(SWITCHER_ADDR + SHARED_SWITCHER_PAGES*PAGE_SIZE))[cpu]);
}
+/*H:010 We need to set up the Switcher at a high virtual address. Remember the
+ * Switcher is a few hundred bytes of assembler code which actually changes the
+ * CPU to run the Guest, and then changes back to the Host when a trap or
+ * interrupt happens.
+ *
+ * The Switcher code must be at the same virtual address in the Guest as the
+ * Host since it will be running as the switchover occurs.
+ *
+ * Trying to map memory at a particular address is an unusual thing to do, so
+ * it's not a simple one-liner. We also set up the per-cpu parts of the
+ * Switcher here.
+ */
static __init int map_switcher(void)
{
int i, err;
struct page **pagep;
+ /*
+ * Map the Switcher in to high memory.
+ *
+ * It turns out that if we choose the address 0xFFC00000 (4MB under the
+ * top virtual address), it makes setting up the page tables really
+ * easy.
+ */
+
+ /* We allocate an array of "struct page"s. map_vm_area() wants the
+ * pages in this form, rather than just an array of pointers. */
switcher_page = kmalloc(sizeof(switcher_page[0])*TOTAL_SWITCHER_PAGES,
GFP_KERNEL);
if (!switcher_page) {
goto out;
}
+ /* Now we actually allocate the pages. The Guest will see these pages,
+ * so we make sure they're zeroed. */
for (i = 0; i < TOTAL_SWITCHER_PAGES; i++) {
unsigned long addr = get_zeroed_page(GFP_KERNEL);
if (!addr) {
switcher_page[i] = virt_to_page(addr);
}
+ /* Now we reserve the "virtual memory area" we want: 0xFFC00000
+ * (SWITCHER_ADDR). We might not get it in theory, but in practice
+ * it's worked so far. */
switcher_vma = __get_vm_area(TOTAL_SWITCHER_PAGES * PAGE_SIZE,
VM_ALLOC, SWITCHER_ADDR, VMALLOC_END);
if (!switcher_vma) {
goto free_pages;
}
+ /* This code actually sets up the pages we've allocated to appear at
+ * SWITCHER_ADDR. map_vm_area() takes the vma we allocated above, the
+ * kind of pages we're mapping (kernel pages), and a pointer to our
+ * array of struct pages. It increments that pointer, but we don't
+ * care. */
pagep = switcher_page;
err = map_vm_area(switcher_vma, PAGE_KERNEL, &pagep);
if (err) {
printk("lguest: map_vm_area failed: %i\n", err);
goto free_vma;
}
+
+ /* Now the switcher is mapped at the right address, we can't fail!
+ * Copy in the compiled-in Switcher code (from switcher.S). */
memcpy(switcher_vma->addr, start_switcher_text,
end_switcher_text - start_switcher_text);
- /* Fix up IDT entries to point into copied text. */
+ /* Most of the switcher.S doesn't care that it's been moved; on Intel,
+ * jumps are relative, and it doesn't access any references to external
+ * code or data.
+ *
+ * The only exception is the interrupt handlers in switcher.S: their
+ * addresses are placed in a table (default_idt_entries), so we need to
+ * update the table with the new addresses. switcher_offset() is a
+ * convenience function which returns the distance between the builtin
+ * switcher code and the high-mapped copy we just made. */
for (i = 0; i < IDT_ENTRIES; i++)
default_idt_entries[i] += switcher_offset();
+ /*
+ * Set up the Switcher's per-cpu areas.
+ *
+ * Each CPU gets two pages of its own within the high-mapped region
+ * (aka. "struct lguest_pages"). Much of this can be initialized now,
+ * but some depends on what Guest we are running (which is set up in
+ * copy_in_guest_info()).
+ */
for_each_possible_cpu(i) {
+ /* lguest_pages() returns this CPU's two pages. */
struct lguest_pages *pages = lguest_pages(i);
+ /* This is a convenience pointer to make the code fit one
+ * statement to a line. */
struct lguest_ro_state *state = &pages->state;
- /* These fields are static: rest done in copy_in_guest_info */
+ /* The Global Descriptor Table: the Host has a different one
+ * for each CPU. We keep a descriptor for the GDT which says
+ * where it is and how big it is (the size is actually the last
+ * byte, not the size, hence the "-1"). */
state->host_gdt_desc.size = GDT_SIZE-1;
state->host_gdt_desc.address = (long)get_cpu_gdt_table(i);
+
+ /* All CPUs on the Host use the same Interrupt Descriptor
+ * Table, so we just use store_idt(), which gets this CPU's IDT
+ * descriptor. */
store_idt(&state->host_idt_desc);
+
+ /* The descriptors for the Guest's GDT and IDT can be filled
+ * out now, too. We copy the GDT & IDT into ->guest_gdt and
+ * ->guest_idt before actually running the Guest. */
state->guest_idt_desc.size = sizeof(state->guest_idt)-1;
state->guest_idt_desc.address = (long)&state->guest_idt;
state->guest_gdt_desc.size = sizeof(state->guest_gdt)-1;
state->guest_gdt_desc.address = (long)&state->guest_gdt;
+
+ /* We know where we want the stack to be when the Guest enters
+ * the switcher: in pages->regs. The stack grows upwards, so
+ * we start it at the end of that structure. */
state->guest_tss.esp0 = (long)(&pages->regs + 1);
+ /* And this is the GDT entry to use for the stack: we keep a
+ * couple of special LGUEST entries. */
state->guest_tss.ss0 = LGUEST_DS;
- /* No I/O for you! */
+
+ /* x86 can have a finegrained bitmap which indicates what I/O
+ * ports the process can use. We set it to the end of our
+ * structure, meaning "none". */
state->guest_tss.io_bitmap_base = sizeof(state->guest_tss);
+
+ /* Some GDT entries are the same across all Guests, so we can
+ * set them up now. */
setup_default_gdt_entries(state);
+ /* Most IDT entries are the same for all Guests, too.*/
setup_default_idt_entries(state, default_idt_entries);
- /* Setup LGUEST segments on all cpus */
+ /* The Host needs to be able to use the LGUEST segments on this
+ * CPU, too, so put them in the Host GDT. */
get_cpu_gdt_table(i)[GDT_ENTRY_LGUEST_CS] = FULL_EXEC_SEGMENT;
get_cpu_gdt_table(i)[GDT_ENTRY_LGUEST_DS] = FULL_SEGMENT;
}
- /* Initialize entry point into switcher. */
+ /* In the Switcher, we want the %cs segment register to use the
+ * LGUEST_CS GDT entry: we've put that in the Host and Guest GDTs, so
+ * it will be undisturbed when we switch. To change %cs and jump we
+ * need this structure to feed to Intel's "lcall" instruction. */
lguest_entry.offset = (long)switch_to_guest + switcher_offset();
lguest_entry.segment = LGUEST_CS;
printk(KERN_INFO "lguest: mapped switcher at %p\n",
switcher_vma->addr);
+ /* And we succeeded... */
return 0;
free_vma:
out:
return err;
}
+/*:*/
+/* Cleaning up the mapping when the module is unloaded is almost...
+ * too easy. */
static void unmap_switcher(void)
{
unsigned int i;
+ /* vunmap() undoes *both* map_vm_area() and __get_vm_area(). */
vunmap(switcher_vma->addr);
+ /* Now we just need to free the pages we copied the switcher into */
for (i = 0; i < TOTAL_SWITCHER_PAGES; i++)
__free_pages(switcher_page[i], 0);
}
-/* IN/OUT insns: enough to get us past boot-time probing. */
+/*H:130 Our Guest is usually so well behaved; it never tries to do things it
+ * isn't allowed to. Unfortunately, "struct paravirt_ops" isn't quite
+ * complete, because it doesn't contain replacements for the Intel I/O
+ * instructions. As a result, the Guest sometimes fumbles across one during
+ * the boot process as it probes for various things which are usually attached
+ * to a PC.
+ *
+ * When the Guest uses one of these instructions, we get trap #13 (General
+ * Protection Fault) and come here. We see if it's one of those troublesome
+ * instructions and skip over it. We return true if we did. */
static int emulate_insn(struct lguest *lg)
{
u8 insn;
unsigned int insnlen = 0, in = 0, shift = 0;
+ /* The eip contains the *virtual* address of the Guest's instruction:
+ * guest_pa just subtracts the Guest's page_offset. */
unsigned long physaddr = guest_pa(lg, lg->regs->eip);
- /* This only works for addresses in linear mapping... */
+ /* The guest_pa() function only works for Guest kernel addresses, but
+ * that's all we're trying to do anyway. */
if (lg->regs->eip < lg->page_offset)
return 0;
+
+ /* Decoding x86 instructions is icky. */
lgread(lg, &insn, physaddr, 1);
- /* Operand size prefix means it's actually for ax. */
+ /* 0x66 is an "operand prefix". It means it's using the upper 16 bits
+ of the eax register. */
if (insn == 0x66) {
shift = 16;
+ /* The instruction is 1 byte so far, read the next byte. */
insnlen = 1;
lgread(lg, &insn, physaddr + insnlen, 1);
}
+ /* We can ignore the lower bit for the moment and decode the 4 opcodes
+ * we need to emulate. */
switch (insn & 0xFE) {
case 0xE4: /* in <next byte>,%al */
insnlen += 2;
insnlen += 1;
break;
default:
+ /* OK, we don't know what this is, can't emulate. */
return 0;
}
+ /* If it was an "IN" instruction, they expect the result to be read
+ * into %eax, so we change %eax. We always return all-ones, which
+ * traditionally means "there's nothing there". */
if (in) {
/* Lower bit tells is whether it's a 16 or 32 bit access */
if (insn & 0x1)
else
lg->regs->eax |= (0xFFFF << shift);
}
+ /* Finally, we've "done" the instruction, so move past it. */
lg->regs->eip += insnlen;
+ /* Success! */
return 1;
}
+/*:*/
/*L:305
* Dealing With Guest Memory.
