| CVE |
Vendors |
Products |
Updated |
CVSS v3.1 |
| A vulnerability has been identified in RUGGEDCOM i800 (All versions), RUGGEDCOM i801 (All versions), RUGGEDCOM i802 (All versions), RUGGEDCOM i803 (All versions), RUGGEDCOM M2100 (All versions), RUGGEDCOM M2200 (All versions), RUGGEDCOM M969 (All versions), RUGGEDCOM RMC30 (All versions), RUGGEDCOM RMC8388 V4.X (All versions), RUGGEDCOM RMC8388 V5.X (All versions < V5.10.0), RUGGEDCOM RP110 (All versions), RUGGEDCOM RS1600 (All versions), RUGGEDCOM RS1600F (All versions), RUGGEDCOM RS1600T (All versions), RUGGEDCOM RS400 (All versions), RUGGEDCOM RS401 (All versions), RUGGEDCOM RS416 (All versions), RUGGEDCOM RS416P (All versions), RUGGEDCOM RS416Pv2 V4.X (All versions), RUGGEDCOM RS416Pv2 V5.X (All versions < V5.10.0), RUGGEDCOM RS416v2 V4.X (All versions), RUGGEDCOM RS416v2 V5.X (All versions < V5.10.0), RUGGEDCOM RS8000 (All versions), RUGGEDCOM RS8000A (All versions), RUGGEDCOM RS8000H (All versions), RUGGEDCOM RS8000T (All versions), RUGGEDCOM RS900 (All versions), RUGGEDCOM RS900 (32M) V4.X (All versions), RUGGEDCOM RS900 (32M) V5.X (All versions < V5.10.0), RUGGEDCOM RS900G (All versions), RUGGEDCOM RS900G (32M) V4.X (All versions), RUGGEDCOM RS900G (32M) V5.X (All versions < V5.10.0), RUGGEDCOM RS900GP (All versions), RUGGEDCOM RS900L (All versions), RUGGEDCOM RS900M-GETS-C01 (All versions), RUGGEDCOM RS900M-GETS-XX (All versions), RUGGEDCOM RS900M-STND-C01 (All versions), RUGGEDCOM RS900M-STND-XX (All versions), RUGGEDCOM RS900W (All versions), RUGGEDCOM RS910 (All versions), RUGGEDCOM RS910L (All versions), RUGGEDCOM RS910W (All versions), RUGGEDCOM RS920L (All versions), RUGGEDCOM RS920W (All versions), RUGGEDCOM RS930L (All versions), RUGGEDCOM RS930W (All versions), RUGGEDCOM RS940G (All versions), RUGGEDCOM RS969 (All versions), RUGGEDCOM RSG2100 (All versions), RUGGEDCOM RSG2100 (32M) V4.X (All versions), RUGGEDCOM RSG2100 (32M) V5.X (All versions < V5.10.0), RUGGEDCOM RSG2100P (All versions), RUGGEDCOM RSG2100P (32M) V4.X (All versions), RUGGEDCOM RSG2100P (32M) V5.X (All versions < V5.10.0), RUGGEDCOM RSG2200 (All versions), RUGGEDCOM RSG2288 V4.X (All versions), RUGGEDCOM RSG2288 V5.X (All versions < V5.10.0), RUGGEDCOM RSG2300 V4.X (All versions), RUGGEDCOM RSG2300 V5.X (All versions < V5.10.0), RUGGEDCOM RSG2300P V4.X (All versions), RUGGEDCOM RSG2300P V5.X (All versions < V5.10.0), RUGGEDCOM RSG2488 V4.X (All versions), RUGGEDCOM RSG2488 V5.X (All versions < V5.10.0), RUGGEDCOM RSG907R (All versions < V5.10.0), RUGGEDCOM RSG908C (All versions < V5.10.0), RUGGEDCOM RSG909R (All versions < V5.10.0), RUGGEDCOM RSG910C (All versions < V5.10.0), RUGGEDCOM RSG920P V4.X (All versions), RUGGEDCOM RSG920P V5.X (All versions < V5.10.0), RUGGEDCOM RSL910 (All versions < V5.10.0), RUGGEDCOM RST2228 (All versions < V5.10.0), RUGGEDCOM RST2228P (All versions < V5.10.0), RUGGEDCOM RST916C (All versions < V5.10.0), RUGGEDCOM RST916P (All versions < V5.10.0). The affected devices support the TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA256 cipher suite, which uses CBC (Cipher Block Chaining) mode that is known to be vulnerable to timing attacks. This could allow an attacker to compromise the integrity and confidentiality of encrypted communications. |
| An Improper Authorization vulnerability was identified in the EOL OVA based connect component which is deployed for installation purposes in the customer internal network. Under certain conditions, this could allow a bad actor to gain unauthorized access to the local db containing weakly hashed credentials of the installer. This EOL component was deprecated in September 2023 with end of support extended till January 2024. |
