One document matched: draft-reddy-dots-transport-02.xml
<?xml version="1.0" encoding="US-ASCII"?>
<!DOCTYPE rfc SYSTEM "rfc2629.dtd">
<?rfc toc="yes"?>
<?rfc tocompact="yes"?>
<?rfc tocdepth="3"?>
<?rfc tocindent="yes"?>
<?rfc symrefs="yes"?>
<?rfc sortrefs="yes"?>
<?rfc comments="yes"?>
<?rfc inline="yes"?>
<?rfc compact="yes"?>
<?rfc subcompact="no"?>
<rfc category="std" docName="draft-reddy-dots-transport-02" ipr="trust200902">
<front>
<title abbrev="Co-operative DDoS Mitigation">Co-operative DDoS
Mitigation</title>
<author fullname="Tirumaleswar Reddy" initials="T." surname="Reddy">
<organization abbrev="Cisco">Cisco Systems, Inc.</organization>
<address>
<postal>
<street>Cessna Business Park, Varthur Hobli</street>
<street>Sarjapur Marathalli Outer Ring Road</street>
<city>Bangalore</city>
<region>Karnataka</region>
<code>560103</code>
<country>India</country>
</postal>
<email>tireddy@cisco.com</email>
</address>
</author>
<author fullname="Dan Wing" initials="D." surname="Wing">
<organization abbrev="Cisco">Cisco Systems, Inc.</organization>
<address>
<postal>
<street>170 West Tasman Drive</street>
<city>San Jose</city>
<region>California</region>
<code>95134</code>
<country>USA</country>
</postal>
<email>dwing@cisco.com</email>
</address>
</author>
<author fullname="Prashanth Patil" initials="P." surname="Patil">
<organization abbrev="Cisco">Cisco Systems, Inc.</organization>
<address>
<postal>
<street></street>
<street></street>
<city></city>
<country></country>
</postal>
<email>praspati@cisco.com</email>
</address>
</author>
<author fullname="Mike Geller" initials="M." surname="Geller">
<organization abbrev="Cisco">Cisco Systems, Inc.</organization>
<address>
<postal>
<street>3250</street>
<city></city>
<region>Florida</region>
<code>33309</code>
<country>USA</country>
</postal>
<email>mgeller@cisco.com</email>
</address>
</author>
<author fullname="Mohamed Boucadair" initials="M." surname="Boucadair">
<organization>France Telecom</organization>
<address>
<postal>
<street></street>
<city>Rennes</city>
<region></region>
<code>35000</code>
<country>France</country>
</postal>
<email>mohamed.boucadair@orange.com</email>
</address>
</author>
<author fullname="Robert Moskowitz" initials="R." surname="Moskowitz">
<organization>HTT Consulting</organization>
<address>
<postal>
<street></street>
<city>Oak Park, MI</city>
<code>42837</code>
<country>United States</country>
</postal>
<email>rgm@htt-consult.com</email>
</address>
</author>
<date />
<workgroup>DOTS</workgroup>
<abstract>
<t>This document discusses mechanisms that a DOTS client can use, when
it detects a potential Distributed Denial-of-Service (DDoS) attack, to
signal that the DOTS client is under an attack or request an upstream
DOTS server to perform inbound filtering in its ingress routers for
traffic that the DOTS client wishes to drop. The DOTS server can then
undertake appropriate actions (including, blackhole, drop, rate-limit,
or add to watch list) on the suspect traffic to the DOTS client, thus
reducing the effectiveness of the attack.</t>
</abstract>
</front>
<middle>
<section anchor="introduction" title="Introduction">
<t>A distributed denial-of-service (DDoS) attack is an attempt to make
machines or network resources unavailable to their intended users. In
most cases, sufficient scale can be achieved by compromising enough
end-hosts and using those infected hosts to perpetrate and amplify the
attack. The victim in this attack can be an application server, a
client, a router, a firewall, or an entire network, etc. The reader may
refer, for example, to <xref target="REPORT"></xref> that reports the
following:</t>
<t><list style="symbols">
<t>Very large DDoS attacks above the 100 Gbps threshold are
experienced.</t>
<t>DDoS attacks against customers remain the number one operational
threat for service providers, with DDoS attacks against
infrastructures being the top concern for 2014.</t>
<t>Over 60% of service providers are seeing increased demand for
DDoS detection and mitigation services from their customers (2014),
with just over one-third seeing the same demand as in 2013.</t>
