| /*P:700 The pagetable code, on the other hand, still shows the scars of |
| * previous encounters. It's functional, and as neat as it can be in the |
| * circumstances, but be wary, for these things are subtle and break easily. |
| * The Guest provides a virtual to physical mapping, but we can neither trust |
| * it nor use it: we verify and convert it here then point the CPU to the |
| * converted Guest pages when running the Guest. :*/ |
| |
| /* Copyright (C) Rusty Russell IBM Corporation 2006. |
| * GPL v2 and any later version */ |
| #include <linux/mm.h> |
| #include <linux/types.h> |
| #include <linux/spinlock.h> |
| #include <linux/random.h> |
| #include <linux/percpu.h> |
| #include <asm/tlbflush.h> |
| #include <asm/uaccess.h> |
| #include <asm/bootparam.h> |
| #include "lg.h" |
| |
| /*M:008 We hold reference to pages, which prevents them from being swapped. |
| * It'd be nice to have a callback in the "struct mm_struct" when Linux wants |
| * to swap out. If we had this, and a shrinker callback to trim PTE pages, we |
| * could probably consider launching Guests as non-root. :*/ |
| |
| /*H:300 |
| * The Page Table Code |
| * |
| * We use two-level page tables for the Guest. If you're not entirely |
| * comfortable with virtual addresses, physical addresses and page tables then |
| * I recommend you review arch/x86/lguest/boot.c's "Page Table Handling" (with |
| * diagrams!). |
| * |
| * The Guest keeps page tables, but we maintain the actual ones here: these are |
| * called "shadow" page tables. Which is a very Guest-centric name: these are |
| * the real page tables the CPU uses, although we keep them up to date to |
| * reflect the Guest's. (See what I mean about weird naming? Since when do |
| * shadows reflect anything?) |
| * |
| * Anyway, this is the most complicated part of the Host code. There are seven |
| * parts to this: |
| * (i) Looking up a page table entry when the Guest faults, |
| * (ii) Making sure the Guest stack is mapped, |
| * (iii) Setting up a page table entry when the Guest tells us one has changed, |
| * (iv) Switching page tables, |
| * (v) Flushing (throwing away) page tables, |
| * (vi) Mapping the Switcher when the Guest is about to run, |
| * (vii) Setting up the page tables initially. |
| :*/ |
| |
| |
| /* 1024 entries in a page table page maps 1024 pages: 4MB. The Switcher is |
| * conveniently placed at the top 4MB, so it uses a separate, complete PTE |
| * page. */ |
| #define SWITCHER_PGD_INDEX (PTRS_PER_PGD - 1) |
| |
| /* We actually need a separate PTE page for each CPU. Remember that after the |
| * Switcher code itself comes two pages for each CPU, and we don't want this |
| * CPU's guest to see the pages of any other CPU. */ |
| static DEFINE_PER_CPU(pte_t *, switcher_pte_pages); |
| #define switcher_pte_page(cpu) per_cpu(switcher_pte_pages, cpu) |
| |
| /*H:320 The page table code is curly enough to need helper functions to keep it |
| * clear and clean. |
| * |
| * There are two functions which return pointers to the shadow (aka "real") |
| * page tables. |
| * |
| * spgd_addr() takes the virtual address and returns a pointer to the top-level |
| * page directory entry (PGD) for that address. Since we keep track of several |
| * page tables, the "i" argument tells us which one we're interested in (it's |
| * usually the current one). */ |
| static pgd_t *spgd_addr(struct lg_cpu *cpu, u32 i, unsigned long vaddr) |
| { |
| unsigned int index = pgd_index(vaddr); |
| |
| /* We kill any Guest trying to touch the Switcher addresses. */ |
| if (index >= SWITCHER_PGD_INDEX) { |
| kill_guest(cpu, "attempt to access switcher pages"); |
| index = 0; |
| } |
| /* Return a pointer index'th pgd entry for the i'th page table. */ |
| return &cpu->lg->pgdirs[i].pgdir[index]; |
| } |
| |
| /* This routine then takes the page directory entry returned above, which |
| * contains the address of the page table entry (PTE) page. It then returns a |
| * pointer to the PTE entry for the given address. */ |
| static pte_t *spte_addr(pgd_t spgd, unsigned long vaddr) |
