<- BCP Index (1..100)
BCP 72
(also RFC 3552, RFC 9416)
[Note that this file is a concatenation of more than one RFC.]
Network Working Group E. Rescorla
Request for Comments: 3552 RTFM, Inc.
BCP: 72 B. Korver
Category: Best Current Practice Xythos Software
Internet Architecture Board
IAB
July 2003
Guidelines for Writing RFC Text on Security Considerations
Status of this Memo
This document specifies an Internet Best Current Practices for the
Internet Community, and requests discussion and suggestions for
improvements. Distribution of this memo is unlimited.
Copyright Notice
Copyright (C) The Internet Society (2003). All Rights Reserved.
Abstract
All RFCs are required to have a Security Considerations section.
Historically, such sections have been relatively weak. This document
provides guidelines to RFC authors on how to write a good Security
Considerations section.
Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . 3
1.1. Requirements. . . . . . . . . . . . . . . . . . . . . 3
2. The Goals of Security. . . . . . . . . . . . . . . . . . . 3
2.1. Communication Security. . . . . . . . . . . . . . . . 3
2.1.1. Confidentiality. . . . . . . . . . . . . . . . 4
2.1.2. Data Integrity . . . . . . . . . . . . . . . . 4
2.1.3. Peer Entity authentication . . . . . . . . . . 4
2.2. Non-Repudiation . . . . . . . . . . . . . . . . . . . 5
2.3. Systems Security. . . . . . . . . . . . . . . . . . . 5
2.3.1. Unauthorized Usage . . . . . . . . . . . . . . 6
2.3.2. Inappropriate Usage. . . . . . . . . . . . . . 6
2.3.3. Denial of Service. . . . . . . . . . . . . . . 6
3. The Internet Threat Model. . . . . . . . . . . . . . . . . 6
3.1. Limited Threat Models . . . . . . . . . . . . . . . . 7
3.2. Passive Attacks . . . . . . . . . . . . . . . . . . . 7
3.2.1. Confidentiality Violations . . . . . . . . . . 8
3.2.2. Password Sniffing. . . . . . . . . . . . . . . 8
3.2.3. Offline Cryptographic Attacks. . . . . . . . . 9
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3.3. Active Attacks. . . . . . . . . . . . . . . . . . . . 9
3.3.1. Replay Attacks . . . . . . . . . . . . . . . . 10
3.3.2. Message Insertion. . . . . . . . . . . . . . . 10
3.3.3. Message Deletion . . . . . . . . . . . . . . . 11
3.3.4. Message Modification . . . . . . . . . . . . . 11
3.3.5. Man-In-The-Middle. . . . . . . . . . . . . . . 12
3.4. Topological Issues. . . . . . . . . . . . . . . . . . 12
3.5. On-path versus off-path . . . . . . . . . . . . . . . 13
3.6. Link-local. . . . . . . . . . . . . . . . . . . . . . 13
4. Common Issues. . . . . . . . . . . . . . . . . . . . . . . 13
4.1. User Authentication . . . . . . . . . . . . . . . . . 14
4.1.1. Username/Password. . . . . . . . . . . . . . . 14
4.1.2. Challenge Response and One Time Passwords. . . 14
4.1.3. Shared Keys. . . . . . . . . . . . . . . . . . 15
4.1.4. Key Distribution Centers . . . . . . . . . . . 15
4.1.5. Certificates . . . . . . . . . . . . . . . . . 15
4.1.6. Some Uncommon Systems. . . . . . . . . . . . . 15
4.1.7. Host Authentication. . . . . . . . . . . . . . 16
4.2. Generic Security Frameworks . . . . . . . . . . . . . 16
4.3. Non-repudiation . . . . . . . . . . . . . . . . . . . 17
4.4. Authorization vs. Authentication. . . . . . . . . . . 18
4.4.1. Access Control Lists . . . . . . . . . . . . . 18
4.4.2. Certificate Based Systems. . . . . . . . . . . 18
4.5. Providing Traffic Security. . . . . . . . . . . . . . 19
4.5.1. IPsec. . . . . . . . . . . . . . . . . . . . . 19
4.5.2. SSL/TLS. . . . . . . . . . . . . . . . . . . . 20
4.5.3. Remote Login . . . . . . . . . . . . . . . . . 22
4.6. Denial of Service Attacks and Countermeasures . . . . 22
4.6.1. Blind Denial of Service. . . . . . . . . . . . 23
4.6.2. Distributed Denial of Service. . . . . . . . . 23
4.6.3. Avoiding Denial of Service . . . . . . . . . . 24
4.6.4. Example: TCP SYN Floods. . . . . . . . . . . . 24
4.6.5. Example: Photuris. . . . . . . . . . . . . . . 25
4.7. Object vs. Channel Security . . . . . . . . . . . . . 25
4.8. Firewalls and Network Topology. . . . . . . . . . . . 26
5. Writing Security Considerations Sections . . . . . . . . . 26
6. Examples . . . . . . . . . . . . . . . . . . . . . . . . . 28
6.1. SMTP. . . . . . . . . . . . . . . . . . . . . . . . . 29
6.1.1. Security Considerations. . . . . . . . . . . . 29
6.1.2. Communications security issues . . . . . . . . 34
6.1.3. Denial of Service. . . . . . . . . . . . . . . 36
6.2. VRRP. . . . . . . . . . . . . . . . . . . . . . . . . .36
6.2.1. Security Considerations. . . . . . . . . . . . 36
7. Acknowledgments. . . . . . . . . . . . . . . . . . . . . . 38
8. Normative References . . . . . . . . . . . . . . . . . . . 39
9. Informative References . . . . . . . . . . . . . . . . . . 41
10.Security Considerations. . . . . . . . . . . . . . . . . . 42
Appendix A. . . . . . . . . . . . . . . . . . . . . . . . . . 43
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Authors' Addresses. . . . . . . . . . . . . . . . . . . . . . 43
Full Copyright Statement. . . . . . . . . . . . . . . . . . . 44
1. Introduction
All RFCs are required by RFC 2223 to contain a Security
Considerations section. The purpose of this is both to encourage
document authors to consider security in their designs and to inform
the reader of relevant security issues. This memo is intended to
provide guidance to RFC authors in service of both ends.
This document is structured in three parts. The first is a
combination security tutorial and definition of common terms; the
second is a series of guidelines for writing Security Considerations;
the third is a series of examples.
1.1. Requirements
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
document are to be interpreted as described in BCP 14, RFC 2119
[KEYWORDS].
2. The Goals of Security
Most people speak of security as if it were a single monolithic
property of a protocol or system, however, upon reflection, one
realizes that it is clearly not true. Rather, security is a series
of related but somewhat independent properties. Not all of these
properties are required for every application.
We can loosely divide security goals into those related to protecting
communications (COMMUNICATION SECURITY, also known as COMSEC) and
those relating to protecting systems (ADMINISTRATIVE SECURITY or
SYSTEM SECURITY). Since communications are carried out by systems
and access to systems is through communications channels, these goals
obviously interlock, but they can also be independently provided.
2.1. Communication Security
Different authors partition the goals of communication security
differently. The partitioning we've found most useful is to divide
them into three major categories: CONFIDENTIALITY, DATA INTEGRITY and
PEER ENTITY AUTHENTICATION.
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2.1.1. Confidentiality
When most people think of security, they think of CONFIDENTIALITY.
Confidentiality means that your data is kept secret from unintended
listeners. Usually, these listeners are simply eavesdroppers. When
an adversary taps your phone, it poses a risk to your
confidentiality.
Obviously, if you have secrets, then you are probably concerned about
others discovering them. Thus, at the very least, you want to
maintain confidentiality. When you see spies in the movies go into
the bathroom and turn on all the water to foil bugging, the property
they're looking for is confidentiality.
2.1.2. Data Integrity
The second primary goal is DATA INTEGRITY. The basic idea here is
that we want to make sure that the data we receive is the same data
that the sender has sent. In paper-based systems, some data
integrity comes automatically. When you receive a letter written in
pen you can be fairly certain that no words have been removed by an
attacker because pen marks are difficult to remove from paper.
However, an attacker could have easily added some marks to the paper
and completely changed the meaning of the message. Similarly, it's
easy to shorten the page to truncate the message.
On the other hand, in the electronic world, since all bits look
alike, it's trivial to tamper with messages in transit. You simply
remove the message from the wire, copy out the parts you like, add
whatever data you want, and generate a new message of your choosing,
and the recipient is no wiser. This is the moral equivalent of the
attacker taking a letter you wrote, buying some new paper and
recopying the message, changing it as he does it. It's just a lot
easier to do electronically since all bits look alike.
2.1.3. Peer Entity authentication
The third property we're concerned with is PEER ENTITY
AUTHENTICATION. What we mean by this is that we know that one of the
endpoints in the communication is the one we intended. Without peer
entity authentication, it's very difficult to provide either
confidentiality or data integrity. For instance, if we receive a
message from Alice, the property of data integrity doesn't do us much
good unless we know that it was in fact sent by Alice and not the
attacker. Similarly, if we want to send a confidential message to
Bob, it's not of much value to us if we're actually sending a
confidential message to the attacker.
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Note that peer entity authentication can be provided asymmetrically.
When you call someone on the phone, you can be fairly certain that
you have the right person -- or at least that you got a person who's
actually at the phone number you called. On the other hand, if they
don't have caller ID, then the receiver of a phone call has no idea
who's calling them. Calling someone on the phone is an example of
recipient authentication, since you know who the recipient of the
call is, but they don't know anything about the sender.
In messaging situations, you often wish to use peer entity
authentication to establish the identity of the sender of a certain
message. In such contexts, this property is called DATA ORIGIN
AUTHENTICATION.
2.2. Non-Repudiation
A system that provides endpoint authentication allows one party to be
certain of the identity of someone with whom he is communicating.
When the system provides data integrity a receiver can be sure of
both the sender's identity and that he is receiving the data that
that sender meant to send. However, he cannot necessarily
demonstrate this fact to a third party. The ability to make this
demonstration is called NON-REPUDIATION.
There are many situations in which non-repudiation is desirable.
Consider the situation in which two parties have signed a contract
which one party wishes to unilaterally abrogate. He might simply
claim that he had never signed it in the first place. Non-
repudiation prevents him from doing so, thus protecting the
counterparty.
Unfortunately, non-repudiation can be very difficult to achieve in
practice and naive approaches are generally inadequate. Section 4.3
describes some of the difficulties, which generally stem from the
fact that the interests of the two parties are not aligned -- one
party wishes to prove something that the other party wishes to deny.
2.3. Systems Security
In general, systems security is concerned with protecting one's
machines and data. The intent is that machines should be used only
by authorized users and for the purposes that the owners intend.
Furthermore, they should be available for those purposes. Attackers
should not be able to deprive legitimate users of resources.
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2.3.1. Unauthorized Usage
Most systems are not intended to be completely accessible to the
public. Rather, they are intended to be used only by certain
authorized individuals. Although many Internet services are
available to all Internet users, even those servers generally offer a
larger subset of services to specific users. For instance, Web
Servers often will serve data to any user, but restrict the ability
to modify pages to specific users. Such modifications by the general
public would be UNAUTHORIZED USAGE.
2.3.2. Inappropriate Usage
Being an authorized user does not mean that you have free run of the
system. As we said above, some activities are restricted to
authorized users, some to specific users, and some activities are
generally forbidden to all but administrators. Moreover, even
activities which are in general permitted might be forbidden in some
cases. For instance, users may be permitted to send email but
forbidden from sending files above a certain size, or files which
contain viruses. These are examples of INAPPROPRIATE USAGE.
2.3.3. Denial of Service
Recall that our third goal was that the system should be available to
legitimate users. A broad variety of attacks are possible which
threaten such usage. Such attacks are collectively referred to as
DENIAL OF SERVICE attacks. Denial of service attacks are often very
easy to mount and difficult to stop. Many such attacks are designed
to consume machine resources, making it difficult or impossible to
serve legitimate users. Other attacks cause the target machine to
crash, completely denying service to users.
3. The Internet Threat Model
A THREAT MODEL describes the capabilities that an attacker is assumed
to be able to deploy against a resource. It should contain such
information as the resources available to an attacker in terms of
information, computing capability, and control of the system. The
purpose of a threat model is twofold. First, we wish to identify the
threats we are concerned with. Second, we wish to rule some threats
explicitly out of scope. Nearly every security system is vulnerable
to a sufficiently dedicated and resourceful attacker.
The Internet environment has a fairly well understood threat model.
