User:David MacQuigg/Sandbox/Email security: Difference between revisions
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Less serious, but more common is the problem of keeping user addresses off spammer mailing lists. These lists are sold and copied and resold all over the world. Get on one spam list, and you will soon be on many. Even users who are careful to give their real address only to friends may see that address used in a cc list with dozens of other addresses (perhaps a chain letter). If any one of those recipient's computers is infected, these cc'd addresses can be "harvested". | Less serious, but more common is the problem of keeping user addresses off spammer mailing lists. These lists are sold and copied and resold all over the world. Get on one spam list, and you will soon be on many. Even users who are careful to give their real address only to friends may see that address used in a cc list with dozens of other addresses (perhaps a chain letter). If any one of those recipient's computers is infected, these cc'd addresses can be "harvested". | ||
Another big source of target addresses is websites where the user is required to provide an email address, perhaps just for one transaction. If you read the fine print, what the operators of the website are doing may even be perfectly legal. All of these problems may be avoided by using disposable alias addresses. If the alias is ever "spammed out", just pick another. | |||
'''Users should be:'''<br /> | '''Users should be:'''<br /> | ||
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== MSA vulnerabilites == | == MSA vulnerabilites == | ||
A Mail Submission Agent (MSA) may be tricked into relaying mail from an unauthorized source, or from an authorized source that has been infected or has been compromised in some other way. For example, some large email services, eager to get new accounts, may allow criminals to automate their acquisition of free accounts. | A Mail Submission Agent (MSA) may be tricked into relaying mail from an unauthorized source, or from an authorized source that has been infected or has been compromised in some other way. For example, some large email services, eager to get new accounts, may allow criminals to automate their acquisition of free accounts. | ||
The connection between the Client machine and the MSA may be vulnerable to eavesdropping or interception (a [[man-in-the-middle]] attack). These connections are often via insecure local networks (e.g. a coffee shop or university computer lab), and the traffic is light enough that it takes no special equipment to extract the right data packets. If these packets are unencrypted, they can reveal passwords and other sensitive data. | |||
'''Mail Submission Agents should:'''<br /> | '''Mail Submission Agents should:'''<br /> | ||
1) [[authenticate]] any user attempting to submit an email.<br /> | 1) [[authenticate]] any user attempting to submit an email.<br /> | ||
2) require | 2) require users to maintain [[secure passwords]], and not allow automated password guessing.<br /> | ||
3) use secure [[Email port 587|port 587]] instead of the heavily-abused port 25.<br /> | 3) use secure [[Email port 587|port 587]] instead of the heavily-abused port 25.<br /> | ||
4) treat new accounts with special caution, ensuring that the benefits of abuse are less than the cost of establishing new accounts.<br /> | 4) treat new accounts with special caution, ensuring that the benefits of abuse are less than the cost of establishing new accounts.<br /> | ||
5) offer [[TLS]] encrypted connections to their clients.<br /> | |||
Mail Submission Agents are often the owners of the networks through which their users access the Internet. In this case, they can and should do the right thing by blocking outbound packets having a spoofed source address or an impermissible destination port. These limits can be programmed into the routers on the users side ([[ingress filtering]]) or on the Internet side ([[egress filtering]]). They are effective against many kinds of abuse, not just email. | |||
'''Network owners should:'''<br /> | |||
1) block outbound packets having an incorrect source address. --UPD--<br /> | |||
2) block outbound packets to TCP port 25, unless the source address is authorized to act as an email transmitter.<br /> | |||
3) work to eliminate abuse originating within their network.<br /> | |||
== Transmitter vulnerabilites == | == Transmitter vulnerabilites == | ||
The Transmitter to Receiver connection is the weakest link in the passage of email from Author to Recipient. This may be inevitable, given the necessity for communications between unrelated parties across the open Internet. All other links in Figure 1 are between parties that have at least an indirect relationship with each other. | The Transmitter to Receiver connection is the weakest link in the passage of email from Author to Recipient. This may be inevitable, given the necessity for communications between unrelated parties across the open Internet. All other links in Figure 1 are between parties that have at least an indirect relationship with each other. | ||
