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This document contains recommendations on how Internet Service Providers can manage the effects of computers used by their subscribers, which have been infected with malicious bots, via various remediation techniques. Internet users with infected computers are exposed to risks such as loss of personal data, as well as increased susceptibility to online fraud and/or phishing. Such computers can also become an inadvertent participant in or component of an online crime network, spam network, and/or phishing network, as well as be used as a part of a distributed denial of service attack. Mitigating the effects of and remediating the installations of malicious bots will make it more difficult for botnets to operate and could reduce the level of online crime on the Internet in general and/or on a particular Internet Service Provider's network.
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Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than as “work in progress.”
This Internet-Draft will expire on December 8, 2010.
Copyright (c) 2010 IETF Trust and the persons identified as the document authors. All rights reserved.
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1.
Requirements Language
2.
Key Terminology
3.
Introduction and Problem Statement
4.
Important Notice of Limitations and Scope
5.
Detection of Bots
6.
Notification to Internet Users
7.
Remediation of Hosts Infected with a Bot
8.
Guided Remediation Process
9.
Professionally-Assisted Remediation Process
10.
Sharing of Data from the User to the ISP
11.
Security Considerations
12.
IANA Considerations
13.
Acknowledgements
14.
Informative references
Appendix A.
Document Change Log
Appendix B.
Open Issues
§
Authors' Addresses
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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 [RFC2119] (Bradner, S., “Key words for use in RFCs to Indicate Requirement Levels,” March 1997.).
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This section defines the key terms used in this document.
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A malicious or potentially malicious "bot" (derived from the word "robot", hereafter simply referred to as a "bot") refers to a program that is installed on a system in order to enable that system to automatically (or semi-automatically) perform a task or set of tasks typically under the command and control of a remote administrator, or "bot master". Bots are also known as "zombies". Such bots may have been installed surreptitiously, without the user's full understanding of what the bot will do once installed, unknowingly as part of another software installation, under false pretenses, and/or in a variety of other possible ways.
It is important to note that there are 'good', or benign bots. Such benign bots are often found in such environments such as gaming and Internet Relay Chat (IRC) [RFC1459] (Oikarinen, J. and D. Reed, “Internet Relay Chat Protocol,” May 1993.), where a continual, interactive presence can be a requirement for participating in the games, interacting with a computing resource. Since such benign bots are performing useful, lawful, and non-disruptive functions, there is no reason for a provider to monitor for their presence and/or alert users to their presence.
Thus, while there may be benign, or harmless bots, for the purposes of this document all mention of bots shall assume that the bots involved are malicious or potentially malicious in nature. Such malicious bots shall generally be assumed to have been deployed without the permission or conscious understanding of a particular Internet user. Thus, without a user's knowledge, bots may transform the user's computing device into a platform from which malicious activities can be conducted. In addition, included explicitly in this category are potentially malicious bots, which may initially appear neutral but may simply be waiting for remote instructions to transform and/or otherwise begin engaging in malicious behavior. In general, installation of a malicious bot without user knowledge and consent is considered in most regions to be unlawful, and the activities of malicious bots typically involve unlawful or other maliciously disruptive activities.
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These are defined as concerted networks of bots capable of acting on instructions generated remotely. The malicious activities are either focused on the information on the local machine or acting to provide services for remote machines. Bots are highly customizable so they can be programmed to do many things. The major malicious activities include but are not limited to: identity theft, spam, spim (spam over instant messaging), spit (spam over Internet telephony), email address harvesting, distributed denial of service (DDoS) attacks, key-logging, fraudulent DNS pharming (redirection), hosting proxy services, fast flux hosting, hosting of illegal content, use in man-in-the-middle attacks, and click fraud.
Infection vectors include un-patched operating systems, software vulnerabilities (which include so-called zero-day vulnerabilities where no patch yet exists), weak/non-existent passwords, malicious websites, un-patched browsers, malware, vulnerable helper applications and social engineering techniques to gain access to the user's computer. The detection and destruction of bots is an ongoing issue and also a constant battle between the internet security community, network security engineers and bot developers.
Initially, some bots used IRC to communicate but were easy to shutdown if the command and control server was identified and deactivated. Newer command and control methods have evolved, such that those currently employed by bot masters make them much more resistant to deactivation. With the introduction of P2P, HTTP and other resilient communication protocols along with the widespread adoption of encryption, bots are considerably more difficult to identify and isolate from typical network usage. As a result increased reliance is being placed on anomaly detection and behavioral analysis, both locally and remotely, to identify bots.
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An end user's host, or computer, as used in the context of this document, is intended to refer to a computing device that connects to the Internet. This encompasses devices used by Internet users such as personal computers, including laptops, desktops, and netbooks, as well as mobile phones, smart phones, home gateway devices, and other end user computing devices which are connected or can connect to the public Internet and/or private IP networks.
Increasingly, other household systems and devices contain embedded hosts which are connected to or can connect to the public Internet and/or private IP networks. However, these devices may not be under interactive control of the Internet user, such as may be the case with various smart home and smart grid devices.
