| blob | 72213da605f50c07f3684ca07d351a8bbd7435ef |
1 /*
2 * Xen leaves the responsibility for maintaining p2m mappings to the
3 * guests themselves, but it must also access and update the p2m array
4 * during suspend/resume when all the pages are reallocated.
5 *
6 * The p2m table is logically a flat array, but we implement it as a
7 * three-level tree to allow the address space to be sparse.
8 *
9 * Xen
10 * |
11 * p2m_top p2m_top_mfn
12 * / \ / \
13 * p2m_mid p2m_mid p2m_mid_mfn p2m_mid_mfn
14 * / \ / \ / /
15 * p2m p2m p2m p2m p2m p2m p2m ...
16 *
17 * The p2m_mid_mfn pages are mapped by p2m_top_mfn_p.
18 *
19 * The p2m_top and p2m_top_mfn levels are limited to 1 page, so the
20 * maximum representable pseudo-physical address space is:
21 * P2M_TOP_PER_PAGE * P2M_MID_PER_PAGE * P2M_PER_PAGE pages
22 *
23 * P2M_PER_PAGE depends on the architecture, as a mfn is always
24 * unsigned long (8 bytes on 64-bit, 4 bytes on 32), leading to
25 * 512 and 1024 entries respectively.
26 *
27 * In short, these structures contain the Machine Frame Number (MFN) of the PFN.
28 *
29 * However not all entries are filled with MFNs. Specifically for all other
30 * leaf entries, or for the top root, or middle one, for which there is a void
31 * entry, we assume it is "missing". So (for example)
32 * pfn_to_mfn(0x90909090)=INVALID_P2M_ENTRY.
33 *
34 * We also have the possibility of setting 1-1 mappings on certain regions, so
35 * that:
36 * pfn_to_mfn(0xc0000)=0xc0000
37 *
38 * The benefit of this is, that we can assume for non-RAM regions (think
39 * PCI BARs, or ACPI spaces), we can create mappings easily b/c we
40 * get the PFN value to match the MFN.
41 *
42 * For this to work efficiently we have one new page p2m_identity and
43 * allocate (via reserved_brk) any other pages we need to cover the sides
44 * (1GB or 4MB boundary violations). All entries in p2m_identity are set to
45 * INVALID_P2M_ENTRY type (Xen toolstack only recognizes that and MFNs,
46 * no other fancy value).
47 *
48 * On lookup we spot that the entry points to p2m_identity and return the
49 * identity value instead of dereferencing and returning INVALID_P2M_ENTRY.
50 * If the entry points to an allocated page, we just proceed as before and
51 * return the PFN. If the PFN has IDENTITY_FRAME_BIT set we unmask that in
52 * appropriate functions (pfn_to_mfn).
53 *
54 * The reason for having the IDENTITY_FRAME_BIT instead of just returning the
55 * PFN is that we could find ourselves where pfn_to_mfn(pfn)==pfn for a
56 * non-identity pfn. To protect ourselves against we elect to set (and get) the
57 * IDENTITY_FRAME_BIT on all identity mapped PFNs.
58 *
59 * This simplistic diagram is used to explain the more subtle piece of code.
60 * There is also a digram of the P2M at the end that can help.
61 * Imagine your E820 looking as so:
62 *
63 * 1GB 2GB
64 * /-------------------+---------\/----\ /----------\ /---+-----\
65 * | System RAM | Sys RAM ||ACPI| | reserved | | Sys RAM |
66 * \-------------------+---------/\----/ \----------/ \---+-----/
67 * ^- 1029MB ^- 2001MB
68 *
69 * [1029MB = 263424 (0x40500), 2001MB = 512256 (0x7D100),
70 * 2048MB = 524288 (0x80000)]
71 *
72 * And dom0_mem=max:3GB,1GB is passed in to the guest, meaning memory past 1GB
73 * is actually not present (would have to kick the balloon driver to put it in).
74 *
75 * When we are told to set the PFNs for identity mapping (see patch: "xen/setup:
76 * Set identity mapping for non-RAM E820 and E820 gaps.") we pass in the start
77 * of the PFN and the end PFN (263424 and 512256 respectively). The first step
78 * is to reserve_brk a top leaf page if the p2m[1] is missing. The top leaf page
79 * covers 512^2 of page estate (1GB) and in case the start or end PFN is not
80 * aligned on 512^2*PAGE_SIZE (1GB) we loop on aligned 1GB PFNs from start pfn
81 * to end pfn. We reserve_brk top leaf pages if they are missing (means they
82 * point to p2m_mid_missing).