</list></t>
<t>In a lot of cases, it may not be possible for an enterprise to
determine the cause for an attack, but instead just realize that certain
resources seem to be under attack. The document proposes that, in such
cases, the DOTS client just inform the DOTS server that the enterprise
is under a potential attack and that the DOTS server monitor traffic to
the enterprise to mitigate any possible attack. This document also
describes a means for an enterprise, which act as DOTS clients, to
dynamically inform its DOTS server of the IP addresses or prefixes that
are causing DDoS. A DOTS server can use this information to discard
flows from such IP addresses reaching the customer network.</t>
<t>The proposed mechanism can also be used between applications from
various vendors that are deployed within the same network, some of them
are responsible for monitoring and detecting attacks while others are
responsible for enforcing policies on appropriate network elements. This
cooperations contributes to a ensure a highly automated network that is
also robust, reliable and secure. The advantage of the proposed
mechanism is that the DOTS server can provide protection to the DOTS
client from bandwidth-saturating DDoS traffic.</t>
<t>How a DOTS server determines which network elements should be
modified to install appropriate filtering rules is out of scope. A
variety of mechanisms and protocols (including NETCONF) may be
considered to exchange information through a communication interface
between the server and these underlying elements; the selection of
appropriate mechanisms and protocols to be invoked for that interfaces
is deployment-specific.</t>
<t>Terminology and protocol requirements for co-operative DDoS
mitigation are obtained from <xref
target="I-D.ietf-dots-requirements"></xref>.</t>
</section>
<section anchor="notation" title="Notational Conventions">
<t>The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
document are to be interpreted as described in <xref
target="RFC2119"></xref>.</t>
</section>
<section title="Solution Overview">
<t>Network applications have finite resources like CPU cycles, number of
processes or threads they can create and use, maximum number of
simultaneous connections it can handle, limited resources of the control
plane, etc. When processing network traffic, such an application uses
these resources to offer its intended task in the most efficient
fashion. However, an attacker may be able to prevent the application
from performing its intended task by causing the application to exhaust
the finite supply of a specific resource.</t>
<t>TCP DDoS SYN-flood is a memory-exhaustion attack on the victim and
ACK-flood is a CPU exhaustion attack on the victim. Attacks on the link
are carried out by sending enough traffic such that the link becomes
excessively congested, and legitimate traffic suffers high packet loss.
Stateful firewalls can also be attacked by sending traffic that causes
the firewall to hold excessive state and the firewall runs out of
memory, and can no longer instantiate the state required to pass
legitimate flows. Other possible DDoS attacks are discussed in <xref
target="RFC4732"></xref>.</t>
<t>In each of the cases described above, if a network resource detects a
potential DDoS attack from a set of IP addresses, the network resource
(DOTS client) informs its servicing router (DOTS relay) of all suspect
IP addresses that need to be blocked or black-listed for further
investigation. DOTS client could also specify protocols and ports in the
black-list rule. That DOTS relay in-turn propagates the black-listed IP
addresses to the DOTS server and the DOTS server blocks traffic from
these IP addresses to the DOTS client thus reducing the effectiveness of
the attack. The DOTS client periodically queries the DOTS server to
check the counters mitigating the attack. If the DOTS client receives
response that the counters have not incremented then it can instruct the
black-list rules to be removed. If a blacklisted IPv4 address is shared
by multiple subscribers then the side effect of applying the black-list
