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[原创]一条新的glibc IO_FILE利用链:__printf_buffer_as_file_overflow利用分析
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发表于: 2023-3-14 16:47
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之前听说glibc2.37删除了_IO_obstack_jumps这个vtable。但是在源码里还看到obstack结构体存在,那么glibc2.37真的不能再调用_IO_obstack_jumps的那条链吗?看完本文就知道还可以调用_IO_obstack_jumps那条链的关键部分。但目前这条链只存在glibc2.37,所以现在可能还没有利用场景。在此结合源码和自己的理解和大家分享一下,也感谢roderick师傅和whiter师傅的指导与支持。如果有哪里不对恳请师傅们斧正!
在此,我称这条链为house of snake,此利用链与house of apple、house of cat、house of emma等利用一样,利用了修改虚表指针的方法。主要思路就是伪造相关结构体并且修改虚表指针为_IO_printf_buffer_as_file_jumps实现攻击。
1.能修改stdout、stdin、stderr其中一个_IO_FILE_plus结构(fastbin attack或tcachebin attack)或劫持 _IO_list_all。(如large bin attack、tcache stashing unlink attack、fastbin reverse into tcache)
2.能够触发IO流,执行IO相关函数。
3.能够泄露堆地址和libc基址。
在 2.24 版本的 glibc 以后,加入了针对 IO_FILE_plus 的 vtable 劫持的检测措施,glibc 会在调用虚函数之前首先检查 vtable 地址的合法性。首先会验证 vtable 是否位于_IO_vtable 段中,如果满足条件就正常执行,否则会调用_IO_vtable_check 做进一步检查。
简单来说,如果 vtable 地址是非法的,那么会引发 abort。
源码如下:
该结构体应该不难理解,不过多赘述。
当我们对一个文件对象fp进行操作时,往往会使用到_IO_jump_t结构体内某一函数。
源码如下:
也就是在_IO_FILE追加了个指向_IO_jump_t结构体的指针。
了解存在这个结构体即可。
其中FILE就是_IO_FILE_plus,就是在_IO_FILE_plus结构体后追加了个指向__printf_buffer结构体的指针。这个结构体是关键结构体之一,因为本文提及的调用链离不开这个结构体。
简单总结一下,就是一个常见的_IO_FILE_plus后面追加了一个结构体指针,我们只要认识到这一点就行了。
在此,我们只需要知道有这个结构体即可,不需要过多的探究每个成员的意义。
就是在__printf_buffer结构体后追加了一个obstack结构体指针和一个char类型的变量,这个结构体也是关键结构体之一。
由上可知,vtable必须合法,在glibc2.37中有一个新的vtable,源码如下:
可知,该vtable内只存在两个函数,分别为__printf_buffer_as_file_overflow,__printf_buffer_as_file_xsputn
接下来我们先对__printf_buffer_as_file_overflow进行分析。
笔者对该利用链分析只关注调用过程,要绕过的条件先按下不表,最后再总结!
