PPoossttffiixx lleeggaaccyy TTLLSS SSuuppppoorrtt ------------------------------------------------------------------------------- NNOOTTEE This document describes an old TLS user interface that is based on a third- party TLS patch by Lutz Ja"nicke. As of Postfix version 2.3, the old user interface still exists to allow migration from earlier Postfix releases, but its functionality is frozen. WWhhaatt PPoossttffiixx TTLLSS ssuuppppoorrtt ddooeess ffoorr yyoouu Transport Layer Security (TLS, formerly called SSL) provides certificate-based authentication and encrypted sessions. An encrypted session protects the information that is transmitted with SMTP mail or with SASL authentication. Postfix version 2.2 introduces support for TLS as described in RFC 3207. TLS Support for older Postfix versions was available as an add-on patch. The section "Compatibility with Postfix < 2.2 TLS support" below discusses the differences between these implementations. Topics covered in this document: * How Postfix TLS support works * Building Postfix with TLS support * SMTP Server specific settings * SMTP Client specific settings * TLS manager specific settings * Reporting problems * Compatibility with Postfix < 2.2 TLS support * Credits And last but not least, for the impatient: * Getting started, quick and dirty HHooww PPoossttffiixx TTLLSS ssuuppppoorrtt wwoorrkkss The diagram below shows the main elements of the Postfix TLS architecture and their relationships. Colored boxes with numbered names represent Postfix daemon programs. Other colored boxes represent storage elements. * The smtpd(8) server implements the SMTP over TLS server side. * The smtp(8) client implements the SMTP over TLS client side. * The tlsmgr(8) server maintains the pseudo-random number generator (PRNG) that seeds the TLS engines in the smtpd(8) server and smtp(8) client processes, and maintains the TLS session key cache files. <---seed--- ---seed---> Network-> smtpd(8) tlsmgr(8) smtp(8) ->Network <-session-> <-session-> / | \ | / \ smtpd PRNG smtp session state session key cache file key cache BBuuiillddiinngg PPoossttffiixx wwiitthh TTLLSS ssuuppppoorrtt To build Postfix with TLS support, first we need to generate the make(1) files with the necessary definitions. This is done by invoking the command "make makefiles" in the Postfix top-level directory and with arguments as shown next. NNOOTTEE:: DDoo nnoott uussee GGnnuu TTLLSS.. IItt wwiillll ssppoonnttaanneeoouussllyy tteerrmmiinnaattee aa PPoossttffiixx ddaaeemmoonn pprroocceessss wwiitthh eexxiitt ssttaattuuss ccooddee 22,, iinnsstteeaadd ooff aalllloowwiinngg PPoossttffiixx ttoo 11)) rreeppoorrtt tthhee eerrrroorr ttoo tthhee mmaaiilllloogg ffiillee,, aanndd ttoo 22)) pprroovviiddee ppllaaiinntteexxtt sseerrvviiccee wwhheerree tthhiiss iiss aapppprroopprriiaattee.. * If the OpenSSL include files (such as ssl.h) are in directory /usr/include/ openssl, and the OpenSSL libraries (such as libssl.so and libcrypto.so) are in directory /usr/lib: % mmaakkee ttiiddyy # if you have left-over files from a previous build % mmaakkee mmaakkeeffiilleess CCCCAARRGGSS==""--DDUUSSEE__TTLLSS"" AAUUXXLLIIBBSS==""--llssssll --llccrryyppttoo"" * If the OpenSSL include files (such as ssl.h) are in directory /usr/local/ include/openssl, and the OpenSSL libraries (such as libssl.so and libcrypto.so) are in directory /usr/local/lib: % mmaakkee ttiiddyy # if you have left-over files from a previous build % mmaakkee mmaakkeeffiilleess CCCCAARRGGSS==""--DDUUSSEE__TTLLSS --II//uussrr//llooccaall//iinncclluuddee"" \\ AAUUXXLLIIBBSS==""--LL//uussrr//llooccaall//lliibb --llssssll --llccrryyppttoo"" On Solaris, specify the -R option as shown below: % mmaakkee ttiiddyy # if you have left-over files from a previous build % mmaakkee mmaakkeeffiilleess CCCCAARRGGSS==""--DDUUSSEE__TTLLSS --II//uussrr//llooccaall//iinncclluuddee"" \\ AAUUXXLLIIBBSS==""--RR//uussrr//llooccaall//lliibb --LL//uussrr//llooccaall//lliibb --llssssll --llccrryyppttoo"" If you need to apply other customizations (such as Berkeley DB databases, MySQL, PosgreSQL, LDAP or SASL), see the respective Postfix README documents, and combine their "make makefiles" instructions with the instructions above: % mmaakkee ttiiddyy # if you have left-over files from a previous build % mmaakkee mmaakkeeffiilleess CCCCAARRGGSS==""--DDUUSSEE__TTLLSS \\ ((ootthheerr --DD oorr --II ooppttiioonnss))"" \\ AAUUXXLLIIBBSS==""--llssssll --llccrryyppttoo \\ ((ootthheerr --ll ooppttiioonnss ffoorr lliibbrraarriieess iinn //uussrr//lliibb)) \\ ((--LL//ppaatthh//nnaammee ++ --ll ooppttiioonnss ffoorr ootthheerr lliibbrraarriieess))"" To complete the build process, see the Postfix INSTALL instructions. Postfix has TLS support turned off by default, so you can start using Postfix as soon as it is installed. SSMMTTPP SSeerrvveerr ssppeecciiffiicc sseettttiinnggss Topics covered in this section: * Server-side certificate and private key configuration * Server-side TLS activity logging * Enabling TLS in the Postfix SMTP server * Client certificate verification * Supporting AUTH over TLS only * Server-side TLS session cache * Server access control * Server-side cipher controls * Miscellaneous server controls SSeerrvveerr--ssiiddee cceerrttiiffiiccaattee aanndd pprriivvaattee kkeeyy ccoonnffiigguurraattiioonn In order to use TLS, the Postfix SMTP server needs a certificate and a private key. Both must be in "pem" format. The private key must not be encrypted, meaning: the key must be accessible without a password. Both certificate and private key may be in the same file. Both RSA and DSA certificates are supported. Typically you will only have RSA certificates issued by a commercial CA. In addition, the tools supplied with OpenSSL will by default issue RSA certificates. You can have both at the same time, in which case the cipher used determines which certificate is presented. For Netscape and OpenSSL clients without special