USN-5000-1: Linux kernel vulnerabilities
23 June 2021
Several security issues were fixed in the Linux kernel.
Releases
Packages
- linux - Linux kernel
- linux-aws - Linux kernel for Amazon Web Services (AWS) systems
- linux-aws-5.4 - Linux kernel for Amazon Web Services (AWS) systems
- linux-azure - Linux kernel for Microsoft Azure Cloud systems
- linux-azure-5.4 - Linux kernel for Microsoft Azure cloud systems
- linux-gcp - Linux kernel for Google Cloud Platform (GCP) systems
- linux-gcp-5.4 - Linux kernel for Google Cloud Platform (GCP) systems
- linux-gke - Linux kernel for Google Container Engine (GKE) systems
- linux-gke-5.4 - Linux kernel for Google Container Engine (GKE) systems
- linux-gkeop - Linux kernel for Google Container Engine (GKE) systems
- linux-gkeop-5.4 - Linux kernel for Google Container Engine (GKE) systems
- linux-hwe-5.4 - Linux hardware enablement (HWE) kernel
- linux-oracle - Linux kernel for Oracle Cloud systems
- linux-oracle-5.4 - Linux kernel for Oracle Cloud systems
- linux-raspi - Linux kernel for Raspberry Pi (V8) systems
- linux-raspi-5.4 - Linux kernel for Raspberry Pi (V8) systems
Details
Norbert Slusarek discovered a race condition in the CAN BCM networking
protocol of the Linux kernel leading to multiple use-after-free
vulnerabilities. A local attacker could use this issue to execute arbitrary
code. (CVE-2021-3609)
Piotr Krysiuk discovered that the eBPF implementation in the Linux kernel
did not properly enforce limits for pointer operations. A local attacker
could use this to cause a denial of service (system crash) or possibly
execute arbitrary code. (CVE-2021-33200)
Mathy Vanhoef discovered that the Linux kernel’s WiFi implementation did
not properly clear received fragments from memory in some situations. A
physically proximate attacker could possibly use this issue to inject
packets or expose sensitive information. (CVE-2020-24586)
Mathy Vanhoef discovered that the Linux kernel’s WiFi implementation
incorrectly handled encrypted fragments. A physically proximate attacker
could possibly use this issue to decrypt fragments. (CVE-2020-24587)
Mathy Vanhoef discovered that the Linux kernel’s WiFi implementation
incorrectly handled certain malformed frames. If a user were tricked into
connecting to a malicious server, a physically proximate attacker could use
this issue to inject packets. (CVE-2020-24588)
Mathy Vanhoef discovered that the Linux kernel’s WiFi implementation
incorrectly handled EAPOL frames from unauthenticated senders. A physically
proximate attacker could inject malicious packets to cause a denial of
service (system crash). (CVE-2020-26139)
Mathy Vanhoef discovered that the Linux kernel’s WiFi implementation did
not properly verify certain fragmented frames. A physically proximate
attacker could possibly use this issue to inject or decrypt packets.
(CVE-2020-26141)
Mathy Vanhoef discovered that the Linux kernel’s WiFi implementation
accepted plaintext fragments in certain situations. A physically proximate
attacker could use this issue to inject packets. (CVE-2020-26145)
Mathy Vanhoef discovered that the Linux kernel’s WiFi implementation could
reassemble mixed encrypted and plaintext fragments. A physically proximate
attacker could possibly use this issue to inject packets or exfiltrate
selected fragments. (CVE-2020-26147)
Or Cohen discovered that the SCTP implementation in the Linux kernel
contained a race condition in some situations, leading to a use-after-free
condition. A local attacker could use this to cause a denial of service
(system crash) or possibly execute arbitrary code. (CVE-2021-23133)
Or Cohen and Nadav Markus discovered a use-after-free vulnerability in the
nfc implementation in the Linux kernel. A privileged local attacker could
use this issue to cause a denial of service (system crash) or possibly
execute arbitrary code. (CVE-2021-23134)
Piotr Krysiuk discovered that the eBPF implementation in the Linux kernel
did not properly prevent speculative loads in certain situations. A local
attacker could use this to expose sensitive information (kernel memory).