The Internet link is uniquely vulnerable to criminal intrusion. It is very easy to set up an exact replica of a legitimate transmitter relay, duplicating everything from message headers, to the envelope Return Address, to the name of the legitimate transmitter, everything but the transmitter's IP address. That has to be the | The Internet link is uniquely vulnerable to criminal intrusion. It is very easy to set up an exact replica of a legitimate transmitter relay, duplicating everything from message headers, to the envelope Return Address, to the name of the legitimate transmitter, everything but the transmitter's IP address. That has to be the address of the actual transmitter, or there is no TCP connection. | ||
Criminals never use their own names in malicious transmissions. They will either make up a new name, or forge the name of a trusted domain. Criminal use of a trusted domain name provides better access to victim systems, and damages the reputation of the trusted name. | Criminals never use their own names in malicious transmissions. They will either make up a new name, or forge the name of a trusted domain. Criminal use of a trusted domain name provides better access to victim systems, and damages the reputation of the trusted name. | ||
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Filtering the few good messages from this flood of sewage can be a challenge. Traditional filtering methods include statistical analysis of message content, looking for words and phrases that have high probability as spam indicators, and looking for abnormalities in the message headers, using heuristic rule-sets that are updated periodically to follow the latest trends. Both of these techniques reject some legitimate messages, and there is always a compromise between minimizing false rejects and minimizing the amount of spam that gets through to the user's inbox. | Filtering the few good messages from this flood of sewage can be a challenge. Traditional filtering methods include statistical analysis of message content, looking for words and phrases that have high probability as spam indicators, and looking for abnormalities in the message headers, using heuristic rule-sets that are updated periodically to follow the latest trends. Both of these techniques reject some legitimate messages, and there is always a compromise between minimizing false rejects and minimizing the amount of spam that gets through to the user's inbox. | ||
Additional "filtering" methods include [[greylisting]] and [[challenge/response]]. Greylisting involves returning a [[temporary reject]] on the theory that only legitimate transmitters will retry after a temporary failure. Challenge/response (C/R methods) involve asking the | Additional "filtering" methods include [[Email greylisting|greylisting]] and [[Email challenge-response|challenge/response]]. Greylisting involves returning a [[temporary reject]] on the theory that only legitimate transmitters will retry after a temporary failure. Challenge/response (C/R methods) involve asking the sender to respond to a challenge, on the theory that only legitimate senders with important messages will respond. Both these methods are controversial - greylisting as to its long-term effectiveness, and C/R as to its potential for generating unwanted challenges to forged sender addresses. | ||
A recent trend in receiver security is to rely less on statistical techniques, and more on the reputation of the Transmitter agent. If that reputation is good, all messages from that Transmitter can be "whitelisted" and passed directly to the recipient's inbox, not suffering the delays and possible losses in a statistical filter. A well-managed reputation system can whitelist nearly all legitimate senders [Taylor08]. | A recent trend in receiver security is to rely less on statistical techniques, and more on the reputation of the Transmitter agent. If that reputation is good, all messages from that Transmitter can be "whitelisted" and passed directly to the recipient's inbox, not suffering the delays and possible losses in a statistical filter. A well-managed reputation system can whitelist nearly all legitimate senders [Taylor08]. | ||
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1) block persistent sources of abuse efficiently. This is typically done with an [[IP blacklist]].<br /> | 1) block persistent sources of abuse efficiently. This is typically done with an [[IP blacklist]].<br /> | ||
2) provide clear and concise feedback to the senders of rejected messages, so that innocent mistakes can be corrected quickly. This should be done in the [[SMTP reject message]].<br /> | 2) provide clear and concise feedback to the senders of rejected messages, so that innocent mistakes can be corrected quickly. This should be done in the [[SMTP reject message]].<br /> | ||
3) authenticate the | 3) authenticate the domain name associated with the transmitter relay. This is typically done by comparing the transmitter's IP address to authentication records under the domain name.<br /> | ||
4) | 4) authenticate per-message data as needed for better security. This can include checks on the envelope Return Address, the header From: address, and the entire message content.<br /> | ||
5) assess the reputation of the | 5) assess the reputation of the authenticated identities. This can be done using a local or a shared database.<br /> | ||
