| CVE |
Vendors |
Products |
Updated |
CVSS v3.1 |
| Sharp Zaurus PDA SL-5000D and SL-5500 uses a salt of "A0" to encrypt the screen-locking password as stored in the Security.conf file, which makes it easier for local users to guess the password via brute force methods. |
| Spectrum Cash Receipting System before 6.504 uses weak cryptography (static substitution) in the PASSFILE password file, which makes it easier for local users to gain privileges by decrypting a password. |
| Pathways Homecare 6.5 uses weak encryption for user names and passwords, which allows local users to gain privileges by recovering the passwords from the pwhc.ini file. |
| Microsoft SQL Server 6.0 through 2000, with SQL Authentication enabled, uses weak password encryption (XOR), which allows remote attackers to sniff and decrypt the password. |
| Videsh Sanchar Nigam Limited (VSNL) Integrated Dialer Software 1.2.000, when the "Save Password" option is used, stores the password with a weak encryption scheme (one-to-one mapping) in a registry key, which allows local users to obtain and decrypt the password. |
| Alt-N Technologies Mdaemon 5.0 through 5.0.6 uses a weak encryption algorithm to store user passwords, which allows local users to crack passwords. |
| Click2Learn Ingenium Learning Management System 5.1 and 6.1 uses weak encryption for passwords (reversible algorithm), which allows attackers to obtain passwords. |
| Electronic Code Book (ECB) mode in VTun 2.0 through 2.5 uses a weak encryption algorithm that produces the same ciphertext from the same plaintext blocks, which could allow remote attackers to gain sensitive information. |
| The integrity check feature in OpenPGP, when handling a message that was encrypted using cipher feedback (CFB) mode, allows remote attackers to recover part of the plaintext via a chosen-ciphertext attack when the first 2 bytes of a message block are known, and an oracle or other mechanism is available to determine whether an integrity check failed. |
| TeeKai Tracking Online 1.0 uses weak encryption of web usage statistics in data/userlog/log.txt, which allows remote attackers to identify IP's visiting the site by dividing each octet by the MD5 hash of '20'. |
| Use of Hard-coded Cryptographic Key vulnerability in Apache OpenMeetings.
The remember-me cookie encryption key is set to default value in openmeetings.properties and not being auto-rotated. In case OM admin hasn't changed the default encryption key, an attacker who has stolen a cookie from a logged-in user can get full user credentials.
This issue affects Apache OpenMeetings: from 6.1.0 before 9.0.0.
Users are recommended to upgrade to version 9.0.0, which fixes the issue. |
| 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. |
| An issue was discovered in Kaseya Rapid Fire Tools Network Detective through 2.0.16.0. A vulnerability exists in the EncryptionUtil class because symmetric encryption is implemented in a deterministic and non-randomized fashion. The method Encrypt(byte[] clearData) derives both the encryption key and the IV from a fixed, hardcoded input by using a static salt value. As a result, identical plaintext inputs always produce identical ciphertext outputs. This is true for both FIPS and non-FIPS generated passwords. In other words, there is a cryptographic implementation flaw in the password encryption mechanism. Although there are multiple encryption methods grouped under FIPS and non-FIPS classifications, the logic consistently results in predictable and reversible encrypted outputs due to the lack of per-operation randomness and encryption authentication. |
| A private key disclosure vulnerability exists in ZTE's ZXMP M721 product. A low-privileged user can bypass authorization checks to view the device's communication private key, resulting in key exposure and impacting communication security. |
| The devices are vulnerable to an authentication bypass due to flaws in the authorization mechanism. An unauthenticated remote attacker could exploit this weakness by performing brute-force attacks to guess valid credentials or by using MD5 collision techniques to forge authentication hashes, potentially compromising the device. |
| A vulnerability has been identified in SIMATIC RTLS Locating Manager (6GT2780-0DA00) (All versions < V3.0.1.1), SIMATIC RTLS Locating Manager (6GT2780-0DA10) (All versions < V3.0.1.1), SIMATIC RTLS Locating Manager (6GT2780-0DA20) (All versions < V3.0.1.1), SIMATIC RTLS Locating Manager (6GT2780-0DA30) (All versions < V3.0.1.1), SIMATIC RTLS Locating Manager (6GT2780-1EA10) (All versions < V3.0.1.1), SIMATIC RTLS Locating Manager (6GT2780-1EA20) (All versions < V3.0.1.1), SIMATIC RTLS Locating Manager (6GT2780-1EA30) (All versions < V3.0.1.1). The affected systems use symmetric cryptography with a hard-coded key to protect the communication between client and server. This could allow an unauthenticated remote attacker to compromise confidentiality and integrity of the communication and, subsequently, availability of the system.
A successful exploit requires the attacker to gain knowledge of the hard-coded key and to be able to intercept the communication between client and server on the network. |
| 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 products support insecure cryptographic algorithms. An attacker could leverage these legacy algorithms to achieve a man-in-the-middle attack or impersonate communicating parties. |
| Versions of the package cocoon before 0.4.0 are vulnerable to Reusing a Nonce, Key Pair in Encryption when the encrypt, wrap, and dump functions are sequentially called. An attacker can generate the same ciphertext by creating a new encrypted message with the same cocoon object.
**Note:**
The issue does NOT affect objects created with Cocoon::new which utilizes ThreadRng. |
| gitoxide is an implementation of git written in Rust. Before 0.42.0, gitoxide uses SHA-1 hash implementations without any collision detection, leaving it vulnerable to hash collision attacks. gitoxide uses the sha1_smol or sha1 crate, both of which implement standard SHA-1 without any mitigations for collision attacks. This means that two distinct Git objects with colliding SHA-1 hashes would break the Git object model and integrity checks when used with gitoxide. This vulnerability is fixed in 0.42.0. |
| Inadequate encryption strength for some Edge Orchestrator software for Intel(R) Tiberâ„¢ Edge Platform may allow an authenticated user to potentially enable escalation of privilege via adjacent access. |
