#!/bin/sh #++ # NAME # postfix-tls 1 # SUMMARY # Postfix TLS management # SYNOPSIS # \fBpostfix tls\fR \fIsubcommand\fR # DESCRIPTION # The "\fBpostfix tls \fIsubcommand\fR" feature enables # opportunistic TLS in the Postfix SMTP client or server, and # manages Postfix SMTP server private keys and certificates. # # The following subcommands are available: # .IP "\fBenable-client\fR [\fB-r \fIrandsource\fR]" # Enable opportunistic TLS in the Postfix SMTP client, if all # SMTP client TLS settings are at their default values. # Otherwise, suggest parameter settings without making any # changes. # .sp # Specify \fIrandsource\fR to update the value of the # \fBtls_random_source\fR configuration parameter (typically, # /dev/urandom). Prepend \fBdev:\fR to device paths or # \fBegd:\fR to EGD socket paths. # .sp # See also the \fBall-default-client\fR subcommand. # .IP "\fBenable-server\fR [\fB-r \fIrandsource\fR] [\fB-a \fIalgorithm\fR] [\fB-b \fIbits\fR] [\fIhostname\fB...\fR]" # Create a new private key and self-signed server certificate # and enable opportunistic TLS in the Postfix SMTP server, # if all SMTP server TLS settings are at their default values. # Otherwise, suggest parameter settings without making any # changes. # .sp # The \fIrandsource\fR parameter is as with \fBenable-client\fR # above, and the remaining options are as with \fBnew-server-key\fR # below. # .sp # See also the \fBall-default-server\fR subcommand. # .IP "\fBnew-server-key\fR [\fB-a \fIalgorithm\fR] [\fB-b \fIbits\fR] [\fIhostname\fB...\fR]" # Create a new private key and self-signed server certificate, # but do not deploy them. Log and display commands to deploy # the new key and corresponding certificate. Also log and # display commands to output a corresponding CSR or TLSA # records which may be needed to obtain a CA certificate or # to update DNS before the new key can be deployed. # .sp # The \fIalgorithm\fR defaults to \fBrsa\fR, and \fIbits\fR # defaults to 2048. If you choose the \fBecdsa\fR \fIalgorithm\fR # then \fIbits\fR will be an EC curve name (by default # \fBsecp256r1\fR, also known as prime256v1). Curves other # than \fBsecp256r1\fR, \fBsecp384r1\fR or \fBsecp521r1\fR # are unlikely to be widely interoperable. When generating # EC keys, use one of these three. DSA keys are obsolete and # are not supported. # .sp # Note: ECDSA support requires OpenSSL 1.0.0 or later and may # not be available on your system. Not all client systems # will support ECDSA, so you'll generally want to deploy both # RSA and ECDSA certificates to make use of ECDSA with # compatible clients and RSA with the rest. If you want to # deploy certificate chains with intermediate CAs for both # RSA and ECDSA, you'll want at least OpenSSL 1.0.2, as earlier # versions may not handle multiple chain files correctly. # .sp # The first \fIhostname\fR argument will be the \fBCommonName\fR # of both the subject and issuer of the self-signed certificate. # It, and any additional \fIhostname\fR arguments, will also # be listed as DNS alternative names in the certificate. If # no \fIhostname\fR is provided the value of the \fBmyhostname\fR # main.cf parameter will be used. # .sp # For RSA, the generated private key and certificate files # are named \fBkey-\fIyyyymmdd-hhmmss\fB.pem\fR and # \fBcert-\fIyyyymmdd-hhmmss\fB.pem\fR, where \fIyyyymmdd\fR # is the calendar date and \fIhhmmss\fR is the time of day # in UTC. For ECDSA, the file names start with \fBeckey-\fR # and \fBeccert-\fR instead of \fBkey-\fR and \fBcert-\fR # respectively. # .sp # Before deploying the new key and certificate with DANE, # update the DNS with new DANE TLSA records, then wait for # secondary nameservers to update and then for stale records # in remote DNS caches to expire. # .sp # Before deploying a new CA certificate make sure to include # all the required intermediate issuing CA certificates in # the certificate chain file. The server certificate must # be the first certificate in the chain file. Overwrite and # deploy the file with the original self-signed certificate # that was generated together with the key. # .IP "\fBnew-server-cert\fR [\fB-a \fIalgorithm\fR] [\fB-b \fIbits\fR] [\fIhostname\fB...