| blob | 07b13e26215ed3c8c23e462171da6db4c70d88e2 |
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/mm.h>
42 #include <linux/highmem.h>
43 #include <linux/debugfs.h>
44 #include <linux/bug.h>
45 #include <linux/vmalloc.h>
46 #include <linux/export.h>
47 #include <linux/init.h>
48 #include <linux/gfp.h>
49 #include <linux/memblock.h>
50 #include <linux/seq_file.h>
51 #include <linux/crash_dump.h>
53 #include <trace/events/xen.h>
55 #include <asm/pgtable.h>
56 #include <asm/tlbflush.h>
57 #include <asm/fixmap.h>
58 #include <asm/mmu_context.h>
59 #include <asm/setup.h>
60 #include <asm/paravirt.h>
61 #include <asm/e820.h>
62 #include <asm/linkage.h>
63 #include <asm/page.h>
64 #include <asm/init.h>
65 #include <asm/pat.h>
66 #include <asm/smp.h>
68 #include <asm/xen/hypercall.h>
69 #include <asm/xen/hypervisor.h>
71 #include <xen/xen.h>
72 #include <xen/page.h>
73 #include <xen/interface/xen.h>
74 #include <xen/interface/hvm/hvm_op.h>
75 #include <xen/interface/version.h>
76 #include <xen/interface/memory.h>
77 #include <xen/hvc-console.h>
83 /*
84 * Protects atomic reservation decrease/increase against concurrent increases.
85 * Also protects non-atomic updates of current_pages and balloon lists.
86 */
89 #ifdef CONFIG_X86_32
90 /*
91 * Identity map, in addition to plain kernel map. This needs to be
92 * large enough to allocate page table pages to allocate the rest.
93 * Each page can map 2MB.
94 */
95 #define LEVEL1_IDENT_ENTRIES (PTRS_PER_PTE * 4)
97 #endif
98 #ifdef CONFIG_X86_64
99 /* l3 pud for userspace vsyscall mapping */
103 /*
104 * Note about cr3 (pagetable base) values:
105 *
106 * xen_cr3 contains the current logical cr3 value; it contains the
107 * last set cr3. This may not be the current effective cr3, because
108 * its update may be being lazily deferred. However, a vcpu looking
109 * at its own cr3 can use this value knowing that it everything will
110 * be self-consistent.
111 *
112 * xen_current_cr3 contains the actual vcpu cr3; it is set once the
113 * hypercall to set the vcpu cr3 is complete (so it may be a little
114 * out of date, but it will never be set early). If one vcpu is
115 * looking at another vcpu's cr3 value, it should use this variable.
116 */
122 /*
123 * Just beyond the highest usermode address. STACK_TOP_MAX has a
124 * redzone above it, so round it up to a PGD boundary.
125 */
126 #define USER_LIMIT ((STACK_TOP_MAX + PGDIR_SIZE - 1) & PGDIR_MASK)
129 {
133 }
136 {
142 /*
143 * if the PFN is in the linear mapped vaddr range, we can just use
144 * the (quick) virt_to_machine() p2m lookup
145 */
149 /* otherwise we have to do a (slower) full page-table walk */
155 }
159 {
172 }
175 {
188 }
192 {
196 }
199 {
208 /* ptep might be kmapped when using 32-bit HIGHPTE */
215 }
219 {
230 }
234 }
237 {
248 }
252 }
255 {
262 /* ptr may be ioremapped for 64-bit pagetable setup */
270 }
273 {
276 /* If page is not pinned, we can just update the entry
277 directly */
281 }
284 }
286 /*
287 * Associate a virtual page frame with a given physical page frame
288 * and protection flags for that frame.
289 */
291 {
293 }
296 {
311 }
314 {
316 /*
317 * Could call native_set_pte() here and trap and
318 * emulate the PTE write but with 32-bit guests this
319 * needs two traps (one for each of the two 32-bit
320 * words in the PTE) so do one hypercall directly
321 * instead.
322 */
328 }
329 }
332 {
335 }
339 {
342 }
346 {
347 /* Just return the pte as-is. We preserve the bits on commit */
350 }
354 {
365 }
367 /* Assume pteval_t is equivalent to all the other *val_t types. */
369 {
377 else
379 }
382 }
385 {
393 else
395 /*
396 * If there's no mfn for the pfn, then just create an
397 * empty non-present pte. Unfortunately this loses
398 * information about the original pfn, so
399 * pte_mfn_to_pfn is asymmetric.