6) filter any messages that cannot be rejected at authentication, or whitelisted at the reputation check, and use the resulting score to prioritize filtered messages for review by the recipient.<br /> | 6) filter any messages that cannot be rejected at authentication, or whitelisted at the reputation check, and use the resulting score to prioritize filtered messages for review by the recipient.<br /> | ||
7) add authentication headers to facilitate MDA processing. These can include authentication results and spam scores.<br /> | |||
8) accept spam reports and Delivery Status Notifications (DSNs) for any messages that were recently accepted from a Transmitter.<br /> | |||
9) relay DSNs and spam reports to an authenticated sender, and to the Transmitter.<br /> | |||
10) share spam report data with spam-blocking and reputation services.<br /> | |||
== Forwarder vulnerabilities == | == Forwarder vulnerabilities == | ||
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== MDA vulnerabilities == | == MDA vulnerabilities == | ||
Mail Delivery Agents (MDAs) have the same problems as Mail Submission Agents in authenticating users. | Mail Delivery Agents (MDAs) have the same problems as Mail Submission Agents in authenticating users and providing them with secure connections. Users often have the same agent for delivery as they have for submission. In this case, one authentication mechanism can be applied to both roles, and one secure connection can serve both purposes. A user who is already logged in to access a mailstore need not log in again to send a message. | ||
Other than these [[access control]] issues, MDAs will have very little vulnerability in performing the storage and delivery function. The problems that do arise usually relate to confusion over forwarding arrangements. If the recipient simply forwards messages from some source unknown to the MDA, and the MDA is also acting as a Receiver at that same address, the two message streams can get confused. Border defenses applied to a stream of forwarded messages can result in authentication failures, lost messages, and improper abuse reports against a Forwarder who is simply following a recipient's instructions. | Other than these [[access control]] issues, MDAs will have very little vulnerability in performing the storage and delivery function. The problems that do arise usually relate to confusion over forwarding arrangements. If the recipient simply forwards messages from some source unknown to the MDA, and the MDA is also acting as a Receiver at that same address, the two message streams can get confused. Border defenses applied to a stream of forwarded messages can result in authentication failures, lost messages, and improper abuse reports against a Forwarder who is simply following a recipient's instructions. | ||
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'''Mail Delivery Agents should:'''<br /> | '''Mail Delivery Agents should:'''<br /> | ||
1) authenticate | 1) [[authenticate]] any user attempting to access a mailbox.<br /> | ||
2) | 2) require users to maintain [[secure passwords]], and not allow automated password guessing.<br /> | ||
3) make it easy for recipients to whitelist their forwarders.<br /> | 3) offer [[TLS]] encrypted connections to their users.<br /> | ||
4) make it easy for recipients to whitelist their forwarders.<br /> | |||
5) educate recipients on how to avoid mis-configured forwarding arrangements.<br /> | |||
6) provide a convenient mechanism for recipients to report spam.<br /> | |||
7) ensure that spam reports are handled properly.<br /> | |||
== Bibliography == | |||
=== BCPs relevant to email security === | |||
Standards specify what is needed for '''interoperability''' of systems on the Internet. Adding to these standards what is needed to deal with current security threats would make the standards too complex, less permanent, and even controversial. Most of the IETF recommendations relevant to email security are found in a series of documents called Best Current Practices (BCPs). | |||
[http://rfc-editor.org/bcp-index.html BCP Index], Latest list of RFCs approved as '''Best Current Practice''' documents. | |||
[http://tools.ietf.org/html/rfc2505 BCP-30, RFC-2505], "Anti-Spam Recommendations for SMTP MTAs", G.Lindberg (1999). | |||
[http://tools.ietf.org/html/rfc2827 BCP-38, RFC-2827], "Network Ingress Filtering: Defeating Denial of Service Attacks which employ IP Source Address Spoofing", P.Ferguson, D.Senie (2000). | |||
[http://tools.ietf.org/html/rfc3013 BCP-46, RFC-3013], "Recommended Internet Service Provider Security Services and Procedures", T.Killalea (2000). | |||
[http://tools.ietf.org/html/rfc5068 BCP-134, RFC-5068], "Email Submission Operations: Access and Accountability Requirements", C. Hutzler, D. Crocker, P. Resnick, E. Allman, T. Finch (2007). | |||
=== Standards track RFCs relevant to email security === | |||
[http://tools.ietf.org/html/rfc4409 RFC-4409], "Message Submission for Mail", R. Gellens, J. Klensin (2006). | |||
[http://tools.ietf.org/html/rfc5321 RFC-5321], "Simple Mail Transfer Protocol", J. Klensin, ed. (2008). |
Latest revision as of 12:21, 10 October 2009
Talk: Email security is such a huge topic, we could write a book. What are the most important things we can say to students in just a few pages?