cipher choices, the RSA certificate is preferred. In order for remote SMTP clients to check the Postfix SMTP server certificates, the CA certificate (in case of a certificate chain, all CA certificates) must be available. You should add these certificates to the server certificate, the server certificate first, then the issuing CA(s). Example: the certificate for "server.dom.ain" was issued by "intermediate CA" which itself has a certificate issued by "root CA". Create the server.pem file with: % ccaatt sseerrvveerr__cceerrtt..ppeemm iinntteerrmmeeddiiaattee__CCAA..ppeemm >> sseerrvveerr..ppeemm A Postfix SMTP server certificate supplied here must be usable as an SSL server certificate and hence pass the "openssl verify -purpose sslserver ..." test. A client that trusts the root CA has a local copy of the root CA certificate, so it is not necessary to include the root CA certificate here. Leaving it out of the "server.pem" file reduces the overhead of the TLS exchange. If you want the Postfix SMTP server to accept remote SMTP client certificates issued by these CAs, append the root certificate to $smtpd_tls_CAfile or install it in the $smtpd_tls_CApath directory. When you configure trust in a root CA, it is not necessary to explicitly trust intermediary CAs signed by the root CA, unless $smtpd_tls_ccert_verifydepth is less than the number of CAs in the certificate chain for the clients of interest. With a verify depth of 1 you can only verify certificates directly signed by a trusted CA, and all trusted intermediary CAs need to be configured explicitly. With a verify depth of 2 you can verify clients signed by a root CA or a direct intermediary CA (so long as the client is correctly configured to supply its intermediate CA certificate). RSA key and certificate examples: /etc/postfix/main.cf: smtpd_tls_cert_file = /etc/postfix/server.pem smtpd_tls_key_file = $smtpd_tls_cert_file Their DSA counterparts: /etc/postfix/main.cf: smtpd_tls_dcert_file = /etc/postfix/server-dsa.pem smtpd_tls_dkey_file = $smtpd_tls_dcert_file To verify a remote SMTP client certificate, the Postfix SMTP server needs to trust the certificates of the issuing Certification Authorities. These certificates in "pem" format can be stored in a single $smtpd_tls_CAfile or in multiple files, one CA per file in the $smtpd_tls_CApath directory. If you use a directory, don't forget to create the necessary "hash" links with: # $$OOPPEENNSSSSLL__HHOOMMEE//bbiinn//cc__rreehhaasshh //ppaatthh//ttoo//ddiirreeccttoorryy The $smtpd_tls_CAfile contains the CA certificates of one or more trusted CAs. The file is opened (with root privileges) before Postfix enters the optional chroot jail and so need not be accessible from inside the chroot jail. Additional trusted CAs can be specified via the $smtpd_tls_CApath directory, in which case the certificates are read (with $mail_owner privileges) from the files in the directory when the information is needed. Thus, the $smtpd_tls_CApath directory needs to be accessible inside the optional chroot jail. When you configure Postfix to request client certificates (by setting $smtpd_tls_ask_ccert = yes), any certificates in $smtpd_tls_CAfile are sent to the client, in order to allow it to choose an identity signed by a CA you trust. If no $smtpd_tls_CAfile is specified, no preferred CA list is sent, and the client is free to choose an identity signed by any CA. Many clients use a fixed identity regardless of the preferred CA list and you may be able to reduce TLS negotiation overhead by installing client CA certificates mostly or only in $smtpd_tls_CApath. In the latter case you need not specify a $smtpd_tls_CAfile. Note, that unless client certificates are used to allow greater access to TLS authenticated clients, it is best to not ask for client certificates at all, as in addition to increased overhead some clients (notably in some cases qmail) are unable to complete the TLS handshake when client certificates are requested. Example: /etc/postfix/main.cf: smtpd_tls_CAfile = /etc/postfix/CAcert.pem smtpd_tls_CApath = /etc/postfix/certs SSeerrvveerr--ssiiddee TTLLSS aaccttiivviittyy llooggggiinngg To get additional information about Postfix SMTP server TLS activity you can increase the loglevel from 0..4. Each logging level also includes the information that is logged at a lower logging level. 0 Disable logging of TLS activity. 1 Log TLS handshake and certificate information. 2 Log levels during TLS negotiation. 3 Log hexadecimal and ASCII dump of TLS negotiation process 4 Log hexadecimal and ASCII dump of complete transmission after STARTTLS Use loglevel 3 only in case of problems. Use of loglevel 4 is strongly discouraged. Example: /etc/postfix/main.cf: smtpd_tls_loglevel = 0 To include information about the protocol and cipher used as well as the client and issuer CommonName into the "Received:" message header, set the smtpd_tls_received_header variable to true. The default is no, as the information is not necessarily authentic. Only information recorded at the final destination is reliable, since the headers may be changed by intermediate servers. Example: /etc/postfix/main.cf: smtpd_tls_received_header = yes EEnnaabblliinngg TTLLSS iinn tthhee PPoossttffiixx SSMMTTPP sseerrvveerr By default, TLS is disabled in the Postfix SMTP server, so no difference to plain Postfix is visible. Explicitly switch it on using "smtpd_use_tls = yes". Example: /etc/postfix/main.cf: smtpd_use_tls = yes With this, Postfix SMTP server announces STARTTLS support to SMTP clients, but does not require that clients use TLS encryption. Note: when an unprivileged user invokes "sendmail -bs", STARTTLS is never offered due to insufficient privileges to access the server private key. This is intended behavior. You can ENFORCE the use of TLS, so that the Postfix SMTP server announces STARTTLS and accepts no mail without TLS encryption, by setting "smtpd_enforce_tls = yes". According