400 */
407 }
410 }
413 {
417 }
421 {
423 }
427 {
431 }
435 {
438 }
442 {
444 }
448 {
455 /* ptr may be ioremapped for 64-bit pagetable setup */
463 }
466 {
469 /* If page is not pinned, we can just update the entry
470 directly */
474 }
477 }
479 #ifdef CONFIG_X86_PAE
481 {
484 }
487 {
491 }
494 {
497 }
501 {
504 }
507 #if CONFIG_PGTABLE_LEVELS == 4
509 {
511 }
515 {
519 }
523 {
533 }
536 }
539 {
545 }
547 /*
548 * Raw hypercall-based set_pgd, intended for in early boot before
549 * there's a page structure. This implies:
550 * 1. The only existing pagetable is the kernel's
551 * 2. It is always pinned
552 * 3. It has no user pagetable attached to it
553 */
555 {
565 }
568 {
573 /* If page is not pinned, we can just update the entry
574 directly */
580 }
582 }
584 /* If it's pinned, then we can at least batch the kernel and
585 user updates together. */
593 }
596 /*
597 * (Yet another) pagetable walker. This one is intended for pinning a
598 * pagetable. This means that it walks a pagetable and calls the
599 * callback function on each page it finds making up the page table,
600 * at every level. It walks the entire pagetable, but it only bothers
601 * pinning pte pages which are below limit. In the normal case this
602 * will be STACK_TOP_MAX, but at boot we need to pin up to
603 * FIXADDR_TOP.
604 *
605 * For 32-bit the important bit is that we don't pin beyond there,
606 * because then we start getting into Xen's ptes.
607 *
608 * For 64-bit, we must skip the Xen hole in the middle of the address
609 * space, just after the big x86-64 virtual hole.
610 */
615 {
621 /* The limit is the last byte to be touched */
622 limit--;
628 /*
629 * 64-bit has a great big hole in the middle of the address
630 * space, which contains the Xen mappings. On 32-bit these
631 * will end up making a zero-sized hole and so is a no-op.
632 */
637 #if PTRS_PER_PUD > 1
639 #else
641 #endif
642 #if PTRS_PER_PMD > 1
644 #else
646 #endif
690 }
691 }
692 }
694 out:
695 /* Do the top level last, so that the callbacks can use it as
696 a cue to do final things like tlb flushes. */
700 }
706 {
708 }
710 /* If we're using split pte locks, then take the page's lock and
711 return a pointer to it. Otherwise return NULL. */
713 {
716 #if USE_SPLIT_PTE_PTLOCKS
719 #endif
722 }
725 {
728 }
731 {
738 }
742 {
749 /* kmaps need flushing if we found an unpinned
750 highpage */
760 /*
761 * We need to hold the pagetable lock between the time
762 * we make the pagetable RO and when we actually pin
763 * it. If we don't, then other users may come in and
764 * attempt to update the pagetable by writing it,
765 * which will fail because the memory is RO but not
766 * pinned, so Xen won't do the trap'n'emulate.
767 *
768 * If we're using split pte locks, we can't hold the
769 * entire pagetable's worth of locks during the
770 * traverse, because we may wrap the preempt count (8
771 * bits). The solution is to mark RO and pin each PTE
772 * page while holding the lock. This means the number
773 * of locks we end up holding is never more than a
774 * batch size (~32 entries, at present).
775 *
776 * If we're not using split pte locks, we needn't pin
777 * the PTE pages independently, because we're
778 * protected by the overall pagetable lock.
779 */
791 /* Queue a deferred unlock for when this batch
792 is completed. */
794 }
795 }
798 }
800 /* This is called just after a mm has been created, but it has not
801 been used yet. We need to make sure that its pagetable is all
802 read-only, and can be pinned. */
804 {
810 /* re-enable interrupts for flushing */
816 }
818 #ifdef CONFIG_X86_64
819 {
828 }
829 }
831 #ifdef CONFIG_X86_PAE
832 /* Need to make sure unshared kernel PMD is pinnable */
834 PT_PMD);
835 #endif
839 }
842 {
844 }
846 /*
847 * On save, we need to pin all pagetables to make sure they get their
848 * mfns turned into pfns. Search the list for any unpinned pgds and pin
849 * them (unpinned pgds are not currently in use, probably because the
850 * process is under construction or destruction).
