DOTS M. Boucadair, Ed.
Internet-Draft Orange
Intended status: Standards Track T. Reddy, Ed.
Expires: October 17, 2020 McAfee
E. Doron
Radware Ltd.
M. Chen
CMCC
April 15, 2020
Distributed Denial-of-Service Open Threat Signaling (DOTS) Telemetry
draft-ietf-dots-telemetry-07
Abstract
This document aims to enrich DOTS signal channel protocol with
various telemetry attributes allowing optimal DDoS attack mitigation.
It specifies the normal traffic baseline and attack traffic telemetry
attributes a DOTS client can convey to its DOTS server in the
mitigation request, the mitigation status telemetry attributes a DOTS
server can communicate to a DOTS client, and the mitigation efficacy
telemetry attributes a DOTS client can communicate to a DOTS server.
The telemetry attributes can assist the mitigator to choose the DDoS
mitigation techniques and perform optimal DDoS attack mitigation.
Status of This Memo
This Internet-Draft is submitted in full conformance with the
provisions of BCP 78 and BCP 79.
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and may be updated, replaced, or obsoleted by other documents at any
time. It is inappropriate to use Internet-Drafts as reference
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This Internet-Draft will expire on October 17, 2020.
Copyright Notice
Copyright (c) 2020 IETF Trust and the persons identified as the
document authors. All rights reserved.
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 3
2. Terminology . . . . . . . . . . . . . . . . . . . . . . . . . 5
3. DOTS Telemetry: Overview and Purpose . . . . . . . . . . . . 5
4. Generic Considerations . . . . . . . . . . . . . . . . . . . 9
4.1. DOTS Client Identification . . . . . . . . . . . . . . . 9
4.2. DOTS Gateways . . . . . . . . . . . . . . . . . . . . . . 9
4.3. Empty URI Paths . . . . . . . . . . . . . . . . . . . . . 9
4.4. Controlling Configuration Data . . . . . . . . . . . . . 9
4.5. Block-wise Transfer . . . . . . . . . . . . . . . . . . . 10
4.6. DOTS Multi-homing Considerations . . . . . . . . . . . . 10
4.7. YANG Considerations . . . . . . . . . . . . . . . . . . . 10
4.8. A Note About Examples . . . . . . . . . . . . . . . . . . 11
5. Telemetry Operation Paths . . . . . . . . . . . . . . . . . . 11
6. DOTS Telemetry Setup Configuration . . . . . . . . . . . . . 12
6.1. Telemetry Configuration . . . . . . . . . . . . . . . . . 13
6.1.1. Retrieve Current DOTS Telemetry Configuration . . . . 13
6.1.2. Convey DOTS Telemetry Configuration . . . . . . . . . 16
6.1.3. Retrieve Installed DOTS Telemetry Configuration . . . 19
6.1.4. Delete DOTS Telemetry Configuration . . . . . . . . . 19
6.2. Total Pipe Capacity . . . . . . . . . . . . . . . . . . . 20
6.2.1. Convey DOTS Client Domain Pipe Capacity . . . . . . . 21
6.2.2. Retrieve Installed DOTS Client Domain Pipe Capacity . 26
6.2.3. Delete Installed DOTS Client Domain Pipe Capacity . . 26
6.3. Telemetry Baseline . . . . . . . . . . . . . . . . . . . 27
6.3.1. Convey DOTS Client Domain Baseline Information . . . 30
6.3.2. Retrieve Installed Normal Traffic Baseline . . . . . 33
6.3.3. Delete Installed Normal Traffic Baseline . . . . . . 33
6.4. Reset Installed Telemetry Setup . . . . . . . . . . . . . 33
6.5. Conflict with Other DOTS Clients of the Same Domain . . . 33
7. DOTS Pre-or-Ongoing Mitigation Telemetry . . . . . . . . . . 34
7.1. Pre-or-Ongoing-Mitigation DOTS Telemetry Attributes . . . 36
7.1.1. Target . . . . . . . . . . . . . . . . . . . . . . . 36
7.1.2. Total Traffic . . . . . . . . . . . . . . . . . . . . 38
7.1.3. Total Attack Traffic . . . . . . . . . . . . . . . . 39
7.1.4. Total Attack Connections . . . . . . . . . . . . . . 41
7.1.5. Attack Details . . . . . . . . . . . . . . . . . . . 42
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7.2. From DOTS Clients to DOTS Servers . . . . . . . . . . . . 44
7.3. From DOTS Servers to DOTS Clients . . . . . . . . . . . . 47
8. DOTS Telemetry Mitigation Status Update . . . . . . . . . . . 51
8.1. DOTS Clients to Servers Mitigation Efficacy DOTS
Telemetry Attributes . . . . . . . . . . . . . . . . . . 51
8.2. DOTS Servers to Clients Mitigation Status DOTS Telemetry
Attributes . . . . . . . . . . . . . . . . . . . . . . . 53
9. YANG Module . . . . . . . . . . . . . . . . . . . . . . . . . 57
10. YANG/JSON Mapping Parameters to CBOR . . . . . . . . . . . . 83
11. IANA Considerationsr . . . . . . . . . . . . . . . . . . . . 87
11.1. DOTS Signal Channel CBOR Key Values . . . . . . . . . . 87
11.2. DOTS Signal Channel Conflict Cause Codes . . . . . . . . 91
11.3. DOTS Signal Telemetry YANG Module . . . . . . . . . . . 91
12. Security Considerations . . . . . . . . . . . . . . . . . . . 91
13. Contributors . . . . . . . . . . . . . . . . . . . . . . . . 91
14. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . 92
15. References . . . . . . . . . . . . . . . . . . . . . . . . . 92
15.1. Normative References . . . . . . . . . . . . . . . . . . 92
15.2. Informative References . . . . . . . . . . . . . . . . . 93
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 94
1. Introduction
Distributed Denial of Service (DDoS) attacks have become more
sophisticated. IT organizations and service providers are facing
DDoS attacks that fall into two broad categories:
1. Network/Transport layer attacks target the victim's
infrastructure. These attacks are not necessarily aimed at
taking down the actual delivered services, but rather to
eliminate various network elements (routers, switches, firewalls,
transit links, and so on) from serving legitimate users traffic.
The main method of such attacks is to send a large volume or high
packet per second (pps) of traffic toward the victim's
infrastructure. Typically, attack volumes may vary from a few
100 Mbps to 100s of Gbps or even Tbps. Attacks are commonly
carried out leveraging botnets and attack reflectors for
amplification attacks such as NTP (Network Time Protocol), DNS
(Domain Name System), SNMP (Simple Network Management Protocol),
or SSDP (Simple Service Discovery Protocol).
2. Application layer attacks target various applications. Typical
examples include attacks against HTTP/HTTPS, DNS, SIP (Session
Initiation Protocol), or SMTP (Simple Mail Transfer Protocol).
However, all applications with their port numbers open at network
edges can be attractive attack targets.
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Application layer attacks are considered more complex and hard to
categorize, therefore harder to detect and mitigate efficiently.
To compound the problem, attackers also leverage multi-vectored
attacks. These attacks are assembled from dynamic attack vectors
(Network/Application) and tactics. As such, multiple attack vectors
formed by multiple attack types and volumes are launched
simultaneously towards a victim. Multi-vector attacks are harder to
detect and defend. Multiple and simultaneous mitigation techniques
are needed to defeat such attack campaigns. It is also common for
attackers to change attack vectors right after a successful
mitigation, burdening their opponents with changing their defense
methods.
The ultimate conclusion derived from these real scenarios is that
modern attacks detection and mitigation are most certainly
complicated and highly convoluted tasks. They demand a comprehensive
knowledge of the attack attributes, the targeted normal behavior
(including, normal traffic patterns), as well as the attacker's on-
going and past actions. Even more challenging, retrieving all the
analytics needed for detecting these attacks is not simple to obtain
with the industry's current capabilities.
The DOTS signal channel protocol [I-D.ietf-dots-signal-channel] is
used to carry information about a network resource or a network (or a
part thereof) that is under a DDoS attack. Such information is sent
by a DOTS client to one or multiple DOTS servers so that appropriate
mitigation actions are undertaken on traffic deemed suspicious.
Various use cases are discussed in [I-D.ietf-dots-use-cases].
Typically, DOTS clients can be integrated within a DDoS attack
detector, or network and security elements that have been actively
engaged with ongoing attacks. The DOTS client mitigation environment
determines that it is no longer possible or practical for it to
handle these attacks. This can be due to a lack of resources or
security capabilities, as derived from the complexities and the
intensity of these attacks. In this circumstance, the DOTS client
has invaluable knowledge about the actual attacks that need to be
handled by its DOTS server(s). By enabling the DOTS client to share
this comprehensive knowledge of an ongoing attack under specific
circumstances, the DOTS server can drastically increase its ability
to accomplish successful mitigation. While the attack is being
handled by the DOTS server associated mitigation resources, the DOTS
server has the knowledge about the ongoing attack mitigation. The
DOTS server can share this information with the DOTS client so that
the client can better assess and evaluate the actual mitigation
realized.
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DOTS clients can send mitigation hints derived from attack details to
DOTS servers, with the full understanding that the DOTS server may
ignore mitigation hints, as described in [RFC8612] (Gen-004).
Mitigation hints will be transmitted across the DOTS signal channel,
as the data channel may not be functional during an attack. How a
DOTS server is handling normal and attack traffic attributes, and
mitigation hints is implementation-specific.
Both DOTS client and server can benefit this information by
presenting various information in relevant management, reporting, and
portal systems.
This document defines DOTS telemetry attributes that can be conveyed
by DOTS clients to DOTS servers, and vice versa. The DOTS telemetry
attributes are not mandatory fields. Nevertheless, when DOTS
telemetry attributes are available to a DOTS agent, and absent any
policy, it can signal the attributes in order to optimize the overall
mitigation service provisioned using DOTS. Some of the DOTS
telemetry data is not shared during an attack time.
2. Terminology
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and
"OPTIONAL" in this document are to be interpreted as described in BCP
14 [RFC2119][RFC8174] when, and only when, they appear in all
capitals, as shown here.
The reader should be familiar with the terms defined in [RFC8612].
"DOTS Telemetry" is defined as the collection of attributes that are
used to characterize normal traffic baseline, attacks and their
mitigation measures, and any related information that may help in
enforcing countermeasures. The DOTS Telemetry is an optional set of
attributes that can be signaled in the DOTS signal channel protocol.
The meaning of the symbols in YANG tree diagrams is defined in
[RFC8340].
3. DOTS Telemetry: Overview and Purpose
When signaling a mitigation request, it is most certainly beneficial
for DOTS clients to signal to DOTS servers any knowledge regarding
ongoing attacks. This can happen in cases where DOTS clients are
asking DOTS servers for support in defending against attacks that
they have already detected and/or mitigated. These actions taken by
DOTS clients are referred to as "signaling the DOTS Telemetry".
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If attacks are already detected and categorized within a DOTS client
domain, the DOTS server, and its associated mitigation services, can
proactively benefit this information and optimize the overall service
delivery. It is important to note that DOTS clients and servers
detection and mitigation approaches can be different, and can
potentially outcome different results and attack classifications.
The DDoS mitigation service treats the ongoing attack details
received from DOTS clients as hints and cannot completely rely or
trust the attack details conveyed by DOTS clients.
A basic requirement of security operation teams is to be aware and
get visibility into the attacks they need to handle. The DOTS server
security operation teams benefit from the DOTS telemetry, especially
from the reports of ongoing attacks. Even if some mitigation can be
automated, operational teams can use the DOTS telemetry to be
prepared for attack mitigation and to assign the correct resources
(operation staff, networking and mitigation) for the specific
service. Similarly, security operation personnel at the DOTS client
side ask for feedback about their requests for protection.
Therefore, it is valuable for DOTS servers to share DOTS telemetry
with DOTS clients.
Mutual sharing of information is thus crucial for "closing the
mitigation loop" between DOTS clients and servers. For the server
side team, it is important to realize that the same attacks that the
DOTS server's mitigation resources are seeing are those that a DOTS
client is asking to mitigate. For the DOTS client side team, it is
important to realize that the DOTS clients receive the required
service. For example, understanding that "I asked for mitigation of
two attacks and my DOTS server detects and mitigates only one...".
Cases of inconsistency in attack classification between DOTS clients
and servers can be highlighted, and maybe handled, using the DOTS
telemetry attributes.
In addition, management and orchestration systems, at both DOTS
client and server sides, can use DOTS telemetry as a feedback to
automate various control and management activities derived from
signaled telemetry information .
If the DOTS server's mitigation resources have the capabilities to
facilitate the DOTS telemetry, the DOTS server adapts its protection
strategy and activates the required countermeasures immediately
(automation enabled) for the sake of optimized attack mitigation
decisions and actions.
DOTS telemetry can also be used to tune the DDoS mitigators with the
correct state of an attack. During the last few years, DDoS attack
detection technologies have evolved from threshold-based detection
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(that is, cases when all or specific parts of traffic cross a pre-
defined threshold for a certain period of time is considered as an
attack) to an "anomaly detection" approach. For the latter, it is
required to maintain rigorous learning of "normal" behavior and where
an "anomaly" (or an attack) is identified and categorized based on
the knowledge about the normal behavior and a deviation from this
normal behavior. Machine learning approaches are used such that the
actual traffic thresholds are automatically calculated by learning
the protected entity normal traffic behavior during idle time. The
normal traffic characterization learned is referred to as the "normal
traffic baseline". An attack is detected when the victim's actual
traffic is deviating from this normal baseline.
In addition, subsequent activities toward mitigating an attack are
much more challenging. The ability to distinguish legitimate traffic
from attacker traffic on a per packet basis is complex. For example,
a packet may look "legitimate" and no attack signature can be
identified. The anomaly can be identified only after detailed
statistical analysis. DDoS attack mitigators use the normal baseline
during the mitigation of an attack to identify and categorize the
expected appearance of a specific traffic pattern. Particularly, the
mitigators use the normal baseline to recognize the "level of
normality" needs to be achieved during the various mitigation
process.
Normal baseline calculation is performed based on continuous learning
of the normal behavior of the protected entities. The minimum
learning period varies from hours to days and even weeks, depending
on the protected application behavior. The baseline cannot be
learned during active attacks because attack conditions do not
characterize the protected entities' normal behavior.
If the DOTS client has calculated the normal baseline of its
protected entities, signaling such information to the DOTS server
along with the attack traffic levels is significantly valuable. The
DOTS server benefits from this telemetry by tuning its mitigation
resources with the DOTS client's normal baseline. The DOTS server
mitigators use the baseline to familiarize themselves with the attack
victim's normal behavior and target the baseline as the level of
normality they need to achieve. Fed with this inforamtion, the
overall mitigation performances is expected to be improved in terms
of time to mitigate, accuracy, false-negative, and false-positive.
Mitigation of attacks without having certain knowledge of normal
traffic can be inaccurate at best. This is especially true for
recursive signaling (see Section 3.2.3 in [I-D.ietf-dots-use-cases]).
In addition, the highly diverse types of use-cases where DOTS clients
are integrated also emphasize the need for knowledge of each DOTS
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client domain behavior. Consequently, common global thresholds for
attack detection practically cannot be realized. Each DOTS client
domain can have its own levels of traffic and normal behavior.
Without facilitating normal baseline signaling, it may be very
difficult for DOTS servers in some cases to detect and mitigate the
attacks accurately:
It is important to emphasize that it is practically impossible for
the DOTS server's mitigators to calculate the normal baseline in
cases where they do not have any knowledge of the traffic
beforehand.
In addition, baseline learning requires a period of time that
cannot be afforded during active attack.
Of course, this information can provided using out-of-band
mechanisms or manual configuration at the risk to maintain
inaccurate information as the network evolves and "normal"
patterns change. The use of a dynamic and collaborative means
between the DOTS client and server to identify and share key
parameters for the sake of efficient DDoS protection is valuable.
During a high volume attack, DOTS client pipes can be totally
saturated. DOTS clients ask their DOTS servers to handle the attack
upstream so that DOTS client pipes return to a reasonable load level
(normal pattern, ideally). At this point, it is essential to ensure
that the mitigator does not overwhelm the DOTS client pipes by
sending back "clean traffic", or what it believes is "clean". This
can happen when the mitigator has not managed to detect and mitigate
all the attacks launched towards the DOTS client domain. In this
case, it can be valuable to DOTS clients to signal to DOTS servers
the "total pipe capacity", which is the level of traffic the DOTS
client domain can absorb from its upstream network. Dynamic updates
of the condition of pipes between DOTS agents while they are under a
DDoS attack is essential (e.g., where multiple DOTS clients share the
same physical connectivity pipes). It is important to note that the
term "pipe" noted here does not necessary represent physical pipe,
but rather represents the maximum level of traffic that the DOTS
client domain can receive. The DOTS server should activate other
mechanisms to ensure it does not allow the DOTS client domain's pipes
to be saturated unintentionally. The rate-limit action defined in
[I-D.ietf-dots-data-channel] is a reasonable candidate to achieve
this objective; the DOTS client can ask for the type(s) of traffic
(such as ICMP, UDP, TCP port number 80) it prefers to limit. The
rate-limit action can be controlled via the signal-channel
[I-D.ietf-dots-signal-filter-control] even when the pipe is
overwhelmed.
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To summarize:
Timely and effective signaling of up-to-date DDoS telemetry to all
elements involved in the mitigation process is essential and
absolutely improves the overall DDoS mitigation service
effectiveness. Bi-directional feedback between DOTS agents is
required for an increased awareness of each party, supporting
superior and highly efficient attack mitigation service.
