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linux下system函数的简单分析

程序员文章站 2022-06-13 21:58:06
简单分析了linux下system函数的相关内容,具体内容如下 int __libc_system (const char *line) { if (li...

简单分析了linux下system函数的相关内容,具体内容如下

int
__libc_system (const char *line)
{
 if (line == null)
  /* check that we have a command processor available. it might
    not be available after a chroot(), for example. */
  return do_system ("exit 0") == 0;

 return do_system (line);
}
weak_alias (__libc_system, system)

代码位于glibc/sysdeps/posix/system.c,这里system是__libc_system的弱别名,而__libc_system是do_system的前端函数,进行了参数的检查,接下来看do_system函数。

static int
do_system (const char *line)
{
 int status, save;
 pid_t pid;
 struct sigaction sa;
#ifndef _libc_reentrant
 struct sigaction intr, quit;
#endif
 sigset_t omask;

 sa.sa_handler = sig_ign;
 sa.sa_flags = 0;
 __sigemptyset (&sa.sa_mask);

 do_lock ();
 if (add_ref () == 0)
  {
   if (__sigaction (sigint, &sa, &intr) < 0)
  {
   (void) sub_ref ();
   goto out;
  }
   if (__sigaction (sigquit, &sa, &quit) < 0)
  {
   save = errno;
   (void) sub_ref ();
   goto out_restore_sigint;
  }
  }
 do_unlock ();

 /* we reuse the bitmap in the 'sa' structure. */
 __sigaddset (&sa.sa_mask, sigchld);
 save = errno;
 if (__sigprocmask (sig_block, &sa.sa_mask, &omask) < 0)
  {
#ifndef _libc
   if (errno == enosys)
  __set_errno (save);
   else
#endif
  {
   do_lock ();
   if (sub_ref () == 0)
    {
     save = errno;
     (void) __sigaction (sigquit, &quit, (struct sigaction *) null);
    out_restore_sigint:
     (void) __sigaction (sigint, &intr, (struct sigaction *) null);
     __set_errno (save);
    }
  out:
   do_unlock ();
   return -1;
  }
  }

#ifdef cleanup_handler
 cleanup_handler;
#endif

#ifdef fork
 pid = fork ();
#else
 pid = __fork ();
#endif
 if (pid == (pid_t) 0)
  {
   /* child side. */
   const char *new_argv[4];
   new_argv[0] = shell_name;
   new_argv[1] = "-c";
   new_argv[2] = line;
   new_argv[3] = null;

   /* restore the signals. */
   (void) __sigaction (sigint, &intr, (struct sigaction *) null);
   (void) __sigaction (sigquit, &quit, (struct sigaction *) null);
   (void) __sigprocmask (sig_setmask, &omask, (sigset_t *) null);
   init_lock ();

   /* exec the shell. */
   (void) __execve (shell_path, (char *const *) new_argv, __environ);
   _exit (127);
  }
 else if (pid < (pid_t) 0)
  /* the fork failed. */
  status = -1;
 else
  /* parent side. */
  {
   /* note the system() is a cancellation point. but since we call
   waitpid() which itself is a cancellation point we do not
   have to do anything here. */
   if (temp_failure_retry (__waitpid (pid, &status, 0)) != pid)
  status = -1;
  }

#ifdef cleanup_handler
 cleanup_reset;
#endif

 save = errno;
 do_lock ();
 if ((sub_ref () == 0
    && (__sigaction (sigint, &intr, (struct sigaction *) null)
    | __sigaction (sigquit, &quit, (struct sigaction *) null)) != 0)
   || __sigprocmask (sig_setmask, &omask, (sigset_t *) null) != 0)
  {
#ifndef _libc
   /* glibc cannot be used on systems without waitpid. */
   if (errno == enosys)
  __set_errno (save);
   else
#endif
  status = -1;
  }
 do_unlock ();

 return status;
}

do_system

首先函数设置了一些信号处理程序,来处理sigint和sigquit信号,此处我们不过多关心,关键代码段在这里

#ifdef fork
 pid = fork ();
#else
 pid = __fork ();
#endif
 if (pid == (pid_t) 0)
  {
   /* child side. */
   const char *new_argv[4];
   new_argv[0] = shell_name;
   new_argv[1] = "-c";
   new_argv[2] = line;
   new_argv[3] = null;