851 *
852 * Expected to be called in stop_machine() ("equivalent to taking
853 * every spinlock in the system"), so the locking doesn't really
854 * matter all that much.
855 */
857 {
866 }
867 }
870 }
872 /*
873 * The init_mm pagetable is really pinned as soon as its created, but
874 * that's before we have page structures to store the bits. So do all
875 * the book-keeping now.
876 */
879 {
882 }
885 {
887 }
891 {
900 /*
901 * Do the converse to pin_page. If we're using split
902 * pte locks, we must be holding the lock for while
903 * the pte page is unpinned but still RO to prevent
904 * concurrent updates from seeing it in this
905 * partially-pinned state.
906 */
912 }
921 /* unlock when batch completed */
923 }
924 }
927 }
929 /* Release a pagetables pages back as normal RW */
931 {
938 #ifdef CONFIG_X86_64
939 {
946 }
947 }
948 #endif
950 #ifdef CONFIG_X86_PAE
951 /* Need to make sure unshared kernel PMD is unpinned */
953 PT_PMD);
954 #endif
959 }
962 {
964 }
966 /*
967 * On resume, undo any pinning done at save, so that the rest of the
968 * kernel doesn't see any unexpected pinned pagetables.
969 */
971 {
981 }
982 }
985 }
988 {
992 }
995 {
999 }
1002 #ifdef CONFIG_SMP
1003 /* Another cpu may still have their %cr3 pointing at the pagetable, so
1004 we need to repoint it somewhere else before we can unpin it. */
1006 {
1015 /* If this cpu still has a stale cr3 reference, then make sure
1016 it has been flushed. */
1019 }
1022 {
1023 cpumask_var_t mask;
1029 else
1031 }
1033 /* Get the "official" set of cpus referring to our pagetable. */
1040 }
1042 }
1045 /* It's possible that a vcpu may have a stale reference to our
1046 cr3, because its in lazy mode, and it hasn't yet flushed
1047 its set of pending hypercalls yet. In this case, we can
1048 look at its actual current cr3 value, and force it to flush
1049 if needed. */
1053 }
1058 }
1059 #else
1061 {
1064 }
1065 #endif
1067 /*
1068 * While a process runs, Xen pins its pagetables, which means that the
1069 * hypervisor forces it to be read-only, and it controls all updates
1070 * to it. This means that all pagetable updates have to go via the
1071 * hypervisor, which is moderately expensive.
1072 *
1073 * Since we're pulling the pagetable down, we switch to use init_mm,
1074 * unpin old process pagetable and mark it all read-write, which
1075 * allows further operations on it to be simple memory accesses.
1076 *
1077 * The only subtle point is that another CPU may be still using the
1078 * pagetable because of lazy tlb flushing. This means we need need to
1079 * switch all CPUs off this pagetable before we can unpin it.
1080 */
1082 {
1089 /* pgd may not be pinned in the error exit path of execve */
1094 }
1099 {
1106 }
1108 #ifdef CONFIG_X86_64
1111 {
1115 /* NOTE: The loop is more greedy than the cleanup_highmap variant.
1116 * We include the PMD passed in on _both_ boundaries. */
1123 }
1124 /* In case we did something silly, we should crash in this function
1125 * instead of somewhere later and be confusing. */
1127 }
1129 /*
1130 * Make a page range writeable and free it.
1131 */
1133 {
1141 }
1144 {
1151 }
1153 /*
1154 * Since it is well isolated we can (and since it is perhaps large we should)
1155 * also free the page tables mapping the initial P->M table.
1156 */
1158 {
1192 }
1194 }
1200 }
1204 }
1207 {
1213 /* No memory or already called. */
1217 /* using __ka address and sticking INVALID_P2M_ENTRY! */
1221 /*
1222 * We could be in __ka space.
1223 * We roundup to the PMD, which means that if anybody at this stage is
1224 * using the __ka address of xen_start_info or
1225 * xen_start_info->shared_info they are in going to crash. Fortunatly
1226 * we have already revectored in xen_setup_kernel_pagetable and in
1227 * xen_setup_shared_info.