源码如下:
该函数首先堆传入的第一个参数强制类型转换为__printf_buffer_as_file并赋给变量file,然后调用__printf_buffer_as_file_commit函数,
该函数源码如下:
可以看出该函数通过断言对file结构体中的stream结构体与next结构体中的成员进行一系列判断,然后做一个赋值的操作。
可以看到若ch != EOF就调用__printf_buffer_putc,源码如下:
可知__printf_buffer_putc只是做了一些指针记录的数值加减的操作,对此我们不用过多关注。
然后有判断:if (!__printf_buffer_has_failed (file->next) && file->next->write_ptr == file->next->write_end)
就是判断__printf_buffer_as_file结构体中的mode成员是不是__printf_buffer_mode_failed以及file->next->write_ptr == file->next->write_end,我们假设满足这两个条件,会调用__printf_buffer_flush (file->next)
这个函数笔者无法直接在源码中找到,但是配合gdb,笔者还是发现了它的蛛丝马迹。
评论区有师傅(id:我超啊)指出该函数其实是__printf_buffer_flush => Xprintf_buffer_flush => Xprintf (buffer_do_flush) (buf) => __printf_buffer_do_flush这样的!事实确实如此。但是我们只需要关注__printf_buffer_do_flush,源码如下:
在这里我们关注进入__printf_buffer_flush_obstack函数的这一分支
假设满足所有条件进入obstack_1grow宏定义。
可以看到里面还有个宏定义,然后又_obstack_newchunk这一个函数。
假设满足所有条件,进入CALL_CHUNKFUN这个宏定义,该宏定义的源码如下:
可以看到当(((h)->use_extra_arg)不为0时,会调用(*(h)->chunkfun),它的参数是(h)->extra_arg和(size),而我们可以控制(*(h)->chunkfun)与(h)->extra_arg,从而执行system('/bin/sh')。
如果各位跟着本文分析到这,估计就豁然开朗了,因为后半部分与_IO_obstack_xsputn的调用链一样。
回顾一下整个分析过程并将所有相关结构体,并都看成__printf_buffer_as_file结构体,有以下条件:
在__printf_buffer_as_file_overflow函数中:
在__printf_buffer_as_file_commit函数中:
在__printf_buffer_flush函数中:
file->next->mode =__printf_buffer_mode_obstack
在__printf_buffer_flush_obstack函数中:
buf->base.write_ptr == &buf->ch + 1 <==> file->next.write_ptr == &(file->next) + 0x30 + 1
在obstack_1grow宏定义中:
本文分析基于amd64下通过FSOP触发。
我们知道FSOP 的核心思想就是劫持_IO_list_all 的值来伪造链表和其中的_IO_FILE 项,但是单纯的伪造只是构造了数据还需要某种方法进行触发。FSOP 选择的触发方法是exit函数调用_IO_flush_all_lockp,这个函数会刷新_IO_list_all 链表中所有项的文件流,相当于对每个 FILE 调用 fflush,也对应着会调用_IO_FILE_plus.vtable 中的_IO_overflow。
我们调试可以知道_IO_overflow位于vtable指针所指向地址+0x18处,也就是说当FSOP发生的时候会调用_IO_FILE_plus.vtable 中的_IO_overflow。即调用vtable指针所指向地址 + 0x18处的数据。
那么只要我们伪造一个_IO_FILE结构体,将它的vtable替换为&_IO_printf_buffer_as_file_jumps,此时vtable指针所指地址+0x18处为__printf_buffer_as_file_overflow,然后伪造上述所有需要满足的条件(详见poc与攻击模板),就可以完成攻击,如下:
下载glibc2.37源码:
解压:
编译:
准备好POC
可以点击这里下载文件(本来是直接展示源码的...但是放到看雪里排版就错位了...)
编译POC
patchelf
运行
以下攻击模板全是在FSOP下的,可以点击这里下载附件尝试以下三种攻击。
这个payload需要的内存是最小的,只需要0xe0字节大小的内存。
该利用链看起来需要绕过的条件很多,但是并不复杂,并且可以稳定控制rdi与rip。但是ubuntu还没有使用glibc2.37,所以目前这条链新的还没有利用场景2333。但我相信以后说不定会有它的利用场景。
struct _IO_FILE { int _flags;
#define _IO_file_flags _flags
char* _IO_read_ptr; /* Current read pointer */
char* _IO_read_end; /* End of get area. */
char* _IO_read_base; /* Start of putback+get area. */
char* _IO_write_base; /* Start of put area. */
char* _IO_write_ptr; /* Current put pointer. */
char* _IO_write_end; /* End of put area. */
char* _IO_buf_base; /* Start of reserve area. */
char* _IO_buf_end; /* End of reserve area. */
/* The following fields are used to support backing up and undo. */
char *_IO_save_base; /* Pointer to start of non-current get area. */
char *_IO_backup_base; /* Pointer to first valid character of backup area */
char *_IO_save_end; /* Pointer to end of non-current get area. */
struct _IO_marker *_markers;
struct _IO_FILE *_chain;
int _fileno;
#if 0 int _blksize;
#else int _flags2;
#endif _IO_off_t _old_offset; /* This used to be _offset but it's too small. */