\fR]" # This is just like \fBnew-server-key\fR except that, rather # than generating a new private key, any currently deployed # private key is copied to the new key file. Thus if you're # publishing DANE TLSA "3 1 1" or "3 1 2" records, there is # no need to update DNS records. The \fIalgorithm\fR and # \fIbits\fR arguments are used only if no key of the same # algorithm is already configured. # .sp # This command is rarely needed, because the self-signed # certificates generated have a 100-year nominal expiration # time. The underlying public key algorithms may well be # obsoleted by quantum computers long before then. # .sp # The most plausible reason for using this command is when # the system hostname changes, and you'd like the name in the # certificate to match the new hostname (not required for # DANE "3 1 1", but some needlessly picky non-DANE opportunistic # TLS clients may log warnings or even refuse to communicate). # .IP "\fBdeploy-server-cert \fIcertfile\fB \fIkeyfile\fR" # This subcommand deploys the certificates in \fIcertfile\fR # and private key in \fIkeyfile\fR (which are typically # generated by the commands above, which will also log and # display the full command needed to deploy the generated key # and certificate). After the new certificate and key are # deployed any obsolete keys and certificates may be removed # by hand. The \fIkeyfile\fR and \fIcertfile\fR filenames # may be relative to the Postfix configuration directory. # .IP "\fBoutput-server-csr\fR [\fB-k \fIkeyfile\fR] [\fIhostname\fB...\fR]" # Write to stdout a certificate signing request (CSR) for the # specified \fIkeyfile\fR. # .sp # Instead of an absolute pathname or a pathname relative to # $config_directory, \fIkeyfile\fR may specify one of the # supported key algorithm names (see "\fBpostconf -T # public-key-algorithms\fR"). In that case, the corresponding # setting from main.cf is used to locate the \fIkeyfile\fR. # The default \fIkeyfile\fR value is \fBrsa\fR. # .sp # Zero or more \fIhostname\fR values can be specified. The # default \fIhostname\fR is the value of \fBmyhostname\fR # main.cf parameter. # .IP "\fBoutput-server-tlsa\fR [\fB-h \fIhostname\fR] [\fIkeyfile\fB...\fR]" # Write to stdout a DANE TLSA RRset suitable for a port 25 # SMTP server on host \fIhostname\fR with keys from any of # the specified \fIkeyfile\fR values. The default \fIhostname\fR # is the value of the \fBmyhostname\fR main.cf parameter. # .sp # Instead of absolute pathnames or pathnames relative to # $config_directory, the \fIkeyfile\fR list may specify # names of supported public key algorithms (see "\fBpostconf # -T public-key-algorithms\fR"). In that case, the actual # \fIkeyfile\fR list uses the values of the corresponding # Postfix server TLS key file parameters. If a parameter # value is empty or equal to \fBnone\fR, then no TLSA record # is output for that algorithm. # .sp # The default \fIkeyfile\fR list consists of the two supported # algorithms \fBrsa\fR and \fBecdsa\fR. # AUXILIARY COMMANDS # .IP "\fBall-default-client\fR" # Exit with status 0 (success) if all SMTP client TLS settings are # at their default values. Otherwise, exit with a non-zero status. # This is typically used as follows: # .sp # \fBpostfix tls all-default-client && # postfix tls enable-client\fR # .IP "\fBall-default-server\fR" # Exit with status 0 (success) if all SMTP server TLS settings are # at their