X-Git-Url: https://git.exim.org/users/jgh/exim.git/blobdiff_plain/7952eef9f77899f36b23f1b9fa679f459cd52ffd..d6c829b9a350f61c98196768e3260beb3cbecbfe:/doc/doc-txt/experimental-spec.txt diff --git a/doc/doc-txt/experimental-spec.txt b/doc/doc-txt/experimental-spec.txt index b77fb733f..2b77d2647 100644 --- a/doc/doc-txt/experimental-spec.txt +++ b/doc/doc-txt/experimental-spec.txt @@ -388,381 +388,6 @@ mout.gmx.net 212.227.15.16 Use a reasonable IP. eg. one the sending cluster actually uses. -DMARC Support --------------------------------------------------------------- - -DMARC combines feedback from SPF, DKIM, and header From: in order -to attempt to provide better indicators of the authenticity of an -email. This document does not explain the fundamentals, you -should read and understand how it works by visiting the website at -http://www.dmarc.org/. - -DMARC support is added via the libopendmarc library. Visit: - - http://sourceforge.net/projects/opendmarc/ - -to obtain a copy, or find it in your favorite rpm package -repository. If building from source, this description assumes -that headers will be in /usr/local/include, and that the libraries -are in /usr/local/lib. - -1. To compile Exim with DMARC support, you must first enable SPF. -Please read the above section on enabling the EXPERIMENTAL_SPF -feature. You must also have DKIM support, so you cannot set the -DISABLE_DKIM feature. Once both of those conditions have been met -you can enable DMARC in Local/Makefile: - -EXPERIMENTAL_DMARC=yes -LDFLAGS += -lopendmarc -# CFLAGS += -I/usr/local/include -# LDFLAGS += -L/usr/local/lib - -The first line sets the feature to include the correct code, and -the second line says to link the libopendmarc libraries into the -exim binary. The commented out lines should be uncommented if you -built opendmarc from source and installed in the default location. -Adjust the paths if you installed them elsewhere, but you do not -need to uncomment them if an rpm (or you) installed them in the -package controlled locations (/usr/include and /usr/lib). - - -2. Use the following global settings to configure DMARC: - -Optional: -dmarc_tld_file Defines the location of a text file of valid - top level domains the opendmarc library uses - during domain parsing. Maintained by Mozilla, - the most current version can be downloaded - from a link at http://publicsuffix.org/list/. - If unset, "/etc/exim/opendmarc.tlds" (hardcoded) - is used. - -Optional: -dmarc_history_file Defines the location of a file to log results - of dmarc verification on inbound emails. The - contents are importable by the opendmarc tools - which will manage the data, send out DMARC - reports, and expire the data. Make sure the - directory of this file is writable by the user - exim runs as. - -dmarc_forensic_sender The email address to use when sending a - forensic report detailing alignment failures - if a sender domain's dmarc record specifies it - and you have configured Exim to send them. - Default: do-not-reply@$default_hostname - - -3. By default, the DMARC processing will run for any remote, -non-authenticated user. It makes sense to only verify DMARC -status of messages coming from remote, untrusted sources. You can -use standard conditions such as hosts, senders, etc, to decide that -DMARC verification should *not* be performed for them and disable -DMARC with a control setting: - - control = dmarc_disable_verify - -A DMARC record can also specify a "forensic address", which gives -exim an email address to submit reports about failed alignment. -Exim does not do this by default because in certain conditions it -results in unintended information leakage (what lists a user might -be subscribed to, etc). You must configure exim to submit forensic -reports to the owner of the domain. If the DMARC record contains a -forensic address and you specify the control statement below, then -exim will send these forensic emails. It's also advised that you -configure a dmarc_forensic_sender because the default sender address -construction might be inadequate. - - control = dmarc_enable_forensic - -(AGAIN: You can choose not to send these forensic reports by simply -not putting the dmarc_enable_forensic control line at any point in -your exim config. If you don't tell it to send them, it will not -send them.) - -There are no options to either control. Both must appear before -the DATA acl. - - -4. You can now run DMARC checks in incoming SMTP by using the -"dmarc_status" ACL condition in the DATA ACL. You are required to -call the spf condition first in the ACLs, then the "dmarc_status" -condition. Putting this condition in the ACLs is required in order -for a DMARC check to actually occur. All of the variables are set -up before the DATA ACL, but there is no actual DMARC check that -occurs until a "dmarc_status" condition is encountered in the ACLs. - -The dmarc_status condition takes a list of strings on its -right-hand side. These strings describe recommended action based -on the DMARC check. To understand what the policy recommendations -mean, refer to the DMARC website above. Valid strings are: - - o accept The DMARC check passed and the library recommends - accepting the email. - o reject The DMARC check failed and the library recommends - rejecting the email. - o quarantine The DMARC check failed and the library recommends - keeping it for further inspection. - o none The DMARC check passed and the library recommends - no specific action, neutral. - o norecord No policy section in the DMARC record for this - sender domain. - o nofrom Unable to determine the domain of the sender. - o temperror Library error or dns error. - o off The DMARC check was disabled for this email. - -You can prefix each string with an exclamation mark to invert its -meaning, for example "!accept" will match all results but -"accept". The string list is evaluated left-to-right in a -short-circuit fashion. When a string matches the outcome of the -DMARC check, the condition succeeds. If none of the listed -strings matches the outcome of the DMARC check, the condition -fails. - -Of course, you can also use any other lookup method that Exim -supports, including LDAP, Postgres, MySQL, etc, as long as the -result is a list of colon-separated strings. - -Several expansion variables are set before the DATA ACL is -processed, and you can use them in this ACL. The following -expansion variables are available: - - o $dmarc_status - This is a one word status indicating what the DMARC library - thinks of the email. It is a combination of the results of - DMARC record lookup and the SPF/DKIM/DMARC processing results - (if a DMARC record was found). The actual policy declared - in the DMARC record is in a separate expansion variable. - - o $dmarc_status_text - This is a slightly longer, human readable status. - - o $dmarc_used_domain - This is the domain which DMARC used to look up the DMARC - policy record. - - o $dmarc_domain_policy - This is the policy declared in the DMARC record. Valid values - are "none", "reject" and "quarantine". It is blank when there - is any error, including no DMARC record. - - o $dmarc_ar_header - This is the entire Authentication-Results header which you can - add using an add_header modifier. - - -5. How to enable DMARC advanced operation: -By default, Exim's DMARC configuration is intended to be -non-intrusive and conservative. To facilitate this, Exim will not -create any type of logging files without explicit configuration by -you, the admin. Nor will Exim send out any emails/reports about -DMARC issues without explicit configuration by you, the admin (other -than typical bounce messages that may come about due to ACL -processing or failure delivery issues). - -In order to log statistics suitable to be imported by the opendmarc -tools, you need to: -a. Configure the global setting dmarc_history_file. -b. Configure cron jobs to call the appropriate opendmarc history - import scripts and truncating the dmarc_history_file. - -In order to send forensic reports, you need to: -a. Configure the global setting dmarc_forensic_sender. -b. Configure, somewhere before the DATA ACL, the control option to - enable sending DMARC forensic reports. - - -6. Example usage: -(RCPT ACL) - warn domains = +local_domains - hosts = +local_hosts - control = dmarc_disable_verify - - warn !domains = +screwed_up_dmarc_records - control = dmarc_enable_forensic - - warn condition = (lookup if destined to mailing list) - set acl_m_mailing_list = 1 - -(DATA ACL) - warn dmarc_status = accept : none : off - !authenticated = * - log_message = DMARC DEBUG: $dmarc_status $dmarc_used_domain - add_header = $dmarc_ar_header - - warn dmarc_status = !accept - !authenticated = * - log_message = DMARC DEBUG: '$dmarc_status' for $dmarc_used_domain - - warn dmarc_status = quarantine - !authenticated = * - set $acl_m_quarantine = 1 - # Do something in a transport with this flag variable - - deny condition = ${if eq{$dmarc_domain_policy}{reject}} - condition = ${if eq{$acl_m_mailing_list}{1}} - message = Messages from $dmarc_used_domain break mailing lists - - deny dmarc_status = reject - !authenticated = * - message = Message from $dmarc_used_domain failed sender's DMARC policy, REJECT - - - -DANE ------------------------------------------------------------- -DNS-based Authentication