: "memory", "%edx", "%ecx", "%edi", "%esi");
}
+/*H:030 Let's jump straight to the the main loop which runs the Guest.
+ * Remember, this is called by the Launcher reading /dev/lguest, and we keep
+ * going around and around until something interesting happens. */
int run_guest(struct lguest *lg, unsigned long __user *user)
{
+ /* We stop running once the Guest is dead. */
while (!lg->dead) {
+ /* We need to initialize this, otherwise gcc complains. It's
+ * not (yet) clever enough to see that it's initialized when we
+ * need it. */
unsigned int cr2 = 0; /* Damn gcc */
- /* Hypercalls first: we might have been out to userspace */
+ /* First we run any hypercalls the Guest wants done: either in
+ * the hypercall ring in "struct lguest_data", or directly by
+ * using int 31 (LGUEST_TRAP_ENTRY). */
do_hypercalls(lg);
+ /* It's possible the Guest did a SEND_DMA hypercall to the
+ * Launcher, in which case we return from the read() now. */
if (lg->dma_is_pending) {
if (put_user(lg->pending_dma, user) ||
put_user(lg->pending_key, user+1))
return sizeof(unsigned long)*2;
}
+ /* Check for signals */
if (signal_pending(current))
return -ERESTARTSYS;
if (lg->break_out)
return -EAGAIN;
+ /* Check if there are any interrupts which can be delivered
+ * now: if so, this sets up the hander to be executed when we
+ * next run the Guest. */
maybe_do_interrupt(lg);
+ /* All long-lived kernel loops need to check with this horrible
+ * thing called the freezer. If the Host is trying to suspend,
+ * it stops us. */
try_to_freeze();
+ /* Just make absolutely sure the Guest is still alive. One of
+ * those hypercalls could have been fatal, for example. */
if (lg->dead)
break;
+ /* If the Guest asked to be stopped, we sleep. The Guest's
+ * clock timer or LHCALL_BREAK from the Waker will wake us. */
if (lg->halted) {
set_current_state(TASK_INTERRUPTIBLE);
schedule();
continue;
}
+ /* OK, now we're ready to jump into the Guest. First we put up
+ * the "Do Not Disturb" sign: */
local_irq_disable();
- /* Even if *we* don't want FPU trap, guest might... */
+ /* Remember the awfully-named TS bit? If the Guest has asked
+ * to set it we set it now, so we can trap and pass that trap
+ * to the Guest if it uses the FPU. */
if (lg->ts)
set_ts();
- /* Don't let Guest do SYSENTER: we can't handle it. */
+ /* SYSENTER is an optimized way of doing system calls. We
+ * can't allow it because it always jumps to privilege level 0.
+ * A normal Guest won't try it because we don't advertise it in
+ * CPUID, but a malicious Guest (or malicious Guest userspace
+ * program) could, so we tell the CPU to disable it before
+ * running the Guest. */
if (boot_cpu_has(X86_FEATURE_SEP))
wrmsr(MSR_IA32_SYSENTER_CS, 0, 0);
+ /* Now we actually run the Guest. It will pop back out when
+ * something interesting happens, and we can examine its
+ * registers to see what it was doing. */
run_guest_once(lg, lguest_pages(raw_smp_processor_id()));
- /* Save cr2 now if we page-faulted. */
+ /* The "regs" pointer contains two extra entries which are not
+ * really registers: a trap number which says what interrupt or
+ * trap made the switcher code come back, and an error code
+ * which some traps set. */
+
+ /* If the Guest page faulted, then the cr2 register will tell
+ * us the bad virtual address. We have to grab this now,
+ * because once we re-enable interrupts an interrupt could
+ * fault and thus overwrite cr2, or we could even move off to a
+ * different CPU. */
if (lg->regs->trapnum == 14)
cr2 = read_cr2();
+ /* Similarly, if we took a trap because the Guest used the FPU,
+ * we have to restore the FPU it expects to see. */
else if (lg->regs->trapnum == 7)
math_state_restore();
+ /* Restore SYSENTER if it's supposed to be on. */
if (boot_cpu_has(X86_FEATURE_SEP))
wrmsr(MSR_IA32_SYSENTER_CS, __KERNEL_CS, 0);
+
+ /* Now we're ready to be interrupted or moved to other CPUs */
local_irq_enable();
+ /* OK, so what happened? */
switch (lg->regs->trapnum) {
case 13: /* We've intercepted a GPF. */
+ /* Check if this was one of those annoying IN or OUT
+ * instructions which we need to emulate. If so, we
+ * just go back into the Guest after we've done it. */
if (lg->regs->errcode == 0) {
if (emulate_insn(lg))
continue;
}
break;
case 14: /* We've intercepted a page fault. */
+ /* The Guest accessed a virtual address that wasn't
+ * mapped. This happens a lot: we don't actually set
+ * up most of the page tables for the Guest at all when
+ * we start: as it runs it asks for more and more, and
+ * we set them up as required. In this case, we don't
+ * even tell the Guest that the fault happened.
+ *
+ * The errcode tells whether this was a read or a
+ * write, and whether kernel or userspace code. */
if (demand_page(lg, cr2, lg->regs->errcode))
continue;
- /* If lguest_data is NULL, this won't hurt. */
+ /* OK, it's really not there (or not OK): the Guest
+ * needs to know. We write out the cr2 value so it
+ * knows where the fault occurred.
+ *
+ * Note that if the Guest were really messed up, this
+ * could happen before it's done the INITIALIZE
+ * hypercall, so lg->lguest_data will be NULL, so
+ * &lg->lguest_data->cr2 will be address 8. Writing
+ * into that address won't hurt the Host at all,
+ * though. */
if (put_user(cr2, &lg->lguest_data->cr2))
kill_guest(lg, "Writing cr2");
break;
case 7: /* We've intercepted a Device Not Available fault. */
- /* If they don't want to know, just absorb it. */
+ /* If the Guest doesn't want to know, we already
+ * restored the Floating Point Unit, so we just
+ * continue without telling it. */
if (!lg->ts)
continue;
break;
- case 32 ... 255: /* Real interrupt, fall thru */
+ case 32 ... 255:
+ /* These values mean a real interrupt occurred, in
+ * which case the Host handler has already been run.
+ * We just do a friendly check if another process
+ * should now be run, then fall through to loop
+ * around: */
cond_resched();
case LGUEST_TRAP_ENTRY: /* Handled at top of loop */
continue;
}
+ /* If we get here, it's a trap the Guest wants to know
+ * about. */
if (deliver_trap(lg, lg->regs->trapnum))
continue;
+ /* If the Guest doesn't have a handler (either it hasn't
+ * registered any yet, or it's one of the faults we don't let
+ * it handle), it dies with a cryptic error message. */
kill_guest(lg, "unhandled trap %li at %#lx (%#lx)",
lg->regs->trapnum, lg->regs->eip,
lg->regs->trapnum == 14 ? cr2 : lg->regs->errcode);
}
+ /* The Guest is dead => "No such file or directory" */
return -ENOENT;
}
+/* Now we can look at each of the routines this calls, in increasing order of
+ * complexity: do_hypercalls(), emulate_insn(), maybe_do_interrupt(),
+ * deliver_trap() and demand_page(). After all those, we'll be ready to
+ * examine the Switcher, and our philosophical understanding of the Host/Guest
+ * duality will be complete. :*/
+
int find_free_guest(void)
{
unsigned int i;
write_cr4(read_cr4() & ~X86_CR4_PGE);
}
+/*H:000
+ * Welcome to the Host!
+ *
+ * By this point your brain has been tickled by the Guest code and numbed by
+ * the Launcher code; prepare for it to be stretched by the Host code. This is
+ * the heart. Let's begin at the initialization routine for the Host's lg
+ * module.
+ */
static int __init init(void)
{
int err;
+ /* Lguest can't run under Xen, VMI or itself. It does Tricky Stuff. */
if (paravirt_enabled()) {
printk("lguest is afraid of %s\n", paravirt_ops.name);
return -EPERM;
}
+ /* First we put the Switcher up in very high virtual memory. */
err = map_switcher();
if (err)
return err;
+ /* Now we set up the pagetable implementation for the Guests. */
err = init_pagetables(switcher_page, SHARED_SWITCHER_PAGES);
if (err) {
unmap_switcher();
return err;
}
+
+ /* The I/O subsystem needs some things initialized. */
lguest_io_init();
+ /* /dev/lguest needs to be registered. */
err = lguest_device_init();
if (err) {
free_pagetables();
unmap_switcher();
return err;
}
+
+ /* Finally, we need to turn off "Page Global Enable". PGE is an
+ * optimization where page table entries are specially marked to show
+ * they never change. The Host kernel marks all the kernel pages this
+ * way because it's always present, even when userspace is running.
