VirtualBox

source: vbox/trunk/src/VBox/VMM/VMMR3/PGM.cpp@ 73770

Last change on this file since 73770 was 73324, checked in by vboxsync, 6 years ago

PGM: Introduced a special shadow paging mode for NEM that translates to minimal unnecessary work. bugref:9044

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1/* $Id: PGM.cpp 73324 2018-07-23 14:06:55Z vboxsync $ */
2/** @file
3 * PGM - Page Manager and Monitor. (Mixing stuff here, not good?)
4 */
5
6/*
7 * Copyright (C) 2006-2017 Oracle Corporation
8 *
9 * This file is part of VirtualBox Open Source Edition (OSE), as
10 * available from http://www.virtualbox.org. This file is free software;
11 * you can redistribute it and/or modify it under the terms of the GNU
12 * General Public License (GPL) as published by the Free Software
13 * Foundation, in version 2 as it comes in the "COPYING" file of the
14 * VirtualBox OSE distribution. VirtualBox OSE is distributed in the
15 * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind.
16 */
17
18
19/** @page pg_pgm PGM - The Page Manager and Monitor
20 *
21 * @sa @ref grp_pgm
22 * @subpage pg_pgm_pool
23 * @subpage pg_pgm_phys
24 *
25 *
26 * @section sec_pgm_modes Paging Modes
27 *
28 * There are three memory contexts: Host Context (HC), Guest Context (GC)
29 * and intermediate context. When talking about paging HC can also be referred
30 * to as "host paging", and GC referred to as "shadow paging".
31 *
32 * We define three basic paging modes: 32-bit, PAE and AMD64. The host paging mode
33 * is defined by the host operating system. The mode used in the shadow paging mode
34 * depends on the host paging mode and what the mode the guest is currently in. The
35 * following relation between the two is defined:
36 *
37 * @verbatim
38 Host > 32-bit | PAE | AMD64 |
39 Guest | | | |
40 ==v================================
41 32-bit 32-bit PAE PAE
42 -------|--------|--------|--------|
43 PAE PAE PAE PAE
44 -------|--------|--------|--------|
45 AMD64 AMD64 AMD64 AMD64
46 -------|--------|--------|--------| @endverbatim
47 *
48 * All configuration except those in the diagonal (upper left) are expected to
49 * require special effort from the switcher (i.e. a bit slower).
50 *
51 *
52 *
53 *
54 * @section sec_pgm_shw The Shadow Memory Context
55 *
56 *
57 * [..]
58 *
59 * Because of guest context mappings requires PDPT and PML4 entries to allow
60 * writing on AMD64, the two upper levels will have fixed flags whatever the
61 * guest is thinking of using there. So, when shadowing the PD level we will
62 * calculate the effective flags of PD and all the higher levels. In legacy
63 * PAE mode this only applies to the PWT and PCD bits (the rest are
64 * ignored/reserved/MBZ). We will ignore those bits for the present.
65 *
66 *
67 *
68 * @section sec_pgm_int The Intermediate Memory Context
69 *
70 * The world switch goes thru an intermediate memory context which purpose it is
71 * to provide different mappings of the switcher code. All guest mappings are also
72 * present in this context.
73 *
74 * The switcher code is mapped at the same location as on the host, at an
75 * identity mapped location (physical equals virtual address), and at the
76 * hypervisor location. The identity mapped location is for when the world
77 * switches that involves disabling paging.
78 *
79 * PGM maintain page tables for 32-bit, PAE and AMD64 paging modes. This
80 * simplifies switching guest CPU mode and consistency at the cost of more
81 * code to do the work. All memory use for those page tables is located below
82 * 4GB (this includes page tables for guest context mappings).
83 *
84 * Note! The intermediate memory context is also used for 64-bit guest
85 * execution on 32-bit hosts. Because we need to load 64-bit registers
86 * prior to switching to guest context, we need to be in 64-bit mode
87 * first. So, HM has some 64-bit worker routines in VMMRC.rc that get
88 * invoked via the special world switcher code in LegacyToAMD64.asm.
89 *
90 *
91 * @subsection subsec_pgm_int_gc Guest Context Mappings
92 *
93 * During assignment and relocation of a guest context mapping the intermediate
94 * memory context is used to verify the new location.
95 *
96 * Guest context mappings are currently restricted to below 4GB, for reasons
97 * of simplicity. This may change when we implement AMD64 support.
98 *
99 *
100 *
101 *
102 * @section sec_pgm_misc Misc
103 *
104 *
105 * @subsection sec_pgm_misc_A20 The A20 Gate
106 *
107 * PGM implements the A20 gate masking when translating a virtual guest address
108 * into a physical address for CPU access, i.e. PGMGstGetPage (and friends) and
109 * the code reading the guest page table entries during shadowing. The masking
110 * is done consistenly for all CPU modes, paged ones included. Large pages are
111 * also masked correctly. (On current CPUs, experiments indicates that AMD does
112 * not apply A20M in paged modes and intel only does it for the 2nd MB of
113 * memory.)
114 *
115 * The A20 gate implementation is per CPU core. It can be configured on a per
116 * core basis via the keyboard device and PC architecture device. This is
117 * probably not exactly how real CPUs do it, but SMP and A20 isn't a place where
118 * guest OSes try pushing things anyway, so who cares. (On current real systems
119 * the A20M signal is probably only sent to the boot CPU and it affects all
120 * thread and probably all cores in that package.)
121 *
122 * The keyboard device and the PC architecture device doesn't OR their A20
123 * config bits together, rather they are currently implemented such that they
124 * mirror the CPU state. So, flipping the bit in either of them will change the
125 * A20 state. (On real hardware the bits of the two devices should probably be
126 * ORed together to indicate enabled, i.e. both needs to be cleared to disable
127 * A20 masking.)
128 *
129 * The A20 state will change immediately, transmeta fashion. There is no delays
130 * due to buses, wiring or other physical stuff. (On real hardware there are
131 * normally delays, the delays differs between the two devices and probably also
132 * between chipsets and CPU generations. Note that it's said that transmeta CPUs
133 * does the change immediately like us, they apparently intercept/handles the
134 * port accesses in microcode. Neat.)
135 *
136 * @sa http://en.wikipedia.org/wiki/A20_line#The_80286_and_the_high_memory_area
137 *
138 *
139 * @subsection subsec_pgm_misc_diff Differences Between Legacy PAE and Long Mode PAE
140 *
141 * The differences between legacy PAE and long mode PAE are:
142 * -# PDPE bits 1, 2, 5 and 6 are defined differently. In leagcy mode they are
143 * all marked down as must-be-zero, while in long mode 1, 2 and 5 have the
144 * usual meanings while 6 is ignored (AMD). This means that upon switching to
145 * legacy PAE mode we'll have to clear these bits and when going to long mode
146 * they must be set. This applies to both intermediate and shadow contexts,
147 * however we don't need to do it for the intermediate one since we're
148 * executing with CR0.WP at that time.
149 * -# CR3 allows a 32-byte aligned address in legacy mode, while in long mode
150 * a page aligned one is required.
151 *
152 *
153 * @section sec_pgm_handlers Access Handlers
154 *
155 * Placeholder.
156 *
157 *
158 * @subsection sec_pgm_handlers_phys Physical Access Handlers
159 *
160 * Placeholder.
161 *
162 *
163 * @subsection sec_pgm_handlers_virt Virtual Access Handlers
164 *
165 * We currently implement three types of virtual access handlers: ALL, WRITE
166 * and HYPERVISOR (WRITE). See PGMVIRTHANDLERKIND for some more details.
167 *
168 * The HYPERVISOR access handlers is kept in a separate tree since it doesn't apply
169 * to physical pages (PGMTREES::HyperVirtHandlers) and only needs to be consulted in
170 * a special \#PF case. The ALL and WRITE are in the PGMTREES::VirtHandlers tree, the
171 * rest of this section is going to be about these handlers.
172 *
173 * We'll go thru the life cycle of a handler and try make sense of it all, don't know
174 * how successful this is gonna be...
175 *
176 * 1. A handler is registered thru the PGMR3HandlerVirtualRegister and
177 * PGMHandlerVirtualRegisterEx APIs. We check for conflicting virtual handlers
178 * and create a new node that is inserted into the AVL tree (range key). Then
179 * a full PGM resync is flagged (clear pool, sync cr3, update virtual bit of PGMPAGE).
180 *
181 * 2. The following PGMSyncCR3/SyncCR3 operation will first make invoke HandlerVirtualUpdate.
182 *
183 * 2a. HandlerVirtualUpdate will will lookup all the pages covered by virtual handlers
184 * via the current guest CR3 and update the physical page -> virtual handler
185 * translation. Needless to say, this doesn't exactly scale very well. If any changes
186 * are detected, it will flag a virtual bit update just like we did on registration.
187 * PGMPHYS pages with changes will have their virtual handler state reset to NONE.
188 *
189 * 2b. The virtual bit update process will iterate all the pages covered by all the
190 * virtual handlers and update the PGMPAGE virtual handler state to the max of all
191 * virtual handlers on that page.
192 *
193 * 2c. Back in SyncCR3 we will now flush the entire shadow page cache to make sure
194 * we don't miss any alias mappings of the monitored pages.
195 *
196 * 2d. SyncCR3 will then proceed with syncing the CR3 table.
197 *
198 * 3. \#PF(np,read) on a page in the range. This will cause it to be synced
199 * read-only and resumed if it's a WRITE handler. If it's an ALL handler we
200 * will call the handlers like in the next step. If the physical mapping has
201 * changed we will - some time in the future - perform a handler callback
202 * (optional) and update the physical -> virtual handler cache.
203 *
204 * 4. \#PF(,write) on a page in the range. This will cause the handler to
205 * be invoked.
206 *
207 * 5. The guest invalidates the page and changes the physical backing or
208 * unmaps it. This should cause the invalidation callback to be invoked
209 * (it might not yet be 100% perfect). Exactly what happens next... is
210 * this where we mess up and end up out of sync for a while?
211 *
212 * 6. The handler is deregistered by the client via PGMHandlerVirtualDeregister.
213 * We will then set all PGMPAGEs in the physical -> virtual handler cache for
214 * this handler to NONE and trigger a full PGM resync (basically the same
215 * as int step 1). Which means 2 is executed again.
216 *
217 *
218 * @subsubsection sub_sec_pgm_handler_virt_todo TODOs
219 *
220 * There is a bunch of things that needs to be done to make the virtual handlers
221 * work 100% correctly and work more efficiently.
222 *
223 * The first bit hasn't been implemented yet because it's going to slow the
224 * whole mess down even more, and besides it seems to be working reliably for
225 * our current uses. OTOH, some of the optimizations might end up more or less
226 * implementing the missing bits, so we'll see.
227 *
228 * On the optimization side, the first thing to do is to try avoid unnecessary
229 * cache flushing. Then try team up with the shadowing code to track changes
230 * in mappings by means of access to them (shadow in), updates to shadows pages,
231 * invlpg, and shadow PT discarding (perhaps).
232 *
233 * Some idea that have popped up for optimization for current and new features:
234 * - bitmap indicating where there are virtual handlers installed.
235 * (4KB => 2**20 pages, page 2**12 => covers 32-bit address space 1:1!)
236 * - Further optimize this by min/max (needs min/max avl getters).
237 * - Shadow page table entry bit (if any left)?
238 *
239 */
240
241
242/** @page pg_pgm_phys PGM Physical Guest Memory Management
243 *
244 *
245 * Objectives:
246 * - Guest RAM over-commitment using memory ballooning,
247 * zero pages and general page sharing.
248 * - Moving or mirroring a VM onto a different physical machine.
249 *
250 *
251 * @section sec_pgmPhys_Definitions Definitions
252 *
253 * Allocation chunk - A RTR0MemObjAllocPhysNC object and the tracking
254 * machinery associated with it.
255 *
256 *
257 *
258 *
259 * @section sec_pgmPhys_AllocPage Allocating a page.
260 *
261 * Initially we map *all* guest memory to the (per VM) zero page, which
262 * means that none of the read functions will cause pages to be allocated.
263 *
264 * Exception, access bit in page tables that have been shared. This must
265 * be handled, but we must also make sure PGMGst*Modify doesn't make
266 * unnecessary modifications.
267 *
268 * Allocation points:
269 * - PGMPhysSimpleWriteGCPhys and PGMPhysWrite.
270 * - Replacing a zero page mapping at \#PF.
271 * - Replacing a shared page mapping at \#PF.
272 * - ROM registration (currently MMR3RomRegister).
273 * - VM restore (pgmR3Load).
274 *
275 * For the first three it would make sense to keep a few pages handy
276 * until we've reached the max memory commitment for the VM.
277 *
278 * For the ROM registration, we know exactly how many pages we need
279 * and will request these from ring-0. For restore, we will save
280 * the number of non-zero pages in the saved state and allocate
281 * them up front. This would allow the ring-0 component to refuse
282 * the request if the isn't sufficient memory available for VM use.
283 *
284 * Btw. for both ROM and restore allocations we won't be requiring
285 * zeroed pages as they are going to be filled instantly.
286 *
287 *
288 * @section sec_pgmPhys_FreePage Freeing a page
289 *
290 * There are a few points where a page can be freed:
291 * - After being replaced by the zero page.
292 * - After being replaced by a shared page.
293 * - After being ballooned by the guest additions.
294 * - At reset.
295 * - At restore.
296 *
297 * When freeing one or more pages they will be returned to the ring-0
298 * component and replaced by the zero page.
299 *
300 * The reasoning for clearing out all the pages on reset is that it will
301 * return us to the exact same state as on power on, and may thereby help
302 * us reduce the memory load on the system. Further it might have a
303 * (temporary) positive influence on memory fragmentation (@see subsec_pgmPhys_Fragmentation).
304 *
305 * On restore, as mention under the allocation topic, pages should be
306 * freed / allocated depending on how many is actually required by the
307 * new VM state. The simplest approach is to do like on reset, and free
308 * all non-ROM pages and then allocate what we need.
309 *
310 * A measure to prevent some fragmentation, would be to let each allocation
311 * chunk have some affinity towards the VM having allocated the most pages
312 * from it. Also, try make sure to allocate from allocation chunks that
313 * are almost full. Admittedly, both these measures might work counter to
314 * our intentions and its probably not worth putting a lot of effort,
315 * cpu time or memory into this.
316 *
317 *
318 * @section sec_pgmPhys_SharePage Sharing a page
319 *
320 * The basic idea is that there there will be a idle priority kernel
321 * thread walking the non-shared VM pages hashing them and looking for
322 * pages with the same checksum. If such pages are found, it will compare
323 * them byte-by-byte to see if they actually are identical. If found to be
324 * identical it will allocate a shared page, copy the content, check that
325 * the page didn't change while doing this, and finally request both the
326 * VMs to use the shared page instead. If the page is all zeros (special
327 * checksum and byte-by-byte check) it will request the VM that owns it
328 * to replace it with the zero page.
329 *
330 * To make this efficient, we will have to make sure not to try share a page
331 * that will change its contents soon. This part requires the most work.
332 * A simple idea would be to request the VM to write monitor the page for
333 * a while to make sure it isn't modified any time soon. Also, it may
334 * make sense to skip pages that are being write monitored since this
335 * information is readily available to the thread if it works on the
336 * per-VM guest memory structures (presently called PGMRAMRANGE).
337 *
338 *
339 * @section sec_pgmPhys_Fragmentation Fragmentation Concerns and Counter Measures
340 *
341 * The pages are organized in allocation chunks in ring-0, this is a necessity
342 * if we wish to have an OS agnostic approach to this whole thing. (On Linux we
343 * could easily work on a page-by-page basis if we liked. Whether this is possible
344 * or efficient on NT I don't quite know.) Fragmentation within these chunks may
345 * become a problem as part of the idea here is that we wish to return memory to
346 * the host system.
347 *
348 * For instance, starting two VMs at the same time, they will both allocate the
349 * guest memory on-demand and if permitted their page allocations will be
350 * intermixed. Shut down one of the two VMs and it will be difficult to return
351 * any memory to the host system because the page allocation for the two VMs are
352 * mixed up in the same allocation chunks.
353 *
354 * To further complicate matters, when pages are freed because they have been
355 * ballooned or become shared/zero the whole idea is that the page is supposed
356 * to be reused by another VM or returned to the host system. This will cause
357 * allocation chunks to contain pages belonging to different VMs and prevent
358 * returning memory to the host when one of those VM shuts down.
359 *
360 * The only way to really deal with this problem is to move pages. This can
361 * either be done at VM shutdown and or by the idle priority worker thread
362 * that will be responsible for finding sharable/zero pages. The mechanisms
363 * involved for coercing a VM to move a page (or to do it for it) will be
364 * the same as when telling it to share/zero a page.
365 *
366 *
367 * @section sec_pgmPhys_Tracking Tracking Structures And Their Cost
368 *
369 * There's a difficult balance between keeping the per-page tracking structures
370 * (global and guest page) easy to use and keeping them from eating too much
371 * memory. We have limited virtual memory resources available when operating in
372 * 32-bit kernel space (on 64-bit there'll it's quite a different story). The
373 * tracking structures will be attempted designed such that we can deal with up
374 * to 32GB of memory on a 32-bit system and essentially unlimited on 64-bit ones.
375 *
376 *
377 * @subsection subsec_pgmPhys_Tracking_Kernel Kernel Space
378 *
379 * @see pg_GMM
380 *
381 * @subsection subsec_pgmPhys_Tracking_PerVM Per-VM
382 *
383 * Fixed info is the physical address of the page (HCPhys) and the page id
384 * (described above). Theoretically we'll need 48(-12) bits for the HCPhys part.
385 * Today we've restricting ourselves to 40(-12) bits because this is the current
386 * restrictions of all AMD64 implementations (I think Barcelona will up this
387 * to 48(-12) bits, not that it really matters) and I needed the bits for
388 * tracking mappings of a page. 48-12 = 36. That leaves 28 bits, which means a
389 * decent range for the page id: 2^(28+12) = 1024TB.
390 *
391 * In additions to these, we'll have to keep maintaining the page flags as we
392 * currently do. Although it wouldn't harm to optimize these quite a bit, like
393 * for instance the ROM shouldn't depend on having a write handler installed
394 * in order for it to become read-only. A RO/RW bit should be considered so
395 * that the page syncing code doesn't have to mess about checking multiple
396 * flag combinations (ROM || RW handler || write monitored) in order to
397 * figure out how to setup a shadow PTE. But this of course, is second
398 * priority at present. Current this requires 12 bits, but could probably
399 * be optimized to ~8.
400 *
401 * Then there's the 24 bits used to track which shadow page tables are
402 * currently mapping a page for the purpose of speeding up physical
403 * access handlers, and thereby the page pool cache. More bit for this
404 * purpose wouldn't hurt IIRC.
405 *
406 * Then there is a new bit in which we need to record what kind of page
407 * this is, shared, zero, normal or write-monitored-normal. This'll
408 * require 2 bits. One bit might be needed for indicating whether a
409 * write monitored page has been written to. And yet another one or
410 * two for tracking migration status. 3-4 bits total then.
411 *
412 * Whatever is left will can be used to record the sharabilitiy of a
413 * page. The page checksum will not be stored in the per-VM table as
414 * the idle thread will not be permitted to do modifications to it.
415 * It will instead have to keep its own working set of potentially
416 * shareable pages and their check sums and stuff.
417 *
418 * For the present we'll keep the current packing of the
419 * PGMRAMRANGE::aHCPhys to keep the changes simple, only of course,
420 * we'll have to change it to a struct with a total of 128-bits at
421 * our disposal.
422 *
423 * The initial layout will be like this:
424 * @verbatim
425 RTHCPHYS HCPhys; The current stuff.
426 63:40 Current shadow PT tracking stuff.
427 39:12 The physical page frame number.
428 11:0 The current flags.
429 uint32_t u28PageId : 28; The page id.
430 uint32_t u2State : 2; The page state { zero, shared, normal, write monitored }.
431 uint32_t fWrittenTo : 1; Whether a write monitored page was written to.
432 uint32_t u1Reserved : 1; Reserved for later.
433 uint32_t u32Reserved; Reserved for later, mostly sharing stats.
434 @endverbatim
435 *
436 * The final layout will be something like this:
437 * @verbatim
438 RTHCPHYS HCPhys; The current stuff.
439 63:48 High page id (12+).
440 47:12 The physical page frame number.
441 11:0 Low page id.
442 uint32_t fReadOnly : 1; Whether it's readonly page (rom or monitored in some way).
443 uint32_t u3Type : 3; The page type {RESERVED, MMIO, MMIO2, ROM, shadowed ROM, RAM}.
444 uint32_t u2PhysMon : 2; Physical access handler type {none, read, write, all}.
445 uint32_t u2VirtMon : 2; Virtual access handler type {none, read, write, all}..
446 uint32_t u2State : 2; The page state { zero, shared, normal, write monitored }.
447 uint32_t fWrittenTo : 1; Whether a write monitored page was written to.
448 uint32_t u20Reserved : 20; Reserved for later, mostly sharing stats.
449 uint32_t u32Tracking; The shadow PT tracking stuff, roughly.
450 @endverbatim
451 *
452 * Cost wise, this means we'll double the cost for guest memory. There isn't anyway
453 * around that I'm afraid. It means that the cost of dealing out 32GB of memory
454 * to one or more VMs is: (32GB >> PAGE_SHIFT) * 16 bytes, or 128MBs. Or another
455 * example, the VM heap cost when assigning 1GB to a VM will be: 4MB.
456 *
457 * A couple of cost examples for the total cost per-VM + kernel.
458 * 32-bit Windows and 32-bit linux:
459 * 1GB guest ram, 256K pages: 4MB + 2MB(+) = 6MB
460 * 4GB guest ram, 1M pages: 16MB + 8MB(+) = 24MB
461 * 32GB guest ram, 8M pages: 128MB + 64MB(+) = 192MB
462 * 64-bit Windows and 64-bit linux:
463 * 1GB guest ram, 256K pages: 4MB + 3MB(+) = 7MB
464 * 4GB guest ram, 1M pages: 16MB + 12MB(+) = 28MB
465 * 32GB guest ram, 8M pages: 128MB + 96MB(+) = 224MB
466 *
467 * UPDATE - 2007-09-27:
468 * Will need a ballooned flag/state too because we cannot
469 * trust the guest 100% and reporting the same page as ballooned more
470 * than once will put the GMM off balance.
471 *
472 *
473 * @section sec_pgmPhys_Serializing Serializing Access
474 *
475 * Initially, we'll try a simple scheme:
476 *
477 * - The per-VM RAM tracking structures (PGMRAMRANGE) is only modified
478 * by the EMT thread of that VM while in the pgm critsect.
479 * - Other threads in the VM process that needs to make reliable use of
480 * the per-VM RAM tracking structures will enter the critsect.
481 * - No process external thread or kernel thread will ever try enter
482 * the pgm critical section, as that just won't work.
483 * - The idle thread (and similar threads) doesn't not need 100% reliable
484 * data when performing it tasks as the EMT thread will be the one to
485 * do the actual changes later anyway. So, as long as it only accesses
486 * the main ram range, it can do so by somehow preventing the VM from
487 * being destroyed while it works on it...
488 *
489 * - The over-commitment management, including the allocating/freeing
490 * chunks, is serialized by a ring-0 mutex lock (a fast one since the
491 * more mundane mutex implementation is broken on Linux).
492 * - A separate mutex is protecting the set of allocation chunks so
493 * that pages can be shared or/and freed up while some other VM is
494 * allocating more chunks. This mutex can be take from under the other
495 * one, but not the other way around.
496 *
497 *
498 * @section sec_pgmPhys_Request VM Request interface
499 *
500 * When in ring-0 it will become necessary to send requests to a VM so it can
501 * for instance move a page while defragmenting during VM destroy. The idle
502 * thread will make use of this interface to request VMs to setup shared
503 * pages and to perform write monitoring of pages.
504 *
505 * I would propose an interface similar to the current VMReq interface, similar
506 * in that it doesn't require locking and that the one sending the request may
507 * wait for completion if it wishes to. This shouldn't be very difficult to
508 * realize.
509 *
510 * The requests themselves are also pretty simple. They are basically:
511 * -# Check that some precondition is still true.
512 * -# Do the update.
513 * -# Update all shadow page tables involved with the page.
514 *
515 * The 3rd step is identical to what we're already doing when updating a
516 * physical handler, see pgmHandlerPhysicalSetRamFlagsAndFlushShadowPTs.
517 *
518 *
519 *
520 * @section sec_pgmPhys_MappingCaches Mapping Caches
521 *
522 * In order to be able to map in and out memory and to be able to support
523 * guest with more RAM than we've got virtual address space, we'll employing
524 * a mapping cache. Normally ring-0 and ring-3 can share the same cache,
525 * however on 32-bit darwin the ring-0 code is running in a different memory
526 * context and therefore needs a separate cache. In raw-mode context we also
527 * need a separate cache. The 32-bit darwin mapping cache and the one for
528 * raw-mode context share a lot of code, see PGMRZDYNMAP.
529 *
530 *
531 * @subsection subsec_pgmPhys_MappingCaches_R3 Ring-3
532 *
533 * We've considered implementing the ring-3 mapping cache page based but found
534 * that this was bother some when one had to take into account TLBs+SMP and
535 * portability (missing the necessary APIs on several platforms). There were
536 * also some performance concerns with this approach which hadn't quite been
537 * worked out.
538 *
539 * Instead, we'll be mapping allocation chunks into the VM process. This simplifies
540 * matters greatly quite a bit since we don't need to invent any new ring-0 stuff,
541 * only some minor RTR0MEMOBJ mapping stuff. The main concern here is that mapping
542 * compared to the previous idea is that mapping or unmapping a 1MB chunk is more
543 * costly than a single page, although how much more costly is uncertain. We'll
544 * try address this by using a very big cache, preferably bigger than the actual
545 * VM RAM size if possible. The current VM RAM sizes should give some idea for
546 * 32-bit boxes, while on 64-bit we can probably get away with employing an
547 * unlimited cache.
548 *
549 * The cache have to parts, as already indicated, the ring-3 side and the
550 * ring-0 side.