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This is short for malicious software. In this case, malicious bots are considered a subset of malware. Other forms of malware could include viruses and other similar types of software. Internet users can sometimes cause their host to be infected with malware, which may include a bot or cause a bot to install itself, via inadvertently accessing a specific website, downloading a file, or other activities.
In other cases, Internet-connected hosts may become infected with malware through externally initiated malicious activities such as the exploitation of vulnerabilities or the brute force guessing of access credentials.
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DNS Fast Fluxing occurs when a domain is bound in DNS using A records to multiple IP addresses, each of which has a very short Time To Live (TTL) value associated with it. This means that the domain resolves to varying IP addresses over a short period of time.
DNS Fast Flux is typically used in conjunction with proxies which then route the web requests to the real host which serves the data being sought. The proxies are normally run on compromised user hosts. The effect of this is to make the detection of the real host much more difficult and to ensure that the backend or hidden site remains up for as long as possible.
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Hosts used by Internet users, which in this case are customers of an Internet Service Provider (ISP), can be infected with malware which may contain and/or install one or more bots on a host. They can present a major problem for an ISP for a number of reasons (not to mention of course the problems created for users). First, these bots can be used to send spam, in some cases very large volumes of spam [Spamalytics: An Empirical Analysis of Spam Marketing Conversion] (Kanich, C., Kreibich, C., Levchenko, K., Enright, B., Voelker, G., Paxson, V., and S. Savage, “Spamalytics: An Empirical Analysis of Spam Marketing Conversion,” October 2008.). This spam can result in extra cost for the ISPs in terms of wasted network, server, and/or personnel resources, among many other potential costs and side effects. Such spam can also negatively affect the reputation of the ISP, their customers, and the email reputation of the IP address space used by the ISP (often referred to simply as 'IP reputation').
In addition, these bots can act as platforms for directing, participating in, or otherwise conducting attacks on critical Internet infrastructure [Emerging Cyber Threats Report for 2009: Data, Mobility and Questions of Responsibility will Drive Cyber Threats in 2009 and Beyond] (Ahamad, M., Amster, D., Barret, M., Cross, T., Heron, G., Jackson, D., King, J., Lee, W., Naraine, R., Ollman, G., Ramsey, J., Schmidt, H., and P. Traynor, “Emerging Cyber Threats Report for 2009: Data, Mobility and Questions of Responsibility will Drive Cyber Threats in 2009 and Beyond,” October 2008.). Bots are frequently used as part of coordinated Distributed Denial of Service (DDoS) attacks for criminal, political or other motivations [The Gh0st in the Shell: Network Security in the Himalayas] (Vallentin, M., Whiteaker, J., and Y. Ben-David, “The Gh0st in the Shell: Network Security in the Himalayas,” February 2010.) [The snooping dragon: social‑malware surveillance of the Tibetan movement] (Nagaraja, S. and R. Anderson, “The snooping dragon: social-malware surveillance of the Tibetan movement,” March 2009.). For example, bots have been used to attack Internet resources and infrastructure ranging from web sites, to email servers and DNS servers, as well as the critical Internet infrastructure of entire countries [Battling Botnets and Online Mobs: Estonia's Defense Efforts during the Internet War] (Evron, G., “Battling Botnets and Online Mobs: Estonia's Defense Efforts during the Internet War,” May 2005.) [Cyberspace as a Combat Zone: The Phenomenon of Electronic Jihad] (Alshech, E., “Cyberspace as a Combat Zone: The Phenomenon of Electronic Jihad,” February 2007.). Motivations for such coordinated DDoS attacks can range from criminal extortion attempts through to online protesting and nationalistic fervor [Case Study: How a Bookmaker and a Whiz Kid Took On a DDOS‑based Online Extortion Attack] (Berinato, S., “Case Study: How a Bookmaker and a Whiz Kid Took On a DDOS-based Online Extortion Attack,” May 2005.).
While any computing device can be infected with bots, the majority of bot infections affect the personal computers used by Internet end users. As a result of the role of ISPs in providing IP connectivity, among many other services, to Internet users, these ISPs are in a unique position to be able to attempt to detect and observe bot nets operating in their networks. Furthermore, ISPs may also be in a unique position to be able to notify their customers of actual, potential, or likely infection by bots or other infection.
From end users perspective, being notified that they may have an infected computer on their network is important information. Once they know this, they can take steps to remove the bots, resolve any problems which may stem from the bot infection, and protect themselves againts future threats. Given that bots can consume vast amounts of local computing and network resources, enable theft of personal information (including personal financial information), enable the host to be used for criminal activities (that may result in the Internet user being legally culpable), destroy or leave the host in an unrecoverable state via 'kill switch' bot technologies, it is important to notify the user that they may be infected with a bot.
As a result, the intent of this document is to provide guidance to ISPs and other organizations for the remediation of hosts infected with bots, so as to reduce the size of bot nets and minimize the potential harm that bots can inflict upon Internet infrastructure generally, as well as on individual Internet users. Efforts by ISPs and other organizations can, over time, reduce the pool of hosts infected with bots on the Internet, which in turn could result in smaller bot nets with less capability for disruption.