In general, we assume that the end-systems engaging in a protocol
exchange have not themselves been compromised. Protecting against an
attack when one of the end-systems has been compromised is
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extraordinarily difficult. It is, however, possible to design
protocols which minimize the extent of the damage done under these
circumstances.
By contrast, we assume that the attacker has nearly complete control
of the communications channel over which the end-systems communicate.
This means that the attacker can read any PDU (Protocol Data Unit) on
the network and undetectably remove, change, or inject forged packets
onto the wire. This includes being able to generate packets that
appear to be from a trusted machine. Thus, even if the end-system
with which you wish to communicate is itself secure, the Internet
environment provides no assurance that packets which claim to be from
that system in fact are.
It's important to realize that the meaning of a PDU is different at
different levels. At the IP level, a PDU means an IP packet. At the
TCP level, it means a TCP segment. At the application layer, it
means some kind of application PDU. For instance, at the level of
email, it might either mean an RFC-822 message or a single SMTP
command. At the HTTP level, it might mean a request or response.
3.1. Limited Threat Models
As we've said, a resourceful and dedicated attacker can control the
entire communications channel. However, a large number of attacks
can be mounted by an attacker with fewer resources. A number of
currently known attacks can be mounted by an attacker with limited
control of the network. For instance, password sniffing attacks can
be mounted by an attacker who can only read arbitrary packets. This
is generally referred to as a PASSIVE ATTACK [INTAUTH].
By contrast, Morris' sequence number guessing attack [SEQNUM] can be
mounted by an attacker who can write but not read arbitrary packets.
Any attack which requires the attacker to write to the network is
known as an ACTIVE ATTACK.
Thus, a useful way of organizing attacks is to divide them based on
the capabilities required to mount the attack. The rest of this
section describes these categories and provides some examples of each
category.
3.2. Passive Attacks
In a passive attack, the attacker reads packets off the network but
does not write them. The simplest way to mount such an attack is to
simply be on the same LAN as the victim. On most common LAN
configurations, including Ethernet, 802.3, and FDDI, any machine on
the wire can read all traffic destined for any other machine on the
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same LAN. Note that switching hubs make this sort of sniffing
substantially more difficult, since traffic destined for a machine
only goes to the network segment which that machine is on.
Similarly, an attacker who has control of a host in the
communications path between two victim machines is able to mount a
passive attack on their communications. It is also possible to
compromise the routing infrastructure to specifically arrange that
traffic passes through a compromised machine. This might involve an
active attack on the routing infrastructure to facilitate a passive
attack on a victim machine.
Wireless communications channels deserve special consideration,
especially with the recent and growing popularity of wireless-based
LANs, such as those using 802.11. Since the data is simply broadcast
on well known radio frequencies, an attacker simply needs to be able
to receive those transmissions. Such channels are especially
vulnerable to passive attacks. Although many such channels include
cryptographic protection, it is often of such poor quality as to be
nearly useless [WEP].
In general, the goal of a passive attack is to obtain information
which the sender and receiver would prefer to remain private. This
private information may include credentials useful in the electronic
world and/or passwords or credentials useful in the outside world,
such as confidential business information.
3.2.1. Confidentiality Violations
The classic example of passive attack is sniffing some inherently
private data off of the wire. For instance, despite the wide
availability of SSL, many credit card transactions still traverse the
Internet in the clear. An attacker could sniff such a message and
recover the credit card number, which can then be used to make
fraudulent transactions. Moreover, confidential business information
is routinely transmitted over the network in the clear in email.
3.2.2. Password Sniffing
Another example of a passive attack is PASSWORD SNIFFING. Password
sniffing is directed towards obtaining unauthorized use of resources.
Many protocols, including [TELNET], [POP], and [NNTP] use a shared
password to authenticate the client to the server. Frequently, this
password is transmitted from the client to the server in the clear
over the communications channel. An attacker who can read this
traffic can therefore capture the password and REPLAY it. In other
words, the attacker can initiate a connection to the server and pose
as the client and login using the captured password.
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Note that although the login phase of the attack is active, the
actual password capture phase is passive. Moreover, unless the
server checks the originating address of connections, the login phase
does not require any special control of the network.
3.2.3. Offline Cryptographic Attacks
Many cryptographic protocols are subject to OFFLINE ATTACKS. In such
a protocol, the attacker recovers data which has been processed using
the victim's secret key and then mounts a cryptanalytic attack on
that key. Passwords make a particularly vulnerable target because
they are typically low entropy. A number of popular password-based
challenge response protocols are vulnerable to DICTIONARY ATTACK.
The attacker captures a challenge-response pair and then proceeds to
try entries from a list of common words (such as a dictionary file)
until he finds a password that produces the right response.
A similar such attack can be mounted on a local network when NIS is
used. The Unix password is crypted using a one-way function, but
tools exist to break such crypted passwords [KLEIN]. When NIS is
used, the crypted password is transmitted over the local network and
an attacker can thus sniff the password and attack it.
Historically, it has also been possible to exploit small operating
system security holes to recover the password file using an active
attack. These holes can then be bootstrapped into an actual account
by using the aforementioned offline password recovery techniques.
Thus we combine a low-level active attack with an offline passive
attack.
3.3. Active Attacks
When an attack involves writing data to the network, we refer to this
as an ACTIVE ATTACK. When IP is used without IPsec, there is no
authentication for the sender address. As a consequence, it's
straightforward for an attacker to create a packet with a source
address of his choosing. We'll refer to this as a SPOOFING ATTACK.
Under certain circumstances, such a packet may be screened out by the
network. For instance, many packet filtering firewalls screen out
all packets with source addresses on the INTERNAL network that arrive
on the EXTERNAL interface. Note, however, that this provides no
protection against an attacker who is inside the firewall. In
general, designers should assume that attackers can forge packets.
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However, the ability to forge packets does not go hand in hand with
the ability to receive arbitrary packets. In fact, there are active
attacks that involve being able to send forged packets but not
receive the responses. We'll refer to these as BLIND ATTACKS.
Note that not all active attacks require forging addresses. For
instance, the TCP SYN denial of service attack [TCPSYN] can be
mounted successfully without disguising the sender's address.
However, it is common practice to disguise one's address in order to
conceal one's identity if an attack is discovered.
Each protocol is susceptible to specific active attacks, but
experience shows that a number of common patterns of attack can be
adapted to any given protocol. The next sections describe a number
of these patterns and give specific examples of them as applied to
known protocols.
3.3.1. Replay Attacks
In a REPLAY ATTACK, the attacker records a sequence of messages off
of the wire and plays them back to the party which originally
received them. Note that the attacker does not need to be able to
understand the messages. He merely needs to capture and retransmit
them.
For example, consider the case where an S/MIME message is being used
to request some service, such as a credit card purchase or a stock
trade. An attacker might wish to have the service executed twice, if
only to inconvenience the victim. He could capture the message and
replay it, even though he can't read it, causing the transaction to
be executed twice.
3.3.2. Message Insertion
In a MESSAGE INSERTION attack, the attacker forges a message with
some chosen set of properties and injects it into the network. Often
this message will have a forged source address in order to disguise
the identity of the attacker.
For example, a denial-of-service attack can be mounted by inserting a
series of spurious TCP SYN packets directed towards the target host.
The target host responds with its own SYN and allocates kernel data
structures for the new connection. The attacker never completes the
3-way handshake, so the allocated connection endpoints just sit there
taking up kernel memory. Typical TCP stack implementations only
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allow some limited number of connections in this "half-open" state
and when this limit is reached, no more connections can be initiated,
even from legitimate hosts. Note that this attack is a blind attack,
since the attacker does not need to process the victim's SYNs.
3.3.3. Message Deletion
In a MESSAGE DELETION attack, the attacker removes a message from the
wire. Morris' sequence number guessing attack [SEQNUM] often
requires a message deletion attack to be performed successfully. In
this blind attack, the host whose address is being forged will
receive a spurious TCP SYN packet from the host being attacked.
Receipt of this SYN packet generates a RST, which would tear the
illegitimate connection down. In order to prevent this host from
sending a RST so that the attack can be carried out successfully,
Morris describes flooding this host to create queue overflows such
that the SYN packet is lost and thus never responded to.
3.3.4. Message Modification
In a MESSAGE MODIFICATION attack, the attacker removes a message from
the wire, modifies it, and reinjects it into the network. This sort
of attack is particularly useful if the attacker wants to send some
of the data in the message but also wants to change some of it.
Consider the case where the attacker wants to attack an order for
goods placed over the Internet. He doesn't have the victim's credit
card number so he waits for the victim to place the order and then
replaces the delivery address (and possibly the goods description)
with his own. Note that this particular attack is known as a CUT-
AND-PASTE attack since the attacker cuts the credit card number out
of the original message and pastes it into the new message.
Another interesting example of a cut-and-paste attack is provided by
[IPSPPROB]. If IPsec ESP is used without any MAC then it is possible
for the attacker to read traffic encrypted for a victim on the same
machine. The attacker attaches an IP header corresponding to a port
he controls onto the encrypted IP packet. When the packet is
received by the host it will automatically be decrypted and forwarded
to the attacker's port. Similar techniques can be used to mount a
session hijacking attack. Both of these attacks can be avoided by
always using message authentication when you use encryption. Note
that this attack only works if (1) no MAC check is being used, since
this attack generates damaged packets (2) a host-to-host SA is being
used, since a user-to-user SA will result in an inconsistency between
the port associated with the SA and the target port. If the
receiving machine is single-user than this attack is infeasible.
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3.3.5. Man-In-The-Middle
A MAN-IN-THE-MIDDLE attack combines the above techniques in a special
form: The attacker subverts the communication stream in order to pose
as the sender to receiver and the receiver to the sender:
What Alice and Bob think:
Alice <----------------------------------------------> Bob
What's happening:
Alice <----------------> Attacker <----------------> Bob
This differs fundamentally from the above forms of attack because it
attacks the identity of the communicating parties, rather than the
data stream itself. Consequently, many techniques which provide
integrity of the communications stream are insufficient to protect
against man-in-the-middle attacks.
Man-in-the-middle attacks are possible whenever a protocol lacks PEER
ENTITY AUTHENTICATION. For instance, if an attacker can hijack the
client TCP connection during the TCP handshake (perhaps by responding
to the client's SYN before the server does), then the attacker can
open another connection to the server and begin a man-in-the-middle
attack. It is also trivial to mount man-in-the-middle attacks on
local networks via ARP spoofing -- the attacker forges an ARP with
the victim's IP address and his own MAC address. Tools to mount this
sort of attack are readily available.
Note that it is only necessary to authenticate one side of the
transaction in order to prevent man-in-the-middle attacks. In such a
situation the the peers can establish an association in which only
one peer is authenticated. In such a system, an attacker can
initiate an association posing as the unauthenticated peer but cannot
transmit or access data being sent on a legitimate connection. This
is an acceptable situation in contexts such as Web e-commerce where
only the server needs to be authenticated (or the client is
independently authenticated via some non-cryptographic mechanism such
as a credit card number).
3.4. Topological Issues
In practice, the assumption that it's equally easy for an attacker to
read and generate all packets is false, since the Internet is not
fully connected. This has two primary implications.
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3.5. On-path versus off-path
In order for a datagram to be transmitted from one host to another,
it generally must traverse some set of intermediate links and
gateways. Such gateways are naturally able to read, modify, or
remove any datagram transmitted along that path. This makes it much
easier to mount a wide variety of attacks if you are on-path.
Off-path hosts can, of course, transmit arbitrary datagrams that
appear to come from any hosts but cannot necessarily receive
datagrams intended for other hosts. Thus, if an attack depends on
being able to receive data, off-path hosts must first subvert the
topology in order to place themselves on-path. This is by no means
impossible but is not necessarily trivial.
Applications protocol designers MUST NOT assume that all attackers
will be off-path. Where possible, protocols SHOULD be designed to
resist attacks from attackers who have complete control of the
network. However, designers are expected to give more weight to
attacks which can be mounted by off-path attackers as well as on-path
ones.
3.6. Link-local
One specialized case of on-path is being on the same link. In some
situations, it's desirable to distinguish between hosts who are on
the local network and those who are not. The standard technique for
this is verifying the IP TTL value [IP]. Since the TTL must be
decremented by each forwarder, a protocol can demand that TTL be set
to 255 and that all receivers verify the TTL. A receiver then has
some reason to believe that conforming packets are from the same
link. Note that this technique must be used with care in the
presence of tunneling systems, since such systems may pass packets
without decrementing TTL.
