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qemu-load.c
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qemu-load.c
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/*
* Qemu save VM loader
*
* Copyright (C) 2009, 2010, 2011 Red Hat, Inc.
* Written by Paolo Bonzini.
*
* Portions Copyright (C) 2009 David Anderson
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*/
#define _GNU_SOURCE
#include "qemu-load.h"
#include <stdlib.h>
#include <string.h>
#include <assert.h>
#include <sys/mman.h>
#include "kvmdump.h"
struct qemu_device *
device_alloc (struct qemu_device_list *dl, size_t sz,
struct qemu_device_vtbl *vtbl,
uint32_t section_id, uint32_t instance_id, uint32_t version_id)
{
struct qemu_device *d = calloc (1, sz);
d->vtbl = vtbl;
d->list = dl;
d->section_id = section_id;
d->instance_id = instance_id;
d->version_id = version_id;
if (!dl->head)
dl->head = dl->tail = d;
else {
dl->tail->next = d;
d->prev = dl->tail;
dl->tail = d;
}
return d;
}
struct qemu_device *
device_find (struct qemu_device_list *dl, uint32_t section_id)
{
struct qemu_device *d;
d = dl->head;
while (d && d->section_id != section_id)
d = d->next;
return d;
}
struct qemu_device *
device_find_instance (struct qemu_device_list *dl, const char *name,
uint32_t instance_id)
{
struct qemu_device *d;
d = dl->head;
while (d && (strcmp (d->vtbl->name, name) || d->instance_id != instance_id))
d = d->next;
return d;
}
void
device_free (struct qemu_device *d)
{
struct qemu_device_list *dl = d->list;
if (d->prev)
d->prev->next = d->next;
else
dl->head = d->next;
if (d->next)
d->next->prev = d->prev;
else
dl->tail = d->prev;
d->prev = d->next = NULL;
if (d->vtbl->free)
d->vtbl->free (d, dl);
}
void
device_list_free (struct qemu_device_list *l)
{
if (!l)
return;
while (l->head)
device_free (l->head);
}
/* File access. */
static inline uint16_t
get_be16 (FILE *fp)
{
uint8_t a = getc (fp);
uint8_t b = getc (fp);
return (a << 8) | b;
}
static inline uint16_t
get_le16 (FILE *fp)
{
uint8_t b = getc (fp);
uint8_t a = getc (fp);
return (a << 8) | b;
}
static inline uint32_t
get_be32 (FILE *fp)
{
uint16_t a = get_be16 (fp);
uint16_t b = get_be16 (fp);
return (a << 16) | b;
}
static inline uint32_t
get_le32 (FILE *fp)
{
uint16_t b = get_le16 (fp);
uint16_t a = get_le16 (fp);
return (a << 16) | b;
}
static inline uint64_t
get_be64 (FILE *fp)
{
uint32_t a = get_be32 (fp);
uint32_t b = get_be32 (fp);
return ((uint64_t)a << 32) | b;
}
static inline uint64_t
get_le64 (FILE *fp)
{
uint32_t b = get_le32 (fp);
uint32_t a = get_le32 (fp);
return ((uint64_t)a << 32) | b;
}
static inline void
get_qemu128 (FILE *fp, union qemu_uint128_t *result)
{
result->i[1] = get_le32 (fp);
result->i[0] = get_le32 (fp);
result->i[3] = get_le32 (fp);
result->i[2] = get_le32 (fp);
}
/* RAM loader. */
#define RAM_SAVE_FLAG_FULL 0x01
#define RAM_SAVE_FLAG_COMPRESS 0x02
#define RAM_SAVE_FLAG_MEM_SIZE 0x04
#define RAM_SAVE_FLAG_PAGE 0x08
#define RAM_SAVE_FLAG_EOS 0x10
#define RAM_SAVE_FLAG_CONTINUE 0x20
#define RAM_SAVE_ADDR_MASK (~4095LL)
#define RAM_OFFSET_COMPRESSED (~(off_t)255)
static void
ram_alloc (struct qemu_device_ram *dram, uint64_t size)
{
// size_t old_npages = dram->offsets ? 0 : dram->last_ram_offset / 4096;