The potential mitigation of bots is accomplished through a process of detection, notification to Internet users, and remediation of bot infections with a variety of tools, as described later in this document.
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The techniques described in this document in no way guarantee the remediation of all bots. Bot removal is potentially a task requiring specialized knowledge, skills and tools, and may be beyond the ability of average users. Attempts at bot removal may frequently be unsuccessful, or only partially successful, leaving the user's system in an unstable and unsatisfactory state or even in a state where it is still infected. Attempts at bot removal can result in side effects ranging from a loss of data to partial or complete loss of system usability.
In general, the only way a user can be sure they have removed some of today's increasingly sophisticated malware is by 'nuking-and-paving' the system: reformatting the drive, reinstalling the operating system and applications (including all patches) from scratch, and then restoring user files from a known clean backup. However the introduction of persistent memory based malware may mean that, in some cases, this may not be enough and may prove to be more than any end user can be reasonably expected to resolve [Persistent Memory Infection] (Sacco, A. and A. Ortega, “Persistent BIOS Infection,” March 2009.). Experienced users would have to re-flash or re-image persistent memory sections or components of their hosts in order to remove persistent memory based malware. However, in some cases, not even 'nuking-and-paving' the system will solve the problem, which calls for hard drive replacement and/or complete replacement of the host.
Devices with embedded operating systems, such as video gaming consoles and smart home appliances, will most likely be beyond a user's capability to remediate by themselves, and could therefore require the aid of vendor-specific advice, updates and tools. However, in some cases, such devices will have a function or switch to enable the user to reset that device to a factory default configuration, which may in some cases enable the user to remediate the infection. Care must be taken when imparting remediation advice to Internet users given the increasingly wide array of computing devices that can be, or could be, infected by bots in the future.
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An ISP must first identify that an Internet user, in this case a user that is assumed to be their customer or otherwise connected to the ISP's network, is determined to be infected, or likely to have been infected with a bot. The ISP must attempt to detect the presence of bots using methods, processes, and tools which maintain the privacy of the personally identifiable information (PII) of their customers. The ISP must not block legitimate traffic in the course of bot detection, and must instead employ detection methods, tools, and processes which seek to be non-disruptive, and transparent to Internet users and end-user applications.
Detection methods, tools, and processes may include analysis of specific network and/or application traffic flows (such as traffic to an email server), analysis of aggregate network and/or application traffic data, data feeds received from other ISPs and organizations (such as lists of the ISP's IP addresses which have been reported to have sent spam), feedback from the ISP's customers or other Internet users, as well as a wide variety of other possibilities. In practice, it has proven effective to validate a bot infect through the use of a combination of multiple bot detection data points. This can help to corroborate information of varying dependability or consistency, as well as to avoid or minimize the possibility of false positive identification of hosts. Detection should also, where possible and feasible, attempt to classify the specific bot infection type in order to confirm that it is malicious in nature, estimate the variety and severity of threats it may pose (such as spam bot, key-logging bot, file distribution bot, etc.), and to determine potential methods for eventual remediation. However, given the dynamic nature of botnet management and the criminal incentives to seek quick financial rewards, botnets frequently update or change their core capabilities. As a consequence, botnets that are initially detected and classified by the ISP as one particular type of bot need to be continuously monitored and tracked in order to correctly identify the threat the botnet poses at any particular point in time.
Detection is also time-sensitive. If complex analysis is required and multiple confirmations are needed to verify a bot is indeed present, then it is possible that the bot may cause some damage (to either the infected host or a remotely targeted system) before it can be stopped. This means that an ISP needs to balance the desire or need to definitively classify and/or confirm the presence of a bot, which may take an extended period of time, with the ability to predict the likelihood of a bot in a very short period of time. Such determinations have a relatively low false positive rate in order to maintain the trust of users. This 'definitive-vs-likely' challenge is difficult and, when in doubt, ISPs should err on the side of caution by communicating that a bot infection has taken place. This also means that Internet users may benefit from the installation of client-based software on their host. This can enable rapid performance of heuristically-based detection of bot activity, such as the detection of a bot as it starts to communicate with other botnets and execute commands. Any bot detection system should also be capable of adapting, either via manual intervention or automatically, in order to cope with a rapidly evolving threat.
As noted above, detection methods, tools, and processes should ensure that privacy of customers' PII is maintained. While bot detection methods, tools, and processes are similar to spam and virus defenses deployed by the ISP for the benefit of their customers (and may be directly related to those defenses), attempts to detect bots should take into account the need of an ISP to take care to ensure any PII collected or incidentally detected is properly protected. This is important, as just as spam defenses may involve scanning the content of email messages, which may contain PII, then so to may bot defenses similarly come into incidental contact with PII. The definition of PII varies from one jurisdiction to the next so proper care must be taken to ensure that any actions taken comply with legislation and good practice in the jurisdiction in which the PII is gathered. Finally, depending upon the geographic region within which an ISP operates, certain methods relating to bot detection may need to be included in relevant terms of service documents or other documents which are available to the customers of a particular ISP.