4. Common Issues
Although each system's security requirements are unique, certain
common requirements appear in a number of protocols. Often, when
naive protocol designers are faced with these requirements, they
choose an obvious but insecure solution even though better solutions
are available. This section describes a number of issues seen in
many protocols and the common pieces of security technology that may
be useful in addressing them.
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4.1. User Authentication
Essentially every system which wants to control access to its
resources needs some way to authenticate users. A nearly uncountable
number of such mechanisms have been designed for this purpose. The
next several sections describe some of these techniques.
4.1.1. Username/Password
The most common access control mechanism is simple USERNAME/PASSWORD
The user provides a username and a reusable password to the host
which he wishes to use. This system is vulnerable to a simple
passive attack where the attacker sniffs the password off the wire
and then initiates a new session, presenting the password. This
threat can be mitigated by hosting the protocol over an encrypted
connection such as TLS or IPSEC. Unprotected (plaintext)
username/password systems are not acceptable in IETF standards.
4.1.2. Challenge Response and One Time Passwords
Systems which desire greater security than USERNAME/PASSWORD often
employ either a ONE TIME PASSWORD [OTP] scheme or a CHALLENGE-
RESPONSE. In a one time password scheme, the user is provided with a
list of passwords, which must be used in sequence, one time each.
(Often these passwords are generated from some secret key so the user
can simply compute the next password in the sequence.) SecureID and
DES Gold are variants of this scheme. In a challenge-response
scheme, the host and the user share some secret (which often is
represented as a password). In order to authenticate the user, the
host presents the user with a (randomly generated) challenge. The
user computes some function based on the challenge and the secret and
provides that to the host, which verifies it. Often this computation
is performed in a handheld device, such as a DES Gold card.
Both types of scheme provide protection against replay attack, but
often still vulnerable to an OFFLINE KEYSEARCH ATTACK (a form of
passive attack): As previously mentioned, often the one-time password
or response is computed from a shared secret. If the attacker knows
the function being used, he can simply try all possible shared
secrets until he finds one that produces the right output. This is
made easier if the shared secret is a password, in which case he can
mount a DICTIONARY ATTACK -- meaning that he tries a list of common
words (or strings) rather than just random strings.
These systems are also often vulnerable to an active attack. Unless
communication security is provided for the entire session, the
attacker can simply wait until authentication has been performed and
hijack the connection.
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4.1.3. Shared Keys
CHALLENGE-RESPONSE type systems can be made secure against dictionary
attack by using randomly generated shared keys instead of user-
generated passwords. If the keys are sufficiently large then
keysearch attacks become impractical. This approach works best when
the keys are configured into the end nodes rather than memorized and
typed in by users, since users have trouble remembering sufficiently
long keys.
Like password-based systems, shared key systems suffer from
management problems. Each pair of communicating parties must have
their own agreed-upon key, which leads to there being a lot of keys.
4.1.4. Key Distribution Centers
One approach to solving the large number of keys problem is to use an
online "trusted third party" that mediates between the authenticating
parties. The trusted third party (generally called a a KEY
DISTRIBUTION CENTER (KDC)) shares a symmetric key or password with
each party in the system. It first contacts the KDC which gives it a
TICKET containing a randomly generated symmetric key encrypted under
both peer's keys. Since only the proper peers can decrypt the
symmetric key the ticket can be used to establish a trusted
association. By far the most popular KDC system is Kerberos
[KERBEROS].
4.1.5. Certificates
A simple approach is to have all users have CERTIFICATES [PKIX] which
they then use to authenticate in some protocol-specific way, as in
[TLS] or [S/MIME]. A certificate is a signed credential binding an
entity's identity to its public key. The signer of a certificate is
a CERTIFICATE AUTHORITY (CA), whose certificate may itself be signed
by some superior CA. In order for this system to work, trust in one
or more CAs must be established in an out-of-band fashion. Such CAs
are referred to as TRUSTED ROOTS or ROOT CAS. The primary obstacle
to this approach in client-server type systems is that it requires
clients to have certificates, which can be a deployment problem.
4.1.6. Some Uncommon Systems
There are ways to do a better job than the schemes mentioned above,
but they typically don't add much security unless communications
security (at least message integrity) will be employed to secure the
connection, because otherwise the attacker can merely hijack the
connection after authentication has been performed. A number of
protocols ([EKE], [SPEKE], [SRP]) allow one to securely bootstrap a
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user's password into a shared key which can be used as input to a
cryptographic protocol. One major obstacle to the deployment of
these protocols has been that their Intellectual Property status is
extremely unclear. Similarly, the user can authenticate using public
key certificates (e.g., S-HTTP client authentication). Typically
these methods are used as part of a more complete security protocol.
4.1.7. Host Authentication
Host authentication presents a special problem. Quite commonly, the
addresses of services are presented using a DNS hostname, for
instance as a URL [URL]. When requesting such a service, one has to
ensure that the entity that one is talking to not only has a
certificate but that that certificate corresponds to the expected
identity of the server. The important thing to have is a secure
binding between the certificate and the expected hostname.
For instance, it is usually not acceptable for the certificate to
contain an identity in the form of an IP address if the request was
for a given hostname. This does not provide end-to-end security
because the hostname-IP mapping is not secure unless secure name
resolution [DNSSEC] is being used. This is a particular problem when
the hostname is presented at the application layer but the
authentication is performed at some lower layer.
4.2. Generic Security Frameworks
Providing security functionality in a protocol can be difficult. In
addition to the problem of choosing authentication and key
establishment mechanisms, one needs to integrate it into a protocol.
One response to this problem (embodied in IPsec and TLS) is to create
a lower-level security protocol and then insist that new protocols be
run over that protocol. Another approach that has recently become
popular is to design generic application layer security frameworks.
The idea is that you design a protocol that allows you to negotiate
various security mechanisms in a pluggable fashion. Application
protocol designers then arrange to carry the security protocol PDUs
in their application protocol. Examples of such frameworks include
GSS-API [GSS] and SASL [SASL].
The generic framework approach has a number of problems. First, it
is highly susceptible to DOWNGRADE ATTACKS. In a downgrade attack,
an active attacker tampers with the negotiation in order to force the
parties to negotiate weaker protection than they otherwise would.
It's possible to include an integrity check after the negotiation and
key establishment have both completed, but the strength of this
integrity check is necessarily limited to the weakest common
algorithm. This problem exists with any negotiation approach, but
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generic frameworks exacerbate it by encouraging the application
protocol author to just specify the framework rather than think hard
about the appropriate underlying mechanisms, particularly since the
mechanisms can very widely in the degree of security offered.
Another problem is that it's not always obvious how the various
security features in the framework interact with the application
layer protocol. For instance, SASL can be used merely as an
authentication framework -- in which case the SASL exchange occurs
but the rest of the connection is unprotected, but can also negotiate
traffic protection, such as via GSS, as a mechanism. Knowing under
what circumstances traffic protection is optional and which it is
required requires thinking about the threat model.
In general, authentication frameworks are most useful in situations
where new protocols are being added to systems with pre-existing
legacy authentication systems. A framework allows new installations
to provide better authentication while not forcing existing sites
completely redo their legacy authentication systems. When the
security requirements of a system can be clearly identified and only
a few forms of authentication are used, choosing a single security
mechanism leads to greater simplicity and predictability. In
situations where a framework is to be used, designers SHOULD
carefully examine the framework's options and specify only the
mechanisms that are appropriate for their particular threat model.
If a framework is necessary, designers SHOULD choose one of the
established ones instead of designing their own.
4.3. Non-repudiation
The naive approach to non-repudiation is simply to use public-key
digital signatures over the content. The party who wishes to be
bound (the SIGNING PARTY) digitally signs the message in question.
The counterparty (the RELYING PARTY) can later point to the digital
signature as proof that the signing party at one point agreed to the
disputed message. Unfortunately, this approach is insufficient.
The easiest way for the signing party to repudiate the message is by
claiming that his private key has been compromised and that some
attacker (though not necessarily the relying party) signed the
disputed message. In order to defend against this attack the relying
party needs to demonstrate that the signing party's key had not been
compromised at the time of the signature. This requires substantial
infrastructure, including archival storage of certificate revocation
information and timestamp servers to establish the time that the
message was signed.
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Additionally, the relying party might attempt to trick the signing
party into signing one message while thinking he's signing another.
This problem is particularly severe when the relying party controls
the infrastructure that the signing party uses for signing, such as
in kiosk situations. In many such situations the signing party's key
is kept on a smartcard but the message to be signed is displayed by
the relying party.
All of these complications make non-repudiation a difficult service
to deploy in practice.
4.4. Authorization vs. Authentication
AUTHORIZATION is the process by which one determines whether an
authenticated party has permission to access a particular resource or
service. Although tightly bound, it is important to realize that
authentication and authorization are two separate mechanisms.
Perhaps because of this tight coupling, authentication is sometimes
mistakenly thought to imply authorization. Authentication simply
identifies a party, authorization defines whether they can perform a
certain action.
Authorization necessarily relies on authentication, but
authentication alone does not imply authorization. Rather, before
granting permission to perform an action, the authorization mechanism
must be consulted to determine whether that action is permitted.
4.4.1. Access Control Lists
One common form of authorization mechanism is an access control list
(ACL), which lists users that are permitted access to a resource.
Since assigning individual authorization permissions to each resource
is tedious, resources are often hierarchically arranged so that the
parent resource's ACL is inherited by child resources. This allows
administrators to set top level policies and override them when
necessary.
4.4.2. Certificate Based Systems
While the distinction between authentication and authorization is
intuitive when using simple authentication mechanisms such as
username and password (i.e., everyone understands the difference
between the administrator account and a user account), with more
complex authentication mechanisms the distinction is sometimes lost.
With certificates, for instance, presenting a valid signature does
not imply authorization. The signature must be backed by a
certificate chain that contains a trusted root, and that root must be
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trusted in the given context. For instance, users who possess
certificates issued by the Acme MIS CA may have different web access
privileges than users who possess certificates issued by the Acme
Accounting CA, even though both of these CAs are "trusted" by the
Acme web server.
Mechanisms for enforcing these more complicated properties have not
yet been completely explored. One approach is simply to attach
policies to ACLs describing what sorts of certificates are trusted.
Another approach is to carry that information with the certificate,
either as a certificate extension/attribute [PKIX, SPKI] or as a
separate "Attribute Certificate".
4.5. Providing Traffic Security
Securely designed protocols should provide some mechanism for
securing (meaning integrity protecting, authenticating, and possibly
encrypting) all sensitive traffic. One approach is to secure the
protocol itself, as in [DNSSEC], [S/MIME] or [S-HTTP]. Although this
provides security which is most fitted to the protocol, it also
requires considerable effort to get right.
Many protocols can be adequately secured using one of the available
channel security systems. We'll discuss the two most common, IPsec
[AH, ESP] and [TLS].
4.5.1. IPsec
The IPsec protocols (specifically, AH and ESP) can provide
transmission security for all traffic between two hosts. The IPsec
protocols support varying granularities of user identification,
including for example "IP Subnet", "IP Address", "Fully Qualified
Domain Name", and individual user ("Mailbox name"). These varying
levels of identification are employed as inputs to access control
facilities that are an intrinsic part of IPsec. However, a given
IPsec implementation might not support all identity types. In
particular, security gateways may not provide user-to-user
authentication or have mechanisms to provide that authentication
information to applications.
When AH or ESP is used, the application programmer might not need to
do anything (if AH or ESP has been enabled system-wide) or might need
to make specific software changes (e.g., adding specific setsockopt()
calls) -- depending on the AH or ESP implementation being used.
Unfortunately, APIs for controlling IPsec implementations are not yet
standardized.
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The primary obstacle to using IPsec to secure other protocols is
deployment. The major use of IPsec at present is for VPN
applications, especially for remote network access. Without
extremely tight coordination between security administrators and
application developers, VPN usage is not well suited to providing
security services for individual applications since it is difficult
for such applications to determine what security services have in
fact been provided.
IPsec deployment in host-to-host environments has been slow. Unlike
application security systems such as TLS, adding IPsec to a non-IPsec
system generally involves changing the operating system, either by
modifying with the kernel or installing new drivers. This is a
substantially greater undertaking than simply installing a new
application. However, recent versions of a number of commodity
operating systems include IPsec stacks, so deployment is becoming
easier.
In environments where IPsec is sure to be available, it represents a
viable option for protecting application communications traffic. If
the traffic to be protected is UDP, IPsec and application-specific
object security are the only options. However, designers MUST NOT
assume that IPsec will be available. A security policy for a generic
application layer protocol SHOULD NOT simply state that IPsec must be
used, unless there is some reason to believe that IPsec will be
available in the intended deployment environment. In environments
where IPsec may not be available and the traffic is solely TCP, TLS
is the method of choice, since the application developer can easily
ensure its presence by including a TLS implementation in his package.