#define __HAVE_COLUMN /* temporary */ unsigned short _cur_column;
signed char _vtable_offset;
char _shortbuf[1];
/* char* _save_gptr; char* _save_egptr; */
_IO_lock_t *_lock;
#ifdef _IO_USE_OLD_IO_FILE};struct _IO_FILE { int _flags;
#define _IO_file_flags _flags
char* _IO_read_ptr; /* Current read pointer */
char* _IO_read_end; /* End of get area. */
char* _IO_read_base; /* Start of putback+get area. */
char* _IO_write_base; /* Start of put area. */
char* _IO_write_ptr; /* Current put pointer. */
char* _IO_write_end; /* End of put area. */
char* _IO_buf_base; /* Start of reserve area. */
char* _IO_buf_end; /* End of reserve area. */
/* The following fields are used to support backing up and undo. */
char *_IO_save_base; /* Pointer to start of non-current get area. */
char *_IO_backup_base; /* Pointer to first valid character of backup area */
char *_IO_save_end; /* Pointer to end of non-current get area. */
struct _IO_marker *_markers;
struct _IO_FILE *_chain;
int _fileno;
#if 0 int _blksize;
#else int _flags2;
#endif _IO_off_t _old_offset; /* This used to be _offset but it's too small. */
#define __HAVE_COLUMN /* temporary */ unsigned short _cur_column;
signed char _vtable_offset;
char _shortbuf[1];
/* char* _save_gptr; char* _save_egptr; */
_IO_lock_t *_lock;
#ifdef _IO_USE_OLD_IO_FILE};struct _IO_jump_t{ JUMP_FIELD(size_t, __dummy);
JUMP_FIELD(size_t, __dummy2);
JUMP_FIELD(_IO_finish_t, __finish);
JUMP_FIELD(_IO_overflow_t, __overflow);
JUMP_FIELD(_IO_underflow_t, __underflow);
JUMP_FIELD(_IO_underflow_t, __uflow);
JUMP_FIELD(_IO_pbackfail_t, __pbackfail);
/* showmany */
JUMP_FIELD(_IO_xsputn_t, __xsputn);
JUMP_FIELD(_IO_xsgetn_t, __xsgetn);
JUMP_FIELD(_IO_seekoff_t, __seekoff);
JUMP_FIELD(_IO_seekpos_t, __seekpos);
JUMP_FIELD(_IO_setbuf_t, __setbuf);
JUMP_FIELD(_IO_sync_t, __sync);
JUMP_FIELD(_IO_doallocate_t, __doallocate);
JUMP_FIELD(_IO_read_t, __read);
JUMP_FIELD(_IO_write_t, __write);
JUMP_FIELD(_IO_seek_t, __seek);
JUMP_FIELD(_IO_close_t, __close);
JUMP_FIELD(_IO_stat_t, __stat);
JUMP_FIELD(_IO_showmanyc_t, __showmanyc);
JUMP_FIELD(_IO_imbue_t, __imbue);
#if 0 get_column;
set_column;
#endif};struct _IO_jump_t{ JUMP_FIELD(size_t, __dummy);
JUMP_FIELD(size_t, __dummy2);
JUMP_FIELD(_IO_finish_t, __finish);
JUMP_FIELD(_IO_overflow_t, __overflow);
JUMP_FIELD(_IO_underflow_t, __underflow);
JUMP_FIELD(_IO_underflow_t, __uflow);
JUMP_FIELD(_IO_pbackfail_t, __pbackfail);
/* showmany */
JUMP_FIELD(_IO_xsputn_t, __xsputn);
JUMP_FIELD(_IO_xsgetn_t, __xsgetn);
JUMP_FIELD(_IO_seekoff_t, __seekoff);
JUMP_FIELD(_IO_seekpos_t, __seekpos);
JUMP_FIELD(_IO_setbuf_t, __setbuf);
JUMP_FIELD(_IO_sync_t, __sync);
JUMP_FIELD(_IO_doallocate_t, __doallocate);
JUMP_FIELD(_IO_read_t, __read);
JUMP_FIELD(_IO_write_t, __write);
JUMP_FIELD(_IO_seek_t, __seek);
JUMP_FIELD(_IO_close_t, __close);
JUMP_FIELD(_IO_stat_t, __stat);
JUMP_FIELD(_IO_showmanyc_t, __showmanyc);
JUMP_FIELD(_IO_imbue_t, __imbue);
#if 0 get_column;
set_column;
#endif};struct _IO_FILE_plus{ _IO_FILE file;
const struct _IO_jump_t *vtable;
};struct _IO_FILE_plus{ _IO_FILE file;
const struct _IO_jump_t *vtable;
};struct __printf_buffer{ char *write_base;
