last change on this file since 99051 was 98103, checked in by vboxsync, 23 months ago

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1/* $Id: NEMR3Native-win.cpp 98103 2023-01-17 14:15:46Z vboxsync $ */
2/** @file
3 * NEM - Native execution manager, native ring-3 Windows backend.
4 *
5 * Log group 2: Exit logging.
6 * Log group 3: Log context on exit.
7 * Log group 5: Ring-3 memory management
8 * Log group 6: Ring-0 memory management
9 * Log group 12: API intercepts.
10 */
11
12/*
13 * Copyright (C) 2018-2023 Oracle and/or its affiliates.
14 *
15 * This file is part of VirtualBox base platform packages, as
16 * available from https://www.virtualbox.org.
17 *
18 * This program is free software; you can redistribute it and/or
19 * modify it under the terms of the GNU General Public License
20 * as published by the Free Software Foundation, in version 3 of the
21 * License.
22 *
23 * This program is distributed in the hope that it will be useful, but
24 * WITHOUT ANY WARRANTY; without even the implied warranty of
25 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
26 * General Public License for more details.
27 *
28 * You should have received a copy of the GNU General Public License
29 * along with this program; if not, see <https://www.gnu.org/licenses>.
30 *
31 * SPDX-License-Identifier: GPL-3.0-only
32 */
33
34
35/*********************************************************************************************************************************
36* Header Files *
37*********************************************************************************************************************************/
38#define LOG_GROUP LOG_GROUP_NEM
39#define VMCPU_INCL_CPUM_GST_CTX
40#include <iprt/nt/nt-and-windows.h>
41#include <iprt/nt/hyperv.h>
42#include <iprt/nt/vid.h>
43#include <WinHvPlatform.h>
44
45#ifndef _WIN32_WINNT_WIN10
46# error "Missing _WIN32_WINNT_WIN10"
47#endif
48#ifndef _WIN32_WINNT_WIN10_RS1 /* Missing define, causing trouble for us. */
49# define _WIN32_WINNT_WIN10_RS1 (_WIN32_WINNT_WIN10 + 1)
50#endif
51#include <sysinfoapi.h>
52#include <debugapi.h>
53#include <errhandlingapi.h>
54#include <fileapi.h>
55#include <winerror.h> /* no api header for this. */
56
57#include <VBox/vmm/nem.h>
58#include <VBox/vmm/iem.h>
59#include <VBox/vmm/em.h>
60#include <VBox/vmm/apic.h>
61#include <VBox/vmm/pdm.h>
62#include <VBox/vmm/dbgftrace.h>
63#include "NEMInternal.h"
64#include <VBox/vmm/vmcc.h>
65
66#include <iprt/ldr.h>
67#include <iprt/path.h>
68#include <iprt/string.h>
69#include <iprt/system.h>
70#include <iprt/utf16.h>
71
72#ifndef NTDDI_WIN10_VB /* Present in W10 2004 SDK, quite possibly earlier. */
73HRESULT WINAPI WHvQueryGpaRangeDirtyBitmap(WHV_PARTITION_HANDLE, WHV_GUEST_PHYSICAL_ADDRESS, UINT64, UINT64 *, UINT32);
74# define WHvMapGpaRangeFlagTrackDirtyPages ((WHV_MAP_GPA_RANGE_FLAGS)0x00000008)
75#endif
76
77
78/*********************************************************************************************************************************
79* Defined Constants And Macros *
80*********************************************************************************************************************************/
81#ifdef LOG_ENABLED
82# define NEM_WIN_INTERCEPT_NT_IO_CTLS
83#endif
84
85/** VID I/O control detection: Fake partition handle input. */
86#define NEM_WIN_IOCTL_DETECTOR_FAKE_HANDLE ((HANDLE)(uintptr_t)38479125)
87/** VID I/O control detection: Fake partition ID return. */
88#define NEM_WIN_IOCTL_DETECTOR_FAKE_PARTITION_ID UINT64_C(0xfa1e000042424242)
89/** VID I/O control detection: The property we get via VidGetPartitionProperty. */
90#define NEM_WIN_IOCTL_DETECTOR_FAKE_PARTITION_PROPERTY_CODE HvPartitionPropertyProcessorVendor
91/** VID I/O control detection: Fake property value return. */
92#define NEM_WIN_IOCTL_DETECTOR_FAKE_PARTITION_PROPERTY_VALUE UINT64_C(0xf00dface01020304)
93/** VID I/O control detection: Fake CPU index input. */
94#define NEM_WIN_IOCTL_DETECTOR_FAKE_VP_INDEX UINT32_C(42)
95/** VID I/O control detection: Fake timeout input. */
96#define NEM_WIN_IOCTL_DETECTOR_FAKE_TIMEOUT UINT32_C(0x00080286)
97
98
99/*********************************************************************************************************************************
100* Global Variables *
101*********************************************************************************************************************************/
102/** @name APIs imported from WinHvPlatform.dll
103 * @{ */
104static decltype(WHvGetCapability) * g_pfnWHvGetCapability;
105static decltype(WHvCreatePartition) * g_pfnWHvCreatePartition;
106static decltype(WHvSetupPartition) * g_pfnWHvSetupPartition;
107static decltype(WHvDeletePartition) * g_pfnWHvDeletePartition;
108static decltype(WHvGetPartitionProperty) * g_pfnWHvGetPartitionProperty;
109static decltype(WHvSetPartitionProperty) * g_pfnWHvSetPartitionProperty;
110static decltype(WHvMapGpaRange) * g_pfnWHvMapGpaRange;
111static decltype(WHvUnmapGpaRange) * g_pfnWHvUnmapGpaRange;
112static decltype(WHvTranslateGva) * g_pfnWHvTranslateGva;
113static decltype(WHvQueryGpaRangeDirtyBitmap) * g_pfnWHvQueryGpaRangeDirtyBitmap;
114static decltype(WHvCreateVirtualProcessor) * g_pfnWHvCreateVirtualProcessor;
115static decltype(WHvDeleteVirtualProcessor) * g_pfnWHvDeleteVirtualProcessor;
116static decltype(WHvRunVirtualProcessor) * g_pfnWHvRunVirtualProcessor;
117static decltype(WHvCancelRunVirtualProcessor) * g_pfnWHvCancelRunVirtualProcessor;
118static decltype(WHvGetVirtualProcessorRegisters) * g_pfnWHvGetVirtualProcessorRegisters;
119static decltype(WHvSetVirtualProcessorRegisters) * g_pfnWHvSetVirtualProcessorRegisters;
120/** @} */
121
122/** @name APIs imported from Vid.dll
123 * @{ */
124static decltype(VidGetHvPartitionId) *g_pfnVidGetHvPartitionId;
125static decltype(VidGetPartitionProperty) *g_pfnVidGetPartitionProperty;
126#ifdef LOG_ENABLED
127static decltype(VidStartVirtualProcessor) *g_pfnVidStartVirtualProcessor;
128static decltype(VidStopVirtualProcessor) *g_pfnVidStopVirtualProcessor;
129static decltype(VidMessageSlotMap) *g_pfnVidMessageSlotMap;
130static decltype(VidMessageSlotHandleAndGetNext) *g_pfnVidMessageSlotHandleAndGetNext;
131static decltype(VidGetVirtualProcessorState) *g_pfnVidGetVirtualProcessorState;
132static decltype(VidSetVirtualProcessorState) *g_pfnVidSetVirtualProcessorState;
133static decltype(VidGetVirtualProcessorRunningStatus) *g_pfnVidGetVirtualProcessorRunningStatus;
134#endif
135/** @} */
136
137/** The Windows build number. */
138static uint32_t g_uBuildNo = 17134;
139
140
141
142/**
143 * Import instructions.
144 */
145static const struct
146{
147 uint8_t idxDll; /**< 0 for WinHvPlatform.dll, 1 for vid.dll. */
148 bool fOptional; /**< Set if import is optional. */
149 PFNRT *ppfn; /**< The function pointer variable. */
150 const char *pszName; /**< The function name. */
151} g_aImports[] =
152{
153#define NEM_WIN_IMPORT(a_idxDll, a_fOptional, a_Name) { (a_idxDll), (a_fOptional), (PFNRT *)&RT_CONCAT(g_pfn,a_Name), #a_Name }
154 NEM_WIN_IMPORT(0, false, WHvGetCapability),
155 NEM_WIN_IMPORT(0, false, WHvCreatePartition),
156 NEM_WIN_IMPORT(0, false, WHvSetupPartition),
157 NEM_WIN_IMPORT(0, false, WHvDeletePartition),
158 NEM_WIN_IMPORT(0, false, WHvGetPartitionProperty),
159 NEM_WIN_IMPORT(0, false, WHvSetPartitionProperty),
160 NEM_WIN_IMPORT(0, false, WHvMapGpaRange),
161 NEM_WIN_IMPORT(0, false, WHvUnmapGpaRange),
162 NEM_WIN_IMPORT(0, false, WHvTranslateGva),
163 NEM_WIN_IMPORT(0, true, WHvQueryGpaRangeDirtyBitmap),
164 NEM_WIN_IMPORT(0, false, WHvCreateVirtualProcessor),
165 NEM_WIN_IMPORT(0, false, WHvDeleteVirtualProcessor),
166 NEM_WIN_IMPORT(0, false, WHvRunVirtualProcessor),
167 NEM_WIN_IMPORT(0, false, WHvCancelRunVirtualProcessor),
168 NEM_WIN_IMPORT(0, false, WHvGetVirtualProcessorRegisters),
169 NEM_WIN_IMPORT(0, false, WHvSetVirtualProcessorRegisters),
170
171 NEM_WIN_IMPORT(1, true, VidGetHvPartitionId),
172 NEM_WIN_IMPORT(1, true, VidGetPartitionProperty),
173#ifdef LOG_ENABLED
174 NEM_WIN_IMPORT(1, false, VidMessageSlotMap),
175 NEM_WIN_IMPORT(1, false, VidMessageSlotHandleAndGetNext),
176 NEM_WIN_IMPORT(1, false, VidStartVirtualProcessor),
177 NEM_WIN_IMPORT(1, false, VidStopVirtualProcessor),
178 NEM_WIN_IMPORT(1, false, VidGetVirtualProcessorState),
179 NEM_WIN_IMPORT(1, false, VidSetVirtualProcessorState),
180 NEM_WIN_IMPORT(1, false, VidGetVirtualProcessorRunningStatus),
181#endif
182#undef NEM_WIN_IMPORT
183};
184
185
186/** The real NtDeviceIoControlFile API in NTDLL. */
187static decltype(NtDeviceIoControlFile) *g_pfnNtDeviceIoControlFile;
188/** Pointer to the NtDeviceIoControlFile import table entry. */
189static decltype(NtDeviceIoControlFile) **g_ppfnVidNtDeviceIoControlFile;
190#ifdef LOG_ENABLED
191/** Info about the VidGetHvPartitionId I/O control interface. */
192static NEMWINIOCTL g_IoCtlGetHvPartitionId;
193/** Info about the VidGetPartitionProperty I/O control interface. */
194static NEMWINIOCTL g_IoCtlGetPartitionProperty;
195/** Info about the VidStartVirtualProcessor I/O control interface. */
196static NEMWINIOCTL g_IoCtlStartVirtualProcessor;
197/** Info about the VidStopVirtualProcessor I/O control interface. */
198static NEMWINIOCTL g_IoCtlStopVirtualProcessor;
199/** Info about the VidMessageSlotHandleAndGetNext I/O control interface. */
200static NEMWINIOCTL g_IoCtlMessageSlotHandleAndGetNext;
201/** Info about the VidMessageSlotMap I/O control interface - for logging. */
202static NEMWINIOCTL g_IoCtlMessageSlotMap;
203/** Info about the VidGetVirtualProcessorState I/O control interface - for logging. */
204static NEMWINIOCTL g_IoCtlGetVirtualProcessorState;
205/** Info about the VidSetVirtualProcessorState I/O control interface - for logging. */
206static NEMWINIOCTL g_IoCtlSetVirtualProcessorState;
207/** Pointer to what nemR3WinIoctlDetector_ForLogging should fill in. */
208static NEMWINIOCTL *g_pIoCtlDetectForLogging;
209#endif
210
211#ifdef NEM_WIN_INTERCEPT_NT_IO_CTLS
212/** Mapping slot for CPU #0.
213 * @{ */
214static VID_MESSAGE_MAPPING_HEADER *g_pMsgSlotMapping = NULL;
215static const HV_MESSAGE_HEADER *g_pHvMsgHdr;
216static const HV_X64_INTERCEPT_MESSAGE_HEADER *g_pX64MsgHdr;
217/** @} */
218#endif
219
220
221/*
222 * Let the preprocessor alias the APIs to import variables for better autocompletion.
223 */
224#ifndef IN_SLICKEDIT
225# define WHvGetCapability g_pfnWHvGetCapability
226# define WHvCreatePartition g_pfnWHvCreatePartition
227# define WHvSetupPartition g_pfnWHvSetupPartition
228# define WHvDeletePartition g_pfnWHvDeletePartition
229# define WHvGetPartitionProperty g_pfnWHvGetPartitionProperty
230# define WHvSetPartitionProperty g_pfnWHvSetPartitionProperty
231# define WHvMapGpaRange g_pfnWHvMapGpaRange
232# define WHvUnmapGpaRange g_pfnWHvUnmapGpaRange
233# define WHvTranslateGva g_pfnWHvTranslateGva
234# define WHvQueryGpaRangeDirtyBitmap g_pfnWHvQueryGpaRangeDirtyBitmap
235# define WHvCreateVirtualProcessor g_pfnWHvCreateVirtualProcessor
236# define WHvDeleteVirtualProcessor g_pfnWHvDeleteVirtualProcessor
237# define WHvRunVirtualProcessor g_pfnWHvRunVirtualProcessor
238# define WHvGetRunExitContextSize g_pfnWHvGetRunExitContextSize
239# define WHvCancelRunVirtualProcessor g_pfnWHvCancelRunVirtualProcessor
240# define WHvGetVirtualProcessorRegisters g_pfnWHvGetVirtualProcessorRegisters
241# define WHvSetVirtualProcessorRegisters g_pfnWHvSetVirtualProcessorRegisters
242
243# define VidMessageSlotHandleAndGetNext g_pfnVidMessageSlotHandleAndGetNext
244# define VidStartVirtualProcessor g_pfnVidStartVirtualProcessor
245# define VidStopVirtualProcessor g_pfnVidStopVirtualProcessor
246
247#endif
248
249/** WHV_MEMORY_ACCESS_TYPE names */
250static const char * const g_apszWHvMemAccesstypes[4] = { "read", "write", "exec", "!undefined!" };
251
252
253/*********************************************************************************************************************************
254* Internal Functions *
255*********************************************************************************************************************************/
256DECLINLINE(int) nemR3NativeGCPhys2R3PtrReadOnly(PVM pVM, RTGCPHYS GCPhys, const void **ppv);
257DECLINLINE(int) nemR3NativeGCPhys2R3PtrWriteable(PVM pVM, RTGCPHYS GCPhys, void **ppv);
258
259/*
260 * Instantate the code we used to share with ring-0.
261 */
262#include "../VMMAll/NEMAllNativeTemplate-win.cpp.h"
263
264
265
266#ifdef NEM_WIN_INTERCEPT_NT_IO_CTLS
267/**
268 * Wrapper that logs the call from VID.DLL.
269 *
270 * This is very handy for figuring out why an API call fails.
271 */
272static NTSTATUS WINAPI
273nemR3WinLogWrapper_NtDeviceIoControlFile(HANDLE hFile, HANDLE hEvt, PIO_APC_ROUTINE pfnApcCallback, PVOID pvApcCtx,
274 PIO_STATUS_BLOCK pIos, ULONG uFunction, PVOID pvInput, ULONG cbInput,
275 PVOID pvOutput, ULONG cbOutput)
276{
277
278 char szFunction[32];
279 const char *pszFunction;
280 if (uFunction == g_IoCtlMessageSlotHandleAndGetNext.uFunction)
281 pszFunction = "VidMessageSlotHandleAndGetNext";
282 else if (uFunction == g_IoCtlStartVirtualProcessor.uFunction)
283 pszFunction = "VidStartVirtualProcessor";
284 else if (uFunction == g_IoCtlStopVirtualProcessor.uFunction)
285 pszFunction = "VidStopVirtualProcessor";
286 else if (uFunction == g_IoCtlMessageSlotMap.uFunction)
287 pszFunction = "VidMessageSlotMap";
288 else if (uFunction == g_IoCtlGetVirtualProcessorState.uFunction)
289 pszFunction = "VidGetVirtualProcessorState";
290 else if (uFunction == g_IoCtlSetVirtualProcessorState.uFunction)
291 pszFunction = "VidSetVirtualProcessorState";
292 else
293 {
294 RTStrPrintf(szFunction, sizeof(szFunction), "%#x", uFunction);
295 pszFunction = szFunction;
296 }
297
298 if (cbInput > 0 && pvInput)
299 Log12(("VID!NtDeviceIoControlFile: %s/input: %.*Rhxs\n", pszFunction, RT_MIN(cbInput, 32), pvInput));
300 NTSTATUS rcNt = g_pfnNtDeviceIoControlFile(hFile, hEvt, pfnApcCallback, pvApcCtx, pIos, uFunction,
301 pvInput, cbInput, pvOutput, cbOutput);
302 if (!hEvt && !pfnApcCallback && !pvApcCtx)
303 Log12(("VID!NtDeviceIoControlFile: hFile=%#zx pIos=%p->{s:%#x, i:%#zx} uFunction=%s Input=%p LB %#x Output=%p LB %#x) -> %#x; Caller=%p\n",
304 hFile, pIos, pIos->Status, pIos->Information, pszFunction, pvInput, cbInput, pvOutput, cbOutput, rcNt, ASMReturnAddress()));
305 else
306 Log12(("VID!NtDeviceIoControlFile: hFile=%#zx hEvt=%#zx Apc=%p/%p pIos=%p->{s:%#x, i:%#zx} uFunction=%s Input=%p LB %#x Output=%p LB %#x) -> %#x; Caller=%p\n",
307 hFile, hEvt, RT_CB_LOG_CAST(pfnApcCallback), pvApcCtx, pIos, pIos->Status, pIos->Information, pszFunction,
308 pvInput, cbInput, pvOutput, cbOutput, rcNt, ASMReturnAddress()));
309 if (cbOutput > 0 && pvOutput)
310 {
311 Log12(("VID!NtDeviceIoControlFile: %s/output: %.*Rhxs\n", pszFunction, RT_MIN(cbOutput, 32), pvOutput));
312 if (uFunction == 0x2210cc && g_pMsgSlotMapping == NULL && cbOutput >= sizeof(void *))
313 {
314 g_pMsgSlotMapping = *(VID_MESSAGE_MAPPING_HEADER **)pvOutput;
315 g_pHvMsgHdr = (const HV_MESSAGE_HEADER *)(g_pMsgSlotMapping + 1);
316 g_pX64MsgHdr = (const HV_X64_INTERCEPT_MESSAGE_HEADER *)(g_pHvMsgHdr + 1);
317 Log12(("VID!NtDeviceIoControlFile: Message slot mapping: %p\n", g_pMsgSlotMapping));
318 }
319 }
320 if ( g_pMsgSlotMapping
321 && ( uFunction == g_IoCtlMessageSlotHandleAndGetNext.uFunction
322 || uFunction == g_IoCtlStopVirtualProcessor.uFunction
323 || uFunction == g_IoCtlMessageSlotMap.uFunction
324 ))
325 Log12(("VID!NtDeviceIoControlFile: enmVidMsgType=%#x cb=%#x msg=%#x payload=%u cs:rip=%04x:%08RX64 (%s)\n",
326 g_pMsgSlotMapping->enmVidMsgType, g_pMsgSlotMapping->cbMessage,
327 g_pHvMsgHdr->MessageType, g_pHvMsgHdr->PayloadSize,
328 g_pX64MsgHdr->CsSegment.Selector, g_pX64MsgHdr->Rip, pszFunction));
329
330 return rcNt;
331}
332#endif /* NEM_WIN_INTERCEPT_NT_IO_CTLS */
333
334
335/**
336 * Patches the call table of VID.DLL so we can intercept NtDeviceIoControlFile.
337 *
338 * This is for used to figure out the I/O control codes and in logging builds
339 * for logging API calls that WinHvPlatform.dll does.
340 *
341 * @returns VBox status code.
342 * @param hLdrModVid The VID module handle.
343 * @param pErrInfo Where to return additional error information.
344 */
345static int nemR3WinInitVidIntercepts(RTLDRMOD hLdrModVid, PRTERRINFO pErrInfo)
346{
347 /*
348 * Locate the real API.
349 */
350 g_pfnNtDeviceIoControlFile = (decltype(NtDeviceIoControlFile) *)RTLdrGetSystemSymbol("NTDLL.DLL", "NtDeviceIoControlFile");
351 AssertReturn(g_pfnNtDeviceIoControlFile != NULL,
352 RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED, "Failed to resolve NtDeviceIoControlFile from NTDLL.DLL"));
353
354 /*
355 * Locate the PE header and get what we need from it.
356 */
357 uint8_t const *pbImage = (uint8_t const *)RTLdrGetNativeHandle(hLdrModVid);
358 IMAGE_DOS_HEADER const *pMzHdr = (IMAGE_DOS_HEADER const *)pbImage;
359 AssertReturn(pMzHdr->e_magic == IMAGE_DOS_SIGNATURE,
360 RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED, "VID.DLL mapping doesn't start with MZ signature: %#x", pMzHdr->e_magic));
361 IMAGE_NT_HEADERS const *pNtHdrs = (IMAGE_NT_HEADERS const *)&pbImage[pMzHdr->e_lfanew];
362 AssertReturn(pNtHdrs->Signature == IMAGE_NT_SIGNATURE,
363 RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED, "VID.DLL has invalid PE signaturre: %#x @%#x",
364 pNtHdrs->Signature, pMzHdr->e_lfanew));
365
366 uint32_t const cbImage = pNtHdrs->OptionalHeader.SizeOfImage;
367 IMAGE_DATA_DIRECTORY const ImportDir = pNtHdrs->OptionalHeader.DataDirectory[IMAGE_DIRECTORY_ENTRY_IMPORT];
368
369 /*
370 * Walk the import descriptor table looking for NTDLL.DLL.
371 */
372 AssertReturn( ImportDir.Size > 0
373 && ImportDir.Size < cbImage,
374 RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED, "VID.DLL bad import directory size: %#x", ImportDir.Size));
375 AssertReturn( ImportDir.VirtualAddress > 0
376 && ImportDir.VirtualAddress <= cbImage - ImportDir.Size,
377 RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED, "VID.DLL bad import directory RVA: %#x", ImportDir.VirtualAddress));
378
379 for (PIMAGE_IMPORT_DESCRIPTOR pImps = (PIMAGE_IMPORT_DESCRIPTOR)&pbImage[ImportDir.VirtualAddress];
380 pImps->Name != 0 && pImps->FirstThunk != 0;
381 pImps++)
382 {
383 AssertReturn(pImps->Name < cbImage,
384 RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED, "VID.DLL bad import directory entry name: %#x", pImps->Name));
385 const char *pszModName = (const char *)&pbImage[pImps->Name];
386 if (RTStrICmpAscii(pszModName, "ntdll.dll"))
387 continue;
388 AssertReturn(pImps->FirstThunk < cbImage,
389 RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED, "VID.DLL bad FirstThunk: %#x", pImps->FirstThunk));
390 AssertReturn(pImps->OriginalFirstThunk < cbImage,
391 RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED, "VID.DLL bad FirstThunk: %#x", pImps->FirstThunk));
392
393 /*
394 * Walk the thunks table(s) looking for NtDeviceIoControlFile.