There are several bot detection methods, tools, and processes that an ISP may choose to utilize, as noted in the list below. It is important to note that the technical solutions available are relatively immature, and are likely to change over time, evolving rapidly in the coming years. While these items are described in relation to ISPs, they may also be applicable to organizations operating other networks, such as campus networks and enterprise networks.
- a.
- Where legally permissible or otherwise an industry accepted practice in a particular market region, an ISP may in some manner "scan" their IP space in order to detect un-patched or otherwise vulnerable hosts, or to detect the signs of infection. This may provide the ISP with the opportunity to easily identify Internet users who appear to already be infected or are at great risk of being infected with a bot. ISPs should note that some types of port scanning may leave network services in a hung state or render them unusable due to common frailties, and that many modern firewall and host-based intrusion detection implementations may alert the Internet user to the scan. As a result the scan may be interpreted as a malicious attack against the host. Vulnerability scanning has a higher probability of leaving accessible network services and applications in a damaged state and will often result in a higher probability of detection by the Internet user and subsequent interpretation as a targeted attack. Depending upon the vulnerability for which an ISP may be scanning, some automated methods of vulnerability checking may result in data being altered or created afresh on the Internet user's host which can be a problem in many legal environments. It should also be noted that due to the prevalence of Network Address Translation devices, Port Address Translation devices, and/or firewall devices in user networks, network-based vulnerability scanning may be of limited value. Thus, while we note that this is one technique which may be utilized, it is unlikely to be particularly effective and it has problematic side effects, which leads the authors to recommend against the use of this particular method.
- b.
- An ISP may also communicate and share selected data, via feedback loops or other mechanisms, with various third parties. Feedback loops are consistently formatted feeds of real-time (or nearly real-time) abuse reports offered by threat data clearinghouses, security alert organizations, other ISPs, and other organizations. The data may include, but is not limited to, IP addresses of hosts which have or are likely infected, IP addresses, domain names or fully qualified domain names (FQDNs) known to host malware and/or be involved in the command and control of botnets, recently tested or discovered techniques for detecting or remediating bot infections, new threat vectors, and other relevant information. A few good examples of data sharing include SNDS from Microsoft, XBL and PBL from Spamhaus, the DSHIELD AS tool from the SANS Institute.
- c.
- An ISP may use Netflow [RFC3954] (Claise, B., “Cisco Systems NetFlow Services Export Version 9,” October 2004.) or other similar passive network monitoring to identify network anomalies that may be indicative of botnet attacks or bot communications. For example, an ISP may be able to identify compromised hosts by identifying traffic destined to IP addresses associated with the command and control of botnets, or destined to the combination of an IP address and control port associated with a command and control network (sometimes command and control traffic comes from a host which has legitimate traffic). In addition, bots may be identified when a remote host is under a DDoS attack, because hosts participating in the attack will likely be infected by a bot, frequently as observed at network borders (though ISPs should beware of source IP address spoofing techniques to avoid or confuse detection).
- d.
- An ISP may use DNS-based techniques to perform detection. For example, a given classified bot may be known to query a specific list of domain names at specific times or on specific dates (in the example of the so-called "Conficker" bot), often by matching DNS queries to a well known list of domains associated with malware. In many cases such lists are distributed by or shared using third parties, such as threat data clearinghouses.
- e.
- User complaints: Because hosts infected by bots are frequently used to send spam or participate in DDoS attacks, the ISP servicing those hosts will normally receive complaints about the malicious network traffic. Those complaints may be sent to RFC2142-specified [RFC2142] (Crocker, D., “MAILBOX NAMES FOR COMMON SERVICES, ROLES AND FUNCTIONS,” May 1997.) role accounts, such as abuse@, or to other relevant addresses such as to abuse or security addresses specified by the site as part of its WHOIS (or other) contact data.
- f.
- ISPs may also discover likely bot infected hosts located on other networks. Thus, when legally permissible in a particular market region, it may be worthwhile for ISPs to share information relating to those compromised hosts with the relevant remote network operator, with security researchers, and with blocklist operators.
- g.
- ISPs may operate or subscribe to services that provide 'sinkholing' or 'honeynet' capabilities. This may enable the ISP to obtain near-real-time lists of bot infected hosts as they attempt to join a larger botnet or propagate to other hosts on a network.
- h.
- ISP industry associations should examine the possibility of collating statistics from ISP members in order to provide good statistics about bot infections based on real ISP data.
- i.
- An Intrusion Detection System(IDS) can be a useful tool to actually help identify the malware. An IDS tool such as SNORT (open source IDS platform) can be placed in a Walled Garden and used to analyze end user traffic to confirm malware type. This will help with remediation of the infected device.