551 *
552 * The ring-0 will be tied to the page allocator since it will operate on the
553 * memory objects it contains. It will therefore require the first ring-0 mutex
554 * discussed in @ref sec_pgmPhys_Serializing. We some double house keeping wrt
555 * to who has mapped what I think, since both VMMR0.r0 and RTR0MemObj will keep
556 * track of mapping relations
557 *
558 * The ring-3 part will be protected by the pgm critsect. For simplicity, we'll
559 * require anyone that desires to do changes to the mapping cache to do that
560 * from within this critsect. Alternatively, we could employ a separate critsect
561 * for serializing changes to the mapping cache as this would reduce potential
562 * contention with other threads accessing mappings unrelated to the changes
563 * that are in process. We can see about this later, contention will show
564 * up in the statistics anyway, so it'll be simple to tell.
565 *
566 * The organization of the ring-3 part will be very much like how the allocation
567 * chunks are organized in ring-0, that is in an AVL tree by chunk id. To avoid
568 * having to walk the tree all the time, we'll have a couple of lookaside entries
569 * like in we do for I/O ports and MMIO in IOM.
570 *
571 * The simplified flow of a PGMPhysRead/Write function:
572 * -# Enter the PGM critsect.
573 * -# Lookup GCPhys in the ram ranges and get the Page ID.
574 * -# Calc the Allocation Chunk ID from the Page ID.
575 * -# Check the lookaside entries and then the AVL tree for the Chunk ID.
576 * If not found in cache:
577 * -# Call ring-0 and request it to be mapped and supply
578 * a chunk to be unmapped if the cache is maxed out already.
579 * -# Insert the new mapping into the AVL tree (id + R3 address).
580 * -# Update the relevant lookaside entry and return the mapping address.
581 * -# Do the read/write according to monitoring flags and everything.
582 * -# Leave the critsect.
583 *
584 *
585 * @section sec_pgmPhys_Fallback Fallback
586 *
587 * Current all the "second tier" hosts will not support the RTR0MemObjAllocPhysNC
588 * API and thus require a fallback.
589 *
590 * So, when RTR0MemObjAllocPhysNC returns VERR_NOT_SUPPORTED the page allocator
591 * will return to the ring-3 caller (and later ring-0) and asking it to seed
592 * the page allocator with some fresh pages (VERR_GMM_SEED_ME). Ring-3 will
593 * then perform an SUPR3PageAlloc(cbChunk >> PAGE_SHIFT) call and make a
594 * "SeededAllocPages" call to ring-0.
595 *
596 * The first time ring-0 sees the VERR_NOT_SUPPORTED failure it will disable
597 * all page sharing (zero page detection will continue). It will also force
598 * all allocations to come from the VM which seeded the page. Both these
599 * measures are taken to make sure that there will never be any need for
600 * mapping anything into ring-3 - everything will be mapped already.
601 *
602 * Whether we'll continue to use the current MM locked memory management
603 * for this I don't quite know (I'd prefer not to and just ditch that all
604 * together), we'll see what's simplest to do.
605 *
606 *
607 *
608 * @section sec_pgmPhys_Changes Changes
609 *
610 * Breakdown of the changes involved?
611 */
612
613
614/*********************************************************************************************************************************
615* Header Files *
616*********************************************************************************************************************************/
617#define LOG_GROUP LOG_GROUP_PGM
618#include <VBox/vmm/dbgf.h>
619#include <VBox/vmm/pgm.h>
620#include <VBox/vmm/cpum.h>
621#include <VBox/vmm/iom.h>
622#include <VBox/sup.h>
623#include <VBox/vmm/mm.h>
624#include <VBox/vmm/em.h>
625#include <VBox/vmm/stam.h>
626#ifdef VBOX_WITH_REM
627# include <VBox/vmm/rem.h>
628#endif
629#include <VBox/vmm/selm.h>
630#include <VBox/vmm/ssm.h>
631#include <VBox/vmm/hm.h>
632#include "PGMInternal.h"
633#include <VBox/vmm/vm.h>
634#include <VBox/vmm/uvm.h>
635#include "PGMInline.h"
636
637#include <VBox/dbg.h>
638#include <VBox/param.h>
639#include <VBox/err.h>
640
641#include <iprt/asm.h>
642#include <iprt/asm-amd64-x86.h>
643#include <iprt/assert.h>
644#include <iprt/env.h>
645#include <iprt/mem.h>
646#include <iprt/file.h>
647#include <iprt/string.h>
648#include <iprt/thread.h>
649
650
651/*********************************************************************************************************************************
652* Structures and Typedefs *
653*********************************************************************************************************************************/
654/**
655 * Argument package for pgmR3RElocatePhysHnadler, pgmR3RelocateVirtHandler and
656 * pgmR3RelocateHyperVirtHandler.
657 */
658typedef struct PGMRELOCHANDLERARGS
659{
660 RTGCINTPTR offDelta;
661 PVM pVM;
662} PGMRELOCHANDLERARGS;
663/** Pointer to a page access handlere relocation argument package. */
664typedef PGMRELOCHANDLERARGS const *PCPGMRELOCHANDLERARGS;
665
666
667/*********************************************************************************************************************************
668* Internal Functions *
669*********************************************************************************************************************************/
670static int pgmR3InitPaging(PVM pVM);
671static int pgmR3InitStats(PVM pVM);
672static DECLCALLBACK(void) pgmR3PhysInfo(PVM pVM, PCDBGFINFOHLP pHlp, const char *pszArgs);
673static DECLCALLBACK(void) pgmR3InfoMode(PVM pVM, PCDBGFINFOHLP pHlp, const char *pszArgs);
674static DECLCALLBACK(void) pgmR3InfoCr3(PVM pVM, PCDBGFINFOHLP pHlp, const char *pszArgs);
675static DECLCALLBACK(int) pgmR3RelocatePhysHandler(PAVLROGCPHYSNODECORE pNode, void *pvUser);
676#ifdef VBOX_WITH_RAW_MODE
677static DECLCALLBACK(int) pgmR3RelocateVirtHandler(PAVLROGCPTRNODECORE pNode, void *pvUser);
678static DECLCALLBACK(int) pgmR3RelocateHyperVirtHandler(PAVLROGCPTRNODECORE pNode, void *pvUser);
679#endif /* VBOX_WITH_RAW_MODE */
680#ifdef VBOX_STRICT
681static FNVMATSTATE pgmR3ResetNoMorePhysWritesFlag;
682#endif
683
684#ifdef VBOX_WITH_DEBUGGER
685static FNDBGCCMD pgmR3CmdError;
686static FNDBGCCMD pgmR3CmdSync;
687static FNDBGCCMD pgmR3CmdSyncAlways;
688# ifdef VBOX_STRICT
689static FNDBGCCMD pgmR3CmdAssertCR3;
690# endif
691static FNDBGCCMD pgmR3CmdPhysToFile;
692#endif
693
694
695/*********************************************************************************************************************************
696* Global Variables *
697*********************************************************************************************************************************/
698#ifdef VBOX_WITH_DEBUGGER
699/** Argument descriptors for '.pgmerror' and '.pgmerroroff'. */
700static const DBGCVARDESC g_aPgmErrorArgs[] =
701{
702 /* cTimesMin, cTimesMax, enmCategory, fFlags, pszName, pszDescription */
703 { 0, 1, DBGCVAR_CAT_STRING, 0, "where", "Error injection location." },
704};
705
706static const DBGCVARDESC g_aPgmPhysToFileArgs[] =
707{
708 /* cTimesMin, cTimesMax, enmCategory, fFlags, pszName, pszDescription */
709 { 1, 1, DBGCVAR_CAT_STRING, 0, "file", "The file name." },
710 { 0, 1, DBGCVAR_CAT_STRING, 0, "nozero", "If present, zero pages are skipped." },
711};
712
713# ifdef DEBUG_sandervl
714static const DBGCVARDESC g_aPgmCountPhysWritesArgs[] =
715{
716 /* cTimesMin, cTimesMax, enmCategory, fFlags, pszName, pszDescription */
717 { 1, 1, DBGCVAR_CAT_STRING, 0, "enabled", "on/off." },
718 { 1, 1, DBGCVAR_CAT_NUMBER_NO_RANGE, 0, "interval", "Interval in ms." },
719};
720# endif
721
722/** Command descriptors. */
723static const DBGCCMD g_aCmds[] =
724{
725 /* pszCmd, cArgsMin, cArgsMax, paArgDesc, cArgDescs, fFlags, pfnHandler pszSyntax, ....pszDescription */
726 { "pgmsync", 0, 0, NULL, 0, 0, pgmR3CmdSync, "", "Sync the CR3 page." },
727 { "pgmerror", 0, 1, &g_aPgmErrorArgs[0], 1, 0, pgmR3CmdError, "", "Enables inject runtime of errors into parts of PGM." },
728 { "pgmerroroff", 0, 1, &g_aPgmErrorArgs[0], 1, 0, pgmR3CmdError, "", "Disables inject runtime errors into parts of PGM." },
729# ifdef VBOX_STRICT
730 { "pgmassertcr3", 0, 0, NULL, 0, 0, pgmR3CmdAssertCR3, "", "Check the shadow CR3 mapping." },
731# ifdef VBOX_WITH_PAGE_SHARING
732 { "pgmcheckduppages", 0, 0, NULL, 0, 0, pgmR3CmdCheckDuplicatePages, "", "Check for duplicate pages in all running VMs." },
733 { "pgmsharedmodules", 0, 0, NULL, 0, 0, pgmR3CmdShowSharedModules, "", "Print shared modules info." },
734# endif
735# endif
736 { "pgmsyncalways", 0, 0, NULL, 0, 0, pgmR3CmdSyncAlways, "", "Toggle permanent CR3 syncing." },
737 { "pgmphystofile", 1, 2, &g_aPgmPhysToFileArgs[0], 2, 0, pgmR3CmdPhysToFile, "", "Save the physical memory to file." },
738};
739#endif
740
741
742
743
744/**
745 * Initiates the paging of VM.
746 *
747 * @returns VBox status code.
748 * @param pVM The cross context VM structure.
749 */
750VMMR3DECL(int) PGMR3Init(PVM pVM)
751{
752 LogFlow(("PGMR3Init:\n"));
753 PCFGMNODE pCfgPGM = CFGMR3GetChild(CFGMR3GetRoot(pVM), "/PGM");
754 int rc;
755
756 /*
757 * Assert alignment and sizes.
758 */
759 AssertCompile(sizeof(pVM->pgm.s) <= sizeof(pVM->pgm.padding));
760 AssertCompile(sizeof(pVM->aCpus[0].pgm.s) <= sizeof(pVM->aCpus[0].pgm.padding));
761 AssertCompileMemberAlignment(PGM, CritSectX, sizeof(uintptr_t));
762
763 /*
764 * Init the structure.
765 */
766 pVM->pgm.s.offVM = RT_UOFFSETOF(VM, pgm.s);
767 pVM->pgm.s.offVCpuPGM = RT_UOFFSETOF(VMCPU, pgm.s);
768 /*pVM->pgm.s.fRestoreRomPagesAtReset = false;*/
769
770 for (unsigned i = 0; i < RT_ELEMENTS(pVM->pgm.s.aHandyPages); i++)
771 {
772 pVM->pgm.s.aHandyPages[i].HCPhysGCPhys = NIL_RTHCPHYS;
773 pVM->pgm.s.aHandyPages[i].idPage = NIL_GMM_PAGEID;
774 pVM->pgm.s.aHandyPages[i].idSharedPage = NIL_GMM_PAGEID;
775 }
776
777 for (unsigned i = 0; i < RT_ELEMENTS(pVM->pgm.s.aLargeHandyPage); i++)
778 {
779 pVM->pgm.s.aLargeHandyPage[i].HCPhysGCPhys = NIL_RTHCPHYS;
780 pVM->pgm.s.aLargeHandyPage[i].idPage = NIL_GMM_PAGEID;
781 pVM->pgm.s.aLargeHandyPage[i].idSharedPage = NIL_GMM_PAGEID;
782 }
783
784 /* Init the per-CPU part. */
785 for (VMCPUID idCpu = 0; idCpu < pVM->cCpus; idCpu++)
786 {
787 PVMCPU pVCpu = &pVM->aCpus[idCpu];
788 PPGMCPU pPGM = &pVCpu->pgm.s;
789
790 pPGM->offVM = (uintptr_t)&pVCpu->pgm.s - (uintptr_t)pVM;
791 pPGM->offVCpu = RT_UOFFSETOF(VMCPU, pgm.s);
792 pPGM->offPGM = (uintptr_t)&pVCpu->pgm.s - (uintptr_t)&pVM->pgm.s;
793
794 pPGM->enmShadowMode = PGMMODE_INVALID;
795 pPGM->enmGuestMode = PGMMODE_INVALID;
796 pPGM->idxGuestModeData = UINT8_MAX;
797 pPGM->idxShadowModeData = UINT8_MAX;
798 pPGM->idxBothModeData = UINT8_MAX;
799
800 pPGM->GCPhysCR3 = NIL_RTGCPHYS;
801
802 pPGM->pGst32BitPdR3 = NULL;
803 pPGM->pGstPaePdptR3 = NULL;
804 pPGM->pGstAmd64Pml4R3 = NULL;
805#ifndef VBOX_WITH_2X_4GB_ADDR_SPACE
806 pPGM->pGst32BitPdR0 = NIL_RTR0PTR;
807 pPGM->pGstPaePdptR0 = NIL_RTR0PTR;
808 pPGM->pGstAmd64Pml4R0 = NIL_RTR0PTR;
809#endif
810 pPGM->pGst32BitPdRC = NIL_RTRCPTR;
811 pPGM->pGstPaePdptRC = NIL_RTRCPTR;
812 for (unsigned i = 0; i < RT_ELEMENTS(pVCpu->pgm.s.apGstPaePDsR3); i++)
813 {
814 pPGM->apGstPaePDsR3[i] = NULL;
815#ifndef VBOX_WITH_2X_4GB_ADDR_SPACE
816 pPGM->apGstPaePDsR0[i] = NIL_RTR0PTR;
817#endif
818 pPGM->apGstPaePDsRC[i] = NIL_RTRCPTR;
819 pPGM->aGCPhysGstPaePDs[i] = NIL_RTGCPHYS;
820 pPGM->aGstPaePdpeRegs[i].u = UINT64_MAX;
821 pPGM->aGCPhysGstPaePDsMonitored[i] = NIL_RTGCPHYS;
822 }
823
824 pPGM->fA20Enabled = true;
825 pPGM->GCPhysA20Mask = ~((RTGCPHYS)!pPGM->fA20Enabled << 20);
826 }
827
828 pVM->pgm.s.enmHostMode = SUPPAGINGMODE_INVALID;
829 pVM->pgm.s.GCPhys4MBPSEMask = RT_BIT_64(32) - 1; /* default; checked later */
830 pVM->pgm.s.GCPtrPrevRamRangeMapping = MM_HYPER_AREA_ADDRESS;
831
832 rc = CFGMR3QueryBoolDef(CFGMR3GetRoot(pVM), "RamPreAlloc", &pVM->pgm.s.fRamPreAlloc,
833#ifdef VBOX_WITH_PREALLOC_RAM_BY_DEFAULT
834 true
835#else
836 false
837#endif
838 );
839 AssertLogRelRCReturn(rc, rc);
840
841#if HC_ARCH_BITS == 32
842# ifdef RT_OS_DARWIN
843 rc = CFGMR3QueryU32Def(pCfgPGM, "MaxRing3Chunks", &pVM->pgm.s.ChunkR3Map.cMax, _1G / GMM_CHUNK_SIZE * 3);
844# else
845 rc = CFGMR3QueryU32Def(pCfgPGM, "MaxRing3Chunks", &pVM->pgm.s.ChunkR3Map.cMax, _1G / GMM_CHUNK_SIZE);
846# endif
847#else
848 rc = CFGMR3QueryU32Def(pCfgPGM, "MaxRing3Chunks", &pVM->pgm.s.ChunkR3Map.cMax, UINT32_MAX);
849#endif
850 AssertLogRelRCReturn(rc, rc);
851 for (uint32_t i = 0; i < RT_ELEMENTS(pVM->pgm.s.ChunkR3Map.Tlb.aEntries); i++)
852 pVM->pgm.s.ChunkR3Map.Tlb.aEntries[i].idChunk = NIL_GMM_CHUNKID;
853
854 /*
855 * Get the configured RAM size - to estimate saved state size.
856 */
857 uint64_t cbRam;
858 rc = CFGMR3QueryU64(CFGMR3GetRoot(pVM), "RamSize", &cbRam);
859 if (rc == VERR_CFGM_VALUE_NOT_FOUND)
860 cbRam = 0;
861 else if (RT_SUCCESS(rc))
862 {
863 if (cbRam < PAGE_SIZE)
864 cbRam = 0;
865 cbRam = RT_ALIGN_64(cbRam, PAGE_SIZE);
866 }
867 else
868 {
869 AssertMsgFailed(("Configuration error: Failed to query integer \"RamSize\", rc=%Rrc.\n", rc));
870 return rc;
871 }
872
873 /*
874 * Check for PCI pass-through and other configurables.
875 */
876 rc = CFGMR3QueryBoolDef(pCfgPGM, "PciPassThrough", &pVM->pgm.s.fPciPassthrough, false);
877 AssertMsgRCReturn(rc, ("Configuration error: Failed to query integer \"PciPassThrough\", rc=%Rrc.\n", rc), rc);
878 AssertLogRelReturn(!pVM->pgm.s.fPciPassthrough || pVM->pgm.s.fRamPreAlloc, VERR_INVALID_PARAMETER);
879
880 rc = CFGMR3QueryBoolDef(CFGMR3GetRoot(pVM), "PageFusionAllowed", &pVM->pgm.s.fPageFusionAllowed, false);
881 AssertLogRelRCReturn(rc, rc);
882
883 /** @cfgm{/PGM/ZeroRamPagesOnReset, boolean, true}
884 * Whether to clear RAM pages on (hard) reset. */
885 rc = CFGMR3QueryBoolDef(pCfgPGM, "ZeroRamPagesOnReset", &pVM->pgm.s.fZeroRamPagesOnReset, true);
886 AssertLogRelRCReturn(rc, rc);
887
888#ifdef VBOX_WITH_STATISTICS
889 /*
890 * Allocate memory for the statistics before someone tries to use them.
891 */
892 size_t cbTotalStats = RT_ALIGN_Z(sizeof(PGMSTATS), 64) + RT_ALIGN_Z(sizeof(PGMCPUSTATS), 64) * pVM->cCpus;
893 void *pv;
894 rc = MMHyperAlloc(pVM, RT_ALIGN_Z(cbTotalStats, PAGE_SIZE), PAGE_SIZE, MM_TAG_PGM, &pv);
895 AssertRCReturn(rc, rc);
896
897 pVM->pgm.s.pStatsR3 = (PGMSTATS *)pv;
898 pVM->pgm.s.pStatsR0 = MMHyperCCToR0(pVM, pv);
899 pVM->pgm.s.pStatsRC = MMHyperCCToRC(pVM, pv);
900 pv = (uint8_t *)pv + RT_ALIGN_Z(sizeof(PGMSTATS), 64);
901
902 for (VMCPUID iCpu = 0; iCpu < pVM->cCpus; iCpu++)
903 {
904 pVM->aCpus[iCpu].pgm.s.pStatsR3 = (PGMCPUSTATS *)pv;
905 pVM->aCpus[iCpu].pgm.s.pStatsR0 = MMHyperCCToR0(pVM, pv);
906 pVM->aCpus[iCpu].pgm.s.pStatsRC = MMHyperCCToRC(pVM, pv);
907
908 pv = (uint8_t *)pv + RT_ALIGN_Z(sizeof(PGMCPUSTATS), 64);
909 }
910#endif /* VBOX_WITH_STATISTICS */
911
912 /*
913 * Register callbacks, string formatters and the saved state data unit.
914 */
915#ifdef VBOX_STRICT
916 VMR3AtStateRegister(pVM->pUVM, pgmR3ResetNoMorePhysWritesFlag, NULL);
917#endif
918 PGMRegisterStringFormatTypes();
919
920 rc = pgmR3InitSavedState(pVM, cbRam);
921 if (RT_FAILURE(rc))
922 return rc;
923
924 /*
925 * Initialize the PGM critical section and flush the phys TLBs
926 */
927 rc = PDMR3CritSectInit(pVM, &pVM->pgm.s.CritSectX, RT_SRC_POS, "PGM");
928 AssertRCReturn(rc, rc);
929
930 PGMR3PhysChunkInvalidateTLB(pVM);
931 pgmPhysInvalidatePageMapTLB(pVM);
932
933 /*
934 * For the time being we sport a full set of handy pages in addition to the base
935 * memory to simplify things.
936 */
937 rc = MMR3ReserveHandyPages(pVM, RT_ELEMENTS(pVM->pgm.s.aHandyPages)); /** @todo this should be changed to PGM_HANDY_PAGES_MIN but this needs proper testing... */
938 AssertRCReturn(rc, rc);
939
940 /*
941 * Trees
942 */
943 rc = MMHyperAlloc(pVM, sizeof(PGMTREES), 0, MM_TAG_PGM, (void **)&pVM->pgm.s.pTreesR3);
944 if (RT_SUCCESS(rc))
945 {
946 pVM->pgm.s.pTreesR0 = MMHyperR3ToR0(pVM, pVM->pgm.s.pTreesR3);
947 pVM->pgm.s.pTreesRC = MMHyperR3ToRC(pVM, pVM->pgm.s.pTreesR3);
948 }
949
950 /*
951 * Allocate the zero page.
952 */
953 if (RT_SUCCESS(rc))
954 {
955 rc = MMHyperAlloc(pVM, PAGE_SIZE, PAGE_SIZE, MM_TAG_PGM, &pVM->pgm.s.pvZeroPgR3);
956 if (RT_SUCCESS(rc))
957 {
958 pVM->pgm.s.pvZeroPgRC = MMHyperR3ToRC(pVM, pVM->pgm.s.pvZeroPgR3);
959 pVM->pgm.s.pvZeroPgR0 = MMHyperR3ToR0(pVM, pVM->pgm.s.pvZeroPgR3);
960 pVM->pgm.s.HCPhysZeroPg = MMR3HyperHCVirt2HCPhys(pVM, pVM->pgm.s.pvZeroPgR3);
961 AssertRelease(pVM->pgm.s.HCPhysZeroPg != NIL_RTHCPHYS);
962 }
963 }
964
965 /*
966 * Allocate the invalid MMIO page.
967 * (The invalid bits in HCPhysInvMmioPg are set later on init complete.)
968 */
969 if (RT_SUCCESS(rc))
970 {
971 rc = MMHyperAlloc(pVM, PAGE_SIZE, PAGE_SIZE, MM_TAG_PGM, &pVM->pgm.s.pvMmioPgR3);
972 if (RT_SUCCESS(rc))
973 {
974 ASMMemFill32(pVM->pgm.s.pvMmioPgR3, PAGE_SIZE, 0xfeedface);
975 pVM->pgm.s.HCPhysMmioPg = MMR3HyperHCVirt2HCPhys(pVM, pVM->pgm.s.pvMmioPgR3);
976 AssertRelease(pVM->pgm.s.HCPhysMmioPg != NIL_RTHCPHYS);
977 pVM->pgm.s.HCPhysInvMmioPg = pVM->pgm.s.HCPhysMmioPg;
978 }
979 }
980
981 /*
982 * Register the physical access handler protecting ROMs.
983 */
984 if (RT_SUCCESS(rc))
985 rc = PGMR3HandlerPhysicalTypeRegister(pVM, PGMPHYSHANDLERKIND_WRITE,
986 pgmPhysRomWriteHandler,
987 NULL, NULL, "pgmPhysRomWritePfHandler",
988 NULL, NULL, "pgmPhysRomWritePfHandler",
989 "ROM write protection",
990 &pVM->pgm.s.hRomPhysHandlerType);
991
992 /*
993 * Init the paging.
994 */
995 if (RT_SUCCESS(rc))
996 rc = pgmR3InitPaging(pVM);
997
998 /*
999 * Init the page pool.
1000 */
1001 if (RT_SUCCESS(rc))
1002 rc = pgmR3PoolInit(pVM);
1003
1004 if (RT_SUCCESS(rc))
1005 {
1006 for (VMCPUID i = 0; i < pVM->cCpus; i++)
1007 {
1008 PVMCPU pVCpu = &pVM->aCpus[i];
1009 rc = PGMHCChangeMode(pVM, pVCpu, PGMMODE_REAL);
1010 if (RT_FAILURE(rc))
1011 break;
1012 }
1013 }
1014
1015 if (RT_SUCCESS(rc))
1016 {
1017 /*
1018 * Info & statistics
1019 */
1020 DBGFR3InfoRegisterInternalEx(pVM, "mode",
1021 "Shows the current paging mode. "
1022 "Recognizes 'all', 'guest', 'shadow' and 'host' as arguments, defaulting to 'all' if nothing is given.",
1023 pgmR3InfoMode,
1024 DBGFINFO_FLAGS_ALL_EMTS);
1025 DBGFR3InfoRegisterInternal(pVM, "pgmcr3",
1026 "Dumps all the entries in the top level paging table. No arguments.",
1027 pgmR3InfoCr3);
1028 DBGFR3InfoRegisterInternal(pVM, "phys",
1029 "Dumps all the physical address ranges. Pass 'verbose' to get more details.",
1030 pgmR3PhysInfo);
1031 DBGFR3InfoRegisterInternal(pVM, "handlers",
1032 "Dumps physical, virtual and hyper virtual handlers. "
1033 "Pass 'phys', 'virt', 'hyper' as argument if only one kind is wanted."
1034 "Add 'nost' if the statistics are unwanted, use together with 'all' or explicit selection.",
1035 pgmR3InfoHandlers);
1036 DBGFR3InfoRegisterInternal(pVM, "mappings",
1037 "Dumps guest mappings.",
1038 pgmR3MapInfo);
1039
1040 pgmR3InitStats(pVM);
1041
1042#ifdef VBOX_WITH_DEBUGGER
1043 /*
1044 * Debugger commands.
1045 */
1046 static bool s_fRegisteredCmds = false;
1047 if (!s_fRegisteredCmds)
1048 {
1049 int rc2 = DBGCRegisterCommands(&g_aCmds[0], RT_ELEMENTS(g_aCmds));
1050 if (RT_SUCCESS(rc2))
1051 s_fRegisteredCmds = true;
1052 }
1053#endif
1054 return VINF_SUCCESS;
1055 }
1056
1057 /* Almost no cleanup necessary, MM frees all memory. */
1058 PDMR3CritSectDelete(&pVM->pgm.s.CritSectX);
1059
1060 return rc;
1061}
1062
1063
1064/**
1065 * Init paging.
