| CVE |
Vendors |
Products |
Updated |
CVSS v3.1 |
| Adobe Reader and Acrobat before 11.0.18, Acrobat and Acrobat Reader DC Classic before 15.006.30243, and Acrobat and Acrobat Reader DC Continuous before 15.020.20039 on Windows and OS X allow attackers to execute arbitrary code or cause a denial of service (memory corruption) via unspecified vectors, a different vulnerability than CVE-2016-6940, CVE-2016-6941, CVE-2016-6942, CVE-2016-6943, CVE-2016-6947, CVE-2016-6948, CVE-2016-6950, CVE-2016-6951, CVE-2016-6954, CVE-2016-6955, CVE-2016-6956, CVE-2016-6959, CVE-2016-6960, CVE-2016-6966, CVE-2016-6970, CVE-2016-6972, CVE-2016-6973, CVE-2016-6974, CVE-2016-6975, CVE-2016-6976, CVE-2016-6977, CVE-2016-6978, CVE-2016-6995, CVE-2016-6996, CVE-2016-6997, CVE-2016-6998, CVE-2016-7000, CVE-2016-7001, CVE-2016-7002, CVE-2016-7003, CVE-2016-7004, CVE-2016-7005, CVE-2016-7006, CVE-2016-7007, CVE-2016-7008, CVE-2016-7009, CVE-2016-7010, CVE-2016-7011, CVE-2016-7012, CVE-2016-7013, CVE-2016-7014, CVE-2016-7015, CVE-2016-7016, CVE-2016-7018, and CVE-2016-7019. |
| Adobe Reader and Acrobat before 11.0.18, Acrobat and Acrobat Reader DC Classic before 15.006.30243, and Acrobat and Acrobat Reader DC Continuous before 15.020.20039 on Windows and OS X allow attackers to execute arbitrary code or cause a denial of service (memory corruption) via unspecified vectors, a different vulnerability than CVE-2016-6940, CVE-2016-6941, CVE-2016-6942, CVE-2016-6943, CVE-2016-6947, CVE-2016-6948, CVE-2016-6950, CVE-2016-6951, CVE-2016-6954, CVE-2016-6955, CVE-2016-6956, CVE-2016-6959, CVE-2016-6960, CVE-2016-6966, CVE-2016-6970, CVE-2016-6972, CVE-2016-6973, CVE-2016-6974, CVE-2016-6975, CVE-2016-6976, CVE-2016-6977, CVE-2016-6978, CVE-2016-6995, CVE-2016-6996, CVE-2016-6997, CVE-2016-6998, CVE-2016-7000, CVE-2016-7001, CVE-2016-7002, CVE-2016-7003, CVE-2016-7004, CVE-2016-7005, CVE-2016-7006, CVE-2016-7007, CVE-2016-7008, CVE-2016-7009, CVE-2016-7010, CVE-2016-7011, CVE-2016-7012, CVE-2016-7013, CVE-2016-7014, CVE-2016-7015, CVE-2016-7016, CVE-2016-7017, and CVE-2016-7019. |
| The HTTPS protocol does not consider the role of the TCP congestion window in providing information about content length, which makes it easier for remote attackers to obtain cleartext data by leveraging a web-browser configuration in which third-party cookies are sent, aka a "HEIST" attack. |
| The PointerCompare function in codegen.cc in Seccomp-BPF, as used in Google Chrome before 34.0.1847.131 on Windows and OS X and before 34.0.1847.132 on Linux, does not properly merge blocks, which might allow remote attackers to bypass intended sandbox restrictions by leveraging renderer access. |
| Multiple unspecified vulnerabilities in Google Chrome before 34.0.1847.131 on Windows and OS X and before 34.0.1847.132 on Linux allow attackers to cause a denial of service or possibly have other impact via unknown vectors. |
| Multiple unspecified vulnerabilities in Google V8 before 3.24.35.33, as used in Google Chrome before 34.0.1847.131 on Windows and OS X and before 34.0.1847.132 on Linux, allow attackers to cause a denial of service or possibly have other impact via unknown vectors. |
| Integer overflow in api.cc in Google V8, as used in Google Chrome before 34.0.1847.131 on Windows and OS X and before 34.0.1847.132 on Linux, allows remote attackers to cause a denial of service or possibly have unspecified other impact via a large length value. |
| An unspecified IOHIDFamily function in Apple iOS before 8 and Apple TV before 7 lacks proper bounds checking to prevent reading of kernel pointers, which allows attackers to bypass the ASLR protection mechanism via a crafted application. |
| The Assets subsystem in Apple iOS before 8 and Apple TV before 7 allows man-in-the-middle attackers to spoof a device's update status via a crafted Last-Modified HTTP response header. |
| AFP File Server in Apple OS X before 10.10 allows remote attackers to discover the network addresses of all interfaces via an unspecified command to one interface. |
| The kernel in Apple OS X before 10.9.5 allows local users to obtain sensitive address information and bypass the ASLR protection mechanism by leveraging predictability of the location of the CPU Global Descriptor Table. |
| Dock in Apple OS X before 10.10 does not properly manage the screen-lock state, which allows physically proximate attackers to view windows by leveraging an unattended workstation. |
| fdesetup in Apple OS X before 10.10 does not properly display the encryption status in between a setting-update action and a reboot action, which might make it easier for physically proximate attackers to obtain cleartext data by leveraging ignorance of the reboot requirement. |
| Heap-based buffer overflow in the kernel in Apple OS X before 10.10 allows physically proximate attackers to execute arbitrary code via crafted resource forks in an HFS filesystem. |
| The kernel in Apple OS X before 10.10 allows physically proximate attackers to cause a denial of service (NULL pointer dereference and system crash) via a crafted filename on an HFS filesystem. |
| The "iCloud Find My Mac" feature in Apple OS X before 10.10 does not properly enforce rate limiting of lost-mode PIN entry, which makes it easier for physically proximate attackers to obtain access via a brute-force attack involving a series of reboots. |
| IOHIDFamily in Apple OS X before 10.10 allows attackers to cause denial of service (out-of-bounds read operation) via a crafted application. |
| LaunchServices in Apple OS X before 10.10 allows attackers to bypass intended sandbox restrictions via an application that specifies a crafted handler for the Content-Type field of an object. |
| Race condition in LoginWindow in Apple OS X before 10.10 allows physically proximate attackers to obtain access by leveraging an unattended workstation on which screen locking had been attempted. |
| The Sandbox Profiles subsystem in Apple iOS before 8.1.1 does not properly implement the debugserver sandbox, which allows attackers to bypass intended binary-execution restrictions via a crafted application that is run during a time period when debugging is not enabled. |