1228 */
1238 }
1239 }
1242 {
1246 /* At this stage, cleanup_highmap has already cleaned __ka space
1247 * from _brk_limit way up to the max_pfn_mapped (which is the end of
1248 * the ramdisk). We continue on, erasing PMD entries that point to page
1249 * tables - do note that they are accessible at this stage via __va.
1250 * For good measure we also round up to the PMD - which means that if
1251 * anybody is using __ka address to the initial boot-stack - and try
1252 * to use it - they are going to crash. The xen_start_info has been
1253 * taken care of already in xen_setup_kernel_pagetable. */
1259 #ifdef DEBUG
1260 /* This is superfluous and is not necessary, but you know what
1261 * lets do it. The MODULES_VADDR -> MODULES_END should be clear of
1262 * anything at this stage. */
1264 #endif
1265 }
1266 #endif
1269 {
1275 #ifdef CONFIG_X86_64
1279 #endif
1280 /* And revector! Bye bye old array */
1282 }
1285 {
1291 /* Allocate and initialize top and mid mfn levels for p2m structure */
1294 /* Remap memory freed due to conflicts with E820 map */
1299 }
1301 {
1303 }
1306 {
1308 }
1311 {
1313 }
1316 {
1333 }
1335 {
1352 }
1355 {
1372 }
1377 {
1380 #ifdef CONFIG_SMP
1382 #else
1384 #endif
1397 /* Remove us, and any offline CPUS. */
1405 }
1410 }
1413 {
1415 }
1418 {
1420 }
1423 {
1431 else
1444 /* Update xen_current_cr3 once the batch has actually
1445 been submitted. */
1447 }
1448 }
1450 {
1455 /* Update while interrupts are disabled, so its atomic with
1456 respect to ipis */
1461 #ifdef CONFIG_X86_64
1462 {
1466 else
1468 }
1469 #endif
1472 }
1474 #ifdef CONFIG_X86_64
1475 /*
1476 * At the start of the day - when Xen launches a guest, it has already
1477 * built pagetables for the guest. We diligently look over them
1478 * in xen_setup_kernel_pagetable and graft as appropriate them in the
1479 * init_level4_pgt and its friends. Then when we are happy we load
1480 * the new init_level4_pgt - and continue on.
1481 *
1482 * The generic code starts (start_kernel) and 'init_mem_mapping' sets
1483 * up the rest of the pagetables. When it has completed it loads the cr3.
1484 * N.B. that baremetal would start at 'start_kernel' (and the early
1485 * #PF handler would create bootstrap pagetables) - so we are running
1486 * with the same assumptions as what to do when write_cr3 is executed
1487 * at this point.
1488 *
1489 * Since there are no user-page tables at all, we have two variants
1490 * of xen_write_cr3 - the early bootup (this one), and the late one
1491 * (xen_write_cr3). The reason we have to do that is that in 64-bit
1492 * the Linux kernel and user-space are both in ring 3 while the
1493 * hypervisor is in ring 0.
1494 */
1496 {
1501 /* Update while interrupts are disabled, so its atomic with
1502 respect to ipis */
1508 }
1509 #endif
1512 {
1518 #ifdef CONFIG_X86_64
1519 {
1531 #ifdef CONFIG_X86_VSYSCALL_EMULATION
1534 #endif
1536 }
1539 }
1540 #endif
1543 }
1546 {
1547 #ifdef CONFIG_X86_64
1552 #endif
1553 }
1555 /*
1556 * Init-time set_pte while constructing initial pagetables, which
1557 * doesn't allow RO page table pages to be remapped RW.
1558 *
1559 * If there is no MFN for this PFN then this page is initially
1560 * ballooned out so clear the PTE (as in decrease_reservation() in
1561 * drivers/xen/balloon.c).
1562 *
1563 * Many of these PTE updates are done on unpinned and writable pages
1564 * and doing a hypercall for these is unnecessary and expensive. At
1565 * this point it is not possible to tell if a page is pinned or not,
1566 * so always write the PTE directly and rely on Xen trapping and
1567 * emulating any updates as necessary.