1066 *
1067 * Since we need to check what mode the host is operating in before we can choose
1068 * the right paging functions for the host we have to delay this until R0 has
1069 * been initialized.
1070 *
1071 * @returns VBox status code.
1072 * @param pVM The cross context VM structure.
1073 */
1074static int pgmR3InitPaging(PVM pVM)
1075{
1076 /*
1077 * Force a recalculation of modes and switcher so everyone gets notified.
1078 */
1079 for (VMCPUID i = 0; i < pVM->cCpus; i++)
1080 {
1081 PVMCPU pVCpu = &pVM->aCpus[i];
1082
1083 pVCpu->pgm.s.enmShadowMode = PGMMODE_INVALID;
1084 pVCpu->pgm.s.enmGuestMode = PGMMODE_INVALID;
1085 pVCpu->pgm.s.idxGuestModeData = UINT8_MAX;
1086 pVCpu->pgm.s.idxShadowModeData = UINT8_MAX;
1087 pVCpu->pgm.s.idxBothModeData = UINT8_MAX;
1088 }
1089
1090 pVM->pgm.s.enmHostMode = SUPPAGINGMODE_INVALID;
1091
1092 /*
1093 * Allocate static mapping space for whatever the cr3 register
1094 * points to and in the case of PAE mode to the 4 PDs.
1095 */
1096 int rc = MMR3HyperReserve(pVM, PAGE_SIZE * 5, "CR3 mapping", &pVM->pgm.s.GCPtrCR3Mapping);
1097 if (RT_FAILURE(rc))
1098 {
1099 AssertMsgFailed(("Failed to reserve two pages for cr mapping in HMA, rc=%Rrc\n", rc));
1100 return rc;
1101 }
1102 MMR3HyperReserve(pVM, PAGE_SIZE, "fence", NULL);
1103
1104 /*
1105 * Allocate pages for the three possible intermediate contexts
1106 * (AMD64, PAE and plain 32-Bit). We maintain all three contexts
1107 * for the sake of simplicity. The AMD64 uses the PAE for the
1108 * lower levels, making the total number of pages 11 (3 + 7 + 1).
1109 *
1110 * We assume that two page tables will be enought for the core code
1111 * mappings (HC virtual and identity).
1112 */
1113 pVM->pgm.s.pInterPD = (PX86PD)MMR3PageAllocLow(pVM); AssertReturn(pVM->pgm.s.pInterPD, VERR_NO_PAGE_MEMORY);
1114 pVM->pgm.s.apInterPTs[0] = (PX86PT)MMR3PageAllocLow(pVM); AssertReturn(pVM->pgm.s.apInterPTs[0], VERR_NO_PAGE_MEMORY);
1115 pVM->pgm.s.apInterPTs[1] = (PX86PT)MMR3PageAllocLow(pVM); AssertReturn(pVM->pgm.s.apInterPTs[1], VERR_NO_PAGE_MEMORY);
1116 pVM->pgm.s.apInterPaePTs[0] = (PX86PTPAE)MMR3PageAlloc(pVM); AssertReturn(pVM->pgm.s.apInterPaePTs[0], VERR_NO_PAGE_MEMORY);
1117 pVM->pgm.s.apInterPaePTs[1] = (PX86PTPAE)MMR3PageAlloc(pVM); AssertReturn(pVM->pgm.s.apInterPaePTs[1], VERR_NO_PAGE_MEMORY);
1118 pVM->pgm.s.apInterPaePDs[0] = (PX86PDPAE)MMR3PageAlloc(pVM); AssertReturn(pVM->pgm.s.apInterPaePDs[0], VERR_NO_PAGE_MEMORY);
1119 pVM->pgm.s.apInterPaePDs[1] = (PX86PDPAE)MMR3PageAlloc(pVM); AssertReturn(pVM->pgm.s.apInterPaePDs[1], VERR_NO_PAGE_MEMORY);
1120 pVM->pgm.s.apInterPaePDs[2] = (PX86PDPAE)MMR3PageAlloc(pVM); AssertReturn(pVM->pgm.s.apInterPaePDs[2], VERR_NO_PAGE_MEMORY);
1121 pVM->pgm.s.apInterPaePDs[3] = (PX86PDPAE)MMR3PageAlloc(pVM); AssertReturn(pVM->pgm.s.apInterPaePDs[3], VERR_NO_PAGE_MEMORY);
1122 pVM->pgm.s.pInterPaePDPT = (PX86PDPT)MMR3PageAllocLow(pVM); AssertReturn(pVM->pgm.s.pInterPaePDPT, VERR_NO_PAGE_MEMORY);
1123 pVM->pgm.s.pInterPaePDPT64 = (PX86PDPT)MMR3PageAllocLow(pVM); AssertReturn(pVM->pgm.s.pInterPaePDPT64, VERR_NO_PAGE_MEMORY);
1124 pVM->pgm.s.pInterPaePML4 = (PX86PML4)MMR3PageAllocLow(pVM); AssertReturn(pVM->pgm.s.pInterPaePML4, VERR_NO_PAGE_MEMORY);
1125
1126 pVM->pgm.s.HCPhysInterPD = MMPage2Phys(pVM, pVM->pgm.s.pInterPD);
1127 AssertRelease(pVM->pgm.s.HCPhysInterPD != NIL_RTHCPHYS && !(pVM->pgm.s.HCPhysInterPD & PAGE_OFFSET_MASK));
1128 pVM->pgm.s.HCPhysInterPaePDPT = MMPage2Phys(pVM, pVM->pgm.s.pInterPaePDPT);
1129 AssertRelease(pVM->pgm.s.HCPhysInterPaePDPT != NIL_RTHCPHYS && !(pVM->pgm.s.HCPhysInterPaePDPT & PAGE_OFFSET_MASK));
1130 pVM->pgm.s.HCPhysInterPaePML4 = MMPage2Phys(pVM, pVM->pgm.s.pInterPaePML4);
1131 AssertRelease(pVM->pgm.s.HCPhysInterPaePML4 != NIL_RTHCPHYS && !(pVM->pgm.s.HCPhysInterPaePML4 & PAGE_OFFSET_MASK) && pVM->pgm.s.HCPhysInterPaePML4 < 0xffffffff);
1132
1133 /*
1134 * Initialize the pages, setting up the PML4 and PDPT for repetitive 4GB action.
1135 */
1136 ASMMemZeroPage(pVM->pgm.s.pInterPD);
1137 ASMMemZeroPage(pVM->pgm.s.apInterPTs[0]);
1138 ASMMemZeroPage(pVM->pgm.s.apInterPTs[1]);
1139
1140 ASMMemZeroPage(pVM->pgm.s.apInterPaePTs[0]);
1141 ASMMemZeroPage(pVM->pgm.s.apInterPaePTs[1]);
1142
1143 ASMMemZeroPage(pVM->pgm.s.pInterPaePDPT);
1144 for (unsigned i = 0; i < RT_ELEMENTS(pVM->pgm.s.apInterPaePDs); i++)
1145 {
1146 ASMMemZeroPage(pVM->pgm.s.apInterPaePDs[i]);
1147 pVM->pgm.s.pInterPaePDPT->a[i].u = X86_PDPE_P | PGM_PLXFLAGS_PERMANENT
1148 | MMPage2Phys(pVM, pVM->pgm.s.apInterPaePDs[i]);
1149 }
1150
1151 for (unsigned i = 0; i < RT_ELEMENTS(pVM->pgm.s.pInterPaePDPT64->a); i++)
1152 {
1153 const unsigned iPD = i % RT_ELEMENTS(pVM->pgm.s.apInterPaePDs);
1154 pVM->pgm.s.pInterPaePDPT64->a[i].u = X86_PDPE_P | X86_PDPE_RW | X86_PDPE_US | X86_PDPE_A | PGM_PLXFLAGS_PERMANENT
1155 | MMPage2Phys(pVM, pVM->pgm.s.apInterPaePDs[iPD]);
1156 }
1157
1158 RTHCPHYS HCPhysInterPaePDPT64 = MMPage2Phys(pVM, pVM->pgm.s.pInterPaePDPT64);
1159 for (unsigned i = 0; i < RT_ELEMENTS(pVM->pgm.s.pInterPaePML4->a); i++)
1160 pVM->pgm.s.pInterPaePML4->a[i].u = X86_PML4E_P | X86_PML4E_RW | X86_PML4E_US | X86_PML4E_A | PGM_PLXFLAGS_PERMANENT
1161 | HCPhysInterPaePDPT64;
1162
1163 /*
1164 * Initialize paging workers and mode from current host mode
1165 * and the guest running in real mode.
1166 */
1167 pVM->pgm.s.enmHostMode = SUPR3GetPagingMode();
1168 switch (pVM->pgm.s.enmHostMode)
1169 {
1170 case SUPPAGINGMODE_32_BIT:
1171 case SUPPAGINGMODE_32_BIT_GLOBAL:
1172 case SUPPAGINGMODE_PAE:
1173 case SUPPAGINGMODE_PAE_GLOBAL:
1174 case SUPPAGINGMODE_PAE_NX:
1175 case SUPPAGINGMODE_PAE_GLOBAL_NX:
1176 break;
1177
1178 case SUPPAGINGMODE_AMD64:
1179 case SUPPAGINGMODE_AMD64_GLOBAL:
1180 case SUPPAGINGMODE_AMD64_NX:
1181 case SUPPAGINGMODE_AMD64_GLOBAL_NX:
1182 if (ARCH_BITS != 64)
1183 {
1184 AssertMsgFailed(("Host mode %d (64-bit) is not supported by non-64bit builds\n", pVM->pgm.s.enmHostMode));
1185 LogRel(("PGM: Host mode %d (64-bit) is not supported by non-64bit builds\n", pVM->pgm.s.enmHostMode));
1186 return VERR_PGM_UNSUPPORTED_HOST_PAGING_MODE;
1187 }
1188 break;
1189 default:
1190 AssertMsgFailed(("Host mode %d is not supported\n", pVM->pgm.s.enmHostMode));
1191 return VERR_PGM_UNSUPPORTED_HOST_PAGING_MODE;
1192 }
1193
1194 LogFlow(("pgmR3InitPaging: returns successfully\n"));
1195#if HC_ARCH_BITS == 64
1196 LogRel(("PGM: HCPhysInterPD=%RHp HCPhysInterPaePDPT=%RHp HCPhysInterPaePML4=%RHp\n",
1197 pVM->pgm.s.HCPhysInterPD, pVM->pgm.s.HCPhysInterPaePDPT, pVM->pgm.s.HCPhysInterPaePML4));
1198 LogRel(("PGM: apInterPTs={%RHp,%RHp} apInterPaePTs={%RHp,%RHp} apInterPaePDs={%RHp,%RHp,%RHp,%RHp} pInterPaePDPT64=%RHp\n",
1199 MMPage2Phys(pVM, pVM->pgm.s.apInterPTs[0]), MMPage2Phys(pVM, pVM->pgm.s.apInterPTs[1]),
1200 MMPage2Phys(pVM, pVM->pgm.s.apInterPaePTs[0]), MMPage2Phys(pVM, pVM->pgm.s.apInterPaePTs[1]),
1201 MMPage2Phys(pVM, pVM->pgm.s.apInterPaePDs[0]), MMPage2Phys(pVM, pVM->pgm.s.apInterPaePDs[1]), MMPage2Phys(pVM, pVM->pgm.s.apInterPaePDs[2]), MMPage2Phys(pVM, pVM->pgm.s.apInterPaePDs[3]),
1202 MMPage2Phys(pVM, pVM->pgm.s.pInterPaePDPT64)));
1203#endif
1204
1205 /*
1206 * Log the host paging mode. It may come in handy.
1207 */
1208 const char *pszHostMode;
1209 switch (pVM->pgm.s.enmHostMode)
1210 {
1211 case SUPPAGINGMODE_32_BIT: pszHostMode = "32-bit"; break;
1212 case SUPPAGINGMODE_32_BIT_GLOBAL: pszHostMode = "32-bit+PGE"; break;
1213 case SUPPAGINGMODE_PAE: pszHostMode = "PAE"; break;
1214 case SUPPAGINGMODE_PAE_GLOBAL: pszHostMode = "PAE+PGE"; break;
1215 case SUPPAGINGMODE_PAE_NX: pszHostMode = "PAE+NXE"; break;
1216 case SUPPAGINGMODE_PAE_GLOBAL_NX: pszHostMode = "PAE+PGE+NXE"; break;
1217 case SUPPAGINGMODE_AMD64: pszHostMode = "AMD64"; break;
1218 case SUPPAGINGMODE_AMD64_GLOBAL: pszHostMode = "AMD64+PGE"; break;
1219 case SUPPAGINGMODE_AMD64_NX: pszHostMode = "AMD64+NX"; break;
1220 case SUPPAGINGMODE_AMD64_GLOBAL_NX: pszHostMode = "AMD64+PGE+NX"; break;
1221 default: pszHostMode = "???"; break;
1222 }
1223 LogRel(("PGM: Host paging mode: %s\n", pszHostMode));
1224
1225 return VINF_SUCCESS;
1226}
1227
1228
1229/**
1230 * Init statistics
1231 * @returns VBox status code.
1232 */
1233static int pgmR3InitStats(PVM pVM)
1234{
1235 PPGM pPGM = &pVM->pgm.s;
1236 int rc;
1237
1238 /*
1239 * Release statistics.
1240 */
1241 /* Common - misc variables */
1242 STAM_REL_REG(pVM, &pPGM->cAllPages, STAMTYPE_U32, "/PGM/Page/cAllPages", STAMUNIT_COUNT, "The total number of pages.");
1243 STAM_REL_REG(pVM, &pPGM->cPrivatePages, STAMTYPE_U32, "/PGM/Page/cPrivatePages", STAMUNIT_COUNT, "The number of private pages.");
1244 STAM_REL_REG(pVM, &pPGM->cSharedPages, STAMTYPE_U32, "/PGM/Page/cSharedPages", STAMUNIT_COUNT, "The number of shared pages.");
1245 STAM_REL_REG(pVM, &pPGM->cReusedSharedPages, STAMTYPE_U32, "/PGM/Page/cReusedSharedPages", STAMUNIT_COUNT, "The number of reused shared pages.");
1246 STAM_REL_REG(pVM, &pPGM->cZeroPages, STAMTYPE_U32, "/PGM/Page/cZeroPages", STAMUNIT_COUNT, "The number of zero backed pages.");
1247 STAM_REL_REG(pVM, &pPGM->cPureMmioPages, STAMTYPE_U32, "/PGM/Page/cPureMmioPages", STAMUNIT_COUNT, "The number of pure MMIO pages.");
1248 STAM_REL_REG(pVM, &pPGM->cMonitoredPages, STAMTYPE_U32, "/PGM/Page/cMonitoredPages", STAMUNIT_COUNT, "The number of write monitored pages.");
1249 STAM_REL_REG(pVM, &pPGM->cWrittenToPages, STAMTYPE_U32, "/PGM/Page/cWrittenToPages", STAMUNIT_COUNT, "The number of previously write monitored pages that have been written to.");
1250 STAM_REL_REG(pVM, &pPGM->cWriteLockedPages, STAMTYPE_U32, "/PGM/Page/cWriteLockedPages", STAMUNIT_COUNT, "The number of write(/read) locked pages.");
1251 STAM_REL_REG(pVM, &pPGM->cReadLockedPages, STAMTYPE_U32, "/PGM/Page/cReadLockedPages", STAMUNIT_COUNT, "The number of read (only) locked pages.");
1252 STAM_REL_REG(pVM, &pPGM->cBalloonedPages, STAMTYPE_U32, "/PGM/Page/cBalloonedPages", STAMUNIT_COUNT, "The number of ballooned pages.");
1253 STAM_REL_REG(pVM, &pPGM->cHandyPages, STAMTYPE_U32, "/PGM/Page/cHandyPages", STAMUNIT_COUNT, "The number of handy pages (not included in cAllPages).");
1254 STAM_REL_REG(pVM, &pPGM->cLargePages, STAMTYPE_U32, "/PGM/Page/cLargePages", STAMUNIT_COUNT, "The number of large pages allocated (includes disabled).");
1255 STAM_REL_REG(pVM, &pPGM->cLargePagesDisabled, STAMTYPE_U32, "/PGM/Page/cLargePagesDisabled", STAMUNIT_COUNT, "The number of disabled large pages.");
1256 STAM_REL_REG(pVM, &pPGM->cRelocations, STAMTYPE_COUNTER, "/PGM/cRelocations", STAMUNIT_OCCURENCES,"Number of hypervisor relocations.");
1257 STAM_REL_REG(pVM, &pPGM->ChunkR3Map.c, STAMTYPE_U32, "/PGM/ChunkR3Map/c", STAMUNIT_COUNT, "Number of mapped chunks.");
1258 STAM_REL_REG(pVM, &pPGM->ChunkR3Map.cMax, STAMTYPE_U32, "/PGM/ChunkR3Map/cMax", STAMUNIT_COUNT, "Maximum number of mapped chunks.");
1259 STAM_REL_REG(pVM, &pPGM->cMappedChunks, STAMTYPE_U32, "/PGM/ChunkR3Map/Mapped", STAMUNIT_COUNT, "Number of times we mapped a chunk.");
1260 STAM_REL_REG(pVM, &pPGM->cUnmappedChunks, STAMTYPE_U32, "/PGM/ChunkR3Map/Unmapped", STAMUNIT_COUNT, "Number of times we unmapped a chunk.");
1261
1262 STAM_REL_REG(pVM, &pPGM->StatLargePageReused, STAMTYPE_COUNTER, "/PGM/LargePage/Reused", STAMUNIT_OCCURENCES, "The number of times we've reused a large page.");
1263 STAM_REL_REG(pVM, &pPGM->StatLargePageRefused, STAMTYPE_COUNTER, "/PGM/LargePage/Refused", STAMUNIT_OCCURENCES, "The number of times we couldn't use a large page.");
1264 STAM_REL_REG(pVM, &pPGM->StatLargePageRecheck, STAMTYPE_COUNTER, "/PGM/LargePage/Recheck", STAMUNIT_OCCURENCES, "The number of times we've rechecked a disabled large page.");
1265
1266 STAM_REL_REG(pVM, &pPGM->StatShModCheck, STAMTYPE_PROFILE, "/PGM/ShMod/Check", STAMUNIT_TICKS_PER_CALL, "Profiles the shared module checking.");
1267
1268 /* Live save */
1269 STAM_REL_REG_USED(pVM, &pPGM->LiveSave.fActive, STAMTYPE_U8, "/PGM/LiveSave/fActive", STAMUNIT_COUNT, "Active or not.");
1270 STAM_REL_REG_USED(pVM, &pPGM->LiveSave.cIgnoredPages, STAMTYPE_U32, "/PGM/LiveSave/cIgnoredPages", STAMUNIT_COUNT, "The number of ignored pages in the RAM ranges (i.e. MMIO, MMIO2 and ROM).");
1271 STAM_REL_REG_USED(pVM, &pPGM->LiveSave.cDirtyPagesLong, STAMTYPE_U32, "/PGM/LiveSave/cDirtyPagesLong", STAMUNIT_COUNT, "Longer term dirty page average.");
1272 STAM_REL_REG_USED(pVM, &pPGM->LiveSave.cDirtyPagesShort, STAMTYPE_U32, "/PGM/LiveSave/cDirtyPagesShort", STAMUNIT_COUNT, "Short term dirty page average.");
1273 STAM_REL_REG_USED(pVM, &pPGM->LiveSave.cPagesPerSecond, STAMTYPE_U32, "/PGM/LiveSave/cPagesPerSecond", STAMUNIT_COUNT, "Pages per second.");
1274 STAM_REL_REG_USED(pVM, &pPGM->LiveSave.cSavedPages, STAMTYPE_U64, "/PGM/LiveSave/cSavedPages", STAMUNIT_COUNT, "The total number of saved pages.");
1275 STAM_REL_REG_USED(pVM, &pPGM->LiveSave.Ram.cReadyPages, STAMTYPE_U32, "/PGM/LiveSave/Ram/cReadPages", STAMUNIT_COUNT, "RAM: Ready pages.");
1276 STAM_REL_REG_USED(pVM, &pPGM->LiveSave.Ram.cDirtyPages, STAMTYPE_U32, "/PGM/LiveSave/Ram/cDirtyPages", STAMUNIT_COUNT, "RAM: Dirty pages.");
1277 STAM_REL_REG_USED(pVM, &pPGM->LiveSave.Ram.cZeroPages, STAMTYPE_U32, "/PGM/LiveSave/Ram/cZeroPages", STAMUNIT_COUNT, "RAM: Ready zero pages.");
1278 STAM_REL_REG_USED(pVM, &pPGM->LiveSave.Ram.cMonitoredPages, STAMTYPE_U32, "/PGM/LiveSave/Ram/cMonitoredPages", STAMUNIT_COUNT, "RAM: Write monitored pages.");
1279 STAM_REL_REG_USED(pVM, &pPGM->LiveSave.Rom.cReadyPages, STAMTYPE_U32, "/PGM/LiveSave/Rom/cReadPages", STAMUNIT_COUNT, "ROM: Ready pages.");
1280 STAM_REL_REG_USED(pVM, &pPGM->LiveSave.Rom.cDirtyPages, STAMTYPE_U32, "/PGM/LiveSave/Rom/cDirtyPages", STAMUNIT_COUNT, "ROM: Dirty pages.");
1281 STAM_REL_REG_USED(pVM, &pPGM->LiveSave.Rom.cZeroPages, STAMTYPE_U32, "/PGM/LiveSave/Rom/cZeroPages", STAMUNIT_COUNT, "ROM: Ready zero pages.");
1282 STAM_REL_REG_USED(pVM, &pPGM->LiveSave.Rom.cMonitoredPages, STAMTYPE_U32, "/PGM/LiveSave/Rom/cMonitoredPages", STAMUNIT_COUNT, "ROM: Write monitored pages.");
1283 STAM_REL_REG_USED(pVM, &pPGM->LiveSave.Mmio2.cReadyPages, STAMTYPE_U32, "/PGM/LiveSave/Mmio2/cReadPages", STAMUNIT_COUNT, "MMIO2: Ready pages.");
1284 STAM_REL_REG_USED(pVM, &pPGM->LiveSave.Mmio2.cDirtyPages, STAMTYPE_U32, "/PGM/LiveSave/Mmio2/cDirtyPages", STAMUNIT_COUNT, "MMIO2: Dirty pages.");
1285 STAM_REL_REG_USED(pVM, &pPGM->LiveSave.Mmio2.cZeroPages, STAMTYPE_U32, "/PGM/LiveSave/Mmio2/cZeroPages", STAMUNIT_COUNT, "MMIO2: Ready zero pages.");
1286 STAM_REL_REG_USED(pVM, &pPGM->LiveSave.Mmio2.cMonitoredPages,STAMTYPE_U32, "/PGM/LiveSave/Mmio2/cMonitoredPages",STAMUNIT_COUNT, "MMIO2: Write monitored pages.");
1287
1288#ifdef VBOX_WITH_STATISTICS
1289
1290# define PGM_REG_COUNTER(a, b, c) \
1291 rc = STAMR3RegisterF(pVM, a, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, c, b); \
1292 AssertRC(rc);
1293
1294# define PGM_REG_COUNTER_BYTES(a, b, c) \
1295 rc = STAMR3RegisterF(pVM, a, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_BYTES, c, b); \
1296 AssertRC(rc);
1297
1298# define PGM_REG_PROFILE(a, b, c) \
1299 rc = STAMR3RegisterF(pVM, a, STAMTYPE_PROFILE, STAMVISIBILITY_ALWAYS, STAMUNIT_TICKS_PER_CALL, c, b); \
1300 AssertRC(rc);
1301
1302 PGMSTATS *pStats = pVM->pgm.s.pStatsR3;
1303
1304 PGM_REG_PROFILE(&pStats->StatAllocLargePage, "/PGM/LargePage/Prof/Alloc", "Time spent by the host OS for large page allocation.");
1305 PGM_REG_PROFILE(&pStats->StatClearLargePage, "/PGM/LargePage/Prof/Clear", "Time spent clearing the newly allocated large pages.");
1306 PGM_REG_COUNTER(&pStats->StatLargePageOverflow, "/PGM/LargePage/Overflow", "The number of times allocating a large page took too long.");
1307 PGM_REG_PROFILE(&pStats->StatR3IsValidLargePage, "/PGM/LargePage/Prof/R3/IsValid", "pgmPhysIsValidLargePage profiling - R3.");
1308 PGM_REG_PROFILE(&pStats->StatRZIsValidLargePage, "/PGM/LargePage/Prof/RZ/IsValid", "pgmPhysIsValidLargePage profiling - RZ.");
1309
1310 PGM_REG_COUNTER(&pStats->StatR3DetectedConflicts, "/PGM/R3/DetectedConflicts", "The number of times PGMR3CheckMappingConflicts() detected a conflict.");
1311 PGM_REG_PROFILE(&pStats->StatR3ResolveConflict, "/PGM/R3/ResolveConflict", "pgmR3SyncPTResolveConflict() profiling (includes the entire relocation).");
1312 PGM_REG_COUNTER(&pStats->StatR3PhysRead, "/PGM/R3/Phys/Read", "The number of times PGMPhysRead was called.");
1313 PGM_REG_COUNTER_BYTES(&pStats->StatR3PhysReadBytes, "/PGM/R3/Phys/Read/Bytes", "The number of bytes read by PGMPhysRead.");
1314 PGM_REG_COUNTER(&pStats->StatR3PhysWrite, "/PGM/R3/Phys/Write", "The number of times PGMPhysWrite was called.");
1315 PGM_REG_COUNTER_BYTES(&pStats->StatR3PhysWriteBytes, "/PGM/R3/Phys/Write/Bytes", "The number of bytes written by PGMPhysWrite.");
1316 PGM_REG_COUNTER(&pStats->StatR3PhysSimpleRead, "/PGM/R3/Phys/Simple/Read", "The number of times PGMPhysSimpleReadGCPtr was called.");
1317 PGM_REG_COUNTER_BYTES(&pStats->StatR3PhysSimpleReadBytes, "/PGM/R3/Phys/Simple/Read/Bytes", "The number of bytes read by PGMPhysSimpleReadGCPtr.");
1318 PGM_REG_COUNTER(&pStats->StatR3PhysSimpleWrite, "/PGM/R3/Phys/Simple/Write", "The number of times PGMPhysSimpleWriteGCPtr was called.");
1319 PGM_REG_COUNTER_BYTES(&pStats->StatR3PhysSimpleWriteBytes, "/PGM/R3/Phys/Simple/Write/Bytes", "The number of bytes written by PGMPhysSimpleWriteGCPtr.");
1320
1321 PGM_REG_COUNTER(&pStats->StatRZChunkR3MapTlbHits, "/PGM/ChunkR3Map/TlbHitsRZ", "TLB hits.");
1322 PGM_REG_COUNTER(&pStats->StatRZChunkR3MapTlbMisses, "/PGM/ChunkR3Map/TlbMissesRZ", "TLB misses.");
1323 PGM_REG_PROFILE(&pStats->StatChunkAging, "/PGM/ChunkR3Map/Map/Aging", "Chunk aging profiling.");
1324 PGM_REG_PROFILE(&pStats->StatChunkFindCandidate, "/PGM/ChunkR3Map/Map/Find", "Chunk unmap find profiling.");
1325 PGM_REG_PROFILE(&pStats->StatChunkUnmap, "/PGM/ChunkR3Map/Map/Unmap", "Chunk unmap of address space profiling.");
1326 PGM_REG_PROFILE(&pStats->StatChunkMap, "/PGM/ChunkR3Map/Map/Map", "Chunk map of address space profiling.");
1327
1328 PGM_REG_COUNTER(&pStats->StatRZPageMapTlbHits, "/PGM/RZ/Page/MapTlbHits", "TLB hits.");
1329 PGM_REG_COUNTER(&pStats->StatRZPageMapTlbMisses, "/PGM/RZ/Page/MapTlbMisses", "TLB misses.");
1330 PGM_REG_COUNTER(&pStats->StatR3ChunkR3MapTlbHits, "/PGM/ChunkR3Map/TlbHitsR3", "TLB hits.");
1331 PGM_REG_COUNTER(&pStats->StatR3ChunkR3MapTlbMisses, "/PGM/ChunkR3Map/TlbMissesR3", "TLB misses.");
1332 PGM_REG_COUNTER(&pStats->StatR3PageMapTlbHits, "/PGM/R3/Page/MapTlbHits", "TLB hits.");
1333 PGM_REG_COUNTER(&pStats->StatR3PageMapTlbMisses, "/PGM/R3/Page/MapTlbMisses", "TLB misses.");
1334 PGM_REG_COUNTER(&pStats->StatPageMapTlbFlushes, "/PGM/R3/Page/MapTlbFlushes", "TLB flushes (all contexts).");
1335 PGM_REG_COUNTER(&pStats->StatPageMapTlbFlushEntry, "/PGM/R3/Page/MapTlbFlushEntry", "TLB entry flushes (all contexts).");
1336
1337 PGM_REG_COUNTER(&pStats->StatRZRamRangeTlbHits, "/PGM/RZ/RamRange/TlbHits", "TLB hits.");
1338 PGM_REG_COUNTER(&pStats->StatRZRamRangeTlbMisses, "/PGM/RZ/RamRange/TlbMisses", "TLB misses.");