In the special-case of IPv6, both AH and ESP are mandatory to
implement. Hence, it is reasonable to assume that AH/ESP are already
available for IPv6-only protocols or IPv6-only deployments. However,
automatic key management (IKE) is not required to implement so
protocol designers SHOULD not assume it will be present. [USEIPSEC]
provides quite a bit of guidance on when IPsec is a good choice.
4.5.2. SSL/TLS
Currently, the most common approach is to use SSL or its successor
TLS. They provide channel security for a TCP connection at the
application level. That is, they run over TCP. SSL implementations
typically provide a Berkeley Sockets-like interface for easy
programming. The primary issue when designing a protocol solution
around TLS is to differentiate between connections protected using
TLS and those which are not.
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The two primary approaches used have a separate well-known port for
TLS connections (e.g., the HTTP over TLS port is 443) [HTTPTLS] or to
have a mechanism for negotiating upward from the base protocol to TLS
as in [UPGRADE] or [STARTTLS]. When an upward negotiation strategy
is used, care must be taken to ensure that an attacker can not force
a clear connection when both parties wish to use TLS.
Note that TLS depends upon a reliable protocol such as TCP or SCTP.
This produces two notable difficulties. First, it cannot be used to
secure datagram protocols that use UDP. Second, TLS is susceptible
to IP layer attacks that IPsec is not. Typically, these attacks take
some form of denial of service or connection assassination. For
instance, an attacker might forge a TCP RST to shut down SSL
connections. TLS has mechanisms to detect truncation attacks but
these merely allow the victim to know he is being attacked and do not
provide connection survivability in the face of such attacks. By
contrast, if IPsec were being used, such a forged RST could be
rejected without affecting the TCP connection. If forged RSTs or
other such attacks on the TCP connection are a concern, then AH/ESP
or the TCP MD5 option [TCPMD5] are the preferred choices.
4.5.2.1. Virtual Hosts
If the "separate ports" approach to TLS is used, then TLS will be
negotiated before any application-layer traffic is sent. This can
cause a problem with protocols that use virtual hosts, such as
[HTTP], since the server does not know which certificate to offer the
client during the TLS handshake. The TLS hostname extension [TLSEXT]
can be used to solve this problem, although it is too new to have
seen wide deployment.
4.5.2.2. Remote Authentication and TLS
One difficulty with using TLS is that the server is authenticated via
a certificate. This can be inconvenient in environments where
previously the only form of authentication was a password shared
between client and server. It's tempting to use TLS without an
authenticated server (i.e., with anonymous DH or a self-signed RSA
certificate) and then authenticate via some challenge-response
mechanism such as SASL with CRAM-MD5.
Unfortunately, this composition of SASL and TLS is less strong than
one would expect. It's easy for an active attacker to hijack this
connection. The client man-in-the-middles the SSL connection
(remember we're not authenticating the server, which is what
ordinarily prevents this attack) and then simply proxies the SASL
handshake. From then on, it's as if the connection were in the
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clear, at least as far as that attacker is concerned. In order to
prevent this attack, the client needs to verify the server's
certificate.
However, if the server is authenticated, challenge-response becomes
less desirable. If you already have a hardened channel then simple
passwords are fine. In fact, they're arguably superior to
challenge-response since they do not require that the password be
stored in the clear on the server. Thus, compromise of the key file
with challenge-response systems is more serious than if simple
passwords were used.
Note that if the client has a certificate than SSL-based client
authentication can be used. To make this easier, SASL provides the
EXTERNAL mechanism, whereby the SASL client can tell the server
"examine the outer channel for my identity". Obviously, this is not
subject to the layering attacks described above.
4.5.3. Remote Login
In some special cases it may be worth providing channel-level
security directly in the application rather than using IPSEC or
SSL/TLS. One such case is remote terminal security. Characters are
typically delivered from client to server one character at a time.
Since SSL/TLS and AH/ESP authenticate and encrypt every packet, this
can mean a data expansion of 20-fold. The telnet encryption option
[ENCOPT] prevents this expansion by foregoing message integrity.
When using remote terminal service, it's often desirable to securely
perform other sorts of communications services. In addition to
providing remote login, SSH [SSH] also provides secure port
forwarding for arbitrary TCP ports, thus allowing users run arbitrary
TCP-based applications over the SSH channel. Note that SSH Port
Forwarding can be security issue if it is used improperly to
circumvent firewall and improperly expose insecure internal
applications to the outside world.
4.6. Denial of Service Attacks and Countermeasures
Denial of service attacks are all too frequently viewed as an fact of
life. One problem is that an attacker can often choose from one of
many denial of service attacks to inflict upon a victim, and because
most of these attacks cannot be thwarted, common wisdom frequently
assumes that there is no point protecting against one kind of denial
of service attack when there are many other denial of service attacks
that are possible but that cannot be prevented.
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However, not all denial of service attacks are equal and more
importantly, it is possible to design protocols so that denial of
service attacks are made more difficult, if not impractical. Recent
SYN flood attacks [TCPSYN] demonstrate both of these properties: SYN
flood attacks are so easy, anonymous, and effective that they are
more attractive to attackers than other attacks; and because the
design of TCP enables this attack.
Because complete DoS protection is so difficult, security against DoS
must be dealt with pragmatically. In particular, some attacks which
would be desirable to defend against cannot be defended against
economically. The goal should be to manage risk by defending against
attacks with sufficiently high ratios of severity to cost of defense.
Both severity of attack and cost of defense change as technology
changes and therefore so does the set of attacks which should be
defended against.
Authors of internet standards MUST describe which denial of service
attacks their protocol is susceptible to. This description MUST
include the reasons it was either unreasonable or out of scope to
attempt to avoid these denial of service attacks.
4.6.1. Blind Denial of Service
BLIND denial of service attacks are particularly pernicious. With a
blind attack the attacker has a significant advantage. If the
attacker must be able to receive traffic from the victim, then he
must either subvert the routing fabric or use his own IP address.
Either provides an opportunity for the victim to track the attacker
and/or filter out his traffic. With a blind attack the attacker can
use forged IP addresses, making it extremely difficult for the victim
to filter out his packets. The TCP SYN flood attack is an example of
a blind attack. Designers should make every attempt possible to
prevent blind denial of service attacks.
4.6.2. Distributed Denial of Service
Even more dangerous are DISTRIBUTED denial of service attacks (DDoS)
[DDOS]. In a DDoS the attacker arranges for a number of machines to
attack the target machine simultaneously. Usually this is
accomplished by infecting a large number of machines with a program
that allows remote initiation of attacks. The machines actually
performing the attack are called ZOMBIEs and are likely owned by
unsuspecting third parties in an entirely different location from the
true attacker. DDoS attacks can be very hard to counter because the
zombies often appear to be making legitimate protocol requests and
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simply crowd out the real users. DDoS attacks can be difficult to
thwart, but protocol designers are expected to be cognizant of these
forms of attack while designing protocols.
4.6.3. Avoiding Denial of Service
There are two common approaches to making denial of service attacks
more difficult:
4.6.3.1. Make your attacker do more work than you do
If an attacker consumes more of his resources than yours when
launching an attack, attackers with fewer resources than you will be
unable to launch effective attacks. One common technique is to
require the attacker perform a time-intensive operation, such as a
cryptographic operation. Note that an attacker can still mount a
denial of service attack if he can muster substantially sufficient
CPU power. For instance, this technique would not stop the
distributed attacks described in [TCPSYN].
4.6.3.2. Make your attacker prove they can receive data from you
A blind attack can be subverted by forcing the attacker to prove that
they can can receive data from the victim. A common technique is to
require that the attacker reply using information that was gained
earlier in the message exchange. If this countermeasure is used, the
attacker must either use his own address (making him easy to track)
or to forge an address which will be routed back along a path that
traverses the host from which the attack is being launched.
Hosts on small subnets are thus useless to the attacker (at least in
the context of a spoofing attack) because the attack can be traced
back to a subnet (which should be sufficient for locating the
attacker) so that anti-attack measures can be put into place (for
instance, a boundary router can be configured to drop all traffic
from that subnet). A common technique is to require that the
attacker reply using information that was gained earlier in the
message exchange.
4.6.4. Example: TCP SYN Floods
TCP/IP is vulnerable to SYN flood attacks (which are described in
section 3.3.2) because of the design of the 3-way handshake. First,
an attacker can force a victim to consume significant resources (in
this case, memory) by sending a single packet. Second, because the
attacker can perform this action without ever having received data
from the victim, the attack can be performed anonymously (and
therefore using a large number of forged source addresses).
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4.6.5. Example: Photuris
[PHOTURIS] specifies an anti-clogging mechanism that prevents attacks
on Photuris that resemble the SYN flood attack. Photuris employs a
time-variant secret to generate a "cookie" which is returned to the
attacker. This cookie must be returned in subsequent messages for
the exchange to progress. The interesting feature is that this
cookie can be regenerated by the victim later in the exchange, and
thus no state need be retained by the victim until after the attacker
has proven that he can receive packets from the victim.
4.7. Object vs. Channel Security
It's useful to make the conceptual distinction between object
security and channel security. Object security refers to security
measures which apply to entire data objects. Channel security
measures provide a secure channel over which objects may be carried
transparently but the channel has no special knowledge about object
boundaries.
Consider the case of an email message. When it's carried over an
IPSEC or TLS secured connection, the message is protected during
transmission. However, it is unprotected in the receiver's mailbox,
and in intermediate spool files along the way. Moreover, since mail
servers generally run as a daemon, not a user, authentication of
messages generally merely means authentication of the daemon not the
user. Finally, since mail transport is hop-by-hop, even if the user
authenticates to the first hop relay the authentication can't be
safely verified by the receiver.
By contrast, when an email message is protected with S/MIME or
OpenPGP, the entire message is encrypted and integrity protected
until it is examined and decrypted by the recipient. It also
provides strong authentication of the actual sender, as opposed to
the machine the message came from. This is object security.
Moreover, the receiver can prove the signed message's authenticity to
a third party.
Note that the difference between object and channel security is a
matter of perspective. Object security at one layer of the protocol
stack often looks like channel security at the next layer up. So,
from the perspective of the IP layer, each packet looks like an
individually secured object. But from the perspective of a web
client, IPSEC just provides a secure channel.
The distinction isn't always clear-cut. For example, S-HTTP provides
object level security for a single HTTP transaction, but a web page
typically consists of multiple HTTP transactions (the base page and
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numerous inline images). Thus, from the perspective of the total web
page, this looks rather more like channel security. Object security
for a web page would consist of security for the transitive closure
of the page and all its embedded content as a single unit.
4.8. Firewalls and Network Topology
It's common security practice in modern networks to partition the
network into external and internal networks using a firewall. The
internal network is then assumed to be secure and only limited
security measures are used there. The internal portion of such a
network is often called a WALLED GARDEN.
Internet protocol designers cannot safely assume that their protocols
will be deployed in such an environment, for three reasons. First,
protocols which were originally designed to be deployed in closed
environments often are later deployed on the Internet, thus creating
serious vulnerabilities.
Second, networks which appear to be topologically disconnected may
not be. One reason may be that the network has been reconfigured to
allow access by the outside world. Moreover, firewalls are
increasingly passing generic application layer protocols such as
[SOAP] or [HTTP]. Network protocols which are based on these generic
protocols cannot in general assume that a firewall will protect them.
Finally, one of the most serious security threats to systems is from
insiders, not outsiders. Since insiders by definition have access to
the internal network, topological protections such as firewalls will
not protect them.
5. Writing Security Considerations Sections
While it is not a requirement that any given protocol or system be
immune to all forms of attack, it is still necessary for authors to
consider as many forms as possible. Part of the purpose of the
Security Considerations section is to explain what attacks are out of
scope and what countermeasures can be applied to defend against them.
In
There should be a clear description of the kinds of threats on the
described protocol or technology. This should be approached as an
effort to perform "due diligence" in describing all known or
foreseeable risks and threats to potential implementers and users.
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Authors MUST describe
1. which attacks are out of scope (and why!)