rule will be that traffic from non-attackers will also be blocked by the
access network.</t>
<t>If a DOTS client cannot determine the IP address(s) that are causing
the attack, but is under an attack nonetheless, the DOTS client can just
notify the DOTS server that it is under a potential attack and request
that the DOTS server take precautionary measures to mitigate the
attack.</t>
</section>
<section title="Happy Eyeballs">
<t>If a DOTS server IPv4 path is working, but the DOTS server's IPv6
path is not working, a dual-stack DOTS client can experience significant
connection delay compared to an IPv4-only DOTS client. The other problem
is that if a middle box between the DOTS client and server is configured
to block UDP, DOTS client will fail to establish DTLS session <xref
target="RFC6347"></xref> with the DOTS server and will have to fall back
to TLS over TCP <xref target="RFC5246"></xref> incurring significant
connection delay. <xref target="I-D.ietf-dots-requirements"></xref>
discusses that DOTS client and server will have to support both
connectionless and connection-oriented protocols.</t>
<t>To overcome these connection setup problems, the DOTS client MUST try
connecting to the DOTS server using both IPv6 and IPv4, and MUST try
both DTLS over UDP and TLS over TCP in a fashion similar to the "Happy
Eyeballs" mechanism <xref target="RFC6555"></xref>. These connection
attempts are performed by the DOTS client when its initializes, and the
client uses that information for its subsequent alert to the server. In
order of preference (most preferred first), it is UDP over IPv6, UDP
over IPv4, TCP over IPv6, and finally TCP over IPv4, which adheres to
<xref target="RFC6724">address preference order</xref> and the DOTS
preference that UDP be used over TCP (to avoid TCP's head of line
blocking).</t>
<t>TBD: How does the DOTS client discover the DOTS server (use DNS-SD)
?</t>
<t><figure anchor="fig_happy_eyeballs" title="Happy Eyeballs">
<artwork align="center"><![CDATA[
DOTS client DOTS server
| |
|--DTLS ClientHello, IPv6 ---->X |
|--TCP SYN, IPv6-------------->X |
|--DTLS ClientHello, IPv4 ---->X |
|--TCP SYN, IPv4----------------------------------------->|
|--DTLS ClientHello, IPv6 ---->X |
|--TCP SYN, IPv6-------------->X |
|<-TCP SYNACK---------------------------------------------|
|--DTLS ClientHello, IPv4 ---->X |
|--TCP ACK----------------------------------------------->|
|<------------Establish TLS Session---------------------->|
|----------------DOTS signal----------------------------->|
| |
]]></artwork>
</figure></t>
<t>In the diagram above, the DOTS client sends two TCP SYNs and two DTLS
ClientHello messages at the same time over IPv6 and IPv4. In the
diagram, the IPv6 path is broken and UDP is dropped by a middle box but
has little impact to the DOTS client because there is no long delay
before using IPv4 and TCP. The IPv6 path and UDP over IPv6 and IPv4 is
retried until the DOTS client gives up.</t>
<t>DOTS client and server can also use the following techniques to
reduce delay to convey DOTS signal:</t>
<t><list style="symbols">
<t>DOTS client can use (D)TLS session resumption without server-side
state <xref target="RFC5077"></xref> to resume session and convey
the DOTS signal.</t>
<t>TLS False Start <xref target="I-D.ietf-tls-falsestart"></xref>
which reduces round-trips by allowing the TLS second flight of
messages (ChangeCipherSpec) to also contain the DOTS signal.</t>
<t>Cached Information Extension <xref
target="I-D.ietf-tls-cached-info"></xref> which avoids transmitting
the server's certificate and certificate chain if the client has
cached that information from a previous TLS handshake.</t>
<t>TCP Fast Open <xref target="RFC7413"></xref> can reduce the
number of round-trips to convey DOTS signal.</t>
<t>While the communication to the DOTS server is quiescent, the DOTS
client may want to probe the server to ensure it has maintained
cryptographic state. Such probes can also keep alive firewall or NAT
bindings. This probing reduces the frequency of needing a new
handshake when a DOTS signal needs to be conveyed to the server.