   /* restore the signals. */
   (void) __sigaction (sigint, &intr, (struct sigaction *) null);
   (void) __sigaction (sigquit, &quit, (struct sigaction *) null);
   (void) __sigprocmask (sig_setmask, &omask, (sigset_t *) null);
   init_lock ();

   /* exec the shell. */
   (void) __execve (shell_path, (char *const *) new_argv, __environ);
   _exit (127);
  }
 else if (pid < (pid_t) 0)
  /* the fork failed. */
  status = -1;
 else
  /* parent side. */
  {
   /* note the system() is a cancellation point. but since we call
   waitpid() which itself is a cancellation point we do not
   have to do anything here. */
   if (temp_failure_retry (__waitpid (pid, &status, 0)) != pid)
  status = -1;
  }

首先通过前端函数调用系统调用fork产生一个子进程,其中fork有两个返回值,对父进程返回子进程的pid,对子进程返回0。所以子进程执行6-24行代码,父进程执行30-35行代码。

子进程的逻辑非常清晰,调用execve执行shell_path指定的程序,参数通过new_argv传递,环境变量为全局变量__environ。

其中shell_path和shell_name定义如下

#define  shell_path  "/bin/sh"  /* path of the shell. */
#define  shell_name  "sh"    /* name to give it. */ 

其实就是生成一个子进程调用/bin/sh -c "命令"来执行向system传入的命令。 

下面其实是我研究system函数的原因与重点:

在ctf的pwn题中,通过栈溢出调用system函数有时会失败,听师傅们说是环境变量被覆盖,但是一直都是懵懂,今天深入学习了一下,总算搞明白了。

在这里system函数需要的环境变量储存在全局变量__environ中,那么这个变量的内容是什么呢。

__environ是在glibc/csu/libc-start.c中定义的,我们来看几个关键语句。

# define libc_start_main __libc_start_main

__libc_start_main是_start调用的函数,这涉及到程序开始时的一些初始化工作,对这些名词不了解的话可以看一下这篇文章。接下来看libc_start_main函数。

static int
libc_start_main (int (*main) (int, char **, char ** main_auxvec_decl),
     int argc, char **argv,
#ifdef libc_start_main_auxvec_arg
     elfw(auxv_t) *auxvec,
#endif
     __typeof (main) init,
     void (*fini) (void),
     void (*rtld_fini) (void), void *stack_end)
{
 /* result of the 'main' function. */
 int result;

 __libc_multiple_libcs = &_dl_starting_up && !_dl_starting_up;

#ifndef shared
 char **ev = &argv[argc + 1];

 __environ = ev;

 /* store the lowest stack address. this is done in ld.so if this is
   the code for the dso. */
 __libc_stack_end = stack_end;

    ......
 /* nothing fancy, just call the function. */
 result = main (argc, argv, __environ main_auxvec_param);
#endif

 exit (result);
}

我们可以看到,在没有define shared的情况下,在第19行定义了__environ的值。启动程序调用libc_start_main之前,会先将环境变量和argv中的字符串保存起来(其实是保存到栈上),然后依次将环境变量中各项字符串的地址,argv中各项字符串的地址和argc入栈,所以环境变量数组一定位于argv数组的正后方,以一个空地址间隔。所以第17行的&argv[argc + 1]语句就是取环境变量数组在栈上的首地址,保存到ev中,最终保存到__environ中。第203行调用main函数,会将__environ的值入栈,这个被栈溢出覆盖掉没什么问题,只要保证__environ中的地址处不被覆盖即可。

所以,当栈溢出的长度过大,溢出的内容覆盖了__environ中地址中的重要内容时,调用system函数就会失败。具体环境变量距离溢出地址有多远,可以通过在_start中下断查看。

以上就是本文的全部内容,希望对大家的学习有所帮助,也希望大家多多支持。