+ *
+ * Lguest breaks this: unbeknownst to the rest of the Host kernel, we
+ * switch to the Guest kernel. If you don't disable this on all CPUs,
+ * you'll get really weird bugs that you'll chase for two days.
+ *
+ * I used to turn PGE off every time we switched to the Guest and back
+ * on when we return, but that slowed the Switcher down noticibly. */
+
+ /* We don't need the complexity of CPUs coming and going while we're
+ * doing this. */
lock_cpu_hotplug();
if (cpu_has_pge) { /* We have a broader idea of "global". */
+ /* Remember that this was originally set (for cleanup). */
cpu_had_pge = 1;
+ /* adjust_pge is a helper function which sets or unsets the PGE
+ * bit on its CPU, depending on the argument (0 == unset). */
on_each_cpu(adjust_pge, (void *)0, 0, 1);
+ /* Turn off the feature in the global feature set. */
clear_bit(X86_FEATURE_PGE, boot_cpu_data.x86_capability);
}
unlock_cpu_hotplug();
+
+ /* All good! */
return 0;
}
+/* Cleaning up is just the same code, backwards. With a little French. */
static void __exit fini(void)
{
lguest_device_remove();
free_pagetables();
unmap_switcher();
+
+ /* If we had PGE before we started, turn it back on now. */
lock_cpu_hotplug();
if (cpu_had_pge) {
set_bit(X86_FEATURE_PGE, boot_cpu_data.x86_capability);
+ /* adjust_pge's argument "1" means set PGE. */
on_each_cpu(adjust_pge, (void *)1, 0, 1);
}
unlock_cpu_hotplug();
}
+/* The Host side of lguest can be a module. This is a nice way for people to
+ * play with it. */
module_init(init);
module_exit(fini);
MODULE_LICENSE("GPL");
#include <irq_vectors.h>
#include "lg.h"
+/*H:120 This is the core hypercall routine: where the Guest gets what it
+ * wants. Or gets killed. Or, in the case of LHCALL_CRASH, both.
+ *
+ * Remember from the Guest: %eax == which call to make, and the arguments are
+ * packed into %edx, %ebx and %ecx if needed. */
static void do_hcall(struct lguest *lg, struct lguest_regs *regs)
{
switch (regs->eax) {
case LHCALL_FLUSH_ASYNC:
+ /* This call does nothing, except by breaking out of the Guest
+ * it makes us process all the asynchronous hypercalls. */
break;
case LHCALL_LGUEST_INIT:
+ /* You can't get here unless you're already initialized. Don't
+ * do that. */
kill_guest(lg, "already have lguest_data");
break;
case LHCALL_CRASH: {
+ /* Crash is such a trivial hypercall that we do it in four
+ * lines right here. */
char msg[128];
+ /* If the lgread fails, it will call kill_guest() itself; the
+ * kill_guest() with the message will be ignored. */
lgread(lg, msg, regs->edx, sizeof(msg));
msg[sizeof(msg)-1] = '\0';
kill_guest(lg, "CRASH: %s", msg);
break;
}
case LHCALL_FLUSH_TLB:
+ /* FLUSH_TLB comes in two flavors, depending on the
+ * argument: */
if (regs->edx)
guest_pagetable_clear_all(lg);
else
guest_pagetable_flush_user(lg);
break;
case LHCALL_GET_WALLCLOCK: {
+ /* The Guest wants to know the real time in seconds since 1970,
+ * in good Unix tradition. */
struct timespec ts;
ktime_get_real_ts(&ts);
regs->eax = ts.tv_sec;
break;
}
case LHCALL_BIND_DMA:
+ /* BIND_DMA really wants four arguments, but it's the only call
+ * which does. So the Guest packs the number of buffers and
+ * the interrupt number into the final argument, and we decode
+ * it here. This can legitimately fail, since we currently
+ * place a limit on the number of DMA pools a Guest can have.
+ * So we return true or false from this call. */
regs->eax = bind_dma(lg, regs->edx, regs->ebx,
regs->ecx >> 8, regs->ecx & 0xFF);
break;
+
+ /* All these calls simply pass the arguments through to the right
+ * routines. */
case LHCALL_SEND_DMA:
send_dma(lg, regs->edx, regs->ebx);
break;
case LHCALL_SET_CLOCKEVENT:
guest_set_clockevent(lg, regs->edx);
break;
+
case LHCALL_TS:
+ /* This sets the TS flag, as we saw used in run_guest(). */
lg->ts = regs->edx;
break;
case LHCALL_HALT:
+ /* Similarly, this sets the halted flag for run_guest(). */
lg->halted = 1;
break;
default:
}
}
-/* We always do queued calls before actual hypercall. */
+/* Asynchronous hypercalls are easy: we just look in the array in the Guest's
+ * "struct lguest_data" and see if there are any new ones marked "ready".
+ *
+ * We are careful to do these in order: obviously we respect the order the
+ * Guest put them in the ring, but we also promise the Guest that they will
+ * happen before any normal hypercall (which is why we check this before
+ * checking for a normal hcall). */
static void do_async_hcalls(struct lguest *lg)
{
unsigned int i;
u8 st[LHCALL_RING_SIZE];
+ /* For simplicity, we copy the entire call status array in at once. */
if (copy_from_user(&st, &lg->lguest_data->hcall_status, sizeof(st)))
return;
+
+ /* We process "struct lguest_data"s hcalls[] ring once. */
for (i = 0; i < ARRAY_SIZE(st); i++) {
struct lguest_regs regs;
+ /* We remember where we were up to from last time. This makes
+ * sure that the hypercalls are done in the order the Guest
+ * places them in the ring. */
unsigned int n = lg->next_hcall;
+ /* 0xFF means there's no call here (yet). */
if (st[n] == 0xFF)
break;
+ /* OK, we have hypercall. Increment the "next_hcall" cursor,
+ * and wrap back to 0 if we reach the end. */
if (++lg->next_hcall == LHCALL_RING_SIZE)
lg->next_hcall = 0;
+ /* We copy the hypercall arguments into a fake register
+ * structure. This makes life simple for do_hcall(). */
if (get_user(regs.eax, &lg->lguest_data->hcalls[n].eax)
|| get_user(regs.edx, &lg->lguest_data->hcalls[n].edx)
|| get_user(regs.ecx, &lg->lguest_data->hcalls[n].ecx)
break;
}
+ /* Do the hypercall, same as a normal one. */
do_hcall(lg, ®s);
+
+ /* Mark the hypercall done. */
if (put_user(0xFF, &lg->lguest_data->hcall_status[n])) {
kill_guest(lg, "Writing result for async hypercall");
break;
}
+ /* Stop doing hypercalls if we've just done a DMA to the
+ * Launcher: it needs to service this first. */
if (lg->dma_is_pending)
break;
}
}
+/* Last of all, we look at what happens first of all. The very first time the
+ * Guest makes a hypercall, we end up here to set things up: */
static void initialize(struct lguest *lg)
{
u32 tsc_speed;
+ /* You can't do anything until you're initialized. The Guest knows the
+ * rules, so we're unforgiving here. */
if (lg->regs->eax != LHCALL_LGUEST_INIT) {
kill_guest(lg, "hypercall %li before LGUEST_INIT",
lg->regs->eax);
return;
}
- /* We only tell the guest to use the TSC if it's reliable. */
+ /* We insist that the Time Stamp Counter exist and doesn't change with
+ * cpu frequency. Some devious chip manufacturers decided that TSC
+ * changes could be handled in software. I decided that time going
+ * backwards might be good for benchmarks, but it's bad for users.
+ *
+ * We also insist that the TSC be stable: the kernel detects unreliable
+ * TSCs for its own purposes, and we use that here. */
if (boot_cpu_has(X86_FEATURE_CONSTANT_TSC) && !check_tsc_unstable())
tsc_speed = tsc_khz;
else
tsc_speed = 0;
+ /* The pointer to the Guest's "struct lguest_data" is the only
+ * argument. */
lg->lguest_data = (struct lguest_data __user *)lg->regs->edx;
- /* We check here so we can simply copy_to_user/from_user */
+ /* If we check the address they gave is OK now, we can simply
+ * copy_to_user/from_user from now on rather than using lgread/lgwrite.
