qemu/contrib/elf2dmp/main.c
Viktor Prutyanov 06164cc402 contrib/elf2dmp: add kernel start address checking
Before this patch, if elf2dmp failed to find NT kernel PE magic in
allowed virtual address range, then it assumes NULL as NT kernel
address and cause segfault.

This patch fix the problem described above by checking NT kernel address
before futher processing.

Signed-off-by: Viktor Prutyanov <viktor.prutyanov@phystech.edu>
Message-Id: <20190219211936.6466-1-viktor.prutyanov@phystech.edu>
Signed-off-by: Paolo Bonzini <pbonzini@redhat.com>
2019-03-11 16:33:49 +01:00

599 lines
16 KiB
C

/*
* Copyright (c) 2018 Virtuozzo International GmbH
*
* This work is licensed under the terms of the GNU GPL, version 2 or later.
*
*/
#include <inttypes.h>
#include "qemu/osdep.h"
#include "err.h"
#include "addrspace.h"
#include "pe.h"
#include "pdb.h"
#include "kdbg.h"
#include "download.h"
#include "qemu/win_dump_defs.h"
#define SYM_URL_BASE "https://msdl.microsoft.com/download/symbols/"
#define PDB_NAME "ntkrnlmp.pdb"
#define INITIAL_MXCSR 0x1f80
typedef struct idt_desc {
uint16_t offset1; /* offset bits 0..15 */
uint16_t selector;
uint8_t ist;
uint8_t type_attr;
uint16_t offset2; /* offset bits 16..31 */
uint32_t offset3; /* offset bits 32..63 */
uint32_t rsrvd;
} __attribute__ ((packed)) idt_desc_t;
static uint64_t idt_desc_addr(idt_desc_t desc)
{
return (uint64_t)desc.offset1 | ((uint64_t)desc.offset2 << 16) |
((uint64_t)desc.offset3 << 32);
}
static const uint64_t SharedUserData = 0xfffff78000000000;
#define KUSD_OFFSET_SUITE_MASK 0x2d0
#define KUSD_OFFSET_PRODUCT_TYPE 0x264
#define SYM_RESOLVE(base, r, s) ((s = pdb_resolve(base, r, #s)),\
s ? printf(#s" = 0x%016"PRIx64"\n", s) :\
eprintf("Failed to resolve "#s"\n"), s)
static uint64_t rol(uint64_t x, uint64_t y)
{
return (x << y) | (x >> (64 - y));
}
/*
* Decoding algorithm can be found in Volatility project
*/
static void kdbg_decode(uint64_t *dst, uint64_t *src, size_t size,
uint64_t kwn, uint64_t kwa, uint64_t kdbe)
{
size_t i;
assert(size % sizeof(uint64_t) == 0);
for (i = 0; i < size / sizeof(uint64_t); i++) {
uint64_t block;
block = src[i];
block = rol(block ^ kwn, (uint8_t)kwn);
block = __builtin_bswap64(block ^ kdbe) ^ kwa;
dst[i] = block;
}
}
static KDDEBUGGER_DATA64 *get_kdbg(uint64_t KernBase, struct pdb_reader *pdb,
struct va_space *vs, uint64_t KdDebuggerDataBlock)
{
const char OwnerTag[4] = "KDBG";
KDDEBUGGER_DATA64 *kdbg = NULL;
DBGKD_DEBUG_DATA_HEADER64 kdbg_hdr;
bool decode = false;
uint64_t kwn, kwa, KdpDataBlockEncoded;
if (va_space_rw(vs,
KdDebuggerDataBlock + offsetof(KDDEBUGGER_DATA64, Header),
&kdbg_hdr, sizeof(kdbg_hdr), 0)) {
eprintf("Failed to extract KDBG header\n");
return NULL;
}
if (memcmp(&kdbg_hdr.OwnerTag, OwnerTag, sizeof(OwnerTag))) {
uint64_t KiWaitNever, KiWaitAlways;
decode = true;
if (!SYM_RESOLVE(KernBase, pdb, KiWaitNever) ||
!SYM_RESOLVE(KernBase, pdb, KiWaitAlways) ||
!SYM_RESOLVE(KernBase, pdb, KdpDataBlockEncoded)) {
return NULL;
}
if (va_space_rw(vs, KiWaitNever, &kwn, sizeof(kwn), 0) ||
va_space_rw(vs, KiWaitAlways, &kwa, sizeof(kwa), 0)) {
return NULL;
}
printf("[KiWaitNever] = 0x%016"PRIx64"\n", kwn);
printf("[KiWaitAlways] = 0x%016"PRIx64"\n", kwa);
/*
* If KDBG header can be decoded, KDBG size is available
* and entire KDBG can be decoded.