of Named Entities, as applied -to SMTP over TLS, provides assurance to a client that -it is actually talking to the server it wants to rather -than some attacker operating a Man In The Middle (MITM) -operation. The latter can terminate the TLS connection -you make, and make another one to the server (so both -you and the server still think you have an encrypted -connection) and, if one of the "well known" set of -Certificate Authorities has been suborned - something -which *has* been seen already (2014), a verifiable -certificate (if you're using normal root CAs, eg. the -Mozilla set, as your trust anchors). - -What DANE does is replace the CAs with the DNS as the -trust anchor. The assurance is limited to a) the possibility -that the DNS has been suborned, b) mistakes made by the -admins of the target server. The attack surface presented -by (a) is thought to be smaller than that of the set -of root CAs. - -It also allows the server to declare (implicitly) that -connections to it should use TLS. An MITM could simply -fail to pass on a server's STARTTLS. - -DANE scales better than having to maintain (and -side-channel communicate) copies of server certificates -for every possible target server. It also scales -(slightly) better than having to maintain on an SMTP -client a copy of the standard CAs bundle. It also -means not having to pay a CA for certificates. - -DANE requires a server operator to do three things: -1) run DNSSEC. This provides assurance to clients -that DNS lookups they do for the server have not -been tampered with. The domain MX record applying -to this server, its A record, its TLSA record and -any associated CNAME records must all be covered by -DNSSEC. -2) add TLSA DNS records. These say what the server -certificate for a TLS connection should be. -3) offer a server certificate, or certificate chain, -in TLS connections which is traceable to the one -defined by (one of?) the TSLA records - -There are no changes to Exim specific to server-side -operation of DANE. - -The TLSA record for the server may have "certificate -usage" of DANE-TA(2) or DANE-EE(3). The latter specifies -the End Entity directly, i.e. the certificate involved -is that of the server (and should be the sole one transmitted -during the TLS handshake); this is appropriate for a -single system, using a self-signed certificate. - DANE-TA usage is effectively declaring a specific CA -to be used; this might be a private CA or a public, -well-known one. A private CA at simplest is just -a self-signed certificate which is used to sign -cerver certificates, but running one securely does -require careful arrangement. If a private CA is used -then either all clients must be primed with it, or -(probably simpler) the server TLS handshake must transmit -the entire certificate chain from CA to server-certificate. -If a public CA is used then all clients must be primed with it -(losing one advantage of DANE) - but the attack surface is -reduced from all public CAs to that single CA. -DANE-TA is commonly used for several services and/or -servers, each having a TLSA query-domain CNAME record, -all of which point to a single TLSA record. - -The TLSA record should have a Selector field of SPKI(1) -and a Matching Type field of SHA2-512(2). - -At the time of writing, https://www.huque.com/bin/gen_tlsa -is useful for quickly generating TLSA records; and commands like - - openssl x509 -in -pubkey -noout /dev/null \ - | openssl sha512 \ - | awk '{print $2}' - -are workable for 4th-field hashes. - -For use with the DANE-TA model, server certificates -must have a correct name (SubjectName or SubjectAltName). - -The use of OCSP-stapling should be considered, allowing -for fast revocation of certificates (which would otherwise -be limited by the DNS TTL on the TLSA records). However, -this is likely to only be usable with DANE-TA. NOTE: the -default of requesting OCSP for all hosts is modified iff -DANE is in use, to: - - hosts_request_ocsp = ${if or { {= {0}{$tls_out_tlsa_usage}} \ - {= {4}{$tls_out_tlsa_usage}} } \ - {*}{}} - -The (new) variable $tls_out_tlsa_usage is a bitfield with -numbered bits set for TLSA record usage codes. -The zero above means DANE was not in use, -the four means that only DANE-TA usage TLSA records were -found. If the definition of hosts_request_ocsp includes the -string "tls_out_tlsa_usage", they are re-expanded in time to -control the OCSP request. - -This modification of hosts_request_ocsp is only done if -it has the default value of "*". Admins who change it, and -those who use hosts_require_ocsp, should consider the interaction -with DANE in their OCSP settings. - - -For client-side DANE there