4. Generic Considerations
4.1. DOTS Client Identification
Following the rules in [I-D.ietf-dots-signal-channel], a unique
identifier is generated by a DOTS client to prevent request
collisions ('cuid').
As a reminder, [I-D.ietf-dots-signal-channel] forbids 'cuid' to be
returned in a response message body.
4.2. DOTS Gateways
DOTS gateways may be located between DOTS clients and servers. The
considerations elaborated in [I-D.ietf-dots-signal-channel] must be
followed. In particular, 'cdid' attribute is used to unambiguously
identify a DOTS client domain.
As a reminder, [I-D.ietf-dots-signal-channel] forbids 'cdid' (if
present) to be returned in a response message body.
4.3. Empty URI Paths
Uri-Path parameters and attributes with empty values MUST NOT be
present in a request and render an entire message invalid.
4.4. Controlling Configuration Data
The DOTS server follows the same considerations discussed in
Section of 4.5.3 of [I-D.ietf-dots-signal-channel] for managing DOTS
telemetry configuration freshness and notification. Likewise, a DOTS
client may control the selection of configuration and non-
configuration data nodes when sending a GET request by means of the
'c' Uri-Query option and following the procedure specified in
Section of 4.4.2 of [I-D.ietf-dots-signal-channel]. These
considerations are not re-iterated in the following sections.
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4.5. Block-wise Transfer
DOTS clients can use Block-wise transfer [RFC7959] with the
recommendation detailed in Section 4.4.2 of
[I-D.ietf-dots-signal-channel] to control the size of a response when
the data to be returned does not fit within a single datagram.
DOTS clients can also use Block1 Option in a PUT request (see
Section 2.5 of [RFC7959]) to initiate large transfers, but these
Block1 transfers will fail if the inbound "pipe" is running full, so
consideration needs to be made to try to fit this PUT into a single
transfer, or to separate out the PUT into several discrete PUTs where
each of them fits into a single packet.
Block3 and Block 4 options that are similar to the CoAP Block1 and
Block2 options, but enable faster transmissions of big blocks of data
with less packet interchanges, are defined in
[I-D.bosh-core-new-block]. DOTS implementations can consider the use
of Block3 and Block 4 options.
4.6. DOTS Multi-homing Considerations
Multi-homed DOTS clients are assumed to follow the recommendations in
[I-D.ietf-dots-multihoming] to select which DOTS server to contact
and which IP prefixes to include in a telemetry message to a given
peer DOTS server. For example, if each upstream network exposes a
DOTS server and the DOTS client maintains DOTS channels with all of
them, only the information related to prefixes assigned by an
upstream network to the DOTS client domain will be signaled via the
DOTS channel established with the DOTS server of that upstream
network. Considerations related to whether (and how) a DOTS client
gleans some telemetry information (e.g., attack details) it receives
from a first DOTS server and share it with a second DOTS server are
implementation and deployment-specific.
4.7. YANG Considerations
Messages exchanged between DOTS agents are serialized using Concise
Binary Object Representation (CBOR). CBOR-encoded payloads are used
to carry signal channel-specific payload messages which convey
request parameters and response information such as errors
[I-D.ietf-dots-signal-channel].
This document specifies a YANG module for representing DOTS telemetry
message types (Section 9). All parameters in the payload of the DOTS
signal channel are mapped to CBOR types as specified in Section 10.
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This YANG module is not intended to be used via NETCONF/ RESTCONF for
DOTS server management purposes; such module is out of the scope of
this document. It serves only to provide a data model and encoding,
but not a management data model.
DOTS servers are allowed to update the non-configurable 'ro' entities
in the responses.
The DOTS telemetry module (Section 9) uses "enumerations" rather than
"identities" to define units, samples, and intervals because
otherwise the namespace identifier "ietf-dots-telemetry" must be
included when a telemetry attribute is included (e.g., in a
mitigation efficacy update). The use of "identities" is thus
suboptimal from a message compactness standpoint.
4.8. A Note About Examples
Examples are provided for illustration purposes. The document does
not aim to provide a comprehensive list of message examples.
The authoritative reference for validating telemetry messages is the
YANG module (Section 9) and the mapping table established in
Section 10.
5. Telemetry Operation Paths
As discussed in [I-D.ietf-dots-signal-channel], each DOTS operation
is indicated by a path-suffix that indicates the intended operation.
The operation path is appended to the path-prefix to form the URI
used with a CoAP request to perform the desired DOTS operation. The
following telemetry path-suffixes are defined (Table 1):
+-----------------+----------------+-----------+
| Operation | Operation Path | Details |
+-----------------+----------------+-----------+
| Telemetry Setup | /tm-setup | Section 6 |
| Telemetry | /tm | Section 7 |
+-----------------+----------------+-----------+
Table 1: DOTS Telemetry Operations
Consequently, the "ietf-dots-telemetry" YANG module defined in this
document (Section 9) augments the "ietf-dots-signal" with two new
message types called "telemetry-setup" and "telemetry". The tree
structure is shown in Figure 1 (more details are provided in the
following sections about the exact structure of "telemetry-setup" and
"telemetry" message types).
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augment /ietf-signal:dots-signal/ietf-signal:message-type:
+--:(telemetry-setup) {dots-telemetry}?
| ...
| +--rw (setup-type)?
| +--:(telemetry-config)
| | ...
| +--:(pipe)
| | ...
| +--:(baseline)
| ...
+--:(telemetry) {dots-telemetry}?
...
Figure 1: New DOTS Message Types (YANG Tree Structure)
6. DOTS Telemetry Setup Configuration
In reference to Figure 1, a DOTS telemetry setup message MUST include
only telemetry-related configuration parameters (Section 6.1) or
information about DOTS client domain pipe capacity (Section 6.2) or
telemetry traffic baseline (Section 6.3). As such, requests that
include a mix of telemetry configuration, pipe capacity, or traffic
baseline MUST be rejected by DOTS servers with a 4.00 (Bad Request).
A DOTS client can reset all installed DOTS telemetry setup
configuration data following the considerations detailed in
Section 6.4.
A DOTS server may detect conflicts when processing requests related
to DOTS client domain pipe capacity or telemetry traffic baseline
with requests from other DOTS clients of the same DOTS client domain.
More details are included in Section 6.5.
Telemetry setup configuration is bound to a DOTS client domain. DOTS
servers MUST NOT expect DOTS clients to send regular requests to
refresh the telemetry setup configuration. Any available telemetry
setup configuration has a validity timeout of the DOTS association
with a DOTS client domain. DOTS servers MUST NOT reset 'tsid'
because a session failed with a DOTS client. DOTS clients update
their telemetry setup configuration upon change of a parameter that
may impact attack mitigation.
DOTS telemetry setup configuration request and response messages are
marked as Confirmable messages.
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6.1. Telemetry Configuration
A DOTS client can negotiate with its server(s) a set of telemetry
configuration parameters to be used for telemetry. Such parameters
include:
o Percentile-related measurement parameters
o Measurement units
o Acceptable percentile values
o Telemetry notification interval
o Acceptable Server-originated telemetry
Section 11.3 of [RFC2330] includes more details about computing
percentiles.
6.1.1. Retrieve Current DOTS Telemetry Configuration
A GET request is used to obtain acceptable and current telemetry
configuration parameters on the DOTS server. This request may
include a 'cdid' Path-URI when the request is relayed by a DOTS
gateway. An example of such request is depicted in Figure 2.
Header: GET (Code=0.01)
Uri-Path: ".well-known"
Uri-Path: "dots"
Uri-Path: "tm-setup"
Uri-Path: "cuid=dz6pHjaADkaFTbjr0JGBpw"
Figure 2: GET to Retrieve Current and Acceptable DOTS Telemetry
Configuration
Upon receipt of such request, the DOTS server replies with a 2.05
(Content) response that conveys the current and telemetry parameters
acceptable by the DOTS server. The tree structure of the response
message body is provided in Figure 3. Note that the response also
includes any pipe (Section 6.2) and baseline information
(Section 6.3) maintained by the DOTS server for this DOTS client.
DOTS servers that support the capability of sending telemetry
information to DOTS clients prior or during a mitigation
(Section 8.2) sets 'server-originated-telemetry' under 'max-config-
values' to 'true' ('false' is used otherwise). If 'server-
originated-telemetry' is not present in a response, this is
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equivalent to receiving a request with 'server-originated-telemetry'
set to 'false'.
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augment /ietf-signal:dots-signal/ietf-signal:message-type:
+--:(telemetry-setup) {dots-telemetry}?
| +--ro max-config-values
| | +--ro measurement-interval? interval
| | +--ro measurement-sample? sample
| | +--ro low-percentile? percentile
| | +--ro mid-percentile? percentile
| | +--ro high-percentile? percentile
| | +--ro server-originated-telemetry? boolean
| | +--ro telemetry-notify-interval? uint32
| +--ro min-config-values
| | +--ro measurement-interval? interval
| | +--ro measurement-sample? sample
| | +--ro low-percentile? percentile
| | +--ro mid-percentile? percentile
| | +--ro high-percentile? percentile
| | +--ro telemetry-notify-interval? uint32
| +--ro supported-units
| | +--ro unit-config* [unit]
| | +--ro unit unit-type
| | +--ro unit-status boolean
| +--rw telemetry* [cuid tsid]
| +--rw cuid string
| +--rw cdid? string
| +--rw tsid uint32
| +--rw (setup-type)?
| +--:(telemetry-config)
| | +--rw current-config
| | +--rw measurement-interval? interval
| | +--rw measurement-sample? sample
| | +--rw low-percentile? percentile
| | +--rw mid-percentile? percentile
| | +--rw high-percentile? percentile
| | +--rw unit-config* [unit]
| | | +--rw unit unit-type
| | | +--rw unit-status boolean
| | +--rw server-originated-telemetry? boolean
| | +--rw telemetry-notify-interval? uint32
| +--:(pipe)
| ...
| +--:(baseline)
| ...
+--:(telemetry) {dots-telemetry}?
+--rw pre-or-ongoing-mitigation* [cuid tmid]
...
Figure 3: Telemetry Configuration Tree Structure
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When both 'min-config-values' and 'max-config-values' attributes are
present, the values carried in 'max-config-values' attributes MUST be
greater or equal to their counterpart in 'min-config-values'
attributes.
6.1.2. Convey DOTS Telemetry Configuration
PUT request is used to convey the configuration parameters for the
telemetry data (e.g., low, mid, or high percentile values). For
example, a DOTS client may contact its DOTS server to change the
default percentile values used as baseline for telemetry data.
Figure 3 lists the attributes that can be set by a DOTS client in
such PUT request. An example of a DOTS client that modifies all
percentile reference values is shown in Figure 4.
Header: PUT (Code=0.03)
Uri-Path: ".well-known"
Uri-Path: "dots"
Uri-Path: "tm-setup"
Uri-Path: "cuid=dz6pHjaADkaFTbjr0JGBpw"
Uri-Path: "tsid=123"
Content-Format: "application/dots+cbor"
{
"ietf-dots-telemetry:telemetry-setup": {
"telemetry": [
{
"current-config": {
"low-percentile": "5.00",
"mid-percentile": "65.00",
"high-percentile": "95.00"
}
}
]
}
}
Figure 4: PUT to Convey the DOTS Telemetry Configuration
'cuid' is a mandatory Uri-Path parameter for PUT requests.
The following additional Uri-Path parameter is defined:
tsid: Telemetry Setup Identifier is an identifier for the DOTS
telemetry setup configuration data represented as an integer.
This identifier MUST be generated by DOTS clients. 'tsid'
values MUST increase monotonically (when a new PUT is generated
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by a DOTS client to convey new configuration parameters for the
telemetry).
This is a mandatory attribute.
'cuid' and 'tsid' MUST NOT appear in the PUT request message body.
At least one configurable attribute MUST be present in the PUT
request.
The PUT request with a higher numeric 'tsid' value overrides the DOTS
telemetry configuration data installed by a PUT request with a lower
numeric 'tsid' value. To avoid maintaining a long list of 'tsid'
requests for requests carrying telemetry configuration data from a
DOTS client, the lower numeric 'tsid' MUST be automatically deleted
and no longer be available at the DOTS server.
The DOTS server indicates the result of processing the PUT request
using the following response codes:
o If the request is missing a mandatory attribute, does not include
'cuid' or 'tsid' Uri-Path parameters, or contains one or more
invalid or unknown parameters, 4.00 (Bad Request) MUST be returned
in the response.
o If the DOTS server does not find the 'tsid' parameter value
conveyed in the PUT request in its configuration data and if the
DOTS server has accepted the configuration parameters, then a
response code 2.01 (Created) MUST be returned in the response.
o If the DOTS server finds the 'tsid' parameter value conveyed in
the PUT request in its configuration data and if the DOTS server
has accepted the updated configuration parameters, 2.04 (Changed)
MUST be returned in the response.
o If any of the enclosed configurable attribute values are not
acceptable to the DOTS server (Section 6.1.1), 4.22 (Unprocessable
Entity) MUST be returned in the response.
The DOTS client may re-try and send the PUT request with updated
attribute values acceptable to the DOTS server.
By default, low percentile (10th percentile), mid percentile (50th
percentile), high percentile (90th percentile), and peak (100th
percentile) values are used to represent telemetry data.
Nevertheless, a DOTS client can disable some percentile types (low,
mid, high). In particular, setting 'low-percentile' to '0.00'
indicates that the DOTS client is not interested in receiving low-
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percentiles. Likewise, setting 'mid-percentile' (or 'high-
percentile') to the same value as 'low-percentile' (or 'mid-
percentile') indicates that the DOTS client is not interested in
receiving mid-percentiles (or high-percentiles). For example, a DOTS
client can send the request depicted in Figure 5 to inform the server
that it is interested in receiving only high-percentiles. This
assumes that the client will only use that percentile type when
sharing telemetry data with the server.
Header: PUT (Code=0.03)
Uri-Path: ".well-known"
Uri-Path: "dots"
Uri-Path: "tm-setup"
Uri-Path: "cuid=dz6pHjaADkaFTbjr0JGBpw"
Uri-Path: "tsid=569"
Content-Format: "application/dots+cbor"
{
"ietf-dots-telemetry:telemetry-setup": {
"telemetry": [
{
"current-config": {
"low-percentile": "0.00",
"mid-percentile": "0.00",
"high-percentile": "95.00"
}
}
]
}
}
Figure 5: PUT to Disable Low- and Mid-Percentiles
DOTS clients can also configure the unit type(s) to be used for
traffic-related telemetry data. Typically, the supported unit types
are: packets per second, bits per second, and bytes per second.
DOTS clients that are interested to receive pre- or ongoing
mitigation telemetry (pre-or-ongoing-mitigation) information from a
DOTS server (Section 8.2) MUST set 'server-originated-telemetry' to
'true'. If 'server-originated-telemetry' is not present in a PUT
request, this is equivalent to receiving a request with 'server-
originated-telemetry' set to 'false'. An example of a request to
enable pre-or-ongoing-mitigation telemetry from DOTS servers is shown
in Figure 6.
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Header: PUT (Code=0.03)
Uri-Path: ".well-known"
Uri-Path: "dots"
Uri-Path: "tm-setup"
Uri-Path: "cuid=dz6pHjaADkaFTbjr0JGBpw"
Uri-Path: "tsid=569"
Content-Format: "application/dots+cbor"
{
"ietf-dots-telemetry:telemetry-setup": {
"telemetry": [
{
"current-config": {
"server-originated-telemetry": true
}
}
]
}
}
Figure 6: PUT to Enable Pre-or-ongoing-mitigation Telemetry from the
DOTS server
6.1.3. Retrieve Installed DOTS Telemetry Configuration
A DOTS client may issue a GET message with 'tsid' Uri-Path parameter
to retrieve the current DOTS telemetry configuration. An example of
such request is depicted in Figure 7.
Header: GET (Code=0.01)
Uri-Path: ".well-known"
Uri-Path: "dots"
Uri-Path: "tm-setup"
Uri-Path: "cuid=dz6pHjaADkaFTbjr0JGBpw"
Uri-Path: "tsid=123"
Figure 7: GET to Retrieve Current DOTS Telemetry Configuration
If the DOTS server does not find the 'tsid' Uri-Path value conveyed
in the GET request in its configuration data for the requesting DOTS
client, it MUST respond with a 4.04 (Not Found) error response code.
6.1.4. Delete DOTS Telemetry Configuration
A DELETE request is used to delete the installed DOTS telemetry
configuration data (Figure 8). 'cuid' and 'tsid' are mandatory Uri-
Path parameters for such DELETE requests.
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Header: DELETE (Code=0.04)
Uri-Path: ".well-known"
Uri-Path: "dots"
Uri-Path: "tm-setup"
Uri-Path: "cuid=dz6pHjaADkaFTbjr0JGBpw"
Uri-Path: "tsid=123"
Figure 8: Delete Telemetry Configuration
The DOTS server resets the DOTS telemetry configuration back to the
default values and acknowledges a DOTS client's request to remove the
DOTS telemetry configuration using 2.02 (Deleted) response code. A
2.02 (Deleted) Response Code is returned even if the 'tsid' parameter
value conveyed in the DELETE request does not exist in its
configuration data before the request.
Section 6.4 discusses the procedure to reset all DOTS telemetry setup
configuration.
