mirror of
https://github.com/Mbed-TLS/mbedtls.git
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04fa1a4054
Signed-off-by: Janos Follath <janos.follath@arm.com>
138 lines
5.8 KiB
Markdown
138 lines
5.8 KiB
Markdown
## Reporting Vulnerabilities
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If you think you have found an Mbed TLS security vulnerability, then please
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send an email to the security team at
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<mbed-tls-security@lists.trustedfirmware.org>.
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## Security Incident Handling Process
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Our security process is detailed in our
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[security
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center](https://developer.trustedfirmware.org/w/mbed-tls/security-center/).
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Its primary goal is to ensure fixes are ready to be deployed when the issue
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goes public.
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## Maintained branches
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Only the maintained branches, as listed in [`BRANCHES.md`](BRANCHES.md),
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get security fixes.
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Users are urged to always use the latest version of a maintained branch.
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## Threat model
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We classify attacks based on the capabilities of the attacker.
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### Remote attacks
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In this section, we consider an attacker who can observe and modify data sent
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over the network. This includes observing the content and timing of individual
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packets, as well as suppressing or delaying legitimate messages, and injecting
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messages.
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Mbed TLS aims to fully protect against remote attacks and to enable the user
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application in providing full protection against remote attacks. Said
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protection is limited to providing security guarantees offered by the protocol
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being implemented. (For example Mbed TLS alone won't guarantee that the
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messages will arrive without delay, as the TLS protocol doesn't guarantee that
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either.)
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**Warning!** Block ciphers do not yet achieve full protection against attackers
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who can measure the timing of packets with sufficient precision. For details
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and workarounds see the [Block Ciphers](#block-ciphers) section.
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### Local attacks
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In this section, we consider an attacker who can run software on the same
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machine. The attacker has insufficient privileges to directly access Mbed TLS
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assets such as memory and files.
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#### Timing attacks
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The attacker is able to observe the timing of instructions executed by Mbed TLS
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by leveraging shared hardware that both Mbed TLS and the attacker have access
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to. Typical attack vectors include cache timings, memory bus contention and
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branch prediction.
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Mbed TLS provides limited protection against timing attacks. The cost of
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protecting against timing attacks widely varies depending on the granularity of
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the measurements and the noise present. Therefore the protection in Mbed TLS is
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limited. We are only aiming to provide protection against **publicly
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documented attack techniques**.
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As attacks keep improving, so does Mbed TLS's protection. Mbed TLS is moving
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towards a model of fully timing-invariant code, but has not reached this point
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yet.
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**Remark:** Timing information can be observed over the network or through
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physical side channels as well. Remote and physical timing attacks are covered
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in the [Remote attacks](remote-attacks) and [Physical
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attacks](physical-attacks) sections respectively.
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**Warning!** Block ciphers do not yet achieve full protection. For
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details and workarounds see the [Block Ciphers](#block-ciphers) section.
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#### Local non-timing side channels
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The attacker code running on the platform has access to some sensor capable of
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picking up information on the physical state of the hardware while Mbed TLS is
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running. This could for example be an analogue-to-digital converter on the
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platform that is located unfortunately enough to pick up the CPU noise.
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Mbed TLS doesn't make any security guarantees against local non-timing-based
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side channel attacks. If local non-timing attacks are present in a use case or
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a user application's threat model, they need to be mitigated by the platform.
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#### Local fault injection attacks
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Software running on the same hardware can affect the physical state of the
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device and introduce faults.
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Mbed TLS doesn't make any security guarantees against local fault injection
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attacks. If local fault injection attacks are present in a use case or a user
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application's threat model, they need to be mitigated by the platform.
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### Physical attacks
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In this section, we consider an attacker who has access to physical information
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about the hardware Mbed TLS is running on and/or can alter the physical state
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of the hardware (e.g. power analysis, radio emissions or fault injection).
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Mbed TLS doesn't make any security guarantees against physical attacks. If
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physical attacks are present in a use case or a user application's threat
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model, they need to be mitigated by physical countermeasures.
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### Caveats
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#### Out-of-scope countermeasures
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Mbed TLS has evolved organically and a well defined threat model hasn't always
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been present. Therefore, Mbed TLS might have countermeasures against attacks
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outside the above defined threat model.
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The presence of such countermeasures don't mean that Mbed TLS provides
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protection against a class of attacks outside of the above described threat
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model. Neither does it mean that the failure of such a countermeasure is
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considered a vulnerability.
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#### Block ciphers
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Currently there are four block ciphers in Mbed TLS: AES, CAMELLIA, ARIA and
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DES. The pure software implementation in Mbed TLS implementation uses lookup
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tables, which are vulnerable to timing attacks.
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These timing attacks can be physical, local or depending on network latency
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even a remote. The attacks can result in key recovery.
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**Workarounds:**
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- Turn on hardware acceleration for AES. This is supported only on selected
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architectures and currently only available for AES. See configuration options
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`MBEDTLS_AESCE_C`, `MBEDTLS_AESNI_C` and `MBEDTLS_PADLOCK_C` for details.
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- Add a secure alternative implementation (typically hardware acceleration) for
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the vulnerable cipher. See the [Alternative Implementations
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Guide](docs/architecture/alternative-implementations.md) for more information.
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- Use cryptographic mechanisms that are not based on block ciphers. In
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particular, for authenticated encryption, use ChaCha20/Poly1305 instead of
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block cipher modes. For random generation, use HMAC\_DRBG instead of CTR\_DRBG.
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