<list style="symbols">
<t>A <xref target="RFC6520">DTLS heartbeat</xref> verifies the
server still has DTLS state by returning a DTLS message. If the
server has lost state, it returns a DTLS Alert. Upon receipt of
an un-authenicated DTLS alert, the DTLS client validates the
Alert is within the replay window (Section 4.1.2.6 of <xref
target="RFC6347"></xref>). It is difficult for the DTLS client
to validate the DTLS alert was generated by the DTLS server in
response to a request or was generated by an on- or off-path
attacker. Thus, upon receipt of an in-window DTLS Alert, the
client SHOULD continue re-transmitting the DTLS packet (in the
event the Alert was spoofed), and at the same time it SHOULD
initiate DTLS session resumption.</t>
<t>TLS runs over TCP, so a simple probe is a 0-length TCP packet
(a "window probe"). This verifies the TCP connection is still
working, which is also sufficient to prove the server has
retained TLS state, because if the server loses TLS state it
abandons the TCP connection. If the server has lost state, a TCP
RST is returned immediately.</t>
</list></t>
</list></t>
</section>
<section title="Protocol for Signal Channel: HTTP REST">
<t>A DOTS client can use RESTful APIs discussed in this section to
signal/inform a DOTS server of an attack or any desired IP filtering
rules.</t>
<section title="Mitigation service request">
<t>The following APIs define the means to convey an DOTS signal from a
DOTS client to a DOTS server.</t>
<section title="Convey DOTS signal">
<t>An HTTP POST request will be used to convey DOTS signal to the
DOTS server.</t>
<t><figure anchor="Figure1" title="POST to convey DOTS signal">
<artwork align="left"><![CDATA[ POST {scheme}://{host}:{port}/.well-known/{version}/{URI suffix for DOTS signal}
Accept: application/json
Content-type: application/json
{
"policy-id": number,
"target-ip": string,
"target-port": string,
"target-protocol": string,
}
]]></artwork>
</figure></t>
<t>The header fields are described below.</t>
<t><list style="hanging">
<t hangText="policy-id:">Identifier of the policy represented
using a number. This identifier MUST be unique for each policy
bound to the DOTS client i.e. the policy-id needs to be unique
relative to the active policies with the DOTS server. This
identifier must be generated by the client and used as an opaque
value by the server. This document does not make any assumption
about how this identifier is generated. This is an mandatory
attribute.</t>
<t hangText="target-ip:">A list of addresses or prefixes under
attack. This is an optional attribute.</t>
<t hangText="target-port:">A list of ports under attack. This is
an optional attribute.</t>
<t hangText="target-protocol:">A list of protocols under attack.
Valid protocol values include tcp, udp, sctp and dccp. This is
an optional attribute.</t>
</list></t>
<t>Note: administrative-related clauses may be included as part of
the request (such a contract Identifier or a customer identifier).
Those clauses are out of scope of this document.</t>
<t>The relative order of two rules is determined by comparing their
respective policy identifiers. The rule with lower numeric policy
identifier value has higher precedence (and thus will match before)
than the rule with higher numeric policy identifier value.</t>
<t>To avoid DOTS signal message fragmentation and the consequently
decreased probability of message delivery, DOTS agents MUST ensure
that the DTLS record MUST fit within a single datagram. If the Path
MTU is not known to the DOTS server, an IP MTU of 1280 bytes SHOULD
be assumed. The length of the URL MUST NOT exceed 256 bytes. If UDP
is used to convey the DOTS signal and the request size exceeds the
Path MTU then the DOTS client MUST split the DOTS signal into
separate messages, for example the list of addresses in the
target-ip field could be split into multiple lists and each list
conveyed in a new POST request.</t>
<t>Implementation Note: DOTS choice of message size parameters works
well with IPv6 and with most of today's IPv4 paths. However, with
IPv4, it is harder to absolutely ensure that there is no IP
fragmentation. If IPv4 support on unusual networks is a
consideration and path MTU is unknown, implementations may want to
limit themselves to more conservative IPv4 datagram sizes such as
576 bytes, as per <xref target="RFC0791"></xref> IP packets up to
576 bytes should never need to be fragmented, thus sending a maximum
of 500 bytes of DOTS signal over a UDP datagram will generally avoid
IP fragmentation.</t>
<t>The following example shows POST request to signal that a
Web-Service is under attack.</t>
<t><figure anchor="Figure2" title="POST to signal SOS">
<artwork align="left"><![CDATA[ POST https://www.example.com/.well-known/v1/DOTS signal
Accept: application/json
Content-type: application/json
{
"policy-id": 123321333242,
"target-ip": {"2002:db8:6401::1", "2002:db8:6401::1"},
"target-port": {"80", "8080", "443"},
"target-protocol": "tcp",
}
]]></artwork>
</figure></t>
<t>The DOTS server indicates the result of processing the POST
request using HTTP response codes. HTTP 2xx codes are success
whereas HTTP 4xx codes are some sort of invalid request. If the
request is missing one or more mandatory attributes then 400 (Bad
Request) will be returned in the response or if the request contains
invalid or unknown parameters then 400 (Invalid query) will be
returned in the response. The HTTP response will include the JSON
body received in the request.</t>
</section>
<section title="Recall DOTS signal">
<t>An HTTP DELETE request will be used to delete an DOTS signal
signaled to the DOTS server. If the DOTS server does not find the
policy number conveyed in the DELETE request in its policy state
data then it responds with 404 HTTP error response code.</t>
<figure anchor="Figure3" title="Recall SOS">
<artwork align="left"><![CDATA[ DELETE {scheme}://{host}:{port}/.well-known/{URI suffix for DOTS signal}
Accept: application/json
Content-type: application/json
{
"policy-id": number
}
]]></artwork>
</figure>
<t></t>
</section>
<section title="Retrieving DOTS signal">
<t>An HTTP GET request will be used to retrieve an DOTS signal
signaled to the DOTS server. If the DOTS server does not find the
policy number conveyed in the GET request in its policy state data
then it responds with 404 HTTP error response code.</t>
<figure anchor="Figure4" title="GET to retrieve the rules">
<artwork align="left"><![CDATA[ 1) To retrieve all DOTS signal signaled by the DOTS client.