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Once an ISP has detected a bot, or the strong likelihood of a bot, steps should be undertaken to inform the Internet user that they may have a bot-related problem. Depending upon a range of factors, from the technical capabilities of the ISP, to the technical attributes of their network, financial considerations, available server resources, available organizational resources, the number of likely infected hosts detected at any given time, and the severity of any possible threats, among other things, an ISP should decide the most appropriate method or methods for providing notification to one or more of their customers or Internet users. Such notification methods may include one or more of the following, as well as other possible methods not described below.
It is important to note that none of these methods are guaranteed to be one-hundred percent successful, and that each has its own set of limitations. In addition, in some cases, an ISP may determine that a combination of two or more methods is most appropriate and effective, and reduces the chance that malware may block a notification. As such, the authors recommend the use of multiple notification methods. Finally, notification is also considered time sensitive; if the user does not receive or view the notification or a timely basis, then a particular bot could launch an attack, exploit the user, or cause other harm. If possible, an ISP should establish a preferred means of communication when the subscriber first signs up for service. As a part of the notification process, ISPs should maintain a record of the allocation of IP addresses to subscribers for such a period as allows any commonly used bot detection technology to be able to accurately link an infected IP address to a subscriber. This record should only be maintained for a period of time which is necessary, in order to maintain the protection of the privacy of an individual subscriber.
One important factor to bear in mind is that notification to end users needs to be resistant to potential spoofing. This must be done to protect, as reasonably as possible, against the potential of legitimate notifications being spoofed and/or used by parties with intent to perform additional malicious attacks against victims of malware, or even to deliver additional malware.
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This is a common form of notification used by ISPs. One drawback of using email is that it is not guaranteed to be viewed within a reasonable time frame, if at all. The user may be using a different primary email address than that which they have provided to the ISP. In addition, some ISPs do not provide an email account at all, as part of a bundle of Internet services, and/or do not have a need for or method in which to request or retain the primary email addresses of Internet users of their networks. Another possibility is that the user, their email client, and/or their email servers could determine or classify such a notification as spam, which could delete the message or otherwise file it in an email folder that the user may not check on a regular and/or timely basis. Bot masters have also been known to impersonate the ISP or trusted sender and send fraudulent emails to the users. This technique of social engineering often leads to new bot infestations. Finally if the user's email credentials are compromised, then a hacker and/or a bot could simply access the user's email account and delete the email before it is read by the user.
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A telephone call may be an effective means of communication in particularly high-risk situations. However, telephone calls may not be feasible due to the cost of making a large number of calls, as measured in either time, money, organizational resources, server resources, or some other means. In addition, there is no guarantee that the user will answer their phone. To the extent that the telephone number called by the ISP can be answered by the infected computing device, the bot on that host may be able to disconnect, divert, or otherwise interfere with an incoming call. Users may also interpret such a telephone notification as a telemarketing call and as such not welcome it, or not accept the call at all. Finally, even if a representative of the ISP is able to connect with and speak to a user, that user is very likely to lack the necessary technical expertise to understand or be able to effectively deal with the threat.
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This form of notification is probably the least popular and effective means of communication, due to both preparation time, delivery time, the cost of printing and paper, and the cost of postage.
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Placing a user in a walled garden is another approach that ISPs may take to notify users. A walled garden refers to an environment that controls the information and services that a subscriber is allowed to utilize and what network access permissions are granted. A walled garden implementation can range from strict to leaky. In a strict walled garden environment access to most Internet resources are typically limited by the ISP. In contrast a leaky walled garden environment permits access to all Internet resources except those deemed malicious or service and resources that can be used to notify the users.
Walled gardens are effective because it is possible to notify the user and simultaneously block all communication between the bot and the command and control channel. While in many cases the user is almost guaranteed to view the notification message and take any appropriate remediation actions, this approach can pose other challenges. For example, it is not always the case that a user is actively using a host that uses a web browser or which has a web browser actively running on it, or that uses another application which uses ports which are redirected to the walled garden. In one example, a user could be playing a game online, via the use of a dedicated, Internet-connected game console. In another example, the user may not be using a host with a web browser when they are placed in the walled garden and may instead be in the course of a telephone conversation, or may be expecting to receive a call, using a Voice Over IP (VoIP) device of some type. As a result, the ISP may feel the need to maintain a potentially lengthy white list of domains which are not subject to the typical restrictions of a walled garden, which could well prove to be an onerous task, from an operational perspective.
For these reasons the implementation of a leaky walled garden makes more sense but a leaky walled garden has different set of drawbacks. The ISP has to assume that the user will eventually use a web browser to acknowledge the notification other wise the user will remain in the walled garden and not know it. If the intent of the leaky walled garden is to solely notify the user about the bot infection then the leaky walled garden is not ideal because notification is time sensitive and the user may not receive the notification until the user invokes a request for the targeted service and/or resource. This means the bot can potentially do more damage. Additionally, the ISP has to identify which services and/or resources to restrict for the purposes of notification. This does not have to be resource specific and can be time based and or policy based. For example show notification for all HTTP requests every 10 minutes or show the notification for one in five HTTP requests.
