CWE-1258 Base Brouillon

Exposure of Sensitive System Information Due to Uncleared Debug Information

This vulnerability occurs when hardware fails to erase sensitive data like cryptographic keys and intermediate values before entering debug mode, leaving them exposed.

Définition

What is CWE-1258?

This vulnerability occurs when hardware fails to erase sensitive data like cryptographic keys and intermediate values before entering debug mode, leaving them exposed.
During normal operation, hardware components temporarily store security-critical data in registers or cache. This includes encryption keys, intermediate calculation results from cryptographic processes, and other sensitive system information. If this data isn't proactively wiped when the system switches into debug mode, it remains resident in memory. Attackers or untrusted users with debug access can then read these uncleared values directly, potentially compromising entire security systems. This exposure bypasses software protections because the leak happens at the hardware level, where sensitive artifacts were never properly sanitized during the mode transition.
Impact réel

Real-world CVEs caused by CWE-1258

  • CVE-2021-33080

    Uncleared debug information in memory accelerator for SSD product exposes sensitive system information

  • CVE-2022-31162

    Rust library leaks Oauth client details in application debug logs

Comment les attaquants l'exploitent

Parcours de l'attaquant étape par étape

  1. 1

    A cryptographic core in a System-On-a-Chip (SoC) is used for cryptographic acceleration and implements several cryptographic operations (e.g., computation of AES encryption and decryption, SHA-256, HMAC, etc.). The keys for these operations or the intermediate values are stored in registers internal to the cryptographic core. These internal registers are in the Memory Mapped Input Output (MMIO) space and are blocked from access by software and other untrusted agents on the SoC. These registers are accessible through the debug and test interface.

  2. 2

    The following code example is extracted from the AES wrapper module, aes1_wrapper, of the Hack@DAC'21 buggy OpenPiton System-on-Chip (SoC). Within this wrapper module are four memory-mapped registers: core_key, core_key0, core_key1, and core_key2. Core_key0, core_key1, and core_key2 hold encryption/decryption keys. The core_key register selects a key and sends it to the underlying AES module to execute encryption/decryption operations. Debug mode in processors and SoCs facilitates design debugging by granting access to internal signal/register values, including physical pin values of peripherals/core, fabric bus data transactions, and inter-peripheral registers. Debug mode allows users to gather detailed, low-level information about the design to diagnose potential issues. While debug mode is beneficial for diagnosing processors or SoCs, it also introduces a new attack surface for potential attackers. For instance, if an attacker gains access to debug mode, they could potentially read any content transmitted through the fabric bus or access encryption/decryption keys stored in cryptographic peripherals. Therefore, it is crucial to clear the contents of secret registers upon entering debug mode. In the provided example of flawed code below, when debug_mode_i is activated, the register core_key0 is set to zero to prevent AES key leakage during debugging. However, this protective measure is not applied to the core_key1 register [REF-1435], leaving its contents uncleared during debug mode. This oversight enables a debugger to access sensitive information. Failing to clear sensitive data during debug mode may lead to unauthorized access to secret keys and compromise system security.

  3. 3

    To address the issue, it is essential to ensure that the register is cleared and zeroized after activating debug mode on the SoC. In the correct implementation illustrated in the good code below, core_keyx registers are set to zero when debug mode is activated [REF-1436].

Exemple de code vulnérable

Vulnerable Other

A cryptographic core in a System-On-a-Chip (SoC) is used for cryptographic acceleration and implements several cryptographic operations (e.g., computation of AES encryption and decryption, SHA-256, HMAC, etc.). The keys for these operations or the intermediate values are stored in registers internal to the cryptographic core. These internal registers are in the Memory Mapped Input Output (MMIO) space and are blocked from access by software and other untrusted agents on the SoC. These registers are accessible through the debug and test interface.

Vulnérable Other 
In the above scenario, registers that store keys and intermediate values of cryptographic operations are not cleared when system enters debug mode. An untrusted actor running a debugger may read the contents of these registers and gain access to secret keys and other sensitive cryptographic information.
Exemple de code sécurisé

Secure Other

Sécurisé Other 
Whenever the chip enters debug mode, all registers containing security-sensitive data are be cleared rendering them unreadable.
What changed: the unsafe sink is replaced (or the input is validated/escaped) so the same payload no longer triggers the weakness.
Liste de contrôle de prévention

How to prevent CWE-1258

  • Architecture and Design Whenever debug mode is enabled, all registers containing sensitive assets must be cleared.
Signaux de détection

How to detect CWE-1258

SAST High

Exécuter une analyse statique (SAST) sur le code source à la recherche du motif non sécurisé dans le flux de données.

DAST Moderate

Exécuter des tests de sécurité applicative dynamique (DAST) contre le point de terminaison en ligne.

Runtime Moderate

Surveiller les journaux runtime pour détecter des traces d'exception inhabituelles, des entrées malformées ou des tentatives de contournement d'autorisation.

Code review Moderate

Revue de code : signaler tout nouveau code qui traite les entrées de cette surface sans utiliser les helpers du framework validés.

Correction automatique Plexicus

Plexicus détecte automatiquement CWE-1258 et ouvre une PR de correction en moins de 60 secondes.

Codex Remedium analyse chaque commit, identifie cette faiblesse précise et livre une pull request prête à être relue avec le correctif. Pas de tickets. Pas de transferts.

Obtenir une démo Essayer Plexicus gratuitement
Questions fréquentes

Frequently asked questions

Qu'est-ce que CWE-1258 ?

This vulnerability occurs when hardware fails to erase sensitive data like cryptographic keys and intermediate values before entering debug mode, leaving them exposed.

Quelle est la gravité de CWE-1258 ?

MITRE n'a pas publié de note de probabilité d'exploitation pour cette faiblesse. Traitez-la comme un impact moyen jusqu'à ce que votre modèle de menace prouve le contraire.

Quels langages ou plateformes sont affectés par CWE-1258 ?

MITRE lists the following affected platforms: Not OS-Specific, Not Architecture-Specific, Not Technology-Specific.

Comment puis-je prévenir CWE-1258 ?

Whenever debug mode is enabled, all registers containing sensitive assets must be cleared.

Comment Plexicus détecte et corrige CWE-1258 ?

Le moteur SAST de Plexicus reconnaît la signature de flux de données de CWE-1258 à chaque commit. Lorsqu'une correspondance est trouvée, notre agent Codex Remedium ouvre une PR de correction avec le code corrigé, les tests et un résumé d'une ligne pour le relecteur.

Où puis-je en savoir plus sur CWE-1258 ?

MITRE publie la définition canonique à https://cwe.mitre.org/data/definitions/1258.html. Vous pouvez également consulter la documentation OWASP et NIST pour des conseils adjacents.

Faiblesses associées

Weaknesses related to CWE-1258

CWE-212 Parent

Improper Removal of Sensitive Information Before Storage or Transfer

This vulnerability occurs when an application stores or transmits a resource containing sensitive data without properly cleaning it first,…

CWE-226 Frère

Sensitive Information in Resource Not Removed Before Reuse

This vulnerability occurs when a system releases a resource like memory or a file for reuse but fails to erase the sensitive data it…

Ressources

Further reading

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