+ * I put this in to show that I'm not immune to writing stupid
+ * optimizations. */
if (!lguest_address_ok(lg, lg->regs->edx, sizeof(*lg->lguest_data))) {
kill_guest(lg, "bad guest page %p", lg->lguest_data);
return;
}
+ /* The Guest tells us where we're not to deliver interrupts by putting
+ * the range of addresses into "struct lguest_data". */
if (get_user(lg->noirq_start, &lg->lguest_data->noirq_start)
|| get_user(lg->noirq_end, &lg->lguest_data->noirq_end)
- /* We reserve the top pgd entry. */
+ /* We tell the Guest that it can't use the top 4MB of virtual
+ * addresses used by the Switcher. */
|| put_user(4U*1024*1024, &lg->lguest_data->reserve_mem)
|| put_user(tsc_speed, &lg->lguest_data->tsc_khz)
+ /* We also give the Guest a unique id, as used in lguest_net.c. */
|| put_user(lg->guestid, &lg->lguest_data->guestid))
kill_guest(lg, "bad guest page %p", lg->lguest_data);
- /* This is the one case where the above accesses might have
- * been the first write to a Guest page. This may have caused
- * a copy-on-write fault, but the Guest might be referring to
- * the old (read-only) page. */
+ /* This is the one case where the above accesses might have been the
+ * first write to a Guest page. This may have caused a copy-on-write
+ * fault, but the Guest might be referring to the old (read-only)
+ * page. */
guest_pagetable_clear_all(lg);
}
+/* Now we've examined the hypercall code; our Guest can make requests. There
+ * is one other way we can do things for the Guest, as we see in
+ * emulate_insn(). */
-/* Even if we go out to userspace and come back, we don't want to do
- * the hypercall again. */
+/*H:110 Tricky point: we mark the hypercall as "done" once we've done it.
+ * Normally we don't need to do this: the Guest will run again and update the
+ * trap number before we come back around the run_guest() loop to
+ * do_hypercalls().
+ *
+ * However, if we are signalled or the Guest sends DMA to the Launcher, that
+ * loop will exit without running the Guest. When it comes back it would try
+ * to re-run the hypercall. */
static void clear_hcall(struct lguest *lg)
{
lg->regs->trapnum = 255;
}
+/*H:100
+ * Hypercalls
+ *
+ * Remember from the Guest, hypercalls come in two flavors: normal and
+ * asynchronous. This file handles both of types.
+ */
void do_hypercalls(struct lguest *lg)
{
+ /* Not initialized yet? */
if (unlikely(!lg->lguest_data)) {
+ /* Did the Guest make a hypercall? We might have come back for
+ * some other reason (an interrupt, a different trap). */
if (lg->regs->trapnum == LGUEST_TRAP_ENTRY) {
+ /* Set up the "struct lguest_data" */
initialize(lg);
+ /* The hypercall is done. */
clear_hcall(lg);
}
return;
}
+ /* The Guest has initialized.
+ *
+ * Look in the hypercall ring for the async hypercalls: */
do_async_hcalls(lg);
+
+ /* If we stopped reading the hypercall ring because the Guest did a
+ * SEND_DMA to the Launcher, we want to return now. Otherwise if the
+ * Guest asked us to do a hypercall, we do it. */
if (!lg->dma_is_pending && lg->regs->trapnum == LGUEST_TRAP_ENTRY) {
do_hcall(lg, lg->regs);
+ /* The hypercall is done. */
clear_hcall(lg);
}
}
#include <linux/uaccess.h>
#include "lg.h"
+/* The address of the interrupt handler is split into two bits: */
static unsigned long idt_address(u32 lo, u32 hi)
{
return (lo & 0x0000FFFF) | (hi & 0xFFFF0000);
}
+/* The "type" of the interrupt handler is a 4 bit field: we only support a
+ * couple of types. */
static int idt_type(u32 lo, u32 hi)
{
return (hi >> 8) & 0xF;
}
+/* An IDT entry can't be used unless the "present" bit is set. */
static int idt_present(u32 lo, u32 hi)
{
return (hi & 0x8000);
}
+/* We need a helper to "push" a value onto the Guest's stack, since that's a
+ * big part of what delivering an interrupt does. */
static void push_guest_stack(struct lguest *lg, unsigned long *gstack, u32 val)
{
+ /* Stack grows upwards: move stack then write value. */
*gstack -= 4;
lgwrite_u32(lg, *gstack, val);
}
+/*H:210 The set_guest_interrupt() routine actually delivers the interrupt or
+ * trap. The mechanics of delivering traps and interrupts to the Guest are the
+ * same, except some traps have an "error code" which gets pushed onto the
+ * stack as well: the caller tells us if this is one.
+ *
+ * "lo" and "hi" are the two parts of the Interrupt Descriptor Table for this
+ * interrupt or trap. It's split into two parts for traditional reasons: gcc
+ * on i386 used to be frightened by 64 bit numbers.
+ *
+ * We set up the stack just like the CPU does for a real interrupt, so it's
+ * identical for the Guest (and the standard "iret" instruction will undo
+ * it). */
static void set_guest_interrupt(struct lguest *lg, u32 lo, u32 hi, int has_err)
{
unsigned long gstack;
u32 eflags, ss, irq_enable;
- /* If they want a ring change, we use new stack and push old ss/esp */
+ /* There are two cases for interrupts: one where the Guest is already
+ * in the kernel, and a more complex one where the Guest is in
+ * userspace. We check the privilege level to find out. */
if ((lg->regs->ss&0x3) != GUEST_PL) {
+ /* The Guest told us their kernel stack with the SET_STACK
+ * hypercall: both the virtual address and the segment */
gstack = guest_pa(lg, lg->esp1);
ss = lg->ss1;
+ /* We push the old stack segment and pointer onto the new
+ * stack: when the Guest does an "iret" back from the interrupt
+ * handler the CPU will notice they're dropping privilege
+ * levels and expect these here. */
push_guest_stack(lg, &gstack, lg->regs->ss);
push_guest_stack(lg, &gstack, lg->regs->esp);
} else {
+ /* We're staying on the same Guest (kernel) stack. */
gstack = guest_pa(lg, lg->regs->esp);
ss = lg->regs->ss;
}
- /* We use IF bit in eflags to indicate whether irqs were enabled
- (it's always 1, since irqs are enabled when guest is running). */
+ /* Remember that we never let the Guest actually disable interrupts, so
+ * the "Interrupt Flag" bit is always set. We copy that bit from the
+ * Guest's "irq_enabled" field into the eflags word: the Guest copies
+ * it back in "lguest_iret". */
eflags = lg->regs->eflags;
if (get_user(irq_enable, &lg->lguest_data->irq_enabled) == 0
&& !(irq_enable & X86_EFLAGS_IF))
eflags &= ~X86_EFLAGS_IF;
+ /* An interrupt is expected to push three things on the stack: the old
+ * "eflags" word, the old code segment, and the old instruction
+ * pointer. */
push_guest_stack(lg, &gstack, eflags);
push_guest_stack(lg, &gstack, lg->regs->cs);
push_guest_stack(lg, &gstack, lg->regs->eip);
+ /* For the six traps which supply an error code, we push that, too. */
if (has_err)
push_guest_stack(lg, &gstack, lg->regs->errcode);
- /* Change the real stack so switcher returns to trap handler */
+ /* Now we've pushed all the old state, we change the stack, the code
+ * segment and the address to execute. */
lg->regs->ss = ss;
lg->regs->esp = gstack + lg->page_offset;
lg->regs->cs = (__KERNEL_CS|GUEST_PL);
lg->regs->eip = idt_address(lo, hi);
- /* Disable interrupts for an interrupt gate. */
+ /* There are two kinds of interrupt handlers: 0xE is an "interrupt
+ * gate" which expects interrupts to be disabled on entry. */
if (idt_type(lo, hi) == 0xE)
if (put_user(0, &lg->lguest_data->irq_enabled))
kill_guest(lg, "Disabling interrupts");
}
+/*H:200
+ * Virtual Interrupts.
+ *
+ * maybe_do_interrupt() gets called before every entry to the Guest, to see if
+ * we should divert the Guest to running an interrupt handler. */
void maybe_do_interrupt(struct lguest *lg)
{
unsigned int irq;
DECLARE_BITMAP(blk, LGUEST_IRQS);
struct desc_struct *idt;
+ /* If the Guest hasn't even initialized yet, we can do nothing. */
if (!lg->lguest_data)
return;
- /* Mask out any interrupts they have blocked. */
+ /* Take our "irqs_pending" array and remove any interrupts the Guest
+ * wants blocked: the result ends up in "blk". */
if (copy_from_user(&blk, lg->lguest_data->blocked_interrupts,
sizeof(blk)))
return;
bitmap_andnot(blk, lg->irqs_pending, blk, LGUEST_IRQS);
+ /* Find the first interrupt. */
irq = find_first_bit(blk, LGUEST_IRQS);
+ /* None? Nothing to do */
if (irq >= LGUEST_IRQS)
return;
+ /* They may be in the middle of an iret, where they asked us never to
+ * deliver interrupts. */
if (lg->regs->eip >= lg->noirq_start && lg->regs->eip < lg->noirq_end)
return;
- /* If they're halted, we re-enable interrupts. */
+ /* If they're halted, interrupts restart them. */
if (lg->halted) {
/* Re-enable interrupts. */
if (put_user(X86_EFLAGS_IF, &lg->lguest_data->irq_enabled))
kill_guest(lg, "Re-enabling interrupts");
lg->halted = 0;
} else {
- /* Maybe they have interrupts disabled? */
+ /* Otherwise we check if they have interrupts disabled. */
u32 irq_enabled;
if (get_user(irq_enabled, &lg->lguest_data->irq_enabled))
irq_enabled = 0;
return;
}
+ /* Look at the IDT entry the Guest gave us for this interrupt. The
+ * first 32 (FIRST_EXTERNAL_VECTOR) entries are for traps, so we skip
+ * over them. */
idt = &lg->idt[FIRST_EXTERNAL_VECTOR+irq];
+ /* If they don't have a handler (yet?), we just ignore it */
if (idt_present(idt->a, idt->b)) {
+ /* OK, mark it no longer pending and deliver it. */
clear_bit(irq, lg->irqs_pending);
+ /* set_guest_interrupt() takes the interrupt descriptor and a
+ * flag to say whether this interrupt pushes an error code onto
+ * the stack as well: virtual interrupts never do. */
set_guest_interrupt(lg, idt->a, idt->b, 0);
}
}
+/*H:220 Now we've got the routines to deliver interrupts, delivering traps
+ * like page fault is easy. The only trick is that Intel decided that some
+ * traps should have error codes: */
static int has_err(unsigned int trap)
{
return (trap == 8 || (trap >= 10 && trap <= 14) || trap == 17);
}
+/* deliver_trap() returns true if it could deliver the trap. */
int deliver_trap(struct lguest *lg, unsigned int num)
{
u32 lo = lg->idt[num].a, hi = lg->idt[num].b;
+ /* Early on the Guest hasn't set the IDT entries (or maybe it put a
+ * bogus one in): if we fail here, the Guest will be killed. */
if (!idt_present(lo, hi))
return 0;
set_guest_interrupt(lg, lo, hi, has_err(num));
return 1;
}
+/*H:250 Here's the hard part: returning to the Host every time a trap happens
+ * and then calling deliver_trap() and re-entering the Guest is slow.
