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crash/qemu-load.c
Dave Anderson fcd4a192d5 Maintain backwards-compatibility for "kvmdump" dumpfiles that were 
created by older development versions of KVM tools in which the
cpu version id was 12, but the cpu device headers did not contain
the additional XSAVE related fields.
(uobergfe@redhat.com)
2014-09-09 14:27:29 -04:00

1137 lines
25 KiB
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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 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;
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;
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;
}
if (ferror (fp) ||
(result->features & required_features) != required_features)
goto fail;
return result;
fail:
device_list_free (result);
free (result);
return NULL;
}
/*
* crash utility adaptation.
*/
#include "defs.h"
int
is_qemu_vm_file(char *filename)
{
struct libvirt_header header;
FILE *vmp;
int retval;
size_t items ATTRIBUTE_UNUSED;
char *xml;
if ((vmp = fopen(filename, "r")) == NULL) {
error(INFO, "%s: %s\n", filename, strerror(errno));
return FALSE;
}
retval = FALSE;
xml = NULL;
switch (get_be32(vmp))
{
case QEMU_VM_FILE_MAGIC:
retval = TRUE;
break;
case LIBVIRT_QEMU_VM_FILE_MAGIC:
rewind(vmp);
items = fread(&header.magic[0], sizeof(header), 1, vmp);
if (STRNEQ(header.magic, "LibvirtQemudSave")) {
if ((xml = (char *)malloc(header.xml_length))) {
items = fread(xml, header.xml_length, 1, vmp);
/*
* Parse here if necessary or desirable.
*/
} else
fseek(vmp, header.xml_length, SEEK_CUR);
if (get_be32(vmp) == QEMU_VM_FILE_MAGIC)
retval = TRUE;
}
break;
default:
retval = FALSE;
}
if (xml)
free(xml);
switch (retval)
{
case TRUE:
kvm->vmp = vmp;
kvm->vmfd = fileno(vmp);
break;
case FALSE:
fclose(vmp);
break;
}
return retval;
}
void
dump_qemu_header(FILE *out)
{
int i;
struct libvirt_header header;
char magic[4];
uint8_t c;
size_t items ATTRIBUTE_UNUSED;
rewind(kvm->vmp);
if (get_be32(kvm->vmp) == QEMU_VM_FILE_MAGIC) {
fprintf(out, "%s: QEMU_VM_FILE_MAGIC\n", pc->dumpfile);
return;
}
rewind(kvm->vmp);
items = fread(&header, sizeof(header), 1, kvm->vmp);
fprintf(out, "%s: libvirt_header:\n\n", pc->dumpfile);
fprintf(out, " magic: ");
for (i = 0; i < 16; i++)
fprintf(out, "%c", header.magic[i]);
fprintf(out, "\n");
fprintf(out, " version: %d\n", header.version);
fprintf(out, " xml_length: %d\n", header.xml_length);
fprintf(out, " was_running: %d\n", header.was_running);
fprintf(out, " padding: (not shown)\n\n");
for (i = 0; i < header.xml_length; i++) {
c = getc(kvm->vmp);
if (c)
fprintf(out, "%c", c);
}
fprintf(out, "\n");
items = fread(&magic, sizeof(char), 4, kvm->vmp);
for (i = 0; i < 4; i++)
fprintf(out, "%c", magic[i]);
fprintf(out, "\n");
}
static long
device_search(const struct qemu_device_loader *devices, FILE *fp)
{
uint sz;
char *p1, *p2;
long next_device_offset;
long remaining;
char buf[4096];
off_t current;
BZERO(buf, 4096);
current = ftello(fp);
if (fread(buf, sizeof(char), 4096, fp) != 4096) {
fseeko(fp, current, SEEK_SET);
return 0;
}
fseeko(fp, current, SEEK_SET);
while (devices->name) {
for (p1 = buf, remaining = 4096;
(p2 = memchr(p1, devices->name[0], remaining));
p1 = p2+1, remaining = 4096 - (p1-buf)) {
sz = *((unsigned char *)p2-1);
if (STRNEQ(p2, devices->name) &&
(strlen(devices->name) == sz)) {
*(p2+sz) = '\0';
dprintf("device_search: %s\n", p2);
next_device_offset = (p2-buf) - 6;
return next_device_offset;
}
}
devices++;
}
return 0;
}
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