| CVE |
Vendors |
Products |
Updated |
CVSS v3.1 |
| A cryptographic authentication bypass vulnerability exists in OneLogin AD Connector prior to 6.1.5 due to the exposure of a tenant’s SSO JWT signing key via the /api/adc/v4/configuration endpoint. An attacker in possession of the signing key can craft valid JWT tokens impersonating arbitrary users within a OneLogin tenant. The tokens allow authentication to the OneLogin SSO portal and all downstream applications federated via SAML or OIDC. This allows full unauthorized access across the victim’s SaaS environment. |
| An improper certificate validation vulnerability exists in AVTECH IP cameras, DVRs, and NVRs due to the use of wget with --no-check-certificate in scripts like SyncCloudAccount.sh and SyncPermit.sh. This exposes HTTPS communications to man-in-the-middle (MITM) attacks. |
| PingOne MFA Integration Kit contains a vulnerability related to the Prompt Users to Set Up MFA configuration. Under certain conditions, this configuration could allow for a new MFA device to be paired with a target user account without requiring second-factor authentication from the target’s existing registered devices. A threat actor might be able to exploit this vulnerability to register their own MFA device with a target user’s account if they have existing knowledge of the target user’s first factor credential. |
| A firmware downgrade vulnerability exists in the OTA Update functionality of GL-Inet GL-AXT1800 4.7.0. A specially crafted .tar file can lead to a firmware downgrade. An attacker can perform a man-in-the-middle attack to trigger this vulnerability. |
| Applications that use spring-boot-loader or spring-boot-loader-classic and contain custom code that performs signature verification of nested jar files may be vulnerable to signature forgery where content that appears to have been signed by one signer has, in fact, been signed by another. |
| An issue pertaining to CWE-295: Improper Certificate Validation was discovered in Ayms node-To master. The application disables TLS/SSL certificate validation by setting 'rejectUnauthorized': false in TLS socket options |
| Authentication bypass by spoofing issue exists in FileMegane versions above 1.0.0.0 prior to 3.4.0.0, which may lead to user impersonation. If exploited, restricted file contents may be accessed. |
| An issue was discovered in AlertEnterprise Guardian 4.1.14.2.2.1. One can bypass manager approval by changing the user ID in a Request%20Building%20Access requestSubmit API call. The vendor has stated that the system is protected by updating to a version equal to or greater than one of the following build numbers: 4.1.12.2.1.19, 4.1.12.5.2.36, 4.1.13.0.60, 4.1.13.2.0.3.39, 4.1.13.2.0.3.41, 4.1.13.2.42, 4.1.13.2.25.44, 4.1.14.0.13, 4.1.14.0.43, 4.1.14.0.48, and 4.1.14.1.5.32. |
| An issue was discovered in the Bouncy Castle Crypto Package For Java before BC TLS Java 1.0.19 (ships with BC Java 1.78, BC Java (LTS) 2.73.6) and before BC FIPS TLS Java 1.0.19. When endpoint identification is enabled in the BCJSSE and an SSL socket is created without an explicit hostname (as happens with HttpsURLConnection), hostname verification could be performed against a DNS-resolved IP address in some situations, opening up a possibility of DNS poisoning. |