1568 */
1570 {
1571 #ifdef CONFIG_X86_64
1574 /*
1575 * Pages belonging to the initial p2m list mapped outside the default
1576 * address range must be mapped read-only. This region contains the
1577 * page tables for mapping the p2m list, too, and page tables MUST be
1578 * mapped read-only.
1579 */
1585 #endif
1588 }
1592 {
1593 #ifdef CONFIG_X86_32
1594 /* If there's an existing pte, then don't allow _PAGE_RW to be set */
1599 #endif
1601 }
1603 /* Early in boot, while setting up the initial pagetable, assume
1604 everything is pinned. */
1606 {
1607 #ifdef CONFIG_FLATMEM
1609 #endif
1612 }
1614 /* Used for pmd and pud */
1616 {
1617 #ifdef CONFIG_FLATMEM
1619 #endif
1621 }
1623 /* Early release_pte assumes that all pts are pinned, since there's
1624 only init_mm and anything attached to that is pinned. */
1626 {
1629 }
1632 {
1634 }
1637 {
1647 }
1650 {
1657 }
1659 /* This needs to make sure the new pte page is pinned iff its being
1660 attached to a pinned pagetable. */
1663 {
1683 /* make sure there are no stray mappings of
1684 this page */
1686 }
1687 }
1688 }
1691 {
1693 }
1696 {
1698 }
1700 /* This should never happen until we're OK to use struct page */
1702 {
1718 }
1720 }
1721 }
1724 {
1726 }
1729 {
1731 }
1733 #if CONFIG_PGTABLE_LEVELS == 4
1735 {
1737 }
1740 {
1742 }
1743 #endif
1746 {
1747 #ifdef CONFIG_X86_32
1756 }
1758 /*
1759 * Like __va(), but returns address in the kernel mapping (which is
1760 * all we have until the physical memory mapping has been set up.
1761 */
1763 {
1764 #ifdef CONFIG_X86_64
1766 #else
1768 #endif
1769 }
1771 /* Convert a machine address to physical address */
1773 {
1774 phys_addr_t paddr;
1780 }
1782 /* Convert a machine address to kernel virtual */
1784 {
1786 }
1788 /* Set the page permissions on an identity-mapped pages */
1791 {
1797 }
1799 {
1801 }
1802 #ifdef CONFIG_X86_32
1804 {
1810 PAGE_SIZE);
1817 /* Reuse or allocate a page of ptes */
1821 /* Check for free pte pages */
1829 }
1831 /* Install mappings */
1833 pte_t pte;
1843 }
1844 }
1850 }
1851 #endif
1853 {
1861 }
1862 #ifdef CONFIG_X86_32
1865 #endif
1866 }
1868 #ifdef CONFIG_X86_64
1870 {
1874 /* All levels are converted the same way, so just treat them
1875 as ptes. */
1878 }
1881 {
1886 }
1891 }
1892 }
1893 /*
1894 * Set up the initial kernel pagetable.
1895 *
1896 * We can construct this by grafting the Xen provided pagetable into
1897 * head_64.S's preconstructed pagetables. We copy the Xen L2's into
1898 * level2_ident_pgt, and level2_kernel_pgt. This means that only the
1899 * kernel has a physical mapping to start with - but that's enough to
1900 * get __va working. We need to fill in the rest of the physical
1901 * mapping once some sort of allocator has been set up.
1902 */
1904 {
1911 /* max_pfn_mapped is the last pfn mapped in the initial memory
1912 * mappings. Considering that on Xen after the kernel mappings we
1913 * have the mappings of some pages that don't exist in pfn space, we
1914 * set max_pfn_mapped to the last real pfn mapped. */
1917 else
1923 /* Zap identity mapping */
1927 /* Pre-constructed entries are in pfn, so convert to mfn */
1928 /* L4[272] -> level3_ident_pgt
1929 * L4[511] -> level3_kernel_pgt */
1932 /* L3_i[0] -> level2_ident_pgt */
1934 /* L3_k[510] -> level2_kernel_pgt
1935 * L3_k[511] -> level2_fixmap_pgt */
1938 /* L3_k[511][506] -> level1_fixmap_pgt */
1940 }
1941 /* We get [511][511] and have Xen's version of level2_kernel_pgt */
1948 /* Graft it onto L4[272][0]. Note that we creating an aliasing problem:
1949 * Both L4[272][0] and L4[511][510] have entries that point to the same
1950 * L2 (PMD) tables. Meaning that if you modify it in __va space
1951 * it will be also modified in the __ka space! (But if you just
1952 * modify the PMD table to point to other PTE's or none, then you
1953 * are OK - which is what cleanup_highmap does) */
1955 /* Graft it onto L4[511][510] */
1958 /* Copy the initial P->M table mappings if necessary. */
1964 /* Make pagetable pieces RO */
1974 /* Pin down new L4 */
1978 /* Unpin Xen-provided one */
1981 /*
1982 * At this stage there can be no user pgd, and no page
1983 * structure to attach it to, so make sure we just set kernel
1984 * pgd.