395 */
396 uintptr_t *puFirstThunk = (uintptr_t *)&pbImage[pImps->FirstThunk]; /* update this. */
397 if ( pImps->OriginalFirstThunk != 0
398 && pImps->OriginalFirstThunk != pImps->FirstThunk)
399 {
400 uintptr_t const *puOrgThunk = (uintptr_t const *)&pbImage[pImps->OriginalFirstThunk]; /* read from this. */
401 uintptr_t cLeft = (cbImage - (RT_MAX(pImps->FirstThunk, pImps->OriginalFirstThunk)))
402 / sizeof(*puFirstThunk);
403 while (cLeft-- > 0 && *puOrgThunk != 0)
404 {
405 if (!(*puOrgThunk & IMAGE_ORDINAL_FLAG64)) /* ASSUMES 64-bit */
406 {
407 AssertReturn(*puOrgThunk > 0 && *puOrgThunk < cbImage,
408 RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED, "VID.DLL bad thunk entry: %#x", *puOrgThunk));
409
410 const char *pszSymbol = (const char *)&pbImage[*puOrgThunk + 2];
411 if (strcmp(pszSymbol, "NtDeviceIoControlFile") == 0)
412 g_ppfnVidNtDeviceIoControlFile = (decltype(NtDeviceIoControlFile) **)puFirstThunk;
413 }
414
415 puOrgThunk++;
416 puFirstThunk++;
417 }
418 }
419 else
420 {
421 /* No original thunk table, so scan the resolved symbols for a match
422 with the NtDeviceIoControlFile address. */
423 uintptr_t const uNeedle = (uintptr_t)g_pfnNtDeviceIoControlFile;
424 uintptr_t cLeft = (cbImage - pImps->FirstThunk) / sizeof(*puFirstThunk);
425 while (cLeft-- > 0 && *puFirstThunk != 0)
426 {
427 if (*puFirstThunk == uNeedle)
428 g_ppfnVidNtDeviceIoControlFile = (decltype(NtDeviceIoControlFile) **)puFirstThunk;
429 puFirstThunk++;
430 }
431 }
432 }
433
434 if (g_ppfnVidNtDeviceIoControlFile != NULL)
435 {
436 /* Make the thunk writable we can freely modify it. */
437 DWORD fOldProt = PAGE_READONLY;
438 VirtualProtect((void *)(uintptr_t)g_ppfnVidNtDeviceIoControlFile, sizeof(uintptr_t), PAGE_EXECUTE_READWRITE, &fOldProt);
439
440#ifdef NEM_WIN_INTERCEPT_NT_IO_CTLS
441 *g_ppfnVidNtDeviceIoControlFile = nemR3WinLogWrapper_NtDeviceIoControlFile;
442#endif
443 return VINF_SUCCESS;
444 }
445 return RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED, "Failed to patch NtDeviceIoControlFile import in VID.DLL!");
446}
447
448
449/**
450 * Worker for nemR3NativeInit that probes and load the native API.
451 *
452 * @returns VBox status code.
453 * @param fForced Whether the HMForced flag is set and we should
454 * fail if we cannot initialize.
455 * @param pErrInfo Where to always return error info.
456 */
457static int nemR3WinInitProbeAndLoad(bool fForced, PRTERRINFO pErrInfo)
458{
459 /*
460 * Check that the DLL files we need are present, but without loading them.
461 * We'd like to avoid loading them unnecessarily.
462 */
463 WCHAR wszPath[MAX_PATH + 64];
464 UINT cwcPath = GetSystemDirectoryW(wszPath, MAX_PATH);
465 if (cwcPath >= MAX_PATH || cwcPath < 2)
466 return RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED, "GetSystemDirectoryW failed (%#x / %u)", cwcPath, GetLastError());
467
468 if (wszPath[cwcPath - 1] != '\\' || wszPath[cwcPath - 1] != '/')
469 wszPath[cwcPath++] = '\\';
470 RTUtf16CopyAscii(&wszPath[cwcPath], RT_ELEMENTS(wszPath) - cwcPath, "WinHvPlatform.dll");
471 if (GetFileAttributesW(wszPath) == INVALID_FILE_ATTRIBUTES)
472 return RTErrInfoSetF(pErrInfo, VERR_NEM_NOT_AVAILABLE, "The native API dll was not found (%ls)", wszPath);
473
474 /*
475 * Check that we're in a VM and that the hypervisor identifies itself as Hyper-V.
476 */
477 if (!ASMHasCpuId())
478 return RTErrInfoSet(pErrInfo, VERR_NEM_NOT_AVAILABLE, "No CPUID support");
479 if (!RTX86IsValidStdRange(ASMCpuId_EAX(0)))
480 return RTErrInfoSet(pErrInfo, VERR_NEM_NOT_AVAILABLE, "No CPUID leaf #1");
481 if (!(ASMCpuId_ECX(1) & X86_CPUID_FEATURE_ECX_HVP))
482 return RTErrInfoSet(pErrInfo, VERR_NEM_NOT_AVAILABLE, "Not in a hypervisor partition (HVP=0)");
483
484 uint32_t cMaxHyperLeaf = 0;
485 uint32_t uEbx = 0;
486 uint32_t uEcx = 0;
487 uint32_t uEdx = 0;
488 ASMCpuIdExSlow(0x40000000, 0, 0, 0, &cMaxHyperLeaf, &uEbx, &uEcx, &uEdx);
489 if (!RTX86IsValidHypervisorRange(cMaxHyperLeaf))
490 return RTErrInfoSetF(pErrInfo, VERR_NEM_NOT_AVAILABLE, "Invalid hypervisor CPUID range (%#x %#x %#x %#x)",
491 cMaxHyperLeaf, uEbx, uEcx, uEdx);
492 if ( uEbx != UINT32_C(0x7263694d) /* Micr */
493 || uEcx != UINT32_C(0x666f736f) /* osof */
494 || uEdx != UINT32_C(0x76482074) /* t Hv */)
495 return RTErrInfoSetF(pErrInfo, VERR_NEM_NOT_AVAILABLE,
496 "Not Hyper-V CPUID signature: %#x %#x %#x (expected %#x %#x %#x)",
497 uEbx, uEcx, uEdx, UINT32_C(0x7263694d), UINT32_C(0x666f736f), UINT32_C(0x76482074));
498 if (cMaxHyperLeaf < UINT32_C(0x40000005))
499 return RTErrInfoSetF(pErrInfo, VERR_NEM_NOT_AVAILABLE, "Too narrow hypervisor CPUID range (%#x)", cMaxHyperLeaf);
500
501 /** @todo would be great if we could recognize a root partition from the
502 * CPUID info, but I currently don't dare do that. */
503
504 /*
505 * Now try load the DLLs and resolve the APIs.
506 */
507 static const char * const s_apszDllNames[2] = { "WinHvPlatform.dll", "vid.dll" };
508 RTLDRMOD ahMods[2] = { NIL_RTLDRMOD, NIL_RTLDRMOD };
509 int rc = VINF_SUCCESS;
510 for (unsigned i = 0; i < RT_ELEMENTS(s_apszDllNames); i++)
511 {
512 int rc2 = RTLdrLoadSystem(s_apszDllNames[i], true /*fNoUnload*/, &ahMods[i]);
513 if (RT_FAILURE(rc2))
514 {
515 if (!RTErrInfoIsSet(pErrInfo))
516 RTErrInfoSetF(pErrInfo, rc2, "Failed to load API DLL: %s: %Rrc", s_apszDllNames[i], rc2);
517 else
518 RTErrInfoAddF(pErrInfo, rc2, "; %s: %Rrc", s_apszDllNames[i], rc2);
519 ahMods[i] = NIL_RTLDRMOD;
520 rc = VERR_NEM_INIT_FAILED;
521 }
522 }
523 if (RT_SUCCESS(rc))
524 rc = nemR3WinInitVidIntercepts(ahMods[1], pErrInfo);
525 if (RT_SUCCESS(rc))
526 {
527 for (unsigned i = 0; i < RT_ELEMENTS(g_aImports); i++)
528 {
529 int rc2 = RTLdrGetSymbol(ahMods[g_aImports[i].idxDll], g_aImports[i].pszName, (void **)g_aImports[i].ppfn);
530 if (RT_SUCCESS(rc2))
531 {
532 if (g_aImports[i].fOptional)
533 LogRel(("NEM: info: Found optional import %s!%s.\n",
534 s_apszDllNames[g_aImports[i].idxDll], g_aImports[i].pszName));
535 }
536 else
537 {
538 *g_aImports[i].ppfn = NULL;
539
540 LogRel(("NEM: %s: Failed to import %s!%s: %Rrc",
541 g_aImports[i].fOptional ? "info" : fForced ? "fatal" : "error",
542 s_apszDllNames[g_aImports[i].idxDll], g_aImports[i].pszName, rc2));
543 if (!g_aImports[i].fOptional)
544 {
545 if (RTErrInfoIsSet(pErrInfo))
546 RTErrInfoAddF(pErrInfo, rc2, ", %s!%s",
547 s_apszDllNames[g_aImports[i].idxDll], g_aImports[i].pszName);
548 else
549 rc = RTErrInfoSetF(pErrInfo, rc2, "Failed to import: %s!%s",
550 s_apszDllNames[g_aImports[i].idxDll], g_aImports[i].pszName);
551 Assert(RT_FAILURE(rc));
552 }
553 }
554 }
555 if (RT_SUCCESS(rc))
556 {
557 Assert(!RTErrInfoIsSet(pErrInfo));
558 }
559 }
560
561 for (unsigned i = 0; i < RT_ELEMENTS(ahMods); i++)
562 RTLdrClose(ahMods[i]);
563 return rc;
564}
565
566
567/**
568 * Wrapper for different WHvGetCapability signatures.
569 */
570DECLINLINE(HRESULT) WHvGetCapabilityWrapper(WHV_CAPABILITY_CODE enmCap, WHV_CAPABILITY *pOutput, uint32_t cbOutput)
571{
572 return g_pfnWHvGetCapability(enmCap, pOutput, cbOutput, NULL);
573}
574
575
576/**
577 * Worker for nemR3NativeInit that gets the hypervisor capabilities.
578 *
579 * @returns VBox status code.
580 * @param pVM The cross context VM structure.
581 * @param pErrInfo Where to always return error info.
582 */
583static int nemR3WinInitCheckCapabilities(PVM pVM, PRTERRINFO pErrInfo)
584{
585#define NEM_LOG_REL_CAP_EX(a_szField, a_szFmt, a_Value) LogRel(("NEM: %-38s= " a_szFmt "\n", a_szField, a_Value))
586#define NEM_LOG_REL_CAP_SUB_EX(a_szField, a_szFmt, a_Value) LogRel(("NEM: %36s: " a_szFmt "\n", a_szField, a_Value))
587#define NEM_LOG_REL_CAP_SUB(a_szField, a_Value) NEM_LOG_REL_CAP_SUB_EX(a_szField, "%d", a_Value)
588
589 /*
590 * Is the hypervisor present with the desired capability?
591 *
592 * In build 17083 this translates into:
593 * - CPUID[0x00000001].HVP is set
594 * - CPUID[0x40000000] == "Microsoft Hv"
595 * - CPUID[0x40000001].eax == "Hv#1"
596 * - CPUID[0x40000003].ebx[12] is set.
597 * - VidGetExoPartitionProperty(INVALID_HANDLE_VALUE, 0x60000, &Ignored) returns
598 * a non-zero value.
599 */
600 /**
601 * @todo Someone at Microsoft please explain weird API design:
602 * 1. Pointless CapabilityCode duplication int the output;
603 * 2. No output size.
604 */
605 WHV_CAPABILITY Caps;
606 RT_ZERO(Caps);
607 SetLastError(0);
608 HRESULT hrc = WHvGetCapabilityWrapper(WHvCapabilityCodeHypervisorPresent, &Caps, sizeof(Caps));
609 DWORD rcWin = GetLastError();
610 if (FAILED(hrc))
611 return RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED,
612 "WHvGetCapability/WHvCapabilityCodeHypervisorPresent failed: %Rhrc (Last=%#x/%u)",
613 hrc, RTNtLastStatusValue(), RTNtLastErrorValue());
614 if (!Caps.HypervisorPresent)
615 {
616 if (!RTPathExists(RTPATH_NT_PASSTHRU_PREFIX "Device\\VidExo"))
617 return RTErrInfoSetF(pErrInfo, VERR_NEM_NOT_AVAILABLE,
618 "WHvCapabilityCodeHypervisorPresent is FALSE! Make sure you have enabled the 'Windows Hypervisor Platform' feature.");
619 return RTErrInfoSetF(pErrInfo, VERR_NEM_NOT_AVAILABLE, "WHvCapabilityCodeHypervisorPresent is FALSE! (%u)", rcWin);
620 }
621 LogRel(("NEM: WHvCapabilityCodeHypervisorPresent is TRUE, so this might work...\n"));
622
623
624 /*
625 * Check what extended VM exits are supported.
626 */
627 RT_ZERO(Caps);
628 hrc = WHvGetCapabilityWrapper(WHvCapabilityCodeExtendedVmExits, &Caps, sizeof(Caps));
629 if (FAILED(hrc))
630 return RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED,
631 "WHvGetCapability/WHvCapabilityCodeExtendedVmExits failed: %Rhrc (Last=%#x/%u)",
632 hrc, RTNtLastStatusValue(), RTNtLastErrorValue());
633 NEM_LOG_REL_CAP_EX("WHvCapabilityCodeExtendedVmExits", "%'#018RX64", Caps.ExtendedVmExits.AsUINT64);
634 pVM->nem.s.fExtendedMsrExit = RT_BOOL(Caps.ExtendedVmExits.X64MsrExit);
635 pVM->nem.s.fExtendedCpuIdExit = RT_BOOL(Caps.ExtendedVmExits.X64CpuidExit);
636 pVM->nem.s.fExtendedXcptExit = RT_BOOL(Caps.ExtendedVmExits.ExceptionExit);
637 NEM_LOG_REL_CAP_SUB("fExtendedMsrExit", pVM->nem.s.fExtendedMsrExit);
638 NEM_LOG_REL_CAP_SUB("fExtendedCpuIdExit", pVM->nem.s.fExtendedCpuIdExit);
639 NEM_LOG_REL_CAP_SUB("fExtendedXcptExit", pVM->nem.s.fExtendedXcptExit);
640 if (Caps.ExtendedVmExits.AsUINT64 & ~(uint64_t)7)
641 LogRel(("NEM: Warning! Unknown VM exit definitions: %#RX64\n", Caps.ExtendedVmExits.AsUINT64));
642 /** @todo RECHECK: WHV_EXTENDED_VM_EXITS typedef. */
643
644 /*
645 * Check features in case they end up defining any.
646 */
647 RT_ZERO(Caps);
648 hrc = WHvGetCapabilityWrapper(WHvCapabilityCodeFeatures, &Caps, sizeof(Caps));
649 if (FAILED(hrc))
650 return RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED,
651 "WHvGetCapability/WHvCapabilityCodeFeatures failed: %Rhrc (Last=%#x/%u)",
652 hrc, RTNtLastStatusValue(), RTNtLastErrorValue());
653 if (Caps.Features.AsUINT64 & ~(uint64_t)0)
654 LogRel(("NEM: Warning! Unknown feature definitions: %#RX64\n", Caps.Features.AsUINT64));
655 /** @todo RECHECK: WHV_CAPABILITY_FEATURES typedef. */
656
657 /*
658 * Check supported exception exit bitmap bits.
659 * We don't currently require this, so we just log failure.
660 */
661 RT_ZERO(Caps);
662 hrc = WHvGetCapabilityWrapper(WHvCapabilityCodeExceptionExitBitmap, &Caps, sizeof(Caps));
663 if (SUCCEEDED(hrc))
664 LogRel(("NEM: Supported exception exit bitmap: %#RX64\n", Caps.ExceptionExitBitmap));
665 else
666 LogRel(("NEM: Warning! WHvGetCapability/WHvCapabilityCodeExceptionExitBitmap failed: %Rhrc (Last=%#x/%u)",
667 hrc, RTNtLastStatusValue(), RTNtLastErrorValue()));
668
669 /*
670 * Check that the CPU vendor is supported.
671 */
672 RT_ZERO(Caps);
673 hrc = WHvGetCapabilityWrapper(WHvCapabilityCodeProcessorVendor, &Caps, sizeof(Caps));
674 if (FAILED(hrc))
675 return RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED,
676 "WHvGetCapability/WHvCapabilityCodeProcessorVendor failed: %Rhrc (Last=%#x/%u)",
677 hrc, RTNtLastStatusValue(), RTNtLastErrorValue());
678 switch (Caps.ProcessorVendor)
679 {
680 /** @todo RECHECK: WHV_PROCESSOR_VENDOR typedef. */
681 case WHvProcessorVendorIntel:
682 NEM_LOG_REL_CAP_EX("WHvCapabilityCodeProcessorVendor", "%d - Intel", Caps.ProcessorVendor);
683 pVM->nem.s.enmCpuVendor = CPUMCPUVENDOR_INTEL;
684 break;
685 case WHvProcessorVendorAmd:
686 NEM_LOG_REL_CAP_EX("WHvCapabilityCodeProcessorVendor", "%d - AMD", Caps.ProcessorVendor);
687 pVM->nem.s.enmCpuVendor = CPUMCPUVENDOR_AMD;
688 break;
689 default:
690 NEM_LOG_REL_CAP_EX("WHvCapabilityCodeProcessorVendor", "%d", Caps.ProcessorVendor);
691 return RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED, "Unknown processor vendor: %d", Caps.ProcessorVendor);
692 }
693
694 /*
695 * CPU features, guessing these are virtual CPU features?
696 */
697 RT_ZERO(Caps);
698 hrc = WHvGetCapabilityWrapper(WHvCapabilityCodeProcessorFeatures, &Caps, sizeof(Caps));
699 if (FAILED(hrc))
700 return RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED,
701 "WHvGetCapability/WHvCapabilityCodeProcessorFeatures failed: %Rhrc (Last=%#x/%u)",
702 hrc, RTNtLastStatusValue(), RTNtLastErrorValue());
703 NEM_LOG_REL_CAP_EX("WHvCapabilityCodeProcessorFeatures", "%'#018RX64", Caps.ProcessorFeatures.AsUINT64);
704#define NEM_LOG_REL_CPU_FEATURE(a_Field) NEM_LOG_REL_CAP_SUB(#a_Field, Caps.ProcessorFeatures.a_Field)
705 NEM_LOG_REL_CPU_FEATURE(Sse3Support);
706 NEM_LOG_REL_CPU_FEATURE(LahfSahfSupport);
707 NEM_LOG_REL_CPU_FEATURE(Ssse3Support);
708 NEM_LOG_REL_CPU_FEATURE(Sse4_1Support);
709 NEM_LOG_REL_CPU_FEATURE(Sse4_2Support);
710 NEM_LOG_REL_CPU_FEATURE(Sse4aSupport);
711 NEM_LOG_REL_CPU_FEATURE(XopSupport);
712 NEM_LOG_REL_CPU_FEATURE(PopCntSupport);
713 NEM_LOG_REL_CPU_FEATURE(Cmpxchg16bSupport);
714 NEM_LOG_REL_CPU_FEATURE(Altmovcr8Support);
715 NEM_LOG_REL_CPU_FEATURE(LzcntSupport);
716 NEM_LOG_REL_CPU_FEATURE(MisAlignSseSupport);
717 NEM_LOG_REL_CPU_FEATURE(MmxExtSupport);
718 NEM_LOG_REL_CPU_FEATURE(Amd3DNowSupport);
719 NEM_LOG_REL_CPU_FEATURE(ExtendedAmd3DNowSupport);
720 NEM_LOG_REL_CPU_FEATURE(Page1GbSupport);
721 NEM_LOG_REL_CPU_FEATURE(AesSupport);
722 NEM_LOG_REL_CPU_FEATURE(PclmulqdqSupport);
723 NEM_LOG_REL_CPU_FEATURE(PcidSupport);
724 NEM_LOG_REL_CPU_FEATURE(Fma4Support);
725 NEM_LOG_REL_CPU_FEATURE(F16CSupport);
726 NEM_LOG_REL_CPU_FEATURE(RdRandSupport);
727 NEM_LOG_REL_CPU_FEATURE(RdWrFsGsSupport);
728 NEM_LOG_REL_CPU_FEATURE(SmepSupport);
729 NEM_LOG_REL_CPU_FEATURE(EnhancedFastStringSupport);
730 NEM_LOG_REL_CPU_FEATURE(Bmi1Support);
731 NEM_LOG_REL_CPU_FEATURE(Bmi2Support);
732 /* two reserved bits here, see below */
733 NEM_LOG_REL_CPU_FEATURE(MovbeSupport);
734 NEM_LOG_REL_CPU_FEATURE(Npiep1Support);
735 NEM_LOG_REL_CPU_FEATURE(DepX87FPUSaveSupport);
736 NEM_LOG_REL_CPU_FEATURE(RdSeedSupport);
737 NEM_LOG_REL_CPU_FEATURE(AdxSupport);
738 NEM_LOG_REL_CPU_FEATURE(IntelPrefetchSupport);
739 NEM_LOG_REL_CPU_FEATURE(SmapSupport);
740 NEM_LOG_REL_CPU_FEATURE(HleSupport);
741 NEM_LOG_REL_CPU_FEATURE(RtmSupport);
742 NEM_LOG_REL_CPU_FEATURE(RdtscpSupport);
743 NEM_LOG_REL_CPU_FEATURE(ClflushoptSupport);
744 NEM_LOG_REL_CPU_FEATURE(ClwbSupport);
745 NEM_LOG_REL_CPU_FEATURE(ShaSupport);
746 NEM_LOG_REL_CPU_FEATURE(X87PointersSavedSupport);
747#undef NEM_LOG_REL_CPU_FEATURE
748 if (Caps.ProcessorFeatures.AsUINT64 & (~(RT_BIT_64(43) - 1) | RT_BIT_64(27) | RT_BIT_64(28)))
749 LogRel(("NEM: Warning! Unknown CPU features: %#RX64\n", Caps.ProcessorFeatures.AsUINT64));
750 pVM->nem.s.uCpuFeatures.u64 = Caps.ProcessorFeatures.AsUINT64;
751 /** @todo RECHECK: WHV_PROCESSOR_FEATURES typedef. */
752
753 /*
754 * The cache line flush size.
755 */
756 RT_ZERO(Caps);
757 hrc = WHvGetCapabilityWrapper(WHvCapabilityCodeProcessorClFlushSize, &Caps, sizeof(Caps));
758 if (FAILED(hrc))
759 return RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED,
760 "WHvGetCapability/WHvCapabilityCodeProcessorClFlushSize failed: %Rhrc (Last=%#x/%u)",
761 hrc, RTNtLastStatusValue(), RTNtLastErrorValue());
762 NEM_LOG_REL_CAP_EX("WHvCapabilityCodeProcessorClFlushSize", "2^%u", Caps.ProcessorClFlushSize);
763 if (Caps.ProcessorClFlushSize < 8 && Caps.ProcessorClFlushSize > 9)
764 return RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED, "Unsupported cache line flush size: %u", Caps.ProcessorClFlushSize);
765 pVM->nem.s.cCacheLineFlushShift = Caps.ProcessorClFlushSize;
766
767 /*
768 * See if they've added more properties that we're not aware of.
