4 The mmu (in arch/x86/kvm, files mmu.[ch] and paging_tmpl.h) is responsible
5 for presenting a standard x86 mmu to the guest, while translating guest
6 physical addresses to host physical addresses.
8 The mmu code attempts to satisfy the following requirements:
10 - correctness: the guest should not be able to determine that it is running
11 on an emulated mmu except for timing (we attempt to comply
12 with the specification, not emulate the characteristics of
13 a particular implementation such as tlb size)
14 - security: the guest must not be able to touch host memory not assigned
16 - performance: minimize the performance penalty imposed by the mmu
17 - scaling: need to scale to large memory and large vcpu guests
18 - hardware: support the full range of x86 virtualization hardware
19 - integration: Linux memory management code must be in control of guest memory
20 so that swapping, page migration, page merging, transparent
21 hugepages, and similar features work without change
22 - dirty tracking: report writes to guest memory to enable live migration
23 and framebuffer-based displays
24 - footprint: keep the amount of pinned kernel memory low (most memory
26 - reliability: avoid multipage or GFP_ATOMIC allocations
31 pfn host page frame number
32 hpa host physical address
33 hva host virtual address
34 gfn guest frame number
35 gpa guest physical address
36 gva guest virtual address
37 ngpa nested guest physical address
38 ngva nested guest virtual address
39 pte page table entry (used also to refer generically to paging structure
41 gpte guest pte (referring to gfns)
42 spte shadow pte (referring to pfns)
43 tdp two dimensional paging (vendor neutral term for NPT and EPT)
45 Virtual and real hardware supported
46 ===================================
48 The mmu supports first-generation mmu hardware, which allows an atomic switch
49 of the current paging mode and cr3 during guest entry, as well as
50 two-dimensional paging (AMD's NPT and Intel's EPT). The emulated hardware
51 it exposes is the traditional 2/3/4 level x86 mmu, with support for global
52 pages, pae, pse, pse36, cr0.wp, and 1GB pages. Work is in progress to support
53 exposing NPT capable hardware on NPT capable hosts.
58 The primary job of the mmu is to program the processor's mmu to translate
59 addresses for the guest. Different translations are required at different
62 - when guest paging is disabled, we translate guest physical addresses to
63 host physical addresses (gpa->hpa)
64 - when guest paging is enabled, we translate guest virtual addresses, to
65 guest physical addresses, to host physical addresses (gva->gpa->hpa)
66 - when the guest launches a guest of its own, we translate nested guest
67 virtual addresses, to nested guest physical addresses, to guest physical
68 addresses, to host physical addresses (ngva->ngpa->gpa->hpa)
70 The primary challenge is to encode between 1 and 3 translations into hardware
71 that support only 1 (traditional) and 2 (tdp) translations. When the
72 number of required translations matches the hardware, the mmu operates in
73 direct mode; otherwise it operates in shadow mode (see below).
78 Guest memory (gpa) is part of the user address space of the process that is
79 using kvm. Userspace defines the translation between guest addresses and user
80 addresses (gpa->hva); note that two gpas may alias to the same hva, but not
83 These hvas may be backed using any method available to the host: anonymous
84 memory, file backed memory, and device memory. Memory might be paged by the
90 The mmu is driven by events, some from the guest, some from the host.
92 Guest generated events:
93 - writes to control registers (especially cr3)
94 - invlpg/invlpga instruction execution
95 - access to missing or protected translations
97 Host generated events:
98 - changes in the gpa->hpa translation (either through gpa->hva changes or
99 through hva->hpa changes)
100 - memory pressure (the shrinker)
105 The principal data structure is the shadow page, 'struct kvm_mmu_page'. A
106 shadow page contains 512 sptes, which can be either leaf or nonleaf sptes. A
107 shadow page may contain a mix of leaf and nonleaf sptes.
109 A nonleaf spte allows the hardware mmu to reach the leaf pages and
110 is not related to a translation directly. It points to other shadow pages.
112 A leaf spte corresponds to either one or two translations encoded into
113 one paging structure entry. These are always the lowest level of the
114 translation stack, with optional higher level translations left to NPT/EPT.