| BigFix Patch Download Plug-ins are affected by an insecure protocol support. The application can allow improper handling of SSL certificates validation. |
| Zendesk before 2024-07-02 allows remote attackers to read ticket history via e-mail spoofing, because Cc fields are extracted from incoming e-mail messages and used to grant additional authorization for ticket viewing, the mechanism for detecting spoofed e-mail messages is insufficient, and the support e-mail addresses associated with individual tickets are predictable. |
| An issue was discovered in Samsung eMMC with KLMAG2GE4A and KLM8G1WEMB firmware. Code bypass through Electromagnetic Fault Injection allows an attacker to successfully authenticate and write to the RPMB (Replay Protected Memory Block) area without possessing secret information. |
| A vulnerability has been identified in SCALANCE W1748-1 M12 (6GK5748-1GY01-0AA0), SCALANCE W1748-1 M12 (6GK5748-1GY01-0TA0), SCALANCE W1788-1 M12 (6GK5788-1GY01-0AA0), SCALANCE W1788-2 EEC M12 (6GK5788-2GY01-0TA0), SCALANCE W1788-2 M12 (6GK5788-2GY01-0AA0), SCALANCE W1788-2IA M12 (6GK5788-2HY01-0AA0), SCALANCE W721-1 RJ45 (6GK5721-1FC00-0AA0), SCALANCE W721-1 RJ45 (6GK5721-1FC00-0AB0), SCALANCE W722-1 RJ45 (6GK5722-1FC00-0AA0), SCALANCE W722-1 RJ45 (6GK5722-1FC00-0AB0), SCALANCE W722-1 RJ45 (6GK5722-1FC00-0AC0), SCALANCE W734-1 RJ45 (6GK5734-1FX00-0AA0), SCALANCE W734-1 RJ45 (6GK5734-1FX00-0AA6), SCALANCE W734-1 RJ45 (6GK5734-1FX00-0AB0), SCALANCE W734-1 RJ45 (USA) (6GK5734-1FX00-0AB6), SCALANCE W738-1 M12 (6GK5738-1GY00-0AA0), SCALANCE W738-1 M12 (6GK5738-1GY00-0AB0), SCALANCE W748-1 M12 (6GK5748-1GD00-0AA0), SCALANCE W748-1 M12 (6GK5748-1GD00-0AB0), SCALANCE W748-1 RJ45 (6GK5748-1FC00-0AA0), SCALANCE W748-1 RJ45 (6GK5748-1FC00-0AB0), SCALANCE W761-1 RJ45 (6GK5761-1FC00-0AA0), SCALANCE W761-1 RJ45 (6GK5761-1FC00-0AB0), SCALANCE W774-1 M12 EEC (6GK5774-1FY00-0TA0), SCALANCE W774-1 M12 EEC (6GK5774-1FY00-0TB0), SCALANCE W774-1 RJ45 (6GK5774-1FX00-0AA0), SCALANCE W774-1 RJ45 (6GK5774-1FX00-0AA6), SCALANCE W774-1 RJ45 (6GK5774-1FX00-0AB0), SCALANCE W774-1 RJ45 (6GK5774-1FX00-0AC0), SCALANCE W774-1 RJ45 (USA) (6GK5774-1FX00-0AB6), SCALANCE W778-1 M12 (6GK5778-1GY00-0AA0), SCALANCE W778-1 M12 (6GK5778-1GY00-0AB0), SCALANCE W778-1 M12 EEC (6GK5778-1GY00-0TA0), SCALANCE W778-1 M12 EEC (USA) (6GK5778-1GY00-0TB0), SCALANCE W786-1 RJ45 (6GK5786-1FC00-0AA0), SCALANCE W786-1 RJ45 (6GK5786-1FC00-0AB0), SCALANCE W786-2 RJ45 (6GK5786-2FC00-0AA0), SCALANCE W786-2 RJ45 (6GK5786-2FC00-0AB0), SCALANCE W786-2 RJ45 (6GK5786-2FC00-0AC0), SCALANCE W786-2 SFP (6GK5786-2FE00-0AA0), SCALANCE W786-2 SFP (6GK5786-2FE00-0AB0), SCALANCE W786-2IA RJ45 (6GK5786-2HC00-0AA0), SCALANCE W786-2IA RJ45 (6GK5786-2HC00-0AB0), SCALANCE W788-1 M12 (6GK5788-1GD00-0AA0), SCALANCE W788-1 M12 (6GK5788-1GD00-0AB0), SCALANCE W788-1 