to RFC 2487 this MUST NOT be applied in case of a publicly-referenced Postfix SMTP server. This option is off by default and should only seldom be used. Example: /etc/postfix/main.cf: smtpd_enforce_tls = yes TLS is sometimes used in the non-standard "wrapper" mode where a server always uses TLS, instead of announcing STARTTLS support and waiting for clients to request TLS service. Some clients, namely Outlook [Express] prefer the "wrapper" mode. This is true for OE (Win32 < 5.0 and Win32 >=5.0 when run on a port<>25 and OE (5.01 Mac on all ports). It is strictly discouraged to use this mode from main.cf. If you want to support this service, enable a special port in master.cf and specify "- o smtpd_tls_wrappermode = yes" as an smtpd(8) command line option. Port 465 (smtps) was once chosen for this feature. Example: /etc/postfix/master.cf: smtps inet n - n - - smtpd -o smtpd_tls_wrappermode=yes -o smtpd_sasl_auth_enable=yes CClliieenntt cceerrttiiffiiccaattee vveerriiffiiccaattiioonn To receive a remote SMTP client certificate, the Postfix SMTP server must explicitly ask for one (any contents of $smtpd_tls_CAfile are also sent to the client as a hint for choosing a certificate from a suitable CA). Unfortunately, Netscape clients will either complain if no matching client certificate is available or will offer the user client a list of certificates to choose from. Additionally some MTAs (notably some versions of qmail) are unable to complete TLS negotiation when client certificates are requested, and abort the SMTP session. So this option is "off" by default. You will however need the certificate if you want to use certificate based relaying with, for example, the permit_tls_clientcerts feature. Example: /etc/postfix/main.cf: smtpd_tls_ask_ccert = no You may also decide to REQUIRE a remote SMTP client certificate before allowing TLS connections. This feature is included for completeness, and implies "smtpd_tls_ask_ccert = yes". Please be aware, that this will inhibit TLS connections without a proper client certificate and that it makes sense only when non-TLS submission is disabled (smtpd_enforce_tls = yes). Otherwise, clients could bypass the restriction by simply not using STARTTLS at all. When TLS is not enforced, the connection will be handled as if only "smtpd_tls_ask_ccert = yes" is specified, and a warning is logged. Example: /etc/postfix/main.cf: smtpd_tls_req_ccert = no A client certificate verification depth of 1 is sufficient if the certificate is directly issued by a CA listed in the CA file. The default value (5) should also suffice for longer chains (root CA issues special CA which then issues the actual certificate...) Example: /etc/postfix/main.cf: smtpd_tls_ccert_verifydepth = 5 SSuuppppoorrttiinngg AAUUTTHH oovveerr TTLLSS oonnllyy Sending AUTH data over an unencrypted channel poses a security risk. When TLS layer encryption is required (smtpd_enforce_tls = yes), the Postfix SMTP server will announce and accept AUTH only after the TLS layer has been activated with STARTTLS. When TLS layer encryption is optional (smtpd_enforce_tls = no), it may however still be useful to only offer AUTH when TLS is active. To maintain compatibility with non-TLS clients, the default is to accept AUTH without encryption. In order to change this behavior, set "smtpd_tls_auth_only = yes". Example: /etc/postfix/main.cf: smtpd_tls_auth_only = no SSeerrvveerr--ssiiddee TTLLSS sseessssiioonn ccaacchhee The Postfix SMTP server and the remote SMTP client negotiate a session, which takes some computer time and network bandwidth. By default, this session information is cached only in the smtpd(8) process actually using this session and is lost when the process terminates. To share the session information between multiple smtpd(8) processes, a persistent session cache can be used. You can specify any database type that can store objects of several kbytes and that supports the sequence operator. DBM databases are not suitable because they can only store small objects. The cache is maintained by the tlsmgr(8) process, so there is no problem with concurrent access. Session caching is highly recommended, because the cost of repeatedly negotiating TLS session keys is high. Example: /etc/postfix/main.cf: smtpd_tls_session_cache_database = btree:/etc/postfix/smtpd_scache As of version 2.5, Postfix will no longer maintain this file in a directory with non-Postfix ownership. As a migration aid, attempts to open such files are redirected to the Postfix-owned $data_directory, and a warning is logged. Cached Postfix SMTP server session information expires after a certain amount of time. Postfix/TLS does not use the OpenSSL default of 300s, but a longer time of 3600sec (=1 hour). RFC 2246 recommends a maximum of 24 hours. Example: /etc/postfix/main.cf: smtpd_tls_session_cache_timeout = 3600s SSeerrvveerr aacccceessss ccoonnttrrooll Postfix TLS support introduces three additional features for Postfix SMTP server access control: permit_tls_clientcerts Allow the remote SMTP client SMTP request if the client certificate passes verification, and if its fingerprint is listed in the list of client certificates (see relay_clientcerts discussion below). permit_tls_all_clientcerts Allow the remote client SMTP request if the client certificate passes verification. check_ccert_access type:table If the client certificate passes verification, use its fingerprint as a key for the specified access(5) table. The permit_tls_all_clientcerts feature must be used with caution, because it can result in too many access permissions. Use this feature only if a special CA issues the client certificates, and only if this CA is listed as a trusted CA. If other CAs are trusted, any owner of a valid client certificate would be authorized. The permit_tls_all_clientcerts feature can be practical for a specially created email relay server. It is however recommended to stay with the