USN-3312-1: Linux kernel vulnerabilities
Ubuntu Security Notice USN-3312-1
6th June, 2017
linux, linux-aws, linux-gke, linux-raspi2, linux-snapdragon vulnerabilities
A security issue affects these releases of Ubuntu and its
derivatives:
- Ubuntu 16.04 LTS
Summary
Several security issues were fixed in the Linux kernel.
Software description
- linux
– Linux kernel - linux-aws
– Linux kernel for Amazon Web Services (AWS) systems - linux-gke
– Linux kernel for Google Container Engine (GKE) systems - linux-raspi2
– Linux kernel for Raspberry Pi 2 - linux-snapdragon
– Linux kernel for Snapdragon Processors
Details
It was discovered that the netfilter netlink implementation in the Linux
kernel did not properly validate batch messages. A local attacker with the
CAP_NET_ADMIN capability could use this to expose sensitive information or
cause a denial of service. (CVE-2016-7917)
Qian Zhang discovered a heap-based buffer overflow in the tipc_msg_build()
function in the Linux kernel. A local attacker could use to cause a denial
of service (system crash) or possibly execute arbitrary code with
administrative privileges. (CVE-2016-8632)
It was discovered that the keyring implementation in the Linux kernel in
some situations did not prevent special internal keyrings from being joined
by userspace keyrings. A privileged local attacker could use this to bypass
module verification. (CVE-2016-9604)
It was discovered that a buffer overflow existed in the trace subsystem in
the Linux kernel. A privileged local attacker could use this to execute
arbitrary code. (CVE-2017-0605)
Dmitry Vyukov discovered that KVM implementation in the Linux kernel
improperly emulated the VMXON instruction. A local attacker in a guest OS
could use this to cause a denial of service (memory consumption) in the
host OS. (CVE-2017-2596)
Daniel Jiang discovered that a race condition existed in the ipv4 ping
socket implementation in the Linux kernel. A local privileged attacker
could use this to cause a denial of service (system crash). (CVE-2017-2671)
Di Shen discovered that a race condition existed in the perf subsystem of
the Linux kernel. A local attacker could use this to cause a denial of
service or possibly gain administrative privileges. (CVE-2017-6001)
Eric Biggers discovered a memory leak in the keyring implementation in the
Linux kernel. A local attacker could use this to cause a denial of service
(memory consumption). (CVE-2017-7472)
Sabrina Dubroca discovered that the asynchronous cryptographic hash (ahash)
implementation in the Linux kernel did not properly handle a full request
queue. A local attacker could use this to cause a denial of service
(infinite recursion). (CVE-2017-7618)
Tuomas Haanpää and Ari Kauppi discovered that the NFSv2 and NFSv3 server
implementations in the Linux kernel did not properly handle certain long
RPC replies. A remote attacker could use this to cause a denial of service
(system crash). (CVE-2017-7645)
Tommi Rantala and Brad Spengler discovered that the memory manager in the
Linux kernel did not properly enforce the CONFIG_STRICT_DEVMEM protection
mechanism. A local attacker with access to /dev/mem could use this to
expose sensitive information or possibly execute arbitrary code.
(CVE-2017-7889)
Tuomas Haanpää and Ari Kauppi discovered that the NFSv2 and NFSv3 server
implementations in the Linux kernel did not properly check for the end of
buffer. A remote attacker could use this to craft requests that cause a
denial of service (system crash) or possibly execute arbitrary code.
(CVE-2017-7895)
It was discovered that a use-after-free vulnerability existed in the device
driver for XCeive xc2028/xc3028 tuners in the Linux kernel. A local
attacker could use this to cause a denial of service (system crash) or
possibly execute arbitrary code. (CVE-2016-7913)
Vlad Tsyrklevich discovered an integer overflow vulnerability in the VFIO
PCI driver for the Linux kernel. A local attacker with access to a vfio PCI
device file could use this to cause a denial of service (system crash) or
possibly execute arbitrary code. (CVE-2016-9083, CVE-2016-9084)
Update instructions
The problem can be corrected by updating your system to the following
package version:
- Ubuntu 16.04 LTS:
-
linux-image-4.4.0-79-generic
4.4.0-79.100
-
linux-image-4.4.0-1018-aws
4.4.0-1018.27
- linux-image-powerpc-e500mc 4.4.0.79.85
-
linux-image-4.4.0-1014-gke
4.4.0-1014.14
-
linux-image-4.4.0-1057-raspi2
4.4.0-1057.64
- linux-image-virtual 4.4.0.79.85
- linux-image-snapdragon 4.4.0.1059.52
- linux-image-powerpc64-emb 4.4.0.79.85
- linux-image-gke 4.4.0.1014.16
-
linux-image-4.4.0-1059-snapdragon
4.4.0-1059.63
- linux-image-generic 4.4.0.79.85
-
linux-image-4.4.0-79-powerpc-smp
4.4.0-79.100
- linux-image-aws 4.4.0.1018.21
-
linux-image-4.4.0-79-powerpc64-smp
4.4.0-79.100
- linux-image-raspi2 4.4.0.1057.58
-
linux-image-4.4.0-79-powerpc-e500mc
4.4.0-79.100
- linux-image-powerpc-smp 4.4.0.79.85
-
linux-image-4.4.0-79-generic-lpae
4.4.0-79.100
- linux-image-generic-lpae 4.4.0.79.85
-
linux-image-4.4.0-79-lowlatency
4.4.0-79.100
- linux-image-powerpc64-smp 4.4.0.79.85
- linux-image-lowlatency 4.4.0.79.85
To update your system, please follow these instructions:
https://wiki.ubuntu.com/Security/Upgrades.
After a standard system update you need to reboot your computer to make
all the necessary changes.
ATTENTION: Due to an unavoidable ABI change the kernel updates have
been given a new version number, which requires you to recompile and
reinstall all third party kernel modules you might have installed.
Unless you manually uninstalled the standard kernel metapackages
(e.g. linux-generic, linux-generic-lts-RELEASE, linux-virtual,
linux-powerpc), a standard system upgrade will automatically perform
this as well.
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