CVE Vulnerabilities

CVE-2020-11268

Improper Input Validation

Published: May 07, 2021 | Modified: May 14, 2021
CVSS 3.x
7.5
HIGH
Source:
NVD
CVSS:3.1/AV:N/AC:L/PR:N/UI:N/S:U/C:N/I:N/A:H
CVSS 2.x
5 MEDIUM
AV:N/AC:L/Au:N/C:N/I:N/A:P
RedHat/V2
RedHat/V3
Ubuntu

Potential UE reset while decoding a crafted Sib1 or SIB1 that schedules unsupported SIBs and can lead to denial of service in Snapdragon Auto, Snapdragon Mobile

Weakness

The product receives input or data, but it does not validate or incorrectly validates that the input has the properties that are required to process the data safely and correctly.

Affected Software

Name Vendor Start Version End Version
Apq8009 Qualcomm - (including) - (including)
Apq8016 Qualcomm - (including) - (including)
Apq8074 Qualcomm - (including) - (including)
Apq8084 Qualcomm - (including) - (including)
Apq8094 Qualcomm - (including) - (including)
Ar6003 Qualcomm - (including) - (including)
Mdm8215 Qualcomm - (including) - (including)
Mdm8215m Qualcomm - (including) - (including)
Mdm8615m Qualcomm - (including) - (including)
Mdm9215 Qualcomm - (including) - (including)
Mdm9235m Qualcomm - (including) - (including)
Mdm9310 Qualcomm - (including) - (including)
Mdm9609 Qualcomm - (including) - (including)
Mdm9615 Qualcomm - (including) - (including)
Mdm9615m Qualcomm - (including) - (including)
Mdm9635m Qualcomm - (including) - (including)
Mdm9640 Qualcomm - (including) - (including)
Mdm9645 Qualcomm - (including) - (including)
Msm8108 Qualcomm - (including) - (including)
Msm8208 Qualcomm - (including) - (including)
Msm8209 Qualcomm - (including) - (including)
Msm8216 Qualcomm - (including) - (including)
Msm8274 Qualcomm - (including) - (including)
Msm8608 Qualcomm - (including) - (including)
Msm8674 Qualcomm - (including) - (including)
Msm8916 Qualcomm - (including) - (including)
Msm8929 Qualcomm - (including) - (including)
Msm8939 Qualcomm - (including) - (including)
Msm8974 Qualcomm - (including) - (including)
Msm8974p Qualcomm - (including) - (including)
Msm8994 Qualcomm - (including) - (including)
Pm8018 Qualcomm - (including) - (including)
Pm8841 Qualcomm - (including) - (including)
Pm8909 Qualcomm - (including) - (including)
Pm8916 Qualcomm - (including) - (including)
Pm8941 Qualcomm - (including) - (including)
Pm8994 Qualcomm - (including) - (including)
Pmd9635 Qualcomm - (including) - (including)
Pmd9645 Qualcomm - (including) - (including)
Pmi8994 Qualcomm - (including) - (including)
Qca1990 Qualcomm - (including) - (including)
Qca6174 Qualcomm - (including) - (including)
Qca6174a Qualcomm - (including) - (including)
Qca6584 Qualcomm - (including) - (including)
Qfe1035 Qualcomm - (including) - (including)
Qfe1040 Qualcomm - (including) - (including)
Qfe1045 Qualcomm - (including) - (including)
Qfe1100 Qualcomm - (including) - (including)
Qfe1101 Qualcomm - (including) - (including)
Qfe1520 Qualcomm - (including) - (including)
Qfe1550 Qualcomm - (including) - (including)
Qfe2101 Qualcomm - (including) - (including)
Qfe2310 Qualcomm - (including) - (including)
Qfe2320 Qualcomm - (including) - (including)
Qfe2330 Qualcomm - (including) - (including)
Qfe2340 Qualcomm - (including) - (including)
Qfe2520 Qualcomm - (including) - (including)
Qfe2550 Qualcomm - (including) - (including)
Qfe2720 Qualcomm - (including) - (including)
Qfe3100 Qualcomm - (including) - (including)
Qfe3320 Qualcomm - (including) - (including)
Qfe3335 Qualcomm - (including) - (including)
Qfe3340 Qualcomm - (including) - (including)
Qfe3345 Qualcomm - (including) - (including)
Sd210 Qualcomm - (including) - (including)
Smb1360 Qualcomm - (including) - (including)
Wcd9306 Qualcomm - (including) - (including)
Wcd9330 Qualcomm - (including) - (including)
Wcn3610 Qualcomm - (including) - (including)
Wcn3620 Qualcomm - (including) - (including)
Wcn3660 Qualcomm - (including) - (including)
Wcn3660a Qualcomm - (including) - (including)
Wcn3660b Qualcomm - (including) - (including)
Wcn3680 Qualcomm - (including) - (including)
Wcn3680b Qualcomm - (including) - (including)
Wfr1620 Qualcomm - (including) - (including)
Wgr7640 Qualcomm - (including) - (including)
Wtr1605 Qualcomm - (including) - (including)
Wtr1605l Qualcomm - (including) - (including)
Wtr1625 Qualcomm - (including) - (including)
Wtr1625l Qualcomm - (including) - (including)
Wtr2605 Qualcomm - (including) - (including)
Wtr2955 Qualcomm - (including) - (including)
Wtr3925 Qualcomm - (including) - (including)
Wtr4605 Qualcomm - (including) - (including)
Wtr4905 Qualcomm - (including) - (including)