permit_tls_clientcerts feature and list all certificates via $relay_clientcerts, as permit_tls_all_clientcerts does not permit any control when a certificate must no longer be used (e.g. an employee leaving). Example: /etc/postfix/main.cf: smtpd_recipient_restrictions = ... permit_tls_clientcerts reject_unauth_destination ... The Postfix list manipulation routines give special treatment to whitespace and some other characters, making the use of certificate names impractical. Instead we use the certificate fingerprints as they are difficult to fake but easy to use for lookup. Postfix lookup tables are in the form of (key, value) pairs. Since we only need the key, the value can be chosen freely, e.g. the name of the user or host. Example: /etc/postfix/main.cf: relay_clientcerts = hash:/etc/postfix/relay_clientcerts /etc/postfix/relay_clientcerts: D7:04:2F:A7:0B:8C:A5:21:FA:31:77:E1:41:8A:EE:80 lutzpc.at.home SSeerrvveerr--ssiiddee cciipphheerr ccoonnttrroollss To influence the Postfix SMTP server cipher selection scheme, you can give cipherlist string. A detailed description would go too far here; please refer to the OpenSSL documentation. If you don't know what to do with it, simply don't touch it and leave the (openssl-)compiled in default! DO NOT USE " to enclose the string, specify just the string!!! Example: /etc/postfix/main.cf: smtpd_tls_cipherlist = DEFAULT If you want to take advantage of ciphers with EDH, DH parameters are needed. Instead of using the built-in DH parameters for both 1024bit and 512bit, it is better to generate "own" parameters, since otherwise it would "pay" for a possible attacker to start a brute force attack against parameters that are used by everybody. For this reason, the parameters chosen are already different from those distributed with other TLS packages. To generate your own set of DH parameters, use: % ooppeennssssll ggeennddhh --oouutt //eettcc//ppoossttffiixx//ddhh__11002244..ppeemm --22 --rraanndd //vvaarr//rruunn//eeggdd--ppooooll 11002244 % ooppeennssssll ggeennddhh --oouutt //eettcc//ppoossttffiixx//ddhh__551122..ppeemm --22 --rraanndd //vvaarr//rruunn//eeggdd--ppooooll 551122 Examples: /etc/postfix/main.cf: smtpd_tls_dh1024_param_file = /etc/postfix/dh_1024.pem smtpd_tls_dh512_param_file = /etc/postfix/dh_512.pem MMiisscceellllaanneeoouuss sseerrvveerr ccoonnttrroollss The smtpd_starttls_timeout parameter limits the time of Postfix SMTP server write and read operations during TLS startup and shutdown handshake procedures. Example: /etc/postfix/main.cf: smtpd_starttls_timeout = 300s SSMMTTPP CClliieenntt ssppeecciiffiicc sseettttiinnggss Topics covered in this section: * Client-side certificate and private key configuration * Client-side TLS activity logging * Client-side TLS session cache * Enabling TLS in the Postfix SMTP client * Requiring TLS encryption * Disabling server certificate verification * Per-site TLS policies * Closing a DNS loophole with per-site TLS policies * Discovering servers that support TLS * Server certificate verification depth * Client-side cipher controls * Miscellaneous client controls CClliieenntt--ssiiddee cceerrttiiffiiccaattee aanndd pprriivvaattee kkeeyy ccoonnffiigguurraattiioonn During TLS startup negotiation the Postfix SMTP client may present a certificate to the remote SMTP server. The Netscape client is rather clever here and lets the user select between only those certificates that match CA certificates offered by the remote SMTP server. As the Postfix SMTP client uses the "SSL_connect()" function from the OpenSSL package, this is not possible and we have to choose just one certificate. So for now the default is to use _no_ certificate and key unless one is explicitly specified here. Both RSA and DSA certificates are supported. You can have both at the same time, in which case the cipher used determines which certificate is presented. It is possible for the Postfix SMTP client to use the same key/certificate pair as the Postfix SMTP server. If a certificate is to be presented, it must be in "pem" format. The private key must not be encrypted, meaning: it must be accessible without a password. Both parts (certificate and private key) may be in the same file. In order for remote SMTP servers to verify the Postfix SMTP client certificates, the CA certificate (in case of a certificate chain, all CA certificates) must be available. You should add these certificates to the client certificate, the client certificate first, then the issuing CA(s). Example: the certificate for "client.example.com" was issued by "intermediate CA" which itself has a certificate of "root CA". Create the client.pem file with: % ccaatt cclliieenntt__cceerrtt..ppeemm iinntteerrmmeeddiiaattee__CCAA..ppeemm >> cclliieenntt..ppeemm A Postfix SMTP client certificate supplied here must be usable as an SSL client certificate and hence pass the "openssl verify -purpose sslclient ..." test. A server that trusts the root CA has a local copy of the root CA certificate, so it is not necessary to include the root CA certificate here. Leaving it out of the "client.pem" file reduces the overhead of the TLS exchange. If you want the Postfix SMTP client to accept remote SMTP server certificates issued by these CAs, append the root certificate to $smtp_tls_CAfile or install it in the $smtp_tls_CApath directory. When you configure trust in a root CA, it is not necessary to explicitly trust intermediary CAs signed by the root CA, unless $smtp_tls_scert_verifydepth is less than the number of CAs in the certificate chain for the servers of interest. With a verify depth of 1 you can only verify certificates directly signed by a trusted CA, and all trusted intermediary CAs need to be configured explicitly. With a verify depth of 2 you can verify servers signed by a root CA or a direct intermediary CA (so long as the server is correctly configured to supply its intermediate CA certificate). RSA key and certificate