User:David MacQuigg/Sender Policy Framework: Difference between revisions

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'''Definition:''' Method for authenticating the return address on an email message.
'''Edit status:''' copied to main
 
'''Definition:''' Email authentication method that verifies the domain name in the envelope return address against the sender's IP address.


{{seealso|Email authentication}} for a general overview and terminology.
{{seealso|Email authentication}} for a general overview and terminology.
{{TOC|right}}
'''Sender Policy Framework (SPF)''' is an email authentication method that uses the [[IP address|source IP address]] in a [[TCP]] connection to verify the domain name in the envelope [[Email authentication|Return Address]] with every message. A Pass result provides strong assurance that the message came from a transmitter authorized by the domain owner.  A Fail result allows immediate rejection of the message, while the transmitter is still connected, and before transferring any data.


'''Sender Policy Framework (SPF)''' is an email authentication method that seeks to correlate the domain name in the envelope return address with the IP address of an SMTP client currently connected and waiting to send a messageA definite result (Pass or Fail) will allow the disposition of the message to be determined quickly, while the client is still connected, and before transferring the message data.
The domain in the Return Address is verified by doing a [[DNS]] query for an SPF record under the domain name.  If the IP address is listed in that record, the result is PassThus SPF security depends on the security of Internet IP addresses and of the Domain Name System.


After accepting the Mail From: command, the server does a DNS query for an SPF record on the domain name.  If the IP address is listed in the SPF record, the authentication result is PASS, the message may be processed in accordance with the reputation assigned to the domain.  If the authentication result is FAIL, the message may be immediately rejected without any data transfer.
SPF prevents the "replay" abuse possible with [[Email authentication|signature]] methods like [[DKIM]], because the verified domain owner can be held responsible for high-volume replication of a message.


=== Limitations ===
=== Limitations ===
Often, the result of an SPF authenticaion is neither PASS nor FAIL, but NEUTRAL.  This is due to the many domains that don't publish SPF records, or that have records giving indefinite results.
SPF seeks to authenticate the domain name of an originator, usually the MSA, with an IP address from the last agent in a chain of trust, usually the Transmitter.  This works well because there is a close relationship between the MSA and the Transmitter.  Often they are the same agent. 
 
When a Forwarder is involved, however, the source IP address on the "last hop" to the MDA is no longer related to the originator's domain name.  An SPF check by the MDA will likely fail.
 
|--- Sender's Network ---|          |--------- Recipient's Network --------|
                                /
Author ==> MSA/Transmitter --> / --> Receiver/Forwarder ~~> MDA ==> Recipient
                    /        /        /
                    /      Border    /
                  /                  /
                  ------ DNS ------- 
 
The first solution to this problem was a campaign to get Forwarders to re-write the Return Address on forwarded messages, so that it would have the Forwarder's domain name.  (See step 5 in the example below.)  This failed because Forwarders were not willing to install SRS software and take on responsibility for bounced messages.  Also, it required changing a long-standing interpretation of the Return Address as being that of the original sender.


[[forwarding problem]]
The current solution is to emphasize proper setup within the Recipient's network.  SPF checks should be done only at the Border.  Recipients should whitelist their Forwarders at their MDAs.  Unfortunately, the confusion over this issue has persisted so long that it has led to the second big problem with SPF, the "chicken-and-egg" standoff.
 
Senders are unwilling to publish robust SPF records ending in "-all" due to the fear that their mail will be rejected by mis-configured forwarding setups.  The common practice among nearly all domains publishing SPF records is to end them in ?all.  This says to treat all other IP addresses not as Fail, but Neutral.  This takes away the major motivation for Receivers to do SPF checks.  Without large numbers of Receivers taking these records seriously, senders find that they can be sloppy with their SPF records, or not publish them at all, and it doesn't matter.


=== How it works ===
=== How it works ===
Line 23: Line 41:


1) The sender (typically the Mail Submission Agent for example.com) checks the envelope return address to make sure the domain part is "example.com", then relays the message to the Transmitter.
1) The sender (typically the Mail Submission Agent for example.com) checks the envelope return address to make sure the domain part is "example.com", then relays the message to the Transmitter.
  MAIL FROM:<author@example.com>


2) The Receiver extracts the domain part of the return address, and does a DNS query (preferably for the SPF record) under that domain.
2) The Receiver extracts the domain part of the return address, and does a DNS query for the SPF record under that domain.