83 *
84 * With the E820 example above, 263424 is not 1GB aligned so we allocate a
85 * reserve_brk page which will cover the PFNs estate from 0x40000 to 0x80000.
86 * Each entry in the allocate page is "missing" (points to p2m_missing).
87 *
88 * Next stage is to determine if we need to do a more granular boundary check
89 * on the 4MB (or 2MB depending on architecture) off the start and end pfn's.
90 * We check if the start pfn and end pfn violate that boundary check, and if
91 * so reserve_brk a middle (p2m[x][y]) leaf page. This way we have a much finer
92 * granularity of setting which PFNs are missing and which ones are identity.
93 * In our example 263424 and 512256 both fail the check so we reserve_brk two
94 * pages. Populate them with INVALID_P2M_ENTRY (so they both have "missing"
95 * values) and assign them to p2m[1][2] and p2m[1][488] respectively.
96 *
97 * At this point we would at minimum reserve_brk one page, but could be up to
98 * three. Each call to set_phys_range_identity has at maximum a three page
99 * cost. If we were to query the P2M at this stage, all those entries from
100 * start PFN through end PFN (so 1029MB -> 2001MB) would return
101 * INVALID_P2M_ENTRY ("missing").
102 *
103 * The next step is to walk from the start pfn to the end pfn setting
104 * the IDENTITY_FRAME_BIT on each PFN. This is done in set_phys_range_identity.
105 * If we find that the middle leaf is pointing to p2m_missing we can swap it
106 * over to p2m_identity - this way covering 4MB (or 2MB) PFN space. At this
107 * point we do not need to worry about boundary aligment (so no need to
108 * reserve_brk a middle page, figure out which PFNs are "missing" and which
109 * ones are identity), as that has been done earlier. If we find that the
110 * middle leaf is not occupied by p2m_identity or p2m_missing, we dereference
111 * that page (which covers 512 PFNs) and set the appropriate PFN with
112 * IDENTITY_FRAME_BIT. In our example 263424 and 512256 end up there, and we
113 * set from p2m[1][2][256->511] and p2m[1][488][0->256] with
114 * IDENTITY_FRAME_BIT set.
115 *
116 * All other regions that are void (or not filled) either point to p2m_missing
117 * (considered missing) or have the default value of INVALID_P2M_ENTRY (also
118 * considered missing). In our case, p2m[1][2][0->255] and p2m[1][488][257->511]
119 * contain the INVALID_P2M_ENTRY value and are considered "missing."
120 *
121 * This is what the p2m ends up looking (for the E820 above) with this
122 * fabulous drawing:
123 *
124 * p2m /--------------\
125 * /-----\ | &mfn_list[0],| /-----------------\
126 * | 0 |------>| &mfn_list[1],| /---------------\ | ~0, ~0, .. |
127 * |-----| | ..., ~0, ~0 | | ~0, ~0, [x]---+----->| IDENTITY [@256] |
128 * | 1 |---\ \--------------/ | [p2m_identity]+\ | IDENTITY [@257] |
129 * |-----| \ | [p2m_identity]+\\ | .... |
130 * | 2 |--\ \-------------------->| ... | \\ \----------------/
131 * |-----| \ \---------------/ \\
132 * | 3 |\ \ \\ p2m_identity
133 * |-----| \ \-------------------->/---------------\ /-----------------\
134 * | .. +->+ | [p2m_identity]+-->| ~0, ~0, ~0, ... |
135 * \-----/ / | [p2m_identity]+-->| ..., ~0 |
136 * / /---------------\ | .... | \-----------------/
137 * / | IDENTITY[@0] | /-+-[x], ~0, ~0.. |
138 * / | IDENTITY[@256]|<----/ \---------------/
139 * / | ~0, ~0, .... |
140 * | \---------------/
141 * |
142 * p2m_missing p2m_missing
143 * /------------------\ /------------\
144 * | [p2m_mid_missing]+---->| ~0, ~0, ~0 |
145 * | [p2m_mid_missing]+---->| ..., ~0 |
146 * \------------------/ \------------/
147 *
148 * where ~0 is INVALID_P2M_ENTRY. IDENTITY is (PFN | IDENTITY_BIT)
149 */
151 #include <linux/init.h>
152 #include <linux/module.h>
153 #include <linux/list.h>
154 #include <linux/hash.h>
155 #include <linux/sched.h>
156 #include <linux/seq_file.h>
158 #include <asm/cache.h>
159 #include <asm/setup.h>
161 #include <asm/xen/page.h>
162 #include <asm/xen/hypercall.h>
163 #include <asm/xen/hypervisor.h>
164 #include <xen/grant_table.h>
173 #define P2M_PER_PAGE (PAGE_SIZE / sizeof(unsigned long))
174 #define P2M_MID_PER_PAGE (PAGE_SIZE / sizeof(unsigned long *))
175 #define P2M_TOP_PER_PAGE (PAGE_SIZE / sizeof(unsigned long **))
177 #define MAX_P2M_PFN (P2M_TOP_PER_PAGE * P2M_MID_PER_PAGE * P2M_PER_PAGE)
179 /* Placeholders for holes in the address space */
193 /* We might hit two boundary violations at the start and end, at max each
194 * boundary violation will require three middle nodes. */
197 /* When we populate back during bootup, the amount of pages can vary. The
198 * max we have is seen is 395979, but that does not mean it can't be more.
