| blob | 89f3b6edc65a0996fbc111d5c7c82084d1fa4bfc |
1 /*
2 * Xen mmu operations
3 *
4 * This file contains the various mmu fetch and update operations.
5 * The most important job they must perform is the mapping between the
6 * domain's pfn and the overall machine mfns.
7 *
8 * Xen allows guests to directly update the pagetable, in a controlled
9 * fashion. In other words, the guest modifies the same pagetable
10 * that the CPU actually uses, which eliminates the overhead of having
11 * a separate shadow pagetable.
12 *
13 * In order to allow this, it falls on the guest domain to map its
14 * notion of a "physical" pfn - which is just a domain-local linear
15 * address - into a real "machine address" which the CPU's MMU can
16 * use.
17 *
18 * A pgd_t/pmd_t/pte_t will typically contain an mfn, and so can be
19 * inserted directly into the pagetable. When creating a new
20 * pte/pmd/pgd, it converts the passed pfn into an mfn. Conversely,
21 * when reading the content back with __(pgd|pmd|pte)_val, it converts
22 * the mfn back into a pfn.
23 *
24 * The other constraint is that all pages which make up a pagetable
25 * must be mapped read-only in the guest. This prevents uncontrolled
26 * guest updates to the pagetable. Xen strictly enforces this, and
27 * will disallow any pagetable update which will end up mapping a
28 * pagetable page RW, and will disallow using any writable page as a
29 * pagetable.
30 *
31 * Naively, when loading %cr3 with the base of a new pagetable, Xen
32 * would need to validate the whole pagetable before going on.
33 * Naturally, this is quite slow. The solution is to "pin" a
34 * pagetable, which enforces all the constraints on the pagetable even
35 * when it is not actively in use. This menas that Xen can be assured
36 * that it is still valid when you do load it into %cr3, and doesn't
37 * need to revalidate it.
38 *
39 * Jeremy Fitzhardinge <jeremy@xensource.com>, XenSource Inc, 2007
40 */
41 #include <linux/sched.h>
42 #include <linux/highmem.h>
43 #include <linux/debugfs.h>
44 #include <linux/bug.h>
46 #include <asm/pgtable.h>
47 #include <asm/tlbflush.h>
48 #include <asm/fixmap.h>
49 #include <asm/mmu_context.h>
50 #include <asm/paravirt.h>
51 #include <asm/linkage.h>
53 #include <asm/xen/hypercall.h>
54 #include <asm/xen/hypervisor.h>
56 #include <xen/page.h>
57 #include <xen/interface/xen.h>
63 #define MMU_UPDATE_HISTO 30
65 #ifdef CONFIG_XEN_DEBUG_FS
68 u32 pgd_update;
69 u32 pgd_update_pinned;
70 u32 pgd_update_batched;
72 u32 pud_update;
73 u32 pud_update_pinned;
74 u32 pud_update_batched;
76 u32 pmd_update;
77 u32 pmd_update_pinned;
78 u32 pmd_update_batched;
80 u32 pte_update;
81 u32 pte_update_pinned;
82 u32 pte_update_batched;
84 u32 mmu_update;
85 u32 mmu_update_extended;
88 u32 prot_commit;
89 u32 prot_commit_batched;
91 u32 set_pte_at;
92 u32 set_pte_at_batched;
93 u32 set_pte_at_pinned;
94 u32 set_pte_at_current;
95 u32 set_pte_at_kernel;
101 {
105 }
106 }
108 #define ADD_STATS(elem, val) \
109 do { check_zero(); mmu_stats.elem += (val); } while(0)
113 #define ADD_STATS(elem, val) do { (void)(val); } while(0)
117 /*
118 * Just beyond the highest usermode address. STACK_TOP_MAX has a
119 * redzone above it, so round it up to a PGD boundary.