+ * Particularly because Guest userspace system calls are traps (trap 128).
+ *
+ * So we'd like to set up the IDT to tell the CPU to deliver traps directly
+ * into the Guest. This is possible, but the complexities cause the size of
+ * this file to double! However, 150 lines of code is worth writing for taking
+ * system calls down from 1750ns to 270ns. Plus, if lguest didn't do it, all
+ * the other hypervisors would tease it.
+ *
+ * This routine determines if a trap can be delivered directly. */
static int direct_trap(const struct lguest *lg,
const struct desc_struct *trap,
unsigned int num)
{
- /* Hardware interrupts don't go to guest (except syscall). */
+ /* Hardware interrupts don't go to the Guest at all (except system
+ * call). */
if (num >= FIRST_EXTERNAL_VECTOR && num != SYSCALL_VECTOR)
return 0;
- /* We intercept page fault (demand shadow paging & cr2 saving)
- protection fault (in/out emulation) and device not
- available (TS handling), and hypercall */
+ /* The Host needs to see page faults (for shadow paging and to save the
+ * fault address), general protection faults (in/out emulation) and
+ * device not available (TS handling), and of course, the hypercall
+ * trap. */
if (num == 14 || num == 13 || num == 7 || num == LGUEST_TRAP_ENTRY)
return 0;
- /* Interrupt gates (0xE) or not present (0x0) can't go direct. */
+ /* Only trap gates (type 15) can go direct to the Guest. Interrupt
+ * gates (type 14) disable interrupts as they are entered, which we
+ * never let the Guest do. Not present entries (type 0x0) also can't
+ * go direct, of course 8) */
return idt_type(trap->a, trap->b) == 0xF;
}
+/*H:260 When we make traps go directly into the Guest, we need to make sure
+ * the kernel stack is valid (ie. mapped in the page tables). Otherwise, the
+ * CPU trying to deliver the trap will fault while trying to push the interrupt
+ * words on the stack: this is called a double fault, and it forces us to kill
+ * the Guest.
+ *
+ * Which is deeply unfair, because (literally!) it wasn't the Guests' fault. */
void pin_stack_pages(struct lguest *lg)
{
unsigned int i;
+ /* Depending on the CONFIG_4KSTACKS option, the Guest can have one or
+ * two pages of stack space. */
for (i = 0; i < lg->stack_pages; i++)
+ /* The stack grows *upwards*, hence the subtraction */
pin_page(lg, lg->esp1 - i * PAGE_SIZE);
}
+/* Direct traps also mean that we need to know whenever the Guest wants to use
+ * a different kernel stack, so we can change the IDT entries to use that
+ * stack. The IDT entries expect a virtual address, so unlike most addresses
+ * the Guest gives us, the "esp" (stack pointer) value here is virtual, not
+ * physical.
+ *
+ * In Linux each process has its own kernel stack, so this happens a lot: we
+ * change stacks on each context switch. */
void guest_set_stack(struct lguest *lg, u32 seg, u32 esp, unsigned int pages)
{
- /* You cannot have a stack segment with priv level 0. */
+ /* You are not allowd have a stack segment with privilege level 0: bad
+ * Guest! */
if ((seg & 0x3) != GUEST_PL)
kill_guest(lg, "bad stack segment %i", seg);
+ /* We only expect one or two stack pages. */
if (pages > 2)
kill_guest(lg, "bad stack pages %u", pages);
+ /* Save where the stack is, and how many pages */
lg->ss1 = seg;
lg->esp1 = esp;
lg->stack_pages = pages;
+ /* Make sure the new stack pages are mapped */
pin_stack_pages(lg);
}
-/* Set up trap in IDT. */
+/* All this reference to mapping stacks leads us neatly into the other complex
+ * part of the Host: page table handling. */
+
+/*H:235 This is the routine which actually checks the Guest's IDT entry and
+ * transfers it into our entry in "struct lguest": */
static void set_trap(struct lguest *lg, struct desc_struct *trap,
unsigned int num, u32 lo, u32 hi)
{
u8 type = idt_type(lo, hi);
+ /* We zero-out a not-present entry */
if (!idt_present(lo, hi)) {
trap->a = trap->b = 0;
return;
}
+ /* We only support interrupt and trap gates. */
if (type != 0xE && type != 0xF)
kill_guest(lg, "bad IDT type %i", type);
+ /* We only copy the handler address, present bit, privilege level and
+ * type. The privilege level controls where the trap can be triggered
+ * manually with an "int" instruction. This is usually GUEST_PL,
+ * except for system calls which userspace can use. */
trap->a = ((__KERNEL_CS|GUEST_PL)<<16) | (lo&0x0000FFFF);
trap->b = (hi&0xFFFFEF00);
}
+/*H:230 While we're here, dealing with delivering traps and interrupts to the
+ * Guest, we might as well complete the picture: how the Guest tells us where
+ * it wants them to go. This would be simple, except making traps fast
+ * requires some tricks.
+ *
+ * We saw the Guest setting Interrupt Descriptor Table (IDT) entries with the
+ * LHCALL_LOAD_IDT_ENTRY hypercall before: that comes here. */
void load_guest_idt_entry(struct lguest *lg, unsigned int num, u32 lo, u32 hi)
{
- /* Guest never handles: NMI, doublefault, hypercall, spurious irq. */
+ /* Guest never handles: NMI, doublefault, spurious interrupt or
+ * hypercall. We ignore when it tries to set them. */
if (num == 2 || num == 8 || num == 15 || num == LGUEST_TRAP_ENTRY)
return;
+ /* Mark the IDT as changed: next time the Guest runs we'll know we have
+ * to copy this again. */
lg->changed |= CHANGED_IDT;
+
+ /* The IDT which we keep in "struct lguest" only contains 32 entries
+ * for the traps and LGUEST_IRQS (32) entries for interrupts. We
+ * ignore attempts to set handlers for higher interrupt numbers, except
+ * for the system call "interrupt" at 128: we have a special IDT entry
+ * for that. */
if (num < ARRAY_SIZE(lg->idt))
set_trap(lg, &lg->idt[num], num, lo, hi);
else if (num == SYSCALL_VECTOR)
set_trap(lg, &lg->syscall_idt, num, lo, hi);
}
+/* The default entry for each interrupt points into the Switcher routines which
+ * simply return to the Host. The run_guest() loop will then call
+ * deliver_trap() to bounce it back into the Guest. */
static void default_idt_entry(struct desc_struct *idt,
int trap,
const unsigned long handler)
{
+ /* A present interrupt gate. */
u32 flags = 0x8e00;
- /* They can't "int" into any of them except hypercall. */
+ /* Set the privilege level on the entry for the hypercall: this allows
+ * the Guest to use the "int" instruction to trigger it. */
if (trap == LGUEST_TRAP_ENTRY)
flags |= (GUEST_PL << 13);
+ /* Now pack it into the IDT entry in its weird format. */
idt->a = (LGUEST_CS<<16) | (handler&0x0000FFFF);
idt->b = (handler&0xFFFF0000) | flags;
}
+/* When the Guest first starts, we put default entries into the IDT. */
void setup_default_idt_entries(struct lguest_ro_state *state,
const unsigned long *def)
{
default_idt_entry(&state->guest_idt[i], i, def[i]);
}
+/*H:240 We don't use the IDT entries in the "struct lguest" directly, instead
+ * we copy them into the IDT which we've set up for Guests on this CPU, just
+ * before we run the Guest. This routine does that copy. */
void copy_traps(const struct lguest *lg, struct desc_struct *idt,
const unsigned long *def)
{
unsigned int i;
- /* All hardware interrupts are same whatever the guest: only the
- * traps might be different. */
+ /* We can simply copy the direct traps, otherwise we use the default
+ * ones in the Switcher: they will return to the Host. */
for (i = 0; i < FIRST_EXTERNAL_VECTOR; i++) {
if (direct_trap(lg, &lg->idt[i], i))
idt[i] = lg->idt[i];
else
default_idt_entry(&idt[i], i, def[i]);
}
+
+ /* Don't forget the system call trap! The IDT entries for other
+ * interupts never change, so no need to copy them. */
i = SYSCALL_VECTOR;
if (direct_trap(lg, &lg->syscall_idt, i))
idt[i] = lg->syscall_idt;
u8 interrupt; /* 0 when not registered */
};
-/* We have separate types for the guest's ptes & pgds and the shadow ptes &
- * pgds. Since this host might use three-level pagetables and the guest and
- * shadow pagetables don't, we can't use the normal pte_t/pgd_t. */
+/*H:310 The page-table code owes a great debt of gratitude to Andi Kleen. He
+ * reviewed the original code which used "u32" for all page table entries, and
+ * insisted that it would be far clearer with explicit typing. I thought it
+ * was overkill, but he was right: it is much clearer than it was before.