RJ45 (6GK5788-1FC00-0AA0), SCALANCE W788-1 RJ45 (6GK5788-1FC00-0AB0), SCALANCE W788-2 M12 (6GK5788-2GD00-0AA0), SCALANCE W788-2 M12 (6GK5788-2GD00-0AB0), SCALANCE W788-2 M12 EEC (6GK5788-2GD00-0TA0), SCALANCE W788-2 M12 EEC (6GK5788-2GD00-0TB0), SCALANCE W788-2 M12 EEC (6GK5788-2GD00-0TC0), SCALANCE W788-2 RJ45 (6GK5788-2FC00-0AA0), SCALANCE W788-2 RJ45 (6GK5788-2FC00-0AB0), SCALANCE W788-2 RJ45 (6GK5788-2FC00-0AC0), SCALANCE WAM763-1 (6GK5763-1AL00-7DA0), SCALANCE WAM766-1 (EU) (6GK5766-1GE00-7DA0), SCALANCE WAM766-1 (US) (6GK5766-1GE00-7DB0), SCALANCE WAM766-1 EEC (EU) (6GK5766-1GE00-7TA0), SCALANCE WAM766-1 EEC (US) (6GK5766-1GE00-7TB0), SCALANCE WUM763-1 (6GK5763-1AL00-3AA0), SCALANCE WUM763-1 (6GK5763-1AL00-3DA0), SCALANCE WUM766-1 (EU) (6GK5766-1GE00-3DA0), SCALANCE WUM766-1 (US) (6GK5766-1GE00-3DB0). This CVE refers to Scenario 2 "Abuse the queue for network disruptions" of CVE-2022-47522.
Affected devices can be tricked into enabling its power-saving mechanisms for a victim client. This could allow a physically proximate attacker to execute disconnection and denial-of-service attacks. |
| A vulnerability has been identified in SCALANCE W721-1 RJ45 (6GK5721-1FC00-0AA0) (All versions), SCALANCE W721-1 RJ45 (6GK5721-1FC00-0AB0) (All versions), SCALANCE W722-1 RJ45 (6GK5722-1FC00-0AA0) (All versions), SCALANCE W722-1 RJ45 (6GK5722-1FC00-0AB0) (All versions), SCALANCE W722-1 RJ45 (6GK5722-1FC00-0AC0) (All versions), SCALANCE W734-1 RJ45 (6GK5734-1FX00-0AA0) (All versions), SCALANCE W734-1 RJ45 (6GK5734-1FX00-0AA6) (All versions), SCALANCE W734-1 RJ45 (6GK5734-1FX00-0AB0) (All versions), SCALANCE W734-1 RJ45 (USA) (6GK5734-1FX00-0AB6) (All versions), SCALANCE W738-1 M12 (6GK5738-1GY00-0AA0) (All versions), SCALANCE W738-1 M12 (6GK5738-1GY00-0AB0) (All versions), SCALANCE W748-1 M12 (6GK5748-1GD00-0AA0) (All versions), SCALANCE W748-1 M12 (6GK5748-1GD00-0AB0) (All versions), SCALANCE W748-1 RJ45 (6GK5748-1FC00-0AA0) (All versions), SCALANCE W748-1 RJ45 (6GK5748-1FC00-0AB0) (All versions), SCALANCE W761-1 RJ45 (6GK5761-1FC00-0AA0) (All versions), SCALANCE W761-1 RJ45 (6GK5761-1FC00-0AB0) (All versions), SCALANCE W774-1 M12 EEC (6GK5774-1FY00-0TA0) (All versions), SCALANCE W774-1 M12 EEC (6GK5774-1FY00-0TB0) (All versions), SCALANCE W774-1 RJ45 (6GK5774-1FX00-0AA0) (All versions), SCALANCE W774-1 RJ45 (6GK5774-1FX00-0AA6) (All versions), SCALANCE W774-1 RJ45 (6GK5774-1FX00-0AB0) (All versions), SCALANCE W774-1 RJ45 (6GK5774-1FX00-0AC0) (All versions), SCALANCE W774-1 RJ45 (USA) (6GK5774-1FX00-0AB6) (All versions), SCALANCE W778-1 M12 (6GK5778-1GY00-0AA0) (All versions), SCALANCE W778-1 M12 (6GK5778-1GY00-0AB0) (All versions), SCALANCE W778-1 M12 EEC (6GK5778-1GY00-0TA0) (All versions), SCALANCE W778-1 M12 EEC (USA) (6GK5778-1GY00-0TB0) (All versions), SCALANCE W786-1 RJ45 (6GK5786-1FC00-0AA0) (All versions), SCALANCE W786-1 RJ45 (6GK5786-1FC00-0AB0) (All versions), SCALANCE W786-2 RJ45 (6GK5786-2FC00-0AA0) (All versions), SCALANCE W786-2 RJ45 (6GK5786-2FC00-0AB0) (All versions), SCALANCE W786-2 RJ45 (6GK5786-2FC00-0AC0) (All