| { |
| pte_t *page = __va(pgd_pfn(spgd) << PAGE_SHIFT); |
| /* You should never call this if the PGD entry wasn't valid */ |
| BUG_ON(!(pgd_flags(spgd) & _PAGE_PRESENT)); |
| return &page[(vaddr >> PAGE_SHIFT) % PTRS_PER_PTE]; |
| } |
| |
| /* These two functions just like the above two, except they access the Guest |
| * page tables. Hence they return a Guest address. */ |
| static unsigned long gpgd_addr(struct lg_cpu *cpu, unsigned long vaddr) |
| { |
| unsigned int index = vaddr >> (PGDIR_SHIFT); |
| return cpu->lg->pgdirs[cpu->cpu_pgd].gpgdir + index * sizeof(pgd_t); |
| } |
| |
| static unsigned long gpte_addr(pgd_t gpgd, unsigned long vaddr) |
| { |
| unsigned long gpage = pgd_pfn(gpgd) << PAGE_SHIFT; |
| BUG_ON(!(pgd_flags(gpgd) & _PAGE_PRESENT)); |
| return gpage + ((vaddr>>PAGE_SHIFT) % PTRS_PER_PTE) * sizeof(pte_t); |
| } |
| /*:*/ |
| |
| /*M:014 get_pfn is slow: we could probably try to grab batches of pages here as |
| * an optimization (ie. pre-faulting). :*/ |
| |
| /*H:350 This routine takes a page number given by the Guest and converts it to |
| * an actual, physical page number. It can fail for several reasons: the |
| * virtual address might not be mapped by the Launcher, the write flag is set |
| * and the page is read-only, or the write flag was set and the page was |
| * shared so had to be copied, but we ran out of memory. |
| * |
| * This holds a reference to the page, so release_pte() is careful to put that |
| * back. */ |
| static unsigned long get_pfn(unsigned long virtpfn, int write) |
| { |
| struct page *page; |
| |
| /* gup me one page at this address please! */ |
| if (get_user_pages_fast(virtpfn << PAGE_SHIFT, 1, write, &page) == 1) |
| return page_to_pfn(page); |
| |
| /* This value indicates failure. */ |
| return -1UL; |
| } |
| |
| /*H:340 Converting a Guest page table entry to a shadow (ie. real) page table |
| * entry can be a little tricky. The flags are (almost) the same, but the |
| * Guest PTE contains a virtual page number: the CPU needs the real page |
| * number. */ |
| static pte_t gpte_to_spte(struct lg_cpu *cpu, pte_t gpte, int write) |
| { |
| unsigned long pfn, base, flags; |
| |
| /* The Guest sets the global flag, because it thinks that it is using |
| * PGE. We only told it to use PGE so it would tell us whether it was |
| * flushing a kernel mapping or a userspace mapping. We don't actually |
| * use the global bit, so throw it away. */ |
| flags = (pte_flags(gpte) & ~_PAGE_GLOBAL); |
| |
| /* The Guest's pages are offset inside the Launcher. */ |
| base = (unsigned long)cpu->lg->mem_base / PAGE_SIZE; |
| |
| /* We need a temporary "unsigned long" variable to hold the answer from |
| * get_pfn(), because it returns 0xFFFFFFFF on failure, which wouldn't |
| * fit in spte.pfn. get_pfn() finds the real physical number of the |
| * page, given the virtual number. */ |
| pfn = get_pfn(base + pte_pfn(gpte), write); |
| if (pfn == -1UL) { |
| kill_guest(cpu, "failed to get page %lu", pte_pfn(gpte)); |
| /* When we destroy the Guest, we'll go through the shadow page |
| * tables and release_pte() them. Make sure we don't think |
| * this one is valid! */ |
| flags = 0; |
| } |
| /* Now we assemble our shadow PTE from the page number and flags. */ |
| return pfn_pte(pfn, __pgprot(flags)); |
| } |
| |
| /*H:460 And to complete the chain, release_pte() looks like this: */ |
| static void release_pte(pte_t pte) |
| { |
| /* Remember that get_user_pages_fast() took a reference to the page, in |
| * get_pfn()? We have to put it back now. */ |
| if (pte_flags(pte) & _PAGE_PRESENT) |
| put_page(pfn_to_page(pte_pfn(pte))); |
| } |
| /*:*/ |
| |
| static void check_gpte(struct lg_cpu *cpu, pte_t gpte) |
| { |
| if ((pte_flags(gpte) & _PAGE_PSE) || |
| pte_pfn(gpte) >= cpu->lg->pfn_limit) |
| kill_guest(cpu, "bad page table entry"); |
| } |
| |
| static void check_gpgd(struct lg_cpu *cpu, pgd_t gpgd) |
| { |
| if ((pgd_flags(gpgd) & ~_PAGE_TABLE) || |
| (pgd_pfn(gpgd) >= cpu->lg->pfn_limit)) |
| kill_guest(cpu, "bad page directory entry"); |