Extended Description

Input validation is a frequently-used technique for checking potentially dangerous inputs in order to ensure that the inputs are safe for processing within the code, or when communicating with other components. When software does not validate input properly, an attacker is able to craft the input in a form that is not expected by the rest of the application. This will lead to parts of the system receiving unintended input, which may result in altered control flow, arbitrary control of a resource, or arbitrary code execution. Input validation is not the only technique for processing input, however. Other techniques attempt to transform potentially-dangerous input into something safe, such as filtering (CWE-790) - which attempts to remove dangerous inputs - or encoding/escaping (CWE-116), which attempts to ensure that the input is not misinterpreted when it is included in output to another component. Other techniques exist as well (see CWE-138 for more examples.) Input validation can be applied to:

Data can be simple or structured. Structured data can be composed of many nested layers, composed of combinations of metadata and raw data, with other simple or structured data. Many properties of raw data or metadata may need to be validated upon entry into the code, such as:

Implied or derived properties of data must often be calculated or inferred by the code itself. Errors in deriving properties may be considered a contributing factor to improper input validation.

Note that “input validation” has very different meanings to different people, or within different classification schemes. Caution must be used when referencing this CWE entry or mapping to it. For example, some weaknesses might involve inadvertently giving control to an attacker over an input when they should not be able to provide an input at all, but sometimes this is referred to as input validation. Finally, it is important to emphasize that the distinctions between input validation and output escaping are often blurred, and developers must be careful to understand the difference, including how input validation is not always sufficient to prevent vulnerabilities, especially when less stringent data types must be supported, such as free-form text. Consider a SQL injection scenario in which a person’s last name is inserted into a query. The name “O’Reilly” would likely pass the validation step since it is a common last name in the English language. However, this valid name cannot be directly inserted into the database because it contains the “’” apostrophe character, which would need to be escaped or otherwise transformed. In this case, removing the apostrophe might reduce the risk of SQL injection, but it would produce incorrect behavior because the wrong name would be recorded.

Potential Mitigations

  • Assume all input is malicious. Use an “accept known good” input validation strategy, i.e., use a list of acceptable inputs that strictly conform to specifications. Reject any input that does not strictly conform to specifications, or transform it into something that does.
  • When performing input validation, consider all potentially relevant properties, including length, type of input, the full range of acceptable values, missing or extra inputs, syntax, consistency across related fields, and conformance to business rules. As an example of business rule logic, “boat” may be syntactically valid because it only contains alphanumeric characters, but it is not valid if the input is only expected to contain colors such as “red” or “blue.”
  • Do not rely exclusively on looking for malicious or malformed inputs. This is likely to miss at least one undesirable input, especially if the code’s environment changes. This can give attackers enough room to bypass the intended validation. However, denylists can be useful for detecting potential attacks or determining which inputs are so malformed that they should be rejected outright.
  • For any security checks that are performed on the client side, ensure that these checks are duplicated on the server side, in order to avoid CWE-602. Attackers can bypass the client-side checks by modifying values after the checks have been performed, or by changing the client to remove the client-side checks entirely. Then, these modified values would be submitted to the server.
  • Even though client-side checks provide minimal benefits with respect to server-side security, they are still useful. First, they can support intrusion detection. If the server receives input that should have been rejected by the client, then it may be an indication of an attack. Second, client-side error-checking can provide helpful feedback to the user about the expectations for valid input. Third, there may be a reduction in server-side processing time for accidental input errors, although this is typically a small savings.
  • Inputs should be decoded and canonicalized to the application’s current internal representation before being validated (CWE-180, CWE-181). Make sure that your application does not inadvertently decode the same input twice (CWE-174). Such errors could be used to bypass allowlist schemes by introducing dangerous inputs after they have been checked. Use libraries such as the OWASP ESAPI Canonicalization control.
  • Consider performing repeated canonicalization until your input does not change any more. This will avoid double-decoding and similar scenarios, but it might inadvertently modify inputs that are allowed to contain properly-encoded dangerous content.

References