199 * Some machines can have 3GB I/O holes even. With early_can_reuse_p2m_middle
200 * it can re-use Xen provided mfn_list array, so we only need to allocate at
201 * most three P2M top nodes. */
205 {
208 }
211 {
213 }
216 {
218 }
221 {
226 }
229 {
234 }
237 {
242 }
245 {
250 }
253 {
258 }
261 {
266 }
268 /*
269 * Build the parallel p2m_top_mfn and p2m_mid_mfn structures
270 *
271 * This is called both at boot time, and after resuming from suspend:
272 * - At boot time we're called very early, and must use extend_brk()
273 * to allocate memory.
274 *
275 * - After resume we're called from within stop_machine, but the mfn
276 * tree should alreay be completely allocated.
277 */
279 {
282 /* Pre-initialize p2m_top_mfn to be completely missing */
293 /* Reinitialise, mfn's all change after migration */
295 }
306 /* Don't bother allocating any mfn mid levels if
307 * they're just missing, just update the stored mfn,
308 * since all could have changed over a migrate.
309 */
316 }
319 /*
320 * XXX boot-time only! We should never find
321 * missing parts of the mfn tree after
322 * runtime. extend_brk() will BUG if we call
323 * it too late.
324 */
329 }
333 }
334 }
337 {
343 }
345 /* Set up p2m_top to point to the domain-builder provided p2m pages */
347 {
366 /*
367 * The domain builder gives us a pre-constructed p2m array in
368 * mfn_list for all the pages initially given to us, so we just
369 * need to graft that into our tree structure.
370 */
380 }
382 /*
383 * As long as the mfn_list has enough entries to completely
384 * fill a p2m page, pointing into the array is ok. But if
385 * not the entries beyond the last pfn will be undefined.
386 */
393 }
395 }
398 }
401 {
411 /*
412 * The INVALID_P2M_ENTRY is filled in both p2m_*identity
413 * and in p2m_*missing, so returning the INVALID_P2M_ENTRY
414 * would be wrong.
415 */
420 }
424 {
426 }
429 {
431 }
433 /*
434 * Fully allocate the p2m structure for a given pfn. We need to check
435 * that both the top and mid levels are allocated, and make sure the
436 * parallel mfn tree is kept in sync. We may race with other cpus, so
437 * the new pages are installed with cmpxchg; if we lose the race then
438 * simply free the page we allocated and use the one that's there.
439 */
441 {
453 /* Mid level is missing, allocate a new one */
462 }
470 /* Separately check the mid mfn level */
484 else
486 }
490 /* p2m leaf page is missing */
502 else
504 }
507 }
510 {
519 /* Pfff.. No boundary cross-over, lets get out. */
527 /*
528 * Could be done by xen_build_dynamic_phys_to_machine..
529 */
533 /* Boundary cross-over for the edges: */
540 /* For save/restore we need to MFN of the P2M saved */
549 }
552 {
567 }
568 /* And the save/restore P2M tables.. */
575 /* Note: we don't set mid_mfn_p[midix] here,
576 * look in early_alloc_p2m_middle */
577 }
579 }
581 /*
582 * Skim over the P2M tree looking at pages that are either filled with
583 * INVALID_P2M_ENTRY or with 1:1 PFNs. If found, re-use that page and
584 * replace the P2M leaf with a p2m_missing or p2m_identity.