GET {scheme}://{host}:{port}/.well-known/{URI suffix for DOTS signal}
2) To retrieve a specific DOTS signal signaled by the DOTS client.
The policy information in the response will be formatted in the same order
it was processed at the DOTS server.
GET {scheme}://{host}:{port}/.well-known/{URI suffix for DOTS signal}
Accept: application/json
Content-type: application/json
{
"policy-id": number
}]]></artwork>
</figure>
<t>The following example shows the response of all the active
policies on the DOTS server.</t>
<t><figure anchor="Figure5" title="Response body">
<artwork align="left"><![CDATA[ {
"policy-data": [
{ "policy-id": 123321333242, "target-protocol": "tcp"},
{ "policy-id": 123321333244, "target-protocol": "udp"},
]
}
]]></artwork>
</figure></t>
</section>
</section>
<section title="REST">
<t>A DOTS client could use HTTPS to provision and manage filters on
the DOTS server. The DOTS client authenticates itself to the DOTS
relay, which in turn authenticates itself to a DOTS server, creating a
two-link chain of transitive authentication between the DOTS client
and the DOTS server. The DOTS relay validates if the DOTS client is
authorized to signal the black-list rules. Likewise, the DOTS server
validates if the DOTS relay is authorized to signal the black-list
rules. To create or purge filters, the DOTS client sends HTTP requests
to the DOTS relay. The DOTS relay acts as an HTTP proxy, validates the
rules and proxies the HTTP requests containing the black-listed IP
addresses to the DOTS server. When the DOTS relay receives the
associated HTTP response from the HTTP server, it propagates the
response back to the DOTS client.</t>
<t>If an attack is detected by the DOTS relay then it can act as a
HTTP client and signal the black-list rules to the DOTS server. Thus
the DOTS relay plays the role of both HTTP client and HTTP proxy.</t>
<t><figure align="center" anchor="fig">
<artwork><![CDATA[
Network
Resource CPE router Access network
(DOTS client) (DOTS relay) (DOTS server) __________
+-----------+ +----------+ +-------------+ / \
| |____| |_______| |___ | Internet |
|HTTP Client| |HTTP Proxy| | HTTP Server | | |
| | | | | | | |
+-----------+ +----------+ +-------------+ \__________/ ]]></artwork>
</figure></t>
<t>JSON <xref target="RFC7159"></xref> payloads can be used to convey
both filtering rules as well as protocol-specific payload messages
that convey request parameters and response information such as
errors.</t>
<t>The figure above explains the protocol with a DOTS relay. The
protocol is equally applicable to scenarios where a DOTS client
directly talks to the DOTS server.</t>
<section title="Filtering Rules">
<t>The following APIs define means for a DOTS client to configure
filtering rules on a DOTS server.</t>
<section title="Install filtering rules">
<t>An HTTP POST request will be used to push filtering rules to
the DOTS server.</t>
<t><figure anchor="Figure6"
title="POST to install filtering rules">
<artwork align="left"><![CDATA[ POST {scheme}://{host}:{port}/.well-known/{version}/{URI suffix for filtering}
Accept: application/json
Content-type: application/json
{
"policy-id": number,
"traffic-protocol": string,
"source-protocol-port": string,
"destination-protocol-port": string,
"destination-ip": string,
"source-ip": string,
"lifetime": number,
"traffic-rate" : number,
}
]]></artwork>
</figure></t>
<t>The header fields are described below.</t>
<t><list style="hanging">
<t hangText="policy-id:">Identifier of the policy represented
using a number. This identifier MUST be unique for each policy
bound to the DOTS client i.e. the policy-id needs to be unique
relative to the active policies with the DOTS server. This
identifier must be generated by the client and used as an
opaque value by the server. This document does not make any
assumption about how this identifier is generated. This is an
mandatory attribute.</t>
<t hangText="traffic-protocol: ">Valid protocol values include
tcp, udp, sctp and dccp. This is an mandatory attribute.</t>
<t hangText="source-protocol-port: ">For TCP or UDP or SCTP or
DCCP: the source range of ports (e.g., 1024-65535). This is an
optional attribute.</t>
<t hangText="destination-protocol-port: ">For TCP or UDP or
SCTP or DCCP: the destination range of ports (e.g., 443-443).