769 */
770 /** @todo RECHECK: WHV_CAPABILITY_CODE typedef. */
771 if (!IsDebuggerPresent()) /* Too noisy when in debugger, so skip. */
772 {
773 static const struct
774 {
775 uint32_t iMin, iMax; } s_aUnknowns[] =
776 {
777 { 0x0004, 0x000f },
778 { 0x1003, 0x100f },
779 { 0x2000, 0x200f },
780 { 0x3000, 0x300f },
781 { 0x4000, 0x400f },
782 };
783 for (uint32_t j = 0; j < RT_ELEMENTS(s_aUnknowns); j++)
784 for (uint32_t i = s_aUnknowns[j].iMin; i <= s_aUnknowns[j].iMax; i++)
785 {
786 RT_ZERO(Caps);
787 hrc = WHvGetCapabilityWrapper((WHV_CAPABILITY_CODE)i, &Caps, sizeof(Caps));
788 if (SUCCEEDED(hrc))
789 LogRel(("NEM: Warning! Unknown capability %#x returning: %.*Rhxs\n", i, sizeof(Caps), &Caps));
790 }
791 }
792
793 /*
794 * For proper operation, we require CPUID exits.
795 */
796 if (!pVM->nem.s.fExtendedCpuIdExit)
797 return RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED, "Missing required extended CPUID exit support");
798 if (!pVM->nem.s.fExtendedMsrExit)
799 return RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED, "Missing required extended MSR exit support");
800 if (!pVM->nem.s.fExtendedXcptExit)
801 return RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED, "Missing required extended exception exit support");
802
803#undef NEM_LOG_REL_CAP_EX
804#undef NEM_LOG_REL_CAP_SUB_EX
805#undef NEM_LOG_REL_CAP_SUB
806 return VINF_SUCCESS;
807}
808
809#ifdef LOG_ENABLED
810
811/**
812 * Used to fill in g_IoCtlGetHvPartitionId.
813 */
814static NTSTATUS WINAPI
815nemR3WinIoctlDetector_GetHvPartitionId(HANDLE hFile, HANDLE hEvt, PIO_APC_ROUTINE pfnApcCallback, PVOID pvApcCtx,
816 PIO_STATUS_BLOCK pIos, ULONG uFunction, PVOID pvInput, ULONG cbInput,
817 PVOID pvOutput, ULONG cbOutput)
818{
819 AssertLogRelMsgReturn(hFile == NEM_WIN_IOCTL_DETECTOR_FAKE_HANDLE, ("hFile=%p\n", hFile), STATUS_INVALID_PARAMETER_1);
820 RT_NOREF(hEvt); RT_NOREF(pfnApcCallback); RT_NOREF(pvApcCtx);
821 AssertLogRelMsgReturn(RT_VALID_PTR(pIos), ("pIos=%p\n", pIos), STATUS_INVALID_PARAMETER_5);
822 AssertLogRelMsgReturn(cbInput == 0, ("cbInput=%#x\n", cbInput), STATUS_INVALID_PARAMETER_8);
823 RT_NOREF(pvInput);
824
825 AssertLogRelMsgReturn(RT_VALID_PTR(pvOutput), ("pvOutput=%p\n", pvOutput), STATUS_INVALID_PARAMETER_9);
826 AssertLogRelMsgReturn(cbOutput == sizeof(HV_PARTITION_ID), ("cbInput=%#x\n", cbInput), STATUS_INVALID_PARAMETER_10);
827 *(HV_PARTITION_ID *)pvOutput = NEM_WIN_IOCTL_DETECTOR_FAKE_PARTITION_ID;
828
829 g_IoCtlGetHvPartitionId.cbInput = cbInput;
830 g_IoCtlGetHvPartitionId.cbOutput = cbOutput;
831 g_IoCtlGetHvPartitionId.uFunction = uFunction;
832
833 return STATUS_SUCCESS;
834}
835
836
837/**
838 * Used to fill in g_IoCtlGetHvPartitionId.
839 */
840static NTSTATUS WINAPI
841nemR3WinIoctlDetector_GetPartitionProperty(HANDLE hFile, HANDLE hEvt, PIO_APC_ROUTINE pfnApcCallback, PVOID pvApcCtx,
842 PIO_STATUS_BLOCK pIos, ULONG uFunction, PVOID pvInput, ULONG cbInput,
843 PVOID pvOutput, ULONG cbOutput)
844{
845 AssertLogRelMsgReturn(hFile == NEM_WIN_IOCTL_DETECTOR_FAKE_HANDLE, ("hFile=%p\n", hFile), STATUS_INVALID_PARAMETER_1);
846 RT_NOREF(hEvt); RT_NOREF(pfnApcCallback); RT_NOREF(pvApcCtx);
847 AssertLogRelMsgReturn(RT_VALID_PTR(pIos), ("pIos=%p\n", pIos), STATUS_INVALID_PARAMETER_5);
848 AssertLogRelMsgReturn(cbInput == sizeof(VID_PARTITION_PROPERTY_CODE), ("cbInput=%#x\n", cbInput), STATUS_INVALID_PARAMETER_8);
849 AssertLogRelMsgReturn(RT_VALID_PTR(pvInput), ("pvInput=%p\n", pvInput), STATUS_INVALID_PARAMETER_9);
850 AssertLogRelMsgReturn(*(VID_PARTITION_PROPERTY_CODE *)pvInput == NEM_WIN_IOCTL_DETECTOR_FAKE_PARTITION_PROPERTY_CODE,
851 ("*pvInput=%#x, expected %#x\n", *(HV_PARTITION_PROPERTY_CODE *)pvInput,
852 NEM_WIN_IOCTL_DETECTOR_FAKE_PARTITION_PROPERTY_CODE), STATUS_INVALID_PARAMETER_9);
853 AssertLogRelMsgReturn(RT_VALID_PTR(pvOutput), ("pvOutput=%p\n", pvOutput), STATUS_INVALID_PARAMETER_9);
854 AssertLogRelMsgReturn(cbOutput == sizeof(HV_PARTITION_PROPERTY), ("cbInput=%#x\n", cbInput), STATUS_INVALID_PARAMETER_10);
855 *(HV_PARTITION_PROPERTY *)pvOutput = NEM_WIN_IOCTL_DETECTOR_FAKE_PARTITION_PROPERTY_VALUE;
856
857 g_IoCtlGetPartitionProperty.cbInput = cbInput;
858 g_IoCtlGetPartitionProperty.cbOutput = cbOutput;
859 g_IoCtlGetPartitionProperty.uFunction = uFunction;
860
861 return STATUS_SUCCESS;
862}
863
864
865/**
866 * Used to fill in g_IoCtlStartVirtualProcessor.
867 */
868static NTSTATUS WINAPI
869nemR3WinIoctlDetector_StartVirtualProcessor(HANDLE hFile, HANDLE hEvt, PIO_APC_ROUTINE pfnApcCallback, PVOID pvApcCtx,
870 PIO_STATUS_BLOCK pIos, ULONG uFunction, PVOID pvInput, ULONG cbInput,
871 PVOID pvOutput, ULONG cbOutput)
872{
873 AssertLogRelMsgReturn(hFile == NEM_WIN_IOCTL_DETECTOR_FAKE_HANDLE, ("hFile=%p\n", hFile), STATUS_INVALID_PARAMETER_1);
874 RT_NOREF(hEvt); RT_NOREF(pfnApcCallback); RT_NOREF(pvApcCtx);
875 AssertLogRelMsgReturn(RT_VALID_PTR(pIos), ("pIos=%p\n", pIos), STATUS_INVALID_PARAMETER_5);
876 AssertLogRelMsgReturn(cbInput == sizeof(HV_VP_INDEX), ("cbInput=%#x\n", cbInput), STATUS_INVALID_PARAMETER_8);
877 AssertLogRelMsgReturn(RT_VALID_PTR(pvInput), ("pvInput=%p\n", pvInput), STATUS_INVALID_PARAMETER_9);
878 AssertLogRelMsgReturn(*(HV_VP_INDEX *)pvInput == NEM_WIN_IOCTL_DETECTOR_FAKE_VP_INDEX,
879 ("*piCpu=%u\n", *(HV_VP_INDEX *)pvInput), STATUS_INVALID_PARAMETER_9);
880 AssertLogRelMsgReturn(cbOutput == 0, ("cbInput=%#x\n", cbInput), STATUS_INVALID_PARAMETER_10);
881 RT_NOREF(pvOutput);
882
883 g_IoCtlStartVirtualProcessor.cbInput = cbInput;
884 g_IoCtlStartVirtualProcessor.cbOutput = cbOutput;
885 g_IoCtlStartVirtualProcessor.uFunction = uFunction;
886
887 return STATUS_SUCCESS;
888}
889
890
891/**
892 * Used to fill in g_IoCtlStartVirtualProcessor.
893 */
894static NTSTATUS WINAPI
895nemR3WinIoctlDetector_StopVirtualProcessor(HANDLE hFile, HANDLE hEvt, PIO_APC_ROUTINE pfnApcCallback, PVOID pvApcCtx,
896 PIO_STATUS_BLOCK pIos, ULONG uFunction, PVOID pvInput, ULONG cbInput,
897 PVOID pvOutput, ULONG cbOutput)
898{
899 AssertLogRelMsgReturn(hFile == NEM_WIN_IOCTL_DETECTOR_FAKE_HANDLE, ("hFile=%p\n", hFile), STATUS_INVALID_PARAMETER_1);
900 RT_NOREF(hEvt); RT_NOREF(pfnApcCallback); RT_NOREF(pvApcCtx);
901 AssertLogRelMsgReturn(RT_VALID_PTR(pIos), ("pIos=%p\n", pIos), STATUS_INVALID_PARAMETER_5);
902 AssertLogRelMsgReturn(cbInput == sizeof(HV_VP_INDEX), ("cbInput=%#x\n", cbInput), STATUS_INVALID_PARAMETER_8);
903 AssertLogRelMsgReturn(RT_VALID_PTR(pvInput), ("pvInput=%p\n", pvInput), STATUS_INVALID_PARAMETER_9);
904 AssertLogRelMsgReturn(*(HV_VP_INDEX *)pvInput == NEM_WIN_IOCTL_DETECTOR_FAKE_VP_INDEX,
905 ("*piCpu=%u\n", *(HV_VP_INDEX *)pvInput), STATUS_INVALID_PARAMETER_9);
906 AssertLogRelMsgReturn(cbOutput == 0, ("cbInput=%#x\n", cbInput), STATUS_INVALID_PARAMETER_10);
907 RT_NOREF(pvOutput);
908
909 g_IoCtlStopVirtualProcessor.cbInput = cbInput;
910 g_IoCtlStopVirtualProcessor.cbOutput = cbOutput;
911 g_IoCtlStopVirtualProcessor.uFunction = uFunction;
912
913 return STATUS_SUCCESS;
914}
915
916
917/**
918 * Used to fill in g_IoCtlMessageSlotHandleAndGetNext
919 */
920static NTSTATUS WINAPI
921nemR3WinIoctlDetector_MessageSlotHandleAndGetNext(HANDLE hFile, HANDLE hEvt, PIO_APC_ROUTINE pfnApcCallback, PVOID pvApcCtx,
922 PIO_STATUS_BLOCK pIos, ULONG uFunction, PVOID pvInput, ULONG cbInput,
923 PVOID pvOutput, ULONG cbOutput)
924{
925 AssertLogRelMsgReturn(hFile == NEM_WIN_IOCTL_DETECTOR_FAKE_HANDLE, ("hFile=%p\n", hFile), STATUS_INVALID_PARAMETER_1);
926 RT_NOREF(hEvt); RT_NOREF(pfnApcCallback); RT_NOREF(pvApcCtx);
927 AssertLogRelMsgReturn(RT_VALID_PTR(pIos), ("pIos=%p\n", pIos), STATUS_INVALID_PARAMETER_5);
928
929 if (g_uBuildNo >= 17758)
930 {
931 /* No timeout since about build 17758, it's now always an infinite wait. So, a somewhat compatible change. */
932 AssertLogRelMsgReturn(cbInput == RT_UOFFSETOF(VID_IOCTL_INPUT_MESSAGE_SLOT_HANDLE_AND_GET_NEXT, cMillies),
933 ("cbInput=%#x\n", cbInput),
934 STATUS_INVALID_PARAMETER_8);
935 AssertLogRelMsgReturn(RT_VALID_PTR(pvInput), ("pvInput=%p\n", pvInput), STATUS_INVALID_PARAMETER_9);
936 PCVID_IOCTL_INPUT_MESSAGE_SLOT_HANDLE_AND_GET_NEXT pVidIn = (PCVID_IOCTL_INPUT_MESSAGE_SLOT_HANDLE_AND_GET_NEXT)pvInput;
937 AssertLogRelMsgReturn( pVidIn->iCpu == NEM_WIN_IOCTL_DETECTOR_FAKE_VP_INDEX
938 && pVidIn->fFlags == VID_MSHAGN_F_HANDLE_MESSAGE,
939 ("iCpu=%u fFlags=%#x cMillies=%#x\n", pVidIn->iCpu, pVidIn->fFlags, pVidIn->cMillies),
940 STATUS_INVALID_PARAMETER_9);
941 AssertLogRelMsgReturn(cbOutput == 0, ("cbInput=%#x\n", cbInput), STATUS_INVALID_PARAMETER_10);
942 }
943 else
944 {
945 AssertLogRelMsgReturn(cbInput == sizeof(VID_IOCTL_INPUT_MESSAGE_SLOT_HANDLE_AND_GET_NEXT), ("cbInput=%#x\n", cbInput),
946 STATUS_INVALID_PARAMETER_8);
947 AssertLogRelMsgReturn(RT_VALID_PTR(pvInput), ("pvInput=%p\n", pvInput), STATUS_INVALID_PARAMETER_9);
948 PCVID_IOCTL_INPUT_MESSAGE_SLOT_HANDLE_AND_GET_NEXT pVidIn = (PCVID_IOCTL_INPUT_MESSAGE_SLOT_HANDLE_AND_GET_NEXT)pvInput;
949 AssertLogRelMsgReturn( pVidIn->iCpu == NEM_WIN_IOCTL_DETECTOR_FAKE_VP_INDEX
950 && pVidIn->fFlags == VID_MSHAGN_F_HANDLE_MESSAGE
951 && pVidIn->cMillies == NEM_WIN_IOCTL_DETECTOR_FAKE_TIMEOUT,
952 ("iCpu=%u fFlags=%#x cMillies=%#x\n", pVidIn->iCpu, pVidIn->fFlags, pVidIn->cMillies),
953 STATUS_INVALID_PARAMETER_9);
954 AssertLogRelMsgReturn(cbOutput == 0, ("cbInput=%#x\n", cbInput), STATUS_INVALID_PARAMETER_10);
955 RT_NOREF(pvOutput);
956 }
957
958 g_IoCtlMessageSlotHandleAndGetNext.cbInput = cbInput;
959 g_IoCtlMessageSlotHandleAndGetNext.cbOutput = cbOutput;
960 g_IoCtlMessageSlotHandleAndGetNext.uFunction = uFunction;
961
962 return STATUS_SUCCESS;
963}
964
965/**
966 * Used to fill in what g_pIoCtlDetectForLogging points to.
967 */
968static NTSTATUS WINAPI nemR3WinIoctlDetector_ForLogging(HANDLE hFile, HANDLE hEvt, PIO_APC_ROUTINE pfnApcCallback, PVOID pvApcCtx,
969 PIO_STATUS_BLOCK pIos, ULONG uFunction, PVOID pvInput, ULONG cbInput,
970 PVOID pvOutput, ULONG cbOutput)
971{
972 RT_NOREF(hFile, hEvt, pfnApcCallback, pvApcCtx, pIos, pvInput, pvOutput);
973
974 g_pIoCtlDetectForLogging->cbInput = cbInput;
975 g_pIoCtlDetectForLogging->cbOutput = cbOutput;
976 g_pIoCtlDetectForLogging->uFunction = uFunction;
977
978 return STATUS_SUCCESS;
979}
980
981#endif /* LOG_ENABLED */
982
983/**
984 * Worker for nemR3NativeInit that detect I/O control function numbers for VID.
985 *
986 * We use the function numbers directly in ring-0 and to name functions when
987 * logging NtDeviceIoControlFile calls.
988 *
989 * @note We could alternatively do this by disassembling the respective
990 * functions, but hooking NtDeviceIoControlFile and making fake calls
991 * more easily provides the desired information.
992 *
993 * @returns VBox status code.
994 * @param pVM The cross context VM structure. Will set I/O
995 * control info members.
996 * @param pErrInfo Where to always return error info.
997 */
998static int nemR3WinInitDiscoverIoControlProperties(PVM pVM, PRTERRINFO pErrInfo)
999{
1000 RT_NOREF(pVM, pErrInfo);
1001
1002 /*
1003 * Probe the I/O control information for select VID APIs so we can use
1004 * them directly from ring-0 and better log them.
1005 *
1006 */
1007#ifdef LOG_ENABLED
1008 decltype(NtDeviceIoControlFile) * const pfnOrg = *g_ppfnVidNtDeviceIoControlFile;
1009
1010 /* VidGetHvPartitionId - must work due to our memory management. */
1011 BOOL fRet;
1012 if (g_pfnVidGetHvPartitionId)
1013 {
1014 HV_PARTITION_ID idHvPartition = HV_PARTITION_ID_INVALID;
1015 *g_ppfnVidNtDeviceIoControlFile = nemR3WinIoctlDetector_GetHvPartitionId;
1016 fRet = g_pfnVidGetHvPartitionId(NEM_WIN_IOCTL_DETECTOR_FAKE_HANDLE, &idHvPartition);
1017 *g_ppfnVidNtDeviceIoControlFile = pfnOrg;
1018 AssertReturn(fRet && idHvPartition == NEM_WIN_IOCTL_DETECTOR_FAKE_PARTITION_ID && g_IoCtlGetHvPartitionId.uFunction != 0,
1019 RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED,
1020 "Problem figuring out VidGetHvPartitionId: fRet=%u idHvPartition=%#x dwErr=%u",
1021 fRet, idHvPartition, GetLastError()) );
1022 LogRel(("NEM: VidGetHvPartitionId -> fun:%#x in:%#x out:%#x\n",
1023 g_IoCtlGetHvPartitionId.uFunction, g_IoCtlGetHvPartitionId.cbInput, g_IoCtlGetHvPartitionId.cbOutput));
1024 }
1025
1026 /* VidGetPartitionProperty - must work as it's fallback for VidGetHvPartitionId. */
1027 if (g_ppfnVidNtDeviceIoControlFile)
1028 {
1029 HV_PARTITION_PROPERTY uPropValue = ~NEM_WIN_IOCTL_DETECTOR_FAKE_PARTITION_PROPERTY_VALUE;
1030 *g_ppfnVidNtDeviceIoControlFile = nemR3WinIoctlDetector_GetPartitionProperty;
1031 fRet = g_pfnVidGetPartitionProperty(NEM_WIN_IOCTL_DETECTOR_FAKE_HANDLE, NEM_WIN_IOCTL_DETECTOR_FAKE_PARTITION_PROPERTY_CODE,
1032 &uPropValue);
1033 *g_ppfnVidNtDeviceIoControlFile = pfnOrg;
1034 AssertReturn( fRet
1035 && uPropValue == NEM_WIN_IOCTL_DETECTOR_FAKE_PARTITION_PROPERTY_VALUE
1036 && g_IoCtlGetHvPartitionId.uFunction != 0,
1037 RTErrInfoSetF(pErrInfo, VERR_NEM_INIT_FAILED,
1038 "Problem figuring out VidGetPartitionProperty: fRet=%u uPropValue=%#x dwErr=%u",
1039 fRet, uPropValue, GetLastError()) );
1040 LogRel(("NEM: VidGetPartitionProperty -> fun:%#x in:%#x out:%#x\n",
1041 g_IoCtlGetPartitionProperty.uFunction, g_IoCtlGetPartitionProperty.cbInput, g_IoCtlGetPartitionProperty.cbOutput));
1042 }
1043
1044 /* VidStartVirtualProcessor */
1045 *g_ppfnVidNtDeviceIoControlFile = nemR3WinIoctlDetector_StartVirtualProcessor;
1046 fRet = g_pfnVidStartVirtualProcessor(NEM_WIN_IOCTL_DETECTOR_FAKE_HANDLE, NEM_WIN_IOCTL_DETECTOR_FAKE_VP_INDEX);
1047 *g_ppfnVidNtDeviceIoControlFile = pfnOrg;
1048 AssertStmt(fRet && g_IoCtlStartVirtualProcessor.uFunction != 0,
1049 RTERRINFO_LOG_REL_SET_F(pErrInfo, VERR_NEM_RING3_ONLY,
1050 "Problem figuring out VidStartVirtualProcessor: fRet=%u dwErr=%u", fRet, GetLastError()) );
1051 LogRel(("NEM: VidStartVirtualProcessor -> fun:%#x in:%#x out:%#x\n", g_IoCtlStartVirtualProcessor.uFunction,
1052 g_IoCtlStartVirtualProcessor.cbInput, g_IoCtlStartVirtualProcessor.cbOutput));
1053
1054 /* VidStopVirtualProcessor */
1055 *g_ppfnVidNtDeviceIoControlFile = nemR3WinIoctlDetector_StopVirtualProcessor;
1056 fRet = g_pfnVidStopVirtualProcessor(NEM_WIN_IOCTL_DETECTOR_FAKE_HANDLE, NEM_WIN_IOCTL_DETECTOR_FAKE_VP_INDEX);
1057 *g_ppfnVidNtDeviceIoControlFile = pfnOrg;
1058 AssertStmt(fRet && g_IoCtlStopVirtualProcessor.uFunction != 0,
1059 RTERRINFO_LOG_REL_SET_F(pErrInfo, VERR_NEM_RING3_ONLY,
1060 "Problem figuring out VidStopVirtualProcessor: fRet=%u dwErr=%u", fRet, GetLastError()) );
1061 LogRel(("NEM: VidStopVirtualProcessor -> fun:%#x in:%#x out:%#x\n", g_IoCtlStopVirtualProcessor.uFunction,
1062 g_IoCtlStopVirtualProcessor.cbInput, g_IoCtlStopVirtualProcessor.cbOutput));
1063
1064 /* VidMessageSlotHandleAndGetNext */
1065 *g_ppfnVidNtDeviceIoControlFile = nemR3WinIoctlDetector_MessageSlotHandleAndGetNext;
1066 fRet = g_pfnVidMessageSlotHandleAndGetNext(NEM_WIN_IOCTL_DETECTOR_FAKE_HANDLE,
1067 NEM_WIN_IOCTL_DETECTOR_FAKE_VP_INDEX, VID_MSHAGN_F_HANDLE_MESSAGE,
1068 NEM_WIN_IOCTL_DETECTOR_FAKE_TIMEOUT);
1069 *g_ppfnVidNtDeviceIoControlFile = pfnOrg;
1070 AssertStmt(fRet && g_IoCtlMessageSlotHandleAndGetNext.uFunction != 0,
1071 RTERRINFO_LOG_REL_SET_F(pErrInfo, VERR_NEM_RING3_ONLY,
1072 "Problem figuring out VidMessageSlotHandleAndGetNext: fRet=%u dwErr=%u",
1073 fRet, GetLastError()) );
1074 LogRel(("NEM: VidMessageSlotHandleAndGetNext -> fun:%#x in:%#x out:%#x\n",
1075 g_IoCtlMessageSlotHandleAndGetNext.uFunction, g_IoCtlMessageSlotHandleAndGetNext.cbInput,
1076 g_IoCtlMessageSlotHandleAndGetNext.cbOutput));
1077
1078 /* The following are only for logging: */
1079 union
1080 {
1081 VID_MAPPED_MESSAGE_SLOT MapSlot;
1082 HV_REGISTER_NAME Name;
1083 HV_REGISTER_VALUE Value;
1084 } uBuf;
1085
1086 /* VidMessageSlotMap */
1087 g_pIoCtlDetectForLogging = &g_IoCtlMessageSlotMap;
1088 *g_ppfnVidNtDeviceIoControlFile = nemR3WinIoctlDetector_ForLogging;
1089 fRet = g_pfnVidMessageSlotMap(NEM_WIN_IOCTL_DETECTOR_FAKE_HANDLE, &uBuf.MapSlot, NEM_WIN_IOCTL_DETECTOR_FAKE_VP_INDEX);
1090 *g_ppfnVidNtDeviceIoControlFile = pfnOrg;
1091 Assert(fRet);
1092 LogRel(("NEM: VidMessageSlotMap -> fun:%#x in:%#x out:%#x\n", g_pIoCtlDetectForLogging->uFunction,
1093 g_pIoCtlDetectForLogging->cbInput, g_pIoCtlDetectForLogging->cbOutput));
1094
1095 /* VidGetVirtualProcessorState */
1096 uBuf.Name = HvRegisterExplicitSuspend;
1097 g_pIoCtlDetectForLogging = &g_IoCtlGetVirtualProcessorState;
1098 *g_ppfnVidNtDeviceIoControlFile = nemR3WinIoctlDetector_ForLogging;
1099 fRet = g_pfnVidGetVirtualProcessorState(NEM_WIN_IOCTL_DETECTOR_FAKE_HANDLE, NEM_WIN_IOCTL_DETECTOR_FAKE_VP_INDEX,
1100 &uBuf.Name, 1, &uBuf.Value);
1101 *g_ppfnVidNtDeviceIoControlFile = pfnOrg;
1102 Assert(fRet);
1103 LogRel(("NEM: VidGetVirtualProcessorState -> fun:%#x in:%#x out:%#x\n", g_pIoCtlDetectForLogging->uFunction,
1104 g_pIoCtlDetectForLogging->cbInput, g_pIoCtlDetectForLogging->cbOutput));
1105
1106 /* VidSetVirtualProcessorState */
1107 uBuf.Name = HvRegisterExplicitSuspend;
1108 g_pIoCtlDetectForLogging = &g_IoCtlSetVirtualProcessorState;
1109 *g_ppfnVidNtDeviceIoControlFile = nemR3WinIoctlDetector_ForLogging;
1110 fRet = g_pfnVidSetVirtualProcessorState(NEM_WIN_IOCTL_DETECTOR_FAKE_HANDLE, NEM_WIN_IOCTL_DETECTOR_FAKE_VP_INDEX,
1111 &uBuf.Name, 1, &uBuf.Value);
1112 *g_ppfnVidNtDeviceIoControlFile = pfnOrg;
1113 Assert(fRet);
1114 LogRel(("NEM: VidSetVirtualProcessorState -> fun:%#x in:%#x out:%#x\n", g_pIoCtlDetectForLogging->uFunction,
1115 g_pIoCtlDetectForLogging->cbInput, g_pIoCtlDetectForLogging->cbOutput));
1116
1117 g_pIoCtlDetectForLogging = NULL;
1118#endif /* LOG_ENABLED */
1119
1120 return VINF_SUCCESS;
1121}
1122
1123
1124/**
1125 * Creates and sets up a Hyper-V (exo) partition.
