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If a Guest makes hypercall which sets a GDT entry to not present, we currently set any segment registers using that GDT entry to 0. Unfortunately, this is not sufficient: there are other ways of altering GDT entries which will cause a fault. The correct solution to do what Linux does: let them set any GDT value they want and handle the #GP when popping causes a fault. This has the added benefit of making our Switcher slightly more robust in the case of any other bugs which cause it to fault. We kill the Guest if it causes a fault in the Switcher: it's the Guest's responsibility to make sure it's not using segments when it changes them. Signed-off-by: Rusty Russell <rusty@rustcorp.com.au> Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
351 lines
11 KiB
ArmAsm
351 lines
11 KiB
ArmAsm
/*P:900 This is the Switcher: code which sits at 0xFFC00000 to do the low-level
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* Guest<->Host switch. It is as simple as it can be made, but it's naturally
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* very specific to x86.
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*
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* You have now completed Preparation. If this has whet your appetite; if you
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* are feeling invigorated and refreshed then the next, more challenging stage
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* can be found in "make Guest". :*/
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/*S:100
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* Welcome to the Switcher itself!
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*
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* This file contains the low-level code which changes the CPU to run the Guest
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* code, and returns to the Host when something happens. Understand this, and
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* you understand the heart of our journey.
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*
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* Because this is in assembler rather than C, our tale switches from prose to
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* verse. First I tried limericks:
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*
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* There once was an eax reg,
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* To which our pointer was fed,
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* It needed an add,
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* Which asm-offsets.h had
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* But this limerick is hurting my head.
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*
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* Next I tried haikus, but fitting the required reference to the seasons in
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* every stanza was quickly becoming tiresome:
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*
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* The %eax reg
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* Holds "struct lguest_pages" now:
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* Cherry blossoms fall.
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*
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* Then I started with Heroic Verse, but the rhyming requirement leeched away
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* the content density and led to some uniquely awful oblique rhymes:
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*
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* These constants are coming from struct offsets
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* For use within the asm switcher text.
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*
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* Finally, I settled for something between heroic hexameter, and normal prose
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* with inappropriate linebreaks. Anyway, it aint no Shakespeare.
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*/
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// Not all kernel headers work from assembler
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// But these ones are needed: the ENTRY() define
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// And constants extracted from struct offsets
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// To avoid magic numbers and breakage:
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// Should they change the compiler can't save us
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// Down here in the depths of assembler code.
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#include <linux/linkage.h>
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#include <asm/asm-offsets.h>
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#include <asm/page.h>
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#include "lg.h"
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// We mark the start of the code to copy
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// It's placed in .text tho it's never run here
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// You'll see the trick macro at the end
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// Which interleaves data and text to effect.
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.text
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ENTRY(start_switcher_text)
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// When we reach switch_to_guest we have just left
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// The safe and comforting shores of C code
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// %eax has the "struct lguest_pages" to use
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// Where we save state and still see it from the Guest
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// And %ebx holds the Guest shadow pagetable:
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// Once set we have truly left Host behind.
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ENTRY(switch_to_guest)
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// We told gcc all its regs could fade,
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// Clobbered by our journey into the Guest
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// We could have saved them, if we tried
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// But time is our master and cycles count.
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// Segment registers must be saved for the Host
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// We push them on the Host stack for later
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pushl %es
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pushl %ds
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pushl %gs
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pushl %fs
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// But the compiler is fickle, and heeds
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// No warning of %ebp clobbers
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// When frame pointers are used. That register
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// Must be saved and restored or chaos strikes.
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pushl %ebp
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// The Host's stack is done, now save it away
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// In our "struct lguest_pages" at offset
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// Distilled into asm-offsets.h
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movl %esp, LGUEST_PAGES_host_sp(%eax)
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// All saved and there's now five steps before us:
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// Stack, GDT, IDT, TSS
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// And last of all the page tables are flipped.
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// Yet beware that our stack pointer must be
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// Always valid lest an NMI hits
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// %edx does the duty here as we juggle
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// %eax is lguest_pages: our stack lies within.
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movl %eax, %edx
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addl $LGUEST_PAGES_regs, %edx
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movl %edx, %esp
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// The Guest's GDT we so carefully
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// Placed in the "struct lguest_pages" before
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lgdt LGUEST_PAGES_guest_gdt_desc(%eax)
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// The Guest's IDT we did partially
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// Move to the "struct lguest_pages" as well.