*/
printf("Decoding KDBG header...\n");
kdbg_decode((uint64_t *)&kdbg_hdr, (uint64_t *)&kdbg_hdr,
sizeof(kdbg_hdr), kwn, kwa, KdpDataBlockEncoded);
printf("Owner tag is \'%.4s\'\n", (char *)&kdbg_hdr.OwnerTag);
if (memcmp(&kdbg_hdr.OwnerTag, OwnerTag, sizeof(OwnerTag))) {
eprintf("Failed to decode KDBG header\n");
return NULL;
}
}
kdbg = malloc(kdbg_hdr.Size);
if (!kdbg) {
return NULL;
}
if (va_space_rw(vs, KdDebuggerDataBlock, kdbg, kdbg_hdr.Size, 0)) {
eprintf("Failed to extract entire KDBG\n");
return NULL;
}
if (!decode) {
return kdbg;
}
printf("Decoding KdDebuggerDataBlock...\n");
kdbg_decode((uint64_t *)kdbg, (uint64_t *)kdbg, kdbg_hdr.Size,
kwn, kwa, KdpDataBlockEncoded);
va_space_rw(vs, KdDebuggerDataBlock, kdbg, kdbg_hdr.Size, 1);
return kdbg;
}
static void win_context_init_from_qemu_cpu_state(WinContext *ctx,
QEMUCPUState *s)
{
WinContext win_ctx = (WinContext){
.ContextFlags = WIN_CTX_X64 | WIN_CTX_INT | WIN_CTX_SEG | WIN_CTX_CTL,
.MxCsr = INITIAL_MXCSR,
.SegCs = s->cs.selector,
.SegSs = s->ss.selector,
.SegDs = s->ds.selector,
.SegEs = s->es.selector,
.SegFs = s->fs.selector,
.SegGs = s->gs.selector,
.EFlags = (uint32_t)s->rflags,
.Rax = s->rax,
.Rbx = s->rbx,
.Rcx = s->rcx,
.Rdx = s->rdx,
.Rsp = s->rsp,
.Rbp = s->rbp,
.Rsi = s->rsi,
.Rdi = s->rdi,
.R8 = s->r8,
.R9 = s->r9,
.R10 = s->r10,
.R11 = s->r11,
.R12 = s->r12,
.R13 = s->r13,
.R14 = s->r14,
.R15 = s->r15,
.Rip = s->rip,
.FltSave = {
.MxCsr = INITIAL_MXCSR,
},
};
*ctx = win_ctx;
}
/*
* Finds paging-structure hierarchy base,
* if previously set doesn't give access to kernel structures
*/
static int fix_dtb(struct va_space *vs, QEMU_Elf *qe)
{
/*
* Firstly, test previously set DTB.
*/
if (va_space_resolve(vs, SharedUserData)) {
return 0;
}
/*
* Secondly, find CPU which run system task.