3) The terms in the SPF record are tested one at a time, left to right, and the first definite result (pass or fail) is accepted.  The prefixes (+, -, ?) mean (pass, fail, neutral), with + being the default.
3) The terms in the SPF record are tested one at a time, left to right, and the first definite result (pass or fail) is accepted.  The prefixes (+, -, ?) mean (pass, fail, neutral), with + being the default.
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==== Explanatory notes ====
==== Explanatory notes ====


TXT is the code for a text record in DNS. Text records can store any text strings the domain owner wants to publish.  SPF is a new record type, a TXT record just for SPF data.  It will be necessary to publish both records until all DNS software is able to recognize the new type.
TXT is the code for a text record in DNS. Text records can store any text strings the domain owner wants to publish.  SPF is a new record type, a TXT record just for SPF data.  It will be necessary to publish both records until all DNS software is able to recognize the new type.


1800 seconds is the lifetime of the DNS record after it has left the server on which it was published.  This allows frequently used records to be read from a cache, instead of doing a fresh query every time.
1800 seconds is the lifetime of the DNS record after it has left the server on which it was published.  This allows frequently used records to be read from a cache, instead of doing a fresh query every time.


Everything between the double quotes is part of the text string, but not the quotes themselves.  The string consists of a number of space-delimited terms. "v=spf1" means this is a record for version 1 of SPF.
Everything between the double quotes is part of the text string, but not the quotes themselves.  The string consists of a number of space-delimited terms. "v=spf1" means this is a record for version 1 of SPF.
 


The TXT record for DKIM consists of a number of key=value pairs.  This syntax takes a little more space, but it allows for future growth of DKIM by simply adding new key items.  This record specifies an encryption algorithm (k=) a hash algorithm (h=) and a public key value (p=).  The public key is 216 [[base64]] characters, so it fits easily within DNS limits (255 characters per string, 512 bytes in a DNS packet).  Each base64 character encodes 6 bits, so the total key length is 1296 bits (216 * 6), and this is considered quite secure.
The syntax for SPF includes a number of key=value pairs (or key:value).  This syntax takes a little more space, but it allows for future growth of SPF by simply adding new key items.


The Authentication-Results header above shows that there were actually two signatures in this messageDomainKeys was the predecessor to DKIM, so this is probably a legacy system in the sender's domain.
The /28 in the ip4 terms is [[CIDR notation]] for a block of 16 addressesThe number 28 is the number of bits in a "mask", which is a bit pattern used in testing address ranges.  Comparisons using a mask are faster than a general integer range test, but the blocks are limited to sizes that are a power of two (1, 2, 4, 8, 16, ...).  CIDR notation is commonly used in routers, where speed is critical.


=== Bibliography ===
=== Bibliography ===
Line 56: Line 74:
{{r|http://tools.ietf.org/html/rfc4408 RFC-4408}} - "Sender Policy Framework (SPF) for Authorizing Use of Domains in E-Mail, Version 1", M. Wong, W. Schlitt, 2006.  
{{r|http://tools.ietf.org/html/rfc4408 RFC-4408}} - "Sender Policy Framework (SPF) for Authorizing Use of Domains in E-Mail, Version 1", M. Wong, W. Schlitt, 2006.  
{{r|http://www.openspf.org Sender Policy Framework}} - project website
{{r|http://www.openspf.org Sender Policy Framework}} - project website
{{r|http://www.openspf.org/SRS Sender Rewriting Scheme}} - website for SRS
{{r|http://www.openspf.org/SRS Sender Rewriting Scheme}} - webpage for SRS

Latest revision as of 18:34, 26 October 2009

Edit status: copied to main

Definition: Email authentication method that verifies the domain name in the envelope return address against the sender's IP address.

See also: Email authentication for a general overview and terminology.

Sender Policy Framework (SPF) is an email authentication method that uses the source IP address in a TCP connection to verify the domain name in the envelope Return Address with every message. A Pass result provides strong assurance that the message came from a transmitter authorized by the domain owner. A Fail result allows immediate rejection of the message, while the transmitter is still connected, and before transferring any data.

The domain in the Return Address is verified by doing a DNS query for an SPF record under the domain name. If the IP address is listed in that record, the result is Pass. Thus SPF security depends on the security of Internet IP addresses and of the Domain Name System.

SPF prevents the "replay" abuse possible with signature methods like DKIM, because the verified domain owner can be held responsible for high-volume replication of a message.

Limitations

SPF seeks to authenticate the domain name of an originator, usually the MSA, with an IP address from the last agent in a chain of trust, usually the Transmitter. This works well because there is a close relationship between the MSA and the Transmitter. Often they are the same agent.