1339 PGM_REG_COUNTER(&pStats->StatR3RamRangeTlbHits, "/PGM/R3/RamRange/TlbHits", "TLB hits.");
1340 PGM_REG_COUNTER(&pStats->StatR3RamRangeTlbMisses, "/PGM/R3/RamRange/TlbMisses", "TLB misses.");
1341
1342 PGM_REG_PROFILE(&pStats->StatRZSyncCR3HandlerVirtualUpdate, "/PGM/RZ/SyncCR3/Handlers/VirtualUpdate", "Profiling of the virtual handler updates.");
1343 PGM_REG_PROFILE(&pStats->StatRZSyncCR3HandlerVirtualReset, "/PGM/RZ/SyncCR3/Handlers/VirtualReset", "Profiling of the virtual handler resets.");
1344 PGM_REG_PROFILE(&pStats->StatR3SyncCR3HandlerVirtualUpdate, "/PGM/R3/SyncCR3/Handlers/VirtualUpdate", "Profiling of the virtual handler updates.");
1345 PGM_REG_PROFILE(&pStats->StatR3SyncCR3HandlerVirtualReset, "/PGM/R3/SyncCR3/Handlers/VirtualReset", "Profiling of the virtual handler resets.");
1346
1347 PGM_REG_COUNTER(&pStats->StatRZPhysHandlerReset, "/PGM/RZ/PhysHandlerReset", "The number of times PGMHandlerPhysicalReset is called.");
1348 PGM_REG_COUNTER(&pStats->StatR3PhysHandlerReset, "/PGM/R3/PhysHandlerReset", "The number of times PGMHandlerPhysicalReset is called.");
1349 PGM_REG_COUNTER(&pStats->StatRZPhysHandlerLookupHits, "/PGM/RZ/PhysHandlerLookupHits", "The number of cache hits when looking up physical handlers.");
1350 PGM_REG_COUNTER(&pStats->StatR3PhysHandlerLookupHits, "/PGM/R3/PhysHandlerLookupHits", "The number of cache hits when looking up physical handlers.");
1351 PGM_REG_COUNTER(&pStats->StatRZPhysHandlerLookupMisses, "/PGM/RZ/PhysHandlerLookupMisses", "The number of cache misses when looking up physical handlers.");
1352 PGM_REG_COUNTER(&pStats->StatR3PhysHandlerLookupMisses, "/PGM/R3/PhysHandlerLookupMisses", "The number of cache misses when looking up physical handlers.");
1353 PGM_REG_PROFILE(&pStats->StatRZVirtHandlerSearchByPhys, "/PGM/RZ/VirtHandlerSearchByPhys", "Profiling of pgmHandlerVirtualFindByPhysAddr.");
1354 PGM_REG_PROFILE(&pStats->StatR3VirtHandlerSearchByPhys, "/PGM/R3/VirtHandlerSearchByPhys", "Profiling of pgmHandlerVirtualFindByPhysAddr.");
1355
1356 PGM_REG_COUNTER(&pStats->StatRZPageReplaceShared, "/PGM/RZ/Page/ReplacedShared", "Times a shared page was replaced.");
1357 PGM_REG_COUNTER(&pStats->StatRZPageReplaceZero, "/PGM/RZ/Page/ReplacedZero", "Times the zero page was replaced.");
1358/// @todo PGM_REG_COUNTER(&pStats->StatRZPageHandyAllocs, "/PGM/RZ/Page/HandyAllocs", "Number of times we've allocated more handy pages.");
1359 PGM_REG_COUNTER(&pStats->StatR3PageReplaceShared, "/PGM/R3/Page/ReplacedShared", "Times a shared page was replaced.");
1360 PGM_REG_COUNTER(&pStats->StatR3PageReplaceZero, "/PGM/R3/Page/ReplacedZero", "Times the zero page was replaced.");
1361/// @todo PGM_REG_COUNTER(&pStats->StatR3PageHandyAllocs, "/PGM/R3/Page/HandyAllocs", "Number of times we've allocated more handy pages.");
1362
1363 PGM_REG_COUNTER(&pStats->StatRZPhysRead, "/PGM/RZ/Phys/Read", "The number of times PGMPhysRead was called.");
1364 PGM_REG_COUNTER_BYTES(&pStats->StatRZPhysReadBytes, "/PGM/RZ/Phys/Read/Bytes", "The number of bytes read by PGMPhysRead.");
1365 PGM_REG_COUNTER(&pStats->StatRZPhysWrite, "/PGM/RZ/Phys/Write", "The number of times PGMPhysWrite was called.");
1366 PGM_REG_COUNTER_BYTES(&pStats->StatRZPhysWriteBytes, "/PGM/RZ/Phys/Write/Bytes", "The number of bytes written by PGMPhysWrite.");
1367 PGM_REG_COUNTER(&pStats->StatRZPhysSimpleRead, "/PGM/RZ/Phys/Simple/Read", "The number of times PGMPhysSimpleReadGCPtr was called.");
1368 PGM_REG_COUNTER_BYTES(&pStats->StatRZPhysSimpleReadBytes, "/PGM/RZ/Phys/Simple/Read/Bytes", "The number of bytes read by PGMPhysSimpleReadGCPtr.");
1369 PGM_REG_COUNTER(&pStats->StatRZPhysSimpleWrite, "/PGM/RZ/Phys/Simple/Write", "The number of times PGMPhysSimpleWriteGCPtr was called.");
1370 PGM_REG_COUNTER_BYTES(&pStats->StatRZPhysSimpleWriteBytes, "/PGM/RZ/Phys/Simple/Write/Bytes", "The number of bytes written by PGMPhysSimpleWriteGCPtr.");
1371
1372 /* GC only: */
1373 PGM_REG_COUNTER(&pStats->StatRCInvlPgConflict, "/PGM/RC/InvlPgConflict", "Number of times PGMInvalidatePage() detected a mapping conflict.");
1374 PGM_REG_COUNTER(&pStats->StatRCInvlPgSyncMonCR3, "/PGM/RC/InvlPgSyncMonitorCR3", "Number of times PGMInvalidatePage() ran into PGM_SYNC_MONITOR_CR3.");
1375
1376 PGM_REG_COUNTER(&pStats->StatRCPhysRead, "/PGM/RC/Phys/Read", "The number of times PGMPhysRead was called.");
1377 PGM_REG_COUNTER_BYTES(&pStats->StatRCPhysReadBytes, "/PGM/RC/Phys/Read/Bytes", "The number of bytes read by PGMPhysRead.");
1378 PGM_REG_COUNTER(&pStats->StatRCPhysWrite, "/PGM/RC/Phys/Write", "The number of times PGMPhysWrite was called.");
1379 PGM_REG_COUNTER_BYTES(&pStats->StatRCPhysWriteBytes, "/PGM/RC/Phys/Write/Bytes", "The number of bytes written by PGMPhysWrite.");
1380 PGM_REG_COUNTER(&pStats->StatRCPhysSimpleRead, "/PGM/RC/Phys/Simple/Read", "The number of times PGMPhysSimpleReadGCPtr was called.");
1381 PGM_REG_COUNTER_BYTES(&pStats->StatRCPhysSimpleReadBytes, "/PGM/RC/Phys/Simple/Read/Bytes", "The number of bytes read by PGMPhysSimpleReadGCPtr.");
1382 PGM_REG_COUNTER(&pStats->StatRCPhysSimpleWrite, "/PGM/RC/Phys/Simple/Write", "The number of times PGMPhysSimpleWriteGCPtr was called.");
1383 PGM_REG_COUNTER_BYTES(&pStats->StatRCPhysSimpleWriteBytes, "/PGM/RC/Phys/Simple/Write/Bytes", "The number of bytes written by PGMPhysSimpleWriteGCPtr.");
1384
1385 PGM_REG_COUNTER(&pStats->StatTrackVirgin, "/PGM/Track/Virgin", "The number of first time shadowings");
1386 PGM_REG_COUNTER(&pStats->StatTrackAliased, "/PGM/Track/Aliased", "The number of times switching to cRef2, i.e. the page is being shadowed by two PTs.");
1387 PGM_REG_COUNTER(&pStats->StatTrackAliasedMany, "/PGM/Track/AliasedMany", "The number of times we're tracking using cRef2.");
1388 PGM_REG_COUNTER(&pStats->StatTrackAliasedLots, "/PGM/Track/AliasedLots", "The number of times we're hitting pages which has overflowed cRef2");
1389 PGM_REG_COUNTER(&pStats->StatTrackOverflows, "/PGM/Track/Overflows", "The number of times the extent list grows too long.");
1390 PGM_REG_COUNTER(&pStats->StatTrackNoExtentsLeft, "/PGM/Track/NoExtentLeft", "The number of times the extent list was exhausted.");
1391 PGM_REG_PROFILE(&pStats->StatTrackDeref, "/PGM/Track/Deref", "Profiling of SyncPageWorkerTrackDeref (expensive).");
1392
1393# undef PGM_REG_COUNTER
1394# undef PGM_REG_PROFILE
1395#endif
1396
1397 /*
1398 * Note! The layout below matches the member layout exactly!
1399 */
1400
1401 /*
1402 * Common - stats
1403 */
1404 for (VMCPUID idCpu = 0; idCpu < pVM->cCpus; idCpu++)
1405 {
1406 PPGMCPU pPgmCpu = &pVM->aCpus[idCpu].pgm.s;
1407
1408#define PGM_REG_COUNTER(a, b, c) \
1409 rc = STAMR3RegisterF(pVM, a, STAMTYPE_COUNTER, STAMVISIBILITY_ALWAYS, STAMUNIT_OCCURENCES, c, b, idCpu); \
1410 AssertRC(rc);
1411#define PGM_REG_PROFILE(a, b, c) \
1412 rc = STAMR3RegisterF(pVM, a, STAMTYPE_PROFILE, STAMVISIBILITY_ALWAYS, STAMUNIT_TICKS_PER_CALL, c, b, idCpu); \
1413 AssertRC(rc);
1414
1415 PGM_REG_COUNTER(&pPgmCpu->cGuestModeChanges, "/PGM/CPU%u/cGuestModeChanges", "Number of guest mode changes.");
1416 PGM_REG_COUNTER(&pPgmCpu->cA20Changes, "/PGM/CPU%u/cA20Changes", "Number of A20 gate changes.");
1417
1418#ifdef VBOX_WITH_STATISTICS
1419 PGMCPUSTATS *pCpuStats = pVM->aCpus[idCpu].pgm.s.pStatsR3;
1420
1421# if 0 /* rarely useful; leave for debugging. */
1422 for (unsigned j = 0; j < RT_ELEMENTS(pPgmCpu->StatSyncPtPD); j++)
1423 STAMR3RegisterF(pVM, &pCpuStats->StatSyncPtPD[i], STAMTYPE_COUNTER, STAMVISIBILITY_USED, STAMUNIT_OCCURENCES,
1424 "The number of SyncPT per PD n.", "/PGM/CPU%u/PDSyncPT/%04X", i, j);
1425 for (unsigned j = 0; j < RT_ELEMENTS(pCpuStats->StatSyncPagePD); j++)
1426 STAMR3RegisterF(pVM, &pCpuStats->StatSyncPagePD[i], STAMTYPE_COUNTER, STAMVISIBILITY_USED, STAMUNIT_OCCURENCES,
1427 "The number of SyncPage per PD n.", "/PGM/CPU%u/PDSyncPage/%04X", i, j);
1428# endif
1429 /* R0 only: */
1430 PGM_REG_PROFILE(&pCpuStats->StatR0NpMiscfg, "/PGM/CPU%u/R0/NpMiscfg", "PGMR0Trap0eHandlerNPMisconfig() profiling.");
1431 PGM_REG_COUNTER(&pCpuStats->StatR0NpMiscfgSyncPage, "/PGM/CPU%u/R0/NpMiscfgSyncPage", "SyncPage calls from PGMR0Trap0eHandlerNPMisconfig().");
1432
1433 /* RZ only: */
1434 PGM_REG_PROFILE(&pCpuStats->StatRZTrap0e, "/PGM/CPU%u/RZ/Trap0e", "Profiling of the PGMTrap0eHandler() body.");
1435 PGM_REG_PROFILE(&pCpuStats->StatRZTrap0eTime2Ballooned, "/PGM/CPU%u/RZ/Trap0e/Time2/Ballooned", "Profiling of the Trap0eHandler body when the cause is read access to a ballooned page.");
1436 PGM_REG_PROFILE(&pCpuStats->StatRZTrap0eTime2CSAM, "/PGM/CPU%u/RZ/Trap0e/Time2/CSAM", "Profiling of the Trap0eHandler body when the cause is CSAM.");
1437 PGM_REG_PROFILE(&pCpuStats->StatRZTrap0eTime2DirtyAndAccessed, "/PGM/CPU%u/RZ/Trap0e/Time2/DirtyAndAccessedBits", "Profiling of the Trap0eHandler body when the cause is dirty and/or accessed bit emulation.");
1438 PGM_REG_PROFILE(&pCpuStats->StatRZTrap0eTime2GuestTrap, "/PGM/CPU%u/RZ/Trap0e/Time2/GuestTrap", "Profiling of the Trap0eHandler body when the cause is a guest trap.");
1439 PGM_REG_PROFILE(&pCpuStats->StatRZTrap0eTime2HndPhys, "/PGM/CPU%u/RZ/Trap0e/Time2/HandlerPhysical", "Profiling of the Trap0eHandler body when the cause is a physical handler.");
1440 PGM_REG_PROFILE(&pCpuStats->StatRZTrap0eTime2HndVirt, "/PGM/CPU%u/RZ/Trap0e/Time2/HandlerVirtual", "Profiling of the Trap0eHandler body when the cause is a virtual handler.");
1441 PGM_REG_PROFILE(&pCpuStats->StatRZTrap0eTime2HndUnhandled, "/PGM/CPU%u/RZ/Trap0e/Time2/HandlerUnhandled", "Profiling of the Trap0eHandler body when the cause is access outside the monitored areas of a monitored page.");
1442 PGM_REG_PROFILE(&pCpuStats->StatRZTrap0eTime2InvalidPhys, "/PGM/CPU%u/RZ/Trap0e/Time2/InvalidPhys", "Profiling of the Trap0eHandler body when the cause is access to an invalid physical guest address.");
1443 PGM_REG_PROFILE(&pCpuStats->StatRZTrap0eTime2MakeWritable, "/PGM/CPU%u/RZ/Trap0e/Time2/MakeWritable", "Profiling of the Trap0eHandler body when the cause is that a page needed to be made writeable.");
1444 PGM_REG_PROFILE(&pCpuStats->StatRZTrap0eTime2Mapping, "/PGM/CPU%u/RZ/Trap0e/Time2/Mapping", "Profiling of the Trap0eHandler body when the cause is related to the guest mappings.");
1445 PGM_REG_PROFILE(&pCpuStats->StatRZTrap0eTime2Misc, "/PGM/CPU%u/RZ/Trap0e/Time2/Misc", "Profiling of the Trap0eHandler body when the cause is not known.");
1446 PGM_REG_PROFILE(&pCpuStats->StatRZTrap0eTime2OutOfSync, "/PGM/CPU%u/RZ/Trap0e/Time2/OutOfSync", "Profiling of the Trap0eHandler body when the cause is an out-of-sync page.");
1447 PGM_REG_PROFILE(&pCpuStats->StatRZTrap0eTime2OutOfSyncHndPhys, "/PGM/CPU%u/RZ/Trap0e/Time2/OutOfSyncHndPhys", "Profiling of the Trap0eHandler body when the cause is an out-of-sync physical handler page.");
1448 PGM_REG_PROFILE(&pCpuStats->StatRZTrap0eTime2OutOfSyncHndVirt, "/PGM/CPU%u/RZ/Trap0e/Time2/OutOfSyncHndVirt", "Profiling of the Trap0eHandler body when the cause is an out-of-sync virtual handler page.");
1449 PGM_REG_PROFILE(&pCpuStats->StatRZTrap0eTime2OutOfSyncHndObs, "/PGM/CPU%u/RZ/Trap0e/Time2/OutOfSyncObsHnd", "Profiling of the Trap0eHandler body when the cause is an obsolete handler page.");
1450 PGM_REG_PROFILE(&pCpuStats->StatRZTrap0eTime2SyncPT, "/PGM/CPU%u/RZ/Trap0e/Time2/SyncPT", "Profiling of the Trap0eHandler body when the cause is lazy syncing of a PT.");
1451 PGM_REG_PROFILE(&pCpuStats->StatRZTrap0eTime2WPEmulation, "/PGM/CPU%u/RZ/Trap0e/Time2/WPEmulation", "Profiling of the Trap0eHandler body when the cause is CR0.WP emulation.");
1452 PGM_REG_PROFILE(&pCpuStats->StatRZTrap0eTime2Wp0RoUsHack, "/PGM/CPU%u/RZ/Trap0e/Time2/WP0R0USHack", "Profiling of the Trap0eHandler body when the cause is CR0.WP and netware hack to be enabled.");
1453 PGM_REG_PROFILE(&pCpuStats->StatRZTrap0eTime2Wp0RoUsUnhack, "/PGM/CPU%u/RZ/Trap0e/Time2/WP0R0USUnhack", "Profiling of the Trap0eHandler body when the cause is CR0.WP and netware hack to be disabled.");
1454 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eConflicts, "/PGM/CPU%u/RZ/Trap0e/Conflicts", "The number of times #PF was caused by an undetected conflict.");
1455 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eHandlersMapping, "/PGM/CPU%u/RZ/Trap0e/Handlers/Mapping", "Number of traps due to access handlers in mappings.");
1456 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eHandlersOutOfSync, "/PGM/CPU%u/RZ/Trap0e/Handlers/OutOfSync", "Number of traps due to out-of-sync handled pages.");
1457 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eHandlersPhysAll, "/PGM/CPU%u/RZ/Trap0e/Handlers/PhysAll", "Number of traps due to physical all-access handlers.");
1458 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eHandlersPhysAllOpt, "/PGM/CPU%u/RZ/Trap0e/Handlers/PhysAllOpt", "Number of the physical all-access handler traps using the optimization.");
1459 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eHandlersPhysWrite, "/PGM/CPU%u/RZ/Trap0e/Handlers/PhysWrite", "Number of traps due to physical write-access handlers.");
1460 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eHandlersVirtual, "/PGM/CPU%u/RZ/Trap0e/Handlers/Virtual", "Number of traps due to virtual access handlers.");
1461 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eHandlersVirtualByPhys, "/PGM/CPU%u/RZ/Trap0e/Handlers/VirtualByPhys", "Number of traps due to virtual access handlers by physical address.");
1462 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eHandlersVirtualUnmarked,"/PGM/CPU%u/RZ/Trap0e/Handlers/VirtualUnmarked","Number of traps due to virtual access handlers by virtual address (without proper physical flags).");
1463 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eHandlersUnhandled, "/PGM/CPU%u/RZ/Trap0e/Handlers/Unhandled", "Number of traps due to access outside range of monitored page(s).");
1464 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eHandlersInvalid, "/PGM/CPU%u/RZ/Trap0e/Handlers/Invalid", "Number of traps due to access to invalid physical memory.");
1465 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eUSNotPresentRead, "/PGM/CPU%u/RZ/Trap0e/Err/User/NPRead", "Number of user mode not present read page faults.");
1466 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eUSNotPresentWrite, "/PGM/CPU%u/RZ/Trap0e/Err/User/NPWrite", "Number of user mode not present write page faults.");
1467 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eUSWrite, "/PGM/CPU%u/RZ/Trap0e/Err/User/Write", "Number of user mode write page faults.");
1468 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eUSReserved, "/PGM/CPU%u/RZ/Trap0e/Err/User/Reserved", "Number of user mode reserved bit page faults.");
1469 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eUSNXE, "/PGM/CPU%u/RZ/Trap0e/Err/User/NXE", "Number of user mode NXE page faults.");
1470 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eUSRead, "/PGM/CPU%u/RZ/Trap0e/Err/User/Read", "Number of user mode read page faults.");
1471 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eSVNotPresentRead, "/PGM/CPU%u/RZ/Trap0e/Err/Supervisor/NPRead", "Number of supervisor mode not present read page faults.");
1472 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eSVNotPresentWrite, "/PGM/CPU%u/RZ/Trap0e/Err/Supervisor/NPWrite", "Number of supervisor mode not present write page faults.");
1473 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eSVWrite, "/PGM/CPU%u/RZ/Trap0e/Err/Supervisor/Write", "Number of supervisor mode write page faults.");
1474 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eSVReserved, "/PGM/CPU%u/RZ/Trap0e/Err/Supervisor/Reserved", "Number of supervisor mode reserved bit page faults.");
1475 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eSNXE, "/PGM/CPU%u/RZ/Trap0e/Err/Supervisor/NXE", "Number of supervisor mode NXE page faults.");
1476 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eGuestPF, "/PGM/CPU%u/RZ/Trap0e/GuestPF", "Number of real guest page faults.");
1477 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eGuestPFMapping, "/PGM/CPU%u/RZ/Trap0e/GuestPF/InMapping", "Number of real guest page faults in a mapping.");
1478 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eWPEmulInRZ, "/PGM/CPU%u/RZ/Trap0e/WP/InRZ", "Number of guest page faults due to X86_CR0_WP emulation.");
1479 PGM_REG_COUNTER(&pCpuStats->StatRZTrap0eWPEmulToR3, "/PGM/CPU%u/RZ/Trap0e/WP/ToR3", "Number of guest page faults due to X86_CR0_WP emulation (forward to R3 for emulation).");
1480#if 0 /* rarely useful; leave for debugging. */
1481 for (unsigned j = 0; j < RT_ELEMENTS(pCpuStats->StatRZTrap0ePD); j++)
1482 STAMR3RegisterF(pVM, &pCpuStats->StatRZTrap0ePD[i], STAMTYPE_COUNTER, STAMVISIBILITY_USED, STAMUNIT_OCCURENCES,
1483 "The number of traps in page directory n.", "/PGM/CPU%u/RZ/Trap0e/PD/%04X", i, j);
1484#endif
1485 PGM_REG_COUNTER(&pCpuStats->StatRZGuestCR3WriteHandled, "/PGM/CPU%u/RZ/CR3WriteHandled", "The number of times the Guest CR3 change was successfully handled.");
1486 PGM_REG_COUNTER(&pCpuStats->StatRZGuestCR3WriteUnhandled, "/PGM/CPU%u/RZ/CR3WriteUnhandled", "The number of times the Guest CR3 change was passed back to the recompiler.");
1487 PGM_REG_COUNTER(&pCpuStats->StatRZGuestCR3WriteConflict, "/PGM/CPU%u/RZ/CR3WriteConflict", "The number of times the Guest CR3 monitoring detected a conflict.");
1488 PGM_REG_COUNTER(&pCpuStats->StatRZGuestROMWriteHandled, "/PGM/CPU%u/RZ/ROMWriteHandled", "The number of times the Guest ROM change was successfully handled.");
1489 PGM_REG_COUNTER(&pCpuStats->StatRZGuestROMWriteUnhandled, "/PGM/CPU%u/RZ/ROMWriteUnhandled", "The number of times the Guest ROM change was passed back to the recompiler.");
1490
1491 PGM_REG_COUNTER(&pCpuStats->StatRZDynMapMigrateInvlPg, "/PGM/CPU%u/RZ/DynMap/MigrateInvlPg", "invlpg count in PGMR0DynMapMigrateAutoSet.");
1492 PGM_REG_PROFILE(&pCpuStats->StatRZDynMapGCPageInl, "/PGM/CPU%u/RZ/DynMap/PageGCPageInl", "Calls to pgmR0DynMapGCPageInlined.");
1493 PGM_REG_COUNTER(&pCpuStats->StatRZDynMapGCPageInlHits, "/PGM/CPU%u/RZ/DynMap/PageGCPageInl/Hits", "Hash table lookup hits.");
1494 PGM_REG_COUNTER(&pCpuStats->StatRZDynMapGCPageInlMisses, "/PGM/CPU%u/RZ/DynMap/PageGCPageInl/Misses", "Misses that falls back to the code common.");
1495 PGM_REG_COUNTER(&pCpuStats->StatRZDynMapGCPageInlRamHits, "/PGM/CPU%u/RZ/DynMap/PageGCPageInl/RamHits", "1st ram range hits.");
1496 PGM_REG_COUNTER(&pCpuStats->StatRZDynMapGCPageInlRamMisses, "/PGM/CPU%u/RZ/DynMap/PageGCPageInl/RamMisses", "1st ram range misses, takes slow path.");
1497 PGM_REG_PROFILE(&pCpuStats->StatRZDynMapHCPageInl, "/PGM/CPU%u/RZ/DynMap/PageHCPageInl", "Calls to pgmRZDynMapHCPageInlined.");
1498 PGM_REG_COUNTER(&pCpuStats->StatRZDynMapHCPageInlHits, "/PGM/CPU%u/RZ/DynMap/PageHCPageInl/Hits", "Hash table lookup hits.");
1499 PGM_REG_COUNTER(&pCpuStats->StatRZDynMapHCPageInlMisses, "/PGM/CPU%u/RZ/DynMap/PageHCPageInl/Misses", "Misses that falls back to the code common.");
1500 PGM_REG_COUNTER(&pCpuStats->StatRZDynMapPage, "/PGM/CPU%u/RZ/DynMap/Page", "Calls to pgmR0DynMapPage");
