<?xml version="1.0" encoding="UTF-8"?> <!DOCTYPE html PUBLIC "-//W3C//DTD XHTML 1.0 Strict//EN" "http://www.w3.org/TR/xhtml1/DTD/xhtml1-strict.dtd"> <html xmlns="http://www.w3.org/1999/xhtml"> <body> <h1 >Remote support</h1> <p> Libvirt allows you to access hypervisors running on remote machines through authenticated and encrypted connections. </p> <ul> <li> <a href="#Remote_basic_usage">Basic usage</a> </li> <li> <a href="#Remote_transports">Transports</a> </li> <li> <a href="#Remote_URI_reference">Remote URIs</a> <ul> <li> <a href="#Remote_URI_parameters">Extra parameters</a> </li> </ul> </li> <li> <a href="#Remote_certificates">Generating TLS certificates</a> <ul> <li> <a href="#Remote_PKI">Public Key Infrastructure set up</a> </li> <li> <a href="#Remote_TLS_background">Background to TLS certificates</a> </li> <li> <a href="#Remote_TLS_CA">Setting up a Certificate Authority (CA)</a> </li> <li> <a href="#Remote_TLS_server_certificates">Issuing server certificates</a> </li> <li> <a href="#Remote_TLS_client_certificates">Issuing client certificates</a> </li> <li> <a href="#Remote_TLS_troubleshooting">Troubleshooting TLS certificate problems</a> </li> </ul> </li> <li> <a href="#Remote_libvirtd_configuration">libvirtd configuration file</a> </li> <li> <a href="#Remote_IPv6">IPv6 support</a> </li> <li> <a href="#Remote_limitations">Limitations</a> </li> </ul> <h3> <a name="Remote_basic_usage">Basic usage</a> </h3> <p> On the remote machine, <code>libvirtd</code> should be running in general. See <a href="#Remote_libvirtd_configuration">the section on configuring libvirtd</a> for more information. </p> <p> Not all hypervisors supported by libvirt require a running <code>libvirtd</code>. If you want to connect to a VMware ESX/ESXi or GSX server then <code>libvirtd</code> is not necessary. See the <a href="drvesx.html">VMware ESX page</a> for details. </p> <p> To tell libvirt that you want to access a remote resource, you should supply a hostname in the normal <a href="uri.html">URI</a> that is passed to <code>virConnectOpen</code> (or <code>virsh -c ...</code>). For example, if you normally use <code>qemu:///system</code> to access the system-wide QEMU daemon, then to access the system-wide QEMU daemon on a remote machine called <code>oirase</code> you would use <code>qemu://oirase/system</code>. </p> <p> The <a href="#Remote_URI_reference">section on remote URIs</a> describes in more detail these remote URIs. </p> <p> From an API point of view, apart from the change in URI, the API should behave the same. For example, ordinary calls are routed over the remote connection transparently, and values or errors from the remote side are returned to you as if they happened locally. Some differences you may notice: </p> <ul> <li> Additional errors can be generated, specifically ones relating to failures in the remote transport itself. </li> <li> Remote calls are handled synchronously, so they will be much slower than, say, direct hypervisor calls. </li> </ul> <h3> <a name="Remote_transports">Transports</a> </h3> <p> Remote libvirt supports a range of transports: </p> <dl> <dt> tls </dt> <dd><a href="http://en.wikipedia.org/wiki/Transport_Layer_Security" title="Transport Layer Security">TLS</a> 1.0 (SSL 3.1) authenticated and encrypted TCP/IP socket, usually listening on a public port number. To use this you will need to <a href="#Remote_certificates" title="Generating TLS certificates">generate client and server certificates</a>. The standard port is 16514. </dd> <dt> unix </dt> <dd> Unix domain socket. Since this is only accessible on the local machine, it is not encrypted, and uses Unix permissions or SELinux for authentication. The standard socket names are <code>/var/run/libvirt/libvirt-sock</code> and <code>/var/run/libvirt/libvirt-sock-ro</code> (the latter for read-only connections). </dd> <dt> ssh </dt> <dd> Transported over an ordinary <a href="http://www.openssh.com/" title="OpenSSH homepage">ssh (secure shell)</a> connection. Requires <a href="http://netcat.sourceforge.net/">Netcat (nc)</a> installed and libvirtd should be running on the remote machine. You should use some sort of ssh key management (eg. <a href="http://mah.everybody.org/docs/ssh" title="Using ssh-agent with ssh">ssh-agent</a>) otherwise programs which use this transport will stop to ask for a password. </dd> <dt> ext </dt> <dd> Any external program which can make a connection to the remote machine by means outside the scope of libvirt. </dd> <dt> tcp </dt> <dd> Unencrypted TCP/IP socket. Not recommended for production use, this is normally disabled, but an administrator can enable it for testing or use over a trusted network. The standard port is 16509. </dd> <dt> libssh2 </dt> <dd> Transport over the SSH protocol using <a href="http://libssh2.org/" title="libssh2 homepage">libssh2</a> instead of the OpenSSH binary. This transport uses the libvirt authentication callback for all ssh authentication calls and therefore supports keyboard-interactive authentication even with graphical management applications. As with the classic ssh transport netcat is required on the remote side.</dd> </dl> <p> The default transport, if no other is specified, is <code>tls</code>. </p> <h3> <a name="Remote_URI_reference">Remote URIs</a> </h3> <p> See also: <a href="uri.html">documentation on ordinary ("local") URIs</a>. </p> <p> Remote URIs have the general form ("[...]" meaning an optional part): </p> <p><code>driver</code>[<code>+transport</code>]<code>://</code>[<code>username@</code>][<code>hostname</code>][<code>:port</code>]<code>/</code>[<code>path</code>][<code>?extraparameters</code>] </p> <p> Either the transport or the hostname must be given in order to distinguish this from a local URI. </p> <p> Some examples: </p> <ul> <li><code>xen+ssh://rjones@towada/</code><br/> — Connect to a remote Xen hypervisor on host <code>towada</code> using ssh transport and ssh username <code>rjones</code>. </li> <li><code>xen://towada/</code><br/> — Connect to a remote Xen hypervisor on host <code>towada</code> using TLS. </li> <li><code>xen://towada/?no_verify=1</code><br/> — Connect to a remote Xen hypervisor on host <code>towada</code> using TLS. Do not verify the server's certificate. </li> <li><code>qemu+unix:///system?socket=/opt/libvirt/run/libvirt/libvirt-sock</code><br/> — Connect to the local qemu instances over a non-standard Unix socket (the full path to the Unix socket is supplied explicitly in this case). </li> <li><code>test+tcp://localhost:5000/default</code><br/> — Connect to a libvirtd daemon offering unencrypted TCP/IP connections on localhost port 5000 and use the test driver with default settings. </li> <li><code>qemu+libssh2://user@host/system?known_hosts=/home/user/.ssh