1126 *
1127 * @returns VBox status code.
1128 * @param pVM The cross context VM structure.
1129 * @param pErrInfo Where to always return error info.
1130 */
1131static int nemR3WinInitCreatePartition(PVM pVM, PRTERRINFO pErrInfo)
1132{
1133 AssertReturn(!pVM->nem.s.hPartition, RTErrInfoSet(pErrInfo, VERR_WRONG_ORDER, "Wrong initalization order"));
1134 AssertReturn(!pVM->nem.s.hPartitionDevice, RTErrInfoSet(pErrInfo, VERR_WRONG_ORDER, "Wrong initalization order"));
1135
1136 /*
1137 * Create the partition.
1138 */
1139 WHV_PARTITION_HANDLE hPartition;
1140 HRESULT hrc = WHvCreatePartition(&hPartition);
1141 if (FAILED(hrc))
1142 return RTErrInfoSetF(pErrInfo, VERR_NEM_VM_CREATE_FAILED, "WHvCreatePartition failed with %Rhrc (Last=%#x/%u)",
1143 hrc, RTNtLastStatusValue(), RTNtLastErrorValue());
1144
1145 int rc;
1146
1147 /*
1148 * Set partition properties, most importantly the CPU count.
1149 */
1150 /**
1151 * @todo Someone at Microsoft please explain another weird API:
1152 * - Why this API doesn't take the WHV_PARTITION_PROPERTY_CODE value as an
1153 * argument rather than as part of the struct. That is so weird if you've
1154 * used any other NT or windows API, including WHvGetCapability().
1155 * - Why use PVOID when WHV_PARTITION_PROPERTY is what's expected. We
1156 * technically only need 9 bytes for setting/getting
1157 * WHVPartitionPropertyCodeProcessorClFlushSize, but the API insists on 16. */
1158 WHV_PARTITION_PROPERTY Property;
1159 RT_ZERO(Property);
1160 Property.ProcessorCount = pVM->cCpus;
1161 hrc = WHvSetPartitionProperty(hPartition, WHvPartitionPropertyCodeProcessorCount, &Property, sizeof(Property));
1162 if (SUCCEEDED(hrc))
1163 {
1164 RT_ZERO(Property);
1165 Property.ExtendedVmExits.X64CpuidExit = pVM->nem.s.fExtendedCpuIdExit; /** @todo Register fixed results and restrict cpuid exits */
1166 Property.ExtendedVmExits.X64MsrExit = pVM->nem.s.fExtendedMsrExit;
1167 Property.ExtendedVmExits.ExceptionExit = pVM->nem.s.fExtendedXcptExit;
1168 hrc = WHvSetPartitionProperty(hPartition, WHvPartitionPropertyCodeExtendedVmExits, &Property, sizeof(Property));
1169 if (SUCCEEDED(hrc))
1170 {
1171 /*
1172 * We'll continue setup in nemR3NativeInitAfterCPUM.
1173 */
1174 pVM->nem.s.fCreatedEmts = false;
1175 pVM->nem.s.hPartition = hPartition;
1176 LogRel(("NEM: Created partition %p.\n", hPartition));
1177 return VINF_SUCCESS;
1178 }
1179
1180 rc = RTErrInfoSetF(pErrInfo, VERR_NEM_VM_CREATE_FAILED,
1181 "Failed setting WHvPartitionPropertyCodeExtendedVmExits to %'#RX64: %Rhrc",
1182 Property.ExtendedVmExits.AsUINT64, hrc);
1183 }
1184 else
1185 rc = RTErrInfoSetF(pErrInfo, VERR_NEM_VM_CREATE_FAILED,
1186 "Failed setting WHvPartitionPropertyCodeProcessorCount to %u: %Rhrc (Last=%#x/%u)",
1187 pVM->cCpus, hrc, RTNtLastStatusValue(), RTNtLastErrorValue());
1188 WHvDeletePartition(hPartition);
1189
1190 Assert(!pVM->nem.s.hPartitionDevice);
1191 Assert(!pVM->nem.s.hPartition);
1192 return rc;
1193}
1194
1195
1196/**
1197 * Makes sure APIC and firmware will not allow X2APIC mode.
1198 *
1199 * This is rather ugly.
1200 *
1201 * @returns VBox status code
1202 * @param pVM The cross context VM structure.
1203 */
1204static int nemR3WinDisableX2Apic(PVM pVM)
1205{
1206 /*
1207 * First make sure the 'Mode' config value of the APIC isn't set to X2APIC.
1208 * This defaults to APIC, so no need to change unless it's X2APIC.
1209 */
1210 PCFGMNODE pCfg = CFGMR3GetChild(CFGMR3GetRoot(pVM), "/Devices/apic/0/Config");
1211 if (pCfg)
1212 {
1213 uint8_t bMode = 0;
1214 int rc = CFGMR3QueryU8(pCfg, "Mode", &bMode);
1215 AssertLogRelMsgReturn(RT_SUCCESS(rc) || rc == VERR_CFGM_VALUE_NOT_FOUND, ("%Rrc\n", rc), rc);
1216 if (RT_SUCCESS(rc) && bMode == PDMAPICMODE_X2APIC)
1217 {
1218 LogRel(("NEM: Adjusting APIC configuration from X2APIC to APIC max mode. X2APIC is not supported by the WinHvPlatform API!\n"));
1219 LogRel(("NEM: Disable Hyper-V if you need X2APIC for your guests!\n"));
1220 rc = CFGMR3RemoveValue(pCfg, "Mode");
1221 rc = CFGMR3InsertInteger(pCfg, "Mode", PDMAPICMODE_APIC);
1222 AssertLogRelRCReturn(rc, rc);
1223 }
1224 }
1225
1226 /*
1227 * Now the firmwares.
1228 * These also defaults to APIC and only needs adjusting if configured to X2APIC (2).
1229 */
1230 static const char * const s_apszFirmwareConfigs[] =
1231 {
1232 "/Devices/efi/0/Config",
1233 "/Devices/pcbios/0/Config",
1234 };
1235 for (unsigned i = 0; i < RT_ELEMENTS(s_apszFirmwareConfigs); i++)
1236 {
1237 pCfg = CFGMR3GetChild(CFGMR3GetRoot(pVM), "/Devices/APIC/0/Config");
1238 if (pCfg)
1239 {
1240 uint8_t bMode = 0;
1241 int rc = CFGMR3QueryU8(pCfg, "APIC", &bMode);
1242 AssertLogRelMsgReturn(RT_SUCCESS(rc) || rc == VERR_CFGM_VALUE_NOT_FOUND, ("%Rrc\n", rc), rc);
1243 if (RT_SUCCESS(rc) && bMode == 2)
1244 {
1245 LogRel(("NEM: Adjusting %s/Mode from 2 (X2APIC) to 1 (APIC).\n", s_apszFirmwareConfigs[i]));
1246 rc = CFGMR3RemoveValue(pCfg, "APIC");
1247 rc = CFGMR3InsertInteger(pCfg, "APIC", 1);
1248 AssertLogRelRCReturn(rc, rc);
1249 }
1250 }
1251 }
1252
1253 return VINF_SUCCESS;
1254}
1255
1256
1257/**
1258 * Try initialize the native API.
1259 *
1260 * This may only do part of the job, more can be done in
1261 * nemR3NativeInitAfterCPUM() and nemR3NativeInitCompleted().
1262 *
1263 * @returns VBox status code.
1264 * @param pVM The cross context VM structure.
1265 * @param fFallback Whether we're in fallback mode or use-NEM mode. In
1266 * the latter we'll fail if we cannot initialize.
1267 * @param fForced Whether the HMForced flag is set and we should
1268 * fail if we cannot initialize.
1269 */
1270int nemR3NativeInit(PVM pVM, bool fFallback, bool fForced)
1271{
1272 g_uBuildNo = RTSystemGetNtBuildNo();
1273
1274 /*
1275 * Some state init.
1276 */
1277#ifdef NEM_WIN_WITH_A20
1278 pVM->nem.s.fA20Enabled = true;
1279#endif
1280#if 0
1281 for (VMCPUID idCpu = 0; idCpu < pVM->cCpus; idCpu++)
1282 {
1283 PNEMCPU pNemCpu = &pVM->apCpusR3[idCpu]->nem.s;
1284 }
1285#endif
1286
1287 /*
1288 * Error state.
1289 * The error message will be non-empty on failure and 'rc' will be set too.
1290 */
1291 RTERRINFOSTATIC ErrInfo;
1292 PRTERRINFO pErrInfo = RTErrInfoInitStatic(&ErrInfo);
1293 int rc = nemR3WinInitProbeAndLoad(fForced, pErrInfo);
1294 if (RT_SUCCESS(rc))
1295 {
1296 /*
1297 * Check the capabilties of the hypervisor, starting with whether it's present.
1298 */
1299 rc = nemR3WinInitCheckCapabilities(pVM, pErrInfo);
1300 if (RT_SUCCESS(rc))
1301 {
1302 /*
1303 * Discover the VID I/O control function numbers we need (for interception
1304 * only these days).
1305 */
1306 rc = nemR3WinInitDiscoverIoControlProperties(pVM, pErrInfo);
1307 if (RT_SUCCESS(rc))
1308 {
1309 /*
1310 * Create and initialize a partition.
1311 */
1312 rc = nemR3WinInitCreatePartition(pVM, pErrInfo);
1313 if (RT_SUCCESS(rc))
1314 {
1315 /*
1316 * Set ourselves as the execution engine and make config adjustments.
1317 */
1318 VM_SET_MAIN_EXECUTION_ENGINE(pVM, VM_EXEC_ENGINE_NATIVE_API);
1319 Log(("NEM: Marked active!\n"));
1320 nemR3WinDisableX2Apic(pVM);
1321 PGMR3EnableNemMode(pVM);
1322
1323 /*
1324 * Register release statistics
1325 */
1326 STAMR3Register(pVM, (void *)&pVM->nem.s.cMappedPages, STAMTYPE_U32, STAMVISIBILITY_ALWAYS,
1327 "/NEM/PagesCurrentlyMapped", STAMUNIT_PAGES, "Number guest pages currently mapped by the VM");
1328 STAMR3Register(pVM, (void *)&pVM->nem.s.StatMapPage, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS,
1329 "/NEM/PagesMapCalls", STAMUNIT_PAGES, "Calls to WHvMapGpaRange/HvCallMapGpaPages");
1330 STAMR3Register(pVM, (void *)&pVM->nem.s.StatMapPageFailed, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS,
1331 "/NEM/PagesMapFails", STAMUNIT_PAGES, "Calls to WHvMapGpaRange/HvCallMapGpaPages that failed");
1332 STAMR3Register(pVM, (void *)&pVM->nem.s.StatUnmapPage, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS,
1333 "/NEM/PagesUnmapCalls", STAMUNIT_PAGES, "Calls to WHvUnmapGpaRange/HvCallUnmapGpaPages");
1334 STAMR3Register(pVM, (void *)&pVM->nem.s.StatUnmapPageFailed, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS,
1335 "/NEM/PagesUnmapFails", STAMUNIT_PAGES, "Calls to WHvUnmapGpaRange/HvCallUnmapGpaPages that failed");
1336 STAMR3Register(pVM, &pVM->nem.s.StatProfMapGpaRange, STAMTYPE_PROFILE, STAMVISIBILITY_ALWAYS,
1337 "/NEM/PagesMapGpaRange", STAMUNIT_TICKS_PER_CALL, "Profiling calls to WHvMapGpaRange for bigger stuff");
1338 STAMR3Register(pVM, &pVM->nem.s.StatProfUnmapGpaRange, STAMTYPE_PROFILE, STAMVISIBILITY_ALWAYS,
1339 "/NEM/PagesUnmapGpaRange", STAMUNIT_TICKS_PER_CALL, "Profiling calls to WHvUnmapGpaRange for bigger stuff");
1340 STAMR3Register(pVM, &pVM->nem.s.StatProfMapGpaRangePage, STAMTYPE_PROFILE, STAMVISIBILITY_ALWAYS,
1341 "/NEM/PagesMapGpaRangePage", STAMUNIT_TICKS_PER_CALL, "Profiling calls to WHvMapGpaRange for single pages");
1342 STAMR3Register(pVM, &pVM->nem.s.StatProfUnmapGpaRangePage, STAMTYPE_PROFILE, STAMVISIBILITY_ALWAYS,
1343 "/NEM/PagesUnmapGpaRangePage", STAMUNIT_TICKS_PER_CALL, "Profiling calls to WHvUnmapGpaRange for single pages");
1344
1345 for (VMCPUID idCpu = 0; idCpu < pVM->cCpus; idCpu++)
1346 {
1347 PNEMCPU pNemCpu = &pVM->apCpusR3[idCpu]->nem.s;
1348 STAMR3RegisterF(pVM, &pNemCpu->StatExitPortIo, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of port I/O exits", "/NEM/CPU%u/ExitPortIo", idCpu);
1349 STAMR3RegisterF(pVM, &pNemCpu->StatExitMemUnmapped, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of unmapped memory exits", "/NEM/CPU%u/ExitMemUnmapped", idCpu);
1350 STAMR3RegisterF(pVM, &pNemCpu->StatExitMemIntercept, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of intercepted memory exits", "/NEM/CPU%u/ExitMemIntercept", idCpu);
1351 STAMR3RegisterF(pVM, &pNemCpu->StatExitHalt, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of HLT exits", "/NEM/CPU%u/ExitHalt", idCpu);
1352 STAMR3RegisterF(pVM, &pNemCpu->StatExitInterruptWindow, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of interrupt window exits", "/NEM/CPU%u/ExitInterruptWindow", idCpu);
1353 STAMR3RegisterF(pVM, &pNemCpu->StatExitCpuId, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of CPUID exits", "/NEM/CPU%u/ExitCpuId", idCpu);
1354 STAMR3RegisterF(pVM, &pNemCpu->StatExitMsr, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of MSR access exits", "/NEM/CPU%u/ExitMsr", idCpu);
1355 STAMR3RegisterF(pVM, &pNemCpu->StatExitException, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of exception exits", "/NEM/CPU%u/ExitException", idCpu);
1356 STAMR3RegisterF(pVM, &pNemCpu->StatExitExceptionBp, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of #BP exits", "/NEM/CPU%u/ExitExceptionBp", idCpu);
1357 STAMR3RegisterF(pVM, &pNemCpu->StatExitExceptionDb, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of #DB exits", "/NEM/CPU%u/ExitExceptionDb", idCpu);
1358 STAMR3RegisterF(pVM, &pNemCpu->StatExitExceptionGp, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of #GP exits", "/NEM/CPU%u/ExitExceptionGp", idCpu);
1359 STAMR3RegisterF(pVM, &pNemCpu->StatExitExceptionGpMesa, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of #GP exits from mesa driver", "/NEM/CPU%u/ExitExceptionGpMesa", idCpu);
1360 STAMR3RegisterF(pVM, &pNemCpu->StatExitExceptionUd, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of #UD exits", "/NEM/CPU%u/ExitExceptionUd", idCpu);
1361 STAMR3RegisterF(pVM, &pNemCpu->StatExitExceptionUdHandled, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of handled #UD exits", "/NEM/CPU%u/ExitExceptionUdHandled", idCpu);
1362 STAMR3RegisterF(pVM, &pNemCpu->StatExitUnrecoverable, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of unrecoverable exits", "/NEM/CPU%u/ExitUnrecoverable", idCpu);
1363 STAMR3RegisterF(pVM, &pNemCpu->StatGetMsgTimeout, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of get message timeouts/alerts", "/NEM/CPU%u/GetMsgTimeout", idCpu);
1364 STAMR3RegisterF(pVM, &pNemCpu->StatStopCpuSuccess, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of successful CPU stops", "/NEM/CPU%u/StopCpuSuccess", idCpu);
1365 STAMR3RegisterF(pVM, &pNemCpu->StatStopCpuPending, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of pending CPU stops", "/NEM/CPU%u/StopCpuPending", idCpu);
1366 STAMR3RegisterF(pVM, &pNemCpu->StatStopCpuPendingAlerts,STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of pending CPU stop alerts", "/NEM/CPU%u/StopCpuPendingAlerts", idCpu);
1367 STAMR3RegisterF(pVM, &pNemCpu->StatStopCpuPendingOdd, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of odd pending CPU stops (see code)", "/NEM/CPU%u/StopCpuPendingOdd", idCpu);
1368 STAMR3RegisterF(pVM, &pNemCpu->StatCancelChangedState, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of cancel changed state", "/NEM/CPU%u/CancelChangedState", idCpu);
1369 STAMR3RegisterF(pVM, &pNemCpu->StatCancelAlertedThread, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of cancel alerted EMT", "/NEM/CPU%u/CancelAlertedEMT", idCpu);
1370 STAMR3RegisterF(pVM, &pNemCpu->StatBreakOnFFPre, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of pre execution FF breaks", "/NEM/CPU%u/BreakOnFFPre", idCpu);
1371 STAMR3RegisterF(pVM, &pNemCpu->StatBreakOnFFPost, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of post execution FF breaks", "/NEM/CPU%u/BreakOnFFPost", idCpu);
1372 STAMR3RegisterF(pVM, &pNemCpu->StatBreakOnCancel, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of cancel execution breaks", "/NEM/CPU%u/BreakOnCancel", idCpu);
1373 STAMR3RegisterF(pVM, &pNemCpu->StatBreakOnStatus, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of status code breaks", "/NEM/CPU%u/BreakOnStatus", idCpu);
1374 STAMR3RegisterF(pVM, &pNemCpu->StatImportOnDemand, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of on-demand state imports", "/NEM/CPU%u/ImportOnDemand", idCpu);
1375 STAMR3RegisterF(pVM, &pNemCpu->StatImportOnReturn, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of state imports on loop return", "/NEM/CPU%u/ImportOnReturn", idCpu);
1376 STAMR3RegisterF(pVM, &pNemCpu->StatImportOnReturnSkipped, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of skipped state imports on loop return", "/NEM/CPU%u/ImportOnReturnSkipped", idCpu);
1377 STAMR3RegisterF(pVM, &pNemCpu->StatQueryCpuTick, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, "Number of TSC queries", "/NEM/CPU%u/QueryCpuTick", idCpu);
1378 }
1379
1380 if (!SUPR3IsDriverless())
1381 {
1382 PUVM pUVM = pVM->pUVM;
1383 STAMR3RegisterRefresh(pUVM, &pVM->nem.s.R0Stats.cPagesAvailable, STAMTYPE_U64, STAMVISIBILITY_ALWAYS,
1384 STAMUNIT_PAGES, STAM_REFRESH_GRP_NEM, "Free pages available to the hypervisor",
1385 "/NEM/R0Stats/cPagesAvailable");
1386 STAMR3RegisterRefresh(pUVM, &pVM->nem.s.R0Stats.cPagesInUse, STAMTYPE_U64, STAMVISIBILITY_ALWAYS,
1387 STAMUNIT_PAGES, STAM_REFRESH_GRP_NEM, "Pages in use by hypervisor",
1388 "/NEM/R0Stats/cPagesInUse");
1389 }
1390
1391 }
1392 }
1393 }
1394 }
1395
1396 /*
1397 * We only fail if in forced mode, otherwise just log the complaint and return.
1398 */
1399 Assert(pVM->bMainExecutionEngine == VM_EXEC_ENGINE_NATIVE_API || RTErrInfoIsSet(pErrInfo));
1400 if ( (fForced || !fFallback)
1401 && pVM->bMainExecutionEngine != VM_EXEC_ENGINE_NATIVE_API)
1402 return VMSetError(pVM, RT_SUCCESS_NP(rc) ? VERR_NEM_NOT_AVAILABLE : rc, RT_SRC_POS, "%s", pErrInfo->pszMsg);
1403
1404 if (RTErrInfoIsSet(pErrInfo))
1405 LogRel(("NEM: Not available: %s\n", pErrInfo->pszMsg));
1406 return VINF_SUCCESS;
1407}
1408
1409
1410/**
1411 * This is called after CPUMR3Init is done.
1412 *
1413 * @returns VBox status code.
1414 * @param pVM The VM handle..