2. which attacks are in-scope
2.1 and the protocol is susceptible to
2.2 and the protocol protects against
At least the following forms of attack MUST be considered:
eavesdropping, replay, message insertion, deletion, modification, and
man-in-the-middle. Potential denial of service attacks MUST be
identified as well. If the protocol incorporates cryptographic
protection mechanisms, it should be clearly indicated which portions
of the data are protected and what the protections are (i.e.,
integrity only, confidentiality, and/or endpoint authentication,
etc.). Some indication should also be given to what sorts of attacks
the cryptographic protection is susceptible. Data which should be
held secret (keying material, random seeds, etc.) should be clearly
labeled.
If the technology involves authentication, particularly user-host
authentication, the security of the authentication method MUST be
clearly specified. That is, authors MUST document the assumptions
that the security of this authentication method is predicated upon.
For instance, in the case of the UNIX username/password login method,
a statement to the effect of:
Authentication in the system is secure only to the extent that it
is difficult to guess or obtain a ASCII password that is a maximum
of 8 characters long. These passwords can be obtained by sniffing
telnet sessions or by running the 'crack' program using the
contents of the /etc/passwd file. Attempts to protect against
on-line password guessing by (1) disconnecting after several
unsuccessful login attempts and (2) waiting between successive
password prompts is effective only to the extent that attackers
are impatient.
Because the /etc/passwd file maps usernames to user ids, groups,
etc. it must be world readable. In order to permit this usage but
make running crack more difficult, the file is often split into
/etc/passwd and a 'shadow' password file. The shadow file is not
world readable and contains the encrypted password. The regular
/etc/passwd file contains a dummy password in its place.
It is insufficient to simply state that one's protocol should be run
over some lower layer security protocol. If a system relies upon
lower layer security services for security, the protections those
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services are expected to provide MUST be clearly specified. In
addition, the resultant properties of the combined system need to be
specified.
Note: In general, the IESG will not approve standards track protocols
which do not provide for strong authentication, either internal to
the protocol or through tight binding to a lower layer security
protocol.
The threat environment addressed by the Security Considerations
section MUST at a minimum include deployment across the global
Internet across multiple administrative boundaries without assuming
that firewalls are in place, even if only to provide justification
for why such consideration is out of scope for the protocol. It is
not acceptable to only discuss threats applicable to LANs and ignore
the broader threat environment. All IETF standards-track protocols
are considered likely to have deployment in the global Internet. In
some cases, there might be an Applicability Statement discouraging
use of a technology or protocol in a particular environment.
Nonetheless, the security issues of broader deployment should be
discussed in the document.
There should be a clear description of the residual risk to the user
or operator of that protocol after threat mitigation has been
deployed. Such risks might arise from compromise in a related
protocol (e.g., IPsec is useless if key management has been
compromised), from incorrect implementation, compromise of the
security technology used for risk reduction (e.g., a cipher with a
40-bit key), or there might be risks that are not addressed by the
protocol specification (e.g., denial of service attacks on an
underlying link protocol). Particular care should be taken in
situations where the compromise of a single system would compromise
an entire protocol. For instance, in general protocol designers
assume that end-systems are inviolate and don't worry about physical
attack. However, in cases (such as a certificate authority) where
compromise of a single system could lead to widespread compromises,
it is appropriate to consider systems and physical security as well.
There should also be some discussion of potential security risks
arising from potential misapplications of the protocol or technology
described in the RFC. This might be coupled with an Applicability
Statement for that RFC.
6. Examples
This section consists of some example security considerations
sections, intended to give the reader a flavor of what's intended by
this document.
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The first example is a 'retrospective' example, applying the criteria
of this document to an existing widely deployed protocol, SMTP. The
second example is a good security considerations section clipped from
a current protocol.
6.1. SMTP
When RFC 821 was written, Security Considerations sections were not
required in RFCs, and none is contained in that document. [RFC 2821]
updated RFC 821 and added a detailed security considerations section.
We reproduce here the Security Considerations section from that
document (with new section numbers). Our comments are indented and
prefaced with 'NOTE:'. We also add a number of new sections to cover
topics we consider important. Those sections are marked with [NEW]
in the section header.
6.1.1. Security Considerations
6.1.1.1. Mail Security and Spoofing
SMTP mail is inherently insecure in that it is feasible for even
fairly casual users to negotiate directly with receiving and relaying
SMTP servers and create messages that will trick a naive recipient
into believing that they came from somewhere else. Constructing such
a message so that the "spoofed" behavior cannot be detected by an
expert is somewhat more difficult, but not sufficiently so as to be a
deterrent to someone who is determined and knowledgeable.
Consequently, as knowledge of Internet mail increases, so does the
knowledge that SMTP mail inherently cannot be authenticated, or
integrity checks provided, at the transport level. Real mail
security lies only in end-to-end methods involving the message
bodies, such as those which use digital signatures (see [14] and,
e.g., PGP [4] or S/MIME [31]).
NOTE: One bad approach to sender authentication is [IDENT] in
which the receiving mail server contacts the alleged sender and
asks for the username of the sender. This is a bad idea for a
number of reasons, including but not limited to relaying, TCP
connection hijacking, and simple lying by the origin server.
Aside from the fact that IDENT is of low security value, use of
IDENT by receiving sites can lead to operational problems. Many
sending sites blackhole IDENT requests, thus causing mail to be
held until the receiving server's IDENT request times out.
Various protocol extensions and configuration options that provide
authentication at the transport level (e.g., from an SMTP client to
an SMTP server) improve somewhat on the traditional situation
described above. However, unless they are accompanied by careful
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handoffs of responsibility in a carefully-designed trust environment,
they remain inherently weaker than end-to-end mechanisms which use
digitally signed messages rather than depending on the integrity of
the transport system.
Efforts to make it more difficult for users to set envelope return
path and header "From" fields to point to valid addresses other than
their own are largely misguided: they frustrate legitimate
applications in which mail is sent by one user on behalf of another
or in which error (or normal) replies should be directed to a special
address. (Systems that provide convenient ways for users to alter
these fields on a per-message basis should attempt to establish a
primary and permanent mailbox address for the user so that Sender
fields within the message data can be generated sensibly.)
This specification does not further address the authentication issues
associated with SMTP other than to advocate that useful functionality
not be disabled in the hope of providing some small margin of
protection against an ignorant user who is trying to fake mail.
NOTE: We have added additional material on communications security
and SMTP in Section 6.1.2 In a final specification, the above text
would be edited somewhat to reflect that fact.
6.1.1.2. Blind Copies
Addresses that do not appear in the message headers may appear in the
RCPT commands to an SMTP server for a number of reasons. The two
most common involve the use of a mailing address as a "list exploder"
(a single address that resolves into multiple addresses) and the
appearance of "blind copies". Especially when more than one RCPT
command is present, and in order to avoid defeating some of the
purpose of these mechanisms, SMTP clients and servers SHOULD NOT copy
the full set of RCPT command arguments into the headers, either as
part of trace headers or as informational or private-extension
headers. Since this rule is often violated in practice, and cannot
be enforced, sending SMTP systems that are aware of "bcc" use MAY
find it helpful to send each blind copy as a separate message
transaction containing only a single RCPT command.
There is no inherent relationship between either "reverse" (from
MAIL, SAML, etc., commands) or "forward" (RCPT) addresses in the SMTP
transaction ("envelope") and the addresses in the headers. Receiving
systems SHOULD NOT attempt to deduce such relationships and use them
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to alter the headers of the message for delivery. The popular
"Apparently-to" header is a violation of this principle as well as a
common source of unintended information disclosure and SHOULD NOT be
used.
6.1.1.3. VRFY, EXPN, and Security
As discussed in section 3.5, individual sites may want to disable
either or both of VRFY or EXPN for security reasons. As a corollary
to the above, implementations that permit this MUST NOT appear to
have verified addresses that are not, in fact, verified. If a site
disables these commands for security reasons, the SMTP server MUST
return a 252 response, rather than a code that could be confused with
successful or unsuccessful verification.
Returning a 250 reply code with the address listed in the VRFY
command after having checked it only for syntax violates this rule.
Of course, an implementation that "supports" VRFY by always returning
550 whether or not the address is valid is equally not in
conformance.
Within the last few years, the contents of mailing lists have become
popular as an address information source for so-called "spammers."
The use of EXPN to "harvest" addresses has increased as list
administrators have installed protections against inappropriate uses
of the lists themselves. Implementations SHOULD still provide
support for EXPN, but sites SHOULD carefully evaluate the tradeoffs.
As authentication mechanisms are introduced into SMTP, some sites may
choose to make EXPN available only to authenticated requesters.
NOTE: It's not clear that disabling VRFY adds much protection,
since it's often possible to discover whether an address is valid
using RCPT TO.
6.1.1.4. Information Disclosure in Announcements
There has been an ongoing debate about the tradeoffs between the
debugging advantages of announcing server type and version (and,
sometimes, even server domain name) in the greeting response or in
response to the HELP command and the disadvantages of exposing
information that might be useful in a potential hostile attack. The
utility of the debugging information is beyond doubt. Those who
argue for making it available point out that it is far better to
actually secure an SMTP server rather than hope that trying to
conceal known vulnerabilities by hiding the server's precise identity
will provide more protection. Sites are encouraged to evaluate the
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tradeoff with that issue in mind; implementations are strongly
encouraged to minimally provide for making type and version
information available in some way to other network hosts.
6.1.1.5. Information Disclosure in Trace Fields
In some circumstances, such as when mail originates from within a LAN
whose hosts are not directly on the public Internet, trace
("Received") fields produced in conformance with this specification
may disclose host names and similar information that would not
normally be available. This ordinarily does not pose a problem, but
sites with special concerns about name disclosure should be aware of
it. Also, the optional FOR clause should be supplied with caution or
not at all when multiple recipients are involved lest it
inadvertently disclose the identities of "blind copy" recipients to
others.
6.1.1.6. Information Disclosure in Message Forwarding
As discussed in section 3.4, use of the 251 or 551 reply codes to
identify the replacement address associated with a mailbox may
inadvertently disclose sensitive information. Sites that are
concerned about those issues should ensure that they select and
configure servers appropriately.
6.1.1.7. Scope of Operation of SMTP Servers
It is a well-established principle that an SMTP server may refuse to
accept mail for any operational or technical reason that makes sense
to the site providing the server. However, cooperation among sites
and installations makes the Internet possible. If sites take
excessive advantage of the right to reject traffic, the ubiquity of
email availability (one of the strengths of the Internet) will be
threatened; considerable care should be taken and balance maintained
if a site decides to be selective about the traffic it will accept
and process.
In recent years, use of the relay function through arbitrary sites
has been used as part of hostile efforts to hide the actual origins
of mail. Some sites have decided to limit the use of the relay
function to known or identifiable sources, and implementations SHOULD
provide the capability to perform this type of filtering. When mail
is rejected for these or other policy reasons, a 550 code SHOULD be
used in response to EHLO, MAIL, or RCPT as appropriate.
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6.1.1.8. Inappropriate Usage [NEW]
SMTP itself provides no protection is provided against unsolicited
commercial mass e-mail (aka spam). It is extremely difficult to tell
a priori whether a given message is spam or not. From a protocol
perspective, spam is indistinguishable from other e-mail -- the
distinction is almost entirely social and often quite subtle. (For
instance, is a message from a merchant from whom you've purchased
items before advertising similar items spam?) SMTP spam-suppression
mechanisms are generally limited to identifying known spam senders
and either refusing to service them or target them for
punishment/disconnection. [RFC-2505] provides extensive guidance on
making SMTP servers spam-resistant. We provide a brief discussion of
the topic here.
The primary tool for refusal to service spammers is the blacklist.
Some authority such as [MAPS] collects and publishes a list of known
spammers. Individual SMTP servers then block the blacklisted
offenders (generally by IP address).
In order to avoid being blacklisted or otherwise identified, spammers
often attempt to obscure their identity, either simply by sending a
false SMTP identity or by forwarding their mail through an Open Relay
-- an SMTP server which will perform mail relaying for any sender.
As a consequence, there are now blacklists [ORBS] of open relays as
well.
6.1.1.8.1. Closed Relaying [NEW]
To avoid being used for spam forwarding, many SMTP servers operate as
closed relays, providing relaying service only for clients who they
can identify. Such relays should generally insist that senders
advertise a sending address consistent with their known identity. If
the relay is providing service for an identifiable network (such as a
corporate network or an ISP's network) then it is sufficient to block
all other IP addresses). In other cases, explicit authentication
must be used. The two standard choices for this are TLS [STARTTLS]
and SASL [SASLSMTP].
6.1.1.8.2. Endpoints [NEW]
Realistically, SMTP endpoints cannot refuse to deny service to
unauthenticated senders. Since the vast majority of senders are
unauthenticated, this would break Internet mail interoperability.