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lidt LGUEST_PAGES_guest_idt_desc(%eax)
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// The TSS entry which controls traps
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// Must be loaded up with "ltr" now:
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// For after we switch over our page tables
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// It (as the rest) will be writable no more.
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// (The GDT entry TSS needs
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// Changes type when we load it: damn Intel!)
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movl $(GDT_ENTRY_TSS*8), %edx
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ltr %dx
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// Look back now, before we take this last step!
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// The Host's TSS entry was also marked used;
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// Let's clear it again, ere we return.
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// The GDT descriptor of the Host
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// Points to the table after two "size" bytes
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movl (LGUEST_PAGES_host_gdt_desc+2)(%eax), %edx
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// Clear the type field of "used" (byte 5, bit 2)
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andb $0xFD, (GDT_ENTRY_TSS*8 + 5)(%edx)
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// Once our page table's switched, the Guest is live!
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// The Host fades as we run this final step.
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// Our "struct lguest_pages" is now read-only.
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movl %ebx, %cr3
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// The page table change did one tricky thing:
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// The Guest's register page has been mapped
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// Writable onto our %esp (stack) --
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// We can simply pop off all Guest regs.
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popl %ebx
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popl %ecx
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popl %edx
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popl %esi
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popl %edi
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popl %ebp
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popl %gs
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popl %eax
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popl %fs
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popl %ds
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popl %es
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// Near the base of the stack lurk two strange fields
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// Which we fill as we exit the Guest
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// These are the trap number and its error
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// We can simply step past them on our way.
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addl $8, %esp
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// The last five stack slots hold return address
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// And everything needed to change privilege
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// Into the Guest privilege level of 1,
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// And the stack where the Guest had last left it.
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// Interrupts are turned back on: we are Guest.
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iret
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// There are two paths where we switch to the Host
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// So we put the routine in a macro.
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// We are on our way home, back to the Host
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// Interrupted out of the Guest, we come here.
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#define SWITCH_TO_HOST \
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/* We save the Guest state: all registers first \
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* Laid out just as "struct lguest_regs" defines */ \
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pushl %es; \
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pushl %ds; \
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pushl %fs; \
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pushl %eax; \
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pushl %gs; \
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pushl %ebp; \
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pushl %edi; \
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pushl %esi; \
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pushl %edx; \
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pushl %ecx; \
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pushl %ebx; \
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/* Our stack and our code are using segments \
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* Set in the TSS and IDT \
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* Yet if we were to touch data we'd use \
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* Whatever data segment the Guest had. \
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* Load the lguest ds segment for now. */ \
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movl $(LGUEST_DS), %eax; \
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movl %eax, %ds; \
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/* So where are we? Which CPU, which struct? \
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* The stack is our clue: our TSS starts \
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* It at the end of "struct lguest_pages". \
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* Or we may have stumbled while restoring \
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* Our Guest segment regs while in switch_to_guest, \
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* The fault pushed atop that part-unwound stack. \
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* If we round the stack down to the page start \
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* We're at the start of "struct lguest_pages". */ \
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movl %esp, %eax; \
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andl $(~(1 << PAGE_SHIFT - 1)), %eax; \
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/* Save our trap number: the switch will obscure it \
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* (The Guest regs are not mapped here in the Host) \
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* %ebx holds it safe for deliver_to_host */ \
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movl LGUEST_PAGES_regs_trapnum(%eax), %ebx; \
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/* The Host GDT, IDT and stack! \
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* All these lie safely hidden from the Guest: \
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* We must return to the Host page tables \
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* (Hence that was saved in struct lguest_pages) */ \
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movl LGUEST_PAGES_host_cr3(%eax), %edx; \
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movl %edx, %cr3; \
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/* As before, when we looked back at the Host \
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* As we left and marked TSS unused \
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* So must we now for the Guest left behind. */ \
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andb $0xFD, (LGUEST_PAGES_guest_gdt+GDT_ENTRY_TSS*8+5)(%eax); \
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/* Switch to Host's GDT, IDT. */ \
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lgdt LGUEST_PAGES_host_gdt_desc(%eax); \
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lidt LGUEST_PAGES_host_idt_desc(%eax); \
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/* Restore the Host's stack where it's saved regs lie */ \
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movl LGUEST_PAGES_host_sp(%eax), %esp; \
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/* Last the TSS: our Host is complete */ \
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movl $(GDT_ENTRY_TSS*8), %edx; \
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ltr %dx; \
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/* Restore now the regs saved right at the first. */ \
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popl %ebp; \
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popl %fs; \
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popl %gs; \
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popl %ds; \
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popl %es
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// Here's where we come when the Guest has just trapped:
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// (Which trap we'll see has been pushed on the stack).