1985 */
1992 /* We can't that easily rip out L3 and L2, as the Xen pagetables are
1993 * set out this way: [L4], [L1], [L2], [L3], [L1], [L1] ... for
1994 * the initial domain. For guests using the toolstack, they are in:
1995 * [L4], [L3], [L2], [L1], [L1], order .. So for dom0 we can only
1996 * rip out the [L4] (pgd), but for guests we shave off three pages.
1997 */
2001 /* Our (by three pages) smaller Xen pagetable that we are using */
2006 /* Revector the xen_start_info */
2008 }
2010 /*
2011 * Read a value from a physical address.
2012 */
2014 {
2022 }
2024 /*
2025 * Translate a virtual address to a physical one without relying on mapped
2026 * page tables. Don't rely on big pages being aligned in (guest) physical
2027 * space!
2028 */
2030 {
2031 phys_addr_t pa;
2032 pgd_t pgd;
2033 pud_t pud;
2034 pmd_t pmd;
2035 pte_t pte;
2067 }
2069 /*
2070 * Find a new area for the hypervisor supplied p2m list and relocate the p2m to
2071 * this area.
2072 */
2074 {
2095 }
2097 /*
2098 * Setup the page tables for addressing the new p2m list.
2099 * We have asked the hypervisor to map the p2m list at the user address
2100 * PUD_SIZE. It may have done so, or it may have used a kernel space
2101 * address depending on the Xen version.
2102 * To avoid any possible virtual address collision, just use
2103 * 2 * PUD_SIZE for the new area.
2104 */
2116 idx_pmd++) {
2120 idx_pt++) {
2125 idx_pte++) {
2128 p2m_pfn++;
2129 }
2138 }
2146 }
2153 }
2155 /* Now copy the old p2m info to the new area. */
2159 /* Release the old p2m list and set new list info. */
2172 }
2179 }
2181 pfn++;
2182 }
2187 }
2194 {
2200 /*
2201 * We are switching to swapper_pg_dir for the first time (from
2202 * initial_page_table) and therefore need to mark that page
2203 * read-only and then pin it.
2204 *
2205 * Xen disallows sharing of kernel PMDs for PAE
2206 * guests. Therefore we must copy the kernel PMD from
2207 * initial_page_table into a new kernel PMD to be used in
2208 * swapper_pg_dir.
2209 */
2210 swapper_kernel_pmd =
2227 }
2229 /*
2230 * For 32 bit domains xen_start_info->pt_base is the pgd address which might be
2231 * not the first page table in the page table pool.
2232 * Iterate through the initial page tables to find the real page table base.
2233 */
2235 {
2245 }
2248 }
2251 {
2259 initial_kernel_pmd =
2283 }
2287 {
2288 phys_addr_t paddr;
2294 }
2298 }
2299 }
2302 {
2306 }
2307 }
2312 {
2313 pte_t pte;
2320 #ifdef CONFIG_X86_32
2322 # ifdef CONFIG_HIGHMEM
2324 # endif
2325 #elif defined(CONFIG_X86_VSYSCALL_EMULATION)
2327 #endif
2330 /* All local page mappings */
2334 #ifdef CONFIG_X86_LOCAL_APIC
2338 #endif
2340 #ifdef CONFIG_X86_IO_APIC
2342 /*
2343 * We just don't map the IO APIC - all access is via
2344 * hypercalls. Keep the address in the pte for reference.