1415 */
1416int nemR3NativeInitAfterCPUM(PVM pVM)
1417{
1418 /*
1419 * Validate sanity.
1420 */
1421 WHV_PARTITION_HANDLE hPartition = pVM->nem.s.hPartition;
1422 AssertReturn(hPartition != NULL, VERR_WRONG_ORDER);
1423 AssertReturn(!pVM->nem.s.hPartitionDevice, VERR_WRONG_ORDER);
1424 AssertReturn(!pVM->nem.s.fCreatedEmts, VERR_WRONG_ORDER);
1425 AssertReturn(pVM->bMainExecutionEngine == VM_EXEC_ENGINE_NATIVE_API, VERR_WRONG_ORDER);
1426
1427 /*
1428 * Continue setting up the partition now that we've got most of the CPUID feature stuff.
1429 */
1430 WHV_PARTITION_PROPERTY Property;
1431 HRESULT hrc;
1432
1433#if 0
1434 /* Not sure if we really need to set the vendor.
1435 Update: Apparently we don't. WHvPartitionPropertyCodeProcessorVendor was removed in 17110. */
1436 RT_ZERO(Property);
1437 Property.ProcessorVendor = pVM->nem.s.enmCpuVendor == CPUMCPUVENDOR_AMD ? WHvProcessorVendorAmd
1438 : WHvProcessorVendorIntel;
1439 hrc = WHvSetPartitionProperty(hPartition, WHvPartitionPropertyCodeProcessorVendor, &Property, sizeof(Property));
1440 if (FAILED(hrc))
1441 return VMSetError(pVM, VERR_NEM_VM_CREATE_FAILED, RT_SRC_POS,
1442 "Failed to set WHvPartitionPropertyCodeProcessorVendor to %u: %Rhrc (Last=%#x/%u)",
1443 Property.ProcessorVendor, hrc, RTNtLastStatusValue(), RTNtLastErrorValue());
1444#endif
1445
1446 /* Not sure if we really need to set the cache line flush size. */
1447 RT_ZERO(Property);
1448 Property.ProcessorClFlushSize = pVM->nem.s.cCacheLineFlushShift;
1449 hrc = WHvSetPartitionProperty(hPartition, WHvPartitionPropertyCodeProcessorClFlushSize, &Property, sizeof(Property));
1450 if (FAILED(hrc))
1451 return VMSetError(pVM, VERR_NEM_VM_CREATE_FAILED, RT_SRC_POS,
1452 "Failed to set WHvPartitionPropertyCodeProcessorClFlushSize to %u: %Rhrc (Last=%#x/%u)",
1453 pVM->nem.s.cCacheLineFlushShift, hrc, RTNtLastStatusValue(), RTNtLastErrorValue());
1454
1455 /* Intercept #DB, #BP and #UD exceptions. */
1456 RT_ZERO(Property);
1457 Property.ExceptionExitBitmap = RT_BIT_64(WHvX64ExceptionTypeDebugTrapOrFault)
1458 | RT_BIT_64(WHvX64ExceptionTypeBreakpointTrap)
1459 | RT_BIT_64(WHvX64ExceptionTypeInvalidOpcodeFault);
1460
1461 /* Intercept #GP to workaround the buggy mesa vmwgfx driver. */
1462 PVMCPU pVCpu = pVM->apCpusR3[0]; /** @todo In theory per vCPU, in practice same for all. */
1463 if (pVCpu->nem.s.fTrapXcptGpForLovelyMesaDrv)
1464 Property.ExceptionExitBitmap |= RT_BIT_64(WHvX64ExceptionTypeGeneralProtectionFault);
1465
1466 hrc = WHvSetPartitionProperty(hPartition, WHvPartitionPropertyCodeExceptionExitBitmap, &Property, sizeof(Property));
1467 if (FAILED(hrc))
1468 return VMSetError(pVM, VERR_NEM_VM_CREATE_FAILED, RT_SRC_POS,
1469 "Failed to set WHvPartitionPropertyCodeExceptionExitBitmap to %#RX64: %Rhrc (Last=%#x/%u)",
1470 Property.ExceptionExitBitmap, hrc, RTNtLastStatusValue(), RTNtLastErrorValue());
1471
1472
1473 /*
1474 * Sync CPU features with CPUM.
1475 */
1476 /** @todo sync CPU features with CPUM. */
1477
1478 /* Set the partition property. */
1479 RT_ZERO(Property);
1480 Property.ProcessorFeatures.AsUINT64 = pVM->nem.s.uCpuFeatures.u64;
1481 hrc = WHvSetPartitionProperty(hPartition, WHvPartitionPropertyCodeProcessorFeatures, &Property, sizeof(Property));
1482 if (FAILED(hrc))
1483 return VMSetError(pVM, VERR_NEM_VM_CREATE_FAILED, RT_SRC_POS,
1484 "Failed to set WHvPartitionPropertyCodeProcessorFeatures to %'#RX64: %Rhrc (Last=%#x/%u)",
1485 pVM->nem.s.uCpuFeatures.u64, hrc, RTNtLastStatusValue(), RTNtLastErrorValue());
1486
1487 /*
1488 * Set up the partition.
1489 *
1490 * Seems like this is where the partition is actually instantiated and we get
1491 * a handle to it.
1492 */
1493 hrc = WHvSetupPartition(hPartition);
1494 if (FAILED(hrc))
1495 return VMSetError(pVM, VERR_NEM_VM_CREATE_FAILED, RT_SRC_POS,
1496 "Call to WHvSetupPartition failed: %Rhrc (Last=%#x/%u)",
1497 hrc, RTNtLastStatusValue(), RTNtLastErrorValue());
1498
1499 /*
1500 * Hysterical raisins: Get the handle (could also fish this out via VID.DLL NtDeviceIoControlFile intercepting).
1501 */
1502 HANDLE hPartitionDevice;
1503 __try
1504 {
1505 hPartitionDevice = ((HANDLE *)hPartition)[1];
1506 if (!hPartitionDevice)
1507 hPartitionDevice = INVALID_HANDLE_VALUE;
1508 }
1509 __except(EXCEPTION_EXECUTE_HANDLER)
1510 {
1511 hrc = GetExceptionCode();
1512 hPartitionDevice = INVALID_HANDLE_VALUE;
1513 }
1514
1515 /* Test the handle. */
1516 HV_PARTITION_PROPERTY uValue = 0;
1517 if ( g_pfnVidGetPartitionProperty
1518 && hPartitionDevice != INVALID_HANDLE_VALUE
1519 && !g_pfnVidGetPartitionProperty(hPartitionDevice, HvPartitionPropertyProcessorVendor, &uValue))
1520 hPartitionDevice = INVALID_HANDLE_VALUE;
1521 LogRel(("NEM: HvPartitionPropertyProcessorVendor=%#llx (%lld)\n", uValue, uValue));
1522
1523 /*
1524 * More hysterical rasins: Get the partition ID if we can.
1525 */
1526 HV_PARTITION_ID idHvPartition = HV_PARTITION_ID_INVALID;
1527 if ( g_pfnVidGetHvPartitionId
1528 && hPartitionDevice != INVALID_HANDLE_VALUE
1529 && !g_pfnVidGetHvPartitionId(hPartitionDevice, &idHvPartition))
1530 {
1531 idHvPartition = HV_PARTITION_ID_INVALID;
1532 Log(("NEM: VidGetHvPartitionId failed: %#x\n", GetLastError()));
1533 }
1534 pVM->nem.s.hPartitionDevice = hPartitionDevice;
1535
1536 /*
1537 * Setup the EMTs.
1538 */
1539 for (VMCPUID idCpu = 0; idCpu < pVM->cCpus; idCpu++)
1540 {
1541 pVCpu = pVM->apCpusR3[idCpu];
1542
1543 hrc = WHvCreateVirtualProcessor(hPartition, idCpu, 0 /*fFlags*/);
1544 if (FAILED(hrc))
1545 {
1546 NTSTATUS const rcNtLast = RTNtLastStatusValue();
1547 DWORD const dwErrLast = RTNtLastErrorValue();
1548 while (idCpu-- > 0)
1549 {
1550 HRESULT hrc2 = WHvDeleteVirtualProcessor(hPartition, idCpu);
1551 AssertLogRelMsg(SUCCEEDED(hrc2), ("WHvDeleteVirtualProcessor(%p, %u) -> %Rhrc (Last=%#x/%u)\n",
1552 hPartition, idCpu, hrc2, RTNtLastStatusValue(),
1553 RTNtLastErrorValue()));
1554 }
1555 return VMSetError(pVM, VERR_NEM_VM_CREATE_FAILED, RT_SRC_POS,
1556 "Call to WHvCreateVirtualProcessor failed: %Rhrc (Last=%#x/%u)", hrc, rcNtLast, dwErrLast);
1557 }
1558 }
1559 pVM->nem.s.fCreatedEmts = true;
1560
1561 LogRel(("NEM: Successfully set up partition (device handle %p, partition ID %#llx)\n", hPartitionDevice, idHvPartition));
1562
1563 /*
1564 * Any hyper-v statistics we can get at now? HvCallMapStatsPage isn't accessible any more.
1565 */
1566 /** @todo stats */
1567
1568 /*
1569 * Adjust features.
1570 * Note! We've already disabled X2APIC via CFGM during the first init call.
1571 */
1572 return VINF_SUCCESS;
1573}
1574
1575
1576int nemR3NativeInitCompleted(PVM pVM, VMINITCOMPLETED enmWhat)
1577{
1578 //BOOL fRet = SetThreadPriority(GetCurrentThread(), 0);
1579 //AssertLogRel(fRet);
1580
1581 NOREF(pVM); NOREF(enmWhat);
1582 return VINF_SUCCESS;
1583}
1584
1585
1586int nemR3NativeTerm(PVM pVM)
1587{
1588 /*
1589 * Delete the partition.
1590 */
1591 WHV_PARTITION_HANDLE hPartition = pVM->nem.s.hPartition;
1592 pVM->nem.s.hPartition = NULL;
1593 pVM->nem.s.hPartitionDevice = NULL;
1594 if (hPartition != NULL)
1595 {
1596 VMCPUID idCpu = pVM->nem.s.fCreatedEmts ? pVM->cCpus : 0;
1597 LogRel(("NEM: Destroying partition %p with its %u VCpus...\n", hPartition, idCpu));
1598 while (idCpu-- > 0)
1599 {
1600 PVMCPU pVCpu = pVM->apCpusR3[idCpu];
1601 pVCpu->nem.s.pvMsgSlotMapping = NULL;
1602 HRESULT hrc = WHvDeleteVirtualProcessor(hPartition, idCpu);
1603 AssertLogRelMsg(SUCCEEDED(hrc), ("WHvDeleteVirtualProcessor(%p, %u) -> %Rhrc (Last=%#x/%u)\n",
1604 hPartition, idCpu, hrc, RTNtLastStatusValue(),
1605 RTNtLastErrorValue()));
1606 }
1607 WHvDeletePartition(hPartition);
1608 }
1609 pVM->nem.s.fCreatedEmts = false;
1610 return VINF_SUCCESS;
1611}
1612
1613
1614/**
1615 * VM reset notification.
1616 *
1617 * @param pVM The cross context VM structure.
1618 */
1619void nemR3NativeReset(PVM pVM)
1620{
1621#if 0
1622 /* Unfix the A20 gate. */
1623 pVM->nem.s.fA20Fixed = false;
1624#else
1625 RT_NOREF(pVM);
1626#endif
1627}
1628
1629
1630/**
1631 * Reset CPU due to INIT IPI or hot (un)plugging.
1632 *
1633 * @param pVCpu The cross context virtual CPU structure of the CPU being
1634 * reset.
1635 * @param fInitIpi Whether this is the INIT IPI or hot (un)plugging case.
1636 */
1637void nemR3NativeResetCpu(PVMCPU pVCpu, bool fInitIpi)
1638{
1639#ifdef NEM_WIN_WITH_A20
1640 /* Lock the A20 gate if INIT IPI, make sure it's enabled. */
1641 if (fInitIpi && pVCpu->idCpu > 0)
1642 {
1643 PVM pVM = pVCpu->CTX_SUFF(pVM);
1644 if (!pVM->nem.s.fA20Enabled)
1645 nemR3NativeNotifySetA20(pVCpu, true);
1646 pVM->nem.s.fA20Enabled = true;
1647 pVM->nem.s.fA20Fixed = true;
1648 }
1649#else
1650 RT_NOREF(pVCpu, fInitIpi);
1651#endif
1652}
1653
1654
1655VBOXSTRICTRC nemR3NativeRunGC(PVM pVM, PVMCPU pVCpu)
1656{
1657 return nemHCWinRunGC(pVM, pVCpu);
1658}
1659
1660
1661VMMR3_INT_DECL(bool) NEMR3CanExecuteGuest(PVM pVM, PVMCPU pVCpu)
1662{
1663 Assert(VM_IS_NEM_ENABLED(pVM));
1664
1665#ifndef NEM_WIN_WITH_A20
1666 /*
1667 * Only execute when the A20 gate is enabled because this lovely Hyper-V
1668 * blackbox does not seem to have any way to enable or disable A20.
1669 */
1670 RT_NOREF(pVM);
1671 return PGMPhysIsA20Enabled(pVCpu);
1672#else
1673 RT_NOREF(pVM, pVCpu);
1674 return true;
1675#endif
1676}
1677
1678
1679bool nemR3NativeSetSingleInstruction(PVM pVM, PVMCPU pVCpu, bool fEnable)
1680{
1681 NOREF(pVM); NOREF(pVCpu); NOREF(fEnable);
1682 return false;
1683}
1684
1685
1686void nemR3NativeNotifyFF(PVM pVM, PVMCPU pVCpu, uint32_t fFlags)
1687{
1688 Log8(("nemR3NativeNotifyFF: canceling %u\n", pVCpu->idCpu));
1689 HRESULT hrc = WHvCancelRunVirtualProcessor(pVM->nem.s.hPartition, pVCpu->idCpu, 0);
1690 AssertMsg(SUCCEEDED(hrc), ("WHvCancelRunVirtualProcessor -> hrc=%Rhrc\n", hrc));
1691 RT_NOREF_PV(hrc);
1692 RT_NOREF_PV(fFlags);
1693}
1694
1695
1696DECLHIDDEN(bool) nemR3NativeNotifyDebugEventChanged(PVM pVM, bool fUseDebugLoop)
1697{
1698 RT_NOREF(pVM, fUseDebugLoop);
1699 return false;
1700}
1701
1702
1703DECLHIDDEN(bool) nemR3NativeNotifyDebugEventChangedPerCpu(PVM pVM, PVMCPU pVCpu, bool fUseDebugLoop)
1704{
1705 RT_NOREF(pVM, pVCpu, fUseDebugLoop);
1706 return false;
1707}
1708
1709
1710DECLINLINE(int) nemR3NativeGCPhys2R3PtrReadOnly(PVM pVM, RTGCPHYS GCPhys, const void **ppv)
1711{
1712 PGMPAGEMAPLOCK Lock;
1713 int rc = PGMPhysGCPhys2CCPtrReadOnly(pVM, GCPhys, ppv, &Lock);
1714 if (RT_SUCCESS(rc))
1715 PGMPhysReleasePageMappingLock(pVM, &Lock);
1716 return rc;
1717}
1718
1719
1720DECLINLINE(int) nemR3NativeGCPhys2R3PtrWriteable(PVM pVM, RTGCPHYS GCPhys, void **ppv)
1721{
1722 PGMPAGEMAPLOCK Lock;
1723 int rc = PGMPhysGCPhys2CCPtr(pVM, GCPhys, ppv, &Lock);
1724 if (RT_SUCCESS(rc))
1725 PGMPhysReleasePageMappingLock(pVM, &Lock);
1726 return rc;
1727}
1728
1729
1730VMMR3_INT_DECL(int) NEMR3NotifyPhysRamRegister(PVM pVM, RTGCPHYS GCPhys, RTGCPHYS cb, void *pvR3,
1731 uint8_t *pu2State, uint32_t *puNemRange)
1732{
1733 Log5(("NEMR3NotifyPhysRamRegister: %RGp LB %RGp, pvR3=%p pu2State=%p (%d) puNemRange=%p (%d)\n",
1734 GCPhys, cb, pvR3, pu2State, pu2State, puNemRange, *puNemRange));
1735
1736 *pu2State = UINT8_MAX;
1737 RT_NOREF(puNemRange);
1738
1739 if (pvR3)
1740 {
1741 STAM_REL_PROFILE_START(&pVM->nem.s.StatProfMapGpaRange, a);
1742 HRESULT hrc = WHvMapGpaRange(pVM->nem.s.hPartition, pvR3, GCPhys, cb,
1743 WHvMapGpaRangeFlagRead | WHvMapGpaRangeFlagWrite | WHvMapGpaRangeFlagExecute);
1744 STAM_REL_PROFILE_STOP(&pVM->nem.s.StatProfMapGpaRange, a);
1745 if (SUCCEEDED(hrc))
1746 *pu2State = NEM_WIN_PAGE_STATE_WRITABLE;
1747 else
1748 {
1749 LogRel(("NEMR3NotifyPhysRamRegister: GCPhys=%RGp LB %RGp pvR3=%p hrc=%Rhrc (%#x) Last=%#x/%u\n",
1750 GCPhys, cb, pvR3, hrc, hrc, RTNtLastStatusValue(), RTNtLastErrorValue()));
1751 STAM_REL_COUNTER_INC(&pVM->nem.s.StatMapPageFailed);
1752 return VERR_NEM_MAP_PAGES_FAILED;
1753 }
1754 }
1755 return VINF_SUCCESS;
1756}
1757
1758
1759VMMR3_INT_DECL(bool) NEMR3IsMmio2DirtyPageTrackingSupported(PVM pVM)
1760{
1761 RT_NOREF(pVM);
1762 return g_pfnWHvQueryGpaRangeDirtyBitmap != NULL;
1763}
1764
1765
1766VMMR3_INT_DECL(int) NEMR3NotifyPhysMmioExMapEarly(PVM pVM, RTGCPHYS GCPhys, RTGCPHYS cb, uint32_t fFlags,
1767 void *pvRam, void *pvMmio2, uint8_t *pu2State, uint32_t *puNemRange)
1768{
1769 Log5(("NEMR3NotifyPhysMmioExMapEarly: %RGp LB %RGp fFlags=%#x pvRam=%p pvMmio2=%p pu2State=%p (%d) puNemRange=%p (%#x)\n",
1770 GCPhys, cb, fFlags, pvRam, pvMmio2, pu2State, *pu2State, puNemRange, puNemRange ? *puNemRange : UINT32_MAX));
1771 RT_NOREF(puNemRange);
1772
1773 /*
1774 * Unmap the RAM we're replacing.
1775 */
1776 if (fFlags & NEM_NOTIFY_PHYS_MMIO_EX_F_REPLACE)
1777 {
1778 STAM_REL_PROFILE_START(&pVM->nem.s.StatProfUnmapGpaRange, a);
1779 HRESULT hrc = WHvUnmapGpaRange(pVM->nem.s.hPartition, GCPhys, cb);
1780 STAM_REL_PROFILE_STOP(&pVM->nem.s.StatProfUnmapGpaRange, a);
1781 if (SUCCEEDED(hrc))
1782 { /* likely */ }
1783 else if (pvMmio2)
1784 LogRel(("NEMR3NotifyPhysMmioExMapEarly: GCPhys=%RGp LB %RGp fFlags=%#x: Unmap -> hrc=%Rhrc (%#x) Last=%#x/%u (ignored)\n",
1785 GCPhys, cb, fFlags, hrc, hrc, RTNtLastStatusValue(), RTNtLastErrorValue()));
1786 else
1787 {
1788 LogRel(("NEMR3NotifyPhysMmioExMapEarly: GCPhys=%RGp LB %RGp fFlags=%#x: Unmap -> hrc=%Rhrc (%#x) Last=%#x/%u\n",
1789 GCPhys, cb, fFlags, hrc, hrc, RTNtLastStatusValue(), RTNtLastErrorValue()));
1790 STAM_REL_COUNTER_INC(&pVM->nem.s.StatUnmapPageFailed);
1791 return VERR_NEM_UNMAP_PAGES_FAILED;
1792 }
1793 }
1794
1795 /*
1796 * Map MMIO2 if any.
1797 */
1798 if (pvMmio2)
1799 {
1800 Assert(fFlags & NEM_NOTIFY_PHYS_MMIO_EX_F_MMIO2);
1801 WHV_MAP_GPA_RANGE_FLAGS fWHvFlags = WHvMapGpaRangeFlagRead | WHvMapGpaRangeFlagWrite | WHvMapGpaRangeFlagExecute;
1802 if ((fFlags & NEM_NOTIFY_PHYS_MMIO_EX_F_TRACK_DIRTY_PAGES) && g_pfnWHvQueryGpaRangeDirtyBitmap)
1803 fWHvFlags |= WHvMapGpaRangeFlagTrackDirtyPages;
1804 STAM_REL_PROFILE_START(&pVM->nem.s.StatProfMapGpaRange, a);
1805 HRESULT hrc = WHvMapGpaRange(pVM->nem.s.hPartition, pvMmio2, GCPhys, cb, fWHvFlags);
1806 STAM_REL_PROFILE_STOP(&pVM->nem.s.StatProfMapGpaRange, a);
1807 if (SUCCEEDED(hrc))
1808 *pu2State = NEM_WIN_PAGE_STATE_WRITABLE;
1809 else
1810 {
1811 LogRel(("NEMR3NotifyPhysMmioExMapEarly: GCPhys=%RGp LB %RGp fFlags=%#x pvMmio2=%p fWHvFlags=%#x: Map -> hrc=%Rhrc (%#x) Last=%#x/%u\n",
1812 GCPhys, cb, fFlags, pvMmio2, fWHvFlags, hrc, hrc, RTNtLastStatusValue(), RTNtLastErrorValue()));
1813 STAM_REL_COUNTER_INC(&pVM->nem.s.StatMapPageFailed);
1814 return VERR_NEM_MAP_PAGES_FAILED;
1815 }
1816 }
1817 else
1818 {
1819 Assert(!(fFlags & NEM_NOTIFY_PHYS_MMIO_EX_F_MMIO2));
1820 *pu2State = NEM_WIN_PAGE_STATE_UNMAPPED;
1821 }
1822 RT_NOREF(pvRam);
1823 return VINF_SUCCESS;
1824}
1825
1826
1827VMMR3_INT_DECL(int) NEMR3NotifyPhysMmioExMapLate(PVM pVM, RTGCPHYS GCPhys, RTGCPHYS cb, uint32_t fFlags,
1828 void *pvRam, void *pvMmio2, uint32_t *puNemRange)
1829{
1830 RT_NOREF(pVM, GCPhys, cb, fFlags, pvRam, pvMmio2, puNemRange);
1831 return VINF_SUCCESS;
1832}
1833
1834
1835VMMR3_INT_DECL(int) NEMR3NotifyPhysMmioExUnmap(PVM pVM, RTGCPHYS GCPhys, RTGCPHYS cb, uint32_t fFlags, void *pvRam,
1836 void *pvMmio2, uint8_t *pu2State, uint32_t *puNemRange)
1837{
1838 int rc = VINF_SUCCESS;
1839 Log5(("NEMR3NotifyPhysMmioExUnmap: %RGp LB %RGp fFlags=%#x pvRam=%p pvMmio2=%p pu2State=%p uNemRange=%#x (%#x)\n",
1840 GCPhys, cb, fFlags, pvRam, pvMmio2, pu2State, puNemRange, *puNemRange));
1841
1842 /*
1843 * Unmap the MMIO2 pages.