1501 PGM_REG_COUNTER(&pCpuStats->StatRZDynMapSetOptimize, "/PGM/CPU%u/RZ/DynMap/Page/SetOptimize", "Calls to pgmRZDynMapOptimizeAutoSet.");
1502 PGM_REG_COUNTER(&pCpuStats->StatRZDynMapSetSearchFlushes, "/PGM/CPU%u/RZ/DynMap/Page/SetSearchFlushes", "Set search restoring to subset flushes.");
1503 PGM_REG_COUNTER(&pCpuStats->StatRZDynMapSetSearchHits, "/PGM/CPU%u/RZ/DynMap/Page/SetSearchHits", "Set search hits.");
1504 PGM_REG_COUNTER(&pCpuStats->StatRZDynMapSetSearchMisses, "/PGM/CPU%u/RZ/DynMap/Page/SetSearchMisses", "Set search misses.");
1505 PGM_REG_PROFILE(&pCpuStats->StatRZDynMapHCPage, "/PGM/CPU%u/RZ/DynMap/Page/HCPage", "Calls to pgmRZDynMapHCPageCommon (ring-0).");
1506 PGM_REG_COUNTER(&pCpuStats->StatRZDynMapPageHits0, "/PGM/CPU%u/RZ/DynMap/Page/Hits0", "Hits at iPage+0");
1507 PGM_REG_COUNTER(&pCpuStats->StatRZDynMapPageHits1, "/PGM/CPU%u/RZ/DynMap/Page/Hits1", "Hits at iPage+1");
1508 PGM_REG_COUNTER(&pCpuStats->StatRZDynMapPageHits2, "/PGM/CPU%u/RZ/DynMap/Page/Hits2", "Hits at iPage+2");
1509 PGM_REG_COUNTER(&pCpuStats->StatRZDynMapPageInvlPg, "/PGM/CPU%u/RZ/DynMap/Page/InvlPg", "invlpg count in pgmR0DynMapPageSlow.");
1510 PGM_REG_COUNTER(&pCpuStats->StatRZDynMapPageSlow, "/PGM/CPU%u/RZ/DynMap/Page/Slow", "Calls to pgmR0DynMapPageSlow - subtract this from pgmR0DynMapPage to get 1st level hits.");
1511 PGM_REG_COUNTER(&pCpuStats->StatRZDynMapPageSlowLoopHits, "/PGM/CPU%u/RZ/DynMap/Page/SlowLoopHits" , "Hits in the loop path.");
1512 PGM_REG_COUNTER(&pCpuStats->StatRZDynMapPageSlowLoopMisses, "/PGM/CPU%u/RZ/DynMap/Page/SlowLoopMisses", "Misses in the loop path. NonLoopMisses = Slow - SlowLoopHit - SlowLoopMisses");
1513 //PGM_REG_COUNTER(&pCpuStats->StatRZDynMapPageSlowLostHits, "/PGM/CPU%u/R0/DynMap/Page/SlowLostHits", "Lost hits.");
1514 PGM_REG_COUNTER(&pCpuStats->StatRZDynMapSubsets, "/PGM/CPU%u/RZ/DynMap/Subsets", "Times PGMRZDynMapPushAutoSubset was called.");
1515 PGM_REG_COUNTER(&pCpuStats->StatRZDynMapPopFlushes, "/PGM/CPU%u/RZ/DynMap/SubsetPopFlushes", "Times PGMRZDynMapPopAutoSubset flushes the subset.");
1516 PGM_REG_COUNTER(&pCpuStats->aStatRZDynMapSetFilledPct[0], "/PGM/CPU%u/RZ/DynMap/SetFilledPct000..09", "00-09% filled (RC: min(set-size, dynmap-size))");
1517 PGM_REG_COUNTER(&pCpuStats->aStatRZDynMapSetFilledPct[1], "/PGM/CPU%u/RZ/DynMap/SetFilledPct010..19", "10-19% filled (RC: min(set-size, dynmap-size))");
1518 PGM_REG_COUNTER(&pCpuStats->aStatRZDynMapSetFilledPct[2], "/PGM/CPU%u/RZ/DynMap/SetFilledPct020..29", "20-29% filled (RC: min(set-size, dynmap-size))");
1519 PGM_REG_COUNTER(&pCpuStats->aStatRZDynMapSetFilledPct[3], "/PGM/CPU%u/RZ/DynMap/SetFilledPct030..39", "30-39% filled (RC: min(set-size, dynmap-size))");
1520 PGM_REG_COUNTER(&pCpuStats->aStatRZDynMapSetFilledPct[4], "/PGM/CPU%u/RZ/DynMap/SetFilledPct040..49", "40-49% filled (RC: min(set-size, dynmap-size))");
1521 PGM_REG_COUNTER(&pCpuStats->aStatRZDynMapSetFilledPct[5], "/PGM/CPU%u/RZ/DynMap/SetFilledPct050..59", "50-59% filled (RC: min(set-size, dynmap-size))");
1522 PGM_REG_COUNTER(&pCpuStats->aStatRZDynMapSetFilledPct[6], "/PGM/CPU%u/RZ/DynMap/SetFilledPct060..69", "60-69% filled (RC: min(set-size, dynmap-size))");
1523 PGM_REG_COUNTER(&pCpuStats->aStatRZDynMapSetFilledPct[7], "/PGM/CPU%u/RZ/DynMap/SetFilledPct070..79", "70-79% filled (RC: min(set-size, dynmap-size))");
1524 PGM_REG_COUNTER(&pCpuStats->aStatRZDynMapSetFilledPct[8], "/PGM/CPU%u/RZ/DynMap/SetFilledPct080..89", "80-89% filled (RC: min(set-size, dynmap-size))");
1525 PGM_REG_COUNTER(&pCpuStats->aStatRZDynMapSetFilledPct[9], "/PGM/CPU%u/RZ/DynMap/SetFilledPct090..99", "90-99% filled (RC: min(set-size, dynmap-size))");
1526 PGM_REG_COUNTER(&pCpuStats->aStatRZDynMapSetFilledPct[10], "/PGM/CPU%u/RZ/DynMap/SetFilledPct100", "100% filled (RC: min(set-size, dynmap-size))");
1527
1528 /* HC only: */
1529
1530 /* RZ & R3: */
1531 PGM_REG_PROFILE(&pCpuStats->StatRZSyncCR3, "/PGM/CPU%u/RZ/SyncCR3", "Profiling of the PGMSyncCR3() body.");
1532 PGM_REG_PROFILE(&pCpuStats->StatRZSyncCR3Handlers, "/PGM/CPU%u/RZ/SyncCR3/Handlers", "Profiling of the PGMSyncCR3() update handler section.");
1533 PGM_REG_COUNTER(&pCpuStats->StatRZSyncCR3Global, "/PGM/CPU%u/RZ/SyncCR3/Global", "The number of global CR3 syncs.");
1534 PGM_REG_COUNTER(&pCpuStats->StatRZSyncCR3NotGlobal, "/PGM/CPU%u/RZ/SyncCR3/NotGlobal", "The number of non-global CR3 syncs.");
1535 PGM_REG_COUNTER(&pCpuStats->StatRZSyncCR3DstCacheHit, "/PGM/CPU%u/RZ/SyncCR3/DstChacheHit", "The number of times we got some kind of a cache hit.");
1536 PGM_REG_COUNTER(&pCpuStats->StatRZSyncCR3DstFreed, "/PGM/CPU%u/RZ/SyncCR3/DstFreed", "The number of times we've had to free a shadow entry.");
1537 PGM_REG_COUNTER(&pCpuStats->StatRZSyncCR3DstFreedSrcNP, "/PGM/CPU%u/RZ/SyncCR3/DstFreedSrcNP", "The number of times we've had to free a shadow entry for which the source entry was not present.");
1538 PGM_REG_COUNTER(&pCpuStats->StatRZSyncCR3DstNotPresent, "/PGM/CPU%u/RZ/SyncCR3/DstNotPresent", "The number of times we've encountered a not present shadow entry for a present guest entry.");
1539 PGM_REG_COUNTER(&pCpuStats->StatRZSyncCR3DstSkippedGlobalPD, "/PGM/CPU%u/RZ/SyncCR3/DstSkippedGlobalPD", "The number of times a global page directory wasn't flushed.");
1540 PGM_REG_COUNTER(&pCpuStats->StatRZSyncCR3DstSkippedGlobalPT, "/PGM/CPU%u/RZ/SyncCR3/DstSkippedGlobalPT", "The number of times a page table with only global entries wasn't flushed.");
1541 PGM_REG_PROFILE(&pCpuStats->StatRZSyncPT, "/PGM/CPU%u/RZ/SyncPT", "Profiling of the pfnSyncPT() body.");
1542 PGM_REG_COUNTER(&pCpuStats->StatRZSyncPTFailed, "/PGM/CPU%u/RZ/SyncPT/Failed", "The number of times pfnSyncPT() failed.");
1543 PGM_REG_COUNTER(&pCpuStats->StatRZSyncPT4K, "/PGM/CPU%u/RZ/SyncPT/4K", "Nr of 4K PT syncs");
1544 PGM_REG_COUNTER(&pCpuStats->StatRZSyncPT4M, "/PGM/CPU%u/RZ/SyncPT/4M", "Nr of 4M PT syncs");
1545 PGM_REG_COUNTER(&pCpuStats->StatRZSyncPagePDNAs, "/PGM/CPU%u/RZ/SyncPagePDNAs", "The number of time we've marked a PD not present from SyncPage to virtualize the accessed bit.");
1546 PGM_REG_COUNTER(&pCpuStats->StatRZSyncPagePDOutOfSync, "/PGM/CPU%u/RZ/SyncPagePDOutOfSync", "The number of time we've encountered an out-of-sync PD in SyncPage.");
1547 PGM_REG_COUNTER(&pCpuStats->StatRZAccessedPage, "/PGM/CPU%u/RZ/AccessedPage", "The number of pages marked not present for accessed bit emulation.");
1548 PGM_REG_PROFILE(&pCpuStats->StatRZDirtyBitTracking, "/PGM/CPU%u/RZ/DirtyPage", "Profiling the dirty bit tracking in CheckPageFault().");
1549 PGM_REG_COUNTER(&pCpuStats->StatRZDirtyPage, "/PGM/CPU%u/RZ/DirtyPage/Mark", "The number of pages marked read-only for dirty bit tracking.");
1550 PGM_REG_COUNTER(&pCpuStats->StatRZDirtyPageBig, "/PGM/CPU%u/RZ/DirtyPage/MarkBig", "The number of 4MB pages marked read-only for dirty bit tracking.");
1551 PGM_REG_COUNTER(&pCpuStats->StatRZDirtyPageSkipped, "/PGM/CPU%u/RZ/DirtyPage/Skipped", "The number of pages already dirty or readonly.");
1552 PGM_REG_COUNTER(&pCpuStats->StatRZDirtyPageTrap, "/PGM/CPU%u/RZ/DirtyPage/Trap", "The number of traps generated for dirty bit tracking.");
1553 PGM_REG_COUNTER(&pCpuStats->StatRZDirtyPageStale, "/PGM/CPU%u/RZ/DirtyPage/Stale", "The number of traps generated for dirty bit tracking (stale tlb entries).");
1554 PGM_REG_COUNTER(&pCpuStats->StatRZDirtiedPage, "/PGM/CPU%u/RZ/DirtyPage/SetDirty", "The number of pages marked dirty because of write accesses.");
1555 PGM_REG_COUNTER(&pCpuStats->StatRZDirtyTrackRealPF, "/PGM/CPU%u/RZ/DirtyPage/RealPF", "The number of real pages faults during dirty bit tracking.");
1556 PGM_REG_COUNTER(&pCpuStats->StatRZPageAlreadyDirty, "/PGM/CPU%u/RZ/DirtyPage/AlreadySet", "The number of pages already marked dirty because of write accesses.");
1557 PGM_REG_PROFILE(&pCpuStats->StatRZInvalidatePage, "/PGM/CPU%u/RZ/InvalidatePage", "PGMInvalidatePage() profiling.");
1558 PGM_REG_COUNTER(&pCpuStats->StatRZInvalidatePage4KBPages, "/PGM/CPU%u/RZ/InvalidatePage/4KBPages", "The number of times PGMInvalidatePage() was called for a 4KB page.");
1559 PGM_REG_COUNTER(&pCpuStats->StatRZInvalidatePage4MBPages, "/PGM/CPU%u/RZ/InvalidatePage/4MBPages", "The number of times PGMInvalidatePage() was called for a 4MB page.");
1560 PGM_REG_COUNTER(&pCpuStats->StatRZInvalidatePage4MBPagesSkip, "/PGM/CPU%u/RZ/InvalidatePage/4MBPagesSkip","The number of times PGMInvalidatePage() skipped a 4MB page.");
1561 PGM_REG_COUNTER(&pCpuStats->StatRZInvalidatePagePDMappings, "/PGM/CPU%u/RZ/InvalidatePage/PDMappings", "The number of times PGMInvalidatePage() was called for a page directory containing mappings (no conflict).");
1562 PGM_REG_COUNTER(&pCpuStats->StatRZInvalidatePagePDNAs, "/PGM/CPU%u/RZ/InvalidatePage/PDNAs", "The number of times PGMInvalidatePage() was called for a not accessed page directory.");
1563 PGM_REG_COUNTER(&pCpuStats->StatRZInvalidatePagePDNPs, "/PGM/CPU%u/RZ/InvalidatePage/PDNPs", "The number of times PGMInvalidatePage() was called for a not present page directory.");
1564 PGM_REG_COUNTER(&pCpuStats->StatRZInvalidatePagePDOutOfSync, "/PGM/CPU%u/RZ/InvalidatePage/PDOutOfSync", "The number of times PGMInvalidatePage() was called for an out of sync page directory.");
1565 PGM_REG_COUNTER(&pCpuStats->StatRZInvalidatePageSizeChanges, "/PGM/CPU%u/RZ/InvalidatePage/SizeChanges", "The number of times PGMInvalidatePage() was called on a page size change (4KB <-> 2/4MB).");
1566 PGM_REG_COUNTER(&pCpuStats->StatRZInvalidatePageSkipped, "/PGM/CPU%u/RZ/InvalidatePage/Skipped", "The number of times PGMInvalidatePage() was skipped due to not present shw or pending pending SyncCR3.");
1567 PGM_REG_COUNTER(&pCpuStats->StatRZPageOutOfSyncSupervisor, "/PGM/CPU%u/RZ/OutOfSync/SuperVisor", "Number of traps due to pages out of sync (P) and times VerifyAccessSyncPage calls SyncPage.");
1568 PGM_REG_COUNTER(&pCpuStats->StatRZPageOutOfSyncUser, "/PGM/CPU%u/RZ/OutOfSync/User", "Number of traps due to pages out of sync (P) and times VerifyAccessSyncPage calls SyncPage.");
1569 PGM_REG_COUNTER(&pCpuStats->StatRZPageOutOfSyncSupervisorWrite,"/PGM/CPU%u/RZ/OutOfSync/SuperVisorWrite", "Number of traps due to pages out of sync (RW) and times VerifyAccessSyncPage calls SyncPage.");
1570 PGM_REG_COUNTER(&pCpuStats->StatRZPageOutOfSyncUserWrite, "/PGM/CPU%u/RZ/OutOfSync/UserWrite", "Number of traps due to pages out of sync (RW) and times VerifyAccessSyncPage calls SyncPage.");
1571 PGM_REG_COUNTER(&pCpuStats->StatRZPageOutOfSyncBallloon, "/PGM/CPU%u/RZ/OutOfSync/Balloon", "The number of times a ballooned page was accessed (read).");
1572 PGM_REG_PROFILE(&pCpuStats->StatRZPrefetch, "/PGM/CPU%u/RZ/Prefetch", "PGMPrefetchPage profiling.");
1573 PGM_REG_PROFILE(&pCpuStats->StatRZFlushTLB, "/PGM/CPU%u/RZ/FlushTLB", "Profiling of the PGMFlushTLB() body.");
1574 PGM_REG_COUNTER(&pCpuStats->StatRZFlushTLBNewCR3, "/PGM/CPU%u/RZ/FlushTLB/NewCR3", "The number of times PGMFlushTLB was called with a new CR3, non-global. (switch)");
1575 PGM_REG_COUNTER(&pCpuStats->StatRZFlushTLBNewCR3Global, "/PGM/CPU%u/RZ/FlushTLB/NewCR3Global", "The number of times PGMFlushTLB was called with a new CR3, global. (switch)");
1576 PGM_REG_COUNTER(&pCpuStats->StatRZFlushTLBSameCR3, "/PGM/CPU%u/RZ/FlushTLB/SameCR3", "The number of times PGMFlushTLB was called with the same CR3, non-global. (flush)");
1577 PGM_REG_COUNTER(&pCpuStats->StatRZFlushTLBSameCR3Global, "/PGM/CPU%u/RZ/FlushTLB/SameCR3Global", "The number of times PGMFlushTLB was called with the same CR3, global. (flush)");
1578 PGM_REG_PROFILE(&pCpuStats->StatRZGstModifyPage, "/PGM/CPU%u/RZ/GstModifyPage", "Profiling of the PGMGstModifyPage() body.");
1579
1580 PGM_REG_PROFILE(&pCpuStats->StatR3SyncCR3, "/PGM/CPU%u/R3/SyncCR3", "Profiling of the PGMSyncCR3() body.");
1581 PGM_REG_PROFILE(&pCpuStats->StatR3SyncCR3Handlers, "/PGM/CPU%u/R3/SyncCR3/Handlers", "Profiling of the PGMSyncCR3() update handler section.");
1582 PGM_REG_COUNTER(&pCpuStats->StatR3SyncCR3Global, "/PGM/CPU%u/R3/SyncCR3/Global", "The number of global CR3 syncs.");
1583 PGM_REG_COUNTER(&pCpuStats->StatR3SyncCR3NotGlobal, "/PGM/CPU%u/R3/SyncCR3/NotGlobal", "The number of non-global CR3 syncs.");
1584 PGM_REG_COUNTER(&pCpuStats->StatR3SyncCR3DstCacheHit, "/PGM/CPU%u/R3/SyncCR3/DstChacheHit", "The number of times we got some kind of a cache hit.");
1585 PGM_REG_COUNTER(&pCpuStats->StatR3SyncCR3DstFreed, "/PGM/CPU%u/R3/SyncCR3/DstFreed", "The number of times we've had to free a shadow entry.");
1586 PGM_REG_COUNTER(&pCpuStats->StatR3SyncCR3DstFreedSrcNP, "/PGM/CPU%u/R3/SyncCR3/DstFreedSrcNP", "The number of times we've had to free a shadow entry for which the source entry was not present.");
1587 PGM_REG_COUNTER(&pCpuStats->StatR3SyncCR3DstNotPresent, "/PGM/CPU%u/R3/SyncCR3/DstNotPresent", "The number of times we've encountered a not present shadow entry for a present guest entry.");
1588 PGM_REG_COUNTER(&pCpuStats->StatR3SyncCR3DstSkippedGlobalPD, "/PGM/CPU%u/R3/SyncCR3/DstSkippedGlobalPD", "The number of times a global page directory wasn't flushed.");
1589 PGM_REG_COUNTER(&pCpuStats->StatR3SyncCR3DstSkippedGlobalPT, "/PGM/CPU%u/R3/SyncCR3/DstSkippedGlobalPT", "The number of times a page table with only global entries wasn't flushed.");
1590 PGM_REG_PROFILE(&pCpuStats->StatR3SyncPT, "/PGM/CPU%u/R3/SyncPT", "Profiling of the pfnSyncPT() body.");
1591 PGM_REG_COUNTER(&pCpuStats->StatR3SyncPTFailed, "/PGM/CPU%u/R3/SyncPT/Failed", "The number of times pfnSyncPT() failed.");
1592 PGM_REG_COUNTER(&pCpuStats->StatR3SyncPT4K, "/PGM/CPU%u/R3/SyncPT/4K", "Nr of 4K PT syncs");
1593 PGM_REG_COUNTER(&pCpuStats->StatR3SyncPT4M, "/PGM/CPU%u/R3/SyncPT/4M", "Nr of 4M PT syncs");
1594 PGM_REG_COUNTER(&pCpuStats->StatR3SyncPagePDNAs, "/PGM/CPU%u/R3/SyncPagePDNAs", "The number of time we've marked a PD not present from SyncPage to virtualize the accessed bit.");
1595 PGM_REG_COUNTER(&pCpuStats->StatR3SyncPagePDOutOfSync, "/PGM/CPU%u/R3/SyncPagePDOutOfSync", "The number of time we've encountered an out-of-sync PD in SyncPage.");
1596 PGM_REG_COUNTER(&pCpuStats->StatR3AccessedPage, "/PGM/CPU%u/R3/AccessedPage", "The number of pages marked not present for accessed bit emulation.");
1597 PGM_REG_PROFILE(&pCpuStats->StatR3DirtyBitTracking, "/PGM/CPU%u/R3/DirtyPage", "Profiling the dirty bit tracking in CheckPageFault().");
1598 PGM_REG_COUNTER(&pCpuStats->StatR3DirtyPage, "/PGM/CPU%u/R3/DirtyPage/Mark", "The number of pages marked read-only for dirty bit tracking.");
1599 PGM_REG_COUNTER(&pCpuStats->StatR3DirtyPageBig, "/PGM/CPU%u/R3/DirtyPage/MarkBig", "The number of 4MB pages marked read-only for dirty bit tracking.");
1600 PGM_REG_COUNTER(&pCpuStats->StatR3DirtyPageSkipped, "/PGM/CPU%u/R3/DirtyPage/Skipped", "The number of pages already dirty or readonly.");
1601 PGM_REG_COUNTER(&pCpuStats->StatR3DirtyPageTrap, "/PGM/CPU%u/R3/DirtyPage/Trap", "The number of traps generated for dirty bit tracking.");
1602 PGM_REG_COUNTER(&pCpuStats->StatR3DirtiedPage, "/PGM/CPU%u/R3/DirtyPage/SetDirty", "The number of pages marked dirty because of write accesses.");
1603 PGM_REG_COUNTER(&pCpuStats->StatR3DirtyTrackRealPF, "/PGM/CPU%u/R3/DirtyPage/RealPF", "The number of real pages faults during dirty bit tracking.");
1604 PGM_REG_COUNTER(&pCpuStats->StatR3PageAlreadyDirty, "/PGM/CPU%u/R3/DirtyPage/AlreadySet", "The number of pages already marked dirty because of write accesses.");
1605 PGM_REG_PROFILE(&pCpuStats->StatR3InvalidatePage, "/PGM/CPU%u/R3/InvalidatePage", "PGMInvalidatePage() profiling.");
1606 PGM_REG_COUNTER(&pCpuStats->StatR3InvalidatePage4KBPages, "/PGM/CPU%u/R3/InvalidatePage/4KBPages", "The number of times PGMInvalidatePage() was called for a 4KB page.");
1607 PGM_REG_COUNTER(&pCpuStats->StatR3InvalidatePage4MBPages, "/PGM/CPU%u/R3/InvalidatePage/4MBPages", "The number of times PGMInvalidatePage() was called for a 4MB page.");
1608 PGM_REG_COUNTER(&pCpuStats->StatR3InvalidatePage4MBPagesSkip, "/PGM/CPU%u/R3/InvalidatePage/4MBPagesSkip","The number of times PGMInvalidatePage() skipped a 4MB page.");
1609 PGM_REG_COUNTER(&pCpuStats->StatR3InvalidatePagePDMappings, "/PGM/CPU%u/R3/InvalidatePage/PDMappings", "The number of times PGMInvalidatePage() was called for a page directory containing mappings (no conflict).");
1610 PGM_REG_COUNTER(&pCpuStats->StatR3InvalidatePagePDNAs, "/PGM/CPU%u/R3/InvalidatePage/PDNAs", "The number of times PGMInvalidatePage() was called for a not accessed page directory.");
1611 PGM_REG_COUNTER(&pCpuStats->StatR3InvalidatePagePDNPs, "/PGM/CPU%u/R3/InvalidatePage/PDNPs", "The number of times PGMInvalidatePage() was called for a not present page directory.");
1612 PGM_REG_COUNTER(&pCpuStats->StatR3InvalidatePagePDOutOfSync, "/PGM/CPU%u/R3/InvalidatePage/PDOutOfSync", "The number of times PGMInvalidatePage() was called for an out of sync page directory.");
1613 PGM_REG_COUNTER(&pCpuStats->StatR3InvalidatePageSizeChanges, "/PGM/CPU%u/R3/InvalidatePage/SizeChanges", "The number of times PGMInvalidatePage() was called on a page size change (4KB <-> 2/4MB).");
1614 PGM_REG_COUNTER(&pCpuStats->StatR3InvalidatePageSkipped, "/PGM/CPU%u/R3/InvalidatePage/Skipped", "The number of times PGMInvalidatePage() was skipped due to not present shw or pending pending SyncCR3.");
1615 PGM_REG_COUNTER(&pCpuStats->StatR3PageOutOfSyncSupervisor, "/PGM/CPU%u/R3/OutOfSync/SuperVisor", "Number of traps due to pages out of sync and times VerifyAccessSyncPage calls SyncPage.");
1616 PGM_REG_COUNTER(&pCpuStats->StatR3PageOutOfSyncUser, "/PGM/CPU%u/R3/OutOfSync/User", "Number of traps due to pages out of sync and times VerifyAccessSyncPage calls SyncPage.");
1617 PGM_REG_COUNTER(&pCpuStats->StatR3PageOutOfSyncBallloon, "/PGM/CPU%u/R3/OutOfSync/Balloon", "The number of times a ballooned page was accessed (read).");
1618 PGM_REG_PROFILE(&pCpuStats->StatR3Prefetch, "/PGM/CPU%u/R3/Prefetch", "PGMPrefetchPage profiling.");
1619 PGM_REG_PROFILE(&pCpuStats->StatR3FlushTLB, "/PGM/CPU%u/R3/FlushTLB", "Profiling of the PGMFlushTLB() body.");
1620 PGM_REG_COUNTER(&pCpuStats->StatR3FlushTLBNewCR3, "/PGM/CPU%u/R3/FlushTLB/NewCR3", "The number of times PGMFlushTLB was called with a new CR3, non-global. (switch)");
1621 PGM_REG_COUNTER(&pCpuStats->StatR3FlushTLBNewCR3Global, "/PGM/CPU%u/R3/FlushTLB/NewCR3Global", "The number of times PGMFlushTLB was called with a new CR3, global. (switch)");
1622 PGM_REG_COUNTER(&pCpuStats->StatR3FlushTLBSameCR3, "/PGM/CPU%u/R3/FlushTLB/SameCR3", "The number of times PGMFlushTLB was called with the same CR3, non-global. (flush)");
1623 PGM_REG_COUNTER(&pCpuStats->StatR3FlushTLBSameCR3Global, "/PGM/CPU%u/R3/FlushTLB/SameCR3Global", "The number of times PGMFlushTLB was called with the same CR3, global. (flush)");
1624 PGM_REG_PROFILE(&pCpuStats->StatR3GstModifyPage, "/PGM/CPU%u/R3/GstModifyPage", "Profiling of the PGMGstModifyPage() body.");
1625#endif /* VBOX_WITH_STATISTICS */
1626
1627#undef PGM_REG_PROFILE
1628#undef PGM_REG_COUNTER
1629
1630 }
1631
1632 return VINF_SUCCESS;
1633}
1634
1635
1636/**
1637 * Init the PGM bits that rely on VMMR0 and MM to be fully initialized.