When a Forwarder is involved, however, the source IP address on the "last hop" to the MDA is no longer related to the originator's domain name. An SPF check by the MDA will likely fail.

|--- Sender's Network ---|           |--------- Recipient's Network --------|
                                /
Author ==> MSA/Transmitter --> / --> Receiver/Forwarder ~~> MDA ==> Recipient
                    /         /        /
                   /       Border     /
                  /                  /
                  ------ DNS -------  

The first solution to this problem was a campaign to get Forwarders to re-write the Return Address on forwarded messages, so that it would have the Forwarder's domain name. (See step 5 in the example below.) This failed because Forwarders were not willing to install SRS software and take on responsibility for bounced messages. Also, it required changing a long-standing interpretation of the Return Address as being that of the original sender.

The current solution is to emphasize proper setup within the Recipient's network. SPF checks should be done only at the Border. Recipients should whitelist their Forwarders at their MDAs. Unfortunately, the confusion over this issue has persisted so long that it has led to the second big problem with SPF, the "chicken-and-egg" standoff.

Senders are unwilling to publish robust SPF records ending in "-all" due to the fear that their mail will be rejected by mis-configured forwarding setups. The common practice among nearly all domains publishing SPF records is to end them in ?all. This says to treat all other IP addresses not as Fail, but Neutral. This takes away the major motivation for Receivers to do SPF checks. Without large numbers of Receivers taking these records seriously, senders find that they can be sloppy with their SPF records, or not publish them at all, and it doesn't matter.

How it works

This is a brief explanation of an authentication using an SPF record with just a few of the more common terms. See RFC-4408 for the other terms and full details of SPF.

Senders that wish to use SPF should publish a TXT record and an identical SPF record under their domain name in DNS. Typical DNS records might look like:

example.com.  1800  IN  TXT  "v=spf1 ip4:192.168.33.32/28 mx a:colo.example.net ?all"
example.com.  1800  IN  SPF  "v=spf1 ip4:192.168.33.32/28 mx a:colo.example.net ?all"

These records authorize a number of IP addresses to transmit email for example.com. These addresses include a block of 16 starting at 192.168.33.32, plus any addresses found via the MX records for that same domain (i.e. the incoming mail servers), plus any addresses found in A records for the domain colo.example.net. The ?all term at the end means to treat all other addresses as "neutral", meaning the same as if no SPF records were published.

1) The sender (typically the Mail Submission Agent for example.com) checks the envelope return address to make sure the domain part is "example.com", then relays the message to the Transmitter.

  MAIL FROM:<author@example.com>

2) The Receiver extracts the domain part of the return address, and does a DNS query for the SPF record under that domain.

3) The terms in the SPF record are tested one at a time, left to right, and the first definite result (pass or fail) is accepted. The prefixes (+, -, ?) mean (pass, fail, neutral), with + being the default.

4) The Receiver adds an authentication header to the message:

  Received-SPF: Pass (mx1.example.org: domain of
   myname@example.com designates 192.168.33.35 as permitted sender)
      receiver=mx1.example.org; client-ip=192.168.33.35;
      envelope-from=<myname@example.com>; helo=foo.example.com;

5) If the message is forwarded. the forwarder is expected to rewrite the envelope return address so that an SPF check won't fail when the message is forwarded to the next agent. This is done using a related protocol, the Sender Rewriting Scheme (SRS). In this scheme, the forwarder's domain name is substituted for the domain part of the original, and the local part is a concatenation of various strings joined with = characters. These strings include authentication codes and the original return address.

 original:   MAIL FROM:<author@example.com>
 rewritten:  MAIL FROM:<SRS0+yf09=Cw=example.com=author@forwarder.com>


Explanatory notes

TXT is the code for a text record in DNS. Text records can store any text strings the domain owner wants to publish. SPF is a new record type, a TXT record just for SPF data. It will be necessary to publish both records until all DNS software is able to recognize the new type.

1800 seconds is the lifetime of the DNS record after it has left the server on which it was published. This allows frequently used records to be read from a cache, instead of doing a fresh query every time.

Everything between the double quotes is part of the text string, but not the quotes themselves. The string consists of a number of space-delimited terms. "v=spf1" means this is a record for version 1 of SPF.

The syntax for SPF includes a number of key=value pairs (or key:value). This syntax takes a little more space, but it allows for future growth of SPF by simply adding new key items.

The /28 in the ip4 terms is CIDR notation for a block of 16 addresses. The number 28 is the number of bits in a "mask", which is a bit pattern used in testing address ranges. Comparisons using a mask are faster than a general integer range test, but the blocks are limited to sizes that are a power of two (1, 2, 4, 8, 16, ...). CIDR notation is commonly used in routers, where speed is critical.

Bibliography