examples: /etc/postfix/main.cf: smtp_tls_cert_file = /etc/postfix/client.pem smtp_tls_key_file = $smtp_tls_cert_file Their DSA counterparts: /etc/postfix/main.cf: smtp_tls_dcert_file = /etc/postfix/client-dsa.pem smtp_tls_dkey_file = $smtp_tls_dcert_file To verify a remote SMTP server certificate, the Postfix SMTP client needs to trust the certificates of the issuing Certification Authorities. These certificates in "pem" format can be stored in a single $smtp_tls_CAfile or in multiple files, one CA per file in the $smtp_tls_CApath directory. If you use a directory, don't forget to create the necessary "hash" links with: # $$OOPPEENNSSSSLL__HHOOMMEE//bbiinn//cc__rreehhaasshh //ppaatthh//ttoo//ddiirreeccttoorryy The $smtp_tls_CAfile contains the CA certificates of one or more trusted CAs. The file is opened (with root privileges) before Postfix enters the optional chroot jail and so need not be accessible from inside the chroot jail. Additional trusted CAs can be specified via the $smtp_tls_CApath directory, in which case the certificates are read (with $mail_owner privileges) from the files in the directory when the information is needed. Thus, the $smtp_tls_CApath directory needs to be accessible inside the optional chroot jail. The choice between $smtp_tls_CAfile and $smtp_tls_CApath is a space/time tradeoff. If there are many trusted CAs, the cost of preloading them all into memory may not pay off in reduced access time when the certificate is needed. Example: /etc/postfix/main.cf: smtp_tls_CAfile = /etc/postfix/CAcert.pem smtp_tls_CApath = /etc/postfix/certs CClliieenntt--ssiiddee TTLLSS aaccttiivviittyy llooggggiinngg To get additional information about Postfix SMTP client TLS activity you can increase the loglevel from 0..4. Each logging level also includes the information that is logged at a lower logging level. 0 Disable logging of TLS activity. 1 Log TLS handshake and certificate information. 2 Log levels during TLS negotiation. 3 Log hexadecimal and ASCII dump of TLS negotiation process 4 Log hexadecimal and ASCII dump of complete transmission after STARTTLS Example: /etc/postfix/main.cf: smtp_tls_loglevel = 0 CClliieenntt--ssiiddee TTLLSS sseessssiioonn ccaacchhee The remote SMTP server and the Postfix SMTP client negotiate a session, which takes some computer time and network bandwidth. By default, this session information is cached only in the smtp(8) process actually using this session and is lost when the process terminates. To share the session information between multiple smtp(8) processes, a persistent session cache can be used. You can specify any database type that can store objects of several kbytes and that supports the sequence operator. DBM databases are not suitable because they can only store small objects. The cache is maintained by the tlsmgr(8) process, so there is no problem with concurrent access. Session caching is highly recommended, because the cost of repeatedly negotiating TLS session keys is high. Future Postfix SMTP servers may limit the number of sessions that a client is allowed to negotiate per unit time. Example: /etc/postfix/main.cf: smtp_tls_session_cache_database = btree:/etc/postfix/smtp_scache As of version 2.5, Postfix will no longer maintain this file in a directory with non-Postfix ownership. As a migration aid, attempts to open such files are redirected to the Postfix-owned $data_directory, and a warning is logged. Cached Postfix SMTP client session information expires after a certain amount of time. Postfix/TLS does not use the OpenSSL default of 300s, but a longer time of 3600s (=1 hour). RFC 2246 recommends a maximum of 24 hours. Example: /etc/postfix/main.cf: smtp_tls_session_cache_timeout = 3600s EEnnaabblliinngg TTLLSS iinn tthhee PPoossttffiixx SSMMTTPP cclliieenntt By default, TLS is disabled in the Postfix SMTP client, so no difference to plain Postfix is visible. If you enable TLS, the Postfix SMTP client will send STARTTLS when TLS support is announced by the remote SMTP server. When the server accepts the STARTTLS command, but the subsequent TLS handshake fails, and no other server is available, the Postfix SMTP client defers the delivery attempt, and the mail stays in the queue. After a handshake failure, the communications channel is in an indeterminate state and cannot be used for non-TLS deliveries. Example: /etc/postfix/main.cf: smtp_use_tls = yes RReeqquuiirriinngg TTLLSS eennccrryyppttiioonn You can ENFORCE the use of TLS, so that the Postfix SMTP client will not deliver mail over unencrypted connections. In this mode, the remote SMTP server hostname must match the information in the remote server certificate, and the server certificate must be issued by a CA that is trusted by the Postfix SMTP client. If the remote server certificate doesn't verify or the remote SMTP server hostname doesn't match, and no other server is available, the delivery attempt is deferred and the mail stays in the queue. The remote SMTP server hostname is verified against all names provided as dNSNames in the SubjectAlternativeName. If no dNSNames are specified, the CommonName is checked. Verification may be turned off with the smtp_tls_enforce_peername option which is discussed below. Enforcing the use of TLS is useful if you know that you will only connect to servers that support RFC 2487 _and_ that present server certificates that meet the above requirements. An example would be a client only sends email to one specific mailhub that offers the necessary STARTTLS support. Example: /etc/postfix/main.cf: smtp_enforce_tls = yes DDiissaabblliinngg sseerrvveerr cceerrttiiffiiccaattee vveerriiffiiccaattiioonn As of RFC 2487 the requirements for hostname checking for MTA clients are not set. When TLS is required (smtp_enforce_tls = yes), the option smtp_tls_enforce_peername can be set to "no" to disable strict remote SMTP server hostname checking. In this case, the mail delivery will proceed