| Deck Mate 2's firmware update mechanism accepts packages without cryptographic signature verification, encrypts them with a single hard-coded AES key shared across devices, and uses a truncated HMAC for integrity validation. Attackers with access to the update interface - typically via the unit's USB update port - can craft or modify firmware packages to execute arbitrary code as root, allowing persistent compromise of the device's integrity and deck randomization process. Physical or on-premises access remains the most likely attack path, though network-exposed or telemetry-enabled deployments could theoretically allow remote exploitation if misconfigured. The vendor confirmed that firmware updates have been issued to correct these update-chain weaknesses and that USB update access has been disabled on affected units. |
| Use of hard-coded cryptographic key vulnerability in i-PRO Configuration Tool affects the network system for i-PRO Co., Ltd. surveillance cameras and recorders. This vulnerability allows a local authenticated attacker to use the authentication information from the last connected surveillance cameras and recorders. |
| An unauthenticated remote attacker could exploit the used, insecure TLS 1.0 and TLS 1.1 protocols to intercept and manipulate encrypted communications between the Com-Server and connected systems. |
| SmartOS, as used in Triton Data Center and other products, has static host SSH keys in the 60f76fd2-143f-4f57-819b-1ae32684e81b image (a Debian 12 LX zone image from 2024-07-26). |
| Dpanel is a Docker visualization panel system which provides complete Docker management functions. The Dpanel service contains a hardcoded JWT secret in its default configuration, allowing attackers to generate valid JWT tokens and compromise the host machine. This security flaw allows attackers to analyze the source code, discover the embedded secret, and craft legitimate JWT tokens. By forging these tokens, an attacker can successfully bypass authentication mechanisms, impersonate privileged users, and gain unauthorized administrative access. Consequently, this enables full control over the host machine, potentially leading to severe consequences such as sensitive data exposure, unauthorized command execution, privilege escalation, or further lateral movement within the network environment. This issue is patched in version 1.6.1. A workaround for this vulnerability involves replacing the hardcoded secret with a securely generated value and load it from secure configuration storage. |
| Besu Native contains scripts and tooling that is used to build and package the native libraries used by the Ethereum client Hyperledger Besu. Besu 24.7.1 through 25.2.2, corresponding to besu-native versions 0.9.0 through 1.2.1, have a potential consensus bug for the precompiles ALTBN128_ADD (0x06), ALTBN128_MUL (0x07), and ALTBN128_PAIRING (0x08). These precompiles were reimplemented in besu-native using gnark-crypto's bn254 implementation, as the former implementation used a library which was no longer maintained and not sufficiently performant. The new gnark implementation was initially added in version 0.9.0 of besu-native but was not utilized by Besu until version 0.9.2 in Besu 24.7.1. The issue is that there are EC points which may be crafted which are in the correct subgroup but are not on the curve and the besu-native gnark implementation was relying on subgroup checks to perform point-on-curve checks as well. The version of gnark-crypto used at the time did not do this check when performing subgroup checks. The result is that it was possible for Besu to give an incorrect result and fall out of consensus when executing one of these precompiles against a specially crafted input point. Additionally, homogenous Besu-only networks can potentially enshrine invalid state which would be incorrect and difficult to process with patched versions of besu which handle these calls correctly. The underlying defect has been patched in besu-native release 1.3.0. The fixed version of Besu is version 25.3.0. As a workaround for versions of Besu with the problem, the native precompile for altbn128 may be disabled in favor of the pure-java implementation. The pure java implementation is significantly slower, but does not have this consensus issue. |