The ISP has several options to determine when to let the user out of the walled garden. One approach may be to let the user determine when to exit. This option is suggested when the primary purpose of the walled garden is to notify users and provide information on remediation only, particularly since notification is not a guarantee of successful remediation. It could also be the case that, for whatever reason, the user makes the judgment that they cannot then take the time to remediate their host and that other online activities which they would like to resume are more important. Exit from the walled garden may also involve a process to verify that it is indeed the user who is requesting exit from the walled garden and not the bot.
Once the user acknowledges the notification, they may decide to either remediate and exit the walled garden or to exit the walled garden without remediating the issue. Another approach may be to enforce a stricter policy and require the user to clean the host prior to permitting the user to exit the walled garden, though this may not be technically feasible depending upon the type of bot, obfuscation techniques employed by a bot, and/or a range of other factors. Thus, the ISP may also need to support tools to scan the infected host (in the style of a virus scan, rather than a port scan) and determine whether it is still infected or rely on user judgment that the bot has been disabled or removed. One challenge with this approach is that if the user has multiple hosts sharing a single IP address, such as via a common home gateway device which performs Network Address Translation (NAT). In such a case, the ISP may need to determine from user feedback, or other means, that all affected hosts have been remediated, which may or may not be technically feasible.
Finally, when a walled garden is used, a list of well-known addresses for both operating system vendors and security vendors should be created and maintained in a white list which permits access to these sites. This can be important for allowing access from the walled garden by end users in search of operating system and application patches.
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Instant messaging provides the ISP with a simple means to communicate with the user. There are several advantages to using Instant Messaging (IM) which makes it an attractive option. If the ISP provides IM service and the user subscribes to it, then the user can be notified easily. IM-based notification can be a cost effective means to communicate with users automatically from an IM alert system or via a manual process, by the ISP's support staff. Ideally, the ISP should allow the user to register their IM identity in an ISP account management system and grant permission to be contacted via this means. If the IM service provider supports off-line messaging, then the user can be notified regardless of whether they are currently logged into the IM system.
There are several drawbacks with this communications method. There is a high probability that subscriber may interpret the communication to be spim, and as such ignore it. Also, not every user uses IM and/or the user may not provide their IM identity to the ISP so some alternative means have to be used. Even in those cases where a user does have an IM address, they may not be signed onto that IM system when the notification is attempted. There may be a privacy concern on the part of users, when such an IM notification must be transmitted over a third-party network and/or IM service. As such, should this method be used, the notification should be discreet and not include any PII in the notification itself.
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SMS allows the ISP send a brief description of the problem to notify the user of the issue, typically to a mobile device such as a mobile phone or smart phone. Ideally, the ISP should allow the user to register their mobile number and/or SMS address in an ISP account management system and grant permission to be contacted via this means. The primary advantage of SMS is that users are familiar with receiving text messages and are likely to read them. However, users may not act on the notification immediately if they are not in front of their host at the time of the SMS notification.
One disadvantage is that ISPs may have to follow up with an alternate means of notification if not all of the necessary information maybe conveyed in one message, given constraints on the number of characters in an individual message (typically 140 characters). Another disadvantage with SMS is the cost associated with it. The ISP has to either build its own SMS gateway to interface with the various wireless network service providers or use a third-party SMS clearinghouse (relay) to notify users. In both cases an ISP may incur fees related to SMS notifications, depending upon the method used to send the notifications. An additional downside is that SMS messages sent to a user may result in a charge to the user by their wireless provider, depending upon the plan to which they subscribe. Another minor disadvantage is that it is possible to notify the wrong user if the intended user changes their mobile number but forgets to update it with the ISP.
There are several other drawbacks with this communications method. There is a high probability that subscriber may interpret the communication to be spam, and as such ignore it. Also, not every user uses SMS and/or the user may not provide their SMS address or mobile number to the ISP. Even in those cases where a user does have an SMS address or mobile number, their device may not be powered on or otherwise available on a wireless network when the notification is attempted. There maybe also be a privacy concern on the part of users, when such an SMS notification must be transmitted over a third-party network and/or SMS clearinghouse. As such, should this method be used, the notification should be discreet and not include any PII in the notification itself.
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Near real-time notification to the user's web browser is another technique that may be utilized for notifying the user, though how such a system might operate is outside the scope of this document. Such a notification could have a comparative advantage over a walled garden notification, in that it does not restrict traffic to a specified list of destinations in the same way that a walled garden by definition would. However, as with a walled garden notification, there is no guarantee that a user is at any given time making use of a web browser, though such a system could certainly provide a notification when such a browser is eventually used. Compared to a walled garden, a web browser notification is probably preferred from the perspective of Internet users, as it does not have the risk of disrupting non-web sessions, such as online games, VoIP calls, etc. (as noted in Section 6.4 (Walled Garden Notification)).
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Delivering a notification to a location that provides a shared public network, such as a train station, public square, coffee shop, or similar location may be of low value since the users connecting to such networks are typically highly transient and generally not know to site or network administrators. For example, a system may detect that a host on such a network has a bot, but by the time a notification is generated that user has departed from the network and moved elsewhere.
