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Code signing was introduced in Java to provide a mechanism Java uses code signing as a requirement for granting elevated privileges to code irrespective of the security policy in effect. Many security policies permit signed code to operate with elevated privileges. For example, Java applets that need to read system properties from a user's machine can escape the default sandbox restrictions when signed. When a signed applet is run, the user is prompted with a security dialog, asking whether the party that signed the code is considered trustworthy. This element of trusting the signature and the signer allows applets to escape the default security sandbox restrictions. On the other hand, with applications that use a custom security policy, explicit permissions need to be granted to the particular codebase and optionally, the signer. Both these approaches place the control Consequently, users can grant explicit permissions either to a particular codebase or to all code signed by a particular signer. This approach places control of security in the hands of the user, who can choose whether to run the an application either restrictively or with full or restricted permissions.unmigrated-wiki-markup

Signing code, however, has its own problems. According to Bruce Schneier \ [[Schneier 2000|AA. Bibliography#Schneier 00]\]]:

First, users have no idea how to decide if a particular signer is trusted or not. Second, just because a component is signed doesn't mean that it is safe. Third, just because two components are individually signed does not mean that using them together is safe; lots of accidental harmful interactions can be exploited. Fourth, "safe" is not an all-or-nothing thing; there are degrees of safety. And fifth, the fact that the evidence of attack (the signature on the code) is stored on the computer under attack is mostly useless: The attacker could delete or modify the signature during the attack, or simply reformat the drive where the signature is stored."

Code signing is designed primarily to authenticate the origin of the code as well as to verify authenticity of origin and the integrity of the code. It relies on a Certification Authority certification authority (CA) to duly confirm the identity of the principal signer. Naive users should not be expected to understand how certificates and the Public Key Infrastructure public key infrastructure (PKI) work. All too often, users

Users commonly associate digital signatures with safety of code execution, and trust trusting the code to cause them no harm.In general, there is a misconception that signed code is safe to be executed. The problem manifests itself arises when a vulnerability is discovered in signed code. Because many users when prompted with the security dialog, choose the option of permanently trusting the organizations that they consider trustworthy, they are not notified in the future while downloading trusted but potentially vulnerable systems are configured to permanently trust certain signing organizations, those systems fail to notify their users when downloading content signed by the trusted organization, even when that content contains vulnerabilities. An adversary may attacker can offer them the users legitimately signed vulnerable content with the intentions intention of exploiting it that content.

Consider, for example, signed Java applets. Whenever When a certificate is verified to be correct (as opposed to being self-signed or tampered), on widely used platforms, the user is confronted presented with a security dialog that has in which the check box option "Always trust the content from the publisher" is selected by default. The dialog primarily asks whether or not the signed code should be executed or not. Unfortunately, by default this setting overrides any future warning dialogs if the user chooses to execute confirms the code dialog with the check box selected, the "Always trust. An adversary may .." setting overrides any future warning dialogs. An attacker can take advantage of this mechanism by supplying exploiting vulnerable code signed by the trusted organization. In this case, the code will execute without with the user's implied permission and may can be freely exploited.

An organization that signs its own code must should not vouch for code acquired from a third party without carefully auditing itthe third-party code. When signing privileged code, ensure that all of the signed code is confined to the same package (See guideline a single JAR file (see ENV01-J. Place all privileged security-sensitive code in a single package JAR and sign and seal the packageit for more information.) Likewise, and also that any code that is called invoked from the privileged code must is also be bundled in the same package. Non-privileged code can contained in that JAR file. Nonprivileged code must be left unsigned, restricting it to the sandbox. Additionally, any code that is incomprehensible or unaudited must not be signed. (See guideline SEC17-J. Create and sign a SignedObject before creating a SealedObject.) It follows that unprivileged code is not required to be digitally signed and consequently should not be. This conviction adequately respects the guideline SEC00-J. Follow the principle of least privilege. For instanceFor example, unsigned applets and Java Network Launching Protocol (JNLP) applications are granted the minimum set of privileges and are restricted to the sandbox. Finally, never sign any code that is incomprehensible or unaudited.

Exceptions

ENV00-J-EX1: An organization that has an internal PKI and uses code signing for internal development activities (such as to facilitate facilitating code - check-in and track developerstracking developer activity) may sign unprivileged code. This codebase should not be carried forward to the a production environment. The keys used for internal signing must not be distinct from those used to ship the productsto sign externally available code.

ENV00-J-EX2: Oracle has deprecated the use of unsigned applets and will soon cease to support them. Applets that are signed have traditionally been run with full privileges. Since Java 1.7.0 update 21, Oracle has provided mechanisms to allow applets to be signed and yet run without full permissions. This enables applets that are today unsigned to continue to run in a security sandbox despite being signed. Signing an applet that runs with restricted privileges under versions of Java at least as recent as update 21 constitutes an exception to this rule. For more information, see Signed Java Applet Security Improvements on the CERT/CC blog.

Risk Assessment

Signing unprivileged code violates the principle of least privilege as because it can circumvent security restrictions defined by the security policies of applets and Java Network Launch Protocol ( JNLP ) applications, for example.

Automated Detection

TODO

Related Vulnerabilities

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

Bibliography

\[[Schneier 2000|AA. Bibliography#Schneier 00]\]
\[[McGraw 2000|AA. Bibliography#McGraw 00]\] Appendix C: Sign Only Privileged Code
\[[Dormann 2008|AA. Bibliography#Dormann 08]\]

Detecting code that should be considered privileged or sensitive requires programmer assistance. Given identified privileged code as a starting point, automated tools could compute the closure of all code that can be invoked from that point. Such a tool could plausibly determine whether a body of signed code both includes that entire closure and excludes all other code.

Related Guidelines

Android Implementation Details

The Android system uses code signing as a means to identify the author of an application and establish trust relationships between applications, not as a means to grant elevated privileges to code.

Bibliography

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Image Added Image Added Image Added01. Runtime Environment (ENV)      01. Runtime Environment (ENV)      ENV01-J. Place all privileged code in a single package and seal the package