This information is useful to avoid disturbing a group of
customers when address sharing is in use <xref
target="RFC6269"></xref>. This is an optional attribute.</t>
<t hangText="destination-ip: ">The destination IP addresses or
prefixes. This is an optional attribute.</t>
<t hangText="source-ip: ">The source IP addresses or prefixes.
This is an optional attribute.</t>
<t hangText="lifetime: ">Lifetime of the policy in seconds.
Indicates the validity of a rule. Upon the expiry of this
lifetime, and if the request is not reiterated, the rule will
be withdrawn at the upstream network. The request can be
reiterated by sending the same message again. The server
always indicates the actual lifetime in the response. A null
value is not allowed. This is an mandatory attribute.</t>
<t hangText="traffic-rate: ">This field carries the rate
information in IEEE floating point [IEEE.754.1985] format,
units being bytes per second. A traffic-rate of '0' should
result on all traffic for the particular flow to be discarded.
This is an mandatory attribute.</t>
</list></t>
<t>The relative order of two rules is determined by comparing
their respective policy identifiers. The rule with lower numeric
policy identifier value has higher precedence (and thus will match
before) than the rule with higher numeric policy identifier
value.</t>
<t>Note: administrative-related clauses may be included as part of
the request (such a contract Identifier or a customer identifier).
Those clauses are out of scope of this document.</t>
<t>The following example shows POST request to block traffic from
attacker IPv6 prefix 2001:db8:abcd:3f01::/64 to network resource
using IPv6 address 2002:db8:6401::1 to provide HTTPS web
service.</t>
<t><figure anchor="Figure7"
title="POST to install black-list rules">
<artwork align="left"><![CDATA[ POST https://www.example.com/.well-known/v1/filter
Accept: application/json
Content-type: application/json
{
"policy-id": 123321333242,
"traffic-protocol": "tcp",
"source-protocol-port": "1-65535",
"destination-protocol-port": "443",
"destination-ip": "2001:db8:abcd:3f01::/64",
"source-ip": "2002:db8:6401::1",
"lifetime": 1800,
"traffic-rate": 0,
}
]]></artwork>
</figure></t>
<t></t>
</section>
<section title="Remove filtering rules">
<t>An HTTP DELETE request will be used to delete filtering rules
programmed on the DOTS server.</t>
<figure anchor="Figure8" title="DELETE to remove the rules">
<artwork align="left"><![CDATA[ DELETE {scheme}://{host}:{port}/.well-known/{URI suffix for filtering}
Accept: application/json
Content-type: application/json
{
"policy-id": number
}
]]></artwork>
</figure>
<t></t>
</section>
<section title="Retrieving installed filtering rules ">
<t>An HTTP GET request will be used to retrieve filtering rules
programmed on the DOTS server.</t>
<figure anchor="Figure9" title="GET to retrieve the rules">
<artwork align="left"><![CDATA[ 1) To retrieve all the black-lists rules programmed by the DOTS client.