The exception to this is when the endpoint server should only be
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receiving mail from some other server which can itself receive
unauthenticated messages. For instance, a company might operate a
public gateway but configure its internal servers to only talk to the
gateway.
6.1.2. Communications security issues [NEW]
SMTP itself provides no communications security, and therefore a
large number of attacks are possible. A passive attack is sufficient
to recover the text of messages transmitted with SMTP. No endpoint
authentication is provided by the protocol. Sender spoofing is
trivial, and therefore forging email messages is trivial. Some
implementations do add header lines with hostnames derived through
reverse name resolution (which is only secure to the extent that it
is difficult to spoof DNS -- not very), although these header lines
are normally not displayed to users. Receiver spoofing is also
fairly straight-forward, either using TCP connection hijacking or DNS
spoofing. Moreover, since email messages often pass through SMTP
gateways, all intermediate gateways must be trusted, a condition
nearly impossible on the global Internet.
Several approaches are available for alleviating these threats. In
order of increasingly high level in the protocol stack, we have:
SMTP over IPSEC
SMTP/TLS
S/MIME and PGP/MIME
6.1.2.1. SMTP over IPSEC [NEW]
An SMTP connection run over IPSEC can provide confidentiality for the
message between the sender and the first hop SMTP gateway, or between
any pair of connected SMTP gateways. That is to say, it provides
channel security for the SMTP connections. In a situation where the
message goes directly from the client to the receiver's gateway, this
may provide substantial security (though the receiver must still
trust the gateway). Protection is provided against replay attacks,
since the data itself is protected and the packets cannot be
replayed.
Endpoint identification is a problem, however, unless the receiver's
address can be directly cryptographically authenticated. Sender
identification is not generally available, since generally only the
sender's machine is authenticated, not the sender himself.
Furthermore, the identity of the sender simply appears in the From
header of the message, so it is easily spoofable by the sender.
Finally, unless the security policy is set extremely strictly, there
is also an active downgrade to cleartext attack.
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Another problem with IPsec as a security solution for SMTP is the
lack of a standard IPsec API. In order to take advantage of IPsec,
applications in general need to be able to instruct the IPsec
implementation about their security policies and discover what
protection has been applied to their connections. Without a standard
API this is very difficult to do portably.
Implementors of SMTP servers or SMTP administrators MUST NOT assume
that IPsec will be available unless they have reason to believe that
it will be (such as the existence of preexisting association between
two machines). However, it may be a reasonable procedure to attempt
to create an IPsec association opportunistically to a peer server
when mail is delivered. Note that in cases where IPsec is used to
provide a VPN tunnel between two sites, this is of substantial
security value, particularly to the extent that confidentiality is
provided, subject to the caveats mentioned above. Also see
[USEIPSEC] for general guidance on the applicability of IPsec.
6.1.2.2. SMTP/TLS [NEW]
SMTP can be combined with TLS as described in [STARTTLS]. This
provides similar protection to that provided when using IPSEC. Since
TLS certificates typically contain the server's host name, recipient
authentication may be slightly more obvious, but is still susceptible
to DNS spoofing attacks. Notably, common implementations of TLS
contain a US exportable (and hence low security) mode. Applications
desiring high security should ensure that this mode is disabled.
Protection is provided against replay attacks, since the data itself
is protected and the packets cannot be replayed. [Note: The
Security Considerations section of the SMTP over TLS document is
quite good and bears reading as an example of how to do things.]
6.1.2.3. S/MIME and PGP/MIME [NEW]
S/MIME and PGP/MIME are both message oriented security protocols.
They provide object security for individual messages. With various
settings, sender and recipient authentication and confidentiality may
be provided. More importantly, the identification is not of the
sending and receiving machines, but rather of the sender and
recipient themselves. (Or, at least, of cryptographic keys
corresponding to the sender and recipient.) Consequently, end-to-end
security may be obtained. Note, however, that no protection is
provided against replay attacks. Note also that S/MIME and PGP/MIME
generally provide identifying marks for both sender and receiver.
Thus even when confidentiality is provided, traffic analysis is still
possible.
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6.1.3. Denial of Service [NEW]
None of these security measures provides any real protection against
denial of service. SMTP connections can easily be used to tie up
system resources in a number of ways, including excessive port
consumption, excessive disk usage (email is typically delivered to
disk files), and excessive memory consumption (sendmail, for
instance, is fairly large, and typically forks a new process to deal
with each message.)
If transport- or application-layer security is used for SMTP
connections, it is possible to mount a variety of attacks on
individual connections using forged RSTs or other kinds of packet
injection.
6.2. VRRP
The second example is from VRRP, the Virtual Router Redundance
Protocol ([VRRP]). We reproduce here the Security Considerations
section from that document (with new section numbers). Our comments
are indented and prefaced with 'NOTE:'.
6.2.1. Security Considerations
VRRP is designed for a range of internetworking environments that may
employ different security policies. The protocol includes several
authentication methods ranging from no authentication, simple clear
text passwords, and strong authentication using IP Authentication
with MD5 HMAC. The details on each approach including possible
attacks and recommended environments follows.
Independent of any authentication type VRRP includes a mechanism
(setting TTL=255, checking on receipt) that protects against VRRP
packets being injected from another remote network. This limits most
vulnerabilities to local attacks.
NOTE: The security measures discussed in the following sections
only provide various kinds of authentication. No confidentiality
is provided at all. This should be explicitly described as
outside the scope.
6.2.1.1. No Authentication
The use of this authentication type means that VRRP protocol
exchanges are not authenticated. This type of authentication SHOULD
only be used in environments were there is minimal security risk and
little chance for configuration errors (e.g., two VRRP routers on a
LAN).
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6.2.1.2. Simple Text Password
The use of this authentication type means that VRRP protocol
exchanges are authenticated by a simple clear text password.
This type of authentication is useful to protect against accidental
misconfiguration of routers on a LAN. It protects against routers
inadvertently backing up another router. A new router must first be
configured with the correct password before it can run VRRP with
another router. This type of authentication does not protect against
hostile attacks where the password can be learned by a node snooping
VRRP packets on the LAN. The Simple Text Authentication combined
with the TTL check makes it difficult for a VRRP packet to be sent
from another LAN to disrupt VRRP operation.
This type of authentication is RECOMMENDED when there is minimal risk
of nodes on a LAN actively disrupting VRRP operation. If this type
of authentication is used the user should be aware that this clear
text password is sent frequently, and therefore should not be the
same as any security significant password.
NOTE: This section should be clearer. The basic point is that no
authentication and Simple Text are only useful for a very limited
threat model, namely that none of the nodes on the local LAN are
hostile. The TTL check prevents hostile nodes off-LAN from posing
as valid nodes, but nothing stops hostile nodes on-LAN from
impersonating authorized nodes. This is not a particularly
realistic threat model in many situations. In particular, it's
extremely brittle: the compromise of any node the LAN allows
reconfiguration of the VRRP nodes.
6.2.1.3. IP Authentication Header
The use of this authentication type means the VRRP protocol exchanges
are authenticated using the mechanisms defined by the IP
Authentication Header [AH] using [HMAC]. This provides strong
protection against configuration errors, replay attacks, and packet
corruption/modification.
This type of authentication is RECOMMENDED when there is limited
control over the administration of nodes on a LAN. While this type
of authentication does protect the operation of VRRP, there are other
types of attacks that may be employed on shared media links (e.g.,
generation of bogus ARP replies) which are independent from VRRP and
are not protected.
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NOTE: It's a mistake to have AH be a RECOMMENDED in this context.
Since AH is the only mechanism that protects VRRP against attack
from other nodes on the same LAN, it should be a MUST for cases
where there are untrusted nodes on the same network. In any case,
AH should be a MUST implement.
NOTE: There's an important piece of security analysis that's only
hinted at in this document, namely the cost/benefit tradeoff of
VRRP authentication.
[The rest of this section is NEW material]
The threat that VRRP authentication is intended to prevent is an
attacker arranging to be the VRRP master. This would be done by
joining the group (probably multiple times), gagging the master and
then electing oneself master. Such a node could then direct traffic
in arbitrary undesirable ways.
However, it is not necessary for an attacker to be the VRRP master to
do this. An attacker can do similar kinds of damage to the network
by forging ARP packets or (on switched networks) fooling the switch
VRRP authentication offers no real protection against these attacks.
Unfortunately, authentication makes VRRP networks very brittle in the
face of misconfiguration. Consider what happens if two nodes are
configured with different passwords. Each will reject messages from
the other and therefore both will attempt to be master. This creates
substantial network instability.
This set of cost/benefit tradeoffs suggests that VRRP authentication
is a bad idea, since the incremental security benefit is marginal but
the incremental risk is high. This judgment should be revisited if
the current set of non-VRRP threats are removed.
7. Acknowledgments
This document is heavily based on a note written by Ran Atkinson in
1997. That note was written after the IAB Security Workshop held in
early 1997, based on input from everyone at that workshop. Some of
the specific text above was taken from Ran's original document, and
some of that text was taken from an email message written by Fred
Baker. The other primary source for this document is specific
comments received from Steve Bellovin. Early review of this document
was done by Lisa Dusseault and Mark Schertler. Other useful comments
were received from Bill Fenner, Ned Freed, Lawrence Greenfield, Steve
Kent, Allison Mankin and Kurt Zeilenga.
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8. Normative References
[AH] Kent, S. and R. Atkinson, "IP Authentication Header", RFC
2402, November 1998.
[DNSSEC] Eastlake, D., "Domain Name System Security Extensions",
RFC 2535, March 1999.
[ENCOPT] Tso, T., "Telnet Data Encryption Option", RFC 2946,
September, 2000.
[ESP] Kent, S. and R. Atkinson, "IP Encapsulating Security
Payload (ESP)", RFC 2406, November 1998.
[GSS] Linn, J., "Generic Security Services Application Program
Interface Version 2, Update 1", RFC 2743, January 2000.
[HTTP] Fielding, R., Gettys, J., Mogul, J., Frystyk, H.,
Masinter, L., Leach, P. and T. Berners-Lee, "HyperText
Transfer Protocol", RFC 2616, June 1999.
[HTTPTLS] Rescorla, E., "HTTP over TLS", RFC 2818, May 2000.
[HMAC] Madson, C. and R. Glenn, "The Use of HMAC-MD5-96 within
ESP and AH", RFC 2403, November 1998.
KERBEROS] Kohl, J. and C. Neuman, "The Kerberos Network
Authentication Service (V5)", RFC 1510, September 1993.
[KEYWORDS] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[OTP] Haller, N., Metz, C., Nesser, P. and M. Straw, "A One-Time
Password System", STD 61, RFC 2289, February 1998.
[PHOTURIS] Karn, P. and W. Simpson, "Photuris: Session-Key Management
Protocol", RFC 2522, March 1999.
[PKIX] Housley, R., Polk, W., Ford, W. and D. Solo, "Internet
X.509 "Public Key Infrastructure Certificate and
Certificate Restoration List (CRL) Profile", RFC 3280,
April 2002.
[RFC-2223] Postel J. and J. Reynolds, "Instructions to RFC Authors",
RFC 2223, October 1997.
[RFC-2505] Lindberg, G., "Anti-Spam Recommendations for SMTP MTAs",
BCP 30, RFC 2505, February 1999.
Rescorla & Korver Best Current Practice [Page 39]
RFC 3552 Security Considerations Guidelines July 2003
[RFC-2821] Klensin, J., "Simple Mail Transfer Protocol", RFC 2821,
April 2001.
[SASL] Myers, J., "Simple Authentication and Security Layer
(SASL)", RFC 2222, October 1997.
[SPKI] Ellison, C., Frantz, B., Lampson, B., Rivest, R., Thomas,
B. and T. Ylonen, "SPKI Certificate Theory", RFC 2693,
September 1999.
[SSH] Ylonen, T., "SSH - Secure Login Connections Over the
Internet", 6th USENIX Security Symposium, p. 37-42, July
1996.
[SASLSMTP] Myers, J., "SMTP Service Extension for Authentication",
RFC 2554, March 1999.
[STARTTLS] Hoffman, P., "SMTP Service Extension for Secure SMTP over
Transport Layer Security", RFC 3207, February 2002.
[S-HTTP] Rescorla, E. and A. Schiffman, "The Secure HyperText
Transfer Protocol", RFC 2660, August 1999.
[S/MIME] Ramsdell, B., Editor, "S/MIME Version 3 Message
Specification", RFC 2633, June 1999.
[TELNET] Postel, J. and J. Reynolds, "Telnet Protocol
Specification", STD 8, RFC 854, May 1983.