1844 */
1845 /** @todo If we implement aliasing (MMIO2 page aliased into MMIO range),
1846 * we may have more stuff to unmap even in case of pure MMIO... */
1847 if (fFlags & NEM_NOTIFY_PHYS_MMIO_EX_F_MMIO2)
1848 {
1849 STAM_REL_PROFILE_START(&pVM->nem.s.StatProfUnmapGpaRange, a);
1850 HRESULT hrc = WHvUnmapGpaRange(pVM->nem.s.hPartition, GCPhys, cb);
1851 STAM_REL_PROFILE_STOP(&pVM->nem.s.StatProfUnmapGpaRange, a);
1852 if (FAILED(hrc))
1853 {
1854 LogRel2(("NEMR3NotifyPhysMmioExUnmap: GCPhys=%RGp LB %RGp fFlags=%#x: Unmap -> hrc=%Rhrc (%#x) Last=%#x/%u (ignored)\n",
1855 GCPhys, cb, fFlags, hrc, hrc, RTNtLastStatusValue(), RTNtLastErrorValue()));
1856 rc = VERR_NEM_UNMAP_PAGES_FAILED;
1857 STAM_REL_COUNTER_INC(&pVM->nem.s.StatUnmapPageFailed);
1858 }
1859 }
1860
1861 /*
1862 * Restore the RAM we replaced.
1863 */
1864 if (fFlags & NEM_NOTIFY_PHYS_MMIO_EX_F_REPLACE)
1865 {
1866 AssertPtr(pvRam);
1867 STAM_REL_PROFILE_START(&pVM->nem.s.StatProfMapGpaRange, a);
1868 HRESULT hrc = WHvMapGpaRange(pVM->nem.s.hPartition, pvRam, GCPhys, cb,
1869 WHvMapGpaRangeFlagRead | WHvMapGpaRangeFlagWrite | WHvMapGpaRangeFlagExecute);
1870 STAM_REL_PROFILE_STOP(&pVM->nem.s.StatProfMapGpaRange, a);
1871 if (SUCCEEDED(hrc))
1872 { /* likely */ }
1873 else
1874 {
1875 LogRel(("NEMR3NotifyPhysMmioExUnmap: GCPhys=%RGp LB %RGp pvMmio2=%p hrc=%Rhrc (%#x) Last=%#x/%u\n",
1876 GCPhys, cb, pvMmio2, hrc, hrc, RTNtLastStatusValue(), RTNtLastErrorValue()));
1877 rc = VERR_NEM_MAP_PAGES_FAILED;
1878 STAM_REL_COUNTER_INC(&pVM->nem.s.StatMapPageFailed);
1879 }
1880 if (pu2State)
1881 *pu2State = NEM_WIN_PAGE_STATE_WRITABLE;
1882 }
1883 /* Mark the pages as unmapped if relevant. */
1884 else if (pu2State)
1885 *pu2State = NEM_WIN_PAGE_STATE_UNMAPPED;
1886
1887 RT_NOREF(pvMmio2, puNemRange);
1888 return rc;
1889}
1890
1891
1892VMMR3_INT_DECL(int) NEMR3PhysMmio2QueryAndResetDirtyBitmap(PVM pVM, RTGCPHYS GCPhys, RTGCPHYS cb, uint32_t uNemRange,
1893 void *pvBitmap, size_t cbBitmap)
1894{
1895 Assert(VM_IS_NEM_ENABLED(pVM));
1896 AssertReturn(g_pfnWHvQueryGpaRangeDirtyBitmap, VERR_INTERNAL_ERROR_2);
1897 Assert(cbBitmap == (uint32_t)cbBitmap);
1898 RT_NOREF(uNemRange);
1899
1900 /* This is being profiled by PGM, see /PGM/Mmio2QueryAndResetDirtyBitmap. */
1901 HRESULT hrc = WHvQueryGpaRangeDirtyBitmap(pVM->nem.s.hPartition, GCPhys, cb, (UINT64 *)pvBitmap, (uint32_t)cbBitmap);
1902 if (SUCCEEDED(hrc))
1903 return VINF_SUCCESS;
1904
1905 AssertLogRelMsgFailed(("GCPhys=%RGp LB %RGp pvBitmap=%p LB %#zx hrc=%Rhrc (%#x) Last=%#x/%u\n",
1906 GCPhys, cb, pvBitmap, cbBitmap, hrc, hrc, RTNtLastStatusValue(), RTNtLastErrorValue()));
1907 return VERR_NEM_QUERY_DIRTY_BITMAP_FAILED;
1908}
1909
1910
1911VMMR3_INT_DECL(int) NEMR3NotifyPhysRomRegisterEarly(PVM pVM, RTGCPHYS GCPhys, RTGCPHYS cb, void *pvPages, uint32_t fFlags,
1912 uint8_t *pu2State, uint32_t *puNemRange)
1913{
1914 Log5(("nemR3NativeNotifyPhysRomRegisterEarly: %RGp LB %RGp pvPages=%p fFlags=%#x\n", GCPhys, cb, pvPages, fFlags));
1915 *pu2State = UINT8_MAX;
1916 *puNemRange = 0;
1917
1918#if 0 /* Let's not do this after all. We'll protection change notifications for each page and if not we'll map them lazily. */
1919 RTGCPHYS const cPages = cb >> X86_PAGE_SHIFT;
1920 for (RTGCPHYS iPage = 0; iPage < cPages; iPage++, GCPhys += X86_PAGE_SIZE)
1921 {
1922 const void *pvPage;
1923 int rc = nemR3NativeGCPhys2R3PtrReadOnly(pVM, GCPhys, &pvPage);
1924 if (RT_SUCCESS(rc))
1925 {
1926 HRESULT hrc = WHvMapGpaRange(pVM->nem.s.hPartition, (void *)pvPage, GCPhys, X86_PAGE_SIZE,
1927 WHvMapGpaRangeFlagRead | WHvMapGpaRangeFlagExecute);
1928 if (SUCCEEDED(hrc))
1929 { /* likely */ }
1930 else
1931 {
1932 LogRel(("nemR3NativeNotifyPhysRomRegisterEarly: GCPhys=%RGp hrc=%Rhrc (%#x) Last=%#x/%u\n",
1933 GCPhys, hrc, hrc, RTNtLastStatusValue(), RTNtLastErrorValue()));
1934 return VERR_NEM_INIT_FAILED;
1935 }
1936 }
1937 else
1938 {
1939 LogRel(("nemR3NativeNotifyPhysRomRegisterEarly: GCPhys=%RGp rc=%Rrc\n", GCPhys, rc));
1940 return rc;
1941 }
1942 }
1943 RT_NOREF_PV(fFlags);
1944#else
1945 RT_NOREF(pVM, GCPhys, cb, pvPages, fFlags);
1946#endif
1947 return VINF_SUCCESS;
1948}
1949
1950
1951VMMR3_INT_DECL(int) NEMR3NotifyPhysRomRegisterLate(PVM pVM, RTGCPHYS GCPhys, RTGCPHYS cb, void *pvPages,
1952 uint32_t fFlags, uint8_t *pu2State, uint32_t *puNemRange)
1953{
1954 Log5(("nemR3NativeNotifyPhysRomRegisterLate: %RGp LB %RGp pvPages=%p fFlags=%#x pu2State=%p (%d) puNemRange=%p (%#x)\n",
1955 GCPhys, cb, pvPages, fFlags, pu2State, *pu2State, puNemRange, *puNemRange));
1956 *pu2State = UINT8_MAX;
1957
1958 /*
1959 * (Re-)map readonly.
1960 */
1961 AssertPtrReturn(pvPages, VERR_INVALID_POINTER);
1962 STAM_REL_PROFILE_START(&pVM->nem.s.StatProfMapGpaRange, a);
1963 HRESULT hrc = WHvMapGpaRange(pVM->nem.s.hPartition, pvPages, GCPhys, cb, WHvMapGpaRangeFlagRead | WHvMapGpaRangeFlagExecute);
1964 STAM_REL_PROFILE_STOP(&pVM->nem.s.StatProfMapGpaRange, a);
1965 if (SUCCEEDED(hrc))
1966 *pu2State = NEM_WIN_PAGE_STATE_READABLE;
1967 else
1968 {
1969 LogRel(("nemR3NativeNotifyPhysRomRegisterEarly: GCPhys=%RGp LB %RGp pvPages=%p fFlags=%#x hrc=%Rhrc (%#x) Last=%#x/%u\n",
1970 GCPhys, cb, pvPages, fFlags, hrc, hrc, RTNtLastStatusValue(), RTNtLastErrorValue()));
1971 STAM_REL_COUNTER_INC(&pVM->nem.s.StatMapPageFailed);
1972 return VERR_NEM_MAP_PAGES_FAILED;
1973 }
1974 RT_NOREF(fFlags, puNemRange);
1975 return VINF_SUCCESS;
1976}
1977
1978#ifdef NEM_WIN_WITH_A20
1979
1980/**
1981 * @callback_method_impl{FNPGMPHYSNEMCHECKPAGE}
1982 */
1983static DECLCALLBACK(int) nemR3WinUnsetForA20CheckerCallback(PVM pVM, PVMCPU pVCpu, RTGCPHYS GCPhys,
1984 PPGMPHYSNEMPAGEINFO pInfo, void *pvUser)
1985{
1986 /* We'll just unmap the memory. */
1987 if (pInfo->u2NemState > NEM_WIN_PAGE_STATE_UNMAPPED)
1988 {
1989 HRESULT hrc = WHvUnmapGpaRange(pVM->nem.s.hPartition, GCPhys, X86_PAGE_SIZE);
1990 if (SUCCEEDED(hrc))
1991 {
1992 STAM_REL_COUNTER_INC(&pVM->nem.s.StatUnmapPage);
1993 uint32_t cMappedPages = ASMAtomicDecU32(&pVM->nem.s.cMappedPages); NOREF(cMappedPages);
1994 Log5(("NEM GPA unmapped/A20: %RGp (was %s, cMappedPages=%u)\n", GCPhys, g_apszPageStates[pInfo->u2NemState], cMappedPages));
1995 pInfo->u2NemState = NEM_WIN_PAGE_STATE_UNMAPPED;
1996 }
1997 else
1998 {
1999 STAM_REL_COUNTER_INC(&pVM->nem.s.StatUnmapPageFailed);
2000 LogRel(("nemR3WinUnsetForA20CheckerCallback/unmap: GCPhys=%RGp hrc=%Rhrc (%#x) Last=%#x/%u\n",
2001 GCPhys, hrc, hrc, RTNtLastStatusValue(), RTNtLastErrorValue()));
2002 return VERR_INTERNAL_ERROR_2;
2003 }
2004 }
2005 RT_NOREF(pVCpu, pvUser);
2006 return VINF_SUCCESS;
2007}
2008
2009
2010/**
2011 * Unmaps a page from Hyper-V for the purpose of emulating A20 gate behavior.
2012 *
2013 * @returns The PGMPhysNemQueryPageInfo result.
2014 * @param pVM The cross context VM structure.
2015 * @param pVCpu The cross context virtual CPU structure.
2016 * @param GCPhys The page to unmap.
2017 */
2018static int nemR3WinUnmapPageForA20Gate(PVM pVM, PVMCPU pVCpu, RTGCPHYS GCPhys)
2019{
2020 PGMPHYSNEMPAGEINFO Info;
2021 return PGMPhysNemPageInfoChecker(pVM, pVCpu, GCPhys, false /*fMakeWritable*/, &Info,
2022 nemR3WinUnsetForA20CheckerCallback, NULL);
2023}
2024
2025#endif /* NEM_WIN_WITH_A20 */
2026
2027VMMR3_INT_DECL(void) NEMR3NotifySetA20(PVMCPU pVCpu, bool fEnabled)
2028{
2029 Log(("nemR3NativeNotifySetA20: fEnabled=%RTbool\n", fEnabled));
2030 Assert(VM_IS_NEM_ENABLED(pVCpu->CTX_SUFF(pVM)));
2031#ifdef NEM_WIN_WITH_A20
2032 PVM pVM = pVCpu->CTX_SUFF(pVM);
2033 if (!pVM->nem.s.fA20Fixed)
2034 {
2035 pVM->nem.s.fA20Enabled = fEnabled;
2036 for (RTGCPHYS GCPhys = _1M; GCPhys < _1M + _64K; GCPhys += X86_PAGE_SIZE)
2037 nemR3WinUnmapPageForA20Gate(pVM, pVCpu, GCPhys);
2038 }
2039#else
2040 RT_NOREF(pVCpu, fEnabled);
2041#endif
2042}
2043
2044
2045/** @page pg_nem_win NEM/win - Native Execution Manager, Windows.
2046 *
2047 * On Windows the Hyper-V root partition (dom0 in zen terminology) does not have
2048 * nested VT-x or AMD-V capabilities. Early on raw-mode worked inside it, but
2049 * for a while now we've been getting \#GPs when trying to modify CR4 in the
2050 * world switcher. So, when Hyper-V is active on Windows we have little choice
2051 * but to use Hyper-V to run our VMs.
2052 *
2053 *
2054 * @section sub_nem_win_whv The WinHvPlatform API
2055 *
2056 * Since Windows 10 build 17083 there is a documented API for managing Hyper-V
2057 * VMs: header file WinHvPlatform.h and implementation in WinHvPlatform.dll.
2058 * This interface is a wrapper around the undocumented Virtualization
2059 * Infrastructure Driver (VID) API - VID.DLL and VID.SYS. The wrapper is
2060 * written in C++, namespaced, early versions (at least) was using standard C++
2061 * container templates in several places.
2062 *
2063 * When creating a VM using WHvCreatePartition, it will only create the
2064 * WinHvPlatform structures for it, to which you get an abstract pointer. The
2065 * VID API that actually creates the partition is first engaged when you call
2066 * WHvSetupPartition after first setting a lot of properties using
2067 * WHvSetPartitionProperty. Since the VID API is just a very thin wrapper
2068 * around CreateFile and NtDeviceIoControlFile, it returns an actual HANDLE for
2069 * the partition to WinHvPlatform. We fish this HANDLE out of the WinHvPlatform
2070 * partition structures because we need to talk directly to VID for reasons
2071 * we'll get to in a bit. (Btw. we could also intercept the CreateFileW or
2072 * NtDeviceIoControlFile calls from VID.DLL to get the HANDLE should fishing in
2073 * the partition structures become difficult.)
2074 *
2075 * The WinHvPlatform API requires us to both set the number of guest CPUs before
2076 * setting up the partition and call WHvCreateVirtualProcessor for each of them.
2077 * The CPU creation function boils down to a VidMessageSlotMap call that sets up
2078 * and maps a message buffer into ring-3 for async communication with hyper-V
2079 * and/or the VID.SYS thread actually running the CPU thru
2080 * WinHvRunVpDispatchLoop(). When for instance a VMEXIT is encountered, hyper-V
2081 * sends a message that the WHvRunVirtualProcessor API retrieves (and later
2082 * acknowledges) via VidMessageSlotHandleAndGetNext. Since or about build
2083 * 17757 a register page is also mapped into user space when creating the
2084 * virtual CPU. It should be noteded that WHvDeleteVirtualProcessor doesn't do
2085 * much as there seems to be no partner function VidMessagesSlotMap that
2086 * reverses what it did.
2087 *
2088 * Memory is managed thru calls to WHvMapGpaRange and WHvUnmapGpaRange (GPA does
2089 * not mean grade point average here, but rather guest physical addressspace),
2090 * which corresponds to VidCreateVaGpaRangeSpecifyUserVa and VidDestroyGpaRange
2091 * respectively. As 'UserVa' indicates, the functions works on user process
2092 * memory. The mappings are also subject to quota restrictions, so the number
2093 * of ranges are limited and probably their total size as well. Obviously
2094 * VID.SYS keeps track of the ranges, but so does WinHvPlatform, which means
2095 * there is a bit of overhead involved and quota restrctions makes sense.
2096 *
2097 * Running guest code is done through the WHvRunVirtualProcessor function. It
2098 * asynchronously starts or resumes hyper-V CPU execution and then waits for an
2099 * VMEXIT message. Hyper-V / VID.SYS will return information about the message
2100 * in the message buffer mapping, and WHvRunVirtualProcessor will convert that
2101 * finto it's own WHV_RUN_VP_EXIT_CONTEXT format.
2102 *
2103 * Other threads can interrupt the execution by using WHvCancelVirtualProcessor,
2104 * which since or about build 17757 uses VidMessageSlotHandleAndGetNext to do
2105 * the work (earlier builds would open the waiting thread, do a dummy
2106 * QueueUserAPC on it, and let it upon return use VidStopVirtualProcessor to
2107 * do the actual stopping). While there is certainly a race between cancelation
2108 * and the CPU causing a natural VMEXIT, it is not known whether this still
2109 * causes extra work on subsequent WHvRunVirtualProcessor calls (it did in and
2110 * earlier than 17134).
2111 *
2112 * Registers are retrieved and set via WHvGetVirtualProcessorRegisters and
2113 * WHvSetVirtualProcessorRegisters. In addition, several VMEXITs include
2114 * essential register state in the exit context information, potentially making
2115 * it possible to emulate the instruction causing the exit without involving
2116 * WHvGetVirtualProcessorRegisters.
2117 *
2118 *
2119 * @subsection subsec_nem_win_whv_cons Issues & Feedback
2120 *
2121 * Here are some observations (mostly against build 17101):
2122 *
2123 * - The VMEXIT performance is dismal (build 17134).
2124 *
2125 * Our proof of concept implementation with a kernel runloop (i.e. not using
2126 * WHvRunVirtualProcessor and friends, but calling VID.SYS fast I/O control
2127 * entry point directly) delivers 9-10% of the port I/O performance and only
2128 * 6-7% of the MMIO performance that we have with our own hypervisor.
2129 *
2130 * When using the offical WinHvPlatform API, the numbers are %3 for port I/O
2131 * and 5% for MMIO.
2132 *
2133 * While the tests we've done are using tight tight loops only doing port I/O
2134 * and MMIO, the problem is clearly visible when running regular guest OSes.
2135 * Anything that hammers the VGA device would be suffering, for example:
2136 *
2137 * - Windows 2000 boot screen animation overloads us with MMIO exits
2138 * and won't even boot because all the time is spent in interrupt
2139 * handlers and redrawin the screen.
2140 *
2141 * - DSL 4.4 and its bootmenu logo is slower than molasses in january.
2142 *
2143 * We have not found a workaround for this yet.
2144 *
2145 * Something that might improve the issue a little is to detect blocks with
2146 * excessive MMIO and port I/O exits and emulate instructions to cover
2147 * multiple exits before letting Hyper-V have a go at the guest execution
2148 * again. This will only improve the situation under some circumstances,
2149 * since emulating instructions without recompilation can be expensive, so
2150 * there will only be real gains if the exitting instructions are tightly
2151 * packed.
2152 *
2153 * Update: Security fixes during the summer of 2018 caused the performance to
2154 * dropped even more.
2155 *
2156 * Update [build 17757]: Some performance improvements here, but they don't
2157 * yet make up for what was lost this summer.
2158 *
2159 *
2160 * - We need a way to directly modify the TSC offset (or bias if you like).
2161 *
2162 * The current approach of setting the WHvX64RegisterTsc register one by one
2163 * on each virtual CPU in sequence will introduce random inaccuracies,
2164 * especially if the thread doing the job is reschduled at a bad time.
2165 *
2166 *
2167 * - Unable to access WHvX64RegisterMsrMtrrCap (build 17134).
2168 *
2169 *
2170 * - On AMD Ryzen grub/debian 9.0 ends up with a unrecoverable exception
2171 * when IA32_MTRR_PHYSMASK0 is written.
2172 *
2173 *
2174 * - The IA32_APIC_BASE register does not work right:
2175 *
2176 * - Attempts by the guest to clear bit 11 (EN) are ignored, both the
2177 * guest and the VMM reads back the old value.
2178 *
2179 * - Attempts to modify the base address (bits NN:12) seems to be ignored
2180 * in the same way.
2181 *
2182 * - The VMM can modify both the base address as well as the the EN and
2183 * BSP bits, however this is useless if we cannot intercept the WRMSR.
2184 *
2185 * - Attempts by the guest to set the EXTD bit (X2APIC) result in \#GP(0),
2186 * while the VMM ends up with with ERROR_HV_INVALID_PARAMETER. Seems
2187 * there is no way to support X2APIC.
2188 *
2189 *
2190 * - Not sure if this is a thing, but WHvCancelVirtualProcessor seems to cause
2191 * cause a lot more spurious WHvRunVirtualProcessor returns that what we get
2192 * with the replacement code. By spurious returns we mean that the
2193 * subsequent call to WHvRunVirtualProcessor would return immediately.
2194 *
2195 * Update [build 17757]: New cancelation code might have addressed this, but
2196 * haven't had time to test it yet.
2197 *
2198 *
2199 * - There is no API for modifying protection of a page within a GPA range.
2200 *
2201 * From what we can tell, the only way to modify the protection (like readonly
2202 * -> writable, or vice versa) is to first unmap the range and then remap it
2203 * with the new protection.
2204 *
2205 * We are for instance doing this quite a bit in order to track dirty VRAM
2206 * pages. VRAM pages starts out as readonly, when the guest writes to a page
2207 * we take an exit, notes down which page it is, makes it writable and restart
2208 * the instruction. After refreshing the display, we reset all the writable
2209 * pages to readonly again, bulk fashion.
2210 *
2211 * Now to work around this issue, we do page sized GPA ranges. In addition to
2212 * add a lot of tracking overhead to WinHvPlatform and VID.SYS, this also
2213 * causes us to exceed our quota before we've even mapped a default sized
2214 * (128MB) VRAM page-by-page. So, to work around this quota issue we have to
2215 * lazily map pages and actively restrict the number of mappings.
2216 *
2217 * Our best workaround thus far is bypassing WinHvPlatform and VID entirely
2218 * when in comes to guest memory management and instead use the underlying
2219 * hypercalls (HvCallMapGpaPages, HvCallUnmapGpaPages) to do it ourselves.
2220 * (This also maps a whole lot better into our own guest page management
2221 * infrastructure.)
2222 *
2223 * Update [build 17757]: Introduces a KVM like dirty logging API which could
2224 * help tracking dirty VGA pages, while being useless for shadow ROM and
2225 * devices trying catch the guest updating descriptors and such.
2226 *
2227 *
2228 * - Observed problems doing WHvUnmapGpaRange immediately followed by
2229 * WHvMapGpaRange.
2230 *
2231 * As mentioned above, we've been forced to use this sequence when modifying
2232 * page protection. However, when transitioning from readonly to writable,
2233 * we've ended up looping forever with the same write to readonly memory
2234 * VMEXIT. We're wondering if this issue might be related to the lazy mapping
2235 * logic in WinHvPlatform.
2236 *
2237 * Workaround: Insert a WHvRunVirtualProcessor call and make sure to get a GPA
2238 * unmapped exit between the two calls. Not entirely great performance wise
2239 * (or the santity of our code).
2240 *
2241 *
2242 * - Implementing A20 gate behavior is tedious, where as correctly emulating the
2243 * A20M# pin (present on 486 and later) is near impossible for SMP setups
2244 * (e.g. possiblity of two CPUs with different A20 status).
2245 *
2246 * Workaround #1 (obsolete): Only do A20 on CPU 0, restricting the emulation
2247 * to HMA. We unmap all pages related to HMA (0x100000..0x10ffff) when the A20
2248 * state changes, lazily syncing the right pages back when accessed.
2249 *
2250 * Workaround #2 (used): Use IEM when the A20 gate is disabled.