585 * Stick the old page in the new P2M tree location.
586 */
588 {
598 /* We only look when this entails a P2M middle layer */
625 /* IDENTITY_PFNs are 1:1 */
627 ident_pfns++;
629 inv_pfns++;
630 else
632 }
635 }
637 found:
638 /* Found one, replace old with p2m_identity or p2m_missing */
640 /* And the other for save/restore.. */
642 /* NOTE: Even if it is a p2m_identity it should still be point to
643 * a page filled with INVALID_P2M_ENTRY entries. */
646 /* Reset where we want to stick the old page in. */
650 /* This shouldn't happen */
663 }
665 {
678 }
681 }
684 {
699 {
701 }
716 }
718 /* Try to install p2m mapping; fail if intermediate bits missing */
720 {
726 }
730 }
736 /* For sparse holes were the p2m leaf has real PFN along with
737 * PCI holes, stick in the PFN as the MFN value.
738 */
743 /* Swap over from MISSING to IDENTITY if needed. */
748 }
749 }
757 }
760 {
767 }
770 }
772 #define M2P_OVERRIDE_HASH_SHIFT 10
773 #define M2P_OVERRIDE_HASH (1 << M2P_OVERRIDE_HASH_SHIFT)
779 {
787 }
790 {
792 }
794 /* Add an MFN override for a particular page */
797 {
812 }
830 }
831 }
836 /* p2m(m2p(mfn)) == mfn: the mfn is already present somewhere in
837 * this domain. Set the FOREIGN_FRAME_BIT in the p2m for the other
838 * pfn so that the following mfn_to_pfn(mfn) calls will return the
839 * pfn from the m2p_override (the backend pfn) instead.
840 * We need to do this because the pages shared by the frontend
841 * (xen-blkfront) can be already locked (lock_page, called by
842 * do_read_cache_page); when the userspace backend tries to use them
843 * with direct_IO, mfn_to_pfn returns the pfn of the frontend, so
844 * do_blockdev_direct_IO is going to try to lock the same pages
845 * again resulting in a deadlock.
846 * As a side effect get_user_pages_fast might not be safe on the
847 * frontend pages while they are being shared with the backend,
848 * because mfn_to_pfn (that ends up being called by GUPF) will
849 * return the backend pfn rather than the frontend pfn. */
855 }
859 {
880 }
894 /*
895 * It might be that we queued all the m2p grant table
896 * hypercalls in a multicall, then m2p_remove_override
897 * get called before the multicall has actually been
898 * issued. In this case handle is going to -1 because
899 * it hasn't been modified yet.
900 */
903 /*
904 * Now if kmap_op->handle is negative it means that the
905 * hypercall actually returned an error.
906 */
912 }
930 }
931 }
933 /* p2m(m2p(mfn)) == FOREIGN_FRAME(mfn): the mfn is already present
934 * somewhere in this domain, even before being added to the
935 * m2p_override (see comment above in m2p_add_override).
936 * If there are no other entries in the m2p_override corresponding
937 * to this mfn, then remove the FOREIGN_FRAME_BIT from the p2m for
938 * the original pfn (the one shared by the frontend): the backend
939 * cannot do any IO on this page anymore because it has been
940 * unshared. Removing the FOREIGN_FRAME_BIT from the p2m entry of
941 * the original pfn causes mfn_to_pfn(mfn) to return the frontend
942 * pfn again. */
950 }
954 {
967 }
968 }
973 }
976 {
984 }
987 #ifdef CONFIG_XEN_DEBUG_FS
988 #include <linux/debugfs.h>
991 {
994 #define TYPE_IDENTITY 0
995 #define TYPE_MISSING 1
996 #define TYPE_PFN 2
997 #define TYPE_UNKNOWN 3
1038 }
1042 }
1046 }
1052 }
1058 }
1059 }
1061 #undef TYPE_IDENTITY
1062 #undef TYPE_MISSING
1063 #undef TYPE_PFN
1064 #undef TYPE_UNKNOWN
1065 }
1068 {
1070 }
1077 };
1082 {
1092 }