This article on Email security provides a brief overview of the ways in which email systems may be abused, and the most effective ways to fight that abuse. We categorize the vulnerabilities according to their locality in Figure 1 of Email system, repeated here for convenience. We assume the reader is familiar with that article.
In each category, we summarize the requirements for security. These are high-level requirements, not recommendations for any specific method or technique, and not intended as a rigid standard for every system. The same level of security may be provided in some other way. For example, there is less need for passwords if every user can be authenticated by their address on a local network, secure from any outside intruder.
User vulnerabilities
After running a malicious program, perhaps from a phony website or attached to an email, the user's computer may become infected with a zombie program controlled by a remote criminal system. This can result in stolen passwords and data, access to other computers with confidential data, or malicious transmissions from the user's computer, including spam and additional malicious programs. An infected user's computer is a serious threat to an entire system.
Less serious, but more common is the problem of keeping user addresses off spammer mailing lists. These lists are sold and copied and resold all over the world. Get on one spam list, and you will soon be on many. Even users who are careful to give their real address only to friends may see that address used in a cc list with dozens of other addresses (perhaps a chain letter). If any one of those recipient's computers is infected, these cc'd addresses can be "harvested".
Another big source of target addresses is websites where the user is required to provide an email address, perhaps just for one transaction. If you read the fine print, what the operators of the website are doing may even be perfectly legal. All of these problems may be avoided by using disposable alias addresses. If the alias is ever "spammed out", just pick another.
Users should be:
1) trained to not run any programs that may infect their computer.
2) required to run an anti-virus program, and keep it updated.
3) required to install all security updates promptly.
4) required to maintain secure passwords.
5) required to submit emails through their regular MSA, even when they are on the road.
6) encouraged to use aliases for any risky communications.
MSA vulnerabilites
A Mail Submission Agent (MSA) may be tricked into relaying mail from an unauthorized source, or from an authorized source that has been infected or has been compromised in some other way. For example, some large email services, eager to get new accounts, may allow criminals to automate their acquisition of free accounts.
The connection between the Client machine and the MSA may be vulnerable to eavesdropping or interception (a man-in-the-middle attack). These connections are often via insecure local networks (e.g. a coffee shop or university computer lab), and the traffic is light enough that it takes no special equipment to extract the right data packets. If these packets are unencrypted, they can reveal passwords and other sensitive data.
Mail Submission Agents should:
1) authenticate any user attempting to submit an email.
2) require users to maintain secure passwords, and not allow automated password guessing.
3) use secure port 587 instead of the heavily-abused port 25.
4) treat new accounts with special caution, ensuring that the benefits of abuse are less than the cost of establishing new accounts.
5) offer TLS encrypted connections to their clients.
Mail Submission Agents are often the owners of the networks through which their users access the Internet. In this case, they can and should do the right thing by blocking outbound packets having a spoofed source address or an impermissible destination port. These limits can be programmed into the routers on the users side (ingress filtering) or on the Internet side (egress filtering). They are effective against many kinds of abuse, not just email.
Network owners should:
1) block outbound packets having an incorrect source address. --UPD--
2) block outbound packets to TCP port 25, unless the source address is authorized to act as an email transmitter.
3) work to eliminate abuse originating within their network.
Transmitter vulnerabilites
The Transmitter to Receiver connection is the weakest link in the passage of email from Author to Recipient. This may be inevitable, given the necessity for communications between unrelated parties across the open Internet. All other links in Figure 1 are between parties that have at least an indirect relationship with each other.
The Internet link is uniquely vulnerable to criminal intrusion. It is very easy to set up an exact replica of a legitimate transmitter relay, duplicating everything from message headers, to the envelope Return Address, to the name of the legitimate transmitter, everything but the transmitter's IP address. That has to be the address of the actual transmitter, or there is no TCP connection.