2345 */
2348 #endif
2351 /* This is an MFN, but it isn't an IO mapping from the
2352 IO domain */
2357 /* By default, set_fixmap is used for hardware mappings */
2360 }
2364 #ifdef CONFIG_X86_VSYSCALL_EMULATION
2365 /* Replicate changes to map the vsyscall page into the user
2366 pagetable vsyscall mapping. */
2370 }
2371 #endif
2372 }
2375 {
2382 #if CONFIG_PGTABLE_LEVELS == 4
2384 #endif
2386 /* This will work as long as patching hasn't happened yet
2387 (which it hasn't) */
2392 #if CONFIG_PGTABLE_LEVELS == 4
2395 #endif
2398 #ifdef CONFIG_X86_64
2401 #endif
2403 }
2406 {
2411 }
2448 #ifdef CONFIG_X86_PAE
2458 #if CONFIG_PGTABLE_LEVELS == 4
2475 },
2478 };
2481 {
2490 }
2492 /* Protected by xen_reservation_lock. */
2496 #define VOID_PTE (mfn_pte(0, __pgprot(0)))
2500 {
2516 }
2518 }
2520 /*
2521 * Update the pfn-to-mfn mappings for a virtual address range, either to
2522 * point to an array of mfns, or contiguously from a single starting
2523 * mfn.
2524 */
2528 {
2542 else
2550 else
2552 }
2558 }
2561 }
2563 /*
2564 * Perform the hypercall to exchange a region of our pfns to point to
2565 * memory with the required contiguous alignment. Takes the pfns as
2566 * input, and populates mfns as output.
2567 *
2568 * Returns a success code indicating whether the hypervisor was able to
2569 * satisfy the request or not.
2570 */
2577 {
2587 },
2594 }
2595 };
2606 }
2611 {
2617 /*
2618 * Currently an auto-translated guest will not perform I/O, nor will
2619 * it require PAE page directories below 4GB. Therefore any calls to
2620 * this function are redundant and can be ignored.
2621 */
2633 /* 1. Zap current PTEs, remembering MFNs. */
2636 /* 2. Get a new contiguous memory extent. */
2640 address_bits);
2642 /* 3. Map the new extent in place of old pages. */
2645 else
2652 }
2656 {
2673 /* 1. Find start MFN of contiguous extent. */
2676 /* 2. Zap current PTEs. */
2679 /* 3. Do the exchange for non-contiguous MFNs. */
2683 /* 4. Map new pages in place of old pages. */
2686 else
2690 }
2693 #ifdef CONFIG_XEN_PVHVM
2694 #ifdef CONFIG_PROC_VMCORE
2695 /*
2696 * This function is used in two contexts:
2697 * - the kdump kernel has to check whether a pfn of the crashed kernel
2698 * was a ballooned page. vmcore is using this function to decide
2699 * whether to access a pfn of the crashed kernel.
2700 * - the kexec kernel has to check whether a pfn was ballooned by the
2701 * previous kernel. If the pfn is ballooned, handle it properly.
2702 * Returns 0 if the pfn is not backed by a RAM page, the caller may
2703 * handle the pfn special in this case.
2704 */
2706 {
2710 };
2725 }
2728 }
2729 #endif
2732 {
2740 }
2743 {
2753 }
2755 }
2758 {
2761 #ifdef CONFIG_PROC_VMCORE
2763 #endif
2764 }
2765 #endif
2767 #define REMAP_BATCH_SIZE 16
2772 pgprot_t prot;
2774 };
2778 {
2782 /* If we have a contiguous range, just update the mfn itself,
2783 else update pointer to be "next mfn". */
2786 else
2794 }
2802 {
2813 /* We use the err_ptr to indicate if there we are doing a contiguous
2814 * mapping or a discontigious mapping. */
2830 /* We record the error for each page that gives an error, but
2831 * continue mapping until the whole set is done */
2838 /*
2839 * @err_ptr may be the same buffer as @gfn, so
2840 * only clear it after each chunk of @gfn is
2841 * used.
2842 */
2846 }
2863 }
2864 out:
2869 }
2876 {
2878 }
2886 {
2887 /* We BUG_ON because it's a programmer error to pass a NULL err_ptr,
2888 * and the consequences later is quite hard to detect what the actual
2889 * cause of "wrong memory was mapped in".
2890 */
2893 }
2897 /* Returns: 0 success */
2900 {
2905 }