[TLS] Dierks, T. and C. Allen, "The TLS Protocol Version 1.0",
RFC 2246, January 1999.
[TLSEXT] Blake-Wilson, S., Nystrom, M., Hopwood, D. and J.
Mikkelsen, "Transport Layer Security (TLS) Extensions",
RFC 3546, May 2003.
[TCPSYN] "TCP SYN Flooding and IP Spoofing Attacks", CERT Advisory
CA-1996-21, 19 September 1996, CERT.
http://www.cert.org/advisories/CA-1996-21.html
[UPGRADE] Khare, R. and S. Lawrence, "Upgrading to TLS Within
HTTP/1.1", RFC 2817, May 2000.
[URL] Berners-Lee, T., Masinter, M. and M. McCahill, "Uniform
Resource Locators (URL)", RFC 1738, December 1994.
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[VRRP] Knight, S., Weaver, D., Whipple, D., Hinden, R., Mitzel,
D., Hunt, P., Higginson, P., Shand, M. and A. Lindemn,
"Virtual Router Redundancy Protocol", RFC 2338, April
1998.
9. Informative References
[DDOS] "Denial-Of-Service Tools" CERT Advisory CA-1999-17, 28
December 1999, CERT http://www.cert.org/advisories/CA-
1999-17.html
[EKE] Bellovin, S., Merritt, M., "Encrypted Key Exchange:
Password-based protocols secure against dictionary
attacks", Proceedings of the IEEE Symposium on Research in
Security and Privacy, May 1992.
[IDENT] St. Johns, M. and M. Rose, "Identification Protocol", RFC
1414, February 1993.
[INTAUTH] Haller, N. and R. Atkinson, "On Internet Authentication",
RFC 1704, October 1994.
[IPSPPROB] Bellovin, S. M., "Problem Areas for the IP Security
Protocols", Proceedings of the Sixth Usenix UNIX Security
Symposium, July 1996.
[KLEIN] Klein, D.V., "Foiling the Cracker: A Survey of and
Improvements to Password Security", 1990.
[NNTP] Kantor, B. and P. Lapsley, "Network News Transfer
Protocol", RFC 977, February 1986.
[POP] Myers, J. and M. Rose, "Post Office Protocol - Version 3",
STD 53, RFC 1939, May 1996.
[SEQNUM] Morris, R.T., "A Weakness in the 4.2 BSD UNIX TCP/IP
Software", AT&T Bell Laboratories, CSTR 117, 1985.
[SOAP] Box, D., Ehnebuske, D., Kakivaya, G., Layman, A.,
Mendelsoh, N., Nielsen, H., Thatte, S., Winer, D., "Simple
Object Access Protocol (SOAP) 1.1", May 2000.
[SPEKE] Jablon, D., "Strong Password-Only Authenticated Key
Exchange", Computer Communication Review, ACM SIGCOMM,
vol. 26, no. 5, pp. 5-26, October 1996.
[SRP] Wu T., "The Secure Remote Password Protocol", ISOC NDSS
Symposium, 1998.
Rescorla & Korver Best Current Practice [Page 41]
RFC 3552 Security Considerations Guidelines July 2003
[USEIPSEC] Bellovin, S., "Guidelines for Mandating the Use of IPsec",
Work in Progress.
[WEP] Borisov, N., Goldberg, I., Wagner, D., "Intercepting
Mobile Communications: The Insecurity of 802.11",
http://www.isaac.cs.berkeley.edu/isaac/wep-draft.pdf
10. Security Considerations
This entire document is about security considerations.
Rescorla & Korver Best Current Practice [Page 42]
RFC 3552 Security Considerations Guidelines July 2003
Appendix A.
IAB Members at the time of this writing
Harald Alvestrand
Ran Atkinson
Rob Austein
Fred Baker
Leslie Daigle
Steve Deering
Sally Floyd
Ted Hardie
Geoff Huston
Charlie Kaufman
James Kempf
Eric Rescorla
Mike St. Johns
Authors' Addresses
Eric Rescorla
RTFM, Inc.
2439 Alvin Drive
Mountain View, CA 94043
Phone: (650)-320-8549
EMail: ekr@rtfm.com
Brian Korver
Xythos Software, Inc.
77 Maiden Lane, 6th Floor
San Francisco, CA, 94108
Phone: (415)-248-3800
EMail: briank@xythos.com
Internet Architecture Board
IAB
EMail: iab@iab.org
Rescorla & Korver Best Current Practice [Page 43]
RFC 3552 Security Considerations Guidelines July 2003
Full Copyright Statement
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Acknowledgement
Funding for the RFC Editor function is currently provided by the
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Rescorla & Korver Best Current Practice [Page 44]
=========================================================================
Internet Engineering Task Force (IETF) F. Gont
Request for Comments: 9416 SI6 Networks
BCP: 72 I. Arce
Updates: 3552 Quarkslab
Category: Best Current Practice July 2023
ISSN: 2070-1721
Security Considerations for Transient Numeric Identifiers Employed in
Network Protocols
Abstract
Poor selection of transient numerical identifiers in protocols such
as the TCP/IP suite has historically led to a number of attacks on
implementations, ranging from Denial of Service (DoS) or data
injection to information leakages that can be exploited by pervasive
monitoring. Due diligence in the specification of transient numeric
identifiers is required even when cryptographic techniques are
employed, since these techniques might not mitigate all the
associated issues. This document formally updates RFC 3552,
incorporating requirements for transient numeric identifiers, to
prevent flaws in future protocols and implementations.
Status of This Memo
This memo documents an Internet Best Current Practice.
This document is a product of the Internet Engineering Task Force
(IETF). It represents the consensus of the IETF community. It has
received public review and has been approved for publication by the
Internet Engineering Steering Group (IESG). Further information on
BCPs is available in Section 2 of RFC 7841.
Information about the current status of this document, any errata,
and how to provide feedback on it may be obtained at
https://www.rfc-editor.org/info/rfc9416.
Copyright Notice
Copyright (c) 2023 IETF Trust and the persons identified as the
document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal
Provisions Relating to IETF Documents
(https://trustee.ietf.org/license-info) in effect on the date of
publication of this document. Please review these documents
carefully, as they describe your rights and restrictions with respect
to this document. Code Components extracted from this document must
include Revised BSD License text as described in Section 4.e of the
Trust Legal Provisions and are provided without warranty as described
in the Revised BSD License.
Table of Contents
1. Introduction
2. Terminology
3. Issues with the Specification of Transient Numeric Identifiers
4. Common Flaws in the Generation of Transient Numeric Identifiers
5. Requirements for Transient Numeric Identifiers
6. IANA Considerations
7. Security Considerations
8. References
8.1. Normative References
8.2. Informative References
Acknowledgements
Authors' Addresses
1. Introduction
Networking protocols employ a variety of transient numeric
identifiers for different protocol objects, such as IPv4 and IPv6
Identification values [RFC791] [RFC8200], IPv6 Interface Identifiers
(IIDs) [RFC4291], transport-protocol ephemeral port numbers
[RFC6056], TCP Initial Sequence Numbers (ISNs) [RFC9293], NTP
Reference IDs (REFIDs) [RFC5905], and DNS IDs [RFC1035]. These
identifiers typically have specific requirements (e.g., uniqueness
during a specified period of time) that must be satisfied such that
they do not result in negative interoperability implications, and an
associated failure severity when such requirements are not met
[RFC9415].
| NOTE: Some documents refer to the DNS ID as the DNS "Query ID"
| or "TxID".
For more than 30 years, a large number of implementations of IETF
protocols have been subject to a variety of attacks, with effects
ranging from Denial of Service (DoS) or data injection to information
leakages that could be exploited for pervasive monitoring [RFC7258].
The root cause of these issues has been, in many cases, the poor
selection of transient numeric identifiers in such protocols, usually
as a result of insufficient or misleading specifications. While it
is generally trivial to identify an algorithm that can satisfy the
interoperability requirements of a given transient numeric
identifier, empirical evidence exists that doing so without
negatively affecting the security and/or privacy properties of the
aforementioned protocols is prone to error [RFC9414].
For example, implementations have been subject to security and/or
privacy issues resulting from:
* predictable IPv4 or IPv6 Identification values (e.g., see
[Sanfilippo1998a], [RFC6274], and [RFC7739]),
* predictable IPv6 IIDs (e.g., see [RFC7217], [RFC7707], and
[RFC7721]),
* predictable transport-protocol ephemeral port numbers (e.g., see
[RFC6056] and [Silbersack2005]),
* predictable TCP Initial Sequence Numbers (ISNs) (e.g., see
[Morris1985], [Bellovin1989], and [RFC6528]),
* predictable initial timestamps in TCP timestamps options (e.g.,
see [TCPT-uptime] and [RFC7323]), and
* predictable DNS IDs (see, e.g., [Schuba1993] and [Klein2007]).
Recent history indicates that, when new protocols are standardized or
new protocol implementations are produced, the security and privacy
properties of the associated transient numeric identifiers tend to be
overlooked, and inappropriate algorithms to generate such identifiers
are either suggested in the specifications or selected by
implementers. As a result, advice in this area is warranted.
We note that the use of cryptographic techniques for confidentiality
and authentication might not eliminate all the issues associated with
predictable transient numeric identifiers. Therefore, due diligence
in the specification of transient numeric identifiers is required
even when cryptographic techniques are employed.
| NOTE: For example, cryptographic authentication can readily
| mitigate data injection attacks even in the presence of
| predictable transient numeric identifiers (such as "sequence
| numbers"). However, use of flawed algorithms (such as global
| counters) for generating transient numeric identifiers could
| still result in information leakages even when cryptographic
| techniques are employed. These information leakages could in
| turn be leveraged to perform other devastating attacks (please
| see [RFC9415] for further details).
Section 3 provides an overview of common flaws in the specification
of transient numeric identifiers. Section 4 provides an overview of
common flaws in the generation of transient numeric identifiers and
their associated security and privacy implications. Finally,
Section 5 provides key guidelines for protocol designers.
2. Terminology
Transient Numeric Identifier:
A data object in a protocol specification that can be used to
definitely distinguish a protocol object (a datagram, network
interface, transport-protocol endpoint, session, etc.) from all
other objects of the same type, in a given context. Transient
numeric identifiers are usually defined as a series of bits and
represented using integer values. These identifiers are typically
dynamically selected, as opposed to statically assigned numeric
identifiers (e.g., see [IANA-PROT]). We note that different
transient numeric identifiers may have additional requirements or
properties depending on their specific use in a protocol. We use
the term "transient numeric identifier" (or simply "numeric
identifier" or "identifier" as short forms) as a generic term to
refer to any data object in a protocol specification that
satisfies the identification property stated above.
Failure Severity:
The interoperability consequences of a failure to comply with the
interoperability requirements of a given identifier. Severity
considers the worst potential consequence of a failure, determined
by the system damage and/or time lost to repair the failure. In
this document, we define two types of failure severity: "soft" and
"hard".
Soft Failure:
A recoverable condition in which a protocol does not operate in
the prescribed manner but normal operation can be resumed
automatically in a short period of time. For example, a simple
packet-loss event that is subsequently recovered with a
retransmission can be considered a soft failure.
Hard Failure:
A non-recoverable condition in which a protocol does not operate
in the prescribed manner or it operates with excessive degradation
of service. For example, an established TCP connection that is
aborted due to an error condition constitutes, from the point of
view of the transport protocol, a hard failure, since it enters a
state from which normal operation cannot be recovered.
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.
3. Issues with the Specification of Transient Numeric Identifiers
Recent work on transient numeric identifier usage in protocol
specifications and implementations [RFC9414] [RFC9415] revealed that
most of the issues discussed in this document arise as a result of
one of the following conditions:
* protocol specifications that under specify their transient numeric
identifiers
* protocol specifications that over specify their transient numeric
identifiers
* protocol implementations that simply fail to comply with the
specified requirements
Both under specifying and over specifying transient numeric
identifiers is hazardous. TCP local ports [RFC793], as well as DNS
IDs [RFC1035], were originally under specified, leading to
implementations that resulted in predictable values and thus were
vulnerable to numerous off-path attacks. Over specification, as for
IPv6 Interface Identifiers (IIDs) [RFC4291] and IPv6 Identification
values [RFC2460], left implementations unable to respond to security
and privacy issues stemming from the mandated or recommended
algorithms -- IPv6 IIDs need not expose privacy-sensitive link-layer
addresses, and predictable IPv6 Fragment Header Identification values
invite the same off-path attacks that plague TCP.