char *write_ptr;
char *write_end;
uint64_t written;
enum __printf_buffer_mode mode;
};struct __printf_buffer{ char *write_base;
char *write_ptr;
char *write_end;
uint64_t written;
enum __printf_buffer_mode mode;
};struct __printf_buffer_as_file{ /* Interface to libio. */
FILE stream;
const struct _IO_jump_t *vtable;
/* Pointer to the underlying buffer. */
struct __printf_buffer *next;
};struct __printf_buffer_as_file{ /* Interface to libio. */
FILE stream;
const struct _IO_jump_t *vtable;
/* Pointer to the underlying buffer. */
struct __printf_buffer *next;
};struct obstack /* control current object in current chunk */
{ long chunk_size; /* preferred size to allocate chunks in */
struct _obstack_chunk *chunk; /* address of current struct obstack_chunk */
char *object_base; /* address of object we are building */
char *next_free; /* where to add next char to current object */
char *chunk_limit; /* address of char after current chunk */
union
{
PTR_INT_TYPE tempint;
void *tempptr;
} temp; /* Temporary for some macros. */
int alignment_mask; /* Mask of alignment for each object. */
struct _obstack_chunk *(*chunkfun) (void *, long);
void (*freefun) (void *, struct _obstack_chunk *);
void *extra_arg; /* first arg for chunk alloc/dealloc funcs */
unsigned use_extra_arg : 1; /* chunk alloc/dealloc funcs take extra arg */
unsigned maybe_empty_object : 1; /* There is a possibility that the current
unsigned alloc_failed : 1; /* No longer used, as we now call the failed
handler on error, but retained for binary
compatibility. */
};struct obstack /* control current object in current chunk */
{ long chunk_size; /* preferred size to allocate chunks in */
struct _obstack_chunk *chunk; /* address of current struct obstack_chunk */
char *object_base; /* address of object we are building */
char *next_free; /* where to add next char to current object */
char *chunk_limit; /* address of char after current chunk */
union
{
PTR_INT_TYPE tempint;
void *tempptr;
} temp; /* Temporary for some macros. */
int alignment_mask; /* Mask of alignment for each object. */
struct _obstack_chunk *(*chunkfun) (void *, long);
void (*freefun) (void *, struct _obstack_chunk *);
void *extra_arg; /* first arg for chunk alloc/dealloc funcs */
unsigned use_extra_arg : 1; /* chunk alloc/dealloc funcs take extra arg */
unsigned maybe_empty_object : 1; /* There is a possibility that the current
unsigned alloc_failed : 1; /* No longer used, as we now call the failed
handler on error, but retained for binary
compatibility. */
};struct __printf_buffer_obstack{ struct __printf_buffer base;
struct obstack *obstack;
char ch;
};struct __printf_buffer_obstack{ struct __printf_buffer base;
struct obstack *obstack;
char ch;
};static const struct _IO_jump_t _IO_printf_buffer_as_file_jumps libio_vtable =
{ JUMP_INIT_DUMMY,
JUMP_INIT(finish, NULL),
JUMP_INIT(overflow, __printf_buffer_as_file_overflow),//函数一
JUMP_INIT(underflow, NULL),
JUMP_INIT(uflow, NULL),
JUMP_INIT(pbackfail, NULL),
JUMP_INIT(xsputn, __printf_buffer_as_file_xsputn),//函数二
JUMP_INIT(xsgetn, NULL),
JUMP_INIT(seekoff, NULL),
JUMP_INIT(seekpos, NULL),
JUMP_INIT(setbuf, NULL),
JUMP_INIT(sync, NULL),