| } |
| |
| /*H:330 |
| * (i) Looking up a page table entry when the Guest faults. |
| * |
| * We saw this call in run_guest(): when we see a page fault in the Guest, we |
| * come here. That's because we only set up the shadow page tables lazily as |
| * they're needed, so we get page faults all the time and quietly fix them up |
| * and return to the Guest without it knowing. |
| * |
| * If we fixed up the fault (ie. we mapped the address), this routine returns |
| * true. Otherwise, it was a real fault and we need to tell the Guest. */ |
| int demand_page(struct lg_cpu *cpu, unsigned long vaddr, int errcode) |
| { |
| pgd_t gpgd; |
| pgd_t *spgd; |
| unsigned long gpte_ptr; |
| pte_t gpte; |
| pte_t *spte; |
| |
| /* First step: get the top-level Guest page table entry. */ |
| gpgd = lgread(cpu, gpgd_addr(cpu, vaddr), pgd_t); |
| /* Toplevel not present? We can't map it in. */ |
| if (!(pgd_flags(gpgd) & _PAGE_PRESENT)) |
| return 0; |
| |
| /* Now look at the matching shadow entry. */ |
| spgd = spgd_addr(cpu, cpu->cpu_pgd, vaddr); |
| if (!(pgd_flags(*spgd) & _PAGE_PRESENT)) { |
| /* No shadow entry: allocate a new shadow PTE page. */ |
| unsigned long ptepage = get_zeroed_page(GFP_KERNEL); |
| /* This is not really the Guest's fault, but killing it is |
| * simple for this corner case. */ |
| if (!ptepage) { |
| kill_guest(cpu, "out of memory allocating pte page"); |
| return 0; |
| } |
| /* We check that the Guest pgd is OK. */ |
| check_gpgd(cpu, gpgd); |
| /* And we copy the flags to the shadow PGD entry. The page |
| * number in the shadow PGD is the page we just allocated. */ |
| *spgd = __pgd(__pa(ptepage) | pgd_flags(gpgd)); |
| } |
| |
| /* OK, now we look at the lower level in the Guest page table: keep its |
| * address, because we might update it later. */ |
| gpte_ptr = gpte_addr(gpgd, vaddr); |
| gpte = lgread(cpu, gpte_ptr, pte_t); |
| |
| /* If this page isn't in the Guest page tables, we can't page it in. */ |
| if (!(pte_flags(gpte) & _PAGE_PRESENT)) |
| return 0; |
| |
| /* Check they're not trying to write to a page the Guest wants |
| * read-only (bit 2 of errcode == write). */ |
| if ((errcode & 2) && !(pte_flags(gpte) & _PAGE_RW)) |
| return 0; |
| |
| /* User access to a kernel-only page? (bit 3 == user access) */ |
| if ((errcode & 4) && !(pte_flags(gpte) & _PAGE_USER)) |
| return 0; |
| |
| /* Check that the Guest PTE flags are OK, and the page number is below |
| * the pfn_limit (ie. not mapping the Launcher binary). */ |
| check_gpte(cpu, gpte); |
| |
| /* Add the _PAGE_ACCESSED and (for a write) _PAGE_DIRTY flag */ |
| gpte = pte_mkyoung(gpte); |
| if (errcode & 2) |
| gpte = pte_mkdirty(gpte); |
| |
| /* Get the pointer to the shadow PTE entry we're going to set. */ |
| spte = spte_addr(*spgd, vaddr); |
| /* If there was a valid shadow PTE entry here before, we release it. |
| * This can happen with a write to a previously read-only entry. */ |
| release_pte(*spte); |
| |
| /* If this is a write, we insist that the Guest page is writable (the |
| * final arg to gpte_to_spte()). */ |
| if (pte_dirty(gpte)) |
| *spte = gpte_to_spte(cpu, gpte, 1); |
| else |
| /* If this is a read, don't set the "writable" bit in the page |
| * table entry, even if the Guest says it's writable. That way |
| * we will come back here when a write does actually occur, so |
| * we can update the Guest's _PAGE_DIRTY flag. */ |
| *spte = gpte_to_spte(cpu, pte_wrprotect(gpte), 0); |
| |
| /* Finally, we write the Guest PTE entry back: we've set the |
| * _PAGE_ACCESSED and maybe the _PAGE_DIRTY flags. */ |
| lgwrite(cpu, gpte_ptr, pte_t, gpte); |
| |
| /* The fault is fixed, the page table is populated, the mapping |
| * manipulated, the result returned and the code complete. A small |
| * delay and a trace of alliteration are the only indications the Guest |
| * has that a page fault occurred at all. */ |
| return 1; |
| } |
| |
| /*H:360 |
| * (ii) Making sure the Guest stack is mapped. |
| * |
| * Remember that direct traps into the Guest need a mapped Guest kernel stack. |