*/
size_t i;
for (i = 0; i < qe->state_nr; i++) {
QEMUCPUState *s = qe->state[i];
if (is_system(s)) {
va_space_set_dtb(vs, s->cr[3]);
printf("DTB 0x%016"PRIx64" has been found from CPU #%zu"
" as system task CR3\n", vs->dtb, i);
return !(va_space_resolve(vs, SharedUserData));
}
}
/*
* Thirdly, use KERNEL_GS_BASE from CPU #0 as PRCB address and
* CR3 as [Prcb+0x7000]
*/
if (qe->has_kernel_gs_base) {
QEMUCPUState *s = qe->state[0];
uint64_t Prcb = s->kernel_gs_base;
uint64_t *cr3 = va_space_resolve(vs, Prcb + 0x7000);
if (!cr3) {
return 1;
}
va_space_set_dtb(vs, *cr3);
printf("DirectoryTableBase = 0x%016"PRIx64" has been found from CPU #0"
" as interrupt handling CR3\n", vs->dtb);
return !(va_space_resolve(vs, SharedUserData));
}
return 1;
}
static int fill_header(WinDumpHeader64 *hdr, struct pa_space *ps,
struct va_space *vs, uint64_t KdDebuggerDataBlock,
KDDEBUGGER_DATA64 *kdbg, uint64_t KdVersionBlock, int nr_cpus)
{
uint32_t *suite_mask = va_space_resolve(vs, SharedUserData +
KUSD_OFFSET_SUITE_MASK);
int32_t *product_type = va_space_resolve(vs, SharedUserData +
KUSD_OFFSET_PRODUCT_TYPE);
DBGKD_GET_VERSION64 kvb;
WinDumpHeader64 h;
size_t i;
QEMU_BUILD_BUG_ON(KUSD_OFFSET_SUITE_MASK >= PAGE_SIZE);
QEMU_BUILD_BUG_ON(KUSD_OFFSET_PRODUCT_TYPE >= PAGE_SIZE);
if (!suite_mask || !product_type) {
return 1;
}
if (va_space_rw(vs, KdVersionBlock, &kvb, sizeof(kvb), 0)) {
eprintf("Failed to extract KdVersionBlock\n");
return 1;
}
h = (WinDumpHeader64) {
.Signature = "PAGE",
.ValidDump = "DU64",
.MajorVersion = kvb.MajorVersion,
.MinorVersion = kvb.MinorVersion,
.DirectoryTableBase = vs->dtb,
.PfnDatabase = kdbg->MmPfnDatabase,
.PsLoadedModuleList = kdbg->PsLoadedModuleList,
.PsActiveProcessHead = kdbg->PsActiveProcessHead,
.MachineImageType = kvb.MachineType,
.NumberProcessors = nr_cpus,
.BugcheckCode = LIVE_SYSTEM_DUMP,
.KdDebuggerDataBlock = KdDebuggerDataBlock,
.DumpType = 1,
.Comment = "Hello from elf2dmp!",
.SuiteMask = *suite_mask,
.ProductType = *product_type,
.SecondaryDataState = kvb.KdSecondaryVersion,
.PhysicalMemoryBlock = (WinDumpPhyMemDesc64) {
.NumberOfRuns = ps->block_nr,
},
.RequiredDumpSpace = sizeof(h),
};
for (i = 0; i < ps->block_nr; i++) {
h.PhysicalMemoryBlock.NumberOfPages += ps->block[i].size / PAGE_SIZE;
h.PhysicalMemoryBlock.Run[i] = (WinDumpPhyMemRun64) {
.BasePage = ps->block[i].paddr / PAGE_SIZE,
.PageCount = ps->block[i].size / PAGE_SIZE,
};
}
h.RequiredDumpSpace += h.PhysicalMemoryBlock.NumberOfPages << PAGE_BITS;
*hdr = h;
return 0;
}
static int fill_context(KDDEBUGGER_DATA64 *kdbg,
struct va_space *vs, QEMU_Elf *qe)
{
int i;
for (i = 0; i < qe->state_nr; i++) {
uint64_t Prcb;
uint64_t Context;
WinContext ctx;
QEMUCPUState *s = qe->state[i];
if (va_space_rw(vs, kdbg->KiProcessorBlock + sizeof(Prcb) * i,
&Prcb, sizeof(Prcb), 0)) {
eprintf("Failed to read CPU #%d PRCB location\n", i);
return 1;
}
if (va_space_rw(vs, Prcb + kdbg->OffsetPrcbContext,
&Context, sizeof(Context), 0)) {
eprintf("Failed to read CPU #%d ContextFrame location\n", i);