regardless of the CommonName etc. listed in the certificate. Despite the potential for eliminating "man-in-the-middle" and other attacks, mandatory certificate/peername verification is not viable as a default Internet mail delivery policy at this time. A significant fraction of TLS enabled MTAs uses self-signed certificates, or certificates that are signed by a private Certification Authority. On a machine that delivers mail to the Internet, if you set smtp_enforce_tls = yes, you should probably also set smtp_tls_enforce_peername = no. You can use the per-site TLS policies (see below) to enable full peer verification for specific destinations that are known to have verifiable TLS server certificates. Example: /etc/postfix/main.cf: smtp_enforce_tls = yes smtp_tls_enforce_peername = no PPeerr--ssiittee TTLLSS ppoolliicciieess A small fraction of servers offer STARTTLS but the negotiation consistently fails, leading to mail aging out of the queue and bouncing back to the sender. In such cases, you can use the per-site policies to disable TLS for the problem sites. Alternatively, you can enable TLS for just a few specific sites and not enable it for all sites. The smtp_tls_per_site table is searched for a policy that matches the following information: remote SMTP server hostname This is simply the DNS name of the server that the Postfix SMTP client connects to; this name may be obtained from other DNS lookups, such as MX lookups or CNAME lookups. next-hop destination This is normally the domain portion of the recipient address, but it may be overruled by information from the transport(5) table, from the relayhost parameter setting, or from the relay_transport setting. When it's not the recipient domain, the next-hop destination can have the Postfix-specific form "[name]", [name]:port", "name" or "name:port". When both the hostname lookup and the next-hop lookup succeed, the host policy does not automatically override the next-hop policy. Instead, precedence is given to either the more specific or the more secure per-site policy as described below. The smtp_tls_per_site table uses a simple "name whitespace value" format. Specify host names or next-hop destinations on the left-hand side; no wildcards are allowed. On the right hand side specify one of the following keywords: NONE Don't use TLS at all. This overrides a less specific MMAAYY lookup result from the alternate host or next-hop lookup key, and overrides the global smtp_use_tls, smtp_enforce_tls, and smtp_tls_enforce_peername settings. MAY Try to use TLS if the server announces support, otherwise use the unencrypted connection. This has less precedence than a more specific result (including NNOONNEE) from the alternate host or next-hop lookup key, and has less precedence than the more specific global "smtp_enforce_tls = yes" or "smtp_tls_enforce_peername = yes". MUST_NOPEERMATCH Require TLS encryption, but do not require that the remote SMTP server hostname matches the information in the remote SMTP server certificate, or that the server certificate was issued by a trusted CA. This overrides a less secure NNOONNEE or a less specific MMAAYY lookup result from the alternate host or next-hop lookup key, and overrides the global smtp_use_tls, smtp_enforce_tls and smtp_tls_enforce_peername settings. MUST Require TLS encryption, require that the remote SMTP server hostname matches the information in the remote SMTP server certificate, and require that the remote SMTP server certificate was issued by a trusted CA. This overrides a less secure NNOONNEE and MMUUSSTT__NNOOPPEEEERRMMAATTCCHH or a less specific MMAAYY lookup result from the alternate host or next-hop lookup key, and overrides the global smtp_use_tls, smtp_enforce_tls and smtp_tls_enforce_peername settings. The precedences between global (main.cf) and per-site TLS policies can be summarized as follows: * When neither the remote SMTP server hostname nor the next-hop destination are found in the smtp_tls_per_site table, the policy is based on smtp_use_tls, smtp_enforce_tls and smtp_tls_enforce_peername. Note: "smtp_enforce_tls = yes" and "smtp_tls_enforce_peername = yes" imply "smtp_use_tls = yes". * When both hostname and next-hop destination lookups produce a result, the more specific per-site policy (NONE, MUST, etc.) overrides the less specific one (MAY), and the more secure per-site policy (MUST, etc.) overrides the less secure one (NONE). * After the per-site policy lookups are combined, the result generally overrides the global policy. The exception is the less specific MMAAYY per- site policy, which is overruled by the more specific global "smtp_enforce_tls = yes" with server certificate verification as specified with the smtp_tls_enforce_peername parameter. CClloossiinngg aa DDNNSS lloooopphhoollee wwiitthh ppeerr--ssiittee TTLLSS ppoolliicciieess As long as no secure DNS lookup mechanism is available, false hostnames in MX or CNAME responses can change the server hostname that Postfix uses for TLS policy lookup and server certificate verification. Even with a perfect match between the server hostname and the server certificate, there is no guarantee that Postfix is connected to the right server. To avoid this loophole take the following steps: * Eliminate MX lookups. Specify local transport(5) table entries for sensitive domains with explicit smtp:[mailhost] or smtp:[mailhost]:port destinations (you can assure security of this table unlike DNS); in the smtp_tls_per_site table specify the value MMUUSSTT for the key [mailhost] or smtp:[mailhost]:port. This prevents false hostname information in DNS MX records from changing the server hostname that Postfix uses for TLS policy lookup and server certificate verification. * Disallow CNAME hostname overrides. In main.cf specify "smtp_cname_overrides_servername = no". This prevents false hostname information in DNS CNAME records from changing the server hostname that Postfix