- Detalji os-a: LDE
- Važnost: IMP
- Operativni sustavi: L
- Kategorije: LDE
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Debian Security Advisory DSA-3388-1 firstname.lastname@example.org
https://www.debian.org/security/ Kurt Roeckx
November 01, 2015 https://www.debian.org/security/faq
Package : ntp
CVE ID : CVE-2014-9750 CVE-2014-9751 CVE-2015-3405 CVE-2015-5146
CVE-2015-5194 CVE-2015-5195 CVE-2015-5219 CVE-2015-5300
CVE-2015-7691 CVE-2015-7692 CVE-2015-7701 CVE-2015-7702
CVE-2015-7703 CVE-2015-7704 CVE-2015-7850 CVE-2015-7852
Several vulnerabilities were discovered in the Network Time Protocol
daemon and utility programs:
A flaw was found in the way ntpd processed certain remote
configuration packets. An attacker could use a specially crafted
package to cause ntpd to crash if:
* ntpd enabled remote configuration
* The attacker had the knowledge of the configuration password
* The attacker had access to a computer entrusted to perform remote
Note that remote configuration is disabled by default in NTP.
It was found that ntpd could crash due to an uninitialized
variable when processing malformed logconfig configuration
It was found that ntpd exits with a segmentation fault when a
statistics type that was not enabled during compilation (e.g.
timingstats) is referenced by the statistics or filegen
It was discovered that sntp program would hang in an infinite loop
when a crafted NTP packet was received, related to the conversion
of the precision value in the packet to double.
It was found that ntpd did not correctly implement the -g option:
Normally, ntpd exits with a message to the system log if the offset
exceeds the panic threshold, which is 1000 s by default. This
option allows the time to be set to any value without restriction;
however, this can happen only once. If the threshold is exceeded
after that, ntpd will exit with a message to the system log. This
option can be used with the -q and -x options.
ntpd could actually step the clock multiple times by more than the
panic threshold if its clock discipline doesn’t have enough time to
reach the sync state and stay there for at least one update. If a
man-in-the-middle attacker can control the NTP traffic since ntpd
was started (or maybe up to 15-30 minutes after that), they can
prevent the client from reaching the sync state and force it to step
its clock by any amount any number of times, which can be used by
attackers to expire certificates, etc.
This is contrary to what the documentation says. Normally, the
assumption is that an MITM attacker can step the clock more than the
panic threshold only once when ntpd starts and to make a larger
adjustment the attacker has to divide it into multiple smaller
steps, each taking 15 minutes, which is slow.
CVE-2015-7691, CVE-2015-7692, CVE-2015-7702
It was found that the fix for CVE-2014-9750 was incomplete: three
issues were found in the value length checks in ntp_crypto.c, where
a packet with particular autokey operations that contained malicious
data was not always being completely validated. Receipt of these
packets can cause ntpd to crash.
A memory leak flaw was found in ntpd’s CRYPTO_ASSOC. If ntpd is
configured to use autokey authentication, an attacker could send
packets to ntpd that would, after several days of ongoing attack,
cause it to run out of memory.
Miroslav Lichvar of Red Hat found that the :config command can be
used to set the pidfile and driftfile paths without any
restrictions. A remote attacker could use this flaw to overwrite a
file on the file system with a file containing the pid of the ntpd
process (immediately) or the current estimated drift of the system
clock (in hourly intervals). For example:
ntpq -c ‘:config pidfile /tmp/ntp.pid’
ntpq -c ‘:config driftfile /tmp/ntp.drift’
In Debian ntpd is configured to drop root privileges, which limits
the impact of this issue.
If ntpd as an NTP client receives a Kiss-of-Death (KoD) packet
from the server to reduce its polling rate, it doesn’t check if the
originate timestamp in the reply matches the transmit timestamp from
its request. An off-path attacker can send a crafted KoD packet to
the client, which will increase the client’s polling interval to a
large value and effectively disable synchronization with the server.
An exploitable denial of service vulnerability exists in the remote
configuration functionality of the Network Time Protocol. A
specially crafted configuration file could cause an endless loop
resulting in a denial of service. An attacker could provide a the
malicious configuration file to trigger this vulnerability.
A potential off by one vulnerability exists in the cookedprint
functionality of ntpq. A specially crafted buffer could cause a
buffer overflow potentially resulting in null byte being written out
It was found that NTP’s decodenetnum() would abort with an assertion
failure when processing a mode 6 or mode 7 packet containing an
unusually long data value where a network address was expected. This
could allow an authenticated attacker to crash ntpd.
An error handling logic error exists within ntpd that manifests due
to improper error condition handling associated with certain
crypto-NAK packets. An unauthenticated, off-path attacker can force
ntpd processes on targeted servers to peer with time sources of the
attacker’s choosing by transmitting symmetric active crypto-NAK
packets to ntpd. This attack bypasses the authentication typically
required to establish a peer association and allows an attacker to
make arbitrary changes to system time.
For the oldstable distribution (wheezy), these problems have been fixed
in version 1:4.2.6.p5+dfsg-2+deb7u6.
For the stable distribution (jessie), these problems have been fixed in
For the testing distribution (stretch), these problems have been fixed
in version 1:4.2.8p4+dfsg-3.
For the unstable distribution (sid), these problems have been fixed in
We recommend that you upgrade your ntp packages.
Further information about Debian Security Advisories, how to apply
these updates to your system and frequently asked questions can be
found at: https://www.debian.org/security/
Mailing list: email@example.com
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|Cve||CVE-2014-9750 CVE-2014-9751 CVE-2015-3405 CVE-2015-5146 CVE-2015-5194 CVE-2015-5195 CVE-2015-5219 CVE-2015-5300 CVE-2015-7691 CVE-2015-7692 CVE-2015-7701 CVE-2015-7702 CVE-2015-7703 CVE-2015-7704 CVE-2015-7850 CVE-2015-7852 CVE-2015-7855 CVE-2015-7871|