GET {scheme}://{host}:{port}/.well-known/{URI suffix for filtering}
2) To retrieve specific black-list rules programmed by the DOTS cient.
GET {scheme}://{host}:{port}/.well-known/{URI suffix for filtering}
Accept: application/json
Content-type: application/json
{
"policy-id": number
}]]></artwork>
</figure>
</section>
</section>
</section>
</section>
<section title="IANA Considerations">
<t>TODO</t>
</section>
<section anchor="security" title="Security Considerations">
<t>Authenticated encryption MUST be used for data confidentiality and
message integrity. (D)TLS based on client certificate MUST be used for
mutual authentication. The interaction between the DOTS agents requires
Datagram Transport Layer Security (DTLS) and Transport Layer Security
(TLS) with a ciphersuite offering confidentiality protection and the
guidance given in <xref target="RFC7525"></xref> MUST be followed to
avoid attacks on (D)TLS.</t>
<t>If TCP is used between DOTS agents, attacker will be able to inject
RST packets, bogus application segments, etc., regardless of whether TLS
authentication is used. Because the application data is TLS protected,
this will not result in the application receiving bogus data, but it
will constitute a DoS on the connection. This attack can be countered by
using TCP-AO <xref target="RFC5925"></xref>. If TCP-AO is used, then any
bogus packets injected by an attacker will be rejected by the TCP-AO
integrity check and therefore will never reach the TLS layer.</t>
<t>Special care should be taken in order to ensure that the activation
of the proposed mechanism won't have an impact on the stability of the
network (including connectivity and services delivered over that
network).</t>
<t>Involved functional elements in the cooperation system must establish
exchange instructions and notification over a secure and authenticated
channel. Adequate filters can be enforced to avoid that nodes outside a
trusted domain can inject request such as deleting filtering rules.
Nevertheless, attacks can be initiated from within the trusted domain if
an entity has been corrupted. Adequate means to monitor trusted nodes
should also be enabled.</t>
</section>
<section anchor="ack" title="Acknowledgements">
<t>Thanks to C. Jacquenet, Roland Dobbins, Andrew Mortensen, Roman D.
Danyliw for the discussion and comments.</t>
</section>
</middle>
<back>
<references title="Normative References">
<?rfc include="reference.RFC.2119"?>
<?rfc include="reference.RFC.7525"?>
<?rfc include="reference.RFC.6347"?>
<?rfc include="reference.RFC.5246"?>
<?rfc include="reference.RFC.5925"?>
</references>
<references title="Informative References">
<?rfc include="reference.RFC.4732"?>
<reference anchor="REPORT"
target="http://pages.arbornetworks.com/rs/arbor/images/WISR2014.pdf">
<front>
<title>Worldwide Infrastructure Security Report</title>
<author fullname="Arbor">
<organization></organization>
</author>
<date year="2014" />
</front>
</reference>
<?rfc include="reference.RFC.7159"?>
<?rfc include="reference.RFC.7413"?>
<?rfc include="reference.RFC.5077"?>
<?rfc include="reference.RFC.5575"?>
<?rfc include='reference.RFC.6269'?>
<?rfc include='reference.RFC.6555'?>
<?rfc include='reference.RFC.0791'?>
<?rfc include='reference.RFC.6724'?>
<?rfc include="reference.RFC.6520"?>
<?rfc include="reference.I-D.ietf-tls-cached-info"?>
<?rfc include="reference.I-D.ietf-tls-falsestart"?>
<?rfc include="reference.I-D.ietf-dots-requirements"?>
</references>
<section title="BGP">
<t>BGP defines a mechanism as described in <xref
target="RFC5575"></xref> that can be used to automate inter-domain
coordination of traffic filtering, such as what is required in order to
mitigate DDoS attacks. However, support for BGP in an access network
does not guarantee that traffic filtering will always be honored. Since
a DOTS client will not receive an acknowledgment for the filtering
request, the DOTS client should monitor and apply similar rules in its
own network in cases where the DOTS server is unable to enforce the
filtering rules. In addition, enforcement of filtering rules of BGP on
Internet routers are usually governed by the maximum number of data
elements the routers can hold as well as the number of events they are
able to process in a given unit of time.</t>
</section>
</back>
</rfc>
| PAFTECH AB 2003-2026 | 2026-04-24 04:37:24 |