| CVE |
Vendors |
Products |
Updated |
CVSS v3.1 |
| An exploitable stack buffer overflow vulnerability exists in the MQTT packet parsing functionality of Cesanta Mongoose 6.8. A specially crafted MQTT SUBSCRIBE packet can cause a stack buffer overflow resulting in remote code execution. An attacker needs to send a specially crafted MQTT packet over the network to trigger this vulnerability. |
| An exploitable out-of-bounds write vulnerability exists in the xls_mergedCells function of libxls 1.4. . A specially crafted XLS file can cause a memory corruption resulting in remote code execution. An attacker can send malicious XLS file to trigger this vulnerability. |
| An exploitable out-of-bounds write vulnerability exists in the read_MSAT function of libxls 1.4. A specially crafted XLS file can cause a memory corruption resulting in remote code execution. An attacker can send malicious XLS file to trigger this vulnerability. |
| A remote code execution vulnerability in the Android media framework (libmpeg2). Product: Android. Versions: 6.0, 6.0.1, 7.0, 7.1.1, 7.1.2, 8.0. Android ID: A-63125953. |
| An exploitable stack based buffer overflow vulnerability exists in the xls_getfcell function of libxls 1.3.4. A specially crafted XLS file can cause a memory corruption resulting in remote code execution. An attacker can send malicious XLS file to trigger this vulnerability |
| A elevation of privilege vulnerability in the Upstream Linux file system. Product: Android. Versions: Android kernel. Android ID: A-36817013. |
| An elevation of privilege vulnerability in the Qualcomm Wi-Fi driver could enable a local malicious application to execute arbitrary code within the context of the kernel. This issue is rated as High because it first requires compromising a privileged process. Product: Android. Versions: Kernel-3.10. Android ID: A-33979145. References: QC-CR#1105085. |
| Adobe Flash Player versions 24.0.0.186 and earlier have an exploitable memory corruption vulnerability in the JPEG XR codec. Successful exploitation could lead to arbitrary code execution. |
| Adobe Flash Player versions 24.0.0.186 and earlier have an exploitable memory corruption vulnerability related to processing of atoms in MP4 files. Successful exploitation could lead to arbitrary code execution. |
| Adobe Flash Player versions 24.0.0.186 and earlier have an exploitable heap overflow vulnerability when processing Adobe Texture Format files. Successful exploitation could lead to arbitrary code execution. |
| Adobe Flash Player versions 24.0.0.186 and earlier have an exploitable memory corruption vulnerability related to setting visual mode effects. Successful exploitation could lead to arbitrary code execution. |
| Adobe Flash Player versions 24.0.0.186 and earlier have an exploitable memory corruption vulnerability due to a concurrency error when manipulating a display list. Successful exploitation could lead to arbitrary code execution. |
| Adobe Flash Player versions 24.0.0.186 and earlier have an exploitable memory corruption vulnerability related to the parsing of SWF metadata. Successful exploitation could lead to arbitrary code execution. |
| Adobe Flash Player versions 24.0.0.186 and earlier have an exploitable heap overflow vulnerability related to texture compression. Successful exploitation could lead to arbitrary code execution. |
| Adobe Flash Player versions 24.0.0.186 and earlier have an exploitable heap overflow vulnerability when parsing Adobe Texture Format files. Successful exploitation could lead to arbitrary code execution. |
| Adobe Flash Player versions 24.0.0.186 and earlier have an exploitable heap overflow vulnerability when processing the Flash Video container file format. Successful exploitation could lead to arbitrary code execution. |
| Adobe Flash Player versions 24.0.0.194 and earlier have an exploitable heap overflow vulnerability in the h264 decoder routine. Successful exploitation could lead to arbitrary code execution. |
| Adobe Flash Player versions 24.0.0.194 and earlier have an exploitable heap overflow vulnerability in the Flash Video (FLV) codec. Successful exploitation could lead to arbitrary code execution. |
| OpenSSL 1.0.2 (starting from version 1.0.2b) introduced an "error state" mechanism. The intent was that if a fatal error occurred during a handshake then OpenSSL would move into the error state and would immediately fail if you attempted to continue the handshake. This works as designed for the explicit handshake functions (SSL_do_handshake(), SSL_accept() and SSL_connect()), however due to a bug it does not work correctly if SSL_read() or SSL_write() is called directly. In that scenario, if the handshake fails then a fatal error will be returned in the initial function call. If SSL_read()/SSL_write() is subsequently called by the application for the same SSL object then it will succeed and the data is passed without being decrypted/encrypted directly from the SSL/TLS record layer. In order to exploit this issue an application bug would have to be present that resulted in a call to SSL_read()/SSL_write() being issued after having already received a fatal error. OpenSSL version 1.0.2b-1.0.2m are affected. Fixed in OpenSSL 1.0.2n. OpenSSL 1.1.0 is not affected. |
| Stack overflow in PDFium in Google Chrome prior to 60.0.3112.78 for Linux, Windows, and Mac allowed a remote attacker to potentially exploit stack corruption via a crafted PDF file. |