CWE-1247 Base Estável

Improper Protection Against Voltage and Clock Glitches

This vulnerability occurs when a hardware device lacks proper physical safeguards against deliberate electrical manipulation. Without dedicated protection circuits or sensors, attackers can use…

Definição

What is CWE-1247?

This vulnerability occurs when a hardware device lacks proper physical safeguards against deliberate electrical manipulation. Without dedicated protection circuits or sensors, attackers can use voltage spikes or irregular clock signals to bypass security features, potentially exposing sensitive data or taking control of the system.
Modern devices often rely on hardware-backed security features like secure boot, which establishes a chain of trust from immutable firmware up to the operating system. These features depend on stable electrical conditions to function correctly. However, attackers can physically induce faults by manipulating the device's power supply or clock timing, causing the hardware to skip critical security checks or behave unpredictably, thereby breaking the chain of trust. Effective protection requires dedicated on-chip circuitry—such as voltage monitors, clock glitch detectors, and timing sensors—that can detect anomalies and trigger immediate countermeasures. These hardware defenses work alongside firmware to secure debug interfaces, enforce access controls, and maintain system integrity even under physical attack, ensuring that security logic cannot be bypassed through simple electrical manipulation.
Impacto no mundo real

Real-world CVEs caused by CWE-1247

  • Lack of anti-glitch protections allows an attacker to launch a physical attack to bypass the secure boot and read protected eFuses.

  • IP communication firmware allows access to a boot shell via certain impulses

Como os atacantes a exploram

Trajeto do atacante passo a passo

  1. 1

    Identificar um caminho de código que trata input não confiável sem validação.

  2. 2

    Criar um payload que explora o comportamento inseguro — injeção, traversal, overflow ou abuso de lógica.

  3. 3

    Entregar o payload através de um pedido normal e observar a reação da aplicação.

  4. 4

    Iterar até que a resposta exponha dados, execute código do atacante ou escale privilégios.

Exemplo de código vulnerável

Vulnerable C

Below is a representative snippet of C code that is part of the secure-boot flow. A signature of the runtime-firmware image is calculated and compared against a golden value. If the signatures match, the bootloader loads runtime firmware. If there is no match, an error halt occurs. If the underlying hardware executing this code does not contain any circuitry or sensors to detect voltage or clock glitches, an attacker might launch a fault-injection attack right when the signature check is happening (at the location marked with the comment), causing a bypass of the signature-checking process.

