Revision f5c7f5dfbaf0d2f7d946d0fe86f08e6bcb36ed0d authored by Matt Caswell on 30 June 2016, 12:17:08 UTC, committed by Matt Caswell on 22 August 2016, 09:53:55 UTC
DTLS can handle out of order record delivery. Additionally since handshake messages can be bigger than will fit into a single packet, the messages can be fragmented across multiple records (as with normal TLS). That means that the messages can arrive mixed up, and we have to reassemble them. We keep a queue of buffered messages that are "from the future", i.e. messages we're not ready to deal with yet but have arrived early. The messages held there may not be full yet - they could be one or more fragments that are still in the process of being reassembled. The code assumes that we will eventually complete the reassembly and when that occurs the complete message is removed from the queue at the point that we need to use it. However, DTLS is also tolerant of packet loss. To get around that DTLS messages can be retransmitted. If we receive a full (non-fragmented) message from the peer after previously having received a fragment of that message, then we ignore the message in the queue and just use the non-fragmented version. At that point the queued message will never get removed. Additionally the peer could send "future" messages that we never get to in order to complete the handshake. Each message has a sequence number (starting from 0). We will accept a message fragment for the current message sequence number, or for any sequence up to 10 into the future. However if the Finished message has a sequence number of 2, anything greater than that in the queue is just left there. So, in those two ways we can end up with "orphaned" data in the queue that will never get removed - except when the connection is closed. At that point all the queues are flushed. An attacker could seek to exploit this by filling up the queues with lots of large messages that are never going to be used in order to attempt a DoS by memory exhaustion. I will assume that we are only concerned with servers here. It does not seem reasonable to be concerned about a memory exhaustion attack on a client. They are unlikely to process enough connections for this to be an issue. A "long" handshake with many messages might be 5 messages long (in the incoming direction), e.g. ClientHello, Certificate, ClientKeyExchange, CertificateVerify, Finished. So this would be message sequence numbers 0 to 4. Additionally we can buffer up to 10 messages in the future. Therefore the maximum number of messages that an attacker could send that could get orphaned would typically be 15. The maximum size that a DTLS message is allowed to be is defined by max_cert_list, which by default is 100k. Therefore the maximum amount of "orphaned" memory per connection is 1500k. Message sequence numbers get reset after the Finished message, so renegotiation will not extend the maximum number of messages that can be orphaned per connection. As noted above, the queues do get cleared when the connection is closed. Therefore in order to mount an effective attack, an attacker would have to open many simultaneous connections. Issue reported by Quan Luo. CVE-2016-2179 Reviewed-by: Richard Levitte <levitte@openssl.org>
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NOTES.VMS
NOTES FOR THE OPENVMS PLATFORM
==============================
Requirement details
-------------------
In addition to the requirements and instructions listed in INSTALL,
this are required as well:
* At least ODS-5 disk organization for source and build.
Installation can be done on any existing disk organization.
About ANSI C compiler
---------------------
An ANSI C compiled is needed among other things. This means that
VAX C is not and will not be supported.
We have only tested with DEC C (a.k.a HP VMS C / VSI C) and require
version 7.1 or later. Compiling with a different ANSI C compiler may
require some work.
Please avoid using C RTL feature logical names DECC$* when building
and testing OpenSSL. Most of all, they can be disruptive when
running the tests, as they affect the Perl interpreter.
About ODS-5 directory names and Perl
------------------------------------
It seems that the perl function canonpath() in the File::Spec module
doesn't treat file specifications where the last directory name
contains periods very well. Unfortunately, some versions of VMS tar
will keep the periods in the OpenSSL source directory instead of
converting them to underscore, thereby leaving your source in
something like [.openssl-1^.1^.0]. This will lead to issues when
configuring and building OpenSSL.
We have no replacement for Perl's canonpath(), so the best workaround
for now is to rename the OpenSSL source directory, as follows (please
adjust for the actual source directory name you have):
$ rename openssl-1^.1^.0.DIR openssl-1_1_0.DIR
About MMS and DCL
-----------------
MMS has certain limitations when it comes to line length, and DCL has
certain limitations when it comes to total command length. We do
what we can to mitigate, but there is the possibility that it's not
enough. Should you run into issues, a very simple solution is to set
yourself up a few logical names for the directory trees you're going
to use.
Checking the distribution
-------------------------
There have been reports of places where the distribution didn't quite
get through, for example if you've copied the tree from a NFS-mounted
Unix mount point.
The easiest way to check if everything got through as it should is to
check for one of the following files:
[.crypto]opensslconf^.h.in
The best way to get a correct distribution is to download the gzipped
tar file from ftp://ftp.openssl.org/source/, use GZIP -d to uncompress
it and VMSTAR to unpack the resulting tar file.
Gzip and VMSTAR are available here:
http://antinode.info/dec/index.html#Software
Should you need it, you can find UnZip for VMS here:
http://www.info-zip.org/UnZip.html
Computing file changes ...