| A vulnerability was found in Netis WF-2404 1.1.124EN. It has been rated as problematic. This issue affects some unknown processing of the file /еtc/passwd. The manipulation leads to use of weak hash. It is possible to launch the attack on the physical device. The complexity of an attack is rather high. The exploitation is known to be difficult. The exploit has been disclosed to the public and may be used. The vendor was contacted early about this disclosure but did not respond in any way. |
| The device uses a weak hashing alghorithm to create the password hash. Hence, a matching password can be easily calculated by an attacker. This impacts the security and the integrity of the device. |
| There is a configuration defect vulnerability in ZTELink 5.4.9 for iOS. This vulnerability is caused by a flaw in the WiFi parameter configuration of the ZTELink. An attacker can obtain unauthorized access to the WiFi service. |
| Vulnerability in Best Practical Solutions, LLC's Request Tracker prior to v5.0.8, where the Triple DES (3DES) cryptographic algorithm is used to protect emails sent with S/MIME encryption. Triple DES is considered obsolete and insecure due to its susceptibility to birthday attacks, which could compromise the confidentiality of encrypted messages. |
| Inadequate encryption strength for some Edge Orchestrator software for Intel(R) Tiber™ Edge Platform may allow an authenticated user to potentially enable escalation of privilege via adjacent access. |
| LangChain4j-AIDeepin is a Retrieval enhancement generation (RAG) project. Prior to 3.5.0, LangChain4j-AIDeepin uses MD5 to hash files, which may cause file upload conflicts. This issue is fixed in 3.5.0. |
| Missing cryptographic key commitment in the Amazon S3 Encryption Client for Go may allow a user with write access to the S3 bucket to introduce a new EDK that decrypts to different plaintext when the encrypted data key is stored in an "instruction file" instead of S3's metadata record.
To mitigate this issue, upgrade Amazon S3 Encryption Client for Go to version 4.0 or later. |
| Missing cryptographic key commitment in the Amazon S3 Encryption Client for Java may allow a user with write access to the S3 bucket to introduce a new EDK that decrypts to different plaintext when the encrypted data key is stored in an "instruction file" instead of S3's metadata record.
To mitigate this issue, upgrade Amazon S3 Encryption Client for Java to version 4.0.0 or later. |
| Missing cryptographic key commitment in the AWS SDK for Ruby may allow a user with write access to the S3 bucket to introduce a new EDK that decrypts to different plaintext when the encrypted data key is stored in an "instruction file" instead of S3's metadata record.
To mitigate this issue, upgrade AWS SDK for Ruby to version 1.208.0 or later. |
| Missing cryptographic key commitment in the AWS SDK for PHP may allow a user with write access to the S3 bucket to introduce a new EDK that decrypts to different plaintext when the encrypted data key is stored in an "instruction file" instead of S3's metadata record.
To mitigate this issue, upgrade AWS SDK for PHP to version 3.368.0 or later |
| Missing cryptographic key commitment in the AWS SDK for C++ may allow a user with write access to the S3 bucket to introduce a new EDK that decrypts to different plaintext when the encrypted data key is stored in an "instruction file" instead of S3's metadata record.
To mitigate this issue, upgrade AWS SDK for C++ to version 1.11.712 or later |
| Missing cryptographic key commitment in the Amazon S3 Encryption Client for .NET may allow a user with write access to the S3 bucket to introduce a new EDK that decrypts to different plaintext when the encrypted data key is stored in an "instruction file" instead of S3's metadata record.
To mitigate this issue, upgrade Amazon S3 Encryption Client for .NET to version 3.2.0 or later. |