JUMP_INIT(doallocate, NULL),
JUMP_INIT(read, NULL),
JUMP_INIT(write, NULL),
JUMP_INIT(seek, NULL),
JUMP_INIT(close, NULL),
JUMP_INIT(stat, NULL),
JUMP_INIT(showmanyc, NULL),
JUMP_INIT(imbue, NULL)
};static const struct _IO_jump_t _IO_printf_buffer_as_file_jumps libio_vtable =
{ JUMP_INIT_DUMMY,
JUMP_INIT(finish, NULL),
JUMP_INIT(overflow, __printf_buffer_as_file_overflow),//函数一
JUMP_INIT(underflow, NULL),
JUMP_INIT(uflow, NULL),
JUMP_INIT(pbackfail, NULL),
JUMP_INIT(xsputn, __printf_buffer_as_file_xsputn),//函数二
JUMP_INIT(xsgetn, NULL),
JUMP_INIT(seekoff, NULL),
JUMP_INIT(seekpos, NULL),
JUMP_INIT(setbuf, NULL),
JUMP_INIT(sync, NULL),
JUMP_INIT(doallocate, NULL),
JUMP_INIT(read, NULL),
JUMP_INIT(write, NULL),
JUMP_INIT(seek, NULL),
JUMP_INIT(close, NULL),
JUMP_INIT(stat, NULL),
JUMP_INIT(showmanyc, NULL),
JUMP_INIT(imbue, NULL)
};static int
__printf_buffer_as_file_overflow (FILE *fp, int ch)
{ struct __printf_buffer_as_file *file = (struct __printf_buffer_as_file *) fp;
__printf_buffer_as_file_commit (file);
/* EOF means only a flush is requested. */
if (ch != EOF)
__printf_buffer_putc (file->next, ch);
/* Ensure that flushing actually produces room. */
if (!__printf_buffer_has_failed (file->next)
&& file->next->write_ptr == file->next->write_end)
__printf_buffer_flush (file->next);
[...]
}static int
__printf_buffer_as_file_overflow (FILE *fp, int ch)
{ struct __printf_buffer_as_file *file = (struct __printf_buffer_as_file *) fp;
__printf_buffer_as_file_commit (file);
/* EOF means only a flush is requested. */
if (ch != EOF)
__printf_buffer_putc (file->next, ch);
/* Ensure that flushing actually produces room. */
if (!__printf_buffer_has_failed (file->next)
&& file->next->write_ptr == file->next->write_end)
__printf_buffer_flush (file->next);
[...]
}static void__printf_buffer_as_file_commit (struct __printf_buffer_as_file *file)
{ /* Check that the write pointers in the file stream are consistent
with the next buffer. */
assert (file->stream._IO_write_ptr >= file->next->write_ptr);
assert (file->stream._IO_write_ptr <= file->next->write_end);
assert (file->stream._IO_write_base == file->next->write_base);
assert (file->stream._IO_write_end == file->next->write_end);
file->next->write_ptr = file->stream._IO_write_ptr;
}static void__printf_buffer_as_file_commit (struct __printf_buffer_as_file *file)
{ /* Check that the write pointers in the file stream are consistent
with the next buffer. */
assert (file->stream._IO_write_ptr >= file->next->write_ptr);
assert (file->stream._IO_write_ptr <= file->next->write_end);
assert (file->stream._IO_write_base == file->next->write_base);
assert (file->stream._IO_write_end == file->next->write_end);
file->next->write_ptr = file->stream._IO_write_ptr;
}static inline void__printf_buffer_putc (struct __printf_buffer *buf, char ch)
{ if (buf->write_ptr != buf->write_end)
*buf->write_ptr++ = ch;
else
__printf_buffer_putc_1 (buf, ch);
}static inline void__printf_buffer_putc (struct __printf_buffer *buf, char ch)
{ if (buf->write_ptr != buf->write_end)
*buf->write_ptr++ = ch;
else
__printf_buffer_putc_1 (buf, ch);
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