6.2. Total Pipe Capacity
A DOTS client can communicate to its server(s) its DOTS client domain
pipe information. The tree structure of the pipe information is
shown in Figure 9.
augment /ietf-signal:dots-signal/ietf-signal:message-type:
+--:(telemetry-setup) {dots-telemetry}?
| ...
| +--rw telemetry* [cuid tsid]
| +--rw cuid string
| +--rw cdid? string
| +--rw tsid uint32
| +--rw (setup-type)?
| +--:(telemetry-config)
| | ...
| +--:(pipe)
| | +--rw total-pipe-capacity* [link-id unit]
| | +--rw link-id nt:link-id
| | +--rw capacity uint64
| | +--rw unit unit
| +--:(baseline)
| ...
+--:(telemetry) {dots-telemetry}?
+--rw pre-or-ongoing-mitigation* [cuid tmid]
...
Figure 9: Pipe Tree Structure
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A DOTS client domain pipe is defined as a list of limits of
(incoming) traffic volume (total-pipe-capacity") that can be
forwarded over ingress interconnection links of a DOTS client domain.
Each of these links is identified with a "link-id" [RFC8345].
The unit used by a DOTS client when conveying pipe information is
captured in 'unit' attribute.
6.2.1. Convey DOTS Client Domain Pipe Capacity
Similar considerations to those specified in Section 6.1.2 are
followed with one exception:
The relative order of two PUT requests carrying DOTS client domain
pipe attributes from a DOTS client is determined by comparing
their respective 'tsid' values. If such two requests have
overlapping "link-id" and "unit", the PUT request with higher
numeric 'tsid' value will override the request with a lower
numeric 'tsid' value. The overlapped lower numeric 'tsid' MUST be
automatically deleted and no longer be available.
DOTS clients SHOULD minimize the number of active 'tsids' used for
pipe information. Typically, in order to avoid maintaining a long
list of 'tsids' for pipe information, it is RECOMMENDED that DOTS
clients include in any request to update information related to a
given link the information of other links (already communicated using
a lower 'tsid' value). Doing so, this update request will override
these existing requests and hence optimize the number of 'tsid'
request per DOTS client.
o Note: This assumes that all link information can fit in one single
message.
For example, a DOTS client managing a single homed domain (Figure 10)
can send a PUT request (shown in Figure 11) to communicate the
capacity of "link1" used to connect to its ISP.
,--,--,--. ,--,--,--.
,-' `-. ,-' `-.
( DOTS Client )=====( ISP#A )
`-. Domain ,-' link1 `-. ,-'
`--'--'--' `--'--'--'
Figure 10: Single Homed DOTS Client Domain
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Header: PUT (Code=0.03)
Uri-Path: ".well-known"
Uri-Path: "dots"
Uri-Path: "tm-setup"
Uri-Path: "cuid=dz6pHjaADkaFTbjr0JGBpw"
Uri-Path: "tsid=457"
Content-Format: "application/dots+cbor"
{
"ietf-dots-telemetry:telemetry-setup": {
"telemetry": [
{
"total-pipe-capacity": [
{
"link-id": "link1",
"capacity": "500",
"unit": "megabit-ps"
}
]
}
]
}
}
Figure 11: Example of a PUT Request to Convey Pipe Information
(Single Homed)
DOTS clients may be instructed to signal a link aggregate instead of
individual links. For example, a DOTS client managing a DOTS client
domain having two interconnection links with an upstream ISP
(Figure 12) can send a PUT request (shown in Figure 13) to
communicate the aggregate link capacity with its ISP. Signalling
individual or aggregate link capacity is deployment-specific.
,--,--,--. ,--,--,--.
,-' `-.===== ,-' `-.
( DOTS Client ) ( ISP#C )
`-. Domain ,-'====== `-. ,-'
`--'--'--' `--'--'--'
Figure 12: DOTS Client Domain with Two Interconnection Links
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Header: PUT (Code=0.03)
Uri-Path: ".well-known"
Uri-Path: "dots"
Uri-Path: "tm-setup"
Uri-Path: "cuid=dz6pHjaADkaFTbjr0JGBpw"
Uri-Path: "tsid=896"
Content-Format: "application/dots+cbor"
{
"ietf-dots-telemetry:telemetry-setup": {
"telemetry": [
{
"total-pipe-capacity": [
{
"link-id": "aggregate",
"capacity": "700",
"unit": "megabit-ps"
}
]
}
]
}
}
Figure 13: Example of a PUT Request to Convey Pipe Information
(Aggregated Link)
Now consider that the DOTS client domain was upgraded to connect to
an additional ISP (ISP#B of Figure 14), the DOTS client can inform a
third-party DOTS server (that is, not hosted with ISP#A and ISP#B
domains) about this update by sending the PUT request depicted in
Figure 15. This request also includes information related to "link1"
even if that link is not upgraded. Upon receipt of this request, the
DOTS server removes the request with 'tsid=457' and updates its
configuration base to maintain two links (link#1 and link#2).
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,--,--,--.
,-' `-.
( ISP#B )
`-. ,-'
`--'--'--'
||
|| link2
,--,--,--. ,--,--,--.
,-' `-. ,-' `-.
( DOTS Client )=====( ISP#A )
`-. Domain ,-' link1 `-. ,-'
`--'--'--' `--'--'--'
Figure 14: Multi-Homed DOTS Client Domain
Header: PUT (Code=0.03)
Uri-Path: ".well-known"
Uri-Path: "dots"
Uri-Path: "tm-setup"
Uri-Path: "cuid=dz6pHjaADkaFTbjr0JGBpw"
Uri-Path: "tsid=458"
Content-Format: "application/dots+cbor"
{
"ietf-dots-telemetry:telemetry-setup": {
"telemetry": [
{
"total-pipe-capacity": [
{
"link-id": "link1",
"capacity": "500",
"unit": "megabit-ps"
},
{
"link-id": "link2",
"capacity": "500",
"unit": "megabit-ps"
}
]
}
]
}
}
Figure 15: Example of a PUT Request to Convey Pipe Information
(Multi-Homed)
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A DOTS client can delete a link by sending a PUT request with the
'capacity' attribute set to "0" if other links are still active for
the same DOTS client domain (see Section 6.2.3 for other delete
cases). For example, if a DOTS client domain re-homes (that is, it
changes its ISP), the DOTS client can inform its DOTS server about
this update (e.g., from the network configuration in Figure 10 to the
one shown in Figure 16) by sending the PUT request depicted in
Figure 17. Upon receipt of this request, the DOTS server removes
"link1" from its configuration bases for this DOTS client domain.
,--,--,--.
,-' `-.
( ISP#B )
`-. ,-'
`--'--'--'
||
|| link2
,--,--,--.
,-' `-.
( DOTS Client )
`-. Domain ,-'
`--'--'--'
Figure 16: Multi-Homed DOTS Client Domain
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Header: PUT (Code=0.03)
Uri-Path: ".well-known"
Uri-Path: "dots"
Uri-Path: "tm-setup"
Uri-Path: "cuid=dz6pHjaADkaFTbjr0JGBpw"
Uri-Path: "tsid=459"
Content-Format: "application/dots+cbor"
{
"ietf-dots-telemetry:telemetry-setup": {
"telemetry": [
{
"total-pipe-capacity": [
{
"link-id": "link1",
"capacity": "0",
"unit": "megabit-ps"
},
{
"link-id": "link2",
"capacity": "500",
"unit": "megabit-ps"
}
]
}
]
}
}
Figure 17: Example of a PUT Request to Convey Pipe Information
(Multi-Homed)
6.2.2. Retrieve Installed DOTS Client Domain Pipe Capacity
A GET request with 'tsid' Uri-Path parameter is used to retrieve a
specific installed DOTS client domain pipe related information. The
same procedure as defined in (Section 6.1.3) is followed.
To retrieve all pipe information bound to a DOTS client, the DOTS
client proceeds as specified in Section 6.1.1.
6.2.3. Delete Installed DOTS Client Domain Pipe Capacity
A DELETE request is used to delete the installed DOTS client domain
pipe related information. The same procedure as defined in
(Section 6.1.4) is followed.
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6.3. Telemetry Baseline
A DOTS client can communicate to its server(s) its normal traffic
baseline and connections capacity:
Total traffic normal baseline: The percentile values representing
the total traffic normal baseline. It can be represented for a
target using 'total-traffic-normal'.
The traffic normal per protocol ('total-traffic-normal-per-
protocol') baseline is represented for a target and is transport-
protocol specific.
The traffic normal per port number ('total-traffic-normal-per-
port') baseline is represented for each port number bound to a
target.
If the DOTS client negotiated percentile values and units
(Section 6.1), these negotiated values will be used instead of the
default ones.
Total connections capacity: If the target is subjected to resource
consuming DDoS attacks, the following optional attributes for the
target per transport-protocol are useful to detect resource
consuming DDoS attacks:
* The maximum number of simultaneous connections that are allowed
to the target.
* The maximum number of simultaneous connections that are allowed
to the target per client.
* The maximum number of simultaneous embryonic connections that
are allowed to the target. The term "embryonic connection"
refers to a connection whose connection handshake is not
finished. Embryonic connection is only possible in connection-
oriented transport protocols like TCP or SCTP.
* The maximum number of simultaneous embryonic connections that
are allowed to the target per client.
* The maximum number of connections allowed per second to the
target.
* The maximum number of connections allowed per second to the
target per client.
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* The maximum number of requests allowed per second to the
target.
* The maximum number of requests allowed per second to the target
per client.
* The maximum number of partial requests allowed per second to
the target. Attacks relying upon partial requests create a
connection with a target but do not send a complete request
(e.g., HTTP request).
* The maximum number of partial requests allowed per second to
the target per client.
The aggregate per transport protocol is captured in 'total-
connection-capacity', while port-specific capabilities are
represented using 'total-connection-capacity-per-port'.
The tree structure of the baseline is shown in Figure 18.
augment /ietf-signal:dots-signal/ietf-signal:message-type:
+--:(telemetry-setup) {dots-telemetry}?
| ...
| +--rw telemetry* [cuid tsid]
| +--rw cuid string
| +--rw cdid? string
| +--rw tsid uint32
| +--rw (setup-type)?
| +--:(telemetry-config)
| | ...
| +--:(pipe)
| | ...
| +--:(baseline)
| +--rw baseline* [id]
| +--rw id uint32
| +--rw target-prefix* inet:ip-prefix
| +--rw target-port-range* [lower-port]
| | +--rw lower-port inet:port-number
| | +--rw upper-port? inet:port-number
| +--rw target-protocol* uint8
| +--rw target-fqdn* inet:domain-name
| +--rw target-uri* inet:uri
| +--rw alias-name* string
| +--rw total-traffic-normal* [unit]
| | +--rw unit unit
| | +--rw low-percentile-g? yang:gauge64
| | +--rw mid-percentile-g? yang:gauge64
| | +--rw high-percentile-g? yang:gauge64
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| | +--rw peak-g? yang:gauge64
| +--rw total-traffic-normal-per-protocol* [unit protocol]
| | +--rw unit unit
| | +--rw protocol uint8
| | +--rw low-percentile-g? yang:gauge64
| | +--rw mid-percentile-g? yang:gauge64
| | +--rw high-percentile-g? yang:gauge64
| | +--rw peak-g? yang:gauge64
| +--rw total-traffic-normal-per-port* [unit port]
| | +--rw port inet:port-number
| | +--rw unit unit
| | +--rw low-percentile-g? yang:gauge64
| | +--rw mid-percentile-g? yang:gauge64
| | +--rw high-percentile-g? yang:gauge64
| | +--rw peak-g? yang:gauge64
| +--rw total-connection-capacity* [protocol]
| | +--rw protocol uint8
| | +--rw connection? uint64
| | +--rw connection-client? uint64
| | +--rw embryonic? uint64
| | +--rw embryonic-client? uint64
| | +--rw connection-ps? uint64
| | +--rw connection-client-ps? uint64
| | +--rw request-ps? uint64
| | +--rw request-client-ps? uint64
| | +--rw partial-request-ps? uint64
| | +--rw partial-request-client-ps? uint64
| +--rw total-connection-capacity-per-port* [protocol port]
| +--rw protocol uint8
| +--rw port inet:port-number
| +--rw connection? uint64
| +--rw connection-client? uint64
| +--rw embryonic? uint64
| +--rw embryonic-client? uint64
| +--rw connection-ps? uint64
| +--rw connection-client-ps? uint64
| +--rw request-ps? uint64
| +--rw request-client-ps? uint64
| +--rw partial-request-ps? uint64
| +--rw partial-request-client-ps? uint64
+--:(telemetry) {dots-telemetry}?
+--rw pre-or-ongoing-mitigation* [cuid tmid]
...
Figure 18: Telemetry Baseline Tree Structure
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6.3.1. Convey DOTS Client Domain Baseline Information
Similar considerations to those specified in Section 6.1.2 are
followed with one exception:
The relative order of two PUT requests carrying DOTS client domain
baseline attributes from a DOTS client is determined by comparing
their respective 'tsid' values. If such two requests have
overlapping targets, the PUT request with higher numeric 'tsid'
value will override the request with a lower numeric 'tsid' value.
The overlapped lower numeric 'tsid' MUST be automatically deleted
and no longer be available.
Two PUT requests from a DOTS client have overlapping targets if there
is a common IP address, IP prefix, FQDN, URI, or alias-name. Also,
two PUT requests from a DOTS client have overlapping targets if the
addresses associated with the FQDN, URI, or alias are overlapping
with each other or with target-prefix.
DOTS clients SHOULD minimize the number of active 'tsids' used for
baseline information. Typically, in order to avoid maintaining a
long list of 'tsids' for baseline information, it is RECOMMENDED that
DOTS clients include in a request to update information related to a
given target, the information of other targets (already communicated
using a lower 'tsid' value) (assuming this fits within one single
datagram). This update request will override these existing requests
and hence optimize the number of 'tsid' request per DOTS client.
If no target clause in included in the request, this is an indication
that the baseline information applies for the DOTS client domain as a
whole.
An example of a PUT request to convey the baseline information is
shown in Figure 19.
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Header: PUT (Code=0.03)
Uri-Path: ".well-known"
Uri-Path: "dots"
Uri-Path: "tm-setup"
Uri-Path: "cuid=dz6pHjaADkaFTbjr0JGBpw"
Uri-Path: "tsid=126"
Content-Format: "application/dots+cbor"
{
"ietf-dots-telemetry:telemetry-setup": {
"telemetry": [
{
"baseline": [
{
"id": 1,
"target-prefix": [
"2001:db8:6401::1/128",
"2001:db8:6401::2/128"
],
"total-traffic-normal": [
{
"unit": "megabit-ps",
"peak-g": "60"
}
]
}
]
}
]
}
}
Figure 19: PUT to Convey the DOTS Traffic Baseline
The DOTS client may share protocol-specific baseline information
(e.g., TCP and UDP) as shown in Figure 19.
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Header: PUT (Code=0.03)
Uri-Path: ".well-known"
Uri-Path: "dots"
Uri-Path: "tm-setup"
Uri-Path: "cuid=dz6pHjaADkaFTbjr0JGBpw"
Uri-Path: "tsid=128"
Content-Format: "application/dots+cbor"
{
"ietf-dots-telemetry:telemetry-setup": {
"telemetry": [
{
"baseline": [
{
"id": 1,
"target-prefix": [
"2001:db8:6401::1/128",
"2001:db8:6401::2/128"
],
"total-traffic-normal-per-protocol": [
{
"unit": "megabit-ps",
"protocol": 6,
"peak-g": "50"
},
{
"unit": "megabit-ps",
"protocol": 17,
"peak-g": "10"
}
]
}
]
}
]
}
}
Figure 20: PUT to Convey the DOTS Traffic Baseline (2)
The traffic baseline information should be updated to reflect
legitimate overloads (e.g., flash crowds) to prevent unnecessary
mitigation.
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6.3.2. Retrieve Installed Normal Traffic Baseline
A GET request with 'tsid' Uri-Path parameter is used to retrieve a
specific installed DOTS client domain baseline traffic information.
The same procedure as defined in (Section 6.1.3) is followed.
To retrieve all baseline information bound to a DOTS client, the DOTS
client proceeds as specified in Section 6.1.1.
6.3.3. Delete Installed Normal Traffic Baseline
A DELETE request is used to delete the installed DOTS client domain
normal traffic baseline. The same procedure as defined in
(Section 6.1.4) is followed.
6.4. Reset Installed Telemetry Setup
Upon bootstrapping (or reboot or any other event that may alter the
DOTS client setup), a DOTS client MAY send a DELETE request to set
the telemetry parameters to default values. Such a request does not
include any 'tsid'. An example of such request is depicted in
Figure 21.
Header: DELETE (Code=0.04)
Uri-Path: ".well-known"
Uri-Path: "dots"
Uri-Path: "tm-setup"
Uri-Path: "cuid=dz6pHjaADkaFTbjr0JGBpw"
Figure 21: Delete Telemetry Configuration
6.5. Conflict with Other DOTS Clients of the Same Domain
A DOTS server may detect conflicts between requests to convey pipe
and baseline information received from DOTS clients of the same DOTS
client domain. 'conflict-information' is used to report the conflict
to the DOTS client following similar conflict handling discussed in
Section 4.4.1 of [I-D.ietf-dots-signal-channel]. The conflict cause
can be set to one of these values:
1: Overlapping targets (already defined in
[I-D.ietf-dots-signal-channel]).
TBA: Overlapping pipe scope (see Section 11).