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Delivering a notification to a location that Internet access routed through one or more shared public IP addresses may be of low value since it may be quite difficult to differentiate between users when providing a notification. For example, on a business network of 500 users, all sharing one public IP address, it may be sub-optimal to provide a notification to all 500 users if you only need one specific user to be notified and take action. As a result, such networks may find value in establishing a localized bot detection and notification system, just as they are likely to also establish other localized systems for security, file sharing, email, and so on.
However, should an ISP implement some form of notification to such networks, it may be better to simply send notifications to a designated network administrator at the site. In such a case the local network administrator may like to receive additional information in such a notification, such as a date and timestamp, the source port of the infected system, and malicious sites and ports that may have been visited.
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This section covers the different options available to remediate a host, which means to remove, disable, or otherwise render a bot harmless. Prior to this step, an ISP has detected the bot, notified the user that one of their hosts is infected with a bot, and now may provide some recommended means to clean the host. The generally recommended approach is to provide the necessary tools and education to the user so that they may perform bot remediation themselves, particularly given the risks and difficulties inherent in attempting to remove a bot.
For example, this may include the creation of a special web site with security-oriented content that is dedicated for this purpose. This should be a well-publicized security web site to which a user with a bot infection can be directed to for remediation. This security web site should clearly explain why the user was notified and may include an explanation of what bots are, and the threats that they pose. There should be a clear explanation of the steps that the user should take in order to attempt to clean their host and provide information on how users can keep the host free of future infections. The security web site should also have a guided process that takes non-technical users through the remediation process, on an easily understood, step-by-step basis.
In terms of the text used to explain what bots are and the threats that they pose, something simple such as this may suffice:
- "What is a bot? A bot is a piece of software, generally installed on your machine without your knowledge, which either sends spam or tries to steal your personal information. They can be very difficult to spot, though you may have noticed that your computer is running much more slowly than usual or you notice regular disk activity even when you are not doing anything. Ignoring this problem is risky to you and your personal information. Thus, bots need to be removed to protect your data and your personal information."
It is also important to note that it may not be immediately apparent to the Internet user precisely which devices have been infected with a particular bot. This may be due to the user's home network configuration, which may encompass several hosts, where a home gateway which performs Network Address Translation (NAT) to share a single public IP address has been used. Therefore, any of these devices can be infected with a bot. The consequence of this for an ISP is that remediation advice may not ultimately be immediately actionable by the Internet user, as that user may need to perform additional investigation within their own home network.
An added complication is that the user may have a bot infection on a device such as a video console, multimedia system, appliance, or other end-user computing device which does not have a typical Windows or Macintosh user interface. As a result, diligence needs to be taken by the ISP where possible such that they can identify and communicate the specific nature of the device that has been infected with a bot, and further providing appropriate remediation advice.
There are a number of forums that exist online to provide security related support to end users. These forums are staffed by volunteers and often are focussed around the use of a common tool set to help end users to remediate hosts infected with malware. It may be advantageous to ISPs to foster a relationship with one or more forums, perhaps by offering free hosting or other forms of sponsorship.
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Minimally the Guided Remediation Process should include options and/or recommendations on how a user should:
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It should be acknowledged that, based on the current state of remediation tools and the technical abilities of end users, that many users may be unable to remediate on their own. As a result, it is recommended that users have the option for professional assistance. This may entail online or telephone assistance for remediation, as well as working face to face with a professional who has training and expertise in the removal of malware.
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As an additional consideration, it may be useful to create a process by which users could choose, at their option and with their express consent, to share data regarding their bot infection with their ISP and/or another authorized third party. Such third parties may include governmental entities that aggregate threat data, such as the Internet Crime Complaint Center referred to earlier in this document, to academic institutions, and/or security researchers. While in many cases the information shared with the user's ISP or designated third parties will only be used for aggregated statistical analysis, it is also possible that certain research needs may be best met with more detailed data. Thus, any such data sharing from a user to the ISP or authorized third party may contain some type of personally identifiable information, either by design or inadvertently. As a result, any such data sharing must be enabled on an opt-in based, where users review and approve of the data being shared and the parties with which it is to be shared, unless the ISP is already required to share such data in order to comply with local laws and in accordance with those laws and applicable regulations.
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This document describes in detail the numerous security risks and concerns relating to bot nets. As such, it has been appropriate to include specific information about security in each section above. This document describes the security risks related to malicious bot infections themselves, such as enabling identity theft, theft of authentication credentials, and the use of a host to unwittingly participate in a DDoS attack, among many other risks. This document also describes at a high level the activities that ISPs should be sensitive to, where the collection or communication of PII may be possible. Finally, the document also describes security risks which may relate to the particular methods of communicating a notification to Internet users. Bot networks and bot infections pose extremely serious security risks and any reader should review this document carefully.