return 1;
}
printf("Filling context for CPU #%d...\n", i);
win_context_init_from_qemu_cpu_state(&ctx, s);
if (va_space_rw(vs, Context, &ctx, sizeof(ctx), 1)) {
eprintf("Failed to fill CPU #%d context\n", i);
return 1;
}
}
return 0;
}
static int write_dump(struct pa_space *ps,
WinDumpHeader64 *hdr, const char *name)
{
FILE *dmp_file = fopen(name, "wb");
size_t i;
if (!dmp_file) {
eprintf("Failed to open output file \'%s\'\n", name);
return 1;
}
printf("Writing header to file...\n");
if (fwrite(hdr, sizeof(*hdr), 1, dmp_file) != 1) {
eprintf("Failed to write dump header\n");
fclose(dmp_file);
return 1;
}
for (i = 0; i < ps->block_nr; i++) {
struct pa_block *b = &ps->block[i];
printf("Writing block #%zu/%zu to file...\n", i, ps->block_nr);
if (fwrite(b->addr, b->size, 1, dmp_file) != 1) {
eprintf("Failed to write dump header\n");
fclose(dmp_file);
return 1;
}
}
return fclose(dmp_file);
}
static int pe_get_pdb_symstore_hash(uint64_t base, void *start_addr,
char *hash, struct va_space *vs)
{
const char e_magic[2] = "MZ";
const char Signature[4] = "PE\0\0";
const char sign_rsds[4] = "RSDS";
IMAGE_DOS_HEADER *dos_hdr = start_addr;
IMAGE_NT_HEADERS64 nt_hdrs;
IMAGE_FILE_HEADER *file_hdr = &nt_hdrs.FileHeader;
IMAGE_OPTIONAL_HEADER64 *opt_hdr = &nt_hdrs.OptionalHeader;
IMAGE_DATA_DIRECTORY *data_dir = nt_hdrs.OptionalHeader.DataDirectory;
IMAGE_DEBUG_DIRECTORY debug_dir;
OMFSignatureRSDS rsds;
char *pdb_name;
size_t pdb_name_sz;
size_t i;
QEMU_BUILD_BUG_ON(sizeof(*dos_hdr) >= PAGE_SIZE);
if (memcmp(&dos_hdr->e_magic, e_magic, sizeof(e_magic))) {
return 1;
}
if (va_space_rw(vs, base + dos_hdr->e_lfanew,
&nt_hdrs, sizeof(nt_hdrs), 0)) {
return 1;
}
if (memcmp(&nt_hdrs.Signature, Signature, sizeof(Signature)) ||
file_hdr->Machine != 0x8664 || opt_hdr->Magic != 0x020b) {
return 1;
}
printf("Debug Directory RVA = 0x%08"PRIx32"\n",
(uint32_t)data_dir[IMAGE_FILE_DEBUG_DIRECTORY].VirtualAddress);
if (va_space_rw(vs,
base + data_dir[IMAGE_FILE_DEBUG_DIRECTORY].VirtualAddress,
&debug_dir, sizeof(debug_dir), 0)) {
return 1;
}
if (debug_dir.Type != IMAGE_DEBUG_TYPE_CODEVIEW) {
return 1;
}
if (va_space_rw(vs,
base + debug_dir.AddressOfRawData,
&rsds, sizeof(rsds), 0)) {
return 1;
}
printf("CodeView signature is \'%.4s\'\n", rsds.Signature);
if (memcmp(&rsds.Signature, sign_rsds, sizeof(sign_rsds))) {
return 1;
}
pdb_name_sz = debug_dir.SizeOfData - sizeof(rsds);
pdb_name = malloc(pdb_name_sz);
if (!pdb_name) {
return 1;
}
if (va_space_rw(vs, base + debug_dir.AddressOfRawData +
offsetof(OMFSignatureRSDS, name), pdb_name, pdb_name_sz, 0)) {
free(pdb_name);
return 1;
}
printf("PDB name is \'%s\', \'%s\' expected\n", pdb_name, PDB_NAME);
if (strcmp(pdb_name, PDB_NAME)) {
eprintf("Unexpected PDB name, it seems the kernel isn't found\n");
free(pdb_name);
return 1;
}
free(pdb_name);
sprintf(hash, "%.08x%.04x%.04x%.02x%.02x", rsds.guid.a, rsds.guid.b,
rsds.guid.c, rsds.guid.d[0], rsds.guid.d[1]);
hash += 20;
for (i = 0; i < 6; i++, hash += 2) {
sprintf(hash, "%.02x", rsds.guid.e[i]);