115 Leaf ptes point at guest pages.
117 The following table shows translations encoded by leaf ptes, with higher-level
118 translations in parentheses:
122 paging: gva->gpa->hpa
123 paging, tdp: (gva->)gpa->hpa
125 non-tdp: ngva->gpa->hpa (*)
126 tdp: (ngva->)ngpa->gpa->hpa
128 (*) the guest hypervisor will encode the ngva->gpa translation into its page
129 tables if npt is not present
131 Shadow pages contain the following information:
133 The level in the shadow paging hierarchy that this shadow page belongs to.
134 1=4k sptes, 2=2M sptes, 3=1G sptes, etc.
136 If set, leaf sptes reachable from this page are for a linear range.
137 Examples include real mode translation, large guest pages backed by small
138 host pages, and gpa->hpa translations when NPT or EPT is active.
139 The linear range starts at (gfn << PAGE_SHIFT) and its size is determined
140 by role.level (2MB for first level, 1GB for second level, 0.5TB for third
141 level, 256TB for fourth level)
142 If clear, this page corresponds to a guest page table denoted by the gfn
145 When role.cr4_pae=0, the guest uses 32-bit gptes while the host uses 64-bit
146 sptes. That means a guest page table contains more ptes than the host,
147 so multiple shadow pages are needed to shadow one guest page.
148 For first-level shadow pages, role.quadrant can be 0 or 1 and denotes the
149 first or second 512-gpte block in the guest page table. For second-level
150 page tables, each 32-bit gpte is converted to two 64-bit sptes
151 (since each first-level guest page is shadowed by two first-level
152 shadow pages) so role.quadrant takes values in the range 0..3. Each
153 quadrant maps 1GB virtual address space.
155 Inherited guest access permissions in the form uwx. Note execute
156 permission is positive, not negative.
158 The page is invalid and should not be used. It is a root page that is
159 currently pinned (by a cpu hardware register pointing to it); once it is
160 unpinned it will be destroyed.
162 Contains the value of cr4.pae for which the page is valid (e.g. whether
163 32-bit or 64-bit gptes are in use).
165 Contains the value of efer.nxe for which the page is valid.
167 Contains the value of cr0.wp for which the page is valid.
169 Either the guest page table containing the translations shadowed by this
170 page, or the base page frame for linear translations. See role.direct.
172 A pageful of 64-bit sptes containing the translations for this page.
173 Accessed by both kvm and hardware.
174 The page pointed to by spt will have its page->private pointing back
175 at the shadow page structure.
176 sptes in spt point either at guest pages, or at lower-level shadow pages.
177 Specifically, if sp1 and sp2 are shadow pages, then sp1->spt[n] may point
178 at __pa(sp2->spt). sp2 will point back at sp1 through parent_pte.
179 The spt array forms a DAG structure with the shadow page as a node, and
180 guest pages as leaves.
182 An array of 512 guest frame numbers, one for each present pte. Used to
183 perform a reverse map from a pte to a gfn. When role.direct is set, any
184 element of this array can be calculated from the gfn field when used, in
185 this case, the array of gfns is not allocated. See role.direct and gfn.
187 A bitmap containing one bit per memory slot. If the page contains a pte
188 mapping a page from memory slot n, then bit n of slot_bitmap will be set
189 (if a page is aliased among several slots, then it is not guaranteed that
190 all slots will be marked).
191 Used during dirty logging to avoid scanning a shadow page if none if its
194 A counter keeping track of how many hardware registers (guest cr3 or
195 pdptrs) are now pointing at the page. While this counter is nonzero, the
196 page cannot be destroyed. See role.invalid.
198 Whether there exist multiple sptes pointing at this page.
199 parent_pte/parent_ptes:
200 If multimapped is zero, parent_pte points at the single spte that points at
201 this page's spt. Otherwise, parent_ptes points at a data structure
202 with a list of parent_ptes.
204 If true, then the translations in this page may not match the guest's
205 translation. This is equivalent to the state of the tlb when a pte is
206 changed but before the tlb entry is flushed. Accordingly, unsync ptes
207 are synchronized when the guest executes invlpg or flushes its tlb by
208 other means. Valid for leaf pages.
210 How many sptes in the page point at pages that are unsync (or have
211 unsynchronized children).
213 A bitmap indicating which sptes in spt point (directly or indirectly) at
214 pages that may be unsynchronized. Used to quickly locate all unsychronized
215 pages reachable from a given page.
220 The mmu maintains a reverse mapping whereby all ptes mapping a page can be
221 reached given its gfn. This is used, for example, when swapping out a page.