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7. DOTS Pre-or-Ongoing Mitigation Telemetry
There are two broad types of DDoS attacks, one is bandwidth consuming
attack, the other is target resource consuming attack. This section
outlines the set of DOTS telemetry attributes (Section 7.1) that
covers both the types of attacks. The objective of these attributes
is to allow for the complete knowledge of attacks and the various
particulars that can best characterize attacks.
The "ietf-dots-telemetry" YANG module (Section 9) augments the "ietf-
dots-signal" with a new message type called "telemetry". The tree
structure of the "telemetry" message type is shown Figure 24.
The pre-or-ongoing-mitigation telemetry attributes are indicated by
the path-suffix '/tm'. The '/tm' is appended to the path-prefix to
form the URI used with a CoAP request to signal the DOTS telemetry.
Pre-or-ongoing-mitigation telemetry attributes specified in
Section 7.1 can be signaled between DOTS agents.
Pre-or-ongoing-mitigation telemetry attributes may be sent by a DOTS
client or a DOTS server.
DOTS agents SHOULD bind pre-or-ongoing-mitigation telemetry data with
mitigation requests relying upon the target clause. In particular, a
telemetry PUT request sent after a mitigation request may include a
reference to that mitigation request ('mid-list') as shown in
Figure 22. An example illustrating requests correlation by means of
'target-prefix' is shown in Figure 23.
When generating telemetry data to send to a peer, the DOTS agent must
auto-scale so that appropriate unit(s) are used.
+-----------+ +-----------+
|DOTS client| |DOTS server|
+-----------+ +-----------+
| |
|=========Mitigation Request (mid)=====================>|
| |
|================ Telemetry (mid-list{mid})============>|
| |
Figure 22: Example of Request Correlation using 'mid'
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+-----------+ +-----------+
|DOTS client| |DOTS server|
+-----------+ +-----------+
| |
|<=============== Telemetry (target-prefix)=============|
| |
|=========Mitigation Request (target-prefix)===========>|
| |
Figure 23: Example of Request Correlation using Target Prefix
DOTS agents MUST NOT send pre-or-ongoing-mitigation telemetry
messages to the same peer more frequently than once every 'telemetry-
notify-interval' (Section 6.1). If a telemetry notification is sent
using a block-like transfer mechanism (e.g.,
[I-D.bosh-core-new-block]), this rate limit policy MUST NOT consider
these individual blocks as separate notifications, but as a single
notification.
DOTS pre-or-ongoing-mitigation telemetry request and response
messages MUST be marked as Non-Confirmable messages.
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augment /ietf-signal:dots-signal/ietf-signal:message-type:
+--:(telemetry-setup) {dots-telemetry}?
| +--rw telemetry* [cuid tsid]
| ...
+--:(telemetry) {dots-telemetry}?
+--rw pre-or-ongoing-mitigation* [cuid tmid]
+--rw cuid string
+--rw cdid? string
+--rw tmid uint32
+--rw target
| ...
+--rw total-traffic* [unit]
| ...
+--rw total-traffic-protocol* [unit protocol]
| ...
+--rw total-traffic-port* [unit port]
| ...
+--rw total-attack-traffic* [unit]
| ...
+--rw total-attack-traffic-protocol* [unit protocol]
| ...
+--rw total-attack-traffic-port* [unit port]
| ...
+--rw total-attack-connection
| ...
+--rw total-attack-connection-port
| ...
+--rw attack-detail* [attack-id]
...
Figure 24: Telemetry Message Type Tree Structure
7.1. Pre-or-Ongoing-Mitigation DOTS Telemetry Attributes
The description and motivation behind each attribute are presented in
Section 3. DOTS telemetry attributes are optionally signaled and
therefore MUST NOT be treated as mandatory fields in the DOTS signal
channel protocol.
7.1.1. Target
A target resource (Figure 25) is identified using the attributes
'target-prefix', 'target-port-range', 'target-protocol', 'target-
fqdn', 'target-uri', 'alias-name', or a pointer to a mitigation
request ('mid-list').
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+--:(telemetry) {dots-telemetry}?
+--rw pre-or-ongoing-mitigation* [cuid tmid]
+--rw cuid string
+--rw cdid? string
+--rw tmid uint32
+--rw target
| +--rw target-prefix* inet:ip-prefix
| +--rw target-port-range* [lower-port]
| | +--rw lower-port inet:port-number
| | +--rw upper-port? inet:port-number
| +--rw target-protocol* uint8
| +--rw target-fqdn* inet:domain-name
| +--rw target-uri* inet:uri
| +--rw alias-name* string
| +--rw mid-list* uint32
+--rw total-traffic* [unit]
| ...
+--rw total-traffic-protocol* [unit protocol]
| ...
+--rw total-traffic-port* [unit port]
| ...
+--rw total-attack-traffic* [unit]
| ...
+--rw total-attack-traffic-protocol* [unit protocol]
| ...
+--rw total-attack-traffic-port* [unit port]
| ...
+--rw total-attack-connection
| ...
+--rw total-attack-connection-port
| ...
+--rw attack-detail* [attack-id]
...
Figure 25: Target Tree Structure
At least one of the attributes 'target-prefix', 'target-fqdn',
'target-uri', 'alias-name', or 'mid-list' MUST be present in the
target definition.
If the target is subjected to bandwidth consuming attack, the
attributes representing the percentile values of the 'attack-id'
attack traffic are included.
If the target is subjected to resource consuming DDoS attacks, the
same attributes defined for Section 7.1.4 are applicable for
representing the attack.
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This is an optional sub-attribute.
7.1.2. Total Traffic
The 'total-traffic' attribute (Figure 26) conveys the percentile
values of total traffic observed during a DDoS attack. More granular
total traffic can be conveyed in 'total-traffic-protocol' and 'total-
traffic-port'.
The 'total-traffic-protocol' represents the total traffic for a
target and is transport-protocol specific.
The 'total-traffic-port' represents the total traffic for a target
per port number.
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+--:(telemetry) {dots-telemetry}?
+--rw pre-or-ongoing-mitigation* [cuid tmid]
+--rw cuid string
+--rw cdid? string
+--rw tmid uint32
+--rw target
| ...
+--rw total-traffic* [unit]
| +--rw unit unit
| +--rw low-percentile-g? yang:gauge64
| +--rw mid-percentile-g? yang:gauge64
| +--rw high-percentile-g? yang:gauge64
| +--rw peak-g? yang:gauge64
+--rw total-traffic-protocol* [unit protocol]
| +--rw protocol uint8
| +--rw unit unit
| +--rw low-percentile-g? yang:gauge64
| +--rw mid-percentile-g? yang:gauge64
| +--rw high-percentile-g? yang:gauge64
| +--rw peak-g? yang:gauge64
+--rw total-traffic-port* [unit port]
| +--rw port inet:port-number
| +--rw unit unit
| +--rw low-percentile-g? yang:gauge64
| +--rw mid-percentile-g? yang:gauge64
| +--rw high-percentile-g? yang:gauge64
| +--rw peak-g? yang:gauge64
+--rw total-attack-traffic* [unit]
| ...
+--rw total-attack-traffic-protocol* [unit protocol]
| ...
+--rw total-attack-traffic-port* [unit port]
| ...
+--rw total-attack-connection
| ...
+--rw total-attack-connection-port
| ...
+--rw attack-detail* [attack-id]
...
Figure 26: Total Traffic Tree Structure
7.1.3. Total Attack Traffic
The 'total-attack-traffic' attribute (Figure 27) conveys the total
attack traffic identified by the DOTS client domain's DMS (or DDoS
Detector). More granular total traffic can be conveyed in 'total-
attack-traffic-protocol' and 'total-attack-traffic-port'.
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The 'total-attack-traffic-protocol' represents the total attack
traffic for a target and is transport-protocol specific.
The 'total-attack-traffic-port' represents the total attack traffic
for a target per port number.
+--:(telemetry) {dots-telemetry}?
+--rw pre-or-ongoing-mitigation* [cuid tmid]
+--rw cuid string
+--rw cdid? string
+--rw tmid uint32
+--rw target
| ...
+--rw total-traffic* [unit]
| ...
+--rw total-traffic-protocol* [unit protocol]
| ...
+--rw total-traffic-port* [unit port]
| ...
+--rw total-attack-traffic* [unit]
| +--rw unit unit
| +--rw low-percentile-g? yang:gauge64
| +--rw mid-percentile-g? yang:gauge64
| +--rw high-percentile-g? yang:gauge64
| +--rw peak-g? yang:gauge64
+--rw total-attack-traffic-protocol* [unit protocol]
| +--rw protocol uint8
| +--rw unit unit
| +--rw low-percentile-g? yang:gauge64
| +--rw mid-percentile-g? yang:gauge64
| +--rw high-percentile-g? yang:gauge64
| +--rw peak-g? yang:gauge64
+--rw total-attack-traffic-port* [unit port]
| +--rw port inet:port-number
| +--rw unit unit
| +--rw low-percentile-g? yang:gauge64
| +--rw mid-percentile-g? yang:gauge64
| +--rw high-percentile-g? yang:gauge64
| +--rw peak-g? yang:gauge64
+--rw total-attack-connection
| ...
+--rw total-attack-connection-port
| ...
+--rw attack-detail* [attack-id]
...
Figure 27: Total Attack Traffic Tree Structure
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7.1.4. Total Attack Connections
If the target is subjected to resource consuming DDoS attack, the
'total-attack-connection' attribute is used to convey the percentile
values of total attack connections. The following optional sub-
attributes for the target per transport-protocol are included to
represent the attack characteristics:
o The number of simultaneous attack connections to the target.
o The number of simultaneous embryonic connections to the target.
o The number of attack connections per second to the target.
o The number of attack requests to the target.
The total attack connections per port number is represented using
'total-attack-connection-port' attribute.
+--:(telemetry) {dots-telemetry}?
+--rw pre-or-ongoing-mitigation* [cuid tmid]
+--rw cuid string
+--rw cdid? string
+--rw tmid uint32
+--rw target
| ...
+--rw total-attack-connection
| +--rw low-percentile-l* [protocol]
| | +--rw protocol uint8
| | +--rw connection? yang:gauge64
| | +--rw embryonic? yang:gauge64
| | +--rw connection-ps? yang:gauge64
| | +--rw request-ps? yang:gauge64
| | +--rw partial-request-ps? yang:gauge64
| +--rw mid-percentile-l* [protocol]
| | +--rw protocol uint8
| | +--rw connection? yang:gauge64
| | +--rw embryonic? yang:gauge64
| | +--rw connection-ps? yang:gauge64
| | +--rw request-ps? yang:gauge64
| | +--rw partial-request-ps? yang:gauge64
| +--rw high-percentile-l* [protocol]
| | +--rw protocol uint8
| | +--rw connection? yang:gauge64
| | +--rw embryonic? yang:gauge64
| | +--rw connection-ps? yang:gauge64
| | +--rw request-ps? yang:gauge64
| | +--rw partial-request-ps? yang:gauge64
| +--rw peak-l* [protocol]
| +--rw protocol uint8
| +--rw connection? yang:gauge64
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| +--rw embryonic? yang:gauge64
| +--rw connection-ps? yang:gauge64
| +--rw request-ps? yang:gauge64
| +--rw partial-request-ps? yang:gauge64
+--rw total-attack-connection-port
| +--rw low-percentile-l* [protocol port]
| | +--rw port inet:port-number
| | +--rw protocol uint8
| | +--rw connection? yang:gauge64
| | +--rw embryonic? yang:gauge64
| | +--rw connection-ps? yang:gauge64
| | +--rw request-ps? yang:gauge64
| | +--rw partial-request-ps? yang:gauge64
| +--rw mid-percentile-l* [protocol port]
| | +--rw port inet:port-number
| | +--rw protocol uint8
| | +--rw connection? yang:gauge64
| | +--rw embryonic? yang:gauge64
| | +--rw connection-ps? yang:gauge64
| | +--rw request-ps? yang:gauge64
| | +--rw partial-request-ps? yang:gauge64
| +--rw high-percentile-l* [protocol port]
| | +--rw port inet:port-number
| | +--rw protocol uint8
| | +--rw connection? yang:gauge64
| | +--rw embryonic? yang:gauge64
| | +--rw connection-ps? yang:gauge64
| | +--rw request-ps? yang:gauge64
| | +--rw partial-request-ps? yang:gauge64
| +--rw peak-l* [protocol port]
| +--rw port inet:port-number
| +--rw protocol uint8
| +--rw connection? yang:gauge64
| +--rw embryonic? yang:gauge64
| +--rw connection-ps? yang:gauge64
| +--rw request-ps? yang:gauge64
| +--rw partial-request-ps? yang:gauge64
+--rw attack-detail* [attack-id]
...
Figure 28: Total Attack Connections Tree Structure
7.1.5. Attack Details
This attribute (Figure 29) is used to signal a set of details
characterizing an attack. The following sub-attributes describing
the on-going attack can be signal as attack details.
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id: Vendor ID is a security vendor's Enterprise Number as registered
with IANA [Enterprise-Numbers]. It is a four-byte integer value.
attack-id: Unique identifier assigned for the attack.
attack-name: Textual representation of attack description. Natural
Language Processing techniques (e.g., word embedding) can possibly
be used to map the attack description to an attack type. Textual
representation of attack solves two problems: (a) avoids the need
to create mapping tables manually between vendors and (2) avoids
the need to standardize attack types which keep evolving.
attack-severity: Attack severity. These values are supported:
emergency (1), critical (2), and alert (3).
start-time: The time the attack started. The attack's start time is
expressed in seconds relative to 1970-01-01T00:00Z in UTC time
(Section 2.4.1 of [RFC7049]). The CBOR encoding is modified so
that the leading tag 1 (epoch-based date/time) MUST be omitted.
end-time: The time the attack-id attack ended. The attack end time
is expressed in seconds relative to 1970-01-01T00:00Z in UTC time
(Section 2.4.1 of [RFC7049]). The CBOR encoding is modified so
that the leading tag 1 (epoch-based date/time) MUST be omitted.
source-count: A count of sources involved in the attack targeting
the victim.
top-talkers: A list of top talkers among attack sources. The top
talkers are represented using the 'source-prefix'.
'spoofed-status' is used whether a top talker is a spoofed IP
address (e.g., reflection attacks) or not.
If the target is subjected to bandwidth consuming attack, the
attack traffic from each of the top talkers is included ('total-
attack-traffic', Section 7.1.3).
If the target is subjected to resource consuming DDoS attacks, the
same attributes defined for Section 7.1.4 are applicable for
representing the attack per talker.
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+--:(telemetry) {dots-telemetry}?
+--rw pre-or-ongoing-mitigation* [cuid tmid]
+--rw cuid string
+--rw cdid? string
+--rw tmid uint32
+--rw target
| ...
+--rw attack-detail* [attack-id]
+--rw id? uint32
+--rw attack-id string
+--rw attack-name? string
+--rw attack-severity? attack-severity
+--rw start-time? uint64
+--rw end-time? uint64
+--rw top-talker
+--rw talker* [source-prefix]
+--rw spoofed-status? boolean
+--rw source-prefix inet:ip-prefix
+--rw source-port-range* [lower-port]
| +--rw lower-port inet:port-number
| +--rw upper-port? inet:port-number
+--rw source-icmp-type-range* [lower-type]
| +--rw lower-type uint8
| +--rw upper-type? uint8
+--rw total-attack-traffic* [unit]
| +--rw unit unit
| +--rw low-percentile-g? yang:gauge64
| +--rw mid-percentile-g? yang:gauge64
| +--rw high-percentile-g? yang:gauge64
| +--rw peak-g? yang:gauge64
+--rw total-attack-connection
+--rw low-percentile-l* [protocol]
| ...
+--rw mid-percentile-l* [protocol]
| ...
+--rw high-percentile-l* [protocol]
| ...
+--rw peak-l* [protocol]
...
Figure 29: Attack Detail Tree Structure
7.2. From DOTS Clients to DOTS Servers
DOTS clients uses PUT request to signal pre-or-ongoing-mitigation
telemetry to DOTS servers. An example of such request is shown in
Figure 30.
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Header: PUT (Code=0.03)
Uri-Path: ".well-known"
Uri-Path: "dots"
Uri-Path: "tm"
Uri-Path: "cuid=dz6pHjaADkaFTbjr0JGBpw"
Uri-Path: "tmid=123"
Content-Format: "application/dots+cbor"
{
"ietf-dots-telemetry:telemetry": {
"pre-or-ongoing-mitigation": [
{
"target": {
"target-prefix": [
"2001:db8::1/128"
]
},
"total-attack-traffic-protocol": [
{
"protocol": 17,
"unit": "megabit-ps",
"mid-percentile-g": "900"
}
],
"attack-detail": [
{
"attack-id": "an-id",
"start-time": "1957811234",
"attack-severity": "emergency"
}
]
}
]
}
}
Figure 30: PUT to Send Pre-or-Ongoing-Mitigation Telemetry
'cuid' is a mandatory Uri-Path parameter for PUT requests.
The following additional Uri-Path parameter is defined:
tmid: Telemetry Identifier is an identifier for the DOTS pre-or-
ongoing-mitigation telemetry data represented as an integer.
This identifier MUST be generated by DOTS clients. 'tmid' values
MUST increase monotonically (when a new PUT is generated by a
DOTS client to convey pre-or-ongoing-mitigation telemetry).
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This is a mandatory attribute.
'cuid' and 'tmid' MUST NOT appear in the PUT request message body.