120 */
121 #define USER_LIMIT ((STACK_TOP_MAX + PGDIR_SIZE - 1) & PGDIR_MASK)
124 #define P2M_ENTRIES_PER_PAGE (PAGE_SIZE / sizeof(unsigned long))
125 #define TOP_ENTRIES (MAX_DOMAIN_PAGES / P2M_ENTRIES_PER_PAGE)
127 /* Placeholder for holes in the address space */
131 /* Array of pointers to pages containing p2m entries */
135 /* Arrays of p2m arrays expressed in mfns used for save/restore */
139 __page_aligned_bss;
142 {
145 }
148 {
150 }
152 /* Build the parallel p2m_top_mfn structures */
154 {
161 }
166 }
173 }
175 /* Set up p2m_top to point to the domain-builder provided p2m pages */
177 {
186 }
187 }
190 {
199 }
203 {
215 else
217 }
220 {
226 }
231 }
235 /* no need to allocate a page to store an invalid entry */
239 }
243 }
246 {
252 /*
253 * if the PFN is in the linear mapped vaddr range, we can just use
254 * the (quick) virt_to_machine() p2m lookup
255 */
259 /* otherwise we have to do a (slower) full page-table walk */
265 }
268 {
280 }
283 {
295 }
299 {
303 }
306 {
320 else
327 }
331 }
334 {
341 /* ptr may be ioremapped for 64-bit pagetable setup */
351 }
354 {
357 /* If page is not pinned, we can just update the entry
358 directly */
362 }
367 }
369 /*
370 * Associate a virtual page frame with a given physical page frame
371 * and protection flags for that frame.
372 */
374 {
376 }
380 {
381 /* updates to init_mm may be done without lock */
386 // ADD_STATS(set_pte_at_pinned, xen_page_pinned(ptep));
402 }
405 out:
408 }
411 {
412 /* Just return the pte as-is. We preserve the bits on commit */
414 }
418 {
431 }
433 /* Assume pteval_t is equivalent to all the other *val_t types. */
435 {
440 }
443 }
446 {
451 }
454 }
457 {
459 }
462 {
464 }
467 {
470 }
473 {
476 }
479 {
481 }
484 {
491 /* ptr may be ioremapped for 64-bit pagetable setup */
501 }
504 {
507 /* If page is not pinned, we can just update the entry
508 directly */
512 }
517 }
520 {
522 // ADD_STATS(pte_update_pinned, xen_page_pinned(ptep));
525 #ifdef CONFIG_X86_PAE
529 #else
531 #endif
532 }
534 #ifdef CONFIG_X86_PAE
536 {
538 }
541 {
545 }
548 {
550 }
554 {
557 }
559 #if PAGETABLE_LEVELS == 4
561 {
563 }
566 {
570 }
573 {
583 }
586 }
589 {
595 }
597 /*
598 * Raw hypercall-based set_pgd, intended for in early boot before
599 * there's a page structure. This implies:
600 * 1. The only existing pagetable is the kernel's
601 * 2. It is always pinned
602 * 3. It has no user pagetable attached to it
603 */
605 {
615 }
618 {
623 /* If page is not pinned, we can just update the entry
624 directly */
630 }
632 }
637 /* If it's pinned, then we can at least batch the kernel and
638 user updates together. */
646 }
649 /*
650 * (Yet another) pagetable walker. This one is intended for pinning a
651 * pagetable. This means that it walks a pagetable and calls the
652 * callback function on each page it finds making up the page table,
653 * at every level. It walks the entire pagetable, but it only bothers
654 * pinning pte pages which are below limit. In the normal case this
655 * will be STACK_TOP_MAX, but at boot we need to pin up to
656 * FIXADDR_TOP.
657 *
658 * For 32-bit the important bit is that we don't pin beyond there,
659 * because then we start getting into Xen's ptes.
660 *
661 * For 64-bit, we must skip the Xen hole in the middle of the address
662 * space, just after the big x86-64 virtual hole.
663 */
668 {
675 /* The limit is the last byte to be touched */
676 limit--;
682 /*
683 * 64-bit has a great big hole in the middle of the address
684 * space, which contains the Xen mappings. On 32-bit these
685 * will end up making a zero-sized hole and so is a no-op.
686 */
691 #if PTRS_PER_PUD > 1
693 #else
695 #endif
696 #if PTRS_PER_PMD > 1
698 #else
700 #endif
744 }
745 }
746 }
748 out:
749 /* Do the top level last, so that the callbacks can use it as
750 a cue to do final things like tlb flushes. */
754 }
756 /* If we're using split pte locks, then take the page's lock and
757 return a pointer to it. Otherwise return NULL. */
759 {
762 #if USE_SPLIT_PTLOCKS
765 #endif
768 }
771 {
774 }
777 {
786 }
790 {
797 /* kmaps need flushing if we found an unpinned
798 highpage */
808 /*
809 * We need to hold the pagetable lock between the time
810 * we make the pagetable RO and when we actually pin
811 * it. If we don't, then other users may come in and
812 * attempt to update the pagetable by writing it,
813 * which will fail because the memory is RO but not
814 * pinned, so Xen won't do the trap'n'emulate.