versions), SCALANCE W786-2 SFP (6GK5786-2FE00-0AA0) (All versions), SCALANCE W786-2 SFP (6GK5786-2FE00-0AB0) (All versions), SCALANCE W786-2IA RJ45 (6GK5786-2HC00-0AA0) (All versions), SCALANCE W786-2IA RJ45 (6GK5786-2HC00-0AB0) (All versions), SCALANCE W788-1 M12 (6GK5788-1GD00-0AA0) (All versions), SCALANCE W788-1 M12 (6GK5788-1GD00-0AB0) (All versions), SCALANCE W788-1 RJ45 (6GK5788-1FC00-0AA0) (All versions), SCALANCE W788-1 RJ45 (6GK5788-1FC00-0AB0) (All versions), SCALANCE W788-2 M12 (6GK5788-2GD00-0AA0) (All versions), SCALANCE W788-2 M12 (6GK5788-2GD00-0AB0) (All versions), SCALANCE W788-2 M12 EEC (6GK5788-2GD00-0TA0) (All versions), SCALANCE W788-2 M12 EEC (6GK5788-2GD00-0TB0) (All versions), SCALANCE W788-2 M12 EEC (6GK5788-2GD00-0TC0) (All versions), SCALANCE W788-2 RJ45 (6GK5788-2FC00-0AA0) (All versions), SCALANCE W788-2 RJ45 (6GK5788-2FC00-0AB0) (All versions), SCALANCE W788-2 RJ45 (6GK5788-2FC00-0AC0) (All versions). This CVE refers to Scenario 1 "Leak frames from the Wi-Fi queue" of CVE-2022-47522.
Affected devices queue frames in order to subsequently change the security context and leak the queued frames. This could allow a physically proximate attacker to intercept (possibly cleartext) target-destined frames. |
| Authentication Bypass by Spoofing vulnerability in Pippin Williamson CGC Maintenance Mode allows Functionality Bypass.This issue affects CGC Maintenance Mode: from n/a through 1.2. |
| An issue was discovered in Ada Web Server 20.0. When configured to use SSL (which is not the default setting), the SSL/TLS used to establish connections to external services is done without proper hostname validation. This is exploitable by man-in-the-middle attackers. |
| Click Studios Passwordstate Core before 9.8 build 9858 allows Authentication Bypass. |
| Versions of the package djoser before 2.3.0 are vulnerable to Authentication Bypass when the authenticate() function fails. This is because the system falls back to querying the database directly, granting access to users with valid credentials, and eventually bypassing custom authentication checks such as two-factor authentication, LDAP validations, or requirements from configured AUTHENTICATION_BACKENDS. |
| A vulnerability was found in EZVIZ CS-C6-21WFR-8 5.2.7 Build 170628. It has been classified as problematic. This affects an unknown part of the component Davinci Application. The manipulation leads to improper certificate validation. It is possible to initiate the attack remotely. The complexity of an attack is rather high. The exploitability is told to be difficult. The identifier VDB-261789 was assigned to this vulnerability. NOTE: The vendor was contacted early about this disclosure but did not respond in any way. |
| The MQTT add-on of PcVue fails to verify that a remote device’s certificate has not already expired or has not yet become valid. This allows malicious devices to present certificates that are not rejected properly.
The use of a client certificate reduces the risk for random devices to take advantage of this flaw. |