At least 'target' attribute and another pre-or-ongoing-mitigation
attributes (Section 7.1) MUST be present in the PUT request. If only
the 'target' attribute is present, this request is handled as per
Section 7.3.
The relative order of two PUT requests carrying DOTS pre-or-ongoing-
mitigation telemetry from a DOTS client is determined by comparing
their respective 'tmid' values. If such two requests have
overlapping 'target', the PUT request with higher numeric 'tmid'
value will override the request with a lower numeric 'tmid' value.
The overlapped lower numeric 'tmid' MUST be automatically deleted and
no longer be available.
The DOTS server indicates the result of processing a PUT request
using CoAP response codes. The response code 2.04 (Changed) is
returned if the DOTS server has accepted the pre-or-ongoing-
mitigation telemetry. The error response code 5.03 (Service
Unavailable) is returned if the DOTS server has erred. 5.03 uses Max-
Age option to indicate the number of seconds after which to retry.
How long a DOTS server maintains a 'tmid' as active or logs the
enclosed telemetry information is implementation-specific. Note that
if a 'tmid' is still active, then logging details are updated by the
DOTS server as a function of the updates received from the peer DOTS
client.
A DOTS client that lost the state of its active 'tmids' or has to set
'tmid' back to zero (e.g., crash or restart) MUST send a GET request
to the DOTS server to retrieve the list of active 'tmid'. The DOTS
client may then delete 'tmids' that should not be active anymore
(Figure 31). Sending a DELETE with no 'tmid' indicates that all
'tmids' must be deactivated (Figure 32).
Header: DELETE (Code=0.04)
Uri-Path: ".well-known"
Uri-Path: "dots"
Uri-Path: "tm"
Uri-Path: "cuid=dz6pHjaADkaFTbjr0JGBpw"
Uri-Path: "tmid=123"
Figure 31: Delete a Pre-or-Ongoing-Mitigation Telemetry
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Header: DELETE (Code=0.04)
Uri-Path: ".well-known"
Uri-Path: "dots"
Uri-Path: "tm"
Uri-Path: "cuid=dz6pHjaADkaFTbjr0JGBpw"
Figure 32: Delete All Pre-or-Ongoing-Mitigation Telemetry
7.3. From DOTS Servers to DOTS Clients
The pre-or-ongoing-mitigation (attack details, in particular) can
also be signaled from DOTS servers to DOTS clients. For example, the
DOTS server co-located with a DDoS detector collects monitoring
information from the target network, identifies DDoS attack using
statistical analysis or deep learning techniques, and signals the
attack details to the DOTS client.
The DOTS client can use the attack details to decide whether to
trigger a DOTS mitigation request or not. Furthermore, the security
operation personnel at the DOTS client domain can use the attack
details to determine the protection strategy and select the
appropriate DOTS server for mitigating the attack.
In order to receive pre-or-ongoing-mitigation telemetry notifications
from a DOTS server, a DOTS client MUST send a PUT (followed by a GET)
with the target filter. An example of such PUT request is shown in
Figure 33. In order to avoid maintaining a long list of such
requests, it is RECOMMENDED that DOTS clients include all targets in
the same request. DOTS servers may be instructed to restrict the
number of pre-or-ongoing-mitigation requests per DOTS client domain.
This request MUST be maintained active by the DOTS server until a
delete request is received from the same DOTS client to clear this
pre-or-ongoing-mitigation telemetry.
The relative order of two PUT requests carrying DOTS pre-or-ongoing-
mitigation telemetry from a DOTS client is determined by comparing
their respective 'tmid' values. If such two requests have
overlapping 'target', the PUT request with higher numeric 'tmid'
value will override the request with a lower numeric 'tmid' value.
The overlapped lower numeric 'tmid' MUST be automatically deleted and
no longer be available.
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Header: PUT (Code=0.03)
Uri-Path: ".well-known"
Uri-Path: "dots"
Uri-Path: "tm"
Uri-Path: "cuid=dz6pHjaADkaFTbjr0JGBpw"
Uri-Path: "tmid=123"
Content-Format: "application/dots+cbor"
{
"ietf-dots-telemetry:telemetry": {
"pre-or-ongoing-mitigation": [
{
"target": {
"target-prefix": [
"2001:db8::/32"
]
}
}
]
}
}
Figure 33: PUT to Request Pre-or-Ongoing-Mitigation Telemetry
DOTS clients of the same domain can request to receive pre-or-
ongoing-mitigation telemetry bound to the same target.
The DOTS client conveys the Observe Option set to '0' in the GET
request to receive asynchronous notifications carrying pre-or-
ongoing-mitigation telemetry data from the DOTS server. The GET
request specifies a 'tmid' (Figure 34) or not (Figure 35).
Header: GET (Code=0.01)
Uri-Path: ".well-known"
Uri-Path: "dots"
Uri-Path: "tm"
Uri-Path: "cuid=dz6pHjaADkaFTbjr0JGBpw"
Uri-Path: "tmid=123"
Observe: 0
Figure 34: GET to Subscribe to Telemetry Asynchronous Notifications
for a Specific 'tmid'
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Header: GET (Code=0.01)
Uri-Path: ".well-known"
Uri-Path: "dots"
Uri-Path: "tm"
Uri-Path: "cuid=dz6pHjaADkaFTbjr0JGBpw"
Observe: 0
Figure 35: GET to Subscribe to Telemetry Asynchronous Notifications
for All 'tmids'
The DOTS client can filter out the asynchronous notifications from
the DOTS server by indicating one or more Uri-Query options in its
GET request. A Uri-Query option can include the following
parameters: target-prefix, lower-port, upper-port, target-protocol,
target-fqdn, target-uri, alias-name. An example of request to
subscribe to asynchronous UDP telemetry notifications is shown in
Figure 36. This filter will be applied for all 'tmids'.
Header: GET (Code=0.01)
Uri-Path: ".well-known"
Uri-Path: "dots"
Uri-Path: "tm"
Uri-Path: "cuid=dz6pHjaADkaFTbjr0JGBpw"
Uri-Query: "target-protocol=17"
Observe: 0
Figure 36: GET Request to Receive Telemetry Asynchronous
Notifications Filtered using Uri-Query
The DOTS server will send asynchronous notifications to the DOTS
client when an attack event is detected following similar
considerations as in Section 4.4.2.1 of
[I-D.ietf-dots-signal-channel]. An example of a pre-or-ongoing-
mitigation telemetry notification is shown in Figure 37.
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{
"ietf-dots-telemetry:telemetry": {
"pre-or-ongoing-mitigation": [
{
"tmid": 123,
"target": {
"target-prefix": [
"2001:db8::1/128"
]
},
"target-protocol": [
17
],
"total-attack-traffic": [
{
"unit": "megabit-ps",
"mid-percentile-g": "900"
}
],
"attack-detail": [
{
"attack-id": "an-id",
"start-time": "1957818434",
"attack-severity": "emergency"
}
]
}
]
}
}
Figure 37: Message Body of a Pre-or-Ongoing-Mitigation Telemetry
Notification from the DOTS Server
A DOTS server sends the aggregate data for a target using 'total-
attack-traffic' attribute. The aggregate assumes that Uri-Query
filters are applied on the target. The DOTS server MAY include more
granular data when needed (that is, 'total-attack-traffic-protocol'
and 'total-attack-traffic-port'). If a port filter (or protocol
filter) is included in a request, 'total-attack-traffic-protocol' (or
'total-attack-traffic-port') conveys the data with the port (or
protocol) filter applied.
A DOTS server may aggregate pre-or-ongoing-mitigation data (e.g.,
'top-talkers') for all targets of a domain, or when justified, send
specific information (e.g., 'top-talkers') per individual targets.
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The DOTS client may log pre-or-ongoing-mitigation telemetry data with
an alert sent to an administrator or a network controller. The DOTS
client may send a mitigation request if the attack cannot be handled
locally.
A DOTS client that is not interested to receive pre-or-ongoing-
mitigation telemetry data for a target MUST send a delete request
similar to the one depicted in Figure 31.
8. DOTS Telemetry Mitigation Status Update
8.1. DOTS Clients to Servers Mitigation Efficacy DOTS Telemetry
Attributes
The mitigation efficacy telemetry attributes can be signaled from
DOTS clients to DOTS servers as part of the periodic mitigation
efficacy updates to the server (Section 5.3.4 of
[I-D.ietf-dots-signal-channel]).
Total Attack Traffic: The overall attack traffic as observed from
the DOTS client perspective during an active mitigation. See
Figure 27.
Attack Details: The overall attack details as observed from the
DOTS client perspective during an active mitigation. See
Section 7.1.5.
The "ietf-dots-telemetry" YANG module augments the "mitigation-scope"
type message defined in "ietf-dots-signal" so that these attributes
can be signalled by a DOTS client in a mitigation efficacy update
(Figure 38).
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augment /ietf-signal:dots-signal/ietf-signal:message-type
/ietf-signal:mitigation-scope/ietf-signal:scope:
+--rw total-attack-traffic* [unit] {dots-telemetry}?
| ...
+--rw attack-detail* [attack-id] {dots-telemetry}?
+--rw id? uint32
+--rw attack-id string
+--rw attack-name? string
+--rw attack-severity? attack-severity
+--rw start-time? uint64
+--rw end-time? uint64
+--rw source-count
| ...
+--rw top-talker
...
Figure 38: Telemetry Efficacy Update Tree Structure
In order to signal telemetry data in a mitigation efficacy update, it
is RECOMMENDED that the DOTS client has already established a DOTS
telemetry setup session with the server in 'idle' time.
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Header: PUT (Code=0.03)
Uri-Path: ".well-known"
Uri-Path: "dots"
Uri-Path: "mitigate"
Uri-Path: "cuid=dz6pHjaADkaFTbjr0JGBpw"
Uri-Path: "mid=123"
If-Match:
Content-Format: "application/dots+cbor"
{
"ietf-dots-signal-channel:mitigation-scope": {
"scope": [
{
"alias-name": [
"https1",
"https2"
],
"attack-status": "under-attack",
"ietf-dots-telemetry:total-attack-traffic": [
{
"ietf-dots-telemetry:unit": "megabit-ps",
"ietf-dots-telemetry:mid-percentile-g": "900"
}
]
}
]
}
}
Figure 39: An Example of Mitigation Efficacy Update with Telemetry
Attributes
8.2. DOTS Servers to Clients Mitigation Status DOTS Telemetry
Attributes
The mitigation status telemetry attributes can be signaled from the
DOTS server to the DOTS client as part of the periodic mitigation
status update (Section 5.3.3 of [I-D.ietf-dots-signal-channel]). In
particular, DOTS clients can receive asynchronous notifications of
the attack details from DOTS servers using the Observe option defined
in [RFC7641].
In order to make use of this feature, DOTS clients MUST establish a
telemetry setup session with the DOTS server in 'idle' time and MUST
set the 'server-originated-telemetry' attribute to 'true'.
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DOTS servers MUST NOT include telemetry attributes in mitigation
status updates sent to DOTS clients for which 'server-originated-
telemetry' attribute is set to 'false'.
As defined in [RFC8612], the actual mitigation activities can include
several countermeasure mechanisms. The DOTS server signals the
current operational status to each relevant countermeasure. A list
of attacks detected by each countermeasure MAY also be included. The
same attributes defined for Section 7.1.5 are applicable for
describing the attacks detected and mitigated.
The "ietf-dots-telemetry" YANG module (Section 9) augments the
"mitigation-scope" type message defined in "ietf-dots-signal" with
telemetry data as depicted in following tree structure:
augment /ietf-signal:dots-signal/ietf-signal:message-type
/ietf-signal:mitigation-scope/ietf-signal:scope:
+--ro total-traffic* [unit] {dots-telemetry}?
| +--ro unit unit
| +--ro low-percentile-g? yang:gauge64
| +--ro mid-percentile-g? yang:gauge64
| +--ro high-percentile-g? yang:gauge64
| +--ro peak-g? yang:gauge64
+--rw total-attack-traffic* [unit] {dots-telemetry}?
| +--rw unit unit
| +--rw low-percentile-g? yang:gauge64
| +--rw mid-percentile-g? yang:gauge64
| +--rw high-percentile-g? yang:gauge64
| +--rw peak-g? yang:gauge64
+--ro total-attack-connection {dots-telemetry}?
| +--ro low-percentile-c
| | +--ro connection? yang:gauge64
| | +--ro embryonic? yang:gauge64
| | +--ro connection-ps? yang:gauge64
| | +--ro request-ps? yang:gauge64
| | +--ro partial-request-ps? yang:gauge64
| +--ro mid-percentile-c
| | ...
| +--ro high-percentile-c
| | ...
| +--ro peak-c
| ...
+--rw attack-detail* [attack-id] {dots-telemetry}?
+--rw id? uint32
+--rw attack-id string
+--rw attack-name? string
+--rw attack-severity? attack-severity
+--rw start-time? uint64
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+--rw end-time? uint64
+--rw source-count
| +--rw low-percentile-g? yang:gauge64
| +--rw mid-percentile-g? yang:gauge64
| +--rw high-percentile-g? yang:gauge64
| +--rw peak-g? yang:gauge64
+--rw top-talker
+--rw talker* [source-prefix]
+--rw spoofed-status? boolean
+--rw source-prefix inet:ip-prefix
+--rw source-port-range* [lower-port]
| +--rw lower-port inet:port-number
| +--rw upper-port? inet:port-number
+--rw source-icmp-type-range* [lower-type]
| +--rw lower-type uint8
| +--rw upper-type? uint8
+--rw total-attack-traffic* [unit]
| +--rw unit unit
| +--rw low-percentile-g? yang:gauge64
| +--rw mid-percentile-g? yang:gauge64
| +--rw high-percentile-g? yang:gauge64
| +--rw peak-g? yang:gauge64
+--rw total-attack-connection
+--rw low-percentile-c
| +--rw connection? yang:gauge64
| +--rw embryonic? yang:gauge64
| +--rw connection-ps? yang:gauge64
| +--rw request-ps? yang:gauge64
| +--rw partial-request-ps? yang:gauge64
+--rw mid-percentile-c
| ...
+--rw high-percentile-c
| ...
+--rw peak-c
...
Figure 40 shows an example of an asynchronous notification of attack
mitigation status from the DOTS server. This notification signals
both the mid-percentile value of processed attack traffic and the
peak percentile value of unique sources involved in the attack.
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{
"ietf-dots-signal-channel:mitigation-scope": {
"scope": [
{
"mid": 12332,
"mitigation-start": "1507818434",
"alias-name": [
"https1",
"https2"
],
"lifetime": 1600,
"status": "attack-successfully-mitigated",
"bytes-dropped": "134334555",
"bps-dropped": "43344",
"pkts-dropped": "333334444",
"pps-dropped": "432432",
"ietf-dots-telemetry:total-attack-traffic": [
{
"ietf-dots-telemetry:unit": "megabit-ps",
"ietf-dots-telemetry:mid-percentile-g": "900"
}
],
"ietf-dots-telemetry::attack-detail": [
{
"ietf-dots-telemetry:attack-id": "another-id",
"ietf-dots-telemetry:source-count": {
"ietf-dots-telemetry:peak-g": "10000"
}
}
]
}
]
}
}
Figure 40: Response Body of a Mitigation Status With Telemetry
Attributes
DOTS clients can filter out the asynchronous notifications from the
DOTS server by indicating one or more Uri-Query options in its GET
request. A Uri-Query option can include the following parameters:
target-prefix, lower-port, upper-port, target-protocol, target-fqdn,
target-uri, alias-name. An example of request to subscribe to
asynchronous notifications bound to the "http1" alias is shown in
Figure 41.
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Header: GET (Code=0.01)
Uri-Path: ".well-known"
Uri-Path: "dots"
Uri-Path: "mitigate"
Uri-Path: "cuid=dz6pHjaADkaFTbjr0JGBpw"
Uri-Path: "mid=12332"
Uri-Query: "target-alias=https1"
Observe: 0
Figure 41: GET Request to Receive Asynchronous Notifications Filtered
using Uri-Query
If the target query does not match the target of the enclosed 'mid'
as maintained by the DOTS server, the latter MUST respond with a 4.04
(Not Found) error response code. The DOTS server MUST NOT add a new
observe entry if this query overlaps with an existing one.
9. YANG Module
This module uses types defined in [RFC6991] and [RFC8345].
<CODE BEGINS> file "ietf-dots-telemetry@2020-04-15.yang"
module ietf-dots-telemetry {
yang-version 1.1;
namespace "urn:ietf:params:xml:ns:yang:ietf-dots-telemetry";
prefix dots-telemetry;
import ietf-dots-signal-channel {
prefix ietf-signal;
reference
"RFC SSSS: Distributed Denial-of-Service Open Threat
Signaling (DOTS) Signal Channel Specification";
}
import ietf-dots-data-channel {
prefix ietf-data;
reference
"RFC DDDD: Distributed Denial-of-Service Open Threat
Signaling (DOTS) Data Channel Specification";
}
import ietf-yang-types {
prefix yang;
reference
"Section 3 of RFC 6991";
}
import ietf-inet-types {
prefix inet;
reference
"Section 4 of RFC 6991";
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}
import ietf-network-topology {
prefix nt;
reference
"Section 6.2 of RFC 8345: A YANG Data Model for Network
Topologies";
}
organization
"IETF DDoS Open Threat Signaling (DOTS) Working Group";
contact
"WG Web: <https://datatracker.ietf.org/wg/dots/>
WG List: <mailto:dots@ietf.org>
Author: Mohamed Boucadair
<mailto:mohamed.boucadair@orange.com>
Author: Konda, Tirumaleswar Reddy
<mailto:TirumaleswarReddy_Konda@McAfee.com>";
description
"This module contains YANG definitions for the signaling
of DOTS telemetry exchanged between a DOTS client and
a DOTS server, by means of the DOTS signal channel.