+ *
+ * We have separate types for the Guest's ptes & pgds and the shadow ptes &
+ * pgds. There's already a Linux type for these (pte_t and pgd_t) but they
+ * change depending on kernel config options (PAE). */
+
+/* Each entry is identical: lower 12 bits of flags and upper 20 bits for the
+ * "page frame number" (0 == first physical page, etc). They are different
+ * types so the compiler will warn us if we mix them improperly. */
typedef union {
struct { unsigned flags:12, pfn:20; };
struct { unsigned long val; } raw;
struct { unsigned flags:12, pfn:20; };
struct { unsigned long val; } raw;
} gpte_t;
+
+/* We have two convenient macros to convert a "raw" value as handed to us by
+ * the Guest into the correct Guest PGD or PTE type. */
#define mkgpte(_val) ((gpte_t){.raw.val = _val})
#define mkgpgd(_val) ((gpgd_t){.raw.val = _val})
+/*:*/
struct pgdir
{
#include <asm/tlbflush.h>
#include "lg.h"
+/*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 lguest.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) Setting up a page table entry for the Guest when it faults,
+ * (ii) Setting up the page table entry for the Guest stack,
+ * (iii) Setting up a page table entry when the Guest tells us it has changed,
+ * (iv) Switching page tables,
+ * (v) Flushing (thowing away) page tables,
+ * (vi) Mapping the Switcher when the Guest is about to run,
+ * (vii) Setting up the page tables initially.
+ :*/
+
+/* Pages a 4k long, and each page table entry is 4 bytes long, giving us 1024
+ * (or 2^10) entries per page. */
#define PTES_PER_PAGE_SHIFT 10
#define PTES_PER_PAGE (1 << PTES_PER_PAGE_SHIFT)
+
+/* 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 (PTES_PER_PAGE - 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(spte_t *, switcher_pte_pages);
#define switcher_pte_page(cpu) per_cpu(switcher_pte_pages, cpu)
+/*H:320 With our shadow and Guest types established, we need to deal with
+ * them: the page table code is curly enough to need helper functions to keep
+ * it clear and clean.
+ *
+ * The first helper takes a virtual address, and says which entry in the top
+ * level page table deals with that address. Since each top level entry deals
+ * with 4M, this effectively divides by 4M. */
static unsigned vaddr_to_pgd_index(unsigned long vaddr)
{
return vaddr >> (PAGE_SHIFT + PTES_PER_PAGE_SHIFT);
}
-/* These access the shadow versions (ie. the ones used by the CPU). */
+/* 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 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 spgd_t *spgd_addr(struct lguest *lg, u32 i, unsigned long vaddr)
{
unsigned int index = vaddr_to_pgd_index(vaddr);
+ /* We kill any Guest trying to touch the Switcher addresses. */
if (index >= SWITCHER_PGD_INDEX) {
kill_guest(lg, "attempt to access switcher pages");
index = 0;
}
+ /* Return a pointer index'th pgd entry for the i'th page table. */
return &lg->pgdirs[i].pgdir[index];
}
+/* This routine then takes the PGD entry given above, which contains the
+ * address of the PTE page. It then returns a pointer to the PTE entry for the
+ * given address. */
static spte_t *spte_addr(struct lguest *lg, spgd_t spgd, unsigned long vaddr)
{
spte_t *page = __va(spgd.pfn << PAGE_SHIFT);
+ /* You should never call this if the PGD entry wasn't valid */
BUG_ON(!(spgd.flags & _PAGE_PRESENT));
return &page[(vaddr >> PAGE_SHIFT) % PTES_PER_PAGE];
}
-/* These access the guest versions. */
+/* 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 lguest *lg, unsigned long vaddr)
{
unsigned int index = vaddr >> (PAGE_SHIFT + PTES_PER_PAGE_SHIFT);
return gpage + ((vaddr>>PAGE_SHIFT) % PTES_PER_PAGE) * sizeof(gpte_t);
}
-/* Do a virtual -> physical mapping on a user page. */
+/*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;
+ /* This value indicates failure. */
unsigned long ret = -1UL;
+ /* get_user_pages() is a complex interface: it gets the "struct
+ * vm_area_struct" and "struct page" assocated with a range of pages.
+ * It also needs the task's mmap_sem held, and is not very quick.
+ * It returns the number of pages it got. */
down_read(¤t->mm->mmap_sem);
if (get_user_pages(current, current->mm, virtpfn << PAGE_SHIFT,
1, write, 1, &page, NULL) == 1)
return ret;
}
+/*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 spte_t gpte_to_spte(struct lguest *lg, gpte_t gpte, int write)
{
spte_t spte;
unsigned long pfn;
- /* We ignore the global flag. */
+ /* 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. */
spte.flags = (gpte.flags & ~_PAGE_GLOBAL);
+
+ /* 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(gpte.pfn, write);
if (pfn == -1UL) {
kill_guest(lg, "failed to get page %u", gpte.pfn);
- /* Must not put_page() bogus page on cleanup. */
+ /* 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! */
spte.flags = 0;
}
+ /* Now we assign the page number, and our shadow PTE is complete. */
spte.pfn = pfn;
return spte;
}
+/*H:460 And to complete the chain, release_pte() looks like this: */
static void release_pte(spte_t pte)
{
+ /* Remember that get_user_pages() took a reference to the page, in
+ * get_pfn()? We have to put it back now. */
if (pte.flags & _PAGE_PRESENT)
put_page(pfn_to_page(pte.pfn));
}
+/*:*/
static void check_gpte(struct lguest *lg, gpte_t gpte)
{
kill_guest(lg, "bad page directory entry");
}
-/* FIXME: We hold reference to pages, which prevents them from being
- swapped. It'd be nice to have a callback when Linux wants to swap out. */
-
-/* We fault pages in, which allows us to update accessed/dirty bits.
- * Return true if we got page. */
+/*H:330
+ * (i) Setting up a page table entry for the Guest when it 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. */
int demand_page(struct lguest *lg, unsigned long vaddr, int errcode)
{
gpgd_t gpgd;
gpte_t gpte;
spte_t *spte;
+ /* First step: get the top-level Guest page table entry. */
gpgd = mkgpgd(lgread_u32(lg, gpgd_addr(lg, vaddr)));
+ /* Toplevel not present? We can't map it in. */
if (!(gpgd.flags & _PAGE_PRESENT))
return 0;
+ /* Now look at the matching shadow entry. */
spgd = spgd_addr(lg, lg->pgdidx, vaddr);
if (!(spgd->flags & _PAGE_PRESENT)) {
- /* Get a page of PTEs for them. */
+ /* No shadow entry: allocate a new shadow PTE page. */
unsigned long ptepage = get_zeroed_page(GFP_KERNEL);
- /* FIXME: Steal from self in this case? */
+ /* This is not really the Guest's fault, but killing it is
+ * simple for this corner case. */
if (!ptepage) {
kill_guest(lg, "out of memory allocating pte page");
return 0;
}
+ /* We check that the Guest pgd is OK. */
check_gpgd(lg, 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->raw.val = (__pa(ptepage) | gpgd.flags);
}
+ /* 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(lg, gpgd, vaddr);
gpte = mkgpte(lgread_u32(lg, gpte_ptr));
- /* No page? */
+ /* If this page isn't in the Guest page tables, we can't page it in. */
if (!(gpte.flags & _PAGE_PRESENT))
return 0;
- /* Write to read-only page? */
+ /* Check they're not trying to write to a page the Guest wants
+ * read-only (bit 2 of errcode == write). */
if ((errcode & 2) && !(gpte.flags & _PAGE_RW))
return 0;
- /* User access to a non-user page? */
+ /* User access to a kernel page? (bit 3 == user access) */
if ((errcode & 4) && !(gpte.flags & _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(lg, gpte);
+ /* Add the _PAGE_ACCESSED and (for a write) _PAGE_DIRTY flag */
gpte.flags |= _PAGE_ACCESSED;
if (errcode & 2)
gpte.flags |= _PAGE_DIRTY;
- /* We're done with the old pte. */
+ /* Get the pointer to the shadow PTE entry we're going to set. */
spte = spte_addr(lg, *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);
- /* We don't make it writable if this isn't a write: later
- * write will fault so we can set dirty bit in guest. */
+ /* If this is a write, we insist that the Guest page is writable (the
+ * final arg to gpte_to_spte()). */
if (gpte.flags & _PAGE_DIRTY)
*spte = gpte_to_spte(lg, 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 come back here when a write does actually ocur, so we can
+ * update the Guest's _PAGE_DIRTY flag. */
gpte_t ro_gpte = gpte;
ro_gpte.flags &= ~_PAGE_RW;
*spte = gpte_to_spte(lg, ro_gpte, 0);
}
- /* Now we update dirty/accessed on guest. */
+ /* Finally, we write the Guest PTE entry back: we've set the
+ * _PAGE_ACCESSED and maybe the _PAGE_DIRTY flags. */
lgwrite_u32(lg, gpte_ptr, gpte.raw.val);
+
+ /* We succeeded in mapping the page! */
return 1;
}
-/* This is much faster than the full demand_page logic. */
+/*H:360 (ii) Setting up the page table entry for the Guest stack.