1638 *
1639 * The dynamic mapping area will also be allocated and initialized at this
1640 * time. We could allocate it during PGMR3Init of course, but the mapping
1641 * wouldn't be allocated at that time preventing us from setting up the
1642 * page table entries with the dummy page.
1643 *
1644 * @returns VBox status code.
1645 * @param pVM The cross context VM structure.
1646 */
1647VMMR3DECL(int) PGMR3InitDynMap(PVM pVM)
1648{
1649 RTGCPTR GCPtr;
1650 int rc;
1651
1652 /*
1653 * Reserve space for the dynamic mappings.
1654 */
1655 rc = MMR3HyperReserve(pVM, MM_HYPER_DYNAMIC_SIZE, "Dynamic mapping", &GCPtr);
1656 if (RT_SUCCESS(rc))
1657 pVM->pgm.s.pbDynPageMapBaseGC = GCPtr;
1658
1659 if ( RT_SUCCESS(rc)
1660 && (pVM->pgm.s.pbDynPageMapBaseGC >> X86_PD_PAE_SHIFT) != ((pVM->pgm.s.pbDynPageMapBaseGC + MM_HYPER_DYNAMIC_SIZE - 1) >> X86_PD_PAE_SHIFT))
1661 {
1662 rc = MMR3HyperReserve(pVM, MM_HYPER_DYNAMIC_SIZE, "Dynamic mapping not crossing", &GCPtr);
1663 if (RT_SUCCESS(rc))
1664 pVM->pgm.s.pbDynPageMapBaseGC = GCPtr;
1665 }
1666 if (RT_SUCCESS(rc))
1667 {
1668 AssertRelease((pVM->pgm.s.pbDynPageMapBaseGC >> X86_PD_PAE_SHIFT) == ((pVM->pgm.s.pbDynPageMapBaseGC + MM_HYPER_DYNAMIC_SIZE - 1) >> X86_PD_PAE_SHIFT));
1669 MMR3HyperReserve(pVM, PAGE_SIZE, "fence", NULL);
1670 }
1671 return rc;
1672}
1673
1674
1675/**
1676 * Ring-3 init finalizing.
1677 *
1678 * @returns VBox status code.
1679 * @param pVM The cross context VM structure.
1680 */
1681VMMR3DECL(int) PGMR3InitFinalize(PVM pVM)
1682{
1683 int rc = VERR_IPE_UNINITIALIZED_STATUS; /* (MSC incorrectly thinks it can be usused uninitialized) */
1684
1685 /*
1686 * Reserve space for the dynamic mappings.
1687 * Initialize the dynamic mapping pages with dummy pages to simply the cache.
1688 */
1689 /* get the pointer to the page table entries. */
1690 PPGMMAPPING pMapping = pgmGetMapping(pVM, pVM->pgm.s.pbDynPageMapBaseGC);
1691 AssertRelease(pMapping);
1692 const uintptr_t off = pVM->pgm.s.pbDynPageMapBaseGC - pMapping->GCPtr;
1693 const unsigned iPT = off >> X86_PD_SHIFT;
1694 const unsigned iPG = (off >> X86_PT_SHIFT) & X86_PT_MASK;
1695 pVM->pgm.s.paDynPageMap32BitPTEsGC = pMapping->aPTs[iPT].pPTRC + iPG * sizeof(pMapping->aPTs[0].pPTR3->a[0]);
1696 pVM->pgm.s.paDynPageMapPaePTEsGC = pMapping->aPTs[iPT].paPaePTsRC + iPG * sizeof(pMapping->aPTs[0].paPaePTsR3->a[0]);
1697
1698 /* init cache area */
1699 RTHCPHYS HCPhysDummy = MMR3PageDummyHCPhys(pVM);
1700 for (uint32_t offDynMap = 0; offDynMap < MM_HYPER_DYNAMIC_SIZE; offDynMap += PAGE_SIZE)
1701 {
1702 rc = PGMMap(pVM, pVM->pgm.s.pbDynPageMapBaseGC + offDynMap, HCPhysDummy, PAGE_SIZE, 0);
1703 AssertRCReturn(rc, rc);
1704 }
1705
1706 /*
1707 * Determine the max physical address width (MAXPHYADDR) and apply it to
1708 * all the mask members and stuff.
1709 */
1710 uint32_t cMaxPhysAddrWidth;
1711 uint32_t uMaxExtLeaf = ASMCpuId_EAX(0x80000000);
1712 if ( uMaxExtLeaf >= 0x80000008
1713 && uMaxExtLeaf <= 0x80000fff)
1714 {
1715 cMaxPhysAddrWidth = ASMCpuId_EAX(0x80000008) & 0xff;
1716 LogRel(("PGM: The CPU physical address width is %u bits\n", cMaxPhysAddrWidth));
1717 cMaxPhysAddrWidth = RT_MIN(52, cMaxPhysAddrWidth);
1718 pVM->pgm.s.fLessThan52PhysicalAddressBits = cMaxPhysAddrWidth < 52;
1719 for (uint32_t iBit = cMaxPhysAddrWidth; iBit < 52; iBit++)
1720 pVM->pgm.s.HCPhysInvMmioPg |= RT_BIT_64(iBit);
1721 }
1722 else
1723 {
1724 LogRel(("PGM: ASSUMING CPU physical address width of 48 bits (uMaxExtLeaf=%#x)\n", uMaxExtLeaf));
1725 cMaxPhysAddrWidth = 48;
1726 pVM->pgm.s.fLessThan52PhysicalAddressBits = true;
1727 pVM->pgm.s.HCPhysInvMmioPg |= UINT64_C(0x000f0000000000);
1728 }
1729
1730 /** @todo query from CPUM. */
1731 pVM->pgm.s.GCPhysInvAddrMask = 0;
1732 for (uint32_t iBit = cMaxPhysAddrWidth; iBit < 64; iBit++)
1733 pVM->pgm.s.GCPhysInvAddrMask |= RT_BIT_64(iBit);
1734
1735 /*
1736 * Initialize the invalid paging entry masks, assuming NX is disabled.
1737 */
1738 uint64_t fMbzPageFrameMask = pVM->pgm.s.GCPhysInvAddrMask & UINT64_C(0x000ffffffffff000);
1739 for (VMCPUID iCpu = 0; iCpu < pVM->cCpus; iCpu++)
1740 {
1741 PVMCPU pVCpu = &pVM->aCpus[iCpu];
1742
1743 /** @todo The manuals are not entirely clear whether the physical
1744 * address width is relevant. See table 5-9 in the intel
1745 * manual vs the PDE4M descriptions. Write testcase (NP). */
1746 pVCpu->pgm.s.fGst32BitMbzBigPdeMask = ((uint32_t)(fMbzPageFrameMask >> (32 - 13)) & X86_PDE4M_PG_HIGH_MASK)
1747 | X86_PDE4M_MBZ_MASK;
1748
1749 pVCpu->pgm.s.fGstPaeMbzPteMask = fMbzPageFrameMask | X86_PTE_PAE_MBZ_MASK_NO_NX;
1750 pVCpu->pgm.s.fGstPaeMbzPdeMask = fMbzPageFrameMask | X86_PDE_PAE_MBZ_MASK_NO_NX;
1751 pVCpu->pgm.s.fGstPaeMbzBigPdeMask = fMbzPageFrameMask | X86_PDE2M_PAE_MBZ_MASK_NO_NX;
1752 pVCpu->pgm.s.fGstPaeMbzPdpeMask = fMbzPageFrameMask | X86_PDPE_PAE_MBZ_MASK;
1753
1754 pVCpu->pgm.s.fGstAmd64MbzPteMask = fMbzPageFrameMask | X86_PTE_LM_MBZ_MASK_NO_NX;
1755 pVCpu->pgm.s.fGstAmd64MbzPdeMask = fMbzPageFrameMask | X86_PDE_LM_MBZ_MASK_NX;
1756 pVCpu->pgm.s.fGstAmd64MbzBigPdeMask = fMbzPageFrameMask | X86_PDE2M_LM_MBZ_MASK_NX;
1757 pVCpu->pgm.s.fGstAmd64MbzPdpeMask = fMbzPageFrameMask | X86_PDPE_LM_MBZ_MASK_NO_NX;
1758 pVCpu->pgm.s.fGstAmd64MbzBigPdpeMask = fMbzPageFrameMask | X86_PDPE1G_LM_MBZ_MASK_NO_NX;
1759 pVCpu->pgm.s.fGstAmd64MbzPml4eMask = fMbzPageFrameMask | X86_PML4E_MBZ_MASK_NO_NX;
1760
1761 pVCpu->pgm.s.fGst64ShadowedPteMask = X86_PTE_P | X86_PTE_RW | X86_PTE_US | X86_PTE_G | X86_PTE_A | X86_PTE_D;
1762 pVCpu->pgm.s.fGst64ShadowedPdeMask = X86_PDE_P | X86_PDE_RW | X86_PDE_US | X86_PDE_A;
1763 pVCpu->pgm.s.fGst64ShadowedBigPdeMask = X86_PDE4M_P | X86_PDE4M_RW | X86_PDE4M_US | X86_PDE4M_A;
1764 pVCpu->pgm.s.fGst64ShadowedBigPde4PteMask =
1765 X86_PDE4M_P | X86_PDE4M_RW | X86_PDE4M_US | X86_PDE4M_G | X86_PDE4M_A | X86_PDE4M_D;
1766 pVCpu->pgm.s.fGstAmd64ShadowedPdpeMask = X86_PDPE_P | X86_PDPE_RW | X86_PDPE_US | X86_PDPE_A;
1767 pVCpu->pgm.s.fGstAmd64ShadowedPml4eMask = X86_PML4E_P | X86_PML4E_RW | X86_PML4E_US | X86_PML4E_A;
1768 }
1769
1770 /*
1771 * Note that AMD uses all the 8 reserved bits for the address (so 40 bits in total);
1772 * Intel only goes up to 36 bits, so we stick to 36 as well.
1773 * Update: More recent intel manuals specifies 40 bits just like AMD.
1774 */
1775 uint32_t u32Dummy, u32Features;
1776 CPUMGetGuestCpuId(VMMGetCpu(pVM), 1, 0, &u32Dummy, &u32Dummy, &u32Dummy, &u32Features);
1777 if (u32Features & X86_CPUID_FEATURE_EDX_PSE36)
1778 pVM->pgm.s.GCPhys4MBPSEMask = RT_BIT_64(RT_MAX(36, cMaxPhysAddrWidth)) - 1;
1779 else
1780 pVM->pgm.s.GCPhys4MBPSEMask = RT_BIT_64(32) - 1;
1781
1782 /*
1783 * Allocate memory if we're supposed to do that.
1784 */
1785 if (pVM->pgm.s.fRamPreAlloc)
1786 rc = pgmR3PhysRamPreAllocate(pVM);
1787
1788 //pgmLogState(pVM);
1789 LogRel(("PGM: PGMR3InitFinalize: 4 MB PSE mask %RGp\n", pVM->pgm.s.GCPhys4MBPSEMask));
1790 return rc;
1791}
1792
1793
1794/**
1795 * Init phase completed callback.
1796 *
1797 * @returns VBox status code.
1798 * @param pVM The cross context VM structure.
1799 * @param enmWhat What has been completed.
1800 * @thread EMT(0)
1801 */
1802VMMR3_INT_DECL(int) PGMR3InitCompleted(PVM pVM, VMINITCOMPLETED enmWhat)
1803{
1804 switch (enmWhat)
1805 {
1806 case VMINITCOMPLETED_HM:
1807#ifdef VBOX_WITH_PCI_PASSTHROUGH
1808 if (pVM->pgm.s.fPciPassthrough)
1809 {
1810 AssertLogRelReturn(pVM->pgm.s.fRamPreAlloc, VERR_PCI_PASSTHROUGH_NO_RAM_PREALLOC);
1811 AssertLogRelReturn(HMIsEnabled(pVM), VERR_PCI_PASSTHROUGH_NO_HM);
1812 AssertLogRelReturn(HMIsNestedPagingActive(pVM), VERR_PCI_PASSTHROUGH_NO_NESTED_PAGING);
1813
1814 /*
1815 * Report assignments to the IOMMU (hope that's good enough for now).
1816 */
1817 if (pVM->pgm.s.fPciPassthrough)
1818 {
1819 int rc = VMMR3CallR0(pVM, VMMR0_DO_PGM_PHYS_SETUP_IOMMU, 0, NULL);
1820 AssertRCReturn(rc, rc);
1821 }
1822 }
1823#else
1824 AssertLogRelReturn(!pVM->pgm.s.fPciPassthrough, VERR_PGM_PCI_PASSTHRU_MISCONFIG);
1825#endif
1826 break;
1827
1828 default:
1829 /* shut up gcc */
1830 break;
1831 }
1832
1833 return VINF_SUCCESS;
1834}
1835
1836
1837/**
1838 * Applies relocations to data and code managed by this component.
1839 *
1840 * This function will be called at init and whenever the VMM need to relocate it
1841 * self inside the GC.
1842 *
1843 * @param pVM The cross context VM structure.
1844 * @param offDelta Relocation delta relative to old location.
1845 */
1846VMMR3DECL(void) PGMR3Relocate(PVM pVM, RTGCINTPTR offDelta)
1847{
1848 LogFlow(("PGMR3Relocate %RGv to %RGv\n", pVM->pgm.s.GCPtrCR3Mapping, pVM->pgm.s.GCPtrCR3Mapping + offDelta));
1849
1850 /*
1851 * Paging stuff.
1852 */
1853 pVM->pgm.s.GCPtrCR3Mapping += offDelta;
1854
1855 /* Shadow, guest and both mode switch & relocation for each VCPU. */
1856 for (VMCPUID i = 0; i < pVM->cCpus; i++)
1857 {
1858 PVMCPU pVCpu = &pVM->aCpus[i];
1859
1860 uintptr_t idxShw = pVCpu->pgm.s.idxShadowModeData;
1861 if ( idxShw < RT_ELEMENTS(g_aPgmShadowModeData)
1862 && g_aPgmShadowModeData[idxShw].pfnRelocate)
1863 g_aPgmShadowModeData[idxShw].pfnRelocate(pVCpu, offDelta);
1864 else
1865 AssertFailed();
1866
1867 uintptr_t const idxGst = pVCpu->pgm.s.idxGuestModeData;
1868 if ( idxGst < RT_ELEMENTS(g_aPgmGuestModeData)
1869 && g_aPgmGuestModeData[idxGst].pfnRelocate)
1870 g_aPgmGuestModeData[idxGst].pfnRelocate(pVCpu, offDelta);
1871 else
1872 AssertFailed();
1873 }
1874
1875 /*
1876 * Trees.
1877 */
1878 pVM->pgm.s.pTreesRC = MMHyperR3ToRC(pVM, pVM->pgm.s.pTreesR3);
1879
1880 /*
1881 * Ram ranges.
1882 */
1883 if (pVM->pgm.s.pRamRangesXR3)
1884 {
1885 /* Update the pSelfRC pointers and relink them. */
1886 for (PPGMRAMRANGE pCur = pVM->pgm.s.pRamRangesXR3; pCur; pCur = pCur->pNextR3)
1887 if (!(pCur->fFlags & PGM_RAM_RANGE_FLAGS_FLOATING))
1888 pCur->pSelfRC = MMHyperCCToRC(pVM, pCur);
1889 pgmR3PhysRelinkRamRanges(pVM);
1890
1891 /* Flush the RC TLB. */
1892 for (unsigned i = 0; i < PGM_RAMRANGE_TLB_ENTRIES; i++)
1893 pVM->pgm.s.apRamRangesTlbRC[i] = NIL_RTRCPTR;
1894 }
1895
1896 /*
1897 * Update the pSelfRC pointer of the MMIO2 ram ranges since they might not
1898 * be mapped and thus not included in the above exercise.
1899 */
1900 for (PPGMREGMMIORANGE pCur = pVM->pgm.s.pRegMmioRangesR3; pCur; pCur = pCur->pNextR3)
1901 if (!(pCur->RamRange.fFlags & PGM_RAM_RANGE_FLAGS_FLOATING))
1902 pCur->RamRange.pSelfRC = MMHyperCCToRC(pVM, &pCur->RamRange);
1903
1904 /*
1905 * Update the two page directories with all page table mappings.
1906 * (One or more of them have changed, that's why we're here.)
1907 */
1908 pVM->pgm.s.pMappingsRC = MMHyperR3ToRC(pVM, pVM->pgm.s.pMappingsR3);
1909 for (PPGMMAPPING pCur = pVM->pgm.s.pMappingsR3; pCur->pNextR3; pCur = pCur->pNextR3)
1910 pCur->pNextRC = MMHyperR3ToRC(pVM, pCur->pNextR3);
1911
1912 /* Relocate GC addresses of Page Tables. */
1913 for (PPGMMAPPING pCur = pVM->pgm.s.pMappingsR3; pCur; pCur = pCur->pNextR3)
1914 {
1915 for (RTHCUINT i = 0; i < pCur->cPTs; i++)
1916 {
1917 pCur->aPTs[i].pPTRC = MMHyperR3ToRC(pVM, pCur->aPTs[i].pPTR3);
1918 pCur->aPTs[i].paPaePTsRC = MMHyperR3ToRC(pVM, pCur->aPTs[i].paPaePTsR3);
1919 }
1920 }
1921
1922 /*
1923 * Dynamic page mapping area.
1924 */
1925 pVM->pgm.s.paDynPageMap32BitPTEsGC += offDelta;
1926 pVM->pgm.s.paDynPageMapPaePTEsGC += offDelta;
1927 pVM->pgm.s.pbDynPageMapBaseGC += offDelta;
1928
1929 if (pVM->pgm.s.pRCDynMap)
1930 {
1931 pVM->pgm.s.pRCDynMap += offDelta;
1932 PPGMRCDYNMAP pDynMap = (PPGMRCDYNMAP)MMHyperRCToCC(pVM, pVM->pgm.s.pRCDynMap);
1933
1934 pDynMap->paPages += offDelta;
1935 PPGMRCDYNMAPENTRY paPages = (PPGMRCDYNMAPENTRY)MMHyperRCToCC(pVM, pDynMap->paPages);
1936
1937 for (uint32_t iPage = 0; iPage < pDynMap->cPages; iPage++)
1938 {
1939 paPages[iPage].pvPage += offDelta;
1940 paPages[iPage].uPte.pLegacy += offDelta;
1941 paPages[iPage].uPte.pPae += offDelta;
1942 }
1943 }
1944
1945 /*
1946 * The Zero page.
1947 */
1948 pVM->pgm.s.pvZeroPgR0 = MMHyperR3ToR0(pVM, pVM->pgm.s.pvZeroPgR3);
1949#ifdef VBOX_WITH_2X_4GB_ADDR_SPACE
1950 AssertRelease(pVM->pgm.s.pvZeroPgR0 != NIL_RTR0PTR || VM_IS_RAW_MODE_ENABLED(pVM));
1951#else
1952 AssertRelease(pVM->pgm.s.pvZeroPgR0 != NIL_RTR0PTR);
1953#endif
1954
1955 /*
1956 * Physical and virtual handlers.
1957 */
1958 PGMRELOCHANDLERARGS Args = { offDelta, pVM };
1959 RTAvlroGCPhysDoWithAll(&pVM->pgm.s.pTreesR3->PhysHandlers, true, pgmR3RelocatePhysHandler, &Args);
1960 pVM->pgm.s.pLastPhysHandlerRC = NIL_RTRCPTR;
1961
1962 PPGMPHYSHANDLERTYPEINT pCurPhysType;
1963 RTListOff32ForEach(&pVM->pgm.s.pTreesR3->HeadPhysHandlerTypes, pCurPhysType, PGMPHYSHANDLERTYPEINT, ListNode)
1964 {
1965 if (pCurPhysType->pfnHandlerRC != NIL_RTRCPTR)
1966 pCurPhysType->pfnHandlerRC += offDelta;
1967 if (pCurPhysType->pfnPfHandlerRC != NIL_RTRCPTR)
1968 pCurPhysType->pfnPfHandlerRC += offDelta;
1969 }
1970
1971#ifdef VBOX_WITH_RAW_MODE
1972 RTAvlroGCPtrDoWithAll(&pVM->pgm.s.pTreesR3->VirtHandlers, true, pgmR3RelocateVirtHandler, &Args);
1973 RTAvlroGCPtrDoWithAll(&pVM->pgm.s.pTreesR3->HyperVirtHandlers, true, pgmR3RelocateHyperVirtHandler, &Args);
1974
1975 PPGMVIRTHANDLERTYPEINT pCurVirtType;
1976 RTListOff32ForEach(&pVM->pgm.s.pTreesR3->HeadVirtHandlerTypes, pCurVirtType, PGMVIRTHANDLERTYPEINT, ListNode)
1977 {
1978 if (pCurVirtType->pfnHandlerRC != NIL_RTRCPTR)
1979 pCurVirtType->pfnHandlerRC += offDelta;
1980 if (pCurVirtType->pfnPfHandlerRC != NIL_RTRCPTR)
1981 pCurVirtType->pfnPfHandlerRC += offDelta;
1982 }
1983#endif
1984
1985 /*
1986 * The page pool.
1987 */
1988 pgmR3PoolRelocate(pVM);
1989
1990#ifdef VBOX_WITH_STATISTICS
1991 /*
1992 * Statistics.
1993 */
1994 pVM->pgm.s.pStatsRC = MMHyperCCToRC(pVM, pVM->pgm.s.pStatsR3);
1995 for (VMCPUID iCpu = 0; iCpu < pVM->cCpus; iCpu++)
1996 pVM->aCpus[iCpu].pgm.s.pStatsRC = MMHyperCCToRC(pVM, pVM->aCpus[iCpu].pgm.s.pStatsR3);
1997#endif
1998}
1999
2000
2001/**
2002 * Callback function for relocating a physical access handler.
2003 *
2004 * @returns 0 (continue enum)
2005 * @param pNode Pointer to a PGMPHYSHANDLER node.
2006 * @param pvUser Pointer to a PGMRELOCHANDLERARGS.
2007 */
2008static DECLCALLBACK(int) pgmR3RelocatePhysHandler(PAVLROGCPHYSNODECORE pNode, void *pvUser)
2009{
2010 PPGMPHYSHANDLER pHandler = (PPGMPHYSHANDLER)pNode;
2011 PCPGMRELOCHANDLERARGS pArgs = (PCPGMRELOCHANDLERARGS)pvUser;
2012 if (pHandler->pvUserRC >= 0x10000)
2013 pHandler->pvUserRC += pArgs->offDelta;
2014 return 0;
2015}
2016
2017#ifdef VBOX_WITH_RAW_MODE
2018
2019/**
2020 * Callback function for relocating a virtual access handler.
2021 *
2022 * @returns 0 (continue enum)
2023 * @param pNode Pointer to a PGMVIRTHANDLER node.
2024 * @param pvUser Pointer to a PGMRELOCHANDLERARGS.
2025 */
2026static DECLCALLBACK(int) pgmR3RelocateVirtHandler(PAVLROGCPTRNODECORE pNode, void *pvUser)
2027{
2028 PPGMVIRTHANDLER pHandler = (PPGMVIRTHANDLER)pNode;
2029 PCPGMRELOCHANDLERARGS pArgs = (PCPGMRELOCHANDLERARGS)pvUser;
2030 Assert(PGMVIRTANDLER_GET_TYPE(pArgs->pVM, pHandler)->enmKind != PGMVIRTHANDLERKIND_HYPERVISOR);
2031
2032 if ( pHandler->pvUserRC != NIL_RTRCPTR
2033 && PGMVIRTANDLER_GET_TYPE(pArgs->pVM, pHandler)->fRelocUserRC)
2034 pHandler->pvUserRC += pArgs->offDelta;
2035 return 0;
2036}
2037
2038
2039/**
2040 * Callback function for relocating a virtual access handler for the hypervisor mapping.