are two new smtp transport options, -hosts_try_dane and hosts_require_dane. -[ should they be domain-based rather than host-based? ] - -Hosts_require_dane will result in failure if the target host -is not DNSSEC-secured. - -DANE will only be usable if the target host has DNSSEC-secured -MX, A and TLSA records. - -A TLSA lookup will be done if either of the above options match -and the host-lookup succeeded using dnssec. -If a TLSA lookup is done and succeeds, a DANE-verified TLS connection -will be required for the host. If it does not, the host will not -be used; there is no fallback to non-DANE or non-TLS. - -If DANE is requested and useable (see above) the following transport -options are ignored: - hosts_require_tls - tls_verify_hosts - tls_try_verify_hosts - tls_verify_certificates - tls_crl - tls_verify_cert_hostnames - -If DANE is not usable, whether requested or not, and CA-anchored -verification evaluation is wanted, the above variables should be set -appropriately. - -Currently dnssec_request_domains must be active (need to think about that) -and dnssec_require_domains is ignored. - -If verification was successful using DANE then the "CV" item -in the delivery log line will show as "CV=dane". - -There is a new variable $tls_out_dane which will have "yes" if -verification succeeded using DANE and "no" otherwise (only useful -in combination with EXPERIMENTAL_EVENT), and a new variable -$tls_out_tlsa_usage (detailed above). - -Under GnuTLS, DANE is only supported from versin 3.0.0 onwards - DSN extra information @@ -861,6 +486,8 @@ an external directory retaining the exim spool format. The spool files can then be processed by external processes and then requeued into exim spool directories for final delivery. +However, note carefully the warnings in the main documentation on +qpool file formats. The motivation/inspiration for the transport is to allow external processes to access email queued by exim and have access to all the @@ -877,7 +504,7 @@ the queuefile driver. The transport only takes one option: * directory - This is used to specify the directory messages should be -copied to +copied to. Expanded. The generic transport options (body_only, current_directory, disable_logging, debug_print, delivery_date_add, envelope_to_add, event_action, group, @@ -910,6 +537,166 @@ to your Local/Makefile. (Re-)build/install exim. exim -d should show Experimental_QUEUEFILE in the line "Support for:". +ARC support +----------- +Specification: https://tools.ietf.org/html/draft-ietf-dmarc-arc-protocol-11 +Note that this is not an RFC yet, so may change. + +ARC is intended to support the utility of SPF and DKIM in the presence of +intermediaries in the transmission path - forwarders and mailinglists - +by establishing a cryptographically-signed chain in headers. + +Normally one would only bother doing ARC-signing when functioning as +an intermediary. One might do verify for local destinations. + +ARC uses the notion of a "ADministrative Management Domain" (ADMD). +Described in RFC 5598 (section 2.3), this is essentially the set of +mail-handling systems that the mail transits. A label should be chosen to +identify the ADMD. Messages should be ARC-verified on entry to the ADMD, +and ARC-signed on exit from it. + + +Verification +-- +An ACL condition is provided to perform the "verifier actions" detailed +in section 6 of the above specification. It may be called from the DATA ACL +and succeeds if the result matches any of a given list. +It also records the highest ARC instance number (the chain size) +and verification result for later use in creating an Authentication-Results: +standard header. + + verify = arc/ none:fail:pass + + add_header = :at_start:${authresults {}} + + Note that it would be wise to strip incoming messages of A-R headers + that claim to be from our own . + +There are four new variables: + + $arc_state One of pass, fail, none + $arc_state_reason (if fail, why) + $arc_domains colon-sep list of ARC chain domains, in chain order. + problematic elements may have empty list elements + $arc_oldest_pass lowest passing instance number of chain + +Example: + logwrite = oldest-p-ams: <${reduce {$lh_ARC-Authentication-Results:} \ + {} \ + {${if = {$arc_oldest_pass} \ + {${extract {i}{${extract {1}{;}{$item}}}}} \ + {$item} {$value}}} \ + }> + +Receive log lines for an ARC pass will be tagged "ARC". + + +Signing +-- +arc_sign = : : [ : ] +An option on the smtp transport, which constructs and prepends to the message +an ARC set of headers. The textually-first Authentication-Results: header +is used as a basis (you must have added one on entry to the ADMD). +Expanded as a whole; if unset, empty