You are viewing an old version of this page. View the current version.

Compare with Current View Page History

« Previous Version 35 Next »

The principle of least privilege states that every program and every user of the system should operate using the least set of privileges necessary to complete the job [Saltzer 74, Saltzer 75]. The Build Security In website [DHS 06] provides additional definitions of this principle. Executing with minimal privileges mitigates against exploitation in case a vulnerability is discovered in the code.

Noncompliant Code Example

Privileged operations are often required in a program, though the program might not need to retain the special privileges. For instance, a network program may require superuser privileges to capture raw network packets but may not require the same set of privileges for carrying out other tasks such as packet analysis. Dropping or elevating privileges alternately according to program requirements is a good design strategy. Moreover, assigning only the required privileges limits the window of exposure for any privilege escalation exploit to succeed.

Consider a custom service that must bind to a well-known port (below 1024). To avoid malicious entities from hijacking client connections, the kernel imposes a condition such that only the superuser can use the bind() system call to bind to these ports.

This noncompliant code example is configured as setuid-superuser. It calls bind() and later forks out a child to perform the bookkeeping tasks. The program continues to run with superuser privileges even after the bind() operation has been carried out.

int establish(void) {
  struct sockaddr_in sa; /* listening socket's address */
  int s; /* listening socket */

  /*  Fill up the structure with address and port number  */

  sa.sin_port = htons(portnum);

  /*  Other system calls like socket()  */

  if (bind(s, (struct sockaddr *)&sa,
        sizeof(struct sockaddr_in)) < 0) {
    /* Perform cleanup */
  }

  /* Return */
}

int main(void) {
   int s = establish();

  /*  Block with accept() until a client connects  */

   switch (fork()) {
      case -1 :  /* Error, clean up and quit */
      case  0 :  /* This is the child, handle the client */
      default :  /* This is the parent, continue blocking */
   }
}

If a vulnerability is exploited in the main body of the program that allows an attacker to execute arbitrary code, this malicious code will run with elevated privileges.

Compliant Solution

The program must follow the principle of least privilege while carefully separating the binding and bookkeeping tasks. To minimize the chance of a flaw in the program from compromising the superuser-level account, it should drop superuser privileges as soon as the privileged operations are completed. In the code shown below, privileges are permanently dropped as soon as the bind() operation is carried out. The code also ensures privileges may not be regained after being permanently dropped, as per POS37-C. Ensure that privilege relinquishment is successful.

/*  Code with elevated privileges  */

int establish(void) {
  struct sockaddr_in sa; /* listening socket's address */
  int s; /* listening socket */

  /* Fill up the structure with address and port number */

  sa.sin_port = htons(portnum);

  /* Other system calls like socket() */

  if (bind(s, (struct sockaddr *)&sa,
        sizeof(struct sockaddr_in)) < 0) {
    /* Perform cleanup */
  }

  /* Return */
}

int main(void) {
  int s = establish();

  /* Drop privileges permanently */
  if (setuid(getuid()) == -1) {
     /*  Handle the error  */
  }

  if (setuid(0) != -1) {
    /* Privileges can be restored, handle error */
  }

  /* Block with accept() until a client connects */

  switch (fork()) {
     case -1: /* Error, clean up and quit */
     case  0: /* Close all open file descriptors
               * This is the child, handle the client
               */
     default: /* This is the parent, continue blocking */
  }
}

Risk Assessment

Failure to follow the principle of least privilege may allow exploits to execute with elevated privileges.

Recommendation

Severity

Likelihood

Remediation Cost

Priority

Level

POS02-C

high

likely

high

P9

L2

Related Vulnerabilities

CVE-2009-2031 results from a violation of this recommendation. OpenSolaris in smbfs snv_84 through snv_110 sets permissions based on mount point options, and not actual user information (obtained from the getuid() and getgid() functions). An attacker can exploit this to achieve higher permissions. Also, in a certain initialization mode the code grants read, write, and execute permissions to users other than the owner, which can be exploited to make files world readable [xorl 2009].

Search for vulnerabilities resulting from the violation of this rule on the CERT website.

References

[DHS 06] Least Privilege
[ISO/IEC PDTR 24772] "XYN Privilege Management"
[MITRE 07] CWE ID 250, "Execution with Unnecessary Privileges," CWE ID 272, "Least Privilege Violation"
[Saltzer 74]
[Saltzer 75]
[Wheeler 03] Section 7.4, "Minimize Privileges"
[xorl 2009] "OpenSolaris CIFS/SMB Invalid File Flags"


      50. POSIX (POS)      POS03-C. Do not use volatile as a synchronization primitive

  • No labels