Vulnerável C
...
 if (signature_matches) // <-Glitch Here
 {

```
   load_runtime_firmware();
 }
 else
 {
   do_not_load_runtime_firmware();
 }
 ...
Exemplo de código seguro

Secure code

After bypassing secure boot, an attacker can gain access to system assets to which the attacker should not have access.

Seguro
If the underlying hardware detects a voltage or clock glitch, the information can be used to prevent the glitch from being successful.
What changed: the unsafe sink is replaced (or the input is validated/escaped) so the same payload no longer triggers the weakness.
Lista de verificação de prevenção

How to prevent CWE-1247

  • Architecture and Design / Implementation At the circuit-level, using Tunable Replica Circuits (TRCs) or special flip-flops such as Razor flip-flops helps mitigate glitch attacks. Working at the SoC or platform base, level sensors may be implemented to detect glitches. Implementing redundancy in security-sensitive code (e.g., where checks are performed)also can help with mitigation of glitch attacks.
Sinais de deteção

How to detect CWE-1247

Manual Analysis Moderate

Put the processor in an infinite loop, which is then followed by instructions that should not ever be executed, since the loop is not expected to exit. After the loop, toggle an I/O bit (for oscilloscope monitoring purposes), print a console message, and reenter the loop. Note that to ensure that the loop exit is actually captured, many NOP instructions should be coded after the loop branch instruction and before the I/O bit toggle and the print statement. Margining the clock consists of varying the clock frequency until an anomaly occurs. This could be a continuous frequency change or it could be a single cycle. The single cycle method is described here. For every 1000th clock pulse, the clock cycle is shortened by 10 percent. If no effect is observed, the width is shortened by 20%. This process is continued in 10% increments up to and including 50%. Note that the cycle time may be increased as well, down to seconds per cycle. Separately, the voltage is margined. Note that the voltage could be increased or decreased. Increasing the voltage has limits, as the circuitry may not be able to withstand a drastically increased voltage. This process starts with a 5% reduction of the DC supply to the CPU chip for 5 millisecond repeated at 1KHz. If this has no effect, the process is repeated, but a 10% reduction is used. This process is repeated at 10% increments down to a 50% reduction. If no effects are observed at 5 millisecond, the whole process is repeated using a 10 millisecond pulse. If no effects are observed, the process is repeated in 10 millisecond increments out to 100 millisecond pulses. While these are suggested starting points for testing circuitry for weaknesses, the limits may need to be pushed further at the risk of device damage. See [REF-1217] for descriptions of Smart Card attacks against a clock (section 14.6.2) and using a voltage glitch (section 15.5.3).

Dynamic Analysis with Manual Results Interpretation

During the implementation phase where actual hardware is available, specialized hardware tools and apparatus such as ChipWhisperer may be used to check if the platform is indeed susceptible to voltage and clock glitching attacks.

Architecture or Design Review

Review if the protections against glitching merely transfer the attack target. For example, suppose a critical authentication routine that an attacker would want to bypass is given the protection of modifying certain artifacts from within that specific routine (so that if the routine is bypassed, one can examine the artifacts and figure out that an attack must have happened). However, if the attacker has the ability to bypass the critical authentication routine, they might also have the ability to bypass the other protection routine that checks the artifacts. Basically, depending on these kind of protections is akin to resorting to "Security by Obscurity".

Architecture or Design Review

Many SoCs come equipped with a built-in Dynamic Voltage and Frequency Scaling (DVFS) that can control the voltage and clocks via software alone. However, there have been demonstrated attacks (like Plundervolt and CLKSCREW) that target this DVFS [REF-1081] [REF-1082]. During the design and implementation phases, one needs to check if the interface to this power management feature is available from unprivileged SW (CWE-1256), which would make the attack very easy.

Correção automática do Plexicus

O Plexicus deteta automaticamente o CWE-1247 e abre um PR de correção em menos de 60 segundos.

O Codex Remedium analisa cada commit, identifica esta fraqueza exata e entrega um pull request pronto para revisão com o patch. Sem tickets. Sem transferências.

Perguntas frequentes

Frequently asked questions

O que é o CWE-1247?

This vulnerability occurs when a hardware device lacks proper physical safeguards against deliberate electrical manipulation. Without dedicated protection circuits or sensors, attackers can use voltage spikes or irregular clock signals to bypass security features, potentially exposing sensitive data or taking control of the system.

Qual a gravidade do CWE-1247?

A MITRE não publicou uma classificação de probabilidade de exploração para esta fraqueza. Trate-a como impacto médio até o seu modelo de ameaças provar o contrário.

Que linguagens ou plataformas são afetadas pelo CWE-1247?

MITRE lists the following affected platforms: Not OS-Specific, Not Architecture-Specific, ICS/OT, System on Chip, Power Management Hardware, Clock/Counter Hardware, Sensor Hardware.

Como posso prevenir o CWE-1247?

At the circuit-level, using Tunable Replica Circuits (TRCs) or special flip-flops such as Razor flip-flops helps mitigate glitch attacks. Working at the SoC or platform base, level sensors may be implemented to detect glitches. Implementing redundancy in security-sensitive code (e.g., where checks are performed)also can help with mitigation of glitch attacks.

Como é que o Plexicus deteta e corrige o CWE-1247?

O motor SAST do Plexicus correlaciona a assinatura de fluxo de dados do CWE-1247 em cada commit. Quando é encontrada uma correspondência, o nosso agente Codex Remedium abre um PR de correção com o código corrigido, testes e um resumo de uma linha para o revisor.

Onde posso saber mais sobre o CWE-1247?

A MITRE publica a definição canónica em https://cwe.mitre.org/data/definitions/1247.html. Pode também consultar a documentação da OWASP e do NIST para orientações adjacentes.

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