223 Synchronized and unsynchronized pages
224 =====================================
226 The guest uses two events to synchronize its tlb and page tables: tlb flushes
227 and page invalidations (invlpg).
229 A tlb flush means that we need to synchronize all sptes reachable from the
230 guest's cr3. This is expensive, so we keep all guest page tables write
231 protected, and synchronize sptes to gptes when a gpte is written.
233 A special case is when a guest page table is reachable from the current
234 guest cr3. In this case, the guest is obliged to issue an invlpg instruction
235 before using the translation. We take advantage of that by removing write
236 protection from the guest page, and allowing the guest to modify it freely.
237 We synchronize modified gptes when the guest invokes invlpg. This reduces
238 the amount of emulation we have to do when the guest modifies multiple gptes,
239 or when the a guest page is no longer used as a page table and is used for
242 As a side effect we have to resynchronize all reachable unsynchronized shadow
243 pages on a tlb flush.
249 - guest page fault (or npt page fault, or ept violation)
251 This is the most complicated event. The cause of a page fault can be:
253 - a true guest fault (the guest translation won't allow the access) (*)
254 - access to a missing translation
255 - access to a protected translation
256 - when logging dirty pages, memory is write protected
257 - synchronized shadow pages are write protected (*)
258 - access to untranslatable memory (mmio)
260 (*) not applicable in direct mode
262 Handling a page fault is performed as follows:
264 - if needed, walk the guest page tables to determine the guest translation
265 (gva->gpa or ngpa->gpa)
266 - if permissions are insufficient, reflect the fault back to the guest
267 - determine the host page
268 - if this is an mmio request, there is no host page; call the emulator
269 to emulate the instruction instead
270 - walk the shadow page table to find the spte for the translation,
271 instantiating missing intermediate page tables as necessary
272 - try to unsynchronize the page
273 - if successful, we can let the guest continue and modify the gpte
274 - emulate the instruction
275 - if failed, unshadow the page and let the guest continue
276 - update any translations that were modified by the instruction
280 - walk the shadow page hierarchy and drop affected translations
281 - try to reinstantiate the indicated translation in the hope that the
282 guest will use it in the near future
284 Guest control register updates:
287 - look up new shadow roots
288 - synchronize newly reachable shadow pages
290 - mov to cr0/cr4/efer
291 - set up mmu context for new paging mode
292 - look up new shadow roots
293 - synchronize newly reachable shadow pages
295 Host translation updates:
297 - mmu notifier called with updated hva
298 - look up affected sptes through reverse map
299 - drop (or update) translations
304 If tdp is not enabled, the host must keep cr0.wp=1 so page write protection
305 works for the guest kernel, not guest guest userspace. When the guest
306 cr0.wp=1, this does not present a problem. However when the guest cr0.wp=0,
307 we cannot map the permissions for gpte.u=1, gpte.w=0 to any spte (the
308 semantics require allowing any guest kernel access plus user read access).
310 We handle this by mapping the permissions to two possible sptes, depending
313 - kernel write fault: spte.u=0, spte.w=1 (allows full kernel access,
314 disallows user access)
315 - read fault: spte.u=1, spte.w=0 (allows full read access, disallows kernel
318 (user write faults generate a #PF)
323 The mmu supports all combinations of large and small guest and host pages.
324 Supported page sizes include 4k, 2M, 4M, and 1G. 4M pages are treated as
325 two separate 2M pages, on both guest and host, since the mmu always uses PAE
328 To instantiate a large spte, four constraints must be satisfied:
330 - the spte must point to a large host page
331 - the guest pte must be a large pte of at least equivalent size (if tdp is
332 enabled, there is no guest pte and this condition is satisified)
333 - if the spte will be writeable, the large page frame may not overlap any
334 write-protected pages
335 - the guest page must be wholly contained by a single memory slot
337 To check the last two conditions, the mmu maintains a ->write_count set of
338 arrays for each memory slot and large page size. Every write protected page
339 causes its write_count to be incremented, thus preventing instantiation of
340 a large spte. The frames at the end of an unaligned memory slot have
341 artificically inflated ->write_counts so they can never be instantiated.
346 - NPT presentation from KVM Forum 2008
347 http://www.linux-kvm.org/wiki/images/c/c8/KvmForum2008%24kdf2008_21.pdf