In addition, regarding notifications, as described in Section 6 (Notification to Internet Users), care should be taken to assure users that notifications have been provided by a trustworthy site and/or party, so that the notification is more difficult for phishers and/or malicious parties using social engineering tactics to mimic, or that the user has some level of trust that the notification is valid, and/or that the user has some way to verify via some other mechanism or step that the notification is valid.
As noted in Section 10 (Sharing of Data from the User to the ISP), any sharing of data from the user to the ISP and/or authorized third parties must be done on an opt-in basis. Additionally the ISP and or authorized third parties must clearly state what data will be shared and with whom the data will be shared with.
Lastly, as noted in some other sections, there my be legal requirements in particular legal jurisdictions concerning how long any subscriber-related or other data is retained, of which an ISP operating in such a jurisdiction must be aware and with which an ISP must comply.
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There are no IANA considerations in this document.
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The authors wish to acknowledge the following individuals for performing a detailed review of this document and/or providing comments and feedback with had helped to improve and evolve this document:
Mark Baugher
Richard Bennett
James Butler
Vint Cerf
Alissa Cooper
Jonathan Curtis
Jeff Chan
Roland Dobbins
Dave Farber
Eliot Gillum
Joel Halpern
Joel Jaeggli
Scott Keoseyan
The Messaging Anti-Abuse Working Group (MAAWG)
Jose Nazario
Gunter Ollmann
David Reed
Roger Safian
Donald Smith
Joe Stewart
Forrest Swick
Sean Turner
Robb Topolski
Eric Ziegast
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[RFC Editor: This section is to be removed before publication]
-09 version:
-08 version:
-07 version:
-06 version:
-05 version:
-04 version:
-03 version:
-02 version:
-01 version:
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[RFC Editor: This section is to be removed before publication]
per Donald, where SNDS is mentioned: That is a list of good examples but there are a lot of other good 3rd party infected client notification resources. Arbor via atlas, ShadowServer, Cymru, SIE, Support Intelligence and many others. It might be worth having a seperate section near the end that has a list of 3rd parties that are willing to share this kind of information with ISPs and provide contact info such as was done for conficker. http://www.confickerworkinggroup.org/wiki/pmwiki.php/SP/ServiceProviders That list is NOT complete in any sense of the word. Providing contact information may help other ISPs get a more complete set of third party reports. I am a bit concerned that some of the 3rd party contact information could change later and be outdated but I believe most of them will use a role based email account or a link.
per Sean, There is no RFC 2119 language in the document. Was this intentional? If it is then we could delete section 1. If it's not then you'll need to figure out which "must", "should", etc. need to be capitalized.
per Donald, in notification method section, consider taking this text from the phone method and using as a new section with drawbacks/challenges: Finally, even if a representative of the ISP is able to connect with and speak to a user, that user is very likely to lack the necessary technical expertise to understand or be able to effectively deal with the threat.
per Donald, consider w/r/t the WG method: That is really the definition of a quarantine walled garden. Walled garden's don't have to quarantine the user (much) to notify the customer. They can be fairly leaky and still notify the customer of their infection.
per Donald, consider text re users who continue to fail to mitigate: Another good approach is just to keep track of whom was put into the walled garden for which infection and if they keep showing up as infected via the trusted third party reports then you can assume they are unable/unwilling to remediate and take what ever additional actions you deem appropriate.
per Donald, inclusion of PII is a good general stmt to consider for an opening section in the notification part of the doc: As such, should this method be used, the notification should be discreet and not include any PII in the notification itself.
per Donald, do we want to consider adding a 'leaky' WG? 'Or design a leaky walled garden that allows most traffic without interference only redirecting the traffic needed to mitigate or notify.'
Address suggestion from Donald Smith: The risks to users of infected systems and others are included/defined in many places within this document. It should probably be defined clearly in one place and referenced in all other places.
per Roger - ponder acct termination
A question has been raised about whether this should change from Informational to BCP.
Guided remediation -- these urls while provided for the purpose of examples are unlikely to be stable on any kind of long timescale. fundamentally updating os software addresses vulnerability not remediation (windows malicious software removal tool notwithstanding)
Guided remediation, bullets 4 - 7 -- It's unclear how these steps are even feasible to undertake for organizations nominally characterized as ISPs. there's a several thousand fold cost differential between automated help and remediation by sending a train professional to lay hands on one computer.
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Jason Livingood | |
Comcast Cable Communications | |
One Comcast Center | |
1701 John F. Kennedy Boulevard | |
Philadelphia, PA 19103 | |
US | |
Email: | jason_livingood@cable.comcast.com |
URI: | http://www.comcast.com |
Nirmal Mody | |
Comcast Cable Communications | |
One Comcast Center | |
1701 John F. Kennedy Boulevard | |
Philadelphia, PA 19103 | |
US | |
Email: | nirmal_mody@cable.comcast.com |
URI: | http://www.comcast.com |
Mike O'Reirdan | |
Comcast Cable Communications | |
One Comcast Center | |
1701 John F. Kennedy Boulevard | |
Philadelphia, PA 19103 | |
US | |
Email: | michael_oreirdan@cable.comcast.com |
URI: | http://www.comcast.com |