| * pin_stack_pages() calls us here: we could simply call demand_page(), but as |
| * we've seen that logic is quite long, and usually the stack pages are already |
| * mapped, so it's overkill. |
| * |
| * This is a quick version which answers the question: is this virtual address |
| * mapped by the shadow page tables, and is it writable? */ |
| static int page_writable(struct lg_cpu *cpu, unsigned long vaddr) |
| { |
| pgd_t *spgd; |
| unsigned long flags; |
| |
| /* Look at the current top level entry: is it present? */ |
| spgd = spgd_addr(cpu, cpu->cpu_pgd, vaddr); |
| if (!(pgd_flags(*spgd) & _PAGE_PRESENT)) |
| return 0; |
| |
| /* Check the flags on the pte entry itself: it must be present and |
| * writable. */ |
| flags = pte_flags(*(spte_addr(*spgd, vaddr))); |
| |
| return (flags & (_PAGE_PRESENT|_PAGE_RW)) == (_PAGE_PRESENT|_PAGE_RW); |
| } |
| |
| /* So, when pin_stack_pages() asks us to pin a page, we check if it's already |
| * in the page tables, and if not, we call demand_page() with error code 2 |
| * (meaning "write"). */ |
| void pin_page(struct lg_cpu *cpu, unsigned long vaddr) |
| { |
| if (!page_writable(cpu, vaddr) && !demand_page(cpu, vaddr, 2)) |
| kill_guest(cpu, "bad stack page %#lx", vaddr); |
| } |
| |
| /*H:450 If we chase down the release_pgd() code, it looks like this: */ |
| static void release_pgd(struct lguest *lg, pgd_t *spgd) |
| { |
| /* If the entry's not present, there's nothing to release. */ |
| if (pgd_flags(*spgd) & _PAGE_PRESENT) { |
| unsigned int i; |
| /* Converting the pfn to find the actual PTE page is easy: turn |
| * the page number into a physical address, then convert to a |
| * virtual address (easy for kernel pages like this one). */ |
| pte_t *ptepage = __va(pgd_pfn(*spgd) << PAGE_SHIFT); |
| /* For each entry in the page, we might need to release it. */ |
| for (i = 0; i < PTRS_PER_PTE; i++) |
| release_pte(ptepage[i]); |
| /* Now we can free the page of PTEs */ |
| free_page((long)ptepage); |
| /* And zero out the PGD entry so we never release it twice. */ |
| *spgd = __pgd(0); |
| } |
| } |
| |
| /*H:445 We saw flush_user_mappings() twice: once from the flush_user_mappings() |
| * hypercall and once in new_pgdir() when we re-used a top-level pgdir page. |
| * It simply releases every PTE page from 0 up to the Guest's kernel address. */ |
| static void flush_user_mappings(struct lguest *lg, int idx) |
| { |
| unsigned int i; |
| /* Release every pgd entry up to the kernel's address. */ |
| for (i = 0; i < pgd_index(lg->kernel_address); i++) |
| release_pgd(lg, lg->pgdirs[idx].pgdir + i); |
| } |
| |
| /*H:440 (v) Flushing (throwing away) page tables, |
| * |
| * The Guest has a hypercall to throw away the page tables: it's used when a |
| * large number of mappings have been changed. */ |
| void guest_pagetable_flush_user(struct lg_cpu *cpu) |
| { |
| /* Drop the userspace part of the current page table. */ |
| flush_user_mappings(cpu->lg, cpu->cpu_pgd); |
| } |
| /*:*/ |
| |
| /* We walk down the guest page tables to get a guest-physical address */ |
| unsigned long guest_pa(struct lg_cpu *cpu, unsigned long vaddr) |
| { |
| pgd_t gpgd; |
| pte_t gpte; |
| |
| /* First step: get the top-level Guest page table entry. */ |
| gpgd = lgread(cpu, gpgd_addr(cpu, vaddr), pgd_t); |
| /* Toplevel not present? We can't map it in. */ |
| if (!(pgd_flags(gpgd) & _PAGE_PRESENT)) { |
| kill_guest(cpu, "Bad address %#lx", vaddr); |
| return -1UL; |
| } |
| |
| gpte = lgread(cpu, gpte_addr(gpgd, vaddr), pte_t); |
| if (!(pte_flags(gpte) & _PAGE_PRESENT)) |
| kill_guest(cpu, "Bad address %#lx", vaddr); |
| |
| return pte_pfn(gpte) * PAGE_SIZE | (vaddr & ~PAGE_MASK); |
| } |
| |
| /* We keep several page tables. This is a simple routine to find the page |
| * table (if any) corresponding to this top-level address the Guest has given |
| * us. */ |
| static unsigned int find_pgdir(struct lguest *lg, unsigned long pgtable) |
| { |
| unsigned int i; |
| for (i = 0; i < ARRAY_SIZE(lg->pgdirs); i++) |
| if (lg->pgdirs[i].pgdir && lg->pgdirs[i].gpgdir == pgtable) |