uses for TLS policy lookup and server certificate verification. This feature requires Postfix 2.2.9 or later. Example: /etc/postfix/main.cf: smtp_tls_per_site = hash:/etc/postfix/tls_per_site relayhost = [msa.example.net]:587 /etc/postfix/tls_per_site: # relayhost exact nexthop match [msa.example.net]:587 MUST # TLS should not be used with the example.org MX hosts. example.org NONE # TLS should not be used with the host smtp.example.com. [smtp.example.com] NONE DDiissccoovveerriinngg sseerrvveerrss tthhaatt ssuuppppoorrtt TTLLSS As we decide on a "per site" basis whether or not to use TLS, it would be good to have a list of sites that offered "STARTTLS". We can collect it ourselves with this option. If the smtp_tls_note_starttls_offer feature is enabled and a server offers STARTTLS while TLS is not already enabled for that server, the Postfix SMTP client logs a line as follows: postfix/smtp[pid]: Host offered STARTTLS: [hostname.example.com] Example: /etc/postfix/main.cf: smtp_tls_note_starttls_offer = yes SSeerrvveerr cceerrttiiffiiccaattee vveerriiffiiccaattiioonn ddeepptthh When verifying a remote SMTP server certificate, a verification depth of 1 is sufficient if the certificate is directly issued by a CA specified with smtp_tls_CAfile or smtp_tls_CApath. The default value of 5 should also suffice for longer chains (root CA issues special CA which then issues the actual certificate...) Example: /etc/postfix/main.cf: smtp_tls_scert_verifydepth = 5 CClliieenntt--ssiiddee cciipphheerr ccoonnttrroollss To influence the Postfix SMTP client cipher selection scheme, you can give cipherlist string. A detailed description would go too far here; please refer to the OpenSSL documentation. If you don't know what to do with it, simply don't touch it and leave the (openssl-)compiled in default! DO NOT USE " to enclose the string, specify just the string!!! Example: /etc/postfix/main.cf: smtp_tls_cipherlist = DEFAULT MMiisscceellllaanneeoouuss cclliieenntt ccoonnttrroollss The smtp_starttls_timeout parameter limits the time of Postfix SMTP client write and read operations during TLS startup and shutdown handshake procedures. In case of problems the Postfix SMTP client tries the next network address on the mail exchanger list, and defers delivery if no alternative server is available. Example: /etc/postfix/main.cf: smtp_starttls_timeout = 300s TTLLSS mmaannaaggeerr ssppeecciiffiicc sseettttiinnggss The security of cryptographic software such as TLS depends critically on the ability to generate unpredictable numbers for keys and other information. To this end, the tlsmgr(8) process maintains a Pseudo Random Number Generator (PRNG) pool. This is queried by the smtp(8) and smtpd(8) processes when they initialize. By default, these daemons request 32 bytes, the equivalent to 256 bits. This is more than sufficient to generate a 128bit (or 168bit) session key. Example: /etc/postfix/main.cf: tls_daemon_random_bytes = 32 In order to feed its in-memory PRNG pool, the tlsmgr(8) reads entropy from an external source, both at startup and during run-time. Specify a good entropy source, like EGD or /dev/urandom; be sure to only use non-blocking sources (on OpenBSD, use /dev/arandom when tlsmgr(8) complains about /dev/urandom timeout errors). If the entropy source is not a regular file, you must prepend the source type to the source name: "dev:" for a device special file, or "egd:" for a source with EGD compatible socket interface. Examples (specify only one in main.cf): /etc/postfix/main.cf: tls_random_source = dev:/dev/urandom tls_random_source = egd:/var/run/egd-pool By default, tlsmgr(8) reads 32 bytes from the external entropy source at each seeding event. This amount (256bits) is more than sufficient for generating a 128bit symmetric key. With EGD and device entropy sources, the tlsmgr(8) limits the amount of data read at each step to 255 bytes. If you specify a regular file as entropy source, a larger amount of data can be read. Example: /etc/postfix/main.cf: tls_random_bytes = 32 In order to update its in-memory PRNG pool, the tlsmgr(8) queries the external entropy source again after a pseudo-random amount of time. The time is calculated using the PRNG, and is between 0 and the maximal time specified with tls_random_reseed_period. The default maximal time interval is 1 hour. Example: /etc/postfix/main.cf: tls_random_reseed_period = 3600s The tlsmgr(8) process saves the PRNG state to a persistent exchange file at regular times and when the process terminates, so that it can recover the PRNG state the next time it starts up. This file is created when it does not exist. Its default location is under the Postfix configuration directory, which is not the proper place for information that is modified by Postfix. Instead, the file location should probably be on the /var partition (but nnoott inside the chroot jail). Examples: /etc/postfix/main.cf: tls_random_exchange_name = /etc/postfix/prng_exch tls_random_prng_update_period = 3600s GGeettttiinngg ssttaarrtteedd,, qquuiicckk aanndd ddiirrttyy The following steps will get you started quickly. Because you sign your own Postfix public key certificate, you get TLS encryption but no TLS authentication. This is sufficient for testing, and for exchanging email with sites that you have no trust relationship with. For real authentication, your Postfix public key certificate needs to be signed by a recognized Certification Authority, and Postfix needs to be configured with a list of public key certificates of Certification Authorities, so that Postfix can verify the public key certificates of remote hosts. In the examples below, user input is shown in bboolldd font, and a "#" prompt indicates a super-user shell. * Become your own Certification Authority, so that you can sign your own public keys. This example uses the CA.pl script that ships with OpenSSL. By default, OpenSSL installs this as /usr/local/ssl/misc/CA.pl, but your mileage may vary. The script creates a private key in ./demoCA/private/ cakey.pem and a public key in ./demoCA/cacert.pem. % //uussrr//llooccaall//ssssll//mmiisscc//CCAA..ppll --nneewwccaa CA certificate filename (or enter to create) Making CA certificate ... Using configuration from /etc/ssl/openssl.cnf Generating a 1024 bit RSA private key ....................