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// We need only switch back, and the Host will decode
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// Why we came home, and what needs to be done.
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return_to_host:
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SWITCH_TO_HOST
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iret
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// An interrupt, with some cause external
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// Has ajerked us rudely from the Guest's code
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// Again we must return home to the Host
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deliver_to_host:
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SWITCH_TO_HOST
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// But now we must go home via that place
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// Where that interrupt was supposed to go
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// Had we not been ensconced, running the Guest.
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// Here we see the cleverness of our stack:
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// The Host stack is formed like an interrupt
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// With EIP, CS and EFLAGS layered.
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// Interrupt handlers end with "iret"
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// And that will take us home at long long last.
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// But first we must find the handler to call!
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// The IDT descriptor for the Host
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// Has two bytes for size, and four for address:
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// %edx will hold it for us for now.
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movl (LGUEST_PAGES_host_idt_desc+2)(%eax), %edx
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// We now know the table address we need,
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// And saved the trap's number inside %ebx.
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// Yet the pointer to the handler is smeared
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// Across the bits of the table entry.
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// What oracle can tell us how to extract
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// From such a convoluted encoding?
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// I consulted gcc, and it gave
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// These instructions, which I gladly credit:
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leal (%edx,%ebx,8), %eax
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movzwl (%eax),%edx
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movl 4(%eax), %eax
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xorw %ax, %ax
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orl %eax, %edx
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// Now the address of the handler's in %edx
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// We call it now: its "iret" takes us home.
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jmp *%edx
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// Every interrupt can come to us here
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// But we must truly tell each apart.
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// They number two hundred and fifty six
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// And each must land in a different spot,
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// Push its number on stack, and join the stream.
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// And worse, a mere six of the traps stand apart
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// And push on their stack an addition:
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// An error number, thirty two bits long
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// So we punish the other two fifty
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// And make them push a zero so they match.
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// Yet two fifty six entries is long
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// And all will look most the same as the last
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// So we create a macro which can make
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// As many entries as we need to fill.
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// Note the change to .data then .text:
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// We plant the address of each entry
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// Into a (data) table for the Host
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// To know where each Guest interrupt should go.
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.macro IRQ_STUB N TARGET
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.data; .long 1f; .text; 1:
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// Trap eight, ten through fourteen and seventeen
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// Supply an error number. Else zero.
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.if (\N <> 8) && (\N < 10 || \N > 14) && (\N <> 17)
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pushl $0
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.endif
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pushl $\N
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jmp \TARGET
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ALIGN
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.endm
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// This macro creates numerous entries
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// Using GAS macros which out-power C's.
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.macro IRQ_STUBS FIRST LAST TARGET
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irq=\FIRST
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.rept \LAST-\FIRST+1
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IRQ_STUB irq \TARGET
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irq=irq+1
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.endr
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.endm
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// Here's the marker for our pointer table
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// Laid in the data section just before
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// Each macro places the address of code
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// Forming an array: each one points to text
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// Which handles interrupt in its turn.
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.data
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.global default_idt_entries
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default_idt_entries:
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.text
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// The first two traps go straight back to the Host
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IRQ_STUBS 0 1 return_to_host
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// We'll say nothing, yet, about NMI
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IRQ_STUB 2 handle_nmi
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// Other traps also return to the Host
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IRQ_STUBS 3 31 return_to_host
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// All interrupts go via their handlers
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IRQ_STUBS 32 127 deliver_to_host
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// 'Cept system calls coming from userspace
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// Are to go to the Guest, never the Host.
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IRQ_STUB 128 return_to_host
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IRQ_STUBS 129 255 deliver_to_host
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// The NMI, what a fabulous beast
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// Which swoops in and stops us no matter that
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// We're suspended between heaven and hell,
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// (Or more likely between the Host and Guest)
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// When in it comes! We are dazed and confused
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// So we do the simplest thing which one can.
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// Though we've pushed the trap number and zero
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// We discard them, return, and hope we live.
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handle_nmi:
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addl $8, %esp
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iret
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// We are done; all that's left is Mastery
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// And "make Mastery" is a journey long
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// Designed to make your fingers itch to code.
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// Here ends the text, the file and poem.
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ENTRY(end_switcher_text)
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