2041 *
2042 * @returns 0 (continue enum)
2043 * @param pNode Pointer to a PGMVIRTHANDLER node.
2044 * @param pvUser Pointer to a PGMRELOCHANDLERARGS.
2045 */
2046static DECLCALLBACK(int) pgmR3RelocateHyperVirtHandler(PAVLROGCPTRNODECORE pNode, void *pvUser)
2047{
2048 PPGMVIRTHANDLER pHandler = (PPGMVIRTHANDLER)pNode;
2049 PCPGMRELOCHANDLERARGS pArgs = (PCPGMRELOCHANDLERARGS)pvUser;
2050 Assert(PGMVIRTANDLER_GET_TYPE(pArgs->pVM, pHandler)->enmKind == PGMVIRTHANDLERKIND_HYPERVISOR);
2051
2052 if ( pHandler->pvUserRC != NIL_RTRCPTR
2053 && PGMVIRTANDLER_GET_TYPE(pArgs->pVM, pHandler)->fRelocUserRC)
2054 pHandler->pvUserRC += pArgs->offDelta;
2055 return 0;
2056}
2057
2058#endif /* VBOX_WITH_RAW_MODE */
2059
2060/**
2061 * Resets a virtual CPU when unplugged.
2062 *
2063 * @param pVM The cross context VM structure.
2064 * @param pVCpu The cross context virtual CPU structure.
2065 */
2066VMMR3DECL(void) PGMR3ResetCpu(PVM pVM, PVMCPU pVCpu)
2067{
2068 uintptr_t const idxGst = pVCpu->pgm.s.idxGuestModeData;
2069 if ( idxGst < RT_ELEMENTS(g_aPgmGuestModeData)
2070 && g_aPgmGuestModeData[idxGst].pfnExit)
2071 {
2072 int rc = g_aPgmGuestModeData[idxGst].pfnExit(pVCpu);
2073 AssertReleaseRC(rc);
2074 }
2075 pVCpu->pgm.s.GCPhysCR3 = NIL_RTGCPHYS;
2076
2077 int rc = PGMHCChangeMode(pVM, pVCpu, PGMMODE_REAL);
2078 AssertReleaseRC(rc);
2079
2080 STAM_REL_COUNTER_RESET(&pVCpu->pgm.s.cGuestModeChanges);
2081
2082 pgmR3PoolResetUnpluggedCpu(pVM, pVCpu);
2083
2084 /*
2085 * Re-init other members.
2086 */
2087 pVCpu->pgm.s.fA20Enabled = true;
2088 pVCpu->pgm.s.GCPhysA20Mask = ~((RTGCPHYS)!pVCpu->pgm.s.fA20Enabled << 20);
2089
2090 /*
2091 * Clear the FFs PGM owns.
2092 */
2093 VMCPU_FF_CLEAR(pVCpu, VMCPU_FF_PGM_SYNC_CR3);
2094 VMCPU_FF_CLEAR(pVCpu, VMCPU_FF_PGM_SYNC_CR3_NON_GLOBAL);
2095}
2096
2097
2098/**
2099 * The VM is being reset.
2100 *
2101 * For the PGM component this means that any PD write monitors
2102 * needs to be removed.
2103 *
2104 * @param pVM The cross context VM structure.
2105 */
2106VMMR3_INT_DECL(void) PGMR3Reset(PVM pVM)
2107{
2108 LogFlow(("PGMR3Reset:\n"));
2109 VM_ASSERT_EMT(pVM);
2110
2111 pgmLock(pVM);
2112
2113 /*
2114 * Unfix any fixed mappings and disable CR3 monitoring.
2115 */
2116 pVM->pgm.s.fMappingsFixed = false;
2117 pVM->pgm.s.fMappingsFixedRestored = false;
2118 pVM->pgm.s.GCPtrMappingFixed = NIL_RTGCPTR;
2119 pVM->pgm.s.cbMappingFixed = 0;
2120
2121 /*
2122 * Exit the guest paging mode before the pgm pool gets reset.
2123 * Important to clean up the amd64 case.
2124 */
2125 for (VMCPUID i = 0; i < pVM->cCpus; i++)
2126 {
2127 PVMCPU pVCpu = &pVM->aCpus[i];
2128 uintptr_t const idxGst = pVCpu->pgm.s.idxGuestModeData;
2129 if ( idxGst < RT_ELEMENTS(g_aPgmGuestModeData)
2130 && g_aPgmGuestModeData[idxGst].pfnExit)
2131 {
2132 int rc = g_aPgmGuestModeData[idxGst].pfnExit(pVCpu);
2133 AssertReleaseRC(rc);
2134 }
2135 pVCpu->pgm.s.GCPhysCR3 = NIL_RTGCPHYS;
2136 }
2137
2138#ifdef DEBUG
2139 DBGFR3_INFO_LOG_SAFE(pVM, "mappings", NULL);
2140 DBGFR3_INFO_LOG_SAFE(pVM, "handlers", "all nostat");
2141#endif
2142
2143 /*
2144 * Switch mode back to real mode. (Before resetting the pgm pool!)
2145 */
2146 for (VMCPUID i = 0; i < pVM->cCpus; i++)
2147 {
2148 PVMCPU pVCpu = &pVM->aCpus[i];
2149
2150 int rc = PGMHCChangeMode(pVM, pVCpu, PGMMODE_REAL);
2151 AssertReleaseRC(rc);
2152
2153 STAM_REL_COUNTER_RESET(&pVCpu->pgm.s.cGuestModeChanges);
2154 STAM_REL_COUNTER_RESET(&pVCpu->pgm.s.cA20Changes);
2155 }
2156
2157 /*
2158 * Reset the shadow page pool.
2159 */
2160 pgmR3PoolReset(pVM);
2161
2162 /*
2163 * Re-init various other members and clear the FFs that PGM owns.
2164 */
2165 for (VMCPUID i = 0; i < pVM->cCpus; i++)
2166 {
2167 PVMCPU pVCpu = &pVM->aCpus[i];
2168
2169 pVCpu->pgm.s.fGst32BitPageSizeExtension = false;
2170 PGMNotifyNxeChanged(pVCpu, false);
2171
2172 VMCPU_FF_CLEAR(pVCpu, VMCPU_FF_PGM_SYNC_CR3);
2173 VMCPU_FF_CLEAR(pVCpu, VMCPU_FF_PGM_SYNC_CR3_NON_GLOBAL);
2174
2175 if (!pVCpu->pgm.s.fA20Enabled)
2176 {
2177 pVCpu->pgm.s.fA20Enabled = true;
2178 pVCpu->pgm.s.GCPhysA20Mask = ~((RTGCPHYS)!pVCpu->pgm.s.fA20Enabled << 20);
2179#ifdef PGM_WITH_A20
2180 pVCpu->pgm.s.fSyncFlags |= PGM_SYNC_UPDATE_PAGE_BIT_VIRTUAL;
2181 VMCPU_FF_SET(pVCpu, VMCPU_FF_PGM_SYNC_CR3);
2182 pgmR3RefreshShadowModeAfterA20Change(pVCpu);
2183 HMFlushTLB(pVCpu);
2184#endif
2185 }
2186 }
2187
2188 //pgmLogState(pVM);
2189 pgmUnlock(pVM);
2190}
2191
2192
2193/**
2194 * Memory setup after VM construction or reset.
2195 *
2196 * @param pVM The cross context VM structure.
2197 * @param fAtReset Indicates the context, after reset if @c true or after
2198 * construction if @c false.
2199 */
2200VMMR3_INT_DECL(void) PGMR3MemSetup(PVM pVM, bool fAtReset)
2201{
2202 if (fAtReset)
2203 {
2204 pgmLock(pVM);
2205
2206 int rc = pgmR3PhysRamZeroAll(pVM);
2207 AssertReleaseRC(rc);
2208
2209 rc = pgmR3PhysRomReset(pVM);
2210 AssertReleaseRC(rc);
2211
2212 pgmUnlock(pVM);
2213 }
2214}
2215
2216
2217#ifdef VBOX_STRICT
2218/**
2219 * VM state change callback for clearing fNoMorePhysWrites after
2220 * a snapshot has been created.
2221 */
2222static DECLCALLBACK(void) pgmR3ResetNoMorePhysWritesFlag(PUVM pUVM, VMSTATE enmState, VMSTATE enmOldState, void *pvUser)
2223{
2224 if ( enmState == VMSTATE_RUNNING
2225 || enmState == VMSTATE_RESUMING)
2226 pUVM->pVM->pgm.s.fNoMorePhysWrites = false;
2227 NOREF(enmOldState); NOREF(pvUser);
2228}
2229#endif
2230
2231/**
2232 * Private API to reset fNoMorePhysWrites.
2233 */
2234VMMR3_INT_DECL(void) PGMR3ResetNoMorePhysWritesFlag(PVM pVM)
2235{
2236 pVM->pgm.s.fNoMorePhysWrites = false;
2237}
2238
2239/**
2240 * Terminates the PGM.
2241 *
2242 * @returns VBox status code.
2243 * @param pVM The cross context VM structure.
2244 */
2245VMMR3DECL(int) PGMR3Term(PVM pVM)
2246{
2247 /* Must free shared pages here. */
2248 pgmLock(pVM);
2249 pgmR3PhysRamTerm(pVM);
2250 pgmR3PhysRomTerm(pVM);
2251 pgmUnlock(pVM);
2252
2253 PGMDeregisterStringFormatTypes();
2254 return PDMR3CritSectDelete(&pVM->pgm.s.CritSectX);
2255}
2256
2257
2258/**
2259 * Show paging mode.
2260 *
2261 * @param pVM The cross context VM structure.
2262 * @param pHlp The info helpers.
2263 * @param pszArgs "all" (default), "guest", "shadow" or "host".
2264 */
2265static DECLCALLBACK(void) pgmR3InfoMode(PVM pVM, PCDBGFINFOHLP pHlp, const char *pszArgs)
2266{
2267 /* digest argument. */
2268 bool fGuest, fShadow, fHost;
2269 if (pszArgs)
2270 pszArgs = RTStrStripL(pszArgs);
2271 if (!pszArgs || !*pszArgs || strstr(pszArgs, "all"))
2272 fShadow = fHost = fGuest = true;
2273 else
2274 {
2275 fShadow = fHost = fGuest = false;
2276 if (strstr(pszArgs, "guest"))
2277 fGuest = true;
2278 if (strstr(pszArgs, "shadow"))
2279 fShadow = true;
2280 if (strstr(pszArgs, "host"))
2281 fHost = true;
2282 }
2283
2284 PVMCPU pVCpu = VMMGetCpu(pVM);
2285 if (!pVCpu)
2286 pVCpu = &pVM->aCpus[0];
2287
2288
2289 /* print info. */
2290 if (fGuest)
2291 pHlp->pfnPrintf(pHlp, "Guest paging mode (VCPU #%u): %s (changed %RU64 times), A20 %s (changed %RU64 times)\n",
2292 pVCpu->idCpu, PGMGetModeName(pVCpu->pgm.s.enmGuestMode), pVCpu->pgm.s.cGuestModeChanges.c,
2293 pVCpu->pgm.s.fA20Enabled ? "enabled" : "disabled", pVCpu->pgm.s.cA20Changes.c);
2294 if (fShadow)
2295 pHlp->pfnPrintf(pHlp, "Shadow paging mode (VCPU #%u): %s\n", pVCpu->idCpu, PGMGetModeName(pVCpu->pgm.s.enmShadowMode));
2296 if (fHost)
2297 {
2298 const char *psz;
2299 switch (pVM->pgm.s.enmHostMode)
2300 {
2301 case SUPPAGINGMODE_INVALID: psz = "invalid"; break;
2302 case SUPPAGINGMODE_32_BIT: psz = "32-bit"; break;
2303 case SUPPAGINGMODE_32_BIT_GLOBAL: psz = "32-bit+G"; break;
2304 case SUPPAGINGMODE_PAE: psz = "PAE"; break;
2305 case SUPPAGINGMODE_PAE_GLOBAL: psz = "PAE+G"; break;
2306 case SUPPAGINGMODE_PAE_NX: psz = "PAE+NX"; break;
2307 case SUPPAGINGMODE_PAE_GLOBAL_NX: psz = "PAE+G+NX"; break;
2308 case SUPPAGINGMODE_AMD64: psz = "AMD64"; break;
2309 case SUPPAGINGMODE_AMD64_GLOBAL: psz = "AMD64+G"; break;
2310 case SUPPAGINGMODE_AMD64_NX: psz = "AMD64+NX"; break;
2311 case SUPPAGINGMODE_AMD64_GLOBAL_NX: psz = "AMD64+G+NX"; break;
2312 default: psz = "unknown"; break;
2313 }
2314 pHlp->pfnPrintf(pHlp, "Host paging mode: %s\n", psz);
2315 }
2316}
2317
2318
2319/**
2320 * Dump registered MMIO ranges to the log.
2321 *
2322 * @param pVM The cross context VM structure.
2323 * @param pHlp The info helpers.
2324 * @param pszArgs Arguments, ignored.
2325 */
2326static DECLCALLBACK(void) pgmR3PhysInfo(PVM pVM, PCDBGFINFOHLP pHlp, const char *pszArgs)
2327{
2328 bool const fVerbose = pszArgs && strstr(pszArgs, "verbose") != NULL;
2329
2330 pHlp->pfnPrintf(pHlp,
2331 "RAM ranges (pVM=%p)\n"
2332 "%.*s %.*s\n",
2333 pVM,
2334 sizeof(RTGCPHYS) * 4 + 1, "GC Phys Range ",
2335 sizeof(RTHCPTR) * 2, "pvHC ");
2336
2337 for (PPGMRAMRANGE pCur = pVM->pgm.s.pRamRangesXR3; pCur; pCur = pCur->pNextR3)
2338 {
2339 pHlp->pfnPrintf(pHlp,
2340 "%RGp-%RGp %RHv %s\n",
2341 pCur->GCPhys,
2342 pCur->GCPhysLast,
2343 pCur->pvR3,
2344 pCur->pszDesc);
2345 if (fVerbose)
2346 {
2347 RTGCPHYS const cPages = pCur->cb >> X86_PAGE_SHIFT;
2348 RTGCPHYS iPage = 0;
2349 while (iPage < cPages)
2350 {
2351 RTGCPHYS const iFirstPage = iPage;
2352 PGMPAGETYPE const enmType = (PGMPAGETYPE)PGM_PAGE_GET_TYPE(&pCur->aPages[iPage]);
2353 do
2354 iPage++;
2355 while (iPage < cPages && (PGMPAGETYPE)PGM_PAGE_GET_TYPE(&pCur->aPages[iPage]) == enmType);
2356 const char *pszType;
2357 const char *pszMore = NULL;
2358 switch (enmType)
2359 {
2360 case PGMPAGETYPE_RAM:
2361 pszType = "RAM";
2362 break;
2363
2364 case PGMPAGETYPE_MMIO2:
2365 pszType = "MMIO2";
2366 break;
2367
2368 case PGMPAGETYPE_MMIO2_ALIAS_MMIO:
2369 pszType = "MMIO2-alias-MMIO";
2370 break;
2371
2372 case PGMPAGETYPE_SPECIAL_ALIAS_MMIO:
2373 pszType = "special-alias-MMIO";
2374 break;
2375
2376 case PGMPAGETYPE_ROM_SHADOW:
2377 case PGMPAGETYPE_ROM:
2378 {
2379 pszType = enmType == PGMPAGETYPE_ROM_SHADOW ? "ROM-shadowed" : "ROM";
2380
2381 RTGCPHYS const GCPhysFirstPg = iFirstPage * X86_PAGE_SIZE;
2382 PPGMROMRANGE pRom = pVM->pgm.s.pRomRangesR3;
2383 while (pRom && GCPhysFirstPg > pRom->GCPhysLast)
2384 pRom = pRom->pNextR3;
2385 if (pRom && GCPhysFirstPg - pRom->GCPhys < pRom->cb)
2386 pszMore = pRom->pszDesc;
2387 break;
2388 }
2389
2390 case PGMPAGETYPE_MMIO:
2391 {
2392 pszType = "MMIO";
2393 pgmLock(pVM);
2394 PPGMPHYSHANDLER pHandler = pgmHandlerPhysicalLookup(pVM, iFirstPage * X86_PAGE_SIZE);
2395 if (pHandler)
2396 pszMore = pHandler->pszDesc;
2397 pgmUnlock(pVM);
2398 break;
2399 }
2400
2401 case PGMPAGETYPE_INVALID:
2402 pszType = "invalid";
2403 break;
2404
2405 default:
2406 pszType = "bad";
2407 break;
2408 }
2409 if (pszMore)
2410 pHlp->pfnPrintf(pHlp, " %RGp-%RGp %-20s %s\n",
2411 pCur->GCPhys + iFirstPage * X86_PAGE_SIZE,
2412 pCur->GCPhys + iPage * X86_PAGE_SIZE,
2413 pszType, pszMore);
2414 else
2415 pHlp->pfnPrintf(pHlp, " %RGp-%RGp %s\n",
2416 pCur->GCPhys + iFirstPage * X86_PAGE_SIZE,
2417 pCur->GCPhys + iPage * X86_PAGE_SIZE,
2418 pszType);
2419
2420 }
2421 }
2422 }
2423}
2424
2425
2426/**
2427 * Dump the page directory to the log.
2428 *
2429 * @param pVM The cross context VM structure.
2430 * @param pHlp The info helpers.
2431 * @param pszArgs Arguments, ignored.
2432 */
2433static DECLCALLBACK(void) pgmR3InfoCr3(PVM pVM, PCDBGFINFOHLP pHlp, const char *pszArgs)
2434{
2435 /** @todo SMP support!! */
2436 PVMCPU pVCpu = &pVM->aCpus[0];
2437
2438/** @todo fix this! Convert the PGMR3DumpHierarchyHC functions to do guest stuff. */
2439 /* Big pages supported? */
2440 const bool fPSE = !!(CPUMGetGuestCR4(pVCpu) & X86_CR4_PSE);
2441
2442 /* Global pages supported? */
2443 const bool fPGE = !!(CPUMGetGuestCR4(pVCpu) & X86_CR4_PGE);
2444
2445 NOREF(pszArgs);
2446
2447 /*
2448 * Get page directory addresses.
2449 */
2450 pgmLock(pVM);
2451 PX86PD pPDSrc = pgmGstGet32bitPDPtr(pVCpu);
2452 Assert(pPDSrc);
2453
2454 /*
2455 * Iterate the page directory.
2456 */
2457 for (unsigned iPD = 0; iPD < RT_ELEMENTS(pPDSrc->a); iPD++)
2458 {
2459 X86PDE PdeSrc = pPDSrc->a[iPD];
2460 if (PdeSrc.n.u1Present)
2461 {
2462 if (PdeSrc.b.u1Size && fPSE)
2463 pHlp->pfnPrintf(pHlp,
2464 "%04X - %RGp P=%d U=%d RW=%d G=%d - BIG\n",
2465 iPD,
2466 pgmGstGet4MBPhysPage(pVM, PdeSrc),
2467 PdeSrc.b.u1Present, PdeSrc.b.u1User, PdeSrc.b.u1Write, PdeSrc.b.u1Global && fPGE);
2468 else
2469 pHlp->pfnPrintf(pHlp,
2470 "%04X - %RGp P=%d U=%d RW=%d [G=%d]\n",
2471 iPD,
2472 (RTGCPHYS)(PdeSrc.u & X86_PDE_PG_MASK),
2473 PdeSrc.n.u1Present, PdeSrc.n.u1User, PdeSrc.n.u1Write, PdeSrc.b.u1Global && fPGE);
2474 }
2475 }
2476 pgmUnlock(pVM);
2477}
2478
2479
2480/**
2481 * Service a VMMCALLRING3_PGM_LOCK call.
2482 *
2483 * @returns VBox status code.
2484 * @param pVM The cross context VM structure.
2485 */
2486VMMR3DECL(int) PGMR3LockCall(PVM pVM)
2487{
2488 int rc = PDMR3CritSectEnterEx(&pVM->pgm.s.CritSectX, true /* fHostCall */);
2489 AssertRC(rc);
2490 return rc;
2491}
2492
2493
2494/**
2495 * Called by pgmPoolFlushAllInt prior to flushing the pool.
2496 *
2497 * @returns VBox status code, fully asserted.
2498 * @param pVCpu The cross context virtual CPU structure.
2499 */
2500int pgmR3ExitShadowModeBeforePoolFlush(PVMCPU pVCpu)
2501{
2502 /* Unmap the old CR3 value before flushing everything. */
2503 int rc = VINF_SUCCESS;
2504 uintptr_t idxBth = pVCpu->pgm.s.idxBothModeData;
2505 if ( idxBth < RT_ELEMENTS(g_aPgmBothModeData)
2506 && g_aPgmBothModeData[idxBth].pfnMapCR3)
2507 {
2508 rc = g_aPgmBothModeData[idxBth].pfnUnmapCR3(pVCpu);
2509 AssertRC(rc);
2510 }
2511
2512 /* Exit the current shadow paging mode as well; nested paging and EPT use a root CR3 which will get flushed here. */
2513 uintptr_t idxShw = pVCpu->pgm.s.idxShadowModeData;
2514 if ( idxShw < RT_ELEMENTS(g_aPgmShadowModeData)
2515 && g_aPgmShadowModeData[idxShw].pfnExit)
2516 {
2517 rc = g_aPgmShadowModeData[idxShw].pfnExit(pVCpu);
2518 AssertMsgRCReturn(rc, ("Exit failed for shadow mode %d: %Rrc\n", pVCpu->pgm.s.enmShadowMode, rc), rc);
2519 }
2520
2521 Assert(pVCpu->pgm.s.pShwPageCR3R3 == NULL);
2522 return rc;
2523}
2524
2525
2526/**
2527 * Called by pgmPoolFlushAllInt after flushing the pool.
2528 *
2529 * @returns VBox status code, fully asserted.
2530 * @param pVM The cross context VM structure.
2531 * @param pVCpu The cross context virtual CPU structure.
2532 */
2533int pgmR3ReEnterShadowModeAfterPoolFlush(PVM pVM, PVMCPU pVCpu)
2534{
2535 pVCpu->pgm.s.enmShadowMode = PGMMODE_INVALID;
2536 int rc = PGMHCChangeMode(pVM, pVCpu, PGMGetGuestMode(pVCpu));
2537 Assert(VMCPU_FF_IS_SET(pVCpu, VMCPU_FF_PGM_SYNC_CR3));
2538 AssertRCReturn(rc, rc);
2539 AssertRCSuccessReturn(rc, VERR_IPE_UNEXPECTED_INFO_STATUS);
2540
2541 Assert(pVCpu->pgm.s.pShwPageCR3R3 != NULL || pVCpu->pgm.s.enmShadowMode == PGMMODE_NONE);
2542 AssertMsg( pVCpu->pgm.s.enmShadowMode >= PGMMODE_NESTED_32BIT
2543 || CPUMGetHyperCR3(pVCpu) == PGMGetHyperCR3(pVCpu),
2544 ("%RHp != %RHp %s\n", (RTHCPHYS)CPUMGetHyperCR3(pVCpu), PGMGetHyperCR3(pVCpu), PGMGetModeName(pVCpu->pgm.s.enmShadowMode)));
2545 return rc;
2546}
2547
2548
2549/**
2550 * Called by PGMR3PhysSetA20 after changing the A20 state.
2551 *
2552 * @param pVCpu The cross context virtual CPU structure.
2553 */
2554void pgmR3RefreshShadowModeAfterA20Change(PVMCPU pVCpu)
2555{
2556 /** @todo Probably doing a bit too much here. */
2557 int rc = pgmR3ExitShadowModeBeforePoolFlush(pVCpu);
2558 AssertReleaseRC(rc);
2559 rc = pgmR3ReEnterShadowModeAfterPoolFlush(pVCpu->CTX_SUFF(pVM), pVCpu);
2560 AssertReleaseRC(rc);
2561}
2562
2563
2564#ifdef VBOX_WITH_DEBUGGER
2565
2566/**
2567 * @callback_method_impl{FNDBGCCMD, The '.pgmerror' and '.pgmerroroff' commands.}
2568 */
2569static DECLCALLBACK(int) pgmR3CmdError(PCDBGCCMD pCmd, PDBGCCMDHLP pCmdHlp, PUVM pUVM, PCDBGCVAR paArgs, unsigned cArgs)
2570{
2571 /*
2572 * Validate input.
2573 */
2574 DBGC_CMDHLP_REQ_UVM_RET(pCmdHlp, pCmd, pUVM);
2575 PVM pVM = pUVM->pVM;
2576 DBGC_CMDHLP_ASSERT_PARSER_RET(pCmdHlp, pCmd, 0, cArgs == 0 || (cArgs == 1 && paArgs[0].enmType == DBGCVAR_TYPE_STRING));
2577
2578 if (!cArgs)
2579 {
2580 /*
2581 * Print the list of error injection locations with status.
2582 */
2583 DBGCCmdHlpPrintf(pCmdHlp, "PGM error inject locations:\n");
2584 DBGCCmdHlpPrintf(pCmdHlp, " handy - %RTbool\n", pVM->pgm.s.fErrInjHandyPages);
2585 }
2586 else
2587 {
2588 /*
2589 * String switch on where to inject the error.
2590 */
2591 bool const fNewState = !strcmp(pCmd->pszCmd, "pgmerror");
2592 const char *pszWhere = paArgs[0].u.pszString;
2593 if (!strcmp(pszWhere, "handy"))
2594 ASMAtomicWriteBool(&pVM->pgm.s.fErrInjHandyPages, fNewState);
2595 else
2596 return DBGCCmdHlpPrintf(pCmdHlp, "error: Invalid 'where' value: %s.\n", pszWhere);
2597 DBGCCmdHlpPrintf(pCmdHlp, "done\n");
2598 }
2599 return VINF_SUCCESS;
2600}
2601
2602
2603/**
2604 * @callback_method_impl{FNDBGCCMD, The '.pgmsync' command.}
2605 */
2606static DECLCALLBACK(int) pgmR3CmdSync(PCDBGCCMD pCmd, PDBGCCMDHLP pCmdHlp, PUVM pUVM, PCDBGCVAR paArgs, unsigned cArgs)
2607{
2608 /*
2609 * Validate input.