Finally, there are protocol implementations that simply fail to
comply with existing protocol specifications. That is, appropriate
guidance is provided by the protocol specification (whether it be the
core specification or an update to it), but an implementation simply
fails to follow such guidance. For example, some popular operating
systems still fail to implement transport-protocol port
randomization, as specified in [RFC6056].
Clear specification of the interoperability requirements for the
transient numeric identifiers will help identify possible algorithms
that could be employed to generate them and also make evident if such
identifiers are being over specified. A protocol specification will
usually also benefit from a vulnerability assessment of the transient
numeric identifiers they specify to prevent the corresponding
considerations from being overlooked.
4. Common Flaws in the Generation of Transient Numeric Identifiers
This section briefly notes common flaws associated with the
generation of transient numeric identifiers. Such common flaws
include, but are not limited to:
* employing trivial algorithms (e.g., global counters) that result
in predictable identifiers,
* employing the same identifier across contexts in which constancy
is not required,
* reusing identifiers across different protocols or layers of the
protocol stack,
* initializing counters or timers to constant values when such
initialization is not required,
* employing the same increment space across different contexts, and
* use of flawed Pseudorandom Number Generators (PRNGs).
Employing trivial algorithms for generating the identifiers means
that any node that is able to sample such identifiers can easily
predict future identifiers employed by the victim node.
When one identifier is employed across contexts where such constancy
is not needed, activity correlation is made possible. For example,
employing an identifier that is constant across networks allows for
node tracking across networks.
Reusing identifiers across different layers or protocols ties the
security and privacy properties of the protocol reusing the
identifier to the security and privacy properties of the original
identifier (over which the protocol reusing the identifier may have
no control regarding its generation). Besides, when reusing an
identifier across protocols from different layers, the goal of
isolating the properties of a layer from those of another layer is
broken, and the vulnerability assessment may be harder to perform
since the combined system, rather than each protocol in isolation,
will have to be assessed.
At times, a protocol needs to convey order information (whether it be
sequence, timing, etc.). In many cases, there is no reason for the
corresponding counter or timer to be initialized to any specific
value, e.g., at system bootstrap. Similarly, there may not be a need
for the difference between successive counter values to be
predictable.
A node that implements a per-context linear function may share the
increment space among different contexts (please see the "Simple PRF-
Based Algorithm" section in [RFC9415]). Sharing the same increment
space allows an attacker that can sample identifiers in other context
to, e.g., learn how many identifiers have been generated between two
sampled values.
Finally, some implementations have been found to employ flawed PRNGs
(e.g., see [Klein2007]).
5. Requirements for Transient Numeric Identifiers
Protocol specifications that employ transient numeric identifiers
MUST explicitly specify the interoperability requirements for the
aforementioned transient numeric identifiers (e.g., required
properties such as uniqueness, along with the failure severity if
such requirements are not met).
A vulnerability assessment of the aforementioned transient numeric
identifiers MUST be performed as part of the specification process.
Such vulnerability assessment should cover, at least, spoofing,
tampering, repudiation, information disclosure, DoS, and elevation of
privilege.
| NOTE: Sections 8 and 9 of [RFC9415] provide a general
| vulnerability assessment of transient numeric identifiers,
| along with a vulnerability assessment of common algorithms for
| generating transient numeric identifiers. Please see
| [Shostack2014] for further guidance on threat modeling.
Protocol specifications SHOULD NOT employ predictable transient
numeric identifiers, except when such predictability is the result of
their interoperability requirements.
Protocol specifications that employ transient numeric identifiers
SHOULD recommend an algorithm for generating the aforementioned
transient numeric identifiers that mitigates the vulnerabilities
identified in the previous step, such as those discussed in
[RFC9415].
As discussed in Section 1, use of cryptographic techniques for
confidentiality and authentication might not eliminate all the issues
associated with predictable transient numeric identifiers.
Therefore, the advice from this section MUST still be applied for
cases where cryptographic techniques for confidentiality or
authentication are employed.
6. IANA Considerations
This document has no IANA actions.
7. Security Considerations
This entire document is about the security and privacy implications
of transient numeric identifiers and formally updates [RFC3552] such
that the security and privacy implications of transient numeric
identifiers are addressed when writing the "Security Considerations"
section of future RFCs.
8. References
8.1. Normative References
[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>.
[RFC3552] Rescorla, E. and B. Korver, "Guidelines for Writing RFC
Text on Security Considerations", BCP 72, RFC 3552,
DOI 10.17487/RFC3552, July 2003,
<https://www.rfc-editor.org/info/rfc3552>.
[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>.
8.2. Informative References
[Bellovin1989]
Bellovin, S., "Security Problems in the TCP/IP Protocol
Suite", Computer Communications Review, vol. 19, no. 2,
pp. 32-48, April 1989,
<https://www.cs.columbia.edu/~smb/papers/ipext.pdf>.
[IANA-PROT]
IANA, "Protocol Registries",
<https://www.iana.org/protocols>.
[Klein2007]
Klein, A., "OpenBSD DNS Cache Poisoning and Multiple O/S
Predictable IP ID Vulnerability", October 2007,
<https://dl.packetstormsecurity.net/papers/attack/OpenBSD_
DNS_Cache_Poisoning_and_Multiple_OS_Predictable_IP_ID_Vuln
erability.pdf>.
[Morris1985]
Morris, R., "A Weakness in the 4.2BSD UNIX TCP/IP
Software", CSTR 117, AT&T Bell Laboratories, Murray Hill,
NJ, February 1985,
<https://pdos.csail.mit.edu/~rtm/papers/117.pdf>.
[PREDICTABLE-NUMERIC-IDS]
Gont, F. and I. Arce, "Security and Privacy Implications
of Numeric Identifiers Employed in Network Protocols",
Work in Progress, Internet-Draft, draft-gont-predictable-
numeric-ids-03, 11 March 2019,
<https://datatracker.ietf.org/doc/html/draft-gont-
predictable-numeric-ids-03>.
[RFC791] Postel, J., "Internet Protocol", STD 5, RFC 791,
DOI 10.17487/RFC791, September 1981,
<https://www.rfc-editor.org/info/rfc791>.
[RFC793] Postel, J., "Transmission Control Protocol", RFC 793,
DOI 10.17487/RFC793, September 1981,
<https://www.rfc-editor.org/info/rfc793>.
[RFC1035] Mockapetris, P., "Domain names - implementation and
specification", STD 13, RFC 1035, DOI 10.17487/RFC1035,
November 1987, <https://www.rfc-editor.org/info/rfc1035>.
[RFC2460] Deering, S. and R. Hinden, "Internet Protocol, Version 6
(IPv6) Specification", RFC 2460, DOI 10.17487/RFC2460,
December 1998, <https://www.rfc-editor.org/info/rfc2460>.
[RFC4291] Hinden, R. and S. Deering, "IP Version 6 Addressing
Architecture", RFC 4291, DOI 10.17487/RFC4291, February
2006, <https://www.rfc-editor.org/info/rfc4291>.
[RFC5905] Mills, D., Martin, J., Ed., Burbank, J., and W. Kasch,
"Network Time Protocol Version 4: Protocol and Algorithms
Specification", RFC 5905, DOI 10.17487/RFC5905, June 2010,
<https://www.rfc-editor.org/info/rfc5905>.
[RFC6056] Larsen, M. and F. Gont, "Recommendations for Transport-
Protocol Port Randomization", BCP 156, RFC 6056,
DOI 10.17487/RFC6056, January 2011,
<https://www.rfc-editor.org/info/rfc6056>.
[RFC6274] Gont, F., "Security Assessment of the Internet Protocol
Version 4", RFC 6274, DOI 10.17487/RFC6274, July 2011,
<https://www.rfc-editor.org/info/rfc6274>.
[RFC6528] Gont, F. and S. Bellovin, "Defending against Sequence
Number Attacks", RFC 6528, DOI 10.17487/RFC6528, February
2012, <https://www.rfc-editor.org/info/rfc6528>.
[RFC7217] Gont, F., "A Method for Generating Semantically Opaque
Interface Identifiers with IPv6 Stateless Address
Autoconfiguration (SLAAC)", RFC 7217,
DOI 10.17487/RFC7217, April 2014,
<https://www.rfc-editor.org/info/rfc7217>.
[RFC7258] Farrell, S. and H. Tschofenig, "Pervasive Monitoring Is an
Attack", BCP 188, RFC 7258, DOI 10.17487/RFC7258, May
2014, <https://www.rfc-editor.org/info/rfc7258>.
[RFC7323] Borman, D., Braden, B., Jacobson, V., and R.
Scheffenegger, Ed., "TCP Extensions for High Performance",
RFC 7323, DOI 10.17487/RFC7323, September 2014,
<https://www.rfc-editor.org/info/rfc7323>.
[RFC7707] Gont, F. and T. Chown, "Network Reconnaissance in IPv6
Networks", RFC 7707, DOI 10.17487/RFC7707, March 2016,
<https://www.rfc-editor.org/info/rfc7707>.
[RFC7721] Cooper, A., Gont, F., and D. Thaler, "Security and Privacy
Considerations for IPv6 Address Generation Mechanisms",
RFC 7721, DOI 10.17487/RFC7721, March 2016,
<https://www.rfc-editor.org/info/rfc7721>.
[RFC7739] Gont, F., "Security Implications of Predictable Fragment
Identification Values", RFC 7739, DOI 10.17487/RFC7739,
February 2016, <https://www.rfc-editor.org/info/rfc7739>.
[RFC8200] Deering, S. and R. Hinden, "Internet Protocol, Version 6
(IPv6) Specification", STD 86, RFC 8200,
DOI 10.17487/RFC8200, July 2017,
<https://www.rfc-editor.org/info/rfc8200>.
[RFC9293] Eddy, W., Ed., "Transmission Control Protocol (TCP)",
STD 7, RFC 9293, DOI 10.17487/RFC9293, August 2022,
<https://www.rfc-editor.org/info/rfc9293>.
[RFC9414] Gont, F. and I. Arce, "Unfortunate History of Transient
Numeric Identifiers", RFC 9414, DOI 10.17487/RFC9414, July
2023, <https://www.rfc-editor.org/info/rfc9414>.
[RFC9415] Gont, F. and I. Arce, "On the Generation of Transient
Numeric Identifiers", RFC 9415, DOI 10.17487/RFC9415, July
2023, <https://www.rfc-editor.org/info/rfc9415>.
[Sanfilippo1998a]
Sanfilippo, S., "about the ip header id", message to the
Bugtraq mailing list, December 1998,
<https://seclists.org/bugtraq/1998/Dec/48>.
[Schuba1993]
Schuba, C., "Addressing Weakness in the Domain Name System
Protocol", August 1993,
<http://ftp.cerias.purdue.edu/pub/papers/christoph-schuba/
schuba-DNS-msthesis.pdf>.
[Shostack2014]
Shostack, A., "Threat Modeling: Designing for Security",
Wiley, 1st edition, February 2014.
[Silbersack2005]
Silbersack, M., "Improving TCP/IP security through
randomization without sacrificing interoperability",
EuroBSDCon 2005 Conference, January 2005,
<http://www.silby.com/eurobsdcon05/
eurobsdcon_silbersack.pdf>.
[TCPT-uptime]
McDanel, B., "TCP Timestamping - Obtaining System Uptime
Remotely", message to the Bugtraq mailing list, March
2001, <https://seclists.org/bugtraq/2001/Mar/182>.
Acknowledgements
The authors would like to thank (in alphabetical order) Bernard
Aboba, Brian Carpenter, Roman Danyliw, Theo de Raadt, Lars Eggert,
Russ Housley, Benjamin Kaduk, Charlie Kaufman, Erik Kline, Alvaro
Retana, Joe Touch, Michael Tüxen, Robert Wilton, and Paul Wouters for
providing valuable comments on draft versions of this document.
The authors would like to thank (in alphabetical order) Steven
Bellovin, Joseph Lorenzo Hall, and Gre Norcie for providing valuable
comments on [PREDICTABLE-NUMERIC-IDS], on which the present document
is based.
The authors would like to thank Diego Armando Maradona for his magic
and inspiration.
Authors' Addresses
Fernando Gont
SI6 Networks
Segurola y Habana 4310 7mo piso
Ciudad Autonoma de Buenos Aires
Argentina
Email: fgont@si6networks.com
URI: https://www.si6networks.com
Ivan Arce
Quarkslab
Segurola y Habana 4310 7mo piso
Ciudad Autonoma de Buenos Aires
Argentina
Email: iarce@quarkslab.com
URI: https://www.quarkslab.com