Criminals never use their own names in malicious transmissions. They will either make up a new name, or forge the name of a trusted domain. Criminal use of a trusted domain name provides better access to victim systems, and damages the reputation of the trusted name.
Domain owners who care about their reputation should protect their name by publishing authentication records in DNS (the Domain Name System). Agents who operate transmitters on behalf of another domain (as opposed to transmitting under their own name) should work closely with the domain owner to ensure that the domain's authentication records are kept up to date. Only the owner has access to these records.
Domain owners should:
1) publish the IP addresses of their authorized transmitters (either their own, or their agent's transmitters that will identify using the domain's name).
2) publish authentication records as needed to protect the use of their name in Return Addresses and in From: headers.
3) publish authentication records as needed to provide digital signature protection for the entire content of email messages.
Transmitter agents should:
1) publish the IP addresses of their own authorized transmitters under whatever name will be used to identify those transmitters.
2) work with their MSA agents and other domain owners to ensure all records are kept up to date.
3) implement rate limits on outgoing mail from each user account.
4) work with their MSA agents to provide additional security as needed in their situation. This could include monitoring the content of outgoing messages.
5) provide alerts to anyone who might be an innocent source of abuse.
6) respond promptly to reports of abuse, even if their transmitters are not responsible.
7) maintain a good reputation for all the domain names used by their transmitters.
8) comply with all standards relating to their operations, thus helping others to avoid mistakes affecting security.
9) handle bounce messages (Delivery Status Notifications) in a way that provides maximum reliability while avoiding abuse. This could include adding validation codes to the Return Address on every outgoing message.
Receiver vulnerabilities
Receivers have the biggest burden of all. Over 90% of incoming messages are fraudulent, many from senders that are transmitting such huge volumes that it would be a Denial of Service (DoS) attack on the receiver if it were unavoidable. Luckily, the most persistent sources can be identified by their IP addresses, and blocked without further processing. That still leaves a large number of new addresses that have not yet been added to the IP blacklists.
Filtering the few good messages from this flood of sewage can be a challenge. Traditional filtering methods include statistical analysis of message content, looking for words and phrases that have high probability as spam indicators, and looking for abnormalities in the message headers, using heuristic rule-sets that are updated periodically to follow the latest trends. Both of these techniques reject some legitimate messages, and there is always a compromise between minimizing false rejects and minimizing the amount of spam that gets through to the user's inbox.
Additional "filtering" methods include greylisting and challenge/response. Greylisting involves returning a temporary reject on the theory that only legitimate transmitters will retry after a temporary failure. Challenge/response (C/R methods) involve asking the sender to respond to a challenge, on the theory that only legitimate senders with important messages will respond. Both these methods are controversial - greylisting as to its long-term effectiveness, and C/R as to its potential for generating unwanted challenges to forged sender addresses.
A recent trend in receiver security is to rely less on statistical techniques, and more on the reputation of the Transmitter agent. If that reputation is good, all messages from that Transmitter can be "whitelisted" and passed directly to the recipient's inbox, not suffering the delays and possible losses in a statistical filter. A well-managed reputation system can whitelist nearly all legitimate senders [Taylor08].
Receiver agents should:
1) block persistent sources of abuse efficiently. This is typically done with an IP blacklist.
2) provide clear and concise feedback to the senders of rejected messages, so that innocent mistakes can be corrected quickly. This should be done in the SMTP reject message.
3) authenticate the domain name associated with the transmitter relay. This is typically done by comparing the transmitter's IP address to authentication records under the domain name.
4) authenticate per-message data as needed for better security. This can include checks on the envelope Return Address, the header From: address, and the entire message content.
5) assess the reputation of the authenticated identities. This can be done using a local or a shared database.
6) filter any messages that cannot be rejected at authentication, or whitelisted at the reputation check, and use the resulting score to prioritize filtered messages for review by the recipient.
7) add authentication headers to facilitate MDA processing. These can include authentication results and spam scores.
8) accept spam reports and Delivery Status Notifications (DSNs) for any messages that were recently accepted from a Transmitter.
9) relay DSNs and spam reports to an authenticated sender, and to the Transmitter.
10) share spam report data with spam-blocking and reputation services.