+ *
+ * Remember pin_stack_pages() which makes sure the stack is mapped? It could
+ * simply call demand_page(), but as we've seen that logic is quite long, and
+ * usually the stack pages are already mapped anyway, so it's not required.
+ *
+ * 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 lguest *lg, unsigned long vaddr)
{
spgd_t *spgd;
unsigned long flags;
+ /* Look at the top level entry: is it present? */
spgd = spgd_addr(lg, lg->pgdidx, vaddr);
if (!(spgd->flags & _PAGE_PRESENT))
return 0;
+ /* Check the flags on the pte entry itself: it must be present and
+ * writable. */
flags = spte_addr(lg, *spgd, vaddr)->flags;
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 lguest *lg, unsigned long vaddr)
{
if (!page_writable(lg, vaddr) && !demand_page(lg, vaddr, 2))
kill_guest(lg, "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, spgd_t *spgd)
{
+ /* If the entry's not present, there's nothing to release. */
if (spgd->flags & _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). */
spte_t *ptepage = __va(spgd->pfn << PAGE_SHIFT);
+ /* For each entry in the page, we might need to release it. */
for (i = 0; i < PTES_PER_PAGE; i++)
release_pte(ptepage[i]);
+ /* Now we can free the page of PTEs */
free_page((long)ptepage);
+ /* And zero out the PGD entry we we never release it twice. */
spgd->raw.val = 0;
}
}
+/*H:440 (v) Flushing (thowing away) page tables,
+ *
+ * We saw flush_user_mappings() called when we re-used a top-level pgdir page.
+ * It simply releases every PTE page from 0 up to the 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 < vaddr_to_pgd_index(lg->page_offset); i++)
release_pgd(lg, lg->pgdirs[idx].pgdir + i);
}
+/* The Guest also has a hypercall to do this manually: it's used when a large
+ * number of mappings have been changed. */
void guest_pagetable_flush_user(struct lguest *lg)
{
+ /* Drop the userspace part of the current page table. */
flush_user_mappings(lg, lg->pgdidx);
}
+/*:*/
+/* 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;
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 lguest *lg,
unsigned long cr3,
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(lg->pgdirs);
+ /* If it's never been allocated at all before, try now. */
if (!lg->pgdirs[next].pgdir) {
lg->pgdirs[next].pgdir = (spgd_t *)get_zeroed_page(GFP_KERNEL);
+ /* If the allocation fails, just keep using the one we have */
if (!lg->pgdirs[next].pgdir)
next = lg->pgdidx;
else
- /* There are no mappings: you'll need to re-pin */
+ /* 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. */
lg->pgdirs[next].cr3 = cr3;
/* Release all the non-kernel mappings. */
flush_user_mappings(lg, next);
return next;
}
+/*H:430 (iv) Switching page tables
+ *
+ * This is what happens when the Guest changes page tables (ie. changes the
+ * top-level pgdir). This happens on almost every context switch. */
void guest_new_pagetable(struct lguest *lg, unsigned long pgtable)
{
int newpgdir, repin = 0;
+ /* Look to see if we have this one already. */
newpgdir = find_pgdir(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(lg->pgdirs))
newpgdir = new_pgdir(lg, pgtable, &repin);
+ /* Change the current pgd index to the new one. */
lg->pgdidx = newpgdir;
+ /* If it was completely blank, we map in the Guest kernel stack */
if (repin)
pin_stack_pages(lg);
}
+/*H:470 Finally, a routine which throws away everything: all PGD entries in all
+ * the shadow page tables. 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 is amazingly slow, but thankfully rare. */
void guest_pagetable_clear_all(struct lguest *lg)
{
release_all_pagetables(lg);
+ /* We need the Guest kernel stack mapped again. */
pin_stack_pages(lg);
}
+/*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 lguest *lg, int idx,
unsigned long vaddr, gpte_t gpte)
{
+ /* Look up the matching shadow page directot entry. */
spgd_t *spgd = spgd_addr(lg, idx, vaddr);
+
+ /* If the top level isn't present, there's no entry to update. */
if (spgd->flags & _PAGE_PRESENT) {
+ /* Otherwise, we start by releasing the existing entry. */
spte_t *spte = spte_addr(lg, *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 (gpte.flags & (_PAGE_DIRTY | _PAGE_ACCESSED)) {
check_gpte(lg, gpte);
*spte = gpte_to_spte(lg, gpte, gpte.flags&_PAGE_DIRTY);
} else
+ /* Otherwise we can demand_page() it in later. */
spte->raw.val = 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 copy keep
+ * all the kernel mappings. This speeds up context switch immensely. */
void guest_set_pte(struct lguest *lg,
unsigned long cr3, unsigned long vaddr, gpte_t gpte)
{
- /* Kernel mappings must be changed on all top levels. */
+ /* Kernel mappings must be changed on all top levels. Slow, but
+ * doesn't happen often. */
if (vaddr >= lg->page_offset) {
unsigned int i;
for (i = 0; i < ARRAY_SIZE(lg->pgdirs); i++)
if (lg->pgdirs[i].pgdir)
do_set_pte(lg, i, vaddr, gpte);
} else {
+ /* Is this page table one we have a shadow for? */
int pgdir = find_pgdir(lg, cr3);
if (pgdir != ARRAY_SIZE(lg->pgdirs))
+ /* If so, do the update. */
do_set_pte(lg, pgdir, vaddr, gpte);
}
}
+/*H:400
+ * (iii) Setting up a page table entry when the Guest tells us it 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 cr3, 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, cr3);
if (pgdir < ARRAY_SIZE(lg->pgdirs))
+ /* ... throw it away. */
release_pgd(lg, lg->pgdirs[pgdir].pgdir + idx);
}
+/*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, unsigned long pgtable)
{
- /* We assume this in flush_user_mappings, so check now */
+ /* In flush_user_mappings() we loop from 0 to
+ * "vaddr_to_pgd_index(lg->page_offset)". This assumes it won't hit
+ * the Switcher mappings, so check that now. */
if (vaddr_to_pgd_index(lg->page_offset) >= SWITCHER_PGD_INDEX)
return -EINVAL;
+ /* We start on the first shadow page table, and give it a blank PGD
+ * page. */
lg->pgdidx = 0;
lg->pgdirs[lg->pgdidx].cr3 = pgtable;
lg->pgdirs[lg->pgdidx].pgdir = (spgd_t*)get_zeroed_page(GFP_KERNEL);
return 0;
}
+/* 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);
}
-/* Caller must be preempt-safe */
+/*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 available to 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. */
void map_switcher_in_guest(struct lguest *lg, struct lguest_pages *pages)
{
spte_t *switcher_pte_page = __get_cpu_var(switcher_pte_pages);
spgd_t switcher_pgd;
spte_t regs_pte;
- /* Since switcher less that 4MB, we simply mug top pte page. */
+ /* Make the last PGD entry for this Guest point to the Switcher's PTE
+ * page for this CPU (with appropriate flags). */
switcher_pgd.pfn = __pa(switcher_pte_page) >> PAGE_SHIFT;
switcher_pgd.flags = _PAGE_KERNEL;
lg->pgdirs[lg->pgdidx].pgdir[SWITCHER_PGD_INDEX] = switcher_pgd;
- /* Map our regs page over stack page. */
+ /* 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. */
regs_pte.pfn = __pa(lg->regs_page) >> PAGE_SHIFT;
regs_pte.flags = _PAGE_KERNEL;
switcher_pte_page[(unsigned long)pages/PAGE_SIZE%PTES_PER_PAGE]
= regs_pte;
}
+/*:*/
static void free_switcher_pte_pages(void)
{
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;
spte_t *pte = switcher_pte_page(cpu);
+ /* The first entries are easy: they map the Switcher code. */
for (i = 0; i < pages; i++) {
pte[i].pfn = page_to_pfn(switcher_page[i]);
pte[i].flags = _PAGE_PRESENT|_PAGE_ACCESSED;
}
- /* We only map this CPU's pages, so guest can't see others. */
+ /* The only other thing we map is this CPU's pair of pages. */
i = pages + cpu*2;
- /* First page (regs) is rw, second (state) is ro. */
+ /* First page (Guest registers) is writable from the Guest */
pte[i].pfn = page_to_pfn(switcher_page[i]);
pte[i].flags = _PAGE_PRESENT|_PAGE_ACCESSED|_PAGE_RW;
+ /* The second page contains the "struct lguest_ro_state", and is
+ * read-only. */
pte[i+1].pfn = page_to_pfn(switcher_page[i+1]);
pte[i+1].flags = _PAGE_PRESENT|_PAGE_ACCESSED;
}
+/*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;
}
return 0;
}
+/*:*/
+/* Cleaning up simply involves freeing the PTE page for each CPU. */
void free_pagetables(void)
{
free_switcher_pte_pages();
* from frolicking through its parklike serenity. :*/
#include "lg.h"
+/*H:600
+ * We've almost completed the Host; there's just one file to go!