or forced-failure then no signing is done. +If it is set, all of the first three elements must be non-empty. + +The fourth element is optional, and if present consists of a comma-separated list +of options. The options implemented are + + timestamps Add a t= tag to the generated AMS and AS headers, with the + current time. + expire[=] Add an x= tag to the generated AMS header, with an expiry time. + If the value is an plain number it is used unchanged. + If it starts with a '+' then the following number is added + to the current time, as an offset in seconds. + If a value is not given it defaults to a one month offset. + +[As of writing, gmail insist that a t= tag on the AS is mandatory] + +Caveats: + * There must be an Authentication-Results header, presumably added by an ACL + while receiving the message, for the same ADMD, for arc_sign to succeed. + This requires careful coordination between inbound and outbound logic. + + Only one A-R header is taken account of. This is a limitation versus + the ARC spec (which says that all A-R headers from within the ADMD must + be used). + + * If passing a message to another system, such as a mailing-list manager + (MLM), between receipt and sending, be wary of manipulations to headers made + by the MLM. + + For instance, Mailman with REMOVE_DKIM_HEADERS==3 might improve + deliverability in a pre-ARC world, but that option also renames the + Authentication-Results header, which breaks signing. + + * Even if you use multiple DKIM keys for different domains, the ARC concept + should try to stick to one ADMD, so pick a primary domain and use that for + AR headers and outbound signing. + +Signing is not compatible with cutthrough delivery; any (before expansion) +value set for the option will result in cutthrough delivery not being +used via the transport in question. + + + + +TLS Session Resumption +---------------------- +TLS Session Resumption for TLS 1.2 and TLS 1.3 connections can be used (defined +in RFC 5077 for 1.2). The support for this can be included by building with +EXPERIMENTAL_TLS_RESUME defined. This requires GnuTLS 3.6.3 or OpenSSL 1.1.1 +(or later). + +Session resumption (this is the "stateless" variant) involves the server sending +a "session ticket" to the client on one connection, which can be stored by the +client and used for a later session. The ticket contains sufficient state for +the server to reconstruct the TLS session, avoiding some expensive crypto +calculation and one full packet roundtrip time. + +Operational cost/benefit: + The extra data being transmitted costs a minor amount, and the client has + extra costs in storing and retrieving the data. + + In the Exim/Gnutls implementation the extra cost on an initial connection + which is TLS1.2 over a loopback path is about 6ms on 2017-laptop class hardware. + The saved cost on a subsequent connection is about 4ms; three or more + connections become a net win. On longer network paths, two or more + connections will have an average lower startup time thanks to the one + saved packet roundtrip. TLS1.3 will save the crypto cpu costs but not any + packet roundtrips. + + Since a new hints DB is used, the hints DB maintenance should be updated + to additionally handle "tls". + +Security aspects: + The session ticket is encrypted, but is obviously an additional security + vulnarability surface. An attacker able to decrypt it would have access + all connections using the resumed session. + The session ticket encryption key is not committed to storage by the server + and is rotated regularly (OpenSSL: 1hr, and one previous key is used for + overlap; GnuTLS 6hr but does not specify any overlap). + Tickets have limited lifetime (2hr, and new ones issued after 1hr under + OpenSSL. GnuTLS 2hr, appears to not do overlap). + + There is a question-mark over the security of the Diffie-Helman parameters + used for session negotiation. TBD. q-value; cf bug 1895 + +Observability: + New log_selector "tls_resumption", appends an asterisk to the tls_cipher "X=" + element. + + Variables $tls_{in,out}_resumption have bits 0-4 indicating respectively + support built, client requested ticket, client offered session, + server issued ticket, resume used. A suitable decode list is provided + in the builtin macro _RESUME_DECODE for ${listextract {}{}}. + +Issues: + In a resumed session: + $tls_{in,out}_cipher will have values different to the original (under GnuTLS) + $tls_{in,out}_ocsp will be "not requested" or "no response", and + hosts_require_ocsp will fail + + -------------------------------------------------------------- End of file --------------------------------------------------------------