Copyright (c) 2020 IETF Trust and the persons identified as
authors of the code. All rights reserved.
Redistribution and use in source and binary forms, with or
without modification, is permitted pursuant to, and subject
to the license terms contained in, the Simplified BSD License
set forth in Section 4.c of the IETF Trust's Legal Provisions
Relating to IETF Documents
(http://trustee.ietf.org/license-info).
This version of this YANG module is part of RFC XXXX; see
the RFC itself for full legal notices.";
revision 2020-04-15 {
description
"Initial revision.";
reference
"RFC XXXX: Distributed Denial-of-Service Open Threat
Signaling (DOTS) Telemetry";
}
feature dots-telemetry {
description
"This feature means that the DOTS signal channel is able
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to convey DOTS telemetry data between DOTS clients and
servers.";
}
typedef attack-severity {
type enumeration {
enum emergency {
value 1;
description
"The attack is severe: emergency.";
}
enum critical {
value 2;
description
"The attack is critical.";
}
enum alert {
value 3;
description
"This is an alert.";
}
}
description
"Enumeration for attack severity.";
}
typedef unit-type {
type enumeration {
enum packet-ps {
value 1;
description
"Packets per second (pps).";
}
enum bit-ps {
value 2;
description
"Bits per Second (bit/s).";
}
enum byte-ps {
value 3;
description
"Bytes per second (Byte/s).";
}
}
description
"Enumeration to indicate which unit type is used.";
}
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typedef unit {
type enumeration {
enum packet-ps {
value 1;
description
"Packets per second (pps).";
}
enum bit-ps {
value 2;
description
"Bits per Second (bps).";
}
enum byte-ps {
value 3;
description
"Bytes per second (Bps).";
}
enum kilopacket-ps {
value 4;
description
"Kilo packets per second (kpps).";
}
enum kilobit-ps {
value 5;
description
"Kilobits per second (kbps).";
}
enum kilobyte-ps {
value 6;
description
"Kilobytes per second (kBps).";
}
enum megapacket-ps {
value 7;
description
"Mega packets per second (Mpps).";
}
enum megabit-ps {
value 8;
description
"Megabits per second (Mbps).";
}
enum megabyte-ps {
value 9;
description
"Megabytes per second (MBps).";
}
enum gigapacket-ps {
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value 10;
description
"Giga packets per second (Gpps).";
}
enum gigabit-ps {
value 11;
description
"Gigabits per second (Gbps).";
}
enum gigabyte-ps {
value 12;
description
"Gigabytes per second (GBps).";
}
enum terapacket-ps {
value 13;
description
"Tera packets per second (Tpps).";
}
enum terabit-ps {
value 14;
description
"Terabits per second (Tbps).";
}
enum terabyte-ps {
value 15;
description
"Terabytes per second (TBps).";
}
}
description
"Enumeration to indicate which unit is used.";
}
typedef interval {
type enumeration {
enum hour {
value 1;
description
"Hour.";
}
enum day {
value 2;
description
"Day.";
}
enum week {
value 3;
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description
"Week.";
}
enum month {
value 4;
description
"Month.";
}
}
description
"Enumeration to indicate the overall measurement period.";
}
typedef sample {
type enumeration {
enum second {
value 1;
description
"Second.";
}
enum 5-seconds {
value 2;
description
"5 seconds.";
}
enum 30-seconds {
value 3;
description
"30 seconds.";
}
enum minute {
value 4;
description
"One minute.";
}
enum 5-minutes {
value 5;
description
"5 minutes.";
}
enum 10-minutes {
value 6;
description
"10 minutes.";
}
enum 30-minutes {
value 7;
description
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"30 minutes.";
}
enum hour {
value 8;
description
"One hour.";
}
}
description
"Enumeration to indicate the measurement perdiod.";
}
typedef percentile {
type decimal64 {
fraction-digits 2;
}
description
"The nth percentile of a set of data is the
value at which n percent of the data is below it.";
}
grouping percentile-config {
description
"Configuration of low, mid, and high percentile values.";
leaf measurement-interval {
type interval;
description
"Defines the period on which percentiles are computed.";
}
leaf measurement-sample {
type sample;
description
"Defines the time distribution for measuring
values that are used to compute percentiles.";
}
leaf low-percentile {
type percentile;
default "10.00";
description
"Low percentile. If set to '0', this means low-percentiles
are disabled.";
}
leaf mid-percentile {
type percentile;
must '. >= ../low-percentile' {
error-message
"The mid-percentile must be greater than
or equal to the low-percentile.";
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}
default "50.00";
description
"Mid percentile. If set to the same value as low-percentiles,
this means mid-percentiles are disabled.";
}
leaf high-percentile {
type percentile;
must '. >= ../mid-percentile' {
error-message
"The high-percentile must be greater than
or equal to the mid-percentile.";
}
default "90.00";
description
"High percentile. If set to the same value as mid-percentiles,
this means high-percentiles are disabled.";
}
}
grouping percentile {
description
"Generic grouping for percentile.";
leaf low-percentile-g {
type yang:gauge64;
description
"Low traffic.";
}
leaf mid-percentile-g {
type yang:gauge64;
description
"Mid percentile.";
}
leaf high-percentile-g {
type yang:gauge64;
description
"High percentile.";
}
leaf peak-g {
type yang:gauge64;
description
"Peak";
}
}
grouping unit-config {
description
"Generic grouping for unit configuration.";
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list unit-config {
key "unit";
description
"Controls which units are allowed when sharing telemetry
data.";
leaf unit {
type unit-type;
description
"Can be packet-ps, bit-ps, or byte-ps.";
}
leaf unit-status {
type boolean;
mandatory true;
description
"Enable/disable the use of the measurement unit.";
}
}
}
grouping traffic-unit {
description
"Grouping of traffic as a function of measurement unit.";
leaf unit {
type unit;
description
"The traffic can be measured using unit types: packets
per second (PPS), Bits per Second (BPS), and/or
bytes per second. DOTS agents auto-scale to the appropriate
units (e.g., megabit-ps, kilobit-ps).";
}
uses percentile;
}
grouping traffic-unit-protocol {
description
"Grouping of traffic of a given transport protocol as
a function of measurement unit.";
leaf protocol {
type uint8;
description
"The transport protocol.
Values are taken from the IANA Protocol Numbers registry:
<https://www.iana.org/assignments/protocol-numbers/>.
For example, this field contains 6 for TCP,
17 for UDP, 33 for DCCP, or 132 for SCTP.";
}
uses traffic-unit;
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}
grouping traffic-unit-port {
description
"Grouping of traffic bound to port number as
a function of measurement unit.";
leaf port {
type inet:port-number;
description
"Port number.";
}
uses traffic-unit;
}
grouping total-connection-capacity {
description
"Total Connections Capacity. If the target is subjected
to resource consuming DDoS attack, these attributes are
useful to detect resource consuming DDoS attacks";
leaf connection {
type uint64;
description
"The maximum number of simultaneous connections that
are allowed to the target server. The threshold is
transport-protocol specific because the target server
could support multiple protocols.";
}
leaf connection-client {
type uint64;
description
"The maximum number of simultaneous connections that
are allowed to the target server per client.";
}
leaf embryonic {
type uint64;
description
"The maximum number of simultaneous embryonic connections
that are allowed to the target server. The term 'embryonic
connection' refers to a connection whose connection handshake
is not finished and embryonic connection is only possible in
connection-oriented transport protocols like TCP or SCTP.";
}
leaf embryonic-client {
type uint64;
description
"The maximum number of simultaneous embryonic connections
that are allowed to the target server per client.";
}
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leaf connection-ps {
type uint64;
description
"The maximum number of connections allowed per second
to the target server.";
}
leaf connection-client-ps {
type uint64;
description
"The maximum number of connections allowed per second
to the target server per client.";
}
leaf request-ps {
type uint64;
description
"The maximum number of requests allowed per second
to the target server.";
}
leaf request-client-ps {
type uint64;
description
"The maximum number of requests allowed per second
to the target server per client.";
}
leaf partial-request-ps {
type uint64;
description
"The maximum number of partial requests allowed per
second to the target server.";
}
leaf partial-request-client-ps {
type uint64;
description
"The maximum number of partial requests allowed per
second to the target server per client.";
}
}
grouping total-connection-capacity-protocol {
description
"Total Connections Capacity per protocol. If the target is subjected
to resource consuming DDoS attack, these attributes are
useful to detect resource consuming DDoS attacks";
leaf protocol {
type uint8;
description
"The transport protocol.
Values are taken from the IANA Protocol Numbers registry:
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<https://www.iana.org/assignments/protocol-numbers/>.";
}
uses total-connection-capacity;
}
grouping connection {
description
"A set of attributes which represent the attack
characteristics";
leaf connection {
type yang:gauge64;
description
"The number of simultaneous attack connections to
the target server.";
}
leaf embryonic {
type yang:gauge64;
description
"The number of simultaneous embryonic connections to
the target server.";
}
leaf connection-ps {
type yang:gauge64;
description
"The number of attack connections per second to
the target server.";
}
leaf request-ps {
type yang:gauge64;
description
"The number of attack requests per second to
the target server.";
}
leaf partial-request-ps {
type yang:gauge64;
description
"The number of attack partial requests to
the target server.";
}
}
grouping connection-percentile {
description
"Total attack connections.";
container low-percentile-c {
description
"Low percentile of attack connections.";
uses connection;
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}
container mid-percentile-c {
description
"Mid percentile of attack connections.";
uses connection;
}
container high-percentile-c {
description
"High percentile of attack connections.";
uses connection;
}
container peak-c {
description
"Peak attack connections.";
uses connection;
}
}
grouping connection-protocol {
description
"Total attack connections.";
leaf protocol {
type uint8;
description
"The transport protocol.
Values are taken from the IANA Protocol Numbers registry:
<https://www.iana.org/assignments/protocol-numbers/>.";
}
uses connection;
}
grouping connection-port {
description
"Total attack connections per port number.";
leaf port {
type inet:port-number;
description
"Port number.";
}
uses connection-protocol;
}
grouping connection-protocol-percentile {
description
"Total attack connections.";
list low-percentile-l {
key "protocol";
description
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"Low percentile of attack connections.";
uses connection-protocol;
}
list mid-percentile-l {
key "protocol";
description
"Mid percentile of attack connections.";
uses connection-protocol;
}
list high-percentile-l {
key "protocol";
description
"High percentile of attack connections.";
uses connection-protocol;
}
list peak-l {
key "protocol";
description
"Peak attack connections.";
uses connection-protocol;
}
}
grouping connection-protocol-port-percentile {
description
"Total attack connections.";
list low-percentile-l {
key "protocol port";
description
"Low percentile of attack connections.";
uses connection-port;
}
list mid-percentile-l {
key "protocol port";
description
"Mid percentile of attack connections.";
uses connection-port;
}
list high-percentile-l {
key "protocol port";
description
"High percentile of attack connections.";
uses connection-port;
}
list peak-l {
key "protocol port";
description
"Peak attack connections.";
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uses connection-port;
}
}
grouping attack-detail {
description
"Various information and details that describe the on-going
attacks that needs to be mitigated by the DOTS server.
The attack details need to cover well-known and common attacks
(such as a SYN Flood) along with new emerging or vendor-specific
attacks.";
leaf id {
type uint32;
description
"Vendor ID is a security vendor's Enterprise Number.";
}
leaf attack-id {
type string;
description
"Unique identifier assigned by the vendor for the attack.";
}
leaf attack-name {
type string;
description
"Textual representation of attack description. Natural Language
Processing techniques (e.g., word embedding) can possibly be used
to map the attack description to an attack type.";
}
leaf attack-severity {
type attack-severity;
description
"Severity level of an attack. How this level is determined
is implementation-specific.";
}
leaf start-time {
type uint64;
description
"The time the attack started. Start time is represented in seconds
relative to 1970-01-01T00:00:00Z in UTC time.";
}
leaf end-time {
type uint64;
description
"The time the attack ended. End time is represented in seconds
relative to 1970-01-01T00:00:00Z in UTC time.";
}
container source-count {
description
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"Indicates the count of unique sources involved
in the attack.";
uses percentile;
}
}
grouping top-talker-aggregate {
description
"Top attack sources.";
list talker {
key "source-prefix";
description
"IPv4 or IPv6 prefix identifying the attacker(s).";
leaf spoofed-status {
type boolean;
description
"Indicates whether this address is spoofed.";
}
leaf source-prefix {
type inet:ip-prefix;
description
"IPv4 or IPv6 prefix identifying the attacker(s).";
}
list source-port-range {
key "lower-port";
description
"Port range. When only lower-port is
present, it represents a single port number.";
leaf lower-port {
type inet:port-number;
mandatory true;
description
"Lower port number of the port range.";
}
leaf upper-port {
type inet:port-number;
must '. >= ../lower-port' {
error-message
"The upper port number must be greater than
or equal to lower port number.";
}
description
"Upper port number of the port range.";
}
}
list source-icmp-type-range {
key "lower-type";
description
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"ICMP type range. When only lower-type is
present, it represents a single ICMP type.";
leaf lower-type {
type uint8;
mandatory true;
description
"Lower ICMP type of the ICMP type range.";
}
leaf upper-type {
type uint8;
must '. >= ../lower-type' {
error-message
"The upper ICMP type must be greater than
or equal to lower ICMP type.";
}
description
"Upper type of the ICMP type range.";
}
}
list total-attack-traffic {
key "unit";
description
"Total attack traffic issued from this source.";
uses traffic-unit;
}
container total-attack-connection {
description
"Total attack connections issued from this source.";
uses connection-percentile;
}
}
}
grouping top-talker {
description
"Top attack sources.";
list talker {
key "source-prefix";
description
"IPv4 or IPv6 prefix identifying the attacker(s).";
leaf spoofed-status {
type boolean;
description
"Indicates whether this address is spoofed.";
}
leaf source-prefix {
type inet:ip-prefix;
description
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"IPv4 or IPv6 prefix identifying the attacker(s).";
}
list source-port-range {
key "lower-port";
description
"Port range. When only lower-port is
present, it represents a single port number.";
leaf lower-port {
type inet:port-number;
mandatory true;
description
"Lower port number of the port range.";
}
leaf upper-port {
type inet:port-number;
must '. >= ../lower-port' {
error-message
"The upper port number must be greater than
or equal to lower port number.";
}
description
"Upper port number of the port range.";
}
}
list source-icmp-type-range {
key "lower-type";
description
"ICMP type range. When only lower-type is
present, it represents a single ICMP type.";
leaf lower-type {
type uint8;
mandatory true;
description
"Lower ICMP type of the ICMP type range.";
}
leaf upper-type {
type uint8;
must '. >= ../lower-type' {
error-message
"The upper ICMP type must be greater than
or equal to lower ICMP type.";
}
description
"Upper type of the ICMP type range.";
}
}
list total-attack-traffic {
key "unit";
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description
"Total attack traffic issued from this source.";
uses traffic-unit;
}
container total-attack-connection {
description
"Total attack connections issued from this source.";
uses connection-protocol-percentile;
}
}
}
grouping baseline {
description
"Grouping for the telemetry baseline.";
uses ietf-data:target;
leaf-list alias-name {
type string;
description
"An alias name that points to a resource.";
}
list total-traffic-normal {
key "unit";
description
"Total traffic normal baselines.";
uses traffic-unit;
}
list total-traffic-normal-per-protocol {
key "unit protocol";
description
"Total traffic normal baselines per protocol.";
uses traffic-unit-protocol;
}
list total-traffic-normal-per-port {
key "unit port";
description
"Total traffic normal baselines per port number.";
uses traffic-unit-port;
}
list total-connection-capacity {
key "protocol";
description
"Total connection capacity.";
uses total-connection-capacity-protocol;
}
list total-connection-capacity-per-port {
key "protocol port";
description
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"Total connection capacity per port number.";
leaf port {
type inet:port-number;
description
"The target port number.";
}
uses total-connection-capacity-protocol;
}
}
grouping pre-or-ongoing-mitigation {
description
"Grouping for the telemetry data.";
list total-traffic {
key "unit";
description
"Total traffic.";
uses traffic-unit;
}
list total-traffic-protocol {
key "unit protocol";
description
"Total traffic per protocol.";
uses traffic-unit-protocol;
}
list total-traffic-port {
key "unit port";
description
"Total traffic per port.";
uses traffic-unit-port;
}
list total-attack-traffic {
key "unit";
description
"Total attack traffic.";
uses traffic-unit-protocol;
}
list total-attack-traffic-protocol {
key "unit protocol";
description
"Total attack traffic per protocol.";
uses traffic-unit-protocol;
}
list total-attack-traffic-port {
key "unit port";
description
"Total attack traffic per port.";
uses traffic-unit-port;
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}
container total-attack-connection {
description
"Total attack connections.";
uses connection-protocol-percentile;
}
container total-attack-connection-port {
description
"Total attack connections.";
uses connection-protocol-port-percentile;
}
list attack-detail {
key "attack-id";
description
"Provides a set of attack details.";
uses attack-detail;
container top-talker {
description
"Lists the top attack sources.";
uses top-talker;
}
}
}
augment "/ietf-signal:dots-signal/ietf-signal:message-type/"
+ "ietf-signal:mitigation-scope/ietf-signal:scope" {
if-feature "dots-telemetry";
description
"Extends mitigation scope with telemetry update data.";
list total-traffic {
key "unit";
config false;
description
"Total traffic.";
uses traffic-unit;
}
list total-attack-traffic {
key "unit";
description
"Total attack traffic.";
uses traffic-unit;
}
container total-attack-connection {
config false;
description
"Total attack connections.";
uses connection-percentile;
}
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list attack-detail {
key "attack-id";
description
"Atatck details";
uses attack-detail;
container top-talker {
description
"Top attack sources.";
uses top-talker-aggregate;
}
}
}
augment "/ietf-signal:dots-signal/ietf-signal:message-type" {
if-feature "dots-telemetry";
description
"Add a new choice to enclose telemetry data in DOTS
signal channel.";
case telemetry-setup {
description
"Indicates the message is about telemetry.";
container max-config-values {
config false;
description
"Maximum acceptable configuration values.";
uses percentile-config;
leaf server-originated-telemetry {
type boolean;
description
"Indicates whether the DOTS server can be instructed
to send pre-or-ongoing-mitigation telemetry. If set to FALSE
or the attribute is not present, this is an indication
that the server does not support this capability.";
}
leaf telemetry-notify-interval {
type uint32 {
range "1 .. 3600";
}
must '. >= ../../min-config-values/telemetry-notify-interval' {
error-message
"The value must be greater than or equal
to the telemetry-notify-interval in the min-config-values";
}
units "seconds";
description
"Minimum number of seconds between successive
telemetry notifications.";
}
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}
container min-config-values {
config false;
description
"Minimum acceptable configuration values.";
uses percentile-config;
leaf telemetry-notify-interval {
type uint32 {
range "1 .. 3600";
}
units "seconds";
description
"Minimum number of seconds between successive
telemetry notifications.";
}
}
container supported-units {
config false;
description
"Supported units and default activation status.";
uses unit-config;
}
list telemetry {
key "cuid tsid";
description
"The telemetry data per DOTS client.";
leaf cuid {
type string;
description
"A unique identifier that is
generated by a DOTS client to prevent
request collisions. It is expected that the
cuid will remain consistent throughout the
lifetime of the DOTS client.";
}
leaf cdid {
type string;
description
"The cdid should be included by a server-domain
DOTS gateway to propagate the client domain
identification information from the
gateway's client-facing-side to the gateway's
server-facing-side, and from the gateway's
server-facing-side to the DOTS server.