| break; |
| return i; |
| } |
| |
| /*H:435 And this is us, creating the new page directory. If we really do |
| * allocate a new one (and so the kernel parts are not there), we set |
| * blank_pgdir. */ |
| static unsigned int new_pgdir(struct lg_cpu *cpu, |
| unsigned long gpgdir, |
| int *blank_pgdir) |
| { |
| unsigned int next; |
| |
| /* We pick one entry at random to throw out. Choosing the Least |
| * Recently Used might be better, but this is easy. */ |
| next = random32() % ARRAY_SIZE(cpu->lg->pgdirs); |
| /* If it's never been allocated at all before, try now. */ |
| if (!cpu->lg->pgdirs[next].pgdir) { |
| cpu->lg->pgdirs[next].pgdir = |
| (pgd_t *)get_zeroed_page(GFP_KERNEL); |
| /* If the allocation fails, just keep using the one we have */ |
| if (!cpu->lg->pgdirs[next].pgdir) |
| next = cpu->cpu_pgd; |
| else |
| /* This is a blank page, so there are no kernel |
| * mappings: caller must map the stack! */ |
| *blank_pgdir = 1; |
| } |
| /* Record which Guest toplevel this shadows. */ |
| cpu->lg->pgdirs[next].gpgdir = gpgdir; |
| /* Release all the non-kernel mappings. */ |
| flush_user_mappings(cpu->lg, next); |
| |
| return next; |
| } |
| |
| /*H:430 (iv) Switching page tables |
| * |
| * Now we've seen all the page table setting and manipulation, let's see what |
| * what happens when the Guest changes page tables (ie. changes the top-level |
| * pgdir). This occurs on almost every context switch. */ |
| void guest_new_pagetable(struct lg_cpu *cpu, unsigned long pgtable) |
| { |
| int newpgdir, repin = 0; |
| |
| /* Look to see if we have this one already. */ |
| newpgdir = find_pgdir(cpu->lg, pgtable); |
| /* If not, we allocate or mug an existing one: if it's a fresh one, |
| * repin gets set to 1. */ |
| if (newpgdir == ARRAY_SIZE(cpu->lg->pgdirs)) |
| newpgdir = new_pgdir(cpu, pgtable, &repin); |
| /* Change the current pgd index to the new one. */ |
| cpu->cpu_pgd = newpgdir; |
| /* If it was completely blank, we map in the Guest kernel stack */ |
| if (repin) |
| pin_stack_pages(cpu); |
| } |
| |
| /*H:470 Finally, a routine which throws away everything: all PGD entries in all |
| * the shadow page tables, including the Guest's kernel mappings. This is used |
| * when we destroy the Guest. */ |
| static void release_all_pagetables(struct lguest *lg) |
| { |
| unsigned int i, j; |
| |
| /* Every shadow pagetable this Guest has */ |
| for (i = 0; i < ARRAY_SIZE(lg->pgdirs); i++) |
| if (lg->pgdirs[i].pgdir) |
| /* Every PGD entry except the Switcher at the top */ |
| for (j = 0; j < SWITCHER_PGD_INDEX; j++) |
| release_pgd(lg, lg->pgdirs[i].pgdir + j); |
| } |
| |
| /* We also throw away everything when a Guest tells us it's changed a kernel |
| * mapping. Since kernel mappings are in every page table, it's easiest to |
| * throw them all away. This traps the Guest in amber for a while as |
| * everything faults back in, but it's rare. */ |
| void guest_pagetable_clear_all(struct lg_cpu *cpu) |
| { |
| release_all_pagetables(cpu->lg); |
| /* We need the Guest kernel stack mapped again. */ |
| pin_stack_pages(cpu); |
| } |
| /*:*/ |
| /*M:009 Since we throw away all mappings when a kernel mapping changes, our |
| * performance sucks for guests using highmem. In fact, a guest with |
| * PAGE_OFFSET 0xc0000000 (the default) and more than about 700MB of RAM is |
| * usually slower than a Guest with less memory. |
| * |
| * This, of course, cannot be fixed. It would take some kind of... well, I |
| * don't know, but the term "puissant code-fu" comes to mind. :*/ |
| |
| /*H:420 This is the routine which actually sets the page table entry for then |
| * "idx"'th shadow page table. |
| * |
| * Normally, we can just throw out the old entry and replace it with 0: if they |
| * use it demand_page() will put the new entry in. We need to do this anyway: |
| * The Guest expects _PAGE_ACCESSED to be set on its PTE the first time a page |
| * is read from, and _PAGE_DIRTY when it's written to. |
| * |
| * But Avi Kivity pointed out that most Operating Systems (Linux included) set |