2251 *
2252 *
2253 * - WHVRunVirtualProcessor wastes time converting VID/Hyper-V messages to its
2254 * own format (WHV_RUN_VP_EXIT_CONTEXT).
2255 *
2256 * We understand this might be because Microsoft wishes to remain free to
2257 * modify the VID/Hyper-V messages, but it's still rather silly and does slow
2258 * things down a little. We'd much rather just process the messages directly.
2259 *
2260 *
2261 * - WHVRunVirtualProcessor would've benefited from using a callback interface:
2262 *
2263 * - The potential size changes of the exit context structure wouldn't be
2264 * an issue, since the function could manage that itself.
2265 *
2266 * - State handling could probably be simplified (like cancelation).
2267 *
2268 *
2269 * - WHvGetVirtualProcessorRegisters and WHvSetVirtualProcessorRegisters
2270 * internally converts register names, probably using temporary heap buffers.
2271 *
2272 * From the looks of things, they are converting from WHV_REGISTER_NAME to
2273 * HV_REGISTER_NAME from in the "Virtual Processor Register Names" section in
2274 * the "Hypervisor Top-Level Functional Specification" document. This feels
2275 * like an awful waste of time.
2276 *
2277 * We simply cannot understand why HV_REGISTER_NAME isn't used directly here,
2278 * or at least the same values, making any conversion reduntant. Restricting
2279 * access to certain registers could easily be implement by scanning the
2280 * inputs.
2281 *
2282 * To avoid the heap + conversion overhead, we're currently using the
2283 * HvCallGetVpRegisters and HvCallSetVpRegisters calls directly, at least for
2284 * the ring-0 code.
2285 *
2286 * Update [build 17757]: Register translation has been very cleverly
2287 * optimized and made table driven (2 top level tables, 4 + 1 leaf tables).
2288 * Register information consists of the 32-bit HV register name, register page
2289 * offset, and flags (giving valid offset, size and more). Register
2290 * getting/settings seems to be done by hoping that the register page provides
2291 * it all, and falling back on the VidSetVirtualProcessorState if one or more
2292 * registers are not available there.
2293 *
2294 * Note! We have currently not updated our ring-0 code to take the register
2295 * page into account, so it's suffering a little compared to the ring-3 code
2296 * that now uses the offical APIs for registers.
2297 *
2298 *
2299 * - The YMM and XCR0 registers are not yet named (17083). This probably
2300 * wouldn't be a problem if HV_REGISTER_NAME was used, see previous point.
2301 *
2302 * Update [build 17757]: XCR0 is added. YMM register values seems to be put
2303 * into a yet undocumented XsaveState interface. Approach is a little bulky,
2304 * but saves number of enums and dispenses with register transation. Also,
2305 * the underlying Vid setter API duplicates the input buffer on the heap,
2306 * adding a 16 byte header.
2307 *
2308 *
2309 * - Why does VID.SYS only query/set 32 registers at the time thru the
2310 * HvCallGetVpRegisters and HvCallSetVpRegisters hypercalls?
2311 *
2312 * We've not trouble getting/setting all the registers defined by
2313 * WHV_REGISTER_NAME in one hypercall (around 80). Some kind of stack
2314 * buffering or similar?
2315 *
2316 *
2317 * - To handle the VMMCALL / VMCALL instructions, it seems we need to intercept
2318 * \#UD exceptions and inspect the opcodes. A dedicated exit for hypercalls
2319 * would be more efficient, esp. for guests using \#UD for other purposes..
2320 *
2321 *
2322 * - Wrong instruction length in the VpContext with unmapped GPA memory exit
2323 * contexts on 17115/AMD.
2324 *
2325 * One byte "PUSH CS" was reported as 2 bytes, while a two byte
2326 * "MOV [EBX],EAX" was reported with a 1 byte instruction length. Problem
2327 * naturally present in untranslated hyper-v messages.
2328 *
2329 *
2330 * - The I/O port exit context information seems to be missing the address size
2331 * information needed for correct string I/O emulation.
2332 *
2333 * VT-x provides this information in bits 7:9 in the instruction information
2334 * field on newer CPUs. AMD-V in bits 7:9 in the EXITINFO1 field in the VMCB.
2335 *
2336 * We can probably work around this by scanning the instruction bytes for
2337 * address size prefixes. Haven't investigated it any further yet.
2338 *
2339 *
2340 * - Querying WHvCapabilityCodeExceptionExitBitmap returns zero even when
2341 * intercepts demonstrably works (17134).
2342 *
2343 *
2344 * - Querying HvPartitionPropertyDebugChannelId via HvCallGetPartitionProperty
2345 * (hypercall) hangs the host (17134).
2346 *
2347 * - CommonUtilities::GuidToString needs a 'static' before the hex digit array,
2348 * looks pointless to re-init a stack copy it for each call (novice mistake).
2349 *
2350 *
2351 * Old concerns that have been addressed:
2352 *
2353 * - The WHvCancelVirtualProcessor API schedules a dummy usermode APC callback
2354 * in order to cancel any current or future alertable wait in VID.SYS during
2355 * the VidMessageSlotHandleAndGetNext call.
2356 *
2357 * IIRC this will make the kernel schedule the specified callback thru
2358 * NTDLL!KiUserApcDispatcher by modifying the thread context and quite
2359 * possibly the userland thread stack. When the APC callback returns to
2360 * KiUserApcDispatcher, it will call NtContinue to restore the old thread
2361 * context and resume execution from there. This naturally adds up to some
2362 * CPU cycles, ring transitions aren't for free, especially after Spectre &
2363 * Meltdown mitigations.
2364 *
2365 * Using NtAltertThread call could do the same without the thread context
2366 * modifications and the extra kernel call.
2367 *
2368 * Update: All concerns have addressed in or about build 17757.
2369 *
2370 * The WHvCancelVirtualProcessor API is now implemented using a new
2371 * VidMessageSlotHandleAndGetNext() flag (4). Codepath is slightly longer
2372 * than NtAlertThread, but has the added benefit that spurious wakeups can be
2373 * more easily reduced.
2374 *
2375 *
2376 * - When WHvRunVirtualProcessor returns without a message, or on a terse
2377 * VID message like HLT, it will make a kernel call to get some registers.
2378 * This is potentially inefficient if the caller decides he needs more
2379 * register state.
2380 *
2381 * It would be better to just return what's available and let the caller fetch
2382 * what is missing from his point of view in a single kernel call.
2383 *
2384 * Update: All concerns have been addressed in or about build 17757. Selected
2385 * registers are now available via shared memory and thus HLT should (not
2386 * verified) no longer require a system call to compose the exit context data.
2387 *
2388 *
2389 * - The WHvRunVirtualProcessor implementation does lazy GPA range mappings when
2390 * a unmapped GPA message is received from hyper-V.
2391 *
2392 * Since MMIO is currently realized as unmapped GPA, this will slow down all
2393 * MMIO accesses a tiny little bit as WHvRunVirtualProcessor looks up the
2394 * guest physical address to check if it is a pending lazy mapping.
2395 *
2396 * The lazy mapping feature makes no sense to us. We as API user have all the
2397 * information and can do lazy mapping ourselves if we want/have to (see next
2398 * point).
2399 *
2400 * Update: All concerns have been addressed in or about build 17757.
2401 *
2402 *
2403 * - The WHvGetCapability function has a weird design:
2404 * - The CapabilityCode parameter is pointlessly duplicated in the output
2405 * structure (WHV_CAPABILITY).
2406 *
2407 * - API takes void pointer, but everyone will probably be using
2408 * WHV_CAPABILITY due to WHV_CAPABILITY::CapabilityCode making it
2409 * impractical to use anything else.
2410 *
2411 * - No output size.
2412 *
2413 * - See GetFileAttributesEx, GetFileInformationByHandleEx,
2414 * FindFirstFileEx, and others for typical pattern for generic
2415 * information getters.
2416 *
2417 * Update: All concerns have been addressed in build 17110.
2418 *
2419 *
2420 * - The WHvGetPartitionProperty function uses the same weird design as
2421 * WHvGetCapability, see above.
2422 *
2423 * Update: All concerns have been addressed in build 17110.
2424 *
2425 *
2426 * - The WHvSetPartitionProperty function has a totally weird design too:
2427 * - In contrast to its partner WHvGetPartitionProperty, the property code
2428 * is not a separate input parameter here but part of the input
2429 * structure.
2430 *
2431 * - The input structure is a void pointer rather than a pointer to
2432 * WHV_PARTITION_PROPERTY which everyone probably will be using because
2433 * of the WHV_PARTITION_PROPERTY::PropertyCode field.
2434 *
2435 * - Really, why use PVOID for the input when the function isn't accepting
2436 * minimal sizes. E.g. WHVPartitionPropertyCodeProcessorClFlushSize only
2437 * requires a 9 byte input, but the function insists on 16 bytes (17083).
2438 *
2439 * - See GetFileAttributesEx, SetFileInformationByHandle, FindFirstFileEx,
2440 * and others for typical pattern for generic information setters and
2441 * getters.
2442 *
2443 * Update: All concerns have been addressed in build 17110.
2444 *
2445 *
2446 * @section sec_nem_win_large_pages Large Pages
2447 *
2448 * We've got a standalone memory allocation and access testcase bs3-memalloc-1
2449 * which was run with 48GiB of guest RAM configured on a NUC 11 box running
2450 * Windows 11 GA. In the simplified NEM memory mode no exits should be
2451 * generated while the access tests are running.
2452 *
2453 * The bs3-memalloc-1 results kind of hints at some tiny speed-up if the guest
2454 * RAM is allocated using the MEM_LARGE_PAGES flag, but only in the 3rd access
2455 * check (typical 350 000 MiB/s w/o and around 400 000 MiB/s). The result for
2456 * the 2nd access varies a lot, perhaps hinting at some table optimizations
2457 * going on.
2458 *
2459 * The initial access where the memory is locked/whatever has absolutely horrid
2460 * results regardless of whether large pages are enabled or not. Typically
2461 * bobbing close to 500 MiB/s, non-large pages a little faster.
2462 *
2463 * NEM w/ simplified memory and MEM_LARGE_PAGES:
2464 * @verbatim
2465bs3-memalloc-1: TESTING...
2466bs3-memalloc-1: #0/0x0: 0x0000000000000000 LB 0x000000000009fc00 USABLE (1)
2467bs3-memalloc-1: #1/0x1: 0x000000000009fc00 LB 0x0000000000000400 RESERVED (2)
2468bs3-memalloc-1: #2/0x2: 0x00000000000f0000 LB 0x0000000000010000 RESERVED (2)
2469bs3-memalloc-1: #3/0x3: 0x0000000000100000 LB 0x00000000dfef0000 USABLE (1)
2470bs3-memalloc-1: #4/0x4: 0x00000000dfff0000 LB 0x0000000000010000 ACPI_RECLAIMABLE (3)
2471bs3-memalloc-1: #5/0x5: 0x00000000fec00000 LB 0x0000000000001000 RESERVED (2)
2472bs3-memalloc-1: #6/0x6: 0x00000000fee00000 LB 0x0000000000001000 RESERVED (2)
2473bs3-memalloc-1: #7/0x7: 0x00000000fffc0000 LB 0x0000000000040000 RESERVED (2)
2474bs3-memalloc-1: #8/0x9: 0x0000000100000000 LB 0x0000000b20000000 USABLE (1)
2475bs3-memalloc-1: Found 1 interesting entries covering 0xb20000000 bytes (44 GB).
2476bs3-memalloc-1: From 0x100000000 to 0xc20000000
2477bs3-memalloc-1: INT15h/E820 : PASSED
2478bs3-memalloc-1: Mapping memory above 4GB : PASSED
2479bs3-memalloc-1: Pages : 11 665 408 pages
2480bs3-memalloc-1: MiBs : 45 568 MB
2481bs3-memalloc-1: Alloc elapsed : 90 925 263 996 ns
2482bs3-memalloc-1: Alloc elapsed in ticks : 272 340 387 336 ticks
2483bs3-memalloc-1: Page alloc time : 7 794 ns/page
2484bs3-memalloc-1: Page alloc time in ticks : 23 345 ticks/page
2485bs3-memalloc-1: Alloc thruput : 128 296 pages/s
2486bs3-memalloc-1: Alloc thruput in MiBs : 501 MB/s
2487bs3-memalloc-1: Allocation speed : PASSED
2488bs3-memalloc-1: Access elapsed : 85 074 483 467 ns
2489bs3-memalloc-1: Access elapsed in ticks : 254 816 088 412 ticks
2490bs3-memalloc-1: Page access time : 7 292 ns/page
2491bs3-memalloc-1: Page access time in ticks : 21 843 ticks/page
2492bs3-memalloc-1: Access thruput : 137 119 pages/s
2493bs3-memalloc-1: Access thruput in MiBs : 535 MB/s
2494bs3-memalloc-1: 2nd access : PASSED
2495bs3-memalloc-1: Access elapsed : 112 963 925 ns
2496bs3-memalloc-1: Access elapsed in ticks : 338 284 436 ticks
2497bs3-memalloc-1: Page access time : 9 ns/page
2498bs3-memalloc-1: Page access time in ticks : 28 ticks/page
2499bs3-memalloc-1: Access thruput : 103 266 666 pages/s
2500bs3-memalloc-1: Access thruput in MiBs : 403 385 MB/s
2501bs3-memalloc-1: 3rd access : PASSED
2502bs3-memalloc-1: SUCCESS
2503 * @endverbatim
2504 *
2505 * NEM w/ simplified memory and but no MEM_LARGE_PAGES:
2506 * @verbatim
2507bs3-memalloc-1: From 0x100000000 to 0xc20000000
2508bs3-memalloc-1: Pages : 11 665 408 pages
2509bs3-memalloc-1: MiBs : 45 568 MB
2510bs3-memalloc-1: Alloc elapsed : 90 062 027 900 ns
2511bs3-memalloc-1: Alloc elapsed in ticks : 269 754 826 466 ticks
2512bs3-memalloc-1: Page alloc time : 7 720 ns/page
2513bs3-memalloc-1: Page alloc time in ticks : 23 124 ticks/page
2514bs3-memalloc-1: Alloc thruput : 129 526 pages/s
2515bs3-memalloc-1: Alloc thruput in MiBs : 505 MB/s
2516bs3-memalloc-1: Allocation speed : PASSED
2517bs3-memalloc-1: Access elapsed : 3 596 017 220 ns
2518bs3-memalloc-1: Access elapsed in ticks : 10 770 732 620 ticks
2519bs3-memalloc-1: Page access time : 308 ns/page
2520bs3-memalloc-1: Page access time in ticks : 923 ticks/page
2521bs3-memalloc-1: Access thruput : 3 243 980 pages/s
2522bs3-memalloc-1: Access thruput in MiBs : 12 671 MB/s
2523bs3-memalloc-1: 2nd access : PASSED
2524bs3-memalloc-1: Access elapsed : 133 060 160 ns
2525bs3-memalloc-1: Access elapsed in ticks : 398 459 884 ticks
2526bs3-memalloc-1: Page access time : 11 ns/page
2527bs3-memalloc-1: Page access time in ticks : 34 ticks/page
2528bs3-memalloc-1: Access thruput : 87 670 178 pages/s
2529bs3-memalloc-1: Access thruput in MiBs : 342 461 MB/s
2530bs3-memalloc-1: 3rd access : PASSED
2531 * @endverbatim
2532 *
2533 * Same everything but native VT-x and VBox (stripped output a little):
2534 * @verbatim
2535bs3-memalloc-1: From 0x100000000 to 0xc20000000
2536bs3-memalloc-1: Pages : 11 665 408 pages
2537bs3-memalloc-1: MiBs : 45 568 MB
2538bs3-memalloc-1: Alloc elapsed : 776 111 427 ns
2539bs3-memalloc-1: Alloc elapsed in ticks : 2 323 267 035 ticks
2540bs3-memalloc-1: Page alloc time : 66 ns/page
2541bs3-memalloc-1: Page alloc time in ticks : 199 ticks/page
2542bs3-memalloc-1: Alloc thruput : 15 030 584 pages/s
2543bs3-memalloc-1: Alloc thruput in MiBs : 58 713 MB/s
2544bs3-memalloc-1: Allocation speed : PASSED
2545bs3-memalloc-1: Access elapsed : 112 141 904 ns
2546bs3-memalloc-1: Access elapsed in ticks : 335 751 077 ticks
2547bs3-memalloc-1: Page access time : 9 ns/page
2548bs3-memalloc-1: Page access time in ticks : 28 ticks/page
2549bs3-memalloc-1: Access thruput : 104 023 630 pages/s
2550bs3-memalloc-1: Access thruput in MiBs : 406 342 MB/s
2551bs3-memalloc-1: 2nd access : PASSED
2552bs3-memalloc-1: Access elapsed : 112 023 049 ns
2553bs3-memalloc-1: Access elapsed in ticks : 335 418 343 ticks
2554bs3-memalloc-1: Page access time : 9 ns/page
2555bs3-memalloc-1: Page access time in ticks : 28 ticks/page
2556bs3-memalloc-1: Access thruput : 104 133 998 pages/s
2557bs3-memalloc-1: Access thruput in MiBs : 406 773 MB/s
2558bs3-memalloc-1: 3rd access : PASSED
2559 * @endverbatim
2560 *
2561 * VBox with large pages disabled:
2562 * @verbatim
2563bs3-memalloc-1: From 0x100000000 to 0xc20000000
2564bs3-memalloc-1: Pages : 11 665 408 pages
2565bs3-memalloc-1: MiBs : 45 568 MB
2566bs3-memalloc-1: Alloc elapsed : 50 986 588 028 ns
2567bs3-memalloc-1: Alloc elapsed in ticks : 152 714 862 044 ticks
2568bs3-memalloc-1: Page alloc time : 4 370 ns/page
2569bs3-memalloc-1: Page alloc time in ticks : 13 091 ticks/page
2570bs3-memalloc-1: Alloc thruput : 228 793 pages/s
2571bs3-memalloc-1: Alloc thruput in MiBs : 893 MB/s
2572bs3-memalloc-1: Allocation speed : PASSED
2573bs3-memalloc-1: Access elapsed : 2 849 641 741 ns
2574bs3-memalloc-1: Access elapsed in ticks : 8 535 372 249 ticks
2575bs3-memalloc-1: Page access time : 244 ns/page
2576bs3-memalloc-1: Page access time in ticks : 731 ticks/page
2577bs3-memalloc-1: Access thruput : 4 093 640 pages/s
2578bs3-memalloc-1: Access thruput in MiBs : 15 990 MB/s
2579bs3-memalloc-1: 2nd access : PASSED
2580bs3-memalloc-1: Access elapsed : 2 866 960 770 ns
2581bs3-memalloc-1: Access elapsed in ticks : 8 587 097 799 ticks
2582bs3-memalloc-1: Page access time : 245 ns/page
2583bs3-memalloc-1: Page access time in ticks : 736 ticks/page
2584bs3-memalloc-1: Access thruput : 4 068 910 pages/s
2585bs3-memalloc-1: Access thruput in MiBs : 15 894 MB/s
2586bs3-memalloc-1: 3rd access : PASSED
2587 * @endverbatim
2588 *
2589 * Comparing large pages, therer is an allocation speed difference of two order
2590 * of magnitude. When disabling large pages in VBox the allocation numbers are
2591 * closer, and the is clear from the 2nd and 3rd access tests that VBox doesn't
2592 * spend enough memory on nested page tables as Hyper-V does. The similar 2nd
2593 * and 3rd access numbers the two large page testruns seems to hint strongly at
2594 * Hyper-V eventually getting the large pages in place too, only that it sucks
2595 * hundredfold in the setting up phase.
2596 *
2597 *
2598 *
2599 * @section sec_nem_win_impl Our implementation.
2600 *
2601 * We set out with the goal of wanting to run as much as possible in ring-0,
2602 * reasoning that this would give use the best performance.
2603 *
2604 * This goal was approached gradually, starting out with a pure WinHvPlatform
2605 * implementation, gradually replacing parts: register access, guest memory
2606 * handling, running virtual processors. Then finally moving it all into
2607 * ring-0, while keeping most of it configurable so that we could make
2608 * comparisons (see NEMInternal.h and nemR3NativeRunGC()).
2609 *
2610 *
2611 * @subsection subsect_nem_win_impl_ioctl VID.SYS I/O control calls
2612 *
2613 * To run things in ring-0 we need to talk directly to VID.SYS thru its I/O
2614 * control interface. Looking at changes between like build 17083 and 17101 (if
2615 * memory serves) a set of the VID I/O control numbers shifted a little, which
2616 * means we need to determin them dynamically. We currently do this by hooking
2617 * the NtDeviceIoControlFile API call from VID.DLL and snooping up the
2618 * parameters when making dummy calls to relevant APIs. (We could also
2619 * disassemble the relevant APIs and try fish out the information from that, but
2620 * this is way simpler.)
2621 *
2622 * Issuing I/O control calls from ring-0 is facing a small challenge with
2623 * respect to direct buffering. When using direct buffering the device will
2624 * typically check that the buffer is actually in the user address space range
2625 * and reject kernel addresses. Fortunately, we've got the cross context VM
2626 * structure that is mapped into both kernel and user space, it's also locked
2627 * and safe to access from kernel space. So, we place the I/O control buffers
2628 * in the per-CPU part of it (NEMCPU::uIoCtlBuf) and give the driver the user
2629 * address if direct access buffering or kernel address if not.
2630 *
2631 * The I/O control calls are 'abstracted' in the support driver, see
2632 * SUPR0IoCtlSetupForHandle(), SUPR0IoCtlPerform() and SUPR0IoCtlCleanup().
2633 *
2634 *
2635 * @subsection subsect_nem_win_impl_cpumctx CPUMCTX
2636 *
2637 * Since the CPU state needs to live in Hyper-V when executing, we probably
2638 * should not transfer more than necessary when handling VMEXITs. To help us
2639 * manage this CPUMCTX got a new field CPUMCTX::fExtrn that to indicate which
2640 * part of the state is currently externalized (== in Hyper-V).
2641 *
2642 *
2643 * @subsection sec_nem_win_benchmarks Benchmarks.
2644 *
2645 * @subsubsection subsect_nem_win_benchmarks_bs2t1 17134/2018-06-22: Bootsector2-test1
2646 *
2647 * This is ValidationKit/bootsectors/bootsector2-test1.asm as of 2018-06-22
2648 * (internal r123172) running a the release build of VirtualBox from the same
2649 * source, though with exit optimizations disabled. Host is AMD Threadripper 1950X
2650 * running out an up to date 64-bit Windows 10 build 17134.
2651 *
2652 * The base line column is using the official WinHv API for everything but physical
2653 * memory mapping. The 2nd column is the default NEM/win configuration where we
2654 * put the main execution loop in ring-0, using hypercalls when we can and VID for
2655 * managing execution. The 3rd column is regular VirtualBox using AMD-V directly,
2656 * hyper-V is disabled, main execution loop in ring-0.