It may be used by the final DOTS server
for policy enforcement purposes.";
}
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leaf tsid {
type uint32;
description
"An identifier for the DOTS telemetry setup
data.";
}
choice setup-type {
description
"Can be a mitigation configuration, a pipe capacity,
or baseline message.";
case telemetry-config {
description
"Uses to set low, mid, and high percentile values.";
container current-config {
description
"Current configuration values.";
uses percentile-config;
uses unit-config;
leaf server-originated-telemetry {
type boolean;
description
"Used by a DOTS client to enable/disable whether it
accepts pre-or-ongoing-mitigation telemetry from
the DOTS server.";
}
leaf telemetry-notify-interval {
type uint32 {
range "1 .. 3600";
}
units "seconds";
description
"Minimum number of seconds between successive
telemetry notifications.";
}
}
}
case pipe {
description
"Total pipe capacity of a DOTS client domain";
list total-pipe-capacity {
key "link-id unit";
description
"Total pipe capacity of a DOTS client domain.";
leaf link-id {
type nt:link-id;
description
"Identifier of an interconnection link.";
}
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leaf capacity {
type uint64;
mandatory true;
description
"Pipe capacity.";
}
leaf unit {
type unit;
description
"The traffic can be measured using unit types: packets
per second (PPS), Bits per Second (BPS), and/or
bytes per second. DOTS agents auto-scale to the
appropriate units (e.g., megabit-ps, kilobit-ps).";
}
}
}
case baseline {
description
"Traffic baseline information";
list baseline {
key "id";
description
"Traffic baseline information";
leaf id {
type uint32;
must '. >= 1';
description
"A baseline entry identifier.";
}
uses baseline;
}
}
}
}
}
case telemetry {
description
"Indicates the message is about telemetry.";
list pre-or-ongoing-mitigation {
key "cuid tmid";
description
"Pre-or-ongoing-mitigation telemetry per DOTS client.";
leaf cuid {
type string;
description
"A unique identifier that is
generated by a DOTS client to prevent
request collisions. It is expected that the
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cuid will remain consistent throughout the
lifetime of the DOTS client.";
}
leaf cdid {
type string;
description
"The cdid should be included by a server-domain
DOTS gateway to propagate the client domain
identification information from the
gateway's client-facing-side to the gateway's
server-facing-side, and from the gateway's
server-facing-side to the DOTS server.
It may be used by the final DOTS server
for policy enforcement purposes.";
}
leaf tmid {
type uint32;
description
"An identifier to uniquely demux telemetry data sent
using the same message.";
}
container target {
description
"Indicates the target.";
uses ietf-data:target;
leaf-list alias-name {
type string;
description
"An alias name that points to a resource.";
}
leaf-list mid-list {
type uint32;
description
"Reference a list of associated mitigation requests.";
}
}
uses pre-or-ongoing-mitigation;
}
}
}
}
<CODE ENDS>
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10. YANG/JSON Mapping Parameters to CBOR
All DOTS telemetry parameters in the payload of the DOTS signal
channel MUST be mapped to CBOR types as shown in the following table:
o Implementers may use the values in: https://github.com/boucadair/
draft-dots-telemetry/blob/master/mapping-table.txt
+----------------------+-------------+------+---------------+--------+
| Parameter Name | YANG | CBOR | CBOR Major | JSON |
| | Type | Key | Type & | Type |
| | | | Information | |
+----------------------+-------------+------+---------------+--------+
| tsid | uint32 |TBA1 | 0 unsigned | Number |
| telemetry | container |TBA2 | 5 map | Object |
| low-percentile | decimal64 |TBA3 | 6 tag 4 | |
| | | | [-2, integer]| String |
| mid-percentile | decimal64 |TBA4 | 6 tag 4 | |
| | | | [-2, integer]| String |
| high-percentile | decimal64 |TBA5 | 6 tag 4 | |
| | | | [-2, integer]| String |
| unit-config | list |TBA6 | 4 array | Array |
| unit | enumeration |TBA7 | 0 unsigned | String |
| unit-status | boolean |TBA8 | 7 bits 20 | False |
| | | | 7 bits 21 | True |
| total-pipe-capability| list |TBA9 | 4 array | Array |
| link-id | string |TBA10 | 3 text string | String |
| pre-or-ongoing- | list |TBA11 | 4 array | Array |
| mitigation | | | | |
| total-traffic-normal | list |TBA12 | 4 array | Array |
| low-percentile-g | yang:gauge64|TBA13 | 0 unsigned | String |
| mid-percentile-g | yang:gauge64|TBA14 | 0 unsigned | String |
| high-percentile-g | yang:gauge64|TBA15 | 0 unsigned | String |
| peak-g | yang:gauge64|TBA16 | 0 unsigned | String |
| total-attack-traffic | list |TBA17 | 4 array | Array |
| total-traffic | list |TBA18 | 4 array | Array |
| total-connection- | | | | |
| capacity | list |TBA19 | 4 array | Array |
| connection | uint64 |TBA20 | 0 unsigned | String |
| connection-client | uint64 |TBA21 | 0 unsigned | String |
| embryonic | uint64 |TBA22 | 0 unsigned | String |
| embryonic-client | uint64 |TBA23 | 0 unsigned | String |
| connection-ps | uint64 |TBA24 | 0 unsigned | String |
| connection-client-ps | uint64 |TBA25 | 0 unsigned | String |
| request-ps | uint64 |TBA26 | 0 unsigned | String |
| request-client-ps | uint64 |TBA27 | 0 unsigned | String |
| partial-request-ps | uint64 |TBA28 | 0 unsigned | String |
| partial-request- | | | | |
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| client-ps | uint64 |TBA29 | 0 unsigned | String |
| total-attack- | | | | |
| connection | container |TBA30 | 5 map | Object |
| low-percentile-l | list |TBA31 | 4 array | Array |
| mid-percentile-l | list |TBA32 | 4 array | Array |
| high-percentile-l | list |TBA33 | 4 array | Array |
| peak-l | list |TBA34 | 4 array | Array |
| attack-detail | list |TBA35 | 4 array | Array |
| id | uint32 |TBA36 | 0 unsigned | Number |
| attack-id | string |TBA37 | 3 text string | String |
| attack-name | string |TBA38 | 3 text string | String |
| attack-severity | enumeration |TBA39 | 0 unsigned | String |
| start-time | uint64 |TBA40 | 0 unsigned | String |
| end-time | uint64 |TBA41 | 0 unsigned | String |
| source-count | container |TBA42 | 5 map | Object |
| top-talker | container |TBA43 | 5 map | Object |
| spoofed-status | boolean |TBA44 | 7 bits 20 | False |
| | | | 7 bits 21 | True |
| low-percentile-c | container |TBA45 | 5 map | Object |
| mid-percentile-c | container |TBA46 | 5 map | Object |
| high-percentile-c | container |TBA47 | 5 map | Object |
| peak-c | container |TBA48 | 5 map | Object |
| baseline | container |TBA49 | 5 map | Object |
| current-config | container |TBA50 | 5 map | Object |
| max-config-values | container |TBA51 | 5 map | Object |
| min-config-values | container |TBA52 | 5 map | Object |
| supported-units | container |TBA53 | 5 map | Object |
| server-originated- | boolean |TBA54 | 7 bits 20 | False |
| telemetry | | | 7 bits 21 | True |
| telemetry-notify- | uint32 |TBA55 | 0 unsigned | Number |
| interval | | | | |
| tmid | uint32 |TBA56 | 0 unsigned | Number |
| measurement-interval | enumeration |TBA57 | 0 unsigned | String |
| measurement-sample | enumeration |TBA58 | 0 unsigned | String |
| talker | list |TBA59 | 4 array | Array |
| source-prefix | inet: |TBA60 | 3 text string | String |
| | ip-prefix | | | |
| mid-list | leaf-list |TBA61 | 4 array | Array |
| | uint32 | | 0 unsigned | Number |
| source-port-range | list |TBA62 | 4 array | Array |
| source-icmp-type- | list |TBA63 | 4 array | Array |
| range | | | | |
| lower-type | uint8 |TBA64 | 0 unsigned | Number |
| upper-type | uint8 |TBA65 | 0 unsigned | Number |
| target | container |TBA66 | 5 map | Object |
| capacity | uint64 |TBA67 | 0 unsigned | String |
| protocol | uint8 |TBA68 | 0 unsigned | Number |
| total-traffic- | | | | |
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| normal-per-protocol | list |TBA69 | 4 array | Array |
| total-traffic- | | | | |
| normal-per-port | list |TBA70 | 4 array | Array |
| total-connection- | | | | |
| capacity-per-port | list |TBA71 | 4 array | Array |
| total-traffic- | | | | |
| -protocol | list |TBA72 | 4 array | Array |
| total-traffic- port | list |TBA73 | 4 array | Array |
| total-attack- | | | | |
| traffic-protocol | list |TBA74 | 4 array | Array |
| total-attack- | | | | |
| traffic-port | list |TBA75 | 4 array | Array |
| total-attack- | | | | |
| connection-port | list |TBA76 | 4 array | Array |
| port | inet: | | | |
| | port-number|TBA77 | 0 unsigned | Number |
| ietf-dots-telemetry: | | | | |
| telemetry-setup | container |TBA80 | 5 map | Object |
| ietf-dots-telemetry: | | | | |
| total-traffic | list |TBA81 | 4 array | Array |
| ietf-dots-telemetry: | | | | |
| unit | enumeration |TBA82 | 0 unsigned | String |
| ietf-dots-telemetry: | | | | |
| low-percentile-g | yang:gauge64|TBA83 | 0 unsigned | String |
| ietf-dots-telemetry: | | | | |
| mid-percentile-g | yang:gauge64|TBA84 | 0 unsigned | String |
| ietf-dots-telemetry: | | | | |
| high-percentile-g | yang:gauge64|TBA85 | 0 unsigned | String |
| ietf-dots-telemetry: | | | | |
| peak-g | yang:gauge64|TBA86 | 0 unsigned | String |
| ietf-dots-telemetry: | | | | |
| total-attack-traffic | list |TBA87 | 4 array | Array |
| ietf-dots-telemetry: | | | | |
| total-attack- | | | | |
| connection | container |TBA88 | 5 map | Object |
| ietf-dots-telemetry: | | | | |
| low-percentile-c | container |TBA89 | 5 map | Object |
| ietf-dots-telemetry: | | | | |
| mid-percentile-c | container |TBA90 | 5 map | Object |
| ietf-dots-telemetry: | | | | |
| high-percentile-c | container |TBA91 | 5 map | Object |
| ietf-dots-telemetry: | | | | |
| peak-c | container |TBA92 | 5 map | Object |
| ietf-dots-telemetry: | | | | |
| connection | uint64 |TBA93 | 0 unsigned | String |
| ietf-dots-telemetry: | | | | |
| embryonic | uint64 |TBA94 | 0 unsigned | String |
| ietf-dots-telemetry: | | | | |
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| connection-ps | uint64 |TBA95 | 0 unsigned | String |
| ietf-dots-telemetry: | | | | |
| request-ps | uint64 |TBA96 | 0 unsigned | String |
| ietf-dots-telemetry: | | | | |
| partial-request-ps | uint64 |TBA97 | 0 unsigned | String |
| ietf-dots-telemetry: | | | | |
| attack-detail | list |TBA98 | 4 array | Array |
| ietf-dots-telemetry: | | | | |
| id | uint32 |TBA99 | 0 unsigned | Number |
| ietf-dots-telemetry: | | | | |
| attack-id | string |TBA100| 3 text string | String |
| ietf-dots-telemetry: | | | | |
| attack-name | string |TBA101| 3 text string | String |
| ietf-dots-telemetry: | | | | |
| attack-severity | enumeration |TBA102| 0 unsigned | String |
| ietf-dots-telemetry: | | | | |
| start-time | uint64 |TBA103| 0 unsigned | String |
| ietf-dots-telemetry: | | | | |
| end-time | uint64 |TBA104| 0 unsigned | String |
| ietf-dots-telemetry: | | | | |
| source-count | container |TBA105| 5 map | Object |
| ietf-dots-telemetry: | | | | |
| top-talker | container |TBA106| 5 map | Object |
| ietf-dots-telemetry: | | | | |
| spoofed-status | boolean |TBA107| 7 bits 20 | False |
| | | | 7 bits 21 | True |
| ietf-dots-telemetry: | | | | |
| talker | list |TBA108| 4 array | Array |
| ietf-dots-telemetry: | inet: |TBA109| 3 text string | String |
| source-prefix | ip-prefix | | | |
| ietf-dots-telemetry: | | | | |
| source-port-range | list |TBA110| 4 array | Array |
| ietf-dots-telemetry: | | | | |
| lower-port | inet: | | | |
| | port-number|TBA111| 0 unsigned | Number |
| ietf-dots-telemetry: | | | | |
| upper-port | inet: | | | |
| | port-number|TBA112| 0 unsigned | Number |
| ietf-dots-telemetry: | | | | |
| source-icmp-type- | list |TBA113| 4 array | Array |
| range | | | | |
| ietf-dots-telemetry: | | | | |
| lower-type | uint8 |TBA114| 0 unsigned | Number |
| ietf-dots-telemetry: | | | | |
| upper-type | uint8 |TBA115| 0 unsigned | Number |
| ietf-dots-telemetry: | | | | |
| telemetry | container |TBA116| 5 map | Object |
+----------------------+-------------+------+---------------+--------+
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11. IANA Considerationsr
11.1. DOTS Signal Channel CBOR Key Values
This specification registers the DOTS telemetry attributes in the
IANA "DOTS Signal Channel CBOR Key Values" registry available at
https://www.iana.org/assignments/dots/dots.xhtml#dots-signal-channel-
cbor-key-values.
The DOTS telemetry attributes defined in this specification are
comprehension-optional parameters.
o Note to the RFC Editor: (1) CBOR keys are assigned from the
32768-49151 range. (2) Please assign the following suggested
values.