++++++ .....++++++ writing new private key to './demoCA/private/cakey.pem' Enter PEM pass phrase:wwhhaatteevveerr * Create an unpassworded private key for host FOO and create an unsigned public key certificate. % ooppeennssssll rreeqq --nneeww --nnooddeess --kkeeyyoouutt FFOOOO--kkeeyy..ppeemm --oouutt FFOOOO--rreeqq..ppeemm --ddaayyss 336655 Using configuration from /etc/ssl/openssl.cnf Generating a 1024 bit RSA private key ........................................++++++ ....++++++ writing new private key to 'FOO-key.pem' ----- You are about to be asked to enter information that will be incorporated into your certificate request. What you are about to enter is what is called a Distinguished Name or a DN. There are quite a few fields but you can leave some blank For some fields there will be a default value, If you enter '.', the field will be left blank. ----- Country Name (2 letter code) [AU]:UUSS State or Province Name (full name) [Some-State]:NNeeww YYoorrkk Locality Name (eg, city) []:WWeessttcchheesstteerr Organization Name (eg, company) [Internet Widgits Pty Ltd]:PPoorrccuuppiinnee Organizational Unit Name (eg, section) []: Common Name (eg, YOUR name) []:FFOOOO Email Address []:wwiieettssee@@ppoorrccuuppiinnee..oorrgg Please enter the following 'extra' attributes to be sent with your certificate request A challenge password []:wwhhaatteevveerr An optional company name []: * Sign the public key certificate for host FOO with the Certification Authority private key that we created a few steps ago. % ooppeennssssll ccaa --oouutt FFOOOO--cceerrtt..ppeemm --iinnffiilleess FFOOOO--rreeqq..ppeemm Uing configuration from /etc/ssl/openssl.cnf Enter PEM pass phrase:wwhhaatteevveerr Check that the request matches the signature Signature ok The Subjects Distinguished Name is as follows countryName :PRINTABLE:'US' stateOrProvinceName :PRINTABLE:'New York' localityName :PRINTABLE:'Westchester' organizationName :PRINTABLE:'Porcupine' commonName :PRINTABLE:'FOO' emailAddress :IA5STRING:'wietse@porcupine.org' Certificate is to be certified until Nov 21 19:40:56 2005 GMT (365 days) Sign the certificate? [y/n]:yy 1 out of 1 certificate requests certified, commit? [y/n]yy Write out database with 1 new entries Data Base Updated * Install the host private key, the host public key certificate, and the Certification Authority certificate files. This requires super-user privileges. # ccpp ddeemmooCCAA//ccaacceerrtt..ppeemm FFOOOO--kkeeyy..ppeemm FFOOOO--cceerrtt..ppeemm //eettcc//ppoossttffiixx # cchhmmoodd 664444 //eettcc//ppoossttffiixx//FFOOOO--cceerrtt..ppeemm //eettcc//ppoossttffiixx//ccaacceerrtt..ppeemm # cchhmmoodd 440000 //eettcc//ppoossttffiixx//FFOOOO--kkeeyy..ppeemm * Configure Postfix, by adding the following to /etc/postfix/main.cf. smtp_tls_CAfile = /etc/postfix/cacert.pem smtp_tls_cert_file = /etc/postfix/FOO-cert.pem smtp_tls_key_file = /etc/postfix/FOO-key.pem smtp_tls_session_cache_database = btree:/var/run/smtp_tls_session_cache smtp_use_tls = yes smtpd_tls_CAfile = /etc/postfix/cacert.pem smtpd_tls_cert_file = /etc/postfix/FOO-cert.pem smtpd_tls_key_file = /etc/postfix/FOO-key.pem smtpd_tls_received_header = yes smtpd_tls_session_cache_database = btree:/var/run/ smtpd_tls_session_cache smtpd_use_tls = yes tls_random_source = dev:/dev/urandom RReeppoorrttiinngg pprroobblleemmss When reporting a problem, please be thorough in the report. Patches, when possible, are greatly appreciated too. Please differentiate when possible between: * Problems in the TLS code: * Problems in vanilla Postfix: CCoommppaattiibbiilliittyy wwiitthh PPoossttffiixx << 22..22 TTLLSS ssuuppppoorrtt Postfix version 2.2 TLS support is based on the Postfix/TLS patch by Lutz Ja"nicke, but differs in a few minor ways. * main.cf: Specify "btree" instead of "sdbm" for TLS session cache databases. TLS session cache databases are now accessed only by the tlsmgr(8) process, so there are no more concurrency issues. Although Postfix has an sdbm client, the sdbm library (1000 lines of code) is not included with Postfix. TLS session caches can use any database that can store objects of several kbytes or more, and that implements the sequence operation. In most cases, btree databases should be adequate. NOTE: You cannot use dbm databases. TLS session objects are too large. * master.cf: Specify "unix" instead of "fifo" as the tlsmgr service type. The smtp(8) and smtpd(8) processes now use a client-server protocol in order to access the tlsmgr(8) pseudo-random number generation (PRNG) pool, and in order to access the TLS session cache databases. Such a protocol cannot be run across fifos. * smtp_tls_per_site: the MUST_NOPEERMATCH per-site policy cannot override the global "smtp_tls_enforce_peername = yes" setting. * smtp_tls_per_site: a combined (NONE + MAY) lookup result for (hostname and next-hop destination) produces counter-intuitive results for different main.cf settings. TLS is enabled with "smtp_tls_enforce_peername = no", but it is disabled when both "smtp_enforce_tls = yes" and "smtp_tls_enforce_peername = yes". The smtp_tls_per_site limitations were removed by the end of the Postfix 2.2 support cycle. CCrreeddiittss * TLS support for Postfix was originally developed by Lutz Ja"nicke at Cottbus Technical University. * Wietse Venema adopted the code, did some restructuring, and compiled this part of the documentation from Lutz's documents. * Victor Duchovni was instrumental with the re-implementation of the smtp_tls_per_site code in terms of enforcement levels, which simplified the implementation greatly.