default values. Otherwise, exit with a non-zero status. # This is typically used as follows: # .sp # \fBpostfix tls all-default-server && # postfix tls enable-server\fR # CONFIGURATION PARAMETERS # .ad # .fi # The "\fBpostfix tls \fIsubcommand\fR" feature reads # or updates the following configuration parameters. # .IP "\fBcommand_directory (see 'postconf -d' output)\fR" # The location of all postfix administrative commands. # .IP "\fBconfig_directory (see 'postconf -d' output)\fR" # The default location of the Postfix main.cf and master.cf # configuration files. # .IP "\fBopenssl_path (openssl)\fR" # The location of the OpenSSL command line program \fBopenssl\fR(1). # .IP "\fBsmtp_tls_loglevel (0)\fR" # Enable additional Postfix SMTP client logging of TLS activity. # .IP "\fBsmtp_tls_security_level (empty)\fR" # The default SMTP TLS security level for the Postfix SMTP client; # when a non-empty value is specified, this overrides the obsolete # parameters smtp_use_tls, smtp_enforce_tls, and smtp_tls_enforce_peername. # .IP "\fBsmtp_tls_session_cache_database (empty)\fR" # Name of the file containing the optional Postfix SMTP client # TLS session cache. # .IP "\fBsmtpd_tls_cert_file (empty)\fR" # File with the Postfix SMTP server RSA certificate in PEM format. # .IP "\fBsmtpd_tls_eccert_file (empty)\fR" # File with the Postfix SMTP server ECDSA certificate in PEM format. # .IP "\fBsmtpd_tls_eckey_file ($smtpd_tls_eccert_file)\fR" # File with the Postfix SMTP server ECDSA private key in PEM format. # .IP "\fBsmtpd_tls_key_file ($smtpd_tls_cert_file)\fR" # File with the Postfix SMTP server RSA private key in PEM format. # .IP "\fBsmtpd_tls_loglevel (0)\fR" # Enable additional Postfix SMTP server logging of TLS activity. # .IP "\fBsmtpd_tls_received_header (no)\fR" # Request that the Postfix SMTP server produces Received: message # headers that include information about the protocol and cipher used, # as well as the remote SMTP client CommonName and client certificate issuer # CommonName. # .IP "\fBsmtpd_tls_security_level (empty)\fR" # The SMTP TLS security level for the Postfix SMTP server; when # a non-empty value is specified, this overrides the obsolete parameters # smtpd_use_tls and smtpd_enforce_tls. # .IP "\fBtls_random_source (see 'postconf -d' output)\fR" # The external entropy source for the in-memory \fBtlsmgr\fR(8) pseudo # random number generator (PRNG) pool. # SEE ALSO # master(8) Postfix master program # postfix(1) Postfix administrative interface # README FILES # .ad # .fi # Use "\fBpostconf readme_directory\fR" or # "\fBpostconf html_directory\fR" to locate this information. # .na # .nf # TLS_README, Postfix TLS configuration and operation # LICENSE # .ad # .fi # The Secure Mailer license must be distributed with this software. # HISTORY # The "\fBpostfix tls\fR" command was introduced with Postfix # version 3.1. # AUTHOR(S) # Viktor Dukhovni #-- RSA_BITS=2048 # default EC_CURVE=secp256r1 # default case $daemon_directory in "") echo This script must be run by the postfix command. 1>&2 echo Do not run directly. 1>&2 exit 1;; esac umask 022 SHELL=/bin/sh postconf=$command_directory/postconf LOGGER="$command_directory/postlog -t $MAIL_LOGTAG/postfix-tls-script" INFO="$LOGGER -p info" WARN="$LOGGER -p warn" ERROR="$LOGGER -p error" FATAL="$LOGGER -p fatal" # Overwrite SMTP client and server settings only when these are at defaults. client_settings=" smtp_use_tls smtp_enforce_tls smtp_tls_enforce_peername smtp_tls_security_level smtp_tls_cert_file smtp_tls_dcert_file smtp_tls_eccert_file " server_settings=" smtpd_use_tls smtpd_enforce_tls smtpd_tls_security_level smtpd_tls_cert_file smtpd_tls_dcert_file smtpd_tls_eccert_file " # # Can't do much without these in place. # cd $command_directory || { # Let's hope there's a "postlog" somewhere