815 *
816 * If we're using split pte locks, we can't hold the
817 * entire pagetable's worth of locks during the
818 * traverse, because we may wrap the preempt count (8
819 * bits). The solution is to mark RO and pin each PTE
820 * page while holding the lock. This means the number
821 * of locks we end up holding is never more than a
822 * batch size (~32 entries, at present).
823 *
824 * If we're not using split pte locks, we needn't pin
825 * the PTE pages independently, because we're
826 * protected by the overall pagetable lock.
827 */
839 /* Queue a deferred unlock for when this batch
840 is completed. */
842 }
843 }
846 }
848 /* This is called just after a mm has been created, but it has not
849 been used yet. We need to make sure that its pagetable is all
850 read-only, and can be pinned. */
852 {
858 /* re-enable interrupts for flushing */
864 }
866 #ifdef CONFIG_X86_64
867 {
875 }
876 }
878 #ifdef CONFIG_X86_PAE
879 /* Need to make sure unshared kernel PMD is pinnable */
881 PT_PMD);
882 #endif
886 }
889 {
891 }
893 /*
894 * On save, we need to pin all pagetables to make sure they get their
895 * mfns turned into pfns. Search the list for any unpinned pgds and pin
896 * them (unpinned pgds are not currently in use, probably because the
897 * process is under construction or destruction).
898 *
899 * Expected to be called in stop_machine() ("equivalent to taking
900 * every spinlock in the system"), so the locking doesn't really
901 * matter all that much.
902 */
904 {
914 }
915 }
918 }
920 /*
921 * The init_mm pagetable is really pinned as soon as its created, but
922 * that's before we have page structures to store the bits. So do all
923 * the book-keeping now.
924 */
927 {
930 }
933 {
935 }
939 {
948 /*
949 * Do the converse to pin_page. If we're using split
950 * pte locks, we must be holding the lock for while
951 * the pte page is unpinned but still RO to prevent
952 * concurrent updates from seeing it in this
953 * partially-pinned state.
954 */
960 }
969 /* unlock when batch completed */
971 }
972 }
975 }
977 /* Release a pagetables pages back as normal RW */
979 {
984 #ifdef CONFIG_X86_64
985 {
991 }
992 }
993 #endif
995 #ifdef CONFIG_X86_PAE
996 /* Need to make sure unshared kernel PMD is unpinned */
998 PT_PMD);
999 #endif
1004 }
1007 {
1009 }
1011 /*
1012 * On resume, undo any pinning done at save, so that the rest of the
1013 * kernel doesn't see any unexpected pinned pagetables.
1014 */
1016 {
1027 }
1028 }
1031 }
1034 {
1038 }
1041 {
1045 }
1048 #ifdef CONFIG_SMP
1049 /* Another cpu may still have their %cr3 pointing at the pagetable, so
1050 we need to repoint it somewhere else before we can unpin it. */
1052 {
1056 #ifdef CONFIG_X86_64
1058 #else
1060 #endif
1065 /* If this cpu still has a stale cr3 reference, then make sure
1066 it has been flushed. */
1070 }
1071 }
1074 {
1075 cpumask_t mask;
1081 else
1084 }
1086 /* Get the "official" set of cpus referring to our pagetable. */
1089 /* It's possible that a vcpu may have a stale reference to our
1090 cr3, because its in lazy mode, and it hasn't yet flushed
1091 its set of pending hypercalls yet. In this case, we can
1092 look at its actual current cr3 value, and force it to flush
1093 if needed. */
1097 }
1101 }
1102 #else
1104 {
1107 }
1108 #endif
1110 /*
1111 * While a process runs, Xen pins its pagetables, which means that the
1112 * hypervisor forces it to be read-only, and it controls all updates
1113 * to it. This means that all pagetable updates have to go via the
1114 * hypervisor, which is moderately expensive.
1115 *
1116 * Since we're pulling the pagetable down, we switch to use init_mm,
1117 * unpin old process pagetable and mark it all read-write, which
1118 * allows further operations on it to be simple memory accesses.
1119 *
1120 * The only subtle point is that another CPU may be still using the
1121 * pagetable because of lazy tlb flushing. This means we need need to
1122 * switch all CPUs off this pagetable before we can unpin it.
1123 */
1125 {
1132 /* pgd may not be pinned in the error exit path of execve */
1137 }
1139 #ifdef CONFIG_XEN_DEBUG_FS
1144 {
1173 // debugfs_create_u32("pte_update_pinned", 0444, d_mmu_debug,
1174 // &mmu_stats.pte_update_pinned);
1197 }