// size_t new_npages = size / 4096;
// assert (size <= SIZE_MAX);
// if (dram->offsets)
// dram->offsets = realloc (dram->offsets,
// new_npages * sizeof (off_t));
// else
// dram->offsets = malloc (new_npages * sizeof (off_t));
//
// assert (dram->offsets);
// while (old_npages < new_npages)
// dram->offsets[old_npages++] = RAM_OFFSET_COMPRESSED | 0;
dram->last_ram_offset = size;
}
#ifndef ATTRIBUTE_UNUSED
#define ATTRIBUTE_UNUSED __attribute__ ((__unused__))
#endif
static int
get_string (FILE *fp, char *name)
{
size_t items ATTRIBUTE_UNUSED;
int sz = (uint8_t) getc (fp);
if (sz == EOF)
return -1;
items = fread (name, sz, 1, fp);
name[sz] = 0;
return sz;
}
static int
get_string_len (FILE *fp, char *name, uint32_t sz)
{
size_t items ATTRIBUTE_UNUSED;
if (sz == EOF)
return -1;
items = fread (name, sz, 1, fp);
name[sz] = 0;
return sz;
}
static void
ram_read_blocks (FILE *fp, uint64_t size)
{
char name[257];
/* The RAM block table is a list of block names followed by
their sizes. Read it until the sizes sum up to SIZE bytes. */
while (size) {
get_string (fp, name);
size -= get_be64 (fp);
}
}
static uint32_t
ram_load (struct qemu_device *d, FILE *fp, enum qemu_save_section sec)
{
char name[257];
struct qemu_device_ram *dram = (struct qemu_device_ram *)d;
uint64_t header;
static int pc_ram = 0;
for (;;) {
uint64_t addr;
off_t entry;
header = get_be64 (fp);
if (feof (fp) || ferror (fp))
return 0;
if (header & RAM_SAVE_FLAG_EOS)
break;
assert (!(header & RAM_SAVE_FLAG_FULL));
addr = header & RAM_SAVE_ADDR_MASK;
if (header & RAM_SAVE_FLAG_MEM_SIZE) {
ram_alloc (dram, addr);
if (d->version_id >= 4)
ram_read_blocks(fp, addr);
continue;
}
if (d->version_id >= 4 && !(header & RAM_SAVE_FLAG_CONTINUE)) {
get_string(fp, name);
if (strcmp(name, "pc.ram") == 0)
pc_ram = 1;
else
pc_ram = 0;
}
if (header & RAM_SAVE_FLAG_COMPRESS) {
entry = RAM_OFFSET_COMPRESSED | getc(fp);
if ((d->version_id == 3) ||
(d->version_id >= 4 && pc_ram))
store_mapfile_offset(addr, &entry);
}
else if (header & RAM_SAVE_FLAG_PAGE) {
entry = ftell(fp);
if ((d->version_id == 3) ||
(d->version_id >= 4 && pc_ram))
store_mapfile_offset(addr, &entry);
fseek (fp, 4096, SEEK_CUR);
}
}
dram->fp = fp;
return QEMU_FEATURE_RAM;
}
static void
ram_free (struct qemu_device *d, struct qemu_device_list *dl)
{
struct qemu_device_ram *dram = (struct qemu_device_ram *)d;
free (dram->offsets);
}
int
ram_read_phys_page (struct qemu_device_ram *dram, void *buf, uint64_t addr)
{
off_t ofs;
ssize_t bytes ATTRIBUTE_UNUSED;
if (addr >= dram->last_ram_offset)
return false;
assert ((addr & 0xfff) == 0);
// ofs = dram->offsets[addr / 4096];
if (load_mapfile_offset(addr, &ofs) < 0)
return 0;
if ((ofs & RAM_OFFSET_COMPRESSED) == RAM_OFFSET_COMPRESSED)
memset (buf, ofs & 255, 4096);
else
bytes = pread (fileno (dram->fp), buf, 4096, ofs);
return true;
}
static struct qemu_device *
ram_init_load (struct qemu_device_list *dl,
uint32_t section_id, uint32_t instance_id,
uint32_t version_id, bool live, FILE *fp)
{
static struct qemu_device_vtbl ram = {
"ram",
ram_load,
ram_free
};
assert (version_id == 3 || version_id == 4);
kvm->mapinfo.ram_version_id = version_id;
return device_alloc (dl, sizeof (struct qemu_device_ram),