| * these bits on PTEs immediately anyway. This is done to save the CPU from |
| * having to update them, but it helps us the same way: if they set |
| * _PAGE_ACCESSED then we can put a read-only PTE entry in immediately, and if |
| * they set _PAGE_DIRTY then we can put a writable PTE entry in immediately. |
| */ |
| static void do_set_pte(struct lg_cpu *cpu, int idx, |
| unsigned long vaddr, pte_t gpte) |
| { |
| /* Look up the matching shadow page directory entry. */ |
| pgd_t *spgd = spgd_addr(cpu, idx, vaddr); |
| |
| /* If the top level isn't present, there's no entry to update. */ |
| if (pgd_flags(*spgd) & _PAGE_PRESENT) { |
| /* Otherwise, we start by releasing the existing entry. */ |
| pte_t *spte = spte_addr(*spgd, vaddr); |
| release_pte(*spte); |
| |
| /* If they're setting this entry as dirty or accessed, we might |
| * as well put that entry they've given us in now. This shaves |
| * 10% off a copy-on-write micro-benchmark. */ |
| if (pte_flags(gpte) & (_PAGE_DIRTY | _PAGE_ACCESSED)) { |
| check_gpte(cpu, gpte); |
| *spte = gpte_to_spte(cpu, gpte, |
| pte_flags(gpte) & _PAGE_DIRTY); |
| } else |
| /* Otherwise kill it and we can demand_page() it in |
| * later. */ |
| *spte = __pte(0); |
| } |
| } |
| |
| /*H:410 Updating a PTE entry is a little trickier. |
| * |
| * We keep track of several different page tables (the Guest uses one for each |
| * process, so it makes sense to cache at least a few). Each of these have |
| * identical kernel parts: ie. every mapping above PAGE_OFFSET is the same for |
| * all processes. So when the page table above that address changes, we update |
| * all the page tables, not just the current one. This is rare. |
| * |
| * The benefit is that when we have to track a new page table, we can keep all |
| * the kernel mappings. This speeds up context switch immensely. */ |
| void guest_set_pte(struct lg_cpu *cpu, |
| unsigned long gpgdir, unsigned long vaddr, pte_t gpte) |
| { |
| /* Kernel mappings must be changed on all top levels. Slow, but doesn't |
| * happen often. */ |
| if (vaddr >= cpu->lg->kernel_address) { |
| unsigned int i; |
| for (i = 0; i < ARRAY_SIZE(cpu->lg->pgdirs); i++) |
| if (cpu->lg->pgdirs[i].pgdir) |
| do_set_pte(cpu, i, vaddr, gpte); |
| } else { |
| /* Is this page table one we have a shadow for? */ |
| int pgdir = find_pgdir(cpu->lg, gpgdir); |
| if (pgdir != ARRAY_SIZE(cpu->lg->pgdirs)) |
| /* If so, do the update. */ |
| do_set_pte(cpu, pgdir, vaddr, gpte); |
| } |
| } |
| |
| /*H:400 |
| * (iii) Setting up a page table entry when the Guest tells us one has changed. |
| * |
| * Just like we did in interrupts_and_traps.c, it makes sense for us to deal |
| * with the other side of page tables while we're here: what happens when the |
| * Guest asks for a page table to be updated? |
| * |
| * We already saw that demand_page() will fill in the shadow page tables when |
| * needed, so we can simply remove shadow page table entries whenever the Guest |
| * tells us they've changed. When the Guest tries to use the new entry it will |
| * fault and demand_page() will fix it up. |
| * |
| * So with that in mind here's our code to to update a (top-level) PGD entry: |
| */ |
| void guest_set_pmd(struct lguest *lg, unsigned long gpgdir, u32 idx) |
| { |
| int pgdir; |
| |
| /* The kernel seems to try to initialize this early on: we ignore its |
| * attempts to map over the Switcher. */ |
| if (idx >= SWITCHER_PGD_INDEX) |
| return; |
| |
| /* If they're talking about a page table we have a shadow for... */ |
| pgdir = find_pgdir(lg, gpgdir); |
| if (pgdir < ARRAY_SIZE(lg->pgdirs)) |
| /* ... throw it away. */ |
| release_pgd(lg, lg->pgdirs[pgdir].pgdir + idx); |
| } |
| |
| /* Once we know how much memory we have we can construct simple identity |
| * (which set virtual == physical) and linear mappings |
| * which will get the Guest far enough into the boot to create its own. |
| * |
| * We lay them out of the way, just below the initrd (which is why we need to |
| * know its size here). */ |
| static unsigned long setup_pagetables(struct lguest *lg, |