else on the PATH FATAL="postlog -p fatal -t $MAIL_LOGTAG/postfix-tls-script" msg="no Postfix command directory '${command_directory}'" $FATAL "$msg" || { echo "$msg" >&2; sleep 1; } exit 1 } check_getopt() { OPTIND=1 a= b= c= set -- -a 1 -b 2 -c -- -pos while getopts :a:b:c o do case $o in a) a="${OPTARG}";; b) b="${OPTARG}";; c) c=3;; *) return 1;; esac done shift `expr ${OPTIND} - 1` if [ "${a}" != "1" -o "${b}" != 2 -o "${c}" != 3 \ -o "${OPTIND}" -ne 7 -o "$1" != "-pos" ]; then return 1 fi } check_getopt || { $FATAL "/bin/sh does not implement a compatible 'getopts' built-in" exit 1 } # ----- BEGIN OpenSSL-specific ----- # No need to set the location of the OpenSSL command in each Postfix instance, # the value from the default instance is used for all instances. # default_config_directory=`$postconf -dh config_directory` openssl=`$postconf -c $default_config_directory -xh openssl_path` "$openssl" version >/dev/null 2>&1 || { $FATAL "No working openssl(1) command found with 'openssl_path = $openssl'" exit 1 } # ----- END OpenSSL-specific ----- test -n "$config_directory" -a -d "$config_directory" || { $FATAL no Postfix configuration directory $config_directory! exit 1 } # Do we support TLS and if so which algorithms? # $postconf -T compile-version | grep . >/dev/null || { mail_version=`$postconf -dh mail_version` $FATAL "Postfix $mail_version is not compiled with TLS support" exit 1 } rsa= ecdsa= for _algo in `$postconf -T public-key-algorithms | egrep '^(rsa|ecdsa)$'` do eval $_algo=$_algo done # ----- BEGIN OpenSSL-specific ----- if [ -n "${ecdsa}" ]; then $openssl ecparam -name secp256r1 >/dev/null 2>&1 || { cat <<-EOM | $WARN Postfix supports ECDSA, but the $openssl command does not. Consider setting the openssl_path parameter to a more capable version of the command-line utility than $openssl (with PATH=$PATH). EOM ecdsa= } fi if [ -n "${rsa}" ]; then DEFALG=rsa elif [ -n "${ecdsa}" ]; then DEFALG=ecdsa else mail_version=`$postconf -dh mail_version` $FATAL "Postfix $mail_version does not support either RSA or ECDSA" exit 1 fi # Make sure stdin is open when testing if [ -r /dev/stdin ] < /dev/null; then stdin=/dev/stdin elif [ -r /dev/fd/0 ] /dev/null` if [ "${tmp}" != "${null256}" ]; then cat <&2 Your $openssl does not support the SHA2-256 digest algorithm. To enable 'postfix tls', install an OpenSSL that does. Install its openssl(1) command at /usr/local/bin/openssl or other suitable location, and set the 'openssl_path' parameter in $default_config_directory/main.cf accordingly. EOF $FATAL "No 'postfix tls' support when openssl(1) is obsolete" exit 1 fi read_key() { [ -n "$1" -a -f "$1" ] || return 1 # Old OpenSSL versions return success even for unsupported sub-commands! # So we inspect the output instead. Don't prompt if the key is password # protected. # while read cmd key_algo key_param cert_param; do $openssl $cmd -passin "pass:umask 077" -in "$1" | grep . && return 0 done 2>/dev/null <<-EOF rsa rsa smtpd_tls_key_file smtpd_tls_cert_file ec ecdsa smtpd_tls_eckey_file smtpd_tls_eccert_file EOF return 1 } pubkey_dgst() { [ -n "$1" -a -f "$1" ] || return 1 # Old OpenSSL versions return success even for unsupported sub-commands! # So we inspect the output instead. # for cmd in ec rsa; do $openssl $cmd -passin "pass:umask 077" -in "$1" -pubout | $openssl $cmd -pubin -outform DER | hex_sha256 | egrep -v "${null256}" && return 0 done 2>/dev/null return 1 } cert_pubkey_dgst() { [ -n "$1" -a -f "$1" ] || return 1 # Old OpenSSL versions return success even for unsupported sub-commands! # So we inspect the output instead. # for cmd in ec rsa; do $openssl x509 -pubkey -noout -in "$1" | $openssl $cmd -pubin -outform DER | hex_sha256 | egrep -v "${null256}" && return 0 done 2>/dev/null return 1 } copy_key() { _algo=$1; shift _bits=$1; shift _fold=$1; shift _fnew=$1; shift _umask=`umask` umask 077 read_key "${_fold}" > "${_fnew}" # sets key_algo of current key _ret=$? umask "${_umask}" if [ "${_ret}" -ne 0 ]; then $FATAL "Error copying private key from '${_fold}' to '${_fnew}'" return 1 fi if [ "${key_algo}" != "${_algo}" ]; then $FATAL "Key algorithm '$key_algo' of '${_fold}' is not '${_algo}'" return 1 fi # XXX: We'd need C-code in postconf to portably check for compatible "bits" } create_key() { _algo=$1 _bits=$2 _fnew=$3 _umask=`umask` case $_algo in "") $FATAL "Internal error: empty algorithm"; return 1;; $rsa) set -- "${openssl}" genrsa -out "${_fnew}" "${_bits}";; $ecdsa) set -- "${openssl}" ecparam -param_enc named_curve -genkey \ -out "${_fnew}" -name "${_bits}";; *) $FATAL "Internal error: bad algorithm '${_algo}'" return 1;; esac umask 077 _err=`"$@" 2>&1` _ret=$? umask "${_umask}" if [ "${_ret}" -ne 0 ]; then echo "${_err}" | $WARN $FATAL "error generating new ${_algo} ${_bits} private key" return 1 fi } create_cert() { _k=$1; shift _c=$1; shift set_fqdn "$1" if [ $# -gt 0 ]; then shift; fi set -- "$fqdn" "$@" if [ -r "${_c}" ]; then $FATAL "New certificate file already exists: ${_c}" return 1 fi # Generate a new self-signed (~100 year) certificate # ( echo "default_md = sha256" echo "x509_extensions = v3" echo "prompt = yes" echo "distinguished_name = dn" echo "[dn]" echo "[v3]" echo "basicConstraints = CA:false" echo "subjectKeyIdentifier = hash" echo "extendedKeyUsage = serverAuth, clientAuth" echo "subjectAltName = @alts" echo "[alts]" i=1; for dns in "$@"; do # XXX map empty to $myhostname echo "DNS.$i = $dns" i=`expr $i + 1` done ) | $openssl req -x509 -config $stdin -new -key "${_k}" \ -subj "/CN=$fqdn" -days 36525 -out "${_c}" || { rm -f "${_c}" "${_k}" $FATAL "error generating self-signed SSL certificate" return 1 } } output_server_csr() { set_keyfile "$1" || return 1 shift set_fqdn "$1" || return 1 shift set -- "$fqdn" "$@" ( echo "default_md = sha256" echo "req_extensions = v3" echo "prompt = yes" echo "distinguished_name = dn" echo "[dn]" echo "[v3]" echo "subjectKeyIdentifier = hash" echo "extendedKeyUsage = serverAuth, clientAuth" echo "subjectAltName = @alts" echo "[alts]" i=1; for dns in "$@"; do echo "DNS.$i = $dns" i=`expr $i + 1` done ) | $openssl req -config $stdin -new -key "$keyfile" -subj / } # ----- END OpenSSL-specific ----- info_enable_client() { cat <<-EOM *** Non-default SMTP client TLS settings detected, no changes made. For opportunistic TLS in the Postfix SMTP client, the below settings are typical: smtp_tls_security_level = may smtp_tls_loglevel = 1 EOM if get_cache_db_type dbtype then echo " smtp_tls_session_cache_database = ${dbtype}:\${data_directory}/smtp_scache" fi } info_client_deployed() { cat <<-EOM Enabled opportunistic TLS in the Postfix SMTP client. Run the command: # postfix reload if you want the new settings to take effect immediately. EOM } info_enable_server() { cat <<-EOM *** Non-default SMTP server TLS settings detected, no changes made. For opportunistic TLS in the Postfix SMTP server, the below settings are typical: smtpd_tls_security_level = may smtpd_tls_loglevel = 1 You can use "postfix tls new-server-cert" to create a new certificate. Or, "postfix tls new-server-key" to also force a new private key. If you publish DANE TLSA records, see: https://tools.ietf.org/html/rfc7671#section-8 https://tools.ietf.org/html/rfc7671#section-5.1 https://tools.ietf.org/html/rfc7671#section-5.2 https://community.letsencrypt.org/t/please-avoid-3-0-1-and-3-0-2-dane-tlsa-records-with-le-certificates/7022 EOM } # args: certfile keyfile deploy info_created() { cat <<-EOM New private key and self-signed certificate created. To deploy run: # postfix tls deploy-server-cert $1 $2 EOM } # args: certfile keyfile deploy info_server_deployed() { if [ "$3" = "enable" ]; then echo "Enabled opportunistic TLS in the Postfix SMTP server" fi cat <<-EOM New TLS private key and certificate deployed. Run the command: # postfix reload if you want the new settings to take effect immediately. EOM } # args: certfile keyfile deploy info_csr() { cat <<-EOM To generate a CSR run: # postfix tls output-server-csr -k $2 [ ...] EOM if [ -z "$3" ]; then echo "Save the signed certificate chain in $1, and deploy as above." else echo "Save the signed certificate chain in $1." fi } # args: certfile keyfile deploy info_tlsa() { # If already deployed, info for how to show all the deployed keys. # Otherwise, just the new keys, so that TLSA records can be updated # first. if [ -n "$3" ]; then shift $#; fi cat <<-EOM To generate TLSA records run: # postfix tls output-server-tlsa [-h ] $2 EOM } # args: certfile keyfile deploy info_dane_dns() { # If already deployed, too late to wait, otherwise advise updating TLSA # RRs before deployment. if [ -n "$3" ]; then cat <<-EOM (If you have DANE TLSA RRs, update them as soon as possible to match the newly deployed keys). EOM else cat <<-EOM (deploy after updating the DNS and waiting for stale RRs to expire). EOM fi } set_fqdn() { if [ -n "$1" ]; then fqdn=$1; return 0; fi fqdn=`$postconf -xh myhostname` || return 1 case $fqdn in /*) fqdn=`cat "${fqdn}"` || return 1;; esac } set_keyfile() { keyfile=$1 case $keyfile in rsa) if [ -n "${rsa}" ]; then keyfile=`$postconf -nxh smtpd_tls_key_file` else keyfile= fi ;; ecdsa) if [ -n "${ecdsa}" ]; then keyfile=`$postconf -nxh smtpd_tls_eckey_file` else keyfile= fi ;; "") : empty ok;; none) : see below;; /*) ;; *) # User-specified key pathnames are relative to the configuration # directory keyfile="${config_directory}/${keyfile}";; esac if [ "${keyfile}" = "none" ]; then keyfile= ; fi } check_key() { read_key "$1" >/dev/null && return 0 $FATAL "no private key found in file: $1" return 1 } # Create new key or copy existing if specified. # ensure_key() { _algo=$1; shift _bits=$1; shift stamp=`TZ=UTC date +%Y%m%d-%H%M%S` case $_algo in "") $FATAL "Internal error: empty algorithm "; return 1;; $rsa) keyfile="${config_directory}/key-${stamp}.pem" certfile="${config_directory}/cert-${stamp}.pem";; $ecdsa) keyfile="${config_directory}/eckey-${stamp}.pem" certfile="${config_directory}/eccert-${stamp}.pem";; *) $FATAL "Internal error: bad algorithm '${_algo}'" return 1;; esac if [ -r "${keyfile}" ]; then $FATAL "New private key file already exists: ${keyfile}" return 1 fi if [ -r "${certfile}" ]; then $FATAL "New certificate file already exists: ${certfile}" return 1 fi if [ -n "$1" ]; then copy_key "${_algo}" "${_bits}" "$1" "${keyfile}" && return 0 else create_key "${_algo}" "${_bits}" "${keyfile}" && return 0 fi rm -f "${keyfile}" return 1 } init_random_source() { tls_random_source=$1 if [ -z "${tls_random_source}" ]; then tls_random_source=`$postconf -xh tls_random_source` fi if [ -n "${tls_random_source}" ]; then return 0 fi if [ -r /dev/urandom ] then tls_random_source=dev:/dev/urandom else $FATAL no default TLS random source defined and no /dev/urandom return 1 fi } # Don't be too clever by half. all_default() { for var in "$@" do val=`$postconf -nh "${var}"` if [ -n "$val" ]; then return 1; fi done return 0 } # Select read-write database type for TLS session caches. # get_cache_db_type() { var=$1; shift prio=0 ret=1 for _dbtype in `$postconf -m` do _prio=0 case $_dbtype in lmdb) _prio=2;; btree) _prio=1;; esac if [ "$_prio" -gt "$prio" ] then eval "$var=\$_dbtype" prio=$_prio ret=0 fi done return $ret } deploy_server_cert() { certfile=$1; shift keyfile=$1; shift case $# in 0) deploy=;; *) deploy=$1; shift;; esac # Sets key_algo, key_param and cert_param check_key "$keyfile" || return 1 cd=`cert_pubkey_dgst "${certfile}"` || { $FATAL "error computing certificate public key digest" return 1 } kd=`pubkey_dgst "$keyfile"` || { $FATAL "error computing public key digest" return 1 } if [ "$cd" != "$kd" ]; then $FATAL "Certificate in ${certfile} does not match key in ${keyfile}" return 1 fi set -- \ "${key_param} = ${keyfile}" \ "${cert_param} = ${certfile}" if [ "${deploy}" = "enable" ]; then set -- "$@" \ "smtpd_tls_security_level = may" \ "smtpd_tls_received_header = yes" \ "smtpd_tls_loglevel = 1" fi if [ -n "${tls_random_source}" ]; then set -- "$@" "tls_random_source = ${tls_random_source}" fi # All in one shot, since postconf delays modifying "hot" main.cf files. $postconf -e "$@" || return 1 } # Prepare a new cert and perhaps re-use any existing private key. # new_server_cert() { algo=$1; shift bits=$1; shift oldkey=$1; shift deploy=$1; shift # resets keyfile (copy or else new) and new certfile ensure_key "$algo" "$bits" "${oldkey}" || return 1 create_cert "${keyfile}" "${certfile}" "$@" || return 1 if [ -n "${deploy}" ]; then deploy_server_cert "${certfile}" "${keyfile}" "${deploy}" || return 1 fi ( if [ -z "${deploy}" ]; then info_created "${certfile}" "${keyfile}" "${deploy}" else info_server_deployed "${certfile}" "${keyfile}" "${deploy}" fi info_csr "${certfile}" "${keyfile}" "${deploy}" info_tlsa "${certfile}" "${keyfile}" "${deploy}" if [ -z "${oldkey}" ]; then info_dane_dns "${certfile}" "${keyfile}" "${deploy}" fi ) | $INFO } enable_client() { if all_default ${client_settings} then set -- \ "smtp_tls_security_level = may" \ "smtp_tls_loglevel = 1" if get_cache_db_type dbtype then set -- "$@" \ "smtp_tls_session_cache_database = ${dbtype}:${data_directory}/smtp_scache" fi if [ -n "${tls_random_source}" ]; then set -- "$@" "tls_random_source = ${tls_random_source}" fi # All in one shot, since postconf delays modifying "hot" main.cf files. $postconf -e "$@" || return 1 info_client_deployed else info_enable_client fi | $INFO } enable_server() { algo=$1; shift bits=$1; shift if all_default ${server_settings} then # algo bits keyfile deploy [hostnames ...] new_server_cert "${algo}" "${bits}" "" "enable" "$@" || return 1 else info_enable_server | $INFO fi } output_server_tlsa() { hostname=$1 check_key "$2" || return 1 data=`pubkey_dgst "$2"` || return 1 if [ -z "$data" ] then $FATAL error computing SHA2-256 SPKI digest of "$key" return 1 fi echo "_25._tcp.$hostname. IN TLSA 3 1 1 $data" } # # Parse JCL # case $1 in enable-client) cmd=$1; shift; OPTIND=1 rand= while getopts :r: _opt do case $_opt in r) rand="${OPTARG}";; *) $FATAL "usage: postfix tls $cmd [-r devrandom]" exit 1;; esac done # No positional arguments supported with enable-client if [ $# -ge "${OPTIND}" ]; then $FATAL "usage: postfix tls $cmd [-r devrandom]" exit 1 fi # But, shift anyway shift `expr $OPTIND - 1` init_random_source "${rand}" || exit 1 enable_client || exit 1 ;; enable-server) cmd=$1; shift; OPTIND=1 algo=$DEFALG bits= rand= while getopts :a:b:r: _opt do case $_opt in a) algo="${OPTARG}";; b) bits="${OPTARG}";; r) rand="${OPTARG}";; *) $FATAL "usage: postfix tls $cmd [-a algorithm] [-b bits ] [-r devrandom] [hostname ...]" exit 1;; esac done # Here positional arguments are hostnames for the new certificate, as # many as the user wants shift `expr $OPTIND - 1` case $algo in "") $FATAL "Internal error: empty algorithm "; return 1;; $rsa) : ${bits:=${RSA_BITS}};; $ecdsa) : ${bits:=${EC_CURVE}};; *) $FATAL "Unsupported private key algorithm: $algo" exit 1;; esac init_random_source "${rand}" || exit 1 enable_server "${algo}" "${bits}" "$@" || exit 1 ;; new-server-key) cmd=$1; shift; OPTIND=1 algo=$DEFALG while getopts :a:b: _opt do case $_opt in a) algo="${OPTARG}";; b) bits="${OPTARG}";; *) $FATAL "usage: postfix tls $cmd [-a algorithm] [-b bits ] [hostname ...]" exit 1;; esac done # Here positional arguments are hostnames for the new certificate, as # many as the user wants shift `expr $OPTIND - 1` case $algo in "") $FATAL "Internal error: empty algorithm "; return 1;; $rsa) : ${bits:=${RSA_BITS}};; $ecdsa) : ${bits:=${EC_CURVE}};; *) $FATAL "Unsupported public key algorithm: $algo" exit 1;; esac # Force new key new_server_cert "${algo}" "${bits}" "" "" "$@" || exit 1 ;; new-server-cert) cmd=$1; shift; OPTIND=1 algo=$DEFALG while getopts :a:b: _opt do case $_opt in a) algo="${OPTARG}";; b) bits="${OPTARG}";; *) $FATAL "usage: postfix tls $cmd [-a algorithm] [-b bits ] [hostname ...]" exit 1;; esac done # Here positional arguments are hostnames for the new certificate, as # many as the user wants shift `expr $OPTIND - 1` case $algo in "") $FATAL "Invalid empty key algorithm"; exit 1;; $rsa) : ${bits:=${RSA_BITS}};; $ecdsa) : ${bits:=${EC_CURVE}};; *) $FATAL "Unsupported private key algorithm: $algo" exit 1;; esac # Existing keyfile or empty set_keyfile "${algo}" if [ -n "${keyfile}" -a ! -f "${keyfile}" ]; then echo "Key file: ${keyfile} not found, creating new keys" | $WARN keyfile= fi # Try to re-use (copy) existing key. new_server_cert "${algo}" "${bits}" "${keyfile}" "" "$@" || exit 1 ;; deploy-server-cert) if [ $# -ne 3 ]; then $FATAL "usage: postfix tls $1 certfile keyfile" exit 1 fi shift # User-specified key and cert pathnames are relative to the # configuration directory # case "${1}" in /*) certfile="${1}" ;; *) certfile="${config_directory}/${1}" ;; esac case "${2}" in /*) keyfile="${2}" ;; *) keyfile="${config_directory}/${2}" ;; esac deploy_server_cert "${certfile}" "${keyfile}" || exit 1 info_server_deployed "${certfile}" "${keyfile}" "deploy" | $INFO ;; output-server-csr) cmd=$1; shift; OPTIND=1 k= while getopts :k: _opt do case $_opt in k) k="${OPTARG}";; *) $FATAL "usage: postfix tls $cmd [-k keyfile] [hostname ...]" exit 1;; esac done # Here positional arguments are hostnames for the new certificate, as # many as the user wants shift `expr $OPTIND - 1` if [ -n "${k}" ]; then set_keyfile "${k}" else for _algo in $rsa $ecdsa do set_keyfile "${_algo}" if [ -n "${keyfile}" ]; then break fi done fi if [ -z "${keyfile}" -o ! -r "${keyfile}" ]; then $FATAL "No usable keyfile specified or configured" exit 1 fi # Default from $myhostname if [ $# -eq 0 ]; then set_fqdn set -- "$fqdn" fi # Output a CSR for the requested names output_server_csr "$keyfile" "$@" || exit 1 ;; output-server-tlsa) cmd=$1; shift; OPTIND=1 hostname= while getopts :h: _opt do case $_opt in h) hostname="${OPTARG}";; *) $FATAL "usage: postfix tls $cmd [-h hostname] [keyfile ...]" exit 1;; esac done set_fqdn "${hostname}" # Here positional arguments are keyfiles for which we output "3 1 1" # TLSA RRs, as many keyfiles as the user wants. By default the live # RSA and/or ECDSA keys. shift `expr $OPTIND - 1` if [ $# -eq 0 ]; then set -- $rsa $ecdsa; fi found= for _k in "$@" do set_keyfile "${_k}" if [ -z "${keyfile}" ]; then continue; fi echo "; ${keyfile}" output_server_tlsa "${fqdn}" "${keyfile}" || exit 1 found=1 done if [ -z "${found}" ]; then $FATAL "No usable keyfiles specified or configured" exit 1 fi ;; all-default-client) cmd=$1; shift; OPTIND=1 # No arguments for all-default-client if [ $# -ge "${OPTIND}" ]; then $FATAL "usage: postfix tls $cmd" exit 1 fi all_default ${client_settings} || exit 1 ;; all-default-server) cmd=$1; shift; OPTIND=1 # No arguments for all-default-server if [ $# -ge "${OPTIND}" ]; then $FATAL "usage: postfix tls $cmd" exit 1 fi all_default ${server_settings} || exit 1 ;; *) $ERROR "unknown tls command: '$1'" $FATAL "usage: postfix tls enable-client (or enable-server, new-server-key, new-server-cert, deploy-server-cert, output-server-csr, output-server-tlsa, all-default-client, all-default-server)" exit 1 ;; esac