Forwarder vulnerabilities
The Forwarder role (played by the Receiver agent in Figure 1) is much like a Transmitter, but instead of sending a message to an unrelated Receiver, the message goes to a related party, the Mail Delivery Agent (MDA) designated by a recipient who has an account with both parties. Ideally, the recipient can ensure that the forwarding arrangement is reliable and secure, turning off authentication checks, spam filters, and any other mechanisms at the MDA that might conflict with the forwarding arrangement, and if necessary, using a private address at the MDA for security. Ideally, recipients should keep forwarding arrangements simple and direct, never a chain of forwarders.
In reality, recipients (non-expert users) make many mistakes. The resulting confusion leads to a special vulnerability that we can associate with the Forwarder. Messed up forwarding arrangements often lead to lost messages, erroneous abuse reports, and more work for both the Forwarder and the MDA.
Forwarding agents should:
1) educate recipients who request forwarding on why and how to whitelist the Forwarder at their MDA.
2) confirm the forwarding arrangement with the MDA.
3) suspend the forwarding arrangement immediately whenever there is a reject from the MDA or an abuse report against the Forwarder.
4) communicate with the recipient to correct the problem.
5) publish the same authentication records for their outgoing IP addresses as they would in playing a Transmitter role.
MDA vulnerabilities
Mail Delivery Agents (MDAs) have the same problems as Mail Submission Agents in authenticating users and providing them with secure connections. Users often have the same agent for delivery as they have for submission. In this case, one authentication mechanism can be applied to both roles, and one secure connection can serve both purposes. A user who is already logged in to access a mailstore need not log in again to send a message.
Other than these access control issues, MDAs will have very little vulnerability in performing the storage and delivery function. The problems that do arise usually relate to confusion over forwarding arrangements. If the recipient simply forwards messages from some source unknown to the MDA, and the MDA is also acting as a Receiver at that same address, the two message streams can get confused. Border defenses applied to a stream of forwarded messages can result in authentication failures, lost messages, and improper abuse reports against a Forwarder who is simply following a recipient's instructions.
These problems may be avoided if recipients whitelist their Forwarders, and MDAs turn off their Border defenses for these whitelisted message streams (a specific Forwarder to a specific recipient account). MDAs that do not have this capability should allow recipients to use private alias accounts. As long as an alias is kept private, all mail to that alias may be whitelisted.
Educating recipients to whitelist their Forwarders is difficult for an MDA, because often the MDA is not even aware that a forwarding arrangement has been set up. The Forwarder should notify the MDA when a recipient requests forwarding, and both should make sure the recipient understands what is being done.
Mail Delivery Agents should:
1) authenticate any user attempting to access a mailbox.
2) require users to maintain secure passwords, and not allow automated password guessing.
3) offer TLS encrypted connections to their users.
4) make it easy for recipients to whitelist their forwarders.
5) educate recipients on how to avoid mis-configured forwarding arrangements.
6) provide a convenient mechanism for recipients to report spam.
7) ensure that spam reports are handled properly.
Bibliography
BCPs relevant to email security
Standards specify what is needed for interoperability of systems on the Internet. Adding to these standards what is needed to deal with current security threats would make the standards too complex, less permanent, and even controversial. Most of the IETF recommendations relevant to email security are found in a series of documents called Best Current Practices (BCPs).
BCP Index, Latest list of RFCs approved as Best Current Practice documents.
BCP-30, RFC-2505, "Anti-Spam Recommendations for SMTP MTAs", G.Lindberg (1999).
BCP-38, RFC-2827, "Network Ingress Filtering: Defeating Denial of Service Attacks which employ IP Source Address Spoofing", P.Ferguson, D.Senie (2000).
BCP-46, RFC-3013, "Recommended Internet Service Provider Security Services and Procedures", T.Killalea (2000).
BCP-134, RFC-5068, "Email Submission Operations: Access and Accountability Requirements", C. Hutzler, D. Crocker, P. Resnick, E. Allman, T. Finch (2007).
Standards track RFCs relevant to email security
RFC-4409, "Message Submission for Mail", R. Gellens, J. Klensin (2006).
RFC-5321, "Simple Mail Transfer Protocol", J. Klensin, ed. (2008).