2610 */
2611 NOREF(pCmd); NOREF(paArgs); NOREF(cArgs);
2612 DBGC_CMDHLP_REQ_UVM_RET(pCmdHlp, pCmd, pUVM);
2613 PVMCPU pVCpu = VMMR3GetCpuByIdU(pUVM, DBGCCmdHlpGetCurrentCpu(pCmdHlp));
2614 if (!pVCpu)
2615 return DBGCCmdHlpFail(pCmdHlp, pCmd, "Invalid CPU ID");
2616
2617 /*
2618 * Force page directory sync.
2619 */
2620 VMCPU_FF_SET(pVCpu, VMCPU_FF_PGM_SYNC_CR3);
2621
2622 int rc = DBGCCmdHlpPrintf(pCmdHlp, "Forcing page directory sync.\n");
2623 if (RT_FAILURE(rc))
2624 return rc;
2625
2626 return VINF_SUCCESS;
2627}
2628
2629#ifdef VBOX_STRICT
2630
2631/**
2632 * EMT callback for pgmR3CmdAssertCR3.
2633 *
2634 * @returns VBox status code.
2635 * @param pUVM The user mode VM handle.
2636 * @param pcErrors Where to return the error count.
2637 */
2638static DECLCALLBACK(int) pgmR3CmdAssertCR3EmtWorker(PUVM pUVM, unsigned *pcErrors)
2639{
2640 PVM pVM = pUVM->pVM;
2641 VM_ASSERT_VALID_EXT_RETURN(pVM, VERR_INVALID_VM_HANDLE);
2642 PVMCPU pVCpu = VMMGetCpu(pVM);
2643
2644 *pcErrors = PGMAssertCR3(pVM, pVCpu, CPUMGetGuestCR3(pVCpu), CPUMGetGuestCR4(pVCpu));
2645
2646 return VINF_SUCCESS;
2647}
2648
2649
2650/**
2651 * @callback_method_impl{FNDBGCCMD, The '.pgmassertcr3' command.}
2652 */
2653static DECLCALLBACK(int) pgmR3CmdAssertCR3(PCDBGCCMD pCmd, PDBGCCMDHLP pCmdHlp, PUVM pUVM, PCDBGCVAR paArgs, unsigned cArgs)
2654{
2655 /*
2656 * Validate input.
2657 */
2658 NOREF(pCmd); NOREF(paArgs); NOREF(cArgs);
2659 DBGC_CMDHLP_REQ_UVM_RET(pCmdHlp, pCmd, pUVM);
2660
2661 int rc = DBGCCmdHlpPrintf(pCmdHlp, "Checking shadow CR3 page tables for consistency.\n");
2662 if (RT_FAILURE(rc))
2663 return rc;
2664
2665 unsigned cErrors = 0;
2666 rc = VMR3ReqCallWaitU(pUVM, DBGCCmdHlpGetCurrentCpu(pCmdHlp), (PFNRT)pgmR3CmdAssertCR3EmtWorker, 2, pUVM, &cErrors);
2667 if (RT_FAILURE(rc))
2668 return DBGCCmdHlpFail(pCmdHlp, pCmd, "VMR3ReqCallWaitU failed: %Rrc", rc);
2669 if (cErrors > 0)
2670 return DBGCCmdHlpFail(pCmdHlp, pCmd, "PGMAssertCR3: %u error(s)", cErrors);
2671 return DBGCCmdHlpPrintf(pCmdHlp, "PGMAssertCR3: OK\n");
2672}
2673
2674#endif /* VBOX_STRICT */
2675
2676/**
2677 * @callback_method_impl{FNDBGCCMD, The '.pgmsyncalways' command.}
2678 */
2679static DECLCALLBACK(int) pgmR3CmdSyncAlways(PCDBGCCMD pCmd, PDBGCCMDHLP pCmdHlp, PUVM pUVM, PCDBGCVAR paArgs, unsigned cArgs)
2680{
2681 /*
2682 * Validate input.
2683 */
2684 NOREF(pCmd); NOREF(paArgs); NOREF(cArgs);
2685 DBGC_CMDHLP_REQ_UVM_RET(pCmdHlp, pCmd, pUVM);
2686 PVMCPU pVCpu = VMMR3GetCpuByIdU(pUVM, DBGCCmdHlpGetCurrentCpu(pCmdHlp));
2687 if (!pVCpu)
2688 return DBGCCmdHlpFail(pCmdHlp, pCmd, "Invalid CPU ID");
2689
2690 /*
2691 * Force page directory sync.
2692 */
2693 int rc;
2694 if (pVCpu->pgm.s.fSyncFlags & PGM_SYNC_ALWAYS)
2695 {
2696 ASMAtomicAndU32(&pVCpu->pgm.s.fSyncFlags, ~PGM_SYNC_ALWAYS);
2697 rc = DBGCCmdHlpPrintf(pCmdHlp, "Disabled permanent forced page directory syncing.\n");
2698 }
2699 else
2700 {
2701 ASMAtomicOrU32(&pVCpu->pgm.s.fSyncFlags, PGM_SYNC_ALWAYS);
2702 VMCPU_FF_SET(pVCpu, VMCPU_FF_PGM_SYNC_CR3);
2703 rc = DBGCCmdHlpPrintf(pCmdHlp, "Enabled permanent forced page directory syncing.\n");
2704 }
2705 return rc;
2706}
2707
2708
2709/**
2710 * @callback_method_impl{FNDBGCCMD, The '.pgmphystofile' command.}
2711 */
2712static DECLCALLBACK(int) pgmR3CmdPhysToFile(PCDBGCCMD pCmd, PDBGCCMDHLP pCmdHlp, PUVM pUVM, PCDBGCVAR paArgs, unsigned cArgs)
2713{
2714 /*
2715 * Validate input.
2716 */
2717 NOREF(pCmd);
2718 DBGC_CMDHLP_REQ_UVM_RET(pCmdHlp, pCmd, pUVM);
2719 PVM pVM = pUVM->pVM;
2720 DBGC_CMDHLP_ASSERT_PARSER_RET(pCmdHlp, pCmd, 0, cArgs == 1 || cArgs == 2);
2721 DBGC_CMDHLP_ASSERT_PARSER_RET(pCmdHlp, pCmd, 0, paArgs[0].enmType == DBGCVAR_TYPE_STRING);
2722 if (cArgs == 2)
2723 {
2724 DBGC_CMDHLP_ASSERT_PARSER_RET(pCmdHlp, pCmd, 1, paArgs[1].enmType == DBGCVAR_TYPE_STRING);
2725 if (strcmp(paArgs[1].u.pszString, "nozero"))
2726 return DBGCCmdHlpFail(pCmdHlp, pCmd, "Invalid 2nd argument '%s', must be 'nozero'.\n", paArgs[1].u.pszString);
2727 }
2728 bool fIncZeroPgs = cArgs < 2;
2729
2730 /*
2731 * Open the output file and get the ram parameters.
2732 */
2733 RTFILE hFile;
2734 int rc = RTFileOpen(&hFile, paArgs[0].u.pszString, RTFILE_O_WRITE | RTFILE_O_CREATE_REPLACE | RTFILE_O_DENY_WRITE);
2735 if (RT_FAILURE(rc))
2736 return DBGCCmdHlpPrintf(pCmdHlp, "error: RTFileOpen(,'%s',) -> %Rrc.\n", paArgs[0].u.pszString, rc);
2737
2738 uint32_t cbRamHole = 0;
2739 CFGMR3QueryU32Def(CFGMR3GetRootU(pUVM), "RamHoleSize", &cbRamHole, MM_RAM_HOLE_SIZE_DEFAULT);
2740 uint64_t cbRam = 0;
2741 CFGMR3QueryU64Def(CFGMR3GetRootU(pUVM), "RamSize", &cbRam, 0);
2742 RTGCPHYS GCPhysEnd = cbRam + cbRamHole;
2743
2744 /*
2745 * Dump the physical memory, page by page.
2746 */
2747 RTGCPHYS GCPhys = 0;
2748 char abZeroPg[PAGE_SIZE];
2749 RT_ZERO(abZeroPg);
2750
2751 pgmLock(pVM);
2752 for (PPGMRAMRANGE pRam = pVM->pgm.s.pRamRangesXR3;
2753 pRam && pRam->GCPhys < GCPhysEnd && RT_SUCCESS(rc);
2754 pRam = pRam->pNextR3)
2755 {
2756 /* fill the gap */
2757 if (pRam->GCPhys > GCPhys && fIncZeroPgs)
2758 {
2759 while (pRam->GCPhys > GCPhys && RT_SUCCESS(rc))
2760 {
2761 rc = RTFileWrite(hFile, abZeroPg, PAGE_SIZE, NULL);
2762 GCPhys += PAGE_SIZE;
2763 }
2764 }
2765
2766 PCPGMPAGE pPage = &pRam->aPages[0];
2767 while (GCPhys < pRam->GCPhysLast && RT_SUCCESS(rc))
2768 {
2769 if ( PGM_PAGE_IS_ZERO(pPage)
2770 || PGM_PAGE_IS_BALLOONED(pPage))
2771 {
2772 if (fIncZeroPgs)
2773 {
2774 rc = RTFileWrite(hFile, abZeroPg, PAGE_SIZE, NULL);
2775 if (RT_FAILURE(rc))
2776 DBGCCmdHlpPrintf(pCmdHlp, "error: RTFileWrite -> %Rrc at GCPhys=%RGp.\n", rc, GCPhys);
2777 }
2778 }
2779 else
2780 {
2781 switch (PGM_PAGE_GET_TYPE(pPage))
2782 {
2783 case PGMPAGETYPE_RAM:
2784 case PGMPAGETYPE_ROM_SHADOW: /* trouble?? */
2785 case PGMPAGETYPE_ROM:
2786 case PGMPAGETYPE_MMIO2:
2787 {
2788 void const *pvPage;
2789 PGMPAGEMAPLOCK Lock;
2790 rc = PGMPhysGCPhys2CCPtrReadOnly(pVM, GCPhys, &pvPage, &Lock);
2791 if (RT_SUCCESS(rc))
2792 {
2793 rc = RTFileWrite(hFile, pvPage, PAGE_SIZE, NULL);
2794 PGMPhysReleasePageMappingLock(pVM, &Lock);
2795 if (RT_FAILURE(rc))
2796 DBGCCmdHlpPrintf(pCmdHlp, "error: RTFileWrite -> %Rrc at GCPhys=%RGp.\n", rc, GCPhys);
2797 }
2798 else
2799 DBGCCmdHlpPrintf(pCmdHlp, "error: PGMPhysGCPhys2CCPtrReadOnly -> %Rrc at GCPhys=%RGp.\n", rc, GCPhys);
2800 break;
2801 }
2802
2803 default:
2804 AssertFailed();
2805 RT_FALL_THRU();
2806 case PGMPAGETYPE_MMIO:
2807 case PGMPAGETYPE_MMIO2_ALIAS_MMIO:
2808 case PGMPAGETYPE_SPECIAL_ALIAS_MMIO:
2809 if (fIncZeroPgs)
2810 {
2811 rc = RTFileWrite(hFile, abZeroPg, PAGE_SIZE, NULL);
2812 if (RT_FAILURE(rc))
2813 DBGCCmdHlpPrintf(pCmdHlp, "error: RTFileWrite -> %Rrc at GCPhys=%RGp.\n", rc, GCPhys);
2814 }
2815 break;
2816 }
2817 }
2818
2819
2820 /* advance */
2821 GCPhys += PAGE_SIZE;
2822 pPage++;
2823 }
2824 }
2825 pgmUnlock(pVM);
2826
2827 RTFileClose(hFile);
2828 if (RT_SUCCESS(rc))
2829 return DBGCCmdHlpPrintf(pCmdHlp, "Successfully saved physical memory to '%s'.\n", paArgs[0].u.pszString);
2830 return VINF_SUCCESS;
2831}
2832
2833#endif /* VBOX_WITH_DEBUGGER */
2834
2835/**
2836 * pvUser argument of the pgmR3CheckIntegrity*Node callbacks.
2837 */
2838typedef struct PGMCHECKINTARGS
2839{
2840 bool fLeftToRight; /**< true: left-to-right; false: right-to-left. */
2841 PPGMPHYSHANDLER pPrevPhys;
2842#ifdef VBOX_WITH_RAW_MODE
2843 PPGMVIRTHANDLER pPrevVirt;
2844 PPGMPHYS2VIRTHANDLER pPrevPhys2Virt;
2845#else
2846 void *pvFiller1, *pvFiller2;
2847#endif
2848 PVM pVM;
2849} PGMCHECKINTARGS, *PPGMCHECKINTARGS;
2850
2851/**
2852 * Validate a node in the physical handler tree.
2853 *
2854 * @returns 0 on if ok, other wise 1.
2855 * @param pNode The handler node.
2856 * @param pvUser pVM.
2857 */
2858static DECLCALLBACK(int) pgmR3CheckIntegrityPhysHandlerNode(PAVLROGCPHYSNODECORE pNode, void *pvUser)
2859{
2860 PPGMCHECKINTARGS pArgs = (PPGMCHECKINTARGS)pvUser;
2861 PPGMPHYSHANDLER pCur = (PPGMPHYSHANDLER)pNode;
2862 AssertReleaseReturn(!((uintptr_t)pCur & 7), 1);
2863 AssertReleaseMsg(pCur->Core.Key <= pCur->Core.KeyLast,
2864 ("pCur=%p %RGp-%RGp %s\n", pCur, pCur->Core.Key, pCur->Core.KeyLast, pCur->pszDesc));
2865 AssertReleaseMsg( !pArgs->pPrevPhys
2866 || ( pArgs->fLeftToRight
2867 ? pArgs->pPrevPhys->Core.KeyLast < pCur->Core.Key
2868 : pArgs->pPrevPhys->Core.KeyLast > pCur->Core.Key),
2869 ("pPrevPhys=%p %RGp-%RGp %s\n"
2870 " pCur=%p %RGp-%RGp %s\n",
2871 pArgs->pPrevPhys, pArgs->pPrevPhys->Core.Key, pArgs->pPrevPhys->Core.KeyLast, pArgs->pPrevPhys->pszDesc,
2872 pCur, pCur->Core.Key, pCur->Core.KeyLast, pCur->pszDesc));
2873 pArgs->pPrevPhys = pCur;
2874 return 0;
2875}
2876
2877#ifdef VBOX_WITH_RAW_MODE
2878
2879/**
2880 * Validate a node in the virtual handler tree.
2881 *
2882 * @returns 0 on if ok, other wise 1.
2883 * @param pNode The handler node.
2884 * @param pvUser pVM.
2885 */
2886static DECLCALLBACK(int) pgmR3CheckIntegrityVirtHandlerNode(PAVLROGCPTRNODECORE pNode, void *pvUser)
2887{
2888 PPGMCHECKINTARGS pArgs = (PPGMCHECKINTARGS)pvUser;
2889 PPGMVIRTHANDLER pCur = (PPGMVIRTHANDLER)pNode;
2890 AssertReleaseReturn(!((uintptr_t)pCur & 7), 1);
2891 AssertReleaseMsg(pCur->Core.Key <= pCur->Core.KeyLast,("pCur=%p %RGv-%RGv %s\n", pCur, pCur->Core.Key, pCur->Core.KeyLast, pCur->pszDesc));
2892 AssertReleaseMsg( !pArgs->pPrevVirt
2893 || (pArgs->fLeftToRight ? pArgs->pPrevVirt->Core.KeyLast < pCur->Core.Key : pArgs->pPrevVirt->Core.KeyLast > pCur->Core.Key),
2894 ("pPrevVirt=%p %RGv-%RGv %s\n"
2895 " pCur=%p %RGv-%RGv %s\n",
2896 pArgs->pPrevVirt, pArgs->pPrevVirt->Core.Key, pArgs->pPrevVirt->Core.KeyLast, pArgs->pPrevVirt->pszDesc,
2897 pCur, pCur->Core.Key, pCur->Core.KeyLast, pCur->pszDesc));
2898 for (unsigned iPage = 0; iPage < pCur->cPages; iPage++)
2899 {
2900 AssertReleaseMsg(pCur->aPhysToVirt[iPage].offVirtHandler == -(intptr_t)RT_UOFFSETOF_DYN(PGMVIRTHANDLER, aPhysToVirt[iPage]),
2901 ("pCur=%p %RGv-%RGv %s\n"
2902 "iPage=%d offVirtHandle=%#x expected %#x\n",
2903 pCur, pCur->Core.Key, pCur->Core.KeyLast, pCur->pszDesc,
2904 iPage, pCur->aPhysToVirt[iPage].offVirtHandler, -(intptr_t)RT_UOFFSETOF_DYN(PGMVIRTHANDLER, aPhysToVirt[iPage])));
2905 }
2906 pArgs->pPrevVirt = pCur;
2907 return 0;
2908}
2909
2910
2911/**
2912 * Validate a node in the virtual handler tree.
2913 *
2914 * @returns 0 on if ok, other wise 1.
2915 * @param pNode The handler node.
2916 * @param pvUser pVM.
2917 */
2918static DECLCALLBACK(int) pgmR3CheckIntegrityPhysToVirtHandlerNode(PAVLROGCPHYSNODECORE pNode, void *pvUser)
2919{
2920 PPGMCHECKINTARGS pArgs = (PPGMCHECKINTARGS)pvUser;
2921 PPGMPHYS2VIRTHANDLER pCur = (PPGMPHYS2VIRTHANDLER)pNode;
2922 AssertReleaseMsgReturn(!((uintptr_t)pCur & 3), ("\n"), 1);
2923 AssertReleaseMsgReturn(!(pCur->offVirtHandler & 3), ("\n"), 1);
2924 AssertReleaseMsg(pCur->Core.Key <= pCur->Core.KeyLast,("pCur=%p %RGp-%RGp\n", pCur, pCur->Core.Key, pCur->Core.KeyLast));
2925 AssertReleaseMsg( !pArgs->pPrevPhys2Virt
2926 || (pArgs->fLeftToRight ? pArgs->pPrevPhys2Virt->Core.KeyLast < pCur->Core.Key : pArgs->pPrevPhys2Virt->Core.KeyLast > pCur->Core.Key),
2927 ("pPrevPhys2Virt=%p %RGp-%RGp\n"
2928 " pCur=%p %RGp-%RGp\n",
2929 pArgs->pPrevPhys2Virt, pArgs->pPrevPhys2Virt->Core.Key, pArgs->pPrevPhys2Virt->Core.KeyLast,
2930 pCur, pCur->Core.Key, pCur->Core.KeyLast));
2931 AssertReleaseMsg( !pArgs->pPrevPhys2Virt
2932 || (pArgs->fLeftToRight ? pArgs->pPrevPhys2Virt->Core.KeyLast < pCur->Core.Key : pArgs->pPrevPhys2Virt->Core.KeyLast > pCur->Core.Key),
2933 ("pPrevPhys2Virt=%p %RGp-%RGp\n"
2934 " pCur=%p %RGp-%RGp\n",
2935 pArgs->pPrevPhys2Virt, pArgs->pPrevPhys2Virt->Core.Key, pArgs->pPrevPhys2Virt->Core.KeyLast,
2936 pCur, pCur->Core.Key, pCur->Core.KeyLast));
2937 AssertReleaseMsg((pCur->offNextAlias & (PGMPHYS2VIRTHANDLER_IN_TREE | PGMPHYS2VIRTHANDLER_IS_HEAD)) == (PGMPHYS2VIRTHANDLER_IN_TREE | PGMPHYS2VIRTHANDLER_IS_HEAD),
2938 ("pCur=%p:{.Core.Key=%RGp, .Core.KeyLast=%RGp, .offVirtHandler=%#RX32, .offNextAlias=%#RX32}\n",
2939 pCur, pCur->Core.Key, pCur->Core.KeyLast, pCur->offVirtHandler, pCur->offNextAlias));
2940 if (pCur->offNextAlias & PGMPHYS2VIRTHANDLER_OFF_MASK)
2941 {
2942 PPGMPHYS2VIRTHANDLER pCur2 = pCur;
2943 for (;;)
2944 {
2945 pCur2 = (PPGMPHYS2VIRTHANDLER)((intptr_t)pCur + (pCur->offNextAlias & PGMPHYS2VIRTHANDLER_OFF_MASK));
2946 AssertReleaseMsg(pCur2 != pCur,
2947 (" pCur=%p:{.Core.Key=%RGp, .Core.KeyLast=%RGp, .offVirtHandler=%#RX32, .offNextAlias=%#RX32}\n",
2948 pCur, pCur->Core.Key, pCur->Core.KeyLast, pCur->offVirtHandler, pCur->offNextAlias));
2949 AssertReleaseMsg((pCur2->offNextAlias & (PGMPHYS2VIRTHANDLER_IN_TREE | PGMPHYS2VIRTHANDLER_IS_HEAD)) == PGMPHYS2VIRTHANDLER_IN_TREE,
2950 (" pCur=%p:{.Core.Key=%RGp, .Core.KeyLast=%RGp, .offVirtHandler=%#RX32, .offNextAlias=%#RX32}\n"
2951 "pCur2=%p:{.Core.Key=%RGp, .Core.KeyLast=%RGp, .offVirtHandler=%#RX32, .offNextAlias=%#RX32}\n",
2952 pCur, pCur->Core.Key, pCur->Core.KeyLast, pCur->offVirtHandler, pCur->offNextAlias,
2953 pCur2, pCur2->Core.Key, pCur2->Core.KeyLast, pCur2->offVirtHandler, pCur2->offNextAlias));
2954 AssertReleaseMsg((pCur2->Core.Key ^ pCur->Core.Key) < PAGE_SIZE,
2955 (" pCur=%p:{.Core.Key=%RGp, .Core.KeyLast=%RGp, .offVirtHandler=%#RX32, .offNextAlias=%#RX32}\n"
2956 "pCur2=%p:{.Core.Key=%RGp, .Core.KeyLast=%RGp, .offVirtHandler=%#RX32, .offNextAlias=%#RX32}\n",
2957 pCur, pCur->Core.Key, pCur->Core.KeyLast, pCur->offVirtHandler, pCur->offNextAlias,
2958 pCur2, pCur2->Core.Key, pCur2->Core.KeyLast, pCur2->offVirtHandler, pCur2->offNextAlias));
2959 AssertReleaseMsg((pCur2->Core.KeyLast ^ pCur->Core.KeyLast) < PAGE_SIZE,
2960 (" pCur=%p:{.Core.Key=%RGp, .Core.KeyLast=%RGp, .offVirtHandler=%#RX32, .offNextAlias=%#RX32}\n"
2961 "pCur2=%p:{.Core.Key=%RGp, .Core.KeyLast=%RGp, .offVirtHandler=%#RX32, .offNextAlias=%#RX32}\n",
2962 pCur, pCur->Core.Key, pCur->Core.KeyLast, pCur->offVirtHandler, pCur->offNextAlias,
2963 pCur2, pCur2->Core.Key, pCur2->Core.KeyLast, pCur2->offVirtHandler, pCur2->offNextAlias));
2964 if (!(pCur2->offNextAlias & PGMPHYS2VIRTHANDLER_OFF_MASK))
2965 break;
2966 }
2967 }
2968
2969 pArgs->pPrevPhys2Virt = pCur;
2970 return 0;
2971}
2972
2973#endif /* VBOX_WITH_RAW_MODE */
2974
2975/**
2976 * Perform an integrity check on the PGM component.
2977 *
2978 * @returns VINF_SUCCESS if everything is fine.
2979 * @returns VBox error status after asserting on integrity breach.
2980 * @param pVM The cross context VM structure.
2981 */
2982VMMR3DECL(int) PGMR3CheckIntegrity(PVM pVM)
2983{
2984 AssertReleaseReturn(pVM->pgm.s.offVM, VERR_INTERNAL_ERROR);
2985
2986 /*
2987 * Check the trees.
2988 */
2989 int cErrors = 0;
2990 const PGMCHECKINTARGS LeftToRight = { true, NULL, NULL, NULL, pVM };
2991 const PGMCHECKINTARGS RightToLeft = { false, NULL, NULL, NULL, pVM };
2992 PGMCHECKINTARGS Args = LeftToRight;
2993 cErrors += RTAvlroGCPhysDoWithAll(&pVM->pgm.s.pTreesR3->PhysHandlers, true, pgmR3CheckIntegrityPhysHandlerNode, &Args);
2994 Args = RightToLeft;
2995 cErrors += RTAvlroGCPhysDoWithAll(&pVM->pgm.s.pTreesR3->PhysHandlers, false, pgmR3CheckIntegrityPhysHandlerNode, &Args);
2996#ifdef VBOX_WITH_RAW_MODE
2997 Args = LeftToRight;
2998 cErrors += RTAvlroGCPtrDoWithAll( &pVM->pgm.s.pTreesR3->VirtHandlers, true, pgmR3CheckIntegrityVirtHandlerNode, &Args);
2999 Args = RightToLeft;
3000 cErrors += RTAvlroGCPtrDoWithAll( &pVM->pgm.s.pTreesR3->VirtHandlers, false, pgmR3CheckIntegrityVirtHandlerNode, &Args);
3001 Args = LeftToRight;
3002 cErrors += RTAvlroGCPtrDoWithAll( &pVM->pgm.s.pTreesR3->HyperVirtHandlers, true, pgmR3CheckIntegrityVirtHandlerNode, &Args);
3003 Args = RightToLeft;
3004 cErrors += RTAvlroGCPtrDoWithAll( &pVM->pgm.s.pTreesR3->HyperVirtHandlers, false, pgmR3CheckIntegrityVirtHandlerNode, &Args);
3005 Args = LeftToRight;
3006 cErrors += RTAvlroGCPhysDoWithAll(&pVM->pgm.s.pTreesR3->PhysToVirtHandlers, true, pgmR3CheckIntegrityPhysToVirtHandlerNode, &Args);
3007 Args = RightToLeft;
3008 cErrors += RTAvlroGCPhysDoWithAll(&pVM->pgm.s.pTreesR3->PhysToVirtHandlers, false, pgmR3CheckIntegrityPhysToVirtHandlerNode, &Args);
3009#endif /* VBOX_WITH_RAW_MODE */
3010
3011 return !cErrors ? VINF_SUCCESS : VERR_INTERNAL_ERROR;
3012}
3013
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