}
sprintf(hash, "%.01x", rsds.age);
return 0;
}
int main(int argc, char *argv[])
{
int err = 0;
QEMU_Elf qemu_elf;
struct pa_space ps;
struct va_space vs;
QEMUCPUState *state;
idt_desc_t first_idt_desc;
uint64_t KernBase;
void *nt_start_addr = NULL;
WinDumpHeader64 header;
char pdb_hash[34];
char pdb_url[] = SYM_URL_BASE PDB_NAME
"/0123456789ABCDEF0123456789ABCDEFx/" PDB_NAME;
struct pdb_reader pdb;
uint64_t KdDebuggerDataBlock;
KDDEBUGGER_DATA64 *kdbg;
uint64_t KdVersionBlock;
if (argc != 3) {
eprintf("usage:\n\t%s elf_file dmp_file\n", argv[0]);
return 1;
}
if (QEMU_Elf_init(&qemu_elf, argv[1])) {
eprintf("Failed to initialize QEMU ELF dump\n");
return 1;
}
if (pa_space_create(&ps, &qemu_elf)) {
eprintf("Failed to initialize physical address space\n");
err = 1;
goto out_elf;
}
state = qemu_elf.state[0];
printf("CPU #0 CR3 is 0x%016"PRIx64"\n", state->cr[3]);
va_space_create(&vs, &ps, state->cr[3]);
if (fix_dtb(&vs, &qemu_elf)) {
eprintf("Failed to find paging base\n");
err = 1;
goto out_elf;
}
printf("CPU #0 IDT is at 0x%016"PRIx64"\n", state->idt.base);
if (va_space_rw(&vs, state->idt.base,
&first_idt_desc, sizeof(first_idt_desc), 0)) {
eprintf("Failed to get CPU #0 IDT[0]\n");
err = 1;
goto out_ps;
}
printf("CPU #0 IDT[0] -> 0x%016"PRIx64"\n", idt_desc_addr(first_idt_desc));
KernBase = idt_desc_addr(first_idt_desc) & ~(PAGE_SIZE - 1);
printf("Searching kernel downwards from 0x%016"PRIx64"...\n", KernBase);
for (; KernBase >= 0xfffff78000000000; KernBase -= PAGE_SIZE) {
nt_start_addr = va_space_resolve(&vs, KernBase);
if (!nt_start_addr) {
continue;
}
if (*(uint16_t *)nt_start_addr == 0x5a4d) { /* MZ */
break;
}
}
if (!nt_start_addr) {
eprintf("Failed to find NT kernel image\n");
err = 1;
goto out_ps;
}
printf("KernBase = 0x%016"PRIx64", signature is \'%.2s\'\n", KernBase,
(char *)nt_start_addr);
if (pe_get_pdb_symstore_hash(KernBase, nt_start_addr, pdb_hash, &vs)) {
eprintf("Failed to get PDB symbol store hash\n");
err = 1;
goto out_ps;
}
sprintf(pdb_url, "%s%s/%s/%s", SYM_URL_BASE, PDB_NAME, pdb_hash, PDB_NAME);
printf("PDB URL is %s\n", pdb_url);
if (download_url(PDB_NAME, pdb_url)) {
eprintf("Failed to download PDB file\n");
err = 1;
goto out_ps;
}
if (pdb_init_from_file(PDB_NAME, &pdb)) {
eprintf("Failed to initialize PDB reader\n");
err = 1;
goto out_pdb_file;
}
if (!SYM_RESOLVE(KernBase, &pdb, KdDebuggerDataBlock) ||
!SYM_RESOLVE(KernBase, &pdb, KdVersionBlock)) {
err = 1;
goto out_pdb;
}
kdbg = get_kdbg(KernBase, &pdb, &vs, KdDebuggerDataBlock);
if (!kdbg) {
err = 1;
goto out_pdb;
}
if (fill_header(&header, &ps, &vs, KdDebuggerDataBlock, kdbg,
KdVersionBlock, qemu_elf.state_nr)) {
err = 1;
goto out_pdb;
}
if (fill_context(kdbg, &vs, &qemu_elf)) {
err = 1;
goto out_pdb;
}
if (write_dump(&ps, &header, argv[2])) {
eprintf("Failed to save dump\n");
err = 1;
goto out_kdbg;
}
out_kdbg:
free(kdbg);
out_pdb:
pdb_exit(&pdb);
out_pdb_file:
unlink(PDB_NAME);
out_ps:
pa_space_destroy(&ps);
out_elf:
QEMU_Elf_exit(&qemu_elf);
return err;
}