(CVE-2021-31829)
It was discovered that a race condition in the kernel Bluetooth subsystem
could lead to use-after-free of slab objects. An attacker could use this
issue to possibly execute arbitrary code. (CVE-2021-32399)
It was discovered that a use-after-free existed in the Bluetooth HCI driver
of the Linux kernel. A local attacker could use this to cause a denial of
service (system crash) or possibly execute arbitrary code. (CVE-2021-33034)
It was discovered that an out-of-bounds (OOB) memory access flaw existed in
the f2fs module of the Linux kernel. A local attacker could use this issue
to cause a denial of service (system crash). (CVE-2021-3506)
Update instructions
The problem can be corrected by updating your system to the following package versions:
Ubuntu 20.04
-
linux-image-gkeop-5.4
-
5.4.0.1018.21
-
linux-image-5.4.0-1038-raspi
-
5.4.0-1038.41
-
linux-image-5.4.0-1051-aws
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5.4.0-1051.53
-
linux-image-gke
-
5.4.0.1046.55
-
linux-image-5.4.0-1048-oracle
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5.4.0-1048.52
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linux-image-oem-osp1
-
5.4.0.77.80
-
linux-image-5.4.0-1018-gkeop
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5.4.0-1018.19
-
linux-image-5.4.0-1046-gke
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5.4.0-1046.48
-
linux-image-oracle-lts-20.04
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5.4.0.1048.48
-
linux-image-gkeop
-
5.4.0.1018.21
-
linux-image-virtual
-
5.4.0.77.80
-
linux-image-raspi
-
5.4.0.1038.73
-
linux-image-gcp-lts-20.04
-
5.4.0.1046.55
-
linux-image-5.4.0-1051-azure
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5.4.0-1051.53
-
linux-image-generic
-
5.4.0.77.80
-
linux-image-aws-lts-20.04
-
5.4.0.1051.53
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linux-image-gke-5.4
-
5.4.0.1046.55
-
linux-image-oem
-
5.4.0.77.80
-
linux-image-raspi2
-
5.4.0.1038.73
-
linux-image-azure-lts-20.04
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5.4.0.1051.49
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linux-image-generic-lpae
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5.4.0.77.80
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linux-image-5.4.0-77-lowlatency
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5.4.0-77.86
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linux-image-5.4.0-77-generic
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5.4.0-77.86
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linux-image-5.4.0-1046-gcp
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5.4.0-1046.49
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linux-image-lowlatency
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5.4.0.77.80
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linux-image-5.4.0-77-generic-lpae
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5.4.0-77.86
Ubuntu 18.04
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linux-image-gkeop-5.4
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5.4.0.1018.19~18.04.19
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linux-image-5.4.0-1038-raspi
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5.4.0-1038.41~18.04.1
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linux-image-5.4.0-1051-aws
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5.4.0-1051.53~18.04.1
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linux-image-5.4.0-1048-oracle
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5.4.0-1048.52~18.04.1
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linux-image-oem-osp1
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5.4.0.77.86~18.04.69
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linux-image-oracle
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5.4.0.1048.52~18.04.30
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linux-image-generic-hwe-18.04
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5.4.0.77.86~18.04.69
-
linux-image-azure
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5.4.0.1051.30
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linux-image-5.4.0-1018-gkeop
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5.4.0-1018.19~18.04.1
-
linux-image-5.4.0-1046-gke
-
5.4.0-1046.48~18.04.1
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linux-image-generic-lpae-hwe-18.04
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5.4.0.77.86~18.04.69
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linux-image-snapdragon-hwe-18.04
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5.4.0.77.86~18.04.69
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linux-image-5.4.0-1051-azure
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5.4.0-1051.53~18.04.1
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linux-image-lowlatency-hwe-18.04
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5.4.0.77.86~18.04.69
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linux-image-virtual-hwe-18.04
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5.4.0.77.86~18.04.69
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linux-image-gke-5.4
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5.4.0.1046.48~18.04.12
-
linux-image-oem
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5.4.0.77.86~18.04.69
-
linux-image-aws
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5.4.0.1051.33
-
linux-image-raspi-hwe-18.04
-
5.4.0.1038.40
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linux-image-gcp
-
5.4.0.1046.33
-
linux-image-5.4.0-77-lowlatency
-
5.4.0-77.86~18.04.1
-
linux-image-5.4.0-77-generic
-
5.4.0-77.86~18.04.1
-
linux-image-5.4.0-1046-gcp
-
5.4.0-1046.49~18.04.1
-
linux-image-5.4.0-77-generic-lpae
-
5.4.0-77.86~18.04.1
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.