| unsigned long mem, |
| unsigned long initrd_size) |
| { |
| pgd_t __user *pgdir; |
| pte_t __user *linear; |
| unsigned int mapped_pages, i, linear_pages, phys_linear; |
| unsigned long mem_base = (unsigned long)lg->mem_base; |
| |
| /* We have mapped_pages frames to map, so we need |
| * linear_pages page tables to map them. */ |
| mapped_pages = mem / PAGE_SIZE; |
| linear_pages = (mapped_pages + PTRS_PER_PTE - 1) / PTRS_PER_PTE; |
| |
| /* We put the toplevel page directory page at the top of memory. */ |
| pgdir = (pgd_t *)(mem + mem_base - initrd_size - PAGE_SIZE); |
| |
| /* Now we use the next linear_pages pages as pte pages */ |
| linear = (void *)pgdir - linear_pages * PAGE_SIZE; |
| |
| /* Linear mapping is easy: put every page's address into the |
| * mapping in order. */ |
| for (i = 0; i < mapped_pages; i++) { |
| pte_t pte; |
| pte = pfn_pte(i, __pgprot(_PAGE_PRESENT|_PAGE_RW|_PAGE_USER)); |
| if (copy_to_user(&linear[i], &pte, sizeof(pte)) != 0) |
| return -EFAULT; |
| } |
| |
| /* The top level points to the linear page table pages above. |
| * We setup the identity and linear mappings here. */ |
| phys_linear = (unsigned long)linear - mem_base; |
| for (i = 0; i < mapped_pages; i += PTRS_PER_PTE) { |
| pgd_t pgd; |
| pgd = __pgd((phys_linear + i * sizeof(pte_t)) | |
| (_PAGE_PRESENT | _PAGE_RW | _PAGE_USER)); |
| |
| if (copy_to_user(&pgdir[i / PTRS_PER_PTE], &pgd, sizeof(pgd)) |
| || copy_to_user(&pgdir[pgd_index(PAGE_OFFSET) |
| + i / PTRS_PER_PTE], |
| &pgd, sizeof(pgd))) |
| return -EFAULT; |
| } |
| |
| /* We return the top level (guest-physical) address: remember where |
| * this is. */ |
| return (unsigned long)pgdir - mem_base; |
| } |
| |
| /*H:500 (vii) Setting up the page tables initially. |
| * |
| * When a Guest is first created, the Launcher tells us where the toplevel of |
| * its first page table is. We set some things up here: */ |
| int init_guest_pagetable(struct lguest *lg) |
| { |
| u64 mem; |
| u32 initrd_size; |
| struct boot_params __user *boot = (struct boot_params *)lg->mem_base; |
| |
| /* Get the Guest memory size and the ramdisk size from the boot header |
| * located at lg->mem_base (Guest address 0). */ |
| if (copy_from_user(&mem, &boot->e820_map[0].size, sizeof(mem)) |
| || get_user(initrd_size, &boot->hdr.ramdisk_size)) |
| return -EFAULT; |
| |
| /* We start on the first shadow page table, and give it a blank PGD |
| * page. */ |
| lg->pgdirs[0].gpgdir = setup_pagetables(lg, mem, initrd_size); |
| if (IS_ERR_VALUE(lg->pgdirs[0].gpgdir)) |
| return lg->pgdirs[0].gpgdir; |
| lg->pgdirs[0].pgdir = (pgd_t *)get_zeroed_page(GFP_KERNEL); |
| if (!lg->pgdirs[0].pgdir) |
| return -ENOMEM; |
| lg->cpus[0].cpu_pgd = 0; |
| return 0; |
| } |
| |
| /* When the Guest calls LHCALL_LGUEST_INIT we do more setup. */ |
| void page_table_guest_data_init(struct lg_cpu *cpu) |
| { |
| /* We get the kernel address: above this is all kernel memory. */ |
| if (get_user(cpu->lg->kernel_address, |
| &cpu->lg->lguest_data->kernel_address) |
| /* We tell the Guest that it can't use the top 4MB of virtual |
| * addresses used by the Switcher. */ |
| || put_user(4U*1024*1024, &cpu->lg->lguest_data->reserve_mem) |
| || put_user(cpu->lg->pgdirs[0].gpgdir, &cpu->lg->lguest_data->pgdir)) |
| kill_guest(cpu, "bad guest page %p", cpu->lg->lguest_data); |
| |
| /* In flush_user_mappings() we loop from 0 to |
| * "pgd_index(lg->kernel_address)". This assumes it won't hit the |
| * Switcher mappings, so check that now. */ |
| if (pgd_index(cpu->lg->kernel_address) >= SWITCHER_PGD_INDEX) |
| kill_guest(cpu, "bad kernel address %#lx", |
| cpu->lg->kernel_address); |
| } |
| |
| /* When a Guest dies, our cleanup is fairly simple. */ |
| void free_guest_pagetable(struct lguest *lg) |
| { |
| unsigned int i; |
| |
| /* Throw away all page table pages. */ |
| release_all_pagetables(lg); |
| /* Now free the top levels: free_page() can handle 0 just fine. */ |
| for (i = 0; i < ARRAY_SIZE(lg->pgdirs); i++) |
| free_page((long)lg->pgdirs[i].pgdir); |
| } |