+ *
+ * Segments & The Global Descriptor Table
+ *
+ * (That title sounds like a bad Nerdcore group. Not to suggest that there are
+ * any good Nerdcore groups, but in high school a friend of mine had a band
+ * called Joe Fish and the Chips, so there are definitely worse band names).
+ *
+ * To refresh: the GDT is a table of 8-byte values describing segments. Once
+ * set up, these segments can be loaded into one of the 6 "segment registers".
+ *
+ * GDT entries are passed around as "struct desc_struct"s, which like IDT
+ * entries are split into two 32-bit members, "a" and "b". One day, someone
+ * will clean that up, and be declared a Hero. (No pressure, I'm just saying).
+ *
+ * Anyway, the GDT entry contains a base (the start address of the segment), a
+ * limit (the size of the segment - 1), and some flags. Sounds simple, and it
+ * would be, except those zany Intel engineers decided that it was too boring
+ * to put the base at one end, the limit at the other, and the flags in
+ * between. They decided to shotgun the bits at random throughout the 8 bytes,
+ * like so:
+ *
+ * 0 16 40 48 52 56 63
+ * [ limit part 1 ][ base part 1 ][ flags ][li][fl][base ]
+ * mit ags part 2
+ * part 2
+ *
+ * As a result, this file contains a certain amount of magic numeracy. Let's
+ * begin.
+ */
+
+/* Is the descriptor the Guest wants us to put in OK?
+ *
+ * The flag which Intel says must be zero: must be zero. The descriptor must
+ * be present, (this is actually checked earlier but is here for thorougness),
+ * and the descriptor type must be 1 (a memory segment). */
static int desc_ok(const struct desc_struct *gdt)
{
- /* MBZ=0, P=1, DT=1 */
return ((gdt->b & 0x00209000) == 0x00009000);
}
+/* Is the segment present? (Otherwise it can't be used by the Guest). */
static int segment_present(const struct desc_struct *gdt)
{
return gdt->b & 0x8000;
}
+/* There are several entries we don't let the Guest set. The TSS entry is the
+ * "Task State Segment" which controls all kinds of delicate things. The
+ * LGUEST_CS and LGUEST_DS entries are reserved for the Switcher, and the
+ * the Guest can't be trusted to deal with double faults. */
static int ignored_gdt(unsigned int num)
{
return (num == GDT_ENTRY_TSS
|| num == GDT_ENTRY_DOUBLEFAULT_TSS);
}
-/* We don't allow removal of CS, DS or SS; it doesn't make sense. */
+/* If the Guest asks us to remove an entry from the GDT, we have to be careful.
+ * If one of the segment registers is pointing at that entry the Switcher will
+ * crash when it tries to reload the segment registers for the Guest.
+ *
+ * It doesn't make much sense for the Guest to try to remove its own code, data
+ * or stack segments while they're in use: assume that's a Guest bug. If it's
+ * one of the lesser segment registers using the removed entry, we simply set
+ * that register to 0 (unusable). */
static void check_segment_use(struct lguest *lg, unsigned int desc)
{
+ /* GDT entries are 8 bytes long, so we divide to get the index and
+ * ignore the bottom bits. */
if (lg->regs->gs / 8 == desc)
lg->regs->gs = 0;
if (lg->regs->fs / 8 == desc)
kill_guest(lg, "Removed live GDT entry %u", desc);
}
+/*H:610 Once the GDT has been changed, we look through the changed entries and
+ * see if they're OK. If not, we'll call kill_guest() and the Guest will never
+ * get to use the invalid entries. */
static void fixup_gdt_table(struct lguest *lg, unsigned start, unsigned end)
{
unsigned int i;
for (i = start; i < end; i++) {
- /* We never copy these ones to real gdt */
+ /* We never copy these ones to real GDT, so we don't care what
+ * they say */
if (ignored_gdt(i))
continue;
if (!desc_ok(&lg->gdt[i]))
kill_guest(lg, "Bad GDT descriptor %i", i);
- /* DPL 0 presumably means "for use by guest". */
+ /* Segment descriptors contain a privilege level: the Guest is
+ * sometimes careless and leaves this as 0, even though it's
+ * running at privilege level 1. If so, we fix it here. */
if ((lg->gdt[i].b & 0x00006000) == 0)
lg->gdt[i].b |= (GUEST_PL << 13);
- /* Set accessed bit, since gdt isn't writable. */
+ /* Each descriptor has an "accessed" bit. If we don't set it
+ * now, the CPU will try to set it when the Guest first loads
+ * that entry into a segment register. But the GDT isn't
+ * writable by the Guest, so bad things can happen. */
lg->gdt[i].b |= 0x00000100;
}
}
+/* This routine is called at boot or modprobe time for each CPU to set up the
+ * "constant" GDT entries for Guests running on that CPU. */
void setup_default_gdt_entries(struct lguest_ro_state *state)
{
struct desc_struct *gdt = state->guest_gdt;
unsigned long tss = (unsigned long)&state->guest_tss;
- /* Hypervisor segments. */
+ /* The hypervisor segments are full 0-4G segments, privilege level 0 */
gdt[GDT_ENTRY_LGUEST_CS] = FULL_EXEC_SEGMENT;
gdt[GDT_ENTRY_LGUEST_DS] = FULL_SEGMENT;
- /* This is the one which we *cannot* copy from guest, since tss
- is depended on this lguest_ro_state, ie. this cpu. */
+ /* The TSS segment refers to the TSS entry for this CPU, so we cannot
+ * copy it from the Guest. Forgive the magic flags */
gdt[GDT_ENTRY_TSS].a = 0x00000067 | (tss << 16);
gdt[GDT_ENTRY_TSS].b = 0x00008900 | (tss & 0xFF000000)
| ((tss >> 16) & 0x000000FF);
}
+/* This routine is called before the Guest is run for the first time. */
void setup_guest_gdt(struct lguest *lg)
{
+ /* Start with full 0-4G segments... */
lg->gdt[GDT_ENTRY_KERNEL_CS] = FULL_EXEC_SEGMENT;
lg->gdt[GDT_ENTRY_KERNEL_DS] = FULL_SEGMENT;
+ /* ...except the Guest is allowed to use them, so set the privilege
+ * level appropriately in the flags. */
lg->gdt[GDT_ENTRY_KERNEL_CS].b |= (GUEST_PL << 13);
lg->gdt[GDT_ENTRY_KERNEL_DS].b |= (GUEST_PL << 13);
}
-/* This is a fast version for the common case where only the three TLS entries
- * have changed. */
+/* Like the IDT, we never simply use the GDT the Guest gives us. We set up the
+ * GDTs for each CPU, then we copy across the entries each time we want to run
+ * a different Guest on that CPU. */
+
+/* A partial GDT load, for the three "thead-local storage" entries. Otherwise
+ * it's just like load_guest_gdt(). So much, in fact, it would probably be
+ * neater to have a single hypercall to cover both. */
void copy_gdt_tls(const struct lguest *lg, struct desc_struct *gdt)
{
unsigned int i;
gdt[i] = lg->gdt[i];
}
+/* This is the full version */
void copy_gdt(const struct lguest *lg, struct desc_struct *gdt)
{
unsigned int i;
+ /* The default entries from setup_default_gdt_entries() are not
+ * replaced. See ignored_gdt() above. */
for (i = 0; i < GDT_ENTRIES; i++)
if (!ignored_gdt(i))
gdt[i] = lg->gdt[i];
}
+/* This is where the Guest asks us to load a new GDT (LHCALL_LOAD_GDT). */
void load_guest_gdt(struct lguest *lg, unsigned long table, u32 num)
{
+ /* We assume the Guest has the same number of GDT entries as the
+ * Host, otherwise we'd have to dynamically allocate the Guest GDT. */
if (num > ARRAY_SIZE(lg->gdt))
kill_guest(lg, "too many gdt entries %i", num);
+ /* We read the whole thing in, then fix it up. */
lgread(lg, lg->gdt, table, num * sizeof(lg->gdt[0]));
fixup_gdt_table(lg, 0, ARRAY_SIZE(lg->gdt));
+ /* Mark that the GDT changed so the core knows it has to copy it again,
+ * even if the Guest is run on the same CPU. */
lg->changed |= CHANGED_GDT;
}
fixup_gdt_table(lg, GDT_ENTRY_TLS_MIN, GDT_ENTRY_TLS_MAX+1);
lg->changed |= CHANGED_GDT_TLS;
}
+
+/*
+ * With this, we have finished the Host.
+ *
+ * Five of the seven parts of our task are complete. You have made it through
+ * the Bit of Despair (I think that's somewhere in the page table code,
+ * myself).
+ *
+ * Next, we examine "make Switcher". It's short, but intense.
+ */
git.openpandora.org / pandora-kernel.git / commitdiff