+----------------------+-------+-------+------------+---------------+
| Parameter Name | CBOR | CBOR | Change | Specification |
| | Key | Major | Controller | Document(s) |
| | Value | Type | | |
+----------------------+-------+-------+------------+---------------+
| tsid | TBA1 | 0 | IESG | [RFCXXXX] |
| telemetry | TBA2 | 5 | IESG | [RFCXXXX] |
| low-percentile | TBA3 | 6tag4 | IESG | [RFCXXXX] |
| mid-percentile | TBA4 | 6tag4 | IESG | [RFCXXXX] |
| high-percentile | TBA5 | 6tag4 | IESG | [RFCXXXX] |
| unit-config | TBA6 | 4 | IESG | [RFCXXXX] |
| unit | TBA7 | 0 | IESG | [RFCXXXX] |
| unit-status | TBA8 | 7 | IESG | [RFCXXXX] |
| total-pipe-capability| TBA9 | 4 | IESG | [RFCXXXX] |
| link-id | TBA10 | 3 | IESG | [RFCXXXX] |
| pre-or-ongoing- | TBA11 | 4 | IESG | [RFCXXXX] |
| mitigation | | | | |
| total-traffic-normal | TBA12 | 4 | IESG | [RFCXXXX] |
| low-percentile-g | TBA13 | 0 | IESG | [RFCXXXX] |
| mid-percentile-g | TBA14 | 0 | IESG | [RFCXXXX] |
| high-percentile-g | TBA15 | 0 | IESG | [RFCXXXX] |
| peak-g | TBA16 | 0 | IESG | [RFCXXXX] |
| total-attack-traffic | TBA17 | 4 | IESG | [RFCXXXX] |
| total-traffic | TBA18 | 4 | IESG | [RFCXXXX] |
| total-connection- | TBA19 | 4 | IESG | [RFCXXXX] |
| capacity | | | | |
| connection | TBA20 | 0 | IESG | [RFCXXXX] |
| connection-client | TBA21 | 0 | IESG | [RFCXXXX] |
| embryonic | TBA22 | 0 | IESG | [RFCXXXX] |
| embryonic-client | TBA23 | 0 | IESG | [RFCXXXX] |
| connection-ps | TBA24 | 0 | IESG | [RFCXXXX] |
| connection-client-ps | TBA25 | 0 | IESG | [RFCXXXX] |
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| request-ps | TBA26 | 0 | IESG | [RFCXXXX] |
| request-client-ps | TBA27 | 0 | IESG | [RFCXXXX] |
| partial-request-ps | TBA28 | 0 | IESG | [RFCXXXX] |
| partial-request- | TBA29 | 0 | IESG | [RFCXXXX] |
| client-ps | | | | |
| total-attack- | TBA30 | 5 | IESG | [RFCXXXX] |
| connection | | | | |
| low-percentile-l | TBA31 | 4 | IESG | [RFCXXXX] |
| mid-percentile-l | TBA32 | 4 | IESG | [RFCXXXX] |
| high-percentile-l | TBA33 | 4 | IESG | [RFCXXXX] |
| peak-l | TBA34 | 4 | IESG | [RFCXXXX] |
| attack-detail | TBA35 | 4 | IESG | [RFCXXXX] |
| id | TBA36 | 0 | IESG | [RFCXXXX] |
| attack-id | TBA37 | 3 | IESG | [RFCXXXX] |
| attack-name | TBA38 | 3 | IESG | [RFCXXXX] |
| attack-severity | TBA39 | 0 | IESG | [RFCXXXX] |
| start-time | TBA40 | 0 | IESG | [RFCXXXX] |
| end-time | TBA41 | 0 | IESG | [RFCXXXX] |
| source-count | TBA42 | 5 | IESG | [RFCXXXX] |
| top-talker | TBA43 | 5 | IESG | [RFCXXXX] |
| spoofed-status | TBA44 | 7 | IESG | [RFCXXXX] |
| low-percentile-c | TBA45 | 5 | IESG | [RFCXXXX] |
| mid-percentile-c | TBA46 | 5 | IESG | [RFCXXXX] |
| high-percentile-c | TBA47 | 5 | IESG | [RFCXXXX] |
| peak-c | TBA48 | 5 | IESG | [RFCXXXX] |
| ietf-dots-signal-cha | TBA49 | 5 | IESG | [RFCXXXX] |
| current-config | TBA50 | 5 | IESG | [RFCXXXX] |
| max-config-value | TBA51 | 5 | IESG | [RFCXXXX] |
| min-config-values | TBA52 | 5 | IESG | [RFCXXXX] |
| supported-units | TBA55 | 5 | IESG | [RFCXXXX] |
| server-originated- | TBA54 | 7 | IESG | [RFCXXXX] |
| telemetry | | | | |
| telemetry-notify- | TBA55 | 0 | IESG | [RFCXXXX] |
| interval | | | | |
| tmid | TBA56 | 0 | IESG | [RFCXXXX] |
| measurement-interval | TBA57 | 0 | IESG | [RFCXXXX] |
| measurement-sample | TBA58 | 0 | IESG | [RFCXXXX] |
| talker | TBA59 | 0 | IESG | [RFCXXXX] |
| source-prefix | TBA60 | 0 | IESG | [RFCXXXX] |
| mid-list | TBA61 | 4 | IESG | [RFCXXXX] |
| source-port-range | TBA62 | 4 | IESG | [RFCXXXX] |
| source-icmp-type- | TBA63 | 4 | IESG | [RFCXXXX] |
| range | | | | |
| lower-type | TBA64 | 0 | IESG | [RFCXXXX] |
| upper-type | TBA65 | 0 | IESG | [RFCXXXX] |
| target | TBA66 | 5 | IESG | [RFCXXXX] |
| capacity | TBA67 | 0 | IESG | [RFCXXXX] |
| protocol | TBA68 | 0 | IESG | [RFCXXXX] |
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| total-traffic- | TBA69 | 4 | IESG | [RFCXXXX] |
| normal-per-protocol | | | | |
| total-traffic- | TBA70 | 4 | IESG | [RFCXXXX] |
| normal-per-port | | | | |
| total-connection- | TBA71 | 4 | IESG | [RFCXXXX] |
| capacity-per-port | | | | |
| total-traffic- | TBA72 | 4 | IESG | [RFCXXXX] |
| -protocol | | | | |
| total-traffic-port | TBA73 | 4 | IESG | [RFCXXXX] |
| total-attack- | TBA74 | 4 | IESG | [RFCXXXX] |
| traffic-protocol | | | | |
| total-attack- | TBA75 | 4 | IESG | [RFCXXXX] |
| traffic-port | | | | |
| total-attack- | TBA76 | 4 | IESG | [RFCXXXX] |
| connection-port | | | | |
| port | TBA77 | 0 | IESG | [RFCXXXX] |
| ietf-dots-telemetry: | TBA80 | 5 | IESG | [RFCXXXX] |
| telemetry-setup | | | | |
| ietf-dots-telemetry: | TBA81 | 0 | IESG | [RFCXXXX] |
| total-traffic | | | | |
| ietf-dots-telemetry: | TBA82 | 0 | IESG | [RFCXXXX] |
| unit | | | | |
| ietf-dots-telemetry: | TBA83 | 0 | IESG | [RFCXXXX] |
| low-percentile-g | | | | |
| ietf-dots-telemetry: | TBA84 | 0 | IESG | [RFCXXXX] |
| mid-percentile-g | | | | |
| ietf-dots-telemetry: | TBA85 | 0 | IESG | [RFCXXXX] |
| high-percentile-g | | | | |
| ietf-dots-telemetry: | TBA86 | 0 | IESG | [RFCXXXX] |
| peak-g | | | | |
| ietf-dots-telemetry: | TBA87 | 0 | IESG | [RFCXXXX] |
| total-attack-traffic | | | | |
| ietf-dots-telemetry: | TBA88 | 0 | IESG | [RFCXXXX] |
| total-attack- | | | | |
| connection | | | | |
| ietf-dots-telemetry: | TBA89 | 0 | IESG | [RFCXXXX] |
| low-percentile-c | | | | |
| ietf-dots-telemetry: | TBA90 | 0 | IESG | [RFCXXXX] |
| mid-percentile-c | | | | |
| ietf-dots-telemetry: | TBA91 | 0 | IESG | [RFCXXXX] |
| high-percentile-c | | | | |
| ietf-dots-telemetry: | TBA92 | 0 | IESG | [RFCXXXX] |
| peak-c | | | | |
| ietf-dots-telemetry: | TBA93 | 0 | IESG | [RFCXXXX] |
| connection | | | | |
| ietf-dots-telemetry: | TBA94 | 0 | IESG | [RFCXXXX] |
| embryonic | | | | |
| ietf-dots-telemetry: | TBA95 | 0 | IESG | [RFCXXXX] |
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| connection-ps | | | | |
| ietf-dots-telemetry: | TBA96 | 0 | IESG | [RFCXXXX] |
| request-ps | | | | |
| ietf-dots-telemetry: | TBA97 | 0 | IESG | [RFCXXXX] |
| partial-request-ps | | | | |
| ietf-dots-telemetry: | TBA98 | 4 | IESG | [RFCXXXX] |
| attack-detail | | | | |
| ietf-dots-telemetry: | TBA99 | 0 | IESG | [RFCXXXX] |
| id | | | | |
| ietf-dots-telemetry: | TBA100| 0 | IESG | [RFCXXXX] |
| attack-id | | | | |
| ietf-dots-telemetry: | TBA101| 0 | IESG | [RFCXXXX] |
| attack-name | | | | |
| ietf-dots-telemetry: | TBA102| 0 | IESG | [RFCXXXX] |
| attack-severity | | | | |
| ietf-dots-telemetry: | TBA103| 0 | IESG | [RFCXXXX] |
| start-time | | | | |
| ietf-dots-telemetry: | TBA104| 0 | IESG | [RFCXXXX] |
| end-time | | | | |
| ietf-dots-telemetry: | TBA105| 0 | IESG | [RFCXXXX] |
| source-count | | | | |
| ietf-dots-telemetry: | TBA106| 0 | IESG | [RFCXXXX] |
| top-talker | | | | |
| ietf-dots-telemetry: | TBA107| 0 | IESG | [RFCXXXX] |
| spoofed-status | | | | |
| ietf-dots-telemetry: | TBA108| 0 | IESG | [RFCXXXX] |
| talker | | | | |
| ietf-dots-telemetry: | TBA109| 0 | IESG | [RFCXXXX] |
| source-prefix | | | | |
| ietf-dots-telemetry: | | | | |
| source-port-range | TBA110| 4 | IESG | [RFCXXXX] |
| ietf-dots-telemetry: | | | | |
| lower-port | TBA111| 0 | IESG | [RFCXXXX] |
| ietf-dots-telemetry: | | | | |
| upper-port | TBA112| 0 | IESG | [RFCXXXX] |
| ietf-dots-telemetry: | | | | |
| source-icmp-type- | TBA113| 4 | IESG | [RFCXXXX] |
| range | | | | |
| ietf-dots-telemetry: | | | | |
| lower-type | TBA114| 0 | IESG | [RFCXXXX] |
| ietf-dots-telemetry: | | | | |
| upper-type | TBA115| 0 | IESG | [RFCXXXX] |
| ietf-dots-telemetry: | TBA116| 5 | IESG | [RFCXXXX] |
| telemetry | | | | |
+----------------------+-------+-------+------------+---------------+
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11.2. DOTS Signal Channel Conflict Cause Codes
This specification requests IANA to assign a new code from the "DOTS
Signal Channel Conflict Cause Codes" registry available at
https://www.iana.org/assignments/dots/dots.xhtml#dots-signal-channel-
conflict-cause-codes.
Code Label Description Reference
TBA overlapping-pipes Overlapping pipe scope [RFCXXXX]
11.3. DOTS Signal Telemetry YANG Module
This document requests IANA to register the following URI in the "ns"
subregistry within the "IETF XML Registry" [RFC3688]:
URI: urn:ietf:params:xml:ns:yang:ietf-dots-telemetry
Registrant Contact: The IESG.
XML: N/A; the requested URI is an XML namespace.
This document requests IANA to register the following YANG module in
the "YANG Module Names" subregistry [RFC7950] within the "YANG
Parameters" registry.
name: ietf-dots-telemetry
namespace: urn:ietf:params:xml:ns:yang:ietf-dots-telemetry
maintained by IANA: N
prefix: dots-telemetry
reference: RFC XXXX
12. Security Considerations
Security considerations in [I-D.ietf-dots-signal-channel] need to be
taken into consideration.
13. Contributors
The following individuals have contributed to this document:
o Li Su, CMCC, Email: suli@chinamobile.com
o Jin Peng, CMCC, Email: pengjin@chinamobile.com
o Pan Wei, Huawei, Email: william.panwei@huawei.com
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14. Acknowledgements
The authors would like to thank Flemming Andreasen, Liang Xia, and
Kaname Nishizuka co-authors of https://tools.ietf.org/html/draft-
doron-dots-telemetry-00 draft and everyone who had contributed to
that document.
The authors would like to thank Kaname Nishizuka, Jon Shallow, Wei
Pan and Yuuhei Hayashi for comments and review.
15. References
15.1. Normative References
[Enterprise-Numbers]
"Private Enterprise Numbers", 2005, <http://www.iana.org/
assignments/enterprise-numbers.html>.
[I-D.ietf-dots-data-channel]
Boucadair, M. and T. Reddy.K, "Distributed Denial-of-
Service Open Threat Signaling (DOTS) Data Channel
Specification", draft-ietf-dots-data-channel-31 (work in
progress), July 2019.
[I-D.ietf-dots-signal-call-home]
Reddy.K, T., Boucadair, M., and J. Shallow, "Distributed
Denial-of-Service Open Threat Signaling (DOTS) Signal
Channel Call Home", draft-ietf-dots-signal-call-home-08
(work in progress), March 2020.
[I-D.ietf-dots-signal-channel]
Reddy.K, T., Boucadair, M., Patil, P., Mortensen, A., and
N. Teague, "Distributed Denial-of-Service Open Threat
Signaling (DOTS) Signal Channel Specification", draft-
ietf-dots-signal-channel-41 (work in progress), January
2020.
[I-D.ietf-dots-signal-filter-control]
Nishizuka, K., Boucadair, M., Reddy.K, T., and T. Nagata,
"Controlling Filtering Rules Using Distributed Denial-of-
Service Open Threat Signaling (DOTS) Signal Channel",
draft-ietf-dots-signal-filter-control-03 (work in
progress), March 2020.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119,
DOI 10.17487/RFC2119, March 1997,
<https://www.rfc-editor.org/info/rfc2119>.
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[RFC3688] Mealling, M., "The IETF XML Registry", BCP 81, RFC 3688,
DOI 10.17487/RFC3688, January 2004,
<https://www.rfc-editor.org/info/rfc3688>.
[RFC6991] Schoenwaelder, J., Ed., "Common YANG Data Types",
RFC 6991, DOI 10.17487/RFC6991, July 2013,
<https://www.rfc-editor.org/info/rfc6991>.
[RFC7049] Bormann, C. and P. Hoffman, "Concise Binary Object
Representation (CBOR)", RFC 7049, DOI 10.17487/RFC7049,
October 2013, <https://www.rfc-editor.org/info/rfc7049>.
[RFC7641] Hartke, K., "Observing Resources in the Constrained
Application Protocol (CoAP)", RFC 7641,
DOI 10.17487/RFC7641, September 2015,
<https://www.rfc-editor.org/info/rfc7641>.
[RFC7950] Bjorklund, M., Ed., "The YANG 1.1 Data Modeling Language",
RFC 7950, DOI 10.17487/RFC7950, August 2016,
<https://www.rfc-editor.org/info/rfc7950>.
[RFC7959] Bormann, C. and Z. Shelby, Ed., "Block-Wise Transfers in
the Constrained Application Protocol (CoAP)", RFC 7959,
DOI 10.17487/RFC7959, August 2016,
<https://www.rfc-editor.org/info/rfc7959>.
[RFC8174] Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC
2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174,
May 2017, <https://www.rfc-editor.org/info/rfc8174>.
[RFC8345] Clemm, A., Medved, J., Varga, R., Bahadur, N.,
Ananthakrishnan, H., and X. Liu, "A YANG Data Model for
Network Topologies", RFC 8345, DOI 10.17487/RFC8345, March
2018, <https://www.rfc-editor.org/info/rfc8345>.
15.2. Informative References
[I-D.bosh-core-new-block]
Boucadair, M. and J. Shallow, "New Constrained Application
Protocol (CoAP) Block-Wise Transfer Options", draft-bosh-
core-new-block-00 (work in progress), April 2020.
[I-D.ietf-dots-multihoming]
Boucadair, M., Reddy.K, T., and W. Pan, "Multi-homing
Deployment Considerations for Distributed-Denial-of-
Service Open Threat Signaling (DOTS)", draft-ietf-dots-
multihoming-03 (work in progress), January 2020.
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[I-D.ietf-dots-use-cases]
Dobbins, R., Migault, D., Moskowitz, R., Teague, N., Xia,
L., and K. Nishizuka, "Use cases for DDoS Open Threat
Signaling", draft-ietf-dots-use-cases-20 (work in
progress), September 2019.
[RFC2330] Paxson, V., Almes, G., Mahdavi, J., and M. Mathis,
"Framework for IP Performance Metrics", RFC 2330,
DOI 10.17487/RFC2330, May 1998,
<https://www.rfc-editor.org/info/rfc2330>.
[RFC8340] Bjorklund, M. and L. Berger, Ed., "YANG Tree Diagrams",
BCP 215, RFC 8340, DOI 10.17487/RFC8340, March 2018,
<https://www.rfc-editor.org/info/rfc8340>.
[RFC8612] Mortensen, A., Reddy, T., and R. Moskowitz, "DDoS Open
Threat Signaling (DOTS) Requirements", RFC 8612,
DOI 10.17487/RFC8612, May 2019,
<https://www.rfc-editor.org/info/rfc8612>.
Authors' Addresses
Mohamed Boucadair (editor)
Orange
Rennes 35000
France
Email: mohamed.boucadair@orange.com
Tirumaleswar Reddy (editor)
McAfee, Inc.
Embassy Golf Link Business Park
Bangalore, Karnataka 560071
India
Email: kondtir@gmail.com
Ehud Doron
Radware Ltd.
Raoul Wallenberg Street
Tel-Aviv 69710
Israel
Email: ehudd@radware.com
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Meiling Chen
CMCC
32, Xuanwumen West
BeiJing, BeiJing 100053
China
Email: chenmeiling@chinamobile.com
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