2657 *
2658 * @verbatim
2659TESTING... WinHv API Hypercalls + VID VirtualBox AMD-V
2660 32-bit paged protected mode, CPUID : 108 874 ins/sec 113% / 123 602 1198% / 1 305 113
2661 32-bit pae protected mode, CPUID : 106 722 ins/sec 115% / 122 740 1232% / 1 315 201
2662 64-bit long mode, CPUID : 106 798 ins/sec 114% / 122 111 1198% / 1 280 404
2663 16-bit unpaged protected mode, CPUID : 106 835 ins/sec 114% / 121 994 1216% / 1 299 665
2664 32-bit unpaged protected mode, CPUID : 105 257 ins/sec 115% / 121 772 1235% / 1 300 860
2665 real mode, CPUID : 104 507 ins/sec 116% / 121 800 1228% / 1 283 848
2666CPUID EAX=1 : PASSED
2667 32-bit paged protected mode, RDTSC : 99 581 834 ins/sec 100% / 100 323 307 93% / 93 473 299
2668 32-bit pae protected mode, RDTSC : 99 620 585 ins/sec 100% / 99 960 952 84% / 83 968 839
2669 64-bit long mode, RDTSC : 100 540 009 ins/sec 100% / 100 946 372 93% / 93 652 826
2670 16-bit unpaged protected mode, RDTSC : 99 688 473 ins/sec 100% / 100 097 751 76% / 76 281 287
2671 32-bit unpaged protected mode, RDTSC : 98 385 857 ins/sec 102% / 100 510 404 94% / 93 379 536
2672 real mode, RDTSC : 100 087 967 ins/sec 101% / 101 386 138 93% / 93 234 999
2673RDTSC : PASSED
2674 32-bit paged protected mode, Read CR4 : 2 156 102 ins/sec 98% / 2 121 967 17114% / 369 009 009
2675 32-bit pae protected mode, Read CR4 : 2 163 820 ins/sec 98% / 2 133 804 17469% / 377 999 261
2676 64-bit long mode, Read CR4 : 2 164 822 ins/sec 98% / 2 128 698 18875% / 408 619 313
2677 16-bit unpaged protected mode, Read CR4 : 2 162 367 ins/sec 100% / 2 168 508 17132% / 370 477 568
2678 32-bit unpaged protected mode, Read CR4 : 2 163 189 ins/sec 100% / 2 169 808 16768% / 362 734 679
2679 real mode, Read CR4 : 2 162 436 ins/sec 100% / 2 164 914 15551% / 336 288 998
2680Read CR4 : PASSED
2681 real mode, 32-bit IN : 104 649 ins/sec 118% / 123 513 1028% / 1 075 831
2682 real mode, 32-bit OUT : 107 102 ins/sec 115% / 123 660 982% / 1 052 259
2683 real mode, 32-bit IN-to-ring-3 : 105 697 ins/sec 98% / 104 471 201% / 213 216
2684 real mode, 32-bit OUT-to-ring-3 : 105 830 ins/sec 98% / 104 598 198% / 210 495
2685 16-bit unpaged protected mode, 32-bit IN : 104 855 ins/sec 117% / 123 174 1029% / 1 079 591
2686 16-bit unpaged protected mode, 32-bit OUT : 107 529 ins/sec 115% / 124 250 992% / 1 067 053
2687 16-bit unpaged protected mode, 32-bit IN-to-ring-3 : 106 337 ins/sec 103% / 109 565 196% / 209 367
2688 16-bit unpaged protected mode, 32-bit OUT-to-ring-3 : 107 558 ins/sec 100% / 108 237 191% / 206 387
2689 32-bit unpaged protected mode, 32-bit IN : 106 351 ins/sec 116% / 123 584 1016% / 1 081 325
2690 32-bit unpaged protected mode, 32-bit OUT : 106 424 ins/sec 116% / 124 252 995% / 1 059 408
2691 32-bit unpaged protected mode, 32-bit IN-to-ring-3 : 104 035 ins/sec 101% / 105 305 202% / 210 750
2692 32-bit unpaged protected mode, 32-bit OUT-to-ring-3 : 103 831 ins/sec 102% / 106 919 205% / 213 198
2693 32-bit paged protected mode, 32-bit IN : 103 356 ins/sec 119% / 123 870 1041% / 1 076 463
2694 32-bit paged protected mode, 32-bit OUT : 107 177 ins/sec 115% / 124 302 998% / 1 069 655
2695 32-bit paged protected mode, 32-bit IN-to-ring-3 : 104 491 ins/sec 100% / 104 744 200% / 209 264
2696 32-bit paged protected mode, 32-bit OUT-to-ring-3 : 106 603 ins/sec 97% / 103 849 197% / 210 219
2697 32-bit pae protected mode, 32-bit IN : 105 923 ins/sec 115% / 122 759 1041% / 1 103 261
2698 32-bit pae protected mode, 32-bit OUT : 107 083 ins/sec 117% / 126 057 1024% / 1 096 667
2699 32-bit pae protected mode, 32-bit IN-to-ring-3 : 106 114 ins/sec 97% / 103 496 199% / 211 312
2700 32-bit pae protected mode, 32-bit OUT-to-ring-3 : 105 675 ins/sec 96% / 102 096 198% / 209 890
2701 64-bit long mode, 32-bit IN : 105 800 ins/sec 113% / 120 006 1013% / 1 072 116
2702 64-bit long mode, 32-bit OUT : 105 635 ins/sec 113% / 120 375 997% / 1 053 655
2703 64-bit long mode, 32-bit IN-to-ring-3 : 105 274 ins/sec 95% / 100 763 197% / 208 026
2704 64-bit long mode, 32-bit OUT-to-ring-3 : 106 262 ins/sec 94% / 100 749 196% / 209 288
2705NOP I/O Port Access : PASSED
2706 32-bit paged protected mode, 32-bit read : 57 687 ins/sec 119% / 69 136 1197% / 690 548
2707 32-bit paged protected mode, 32-bit write : 57 957 ins/sec 118% / 68 935 1183% / 685 930
2708 32-bit paged protected mode, 32-bit read-to-ring-3 : 57 958 ins/sec 95% / 55 432 276% / 160 505
2709 32-bit paged protected mode, 32-bit write-to-ring-3 : 57 922 ins/sec 100% / 58 340 304% / 176 464
2710 32-bit pae protected mode, 32-bit read : 57 478 ins/sec 119% / 68 453 1141% / 656 159
2711 32-bit pae protected mode, 32-bit write : 57 226 ins/sec 118% / 68 097 1157% / 662 504
2712 32-bit pae protected mode, 32-bit read-to-ring-3 : 57 582 ins/sec 94% / 54 651 268% / 154 867
2713 32-bit pae protected mode, 32-bit write-to-ring-3 : 57 697 ins/sec 100% / 57 750 299% / 173 030
2714 64-bit long mode, 32-bit read : 57 128 ins/sec 118% / 67 779 1071% / 611 949
2715 64-bit long mode, 32-bit write : 57 127 ins/sec 118% / 67 632 1084% / 619 395
2716 64-bit long mode, 32-bit read-to-ring-3 : 57 181 ins/sec 94% / 54 123 265% / 151 937
2717 64-bit long mode, 32-bit write-to-ring-3 : 57 297 ins/sec 99% / 57 286 294% / 168 694
2718 16-bit unpaged protected mode, 32-bit read : 58 827 ins/sec 118% / 69 545 1185% / 697 602
2719 16-bit unpaged protected mode, 32-bit write : 58 678 ins/sec 118% / 69 442 1183% / 694 387
2720 16-bit unpaged protected mode, 32-bit read-to-ring-3 : 57 841 ins/sec 96% / 55 730 275% / 159 163
2721 16-bit unpaged protected mode, 32-bit write-to-ring-3 : 57 855 ins/sec 101% / 58 834 304% / 176 169
2722 32-bit unpaged protected mode, 32-bit read : 58 063 ins/sec 120% / 69 690 1233% / 716 444
2723 32-bit unpaged protected mode, 32-bit write : 57 936 ins/sec 120% / 69 633 1199% / 694 753
2724 32-bit unpaged protected mode, 32-bit read-to-ring-3 : 58 451 ins/sec 96% / 56 183 273% / 159 972
2725 32-bit unpaged protected mode, 32-bit write-to-ring-3 : 58 962 ins/sec 99% / 58 955 298% / 175 936
2726 real mode, 32-bit read : 58 571 ins/sec 118% / 69 478 1160% / 679 917
2727 real mode, 32-bit write : 58 418 ins/sec 118% / 69 320 1185% / 692 513
2728 real mode, 32-bit read-to-ring-3 : 58 072 ins/sec 96% / 55 751 274% / 159 145
2729 real mode, 32-bit write-to-ring-3 : 57 870 ins/sec 101% / 58 755 307% / 178 042
2730NOP MMIO Access : PASSED
2731SUCCESS
2732 * @endverbatim
2733 *
2734 * What we see here is:
2735 *
2736 * - The WinHv API approach is 10 to 12 times slower for exits we can
2737 * handle directly in ring-0 in the VBox AMD-V code.
2738 *
2739 * - The WinHv API approach is 2 to 3 times slower for exits we have to
2740 * go to ring-3 to handle with the VBox AMD-V code.
2741 *
2742 * - By using hypercalls and VID.SYS from ring-0 we gain between
2743 * 13% and 20% over the WinHv API on exits handled in ring-0.
2744 *
2745 * - For exits requiring ring-3 handling are between 6% slower and 3% faster
2746 * than the WinHv API.
2747 *
2748 *
2749 * As a side note, it looks like Hyper-V doesn't let the guest read CR4 but
2750 * triggers exits all the time. This isn't all that important these days since
2751 * OSes like Linux cache the CR4 value specifically to avoid these kinds of exits.
2752 *
2753 *
2754 * @subsubsection subsect_nem_win_benchmarks_bs2t1u1 17134/2018-10-02: Bootsector2-test1
2755 *
2756 * Update on 17134. While expectantly testing a couple of newer builds (17758,
2757 * 17763) hoping for some increases in performance, the numbers turned out
2758 * altogether worse than the June test run. So, we went back to the 1803
2759 * (17134) installation, made sure it was fully up to date (as per 2018-10-02)
2760 * and re-tested.
2761 *
2762 * The numbers had somehow turned significantly worse over the last 3-4 months,
2763 * dropping around 70% for the WinHv API test, more for Hypercalls + VID.
2764 *
2765 * @verbatim
2766TESTING... WinHv API Hypercalls + VID VirtualBox AMD-V *
2767 32-bit paged protected mode, CPUID : 33 270 ins/sec 33 154
2768 real mode, CPUID : 33 534 ins/sec 32 711
2769 [snip]
2770 32-bit paged protected mode, RDTSC : 102 216 011 ins/sec 98 225 419
2771 real mode, RDTSC : 102 492 243 ins/sec 98 225 419
2772 [snip]
2773 32-bit paged protected mode, Read CR4 : 2 096 165 ins/sec 2 123 815
2774 real mode, Read CR4 : 2 081 047 ins/sec 2 075 151
2775 [snip]
2776 32-bit paged protected mode, 32-bit IN : 32 739 ins/sec 33 655
2777 32-bit paged protected mode, 32-bit OUT : 32 702 ins/sec 33 777
2778 32-bit paged protected mode, 32-bit IN-to-ring-3 : 32 579 ins/sec 29 985
2779 32-bit paged protected mode, 32-bit OUT-to-ring-3 : 32 750 ins/sec 29 757
2780 [snip]
2781 32-bit paged protected mode, 32-bit read : 20 042 ins/sec 21 489
2782 32-bit paged protected mode, 32-bit write : 20 036 ins/sec 21 493
2783 32-bit paged protected mode, 32-bit read-to-ring-3 : 19 985 ins/sec 19 143
2784 32-bit paged protected mode, 32-bit write-to-ring-3 : 19 972 ins/sec 19 595
2785
2786 * @endverbatim
2787 *
2788 * Suspects are security updates and/or microcode updates installed since then.
2789 * Given that the RDTSC and CR4 numbers are reasonably unchanges, it seems that
2790 * the Hyper-V core loop (in hvax64.exe) aren't affected. Our ring-0 runloop
2791 * is equally affected as the ring-3 based runloop, so it cannot be ring
2792 * switching as such (unless the ring-0 loop is borked and we didn't notice yet).
2793 *
2794 * The issue is probably in the thread / process switching area, could be
2795 * something special for hyper-V interrupt delivery or worker thread switching.
2796 *
2797 * Really wish this thread ping-pong going on in VID.SYS could be eliminated!
2798 *
2799 *
2800 * @subsubsection subsect_nem_win_benchmarks_bs2t1u2 17763: Bootsector2-test1
2801 *
2802 * Some preliminary numbers for build 17763 on the 3.4 GHz AMD 1950X, the second
2803 * column will improve we get time to have a look the register page.
2804 *
2805 * There is a 50% performance loss here compared to the June numbers with
2806 * build 17134. The RDTSC numbers hits that it isn't in the Hyper-V core
2807 * (hvax64.exe), but something on the NT side.
2808 *
2809 * Clearing bit 20 in nt!KiSpeculationFeatures speeds things up (i.e. changing
2810 * the dword from 0x00300065 to 0x00200065 in windbg). This is checked by
2811 * nt!KePrepareToDispatchVirtualProcessor, making it a no-op if the flag is
2812 * clear. winhvr!WinHvpVpDispatchLoop call that function before making
2813 * hypercall 0xc2, which presumably does the heavy VCpu lifting in hvcax64.exe.
2814 *
2815 * @verbatim
2816TESTING... WinHv API Hypercalls + VID clr(bit-20) + WinHv API
2817 32-bit paged protected mode, CPUID : 54 145 ins/sec 51 436 130 076
2818 real mode, CPUID : 54 178 ins/sec 51 713 130 449
2819 [snip]
2820 32-bit paged protected mode, RDTSC : 98 927 639 ins/sec 100 254 552 100 549 882
2821 real mode, RDTSC : 99 601 206 ins/sec 100 886 699 100 470 957
2822 [snip]
2823 32-bit paged protected mode, 32-bit IN : 54 621 ins/sec 51 524 128 294
2824 32-bit paged protected mode, 32-bit OUT : 54 870 ins/sec 51 671 129 397
2825 32-bit paged protected mode, 32-bit IN-to-ring-3 : 54 624 ins/sec 43 964 127 874
2826 32-bit paged protected mode, 32-bit OUT-to-ring-3 : 54 803 ins/sec 44 087 129 443
2827 [snip]
2828 32-bit paged protected mode, 32-bit read : 28 230 ins/sec 34 042 48 113
2829 32-bit paged protected mode, 32-bit write : 27 962 ins/sec 34 050 48 069
2830 32-bit paged protected mode, 32-bit read-to-ring-3 : 27 841 ins/sec 28 397 48 146
2831 32-bit paged protected mode, 32-bit write-to-ring-3 : 27 896 ins/sec 29 455 47 970
2832 * @endverbatim
2833 *
2834 *
2835 * @subsubsection subsect_nem_win_benchmarks_w2k 17134/2018-06-22: Windows 2000 Boot & Shutdown
2836 *
2837 * Timing the startup and automatic shutdown of a Windows 2000 SP4 guest serves
2838 * as a real world benchmark and example of why exit performance is import. When
2839 * Windows 2000 boots up is doing a lot of VGA redrawing of the boot animation,
2840 * which is very costly. Not having installed guest additions leaves it in a VGA
2841 * mode after the bootup sequence is done, keep up the screen access expenses,
2842 * though the graphics driver more economical than the bootvid code.
2843 *
2844 * The VM was configured to automatically logon. A startup script was installed
2845 * to perform the automatic shuting down and powering off the VM (thru
2846 * vts_shutdown.exe -f -p). An offline snapshot of the VM was taken an restored
2847 * before each test run. The test time run time is calculated from the monotonic
2848 * VBox.log timestamps, starting with the state change to 'RUNNING' and stopping
2849 * at 'POWERING_OFF'.
2850 *
2851 * The host OS and VirtualBox build is the same as for the bootsector2-test1
2852 * scenario.
2853 *
2854 * Results:
2855 *
2856 * - WinHv API for all but physical page mappings:
2857 * 32 min 12.19 seconds
2858 *
2859 * - The default NEM/win configuration where we put the main execution loop
2860 * in ring-0, using hypercalls when we can and VID for managing execution:
2861 * 3 min 23.18 seconds
2862 *
2863 * - Regular VirtualBox using AMD-V directly, hyper-V is disabled, main
2864 * execution loop in ring-0:
2865 * 58.09 seconds
2866 *
2867 * - WinHv API with exit history based optimizations:
2868 * 58.66 seconds
2869 *
2870 * - Hypercall + VID.SYS with exit history base optimizations:
2871 * 58.94 seconds
2872 *
2873 * With a well above average machine needing over half an hour for booting a
2874 * nearly 20 year old guest kind of says it all. The 13%-20% exit performance
2875 * increase we get by using hypercalls and VID.SYS directly pays off a lot here.
2876 * The 3m23s is almost acceptable in comparison to the half an hour.
2877 *
2878 * The similarity between the last three results strongly hits at windows 2000
2879 * doing a lot of waiting during boot and shutdown and isn't the best testcase
2880 * once a basic performance level is reached.
2881 *
2882 *
2883 * @subsubsection subsection_iem_win_benchmarks_deb9_nat Debian 9 NAT performance
2884 *
2885 * This benchmark is about network performance over NAT from a 64-bit Debian 9
2886 * VM with a single CPU. For network performance measurements, we use our own
2887 * NetPerf tool (ValidationKit/utils/network/NetPerf.cpp) to measure latency
2888 * and throughput.
2889 *
2890 * The setups, builds and configurations are as in the previous benchmarks
2891 * (release r123172 on 1950X running 64-bit W10/17134 (2016-06-xx). Please note
2892 * that the exit optimizations hasn't yet been in tuned with NetPerf in mind.
2893 *
2894 * The NAT network setup was selected here since it's the default one and the
2895 * slowest one. There is quite a bit of IPC with worker threads and packet
2896 * processing involved.
2897 *
2898 * Latency test is first up. This is a classic back and forth between the two
2899 * NetPerf instances, where the key measurement is the roundrip latency. The
2900 * values here are the lowest result over 3-6 runs.
2901 *
2902 * Against host system:
2903 * - 152 258 ns/roundtrip - 100% - regular VirtualBox SVM
2904 * - 271 059 ns/roundtrip - 178% - Hypercalls + VID.SYS in ring-0 with exit optimizations.
2905 * - 280 149 ns/roundtrip - 184% - Hypercalls + VID.SYS in ring-0
2906 * - 317 735 ns/roundtrip - 209% - Win HV API with exit optimizations.
2907 * - 342 440 ns/roundtrip - 225% - Win HV API
2908 *
2909 * Against a remote Windows 10 system over a 10Gbps link:
2910 * - 243 969 ns/roundtrip - 100% - regular VirtualBox SVM
2911 * - 384 427 ns/roundtrip - 158% - Win HV API with exit optimizations.
2912 * - 402 411 ns/roundtrip - 165% - Hypercalls + VID.SYS in ring-0
2913 * - 406 313 ns/roundtrip - 167% - Win HV API
2914 * - 413 160 ns/roundtrip - 169% - Hypercalls + VID.SYS in ring-0 with exit optimizations.
2915 *
2916 * What we see here is:
2917 *
2918 * - Consistent and signficant latency increase using Hyper-V compared
2919 * to directly harnessing AMD-V ourselves.
2920 *
2921 * - When talking to the host, it's clear that the hypercalls + VID.SYS
2922 * in ring-0 method pays off.
2923 *
2924 * - When talking to a different host, the numbers are closer and it
2925 * is not longer clear which Hyper-V execution method is better.
2926 *
2927 *
2928 * Throughput benchmarks are performed by one side pushing data full throttle
2929 * for 10 seconds (minus a 1 second at each end of the test), then reversing
2930 * the roles and measuring it in the other direction. The tests ran 3-5 times
2931 * and below are the highest and lowest results in each direction.
2932 *
2933 * Receiving from host system:
2934 * - Regular VirtualBox SVM:
2935 * Max: 96 907 549 bytes/s - 100%
2936 * Min: 86 912 095 bytes/s - 100%
2937 * - Hypercalls + VID.SYS in ring-0:
2938 * Max: 84 036 544 bytes/s - 87%
2939 * Min: 64 978 112 bytes/s - 75%
2940 * - Hypercalls + VID.SYS in ring-0 with exit optimizations:
2941 * Max: 77 760 699 bytes/s - 80%
2942 * Min: 72 677 171 bytes/s - 84%
2943 * - Win HV API with exit optimizations:
2944 * Max: 64 465 905 bytes/s - 67%
2945 * Min: 62 286 369 bytes/s - 72%
2946 * - Win HV API:
2947 * Max: 62 466 631 bytes/s - 64%
2948 * Min: 61 362 782 bytes/s - 70%
2949 *
2950 * Sending to the host system:
2951 * - Regular VirtualBox SVM:
2952 * Max: 87 728 652 bytes/s - 100%
2953 * Min: 86 923 198 bytes/s - 100%
2954 * - Hypercalls + VID.SYS in ring-0:
2955 * Max: 84 280 749 bytes/s - 96%
2956 * Min: 78 369 842 bytes/s - 90%
2957 * - Hypercalls + VID.SYS in ring-0 with exit optimizations:
2958 * Max: 84 119 932 bytes/s - 96%
2959 * Min: 77 396 811 bytes/s - 89%
2960 * - Win HV API:
2961 * Max: 81 714 377 bytes/s - 93%
2962 * Min: 78 697 419 bytes/s - 91%
2963 * - Win HV API with exit optimizations:
2964 * Max: 80 502 488 bytes/s - 91%
2965 * Min: 71 164 978 bytes/s - 82%
2966 *
2967 * Receiving from a remote Windows 10 system over a 10Gbps link:
2968 * - Hypercalls + VID.SYS in ring-0:
2969 * Max: 115 346 922 bytes/s - 136%
2970 * Min: 112 912 035 bytes/s - 137%
2971 * - Regular VirtualBox SVM:
2972 * Max: 84 517 504 bytes/s - 100%
2973 * Min: 82 597 049 bytes/s - 100%
2974 * - Hypercalls + VID.SYS in ring-0 with exit optimizations:
2975 * Max: 77 736 251 bytes/s - 92%
2976 * Min: 73 813 784 bytes/s - 89%
2977 * - Win HV API with exit optimizations:
2978 * Max: 63 035 587 bytes/s - 75%
2979 * Min: 57 538 380 bytes/s - 70%
2980 * - Win HV API:
2981 * Max: 62 279 185 bytes/s - 74%
2982 * Min: 56 813 866 bytes/s - 69%
2983 *
2984 * Sending to a remote Windows 10 system over a 10Gbps link:
2985 * - Win HV API with exit optimizations:
2986 * Max: 116 502 357 bytes/s - 103%
2987 * Min: 49 046 550 bytes/s - 59%
2988 * - Regular VirtualBox SVM:
2989 * Max: 113 030 991 bytes/s - 100%
2990 * Min: 83 059 511 bytes/s - 100%
2991 * - Hypercalls + VID.SYS in ring-0:
2992 * Max: 106 435 031 bytes/s - 94%
2993 * Min: 47 253 510 bytes/s - 57%
2994 * - Hypercalls + VID.SYS in ring-0 with exit optimizations:
2995 * Max: 94 842 287 bytes/s - 84%
2996 * Min: 68 362 172 bytes/s - 82%
2997 * - Win HV API:
2998 * Max: 65 165 225 bytes/s - 58%
2999 * Min: 47 246 573 bytes/s - 57%
3000 *
3001 * What we see here is:
3002 *
3003 * - Again consistent numbers when talking to the host. Showing that the
3004 * ring-0 approach is preferable to the ring-3 one.
3005 *
3006 * - Again when talking to a remote host, things get more difficult to
3007 * make sense of. The spread is larger and direct AMD-V gets beaten by
3008 * a different the Hyper-V approaches in each direction.
3009 *
3010 * - However, if we treat the first entry (remote host) as weird spikes, the
3011 * other entries are consistently worse compared to direct AMD-V. For the
3012 * send case we get really bad results for WinHV.
3013 *
3014 */
3015
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