| |
| /*H:480 (vi) Mapping the Switcher when the Guest is about to run. |
| * |
| * The Switcher and the two pages for this CPU need to be visible in the |
| * Guest (and not the pages for other CPUs). We have the appropriate PTE pages |
| * for each CPU already set up, we just need to hook them in now we know which |
| * Guest is about to run on this CPU. */ |
| void map_switcher_in_guest(struct lg_cpu *cpu, struct lguest_pages *pages) |
| { |
| pte_t *switcher_pte_page = __get_cpu_var(switcher_pte_pages); |
| pgd_t switcher_pgd; |
| pte_t regs_pte; |
| unsigned long pfn; |
| |
| /* Make the last PGD entry for this Guest point to the Switcher's PTE |
| * page for this CPU (with appropriate flags). */ |
| switcher_pgd = __pgd(__pa(switcher_pte_page) | __PAGE_KERNEL); |
| |
| cpu->lg->pgdirs[cpu->cpu_pgd].pgdir[SWITCHER_PGD_INDEX] = switcher_pgd; |
| |
| /* We also change the Switcher PTE page. When we're running the Guest, |
| * we want the Guest's "regs" page to appear where the first Switcher |
| * page for this CPU is. This is an optimization: when the Switcher |
| * saves the Guest registers, it saves them into the first page of this |
| * CPU's "struct lguest_pages": if we make sure the Guest's register |
| * page is already mapped there, we don't have to copy them out |
| * again. */ |
| pfn = __pa(cpu->regs_page) >> PAGE_SHIFT; |
| regs_pte = pfn_pte(pfn, __pgprot(__PAGE_KERNEL)); |
| switcher_pte_page[(unsigned long)pages/PAGE_SIZE%PTRS_PER_PTE] = regs_pte; |
| } |
| /*:*/ |
| |
| static void free_switcher_pte_pages(void) |
| { |
| unsigned int i; |
| |
| for_each_possible_cpu(i) |
| free_page((long)switcher_pte_page(i)); |
| } |
| |
| /*H:520 Setting up the Switcher PTE page for given CPU is fairly easy, given |
| * the CPU number and the "struct page"s for the Switcher code itself. |
| * |
| * Currently the Switcher is less than a page long, so "pages" is always 1. */ |
| static __init void populate_switcher_pte_page(unsigned int cpu, |
| struct page *switcher_page[], |
| unsigned int pages) |
| { |
| unsigned int i; |
| pte_t *pte = switcher_pte_page(cpu); |
| |
| /* The first entries are easy: they map the Switcher code. */ |
| for (i = 0; i < pages; i++) { |
| pte[i] = mk_pte(switcher_page[i], |
| __pgprot(_PAGE_PRESENT|_PAGE_ACCESSED)); |
| } |
| |
| /* The only other thing we map is this CPU's pair of pages. */ |
| i = pages + cpu*2; |
| |
| /* First page (Guest registers) is writable from the Guest */ |
| pte[i] = pfn_pte(page_to_pfn(switcher_page[i]), |
| __pgprot(_PAGE_PRESENT|_PAGE_ACCESSED|_PAGE_RW)); |
| |
| /* The second page contains the "struct lguest_ro_state", and is |
| * read-only. */ |
| pte[i+1] = pfn_pte(page_to_pfn(switcher_page[i+1]), |
| __pgprot(_PAGE_PRESENT|_PAGE_ACCESSED)); |
| } |
| |
| /* We've made it through the page table code. Perhaps our tired brains are |
| * still processing the details, or perhaps we're simply glad it's over. |
| * |
| * If nothing else, note that all this complexity in juggling shadow page tables |
| * in sync with the Guest's page tables is for one reason: for most Guests this |
| * page table dance determines how bad performance will be. This is why Xen |
| * uses exotic direct Guest pagetable manipulation, and why both Intel and AMD |
| * have implemented shadow page table support directly into hardware. |
| * |
| * There is just one file remaining in the Host. */ |
| |
| /*H:510 At boot or module load time, init_pagetables() allocates and populates |
| * the Switcher PTE page for each CPU. */ |
| __init int init_pagetables(struct page **switcher_page, unsigned int pages) |
| { |
| unsigned int i; |
| |
| for_each_possible_cpu(i) { |
| switcher_pte_page(i) = (pte_t *)get_zeroed_page(GFP_KERNEL); |
| if (!switcher_pte_page(i)) { |
| free_switcher_pte_pages(); |
| return -ENOMEM; |
| } |
| populate_switcher_pte_page(i, switcher_page, pages); |
| } |
| return 0; |
| } |
| /*:*/ |
| |
| /* Cleaning up simply involves freeing the PTE page for each CPU. */ |
| void free_pagetables(void) |
| { |
| free_switcher_pte_pages(); |
| } |