&ram, section_id, instance_id, version_id);
}
#define BLK_MIG_FLAG_EOS 2
static uint32_t
block_load (struct qemu_device *d, FILE *fp, enum qemu_save_section sec)
{
uint64_t header;
header = get_be64 (fp);
assert (header == BLK_MIG_FLAG_EOS);
return 0;
}
static struct qemu_device *
block_init_load (struct qemu_device_list *dl,
uint32_t section_id, uint32_t instance_id,
uint32_t version_id, bool live, FILE *fp)
{
static struct qemu_device_vtbl block = {
"block",
block_load,
NULL
};
return device_alloc (dl, sizeof (struct qemu_device),
&block, section_id, instance_id, version_id);
}
/* RHEL5 marker. */
static uint32_t
rhel5_marker_load (struct qemu_device *d, FILE *fp, enum qemu_save_section sec)
{
return 0;
}
static struct qemu_device *
rhel5_marker_init_load (struct qemu_device_list *dl,
uint32_t section_id, uint32_t instance_id,
uint32_t version_id, bool live, FILE *fp)
{
static struct qemu_device_vtbl rhel5_marker = {
"__rhel5",
rhel5_marker_load,
NULL
};
assert (!live);
return device_alloc (dl, sizeof (struct qemu_device),
&rhel5_marker, section_id, instance_id,
version_id);
}
/* cpu_common loader. */
struct qemu_device_cpu_common {
struct qemu_device base;
uint32_t halted;
uint32_t irq;
};
static uint32_t
cpu_common_load (struct qemu_device *d, FILE *fp, enum qemu_save_section sec)
{
struct qemu_device_cpu_common *cpu = (struct qemu_device_cpu_common *)d;
cpu->halted = get_be32 (fp);
cpu->irq = get_be32 (fp);
return 0;
}
static struct qemu_device *
cpu_common_init_load (struct qemu_device_list *dl,
uint32_t section_id, uint32_t instance_id,
uint32_t version_id, bool live, FILE *fp)
{
static struct qemu_device_vtbl cpu_common = {
"cpu_common",
cpu_common_load,
NULL
};
assert (!live);
return device_alloc (dl, sizeof (struct qemu_device_cpu_common),
&cpu_common, section_id, instance_id, version_id);
}
/* CPU loader. */
static inline uint64_t
get_be_long (FILE *fp, int size)
{
uint32_t a = size == 32 ? 0 : get_be32 (fp);
uint32_t b = get_be32 (fp);
return ((uint64_t)a << 32) | b;
}
static inline void
get_be_fp80 (FILE *fp, union qemu_fpu_reg *result)
{
result->mmx = get_be64 (fp);
result->bytes[9] = getc (fp);
result->bytes[8] = getc (fp);
}
static void
cpu_load_seg (FILE *fp, struct qemu_x86_seg *seg, int size)
{
seg->selector = get_be32 (fp);
seg->base = get_be_long (fp, size);
seg->limit = get_be32 (fp);
seg->flags = get_be32 (fp);
}
static bool
v12_has_xsave_state(FILE *fp)
{
char name[257];
bool ret = true;
long offset = ftell(fp); // save offset
/*
* peek into byte stream to check for APIC vmstate
*/
if (getc(fp) == QEMU_VM_SECTION_FULL) {
get_be32(fp); // skip section id
get_string(fp, name);
if (strcmp(name, "apic") == 0)
ret = false;
}
fseek(fp, offset, SEEK_SET); // restore offset
return ret;
}
static uint32_t
cpu_load (struct qemu_device *d, FILE *fp, int size)
{
struct qemu_device_x86 *dx86 = (struct qemu_device_x86 *)d;
uint32_t qemu_hflags = 0, qemu_hflags2 = 0;
int nregs;
uint32_t version_id = dx86->dev_base.version_id;
uint32_t rhel5_version_id;
int i;
off_t restart;
struct qemu_device *drhel5;
struct qemu_device_cpu_common *dcpu;
if (kvm->flags & KVMHOST_32)
size = 32;
restart = ftello(fp);
retry:
nregs = size == 32 ? 8 : 16;
drhel5 = device_find_instance (d->list, "__rhel5", 0);
if (drhel5 || (version_id >= 7 && version_id <= 9)) {
rhel5_version_id = version_id;
version_id = 7;
} else {
rhel5_version_id = 0;
version_id = dx86->dev_base.version_id;
}
dprintf("cpu_load: rhel5_version_id: %d (effective) version_id: %d\n",
rhel5_version_id, version_id);
dcpu = (struct qemu_device_cpu_common *)
device_find_instance (d->list, "cpu_common", d->instance_id);
if (dcpu) {
dx86->halted = dcpu->halted;
dx86->irq = dcpu->irq;
// device_free ((struct qemu_device *) dcpu);
}
for (i = 0; i < nregs; i++)
dx86->regs[i] = get_be_long (fp, size);
dx86->eip = get_be_long (fp, size);
dx86->eflags = get_be_long (fp, size);
qemu_hflags = get_be32 (fp);
dx86->fpucw = get_be16 (fp);
dx86->fpusw = get_be16 (fp);
dx86->fpu_free = get_be16 (fp);
if (get_be16 (fp))
for (i = 0; i < 8; i++)
dx86->st[i].mmx = get_be64 (fp);
else
for (i = 0; i < 8; i++)
get_be_fp80 (fp, &dx86->st[i]);
cpu_load_seg (fp, &dx86->es, size);
cpu_load_seg (fp, &dx86->cs, size);
cpu_load_seg (fp, &dx86->ss, size);
cpu_load_seg (fp, &dx86->ds, size);
cpu_load_seg (fp, &dx86->fs, size);
cpu_load_seg (fp, &dx86->gs, size);
cpu_load_seg (fp, &dx86->ldt, size);
cpu_load_seg (fp, &dx86->tr, size);
cpu_load_seg (fp, &dx86->gdt, size);
cpu_load_seg (fp, &dx86->idt, size);
dx86->sysenter.cs = get_be32 (fp);
dx86->sysenter.esp = get_be_long (fp, version_id <= 6 ? 32 : size);
dx86->sysenter.eip = get_be_long (fp, version_id <= 6 ? 32 : size);
dx86->cr0 = get_be_long (fp, size);
dx86->cr2 = get_be_long (fp, size);
dx86->cr3 = get_be_long (fp, size);
dx86->cr4 = get_be_long (fp, size);
for (i = 0; i < 8; i++)
dx86->dr[i] = get_be_long (fp, size);
dx86->a20_masked = get_be32 (fp) != 0xffffffff;
dx86->mxcsr = get_be32 (fp);
for (i = 0; i < nregs; i++)
get_qemu128 (fp, &dx86->xmm[i]);
if (size == 64) {
dx86->efer = get_be64 (fp);
dx86->star = get_be64 (fp);
dx86->lstar = get_be64 (fp);
dx86->cstar = get_be64 (fp);
dx86->fmask = get_be64 (fp);
dx86->kernel_gs_base = get_be64 (fp);
}
dx86->smbase = get_be32 (fp);
dx86->soft_mmu = qemu_hflags & (1 << 2);
dx86->smm = qemu_hflags & (1 << 19);
if (version_id == 4)
goto store;
dx86->pat = get_be64 (fp);
qemu_hflags2 = get_be32 (fp);
dx86->global_if = qemu_hflags2 & (1 << 0);
dx86->in_nmi = qemu_hflags2 & (1 << 2);
if (version_id < 6)
dx86->halted = get_be32 (fp);
dx86->svm.hsave = get_be64 (fp);
dx86->svm.vmcb = get_be64 (fp);
dx86->svm.tsc_offset = get_be64 (fp);
dx86->svm.in_vmm = qemu_hflags & (1 << 21);
dx86->svm.guest_if_mask = qemu_hflags2 & (1 << 1);
dx86->svm.guest_intr_masking = qemu_hflags2 & (1 << 3);
dx86->svm.intercept_mask = get_be64 (fp);
dx86->svm.cr_read_mask = get_be16 (fp);
dx86->svm.cr_write_mask = get_be16 (fp);
dx86->svm.dr_read_mask = get_be16 (fp);
dx86->svm.dr_write_mask = get_be16 (fp);
dx86->svm.exception_intercept_mask = get_be32 (fp);
dx86->cr8 = getc (fp);
if (version_id >= 8) {
for (i = 0; i < 11; i++)
dx86->fixed_mtrr[i] = get_be64 (fp);
dx86->deftype_mtrr = get_be64 (fp);
for (i = 0; i < 8; i++) {
dx86->variable_mtrr[i].base = get_be64 (fp);
dx86->variable_mtrr[i].mask = get_be64 (fp);
}
}
/* This was present only when KVM was enabled up to v8.
* Furthermore, it changed format in v9. */
if (version_id >= 9) {
int32_t pending_irq = (int32_t) get_be32 (fp);
if (pending_irq >= 0 && pending_irq <= 255)
dx86->kvm.int_bitmap[pending_irq / 64] |=
(uint64_t)1 << (pending_irq & 63);
dx86->kvm.mp_state = get_be32 (fp);
dx86->kvm.tsc = get_be64 (fp);
}
else if (d->list->features & QEMU_FEATURE_KVM) {
for (i = 0; i < 4; i++)
dx86->kvm.int_bitmap[i] = get_be64 (fp);
dx86->kvm.tsc = get_be64 (fp);
if (version_id >= 5)
dx86->kvm.mp_state = get_be32 (fp);
}
if (version_id >= 11) {
dx86->kvm.exception_injected = get_be32 (fp);
}
if (rhel5_version_id >= 8) {
dx86->kvm.system_time_msr = get_be64 (fp);
dx86->kvm.wall_clock_msr = get_be64 (fp);
}
if (version_id >= 11 || rhel5_version_id >= 9) {
dx86->kvm.soft_interrupt = getc (fp);
dx86->kvm.nmi_injected = getc (fp);
dx86->kvm.nmi_pending = getc (fp);
dx86->kvm.has_error_code = getc (fp);
dx86->kvm.sipi_vector = get_be32 (fp);
}
if (version_id >= 10) {
dx86->mce.mcg_cap = get_be64 (fp);
dx86->mce.mcg_status = get_be64 (fp);
dx86->mce.mcg_ctl = get_be64 (fp);
for (i = 0; i < 10 * 4; i++)
dx86->mce.mce_banks[i] = get_be64 (fp);
}
if (version_id >= 11) {
dx86->tsc_aux = get_be64 (fp);
dx86->kvm.system_time_msr = get_be64 (fp);
dx86->kvm.wall_clock_msr = get_be64 (fp);
}
if (version_id >= 12 && v12_has_xsave_state(fp)) {
dx86->xcr0 = get_be64 (fp);
dx86->xstate_bv = get_be64 (fp);
for (i = 0; i < nregs; i++)
get_qemu128 (fp, &dx86->ymmh_regs[i]);
}
store:
if (!kvmdump_regs_store(d->instance_id, dx86)) {
size = 32;
kvm->flags |= KVMHOST_32;
fseeko(fp, restart, SEEK_SET);
dprintf("cpu_load: invalid registers: retry with 32-bit host\n");
goto retry;
}
if (dcpu)
device_free ((struct qemu_device *) dcpu);
return QEMU_FEATURE_CPU;
}
static uint32_t
cpu_load_32 (struct qemu_device *d, FILE *fp, enum qemu_save_section sec)
{
return cpu_load (d, fp, 32);
}
static struct qemu_device *
cpu_init_load_32 (struct qemu_device_list *dl,
uint32_t section_id, uint32_t instance_id,
uint32_t version_id, bool live, FILE *fp)
{
struct qemu_device_x86 *dx86;
static struct qemu_device_vtbl cpu = {
"cpu",
cpu_load_32,
NULL
};
assert (!live);
// assert (version_id >= 4 && version_id <= 9);
assert (version_id >= 4 && version_id <= 12);
kvm->mapinfo.cpu_version_id = version_id;
dx86 = (struct qemu_device_x86 *)
device_alloc (dl, sizeof (struct qemu_device_x86),
&cpu, section_id, instance_id, version_id);
return (struct qemu_device *) dx86;
}
static uint32_t
cpu_load_64 (struct qemu_device *d, FILE *fp, enum qemu_save_section sec)
{
return cpu_load (d, fp, 64);
}
static struct qemu_device *
cpu_init_load_64 (struct qemu_device_list *dl,
uint32_t section_id, uint32_t instance_id,
uint32_t version_id, bool live, FILE *fp)
{
struct qemu_device_x86 *dx86;
static struct qemu_device_vtbl cpu = {
"cpu",
cpu_load_64,
NULL
};
assert (!live);
// assert (version_id >= 4 && version_id <= 9);
assert (version_id >= 4 && version_id <= 12);
kvm->mapinfo.cpu_version_id = version_id;
dx86 = (struct qemu_device_x86 *)
device_alloc (dl, sizeof (struct qemu_device_x86),
&cpu, section_id, instance_id, version_id);
return (struct qemu_device *) dx86;
}
/* IOAPIC loader. */
static uint32_t
apic_load (struct qemu_device *d, FILE *fp, enum qemu_save_section sec)
{
switch (d->version_id) {
case 1: fseek (fp, 173, SEEK_CUR); break;
case 2:
case 3: fseek (fp, 181, SEEK_CUR); break;
}
return 0;
}
static struct qemu_device *
apic_init_load (struct qemu_device_list *dl,
uint32_t section_id, uint32_t instance_id,
uint32_t version_id, bool live, FILE *fp)
{
static struct qemu_device_vtbl apic = {
"apic",
apic_load,
NULL
};
assert (!live);
return device_alloc (dl, sizeof (struct qemu_device),
&apic, section_id, instance_id, version_id);
}
/* timer loader. */
static uint32_t
timer_load (struct qemu_device *d, FILE *fp, enum qemu_save_section sec)
{
fseek (fp, 24, SEEK_CUR);
return QEMU_FEATURE_TIMER;
}
static struct qemu_device *
timer_init_load (struct qemu_device_list *dl,
uint32_t section_id, uint32_t instance_id,
uint32_t version_id, bool live, FILE *fp)
{
static struct qemu_device_vtbl timer = {
"timer",
timer_load,
NULL
};
assert (!live);
return device_alloc (dl, sizeof (struct qemu_device),
&timer, section_id, instance_id, version_id);
}
/* kvmclock loader. */
static uint32_t
kvmclock_load (struct qemu_device *d, FILE *fp, enum qemu_save_section sec)
{
fseek (fp, 8, SEEK_CUR);
return QEMU_FEATURE_KVM;
}
static struct qemu_device *
kvmclock_init_load (struct qemu_device_list *dl,
uint32_t section_id, uint32_t instance_id,
uint32_t version_id, bool live, FILE *fp)
{
static struct qemu_device_vtbl kvmclock = {
"kvmclock",
kvmclock_load,
NULL
};
assert (!live);
return device_alloc (dl, sizeof (struct qemu_device),
&kvmclock, section_id, instance_id, version_id);
}
/* kvm-tpr-opt loader. */
static uint32_t
kvm_tpr_opt_load (struct qemu_device *d, FILE *fp, enum qemu_save_section sec)
{
fseek (fp, 144, SEEK_CUR);
return QEMU_FEATURE_KVM;
}
static struct qemu_device *
kvm_tpr_opt_init_load (struct qemu_device_list *dl,
uint32_t section_id, uint32_t instance_id,
uint32_t version_id, bool live, FILE *fp)
{
static struct qemu_device_vtbl kvm_tpr_opt = {
"kvm-tpr-opt",
kvm_tpr_opt_load,
NULL
};
assert (!live);
return device_alloc (dl, sizeof (struct qemu_device),
&kvm_tpr_opt, section_id, instance_id, version_id);
}
/* Putting it together. */
const struct qemu_device_loader devices_x86_64[] = {
{ "__rhel5", rhel5_marker_init_load },
{ "cpu_common", cpu_common_init_load },
{ "kvm-tpr-opt", kvm_tpr_opt_init_load },
{ "kvmclock", kvmclock_init_load },
{ "cpu", cpu_init_load_64 },
{ "apic", apic_init_load },
{ "block", block_init_load },
{ "ram", ram_init_load },
{ "timer", timer_init_load },
{ NULL, NULL }
};
const struct qemu_device_loader devices_x86_32[] = {
{ "__rhel5", rhel5_marker_init_load },
{ "cpu_common", cpu_common_init_load },
{ "kvm-tpr-opt", kvm_tpr_opt_init_load },
{ "kvmclock", kvmclock_init_load },
{ "cpu", cpu_init_load_32 },
{ "apic", apic_init_load },
{ "block", block_init_load },
{ "ram", ram_init_load },
{ "timer", timer_init_load },
{ NULL, NULL }
};
#define QEMU_VM_FILE_MAGIC 0x5145564D
#define LIBVIRT_QEMU_VM_FILE_MAGIC 0x4c696276
struct libvirt_header {
char magic[16];
uint32_t version;
uint32_t xml_length;
uint32_t was_running;
uint32_t padding[16];
};
static long device_search(const struct qemu_device_loader *, FILE *);
static struct qemu_device *
device_get (const struct qemu_device_loader *devices,
struct qemu_device_list *dl, enum qemu_save_section sec, FILE *fp)
{
char name[257];
uint32_t section_id, instance_id, version_id;
// bool live;
const struct qemu_device_loader *devp;
long next_device_offset;
next_device:
devp = devices;
if (sec == QEMU_VM_SUBSECTION) {
get_string(fp, name);
goto search_device;
}
section_id = get_be32 (fp);
if (sec != QEMU_VM_SECTION_START &&
sec != QEMU_VM_SECTION_FULL)
return device_find (dl, section_id);
get_string(fp, name);
instance_id = get_be32 (fp);
version_id = get_be32 (fp);
while (devp->name && strcmp (devp->name, name))
devp++;
if (!devp->name) {
search_device:
dprintf("device_get: unknown/unsupported: \"%s\"\n", name);
if ((next_device_offset = device_search(devices, fp))) {
fseek(fp, next_device_offset, SEEK_CUR);
sec = getc(fp);
if (sec == QEMU_VM_EOF)
return NULL;
goto next_device;
}
return NULL;
}
return devp->init_load (dl, section_id, instance_id, version_id,
sec == QEMU_VM_SECTION_START, fp);
}
struct qemu_device_list *
qemu_load (const struct qemu_device_loader *devices, uint32_t required_features,
FILE *fp)
{
struct qemu_device_list *result = NULL;
struct qemu_device *last = NULL;;
size_t items ATTRIBUTE_UNUSED;
uint32_t footerSecId ATTRIBUTE_UNUSED;
char name[257];
switch (get_be32 (fp)) {
case QEMU_VM_FILE_MAGIC:
break;
case LIBVIRT_QEMU_VM_FILE_MAGIC: {
struct libvirt_header header;
memcpy (header.magic, "Libv", 4);
items = fread (&header.magic[4], sizeof (header) - 4, 1, fp);
if (memcmp ("LibvirtQemudSave", header.magic, 16))
goto fail;
fseek (fp, header.xml_length, SEEK_CUR);
if (get_be32 (fp) != QEMU_VM_FILE_MAGIC)
goto fail;
break;
}
default:
goto fail;
}
if (get_be32 (fp) != 3)
return NULL;
dprintf("\n");
result = calloc (1, sizeof (struct qemu_device_list));
for (;;) {
struct qemu_device *d;
uint32_t features;
enum qemu_save_section sec = getc (fp);
if (feof (fp) || ferror (fp))
break;
if (sec == QEMU_VM_EOF)
break;
if (sec == QEMU_VM_SECTION_FOOTER) {
footerSecId = get_be32 (fp);
continue;
}
if (sec == QEMU_VM_CONFIGURATION) {
uint32_t len = get_be32 (fp);
get_string_len (fp, name, len);
continue;
}
d = device_get (devices, result, sec, fp);
if (!d)
break;
if (d != last) {
dprintf("qemu_load: \"%s\"\n", d->vtbl->name);
last = d;
}
features = d->vtbl->load (d, fp, sec);
if (feof (fp) || ferror (fp))
break;
if (sec == QEMU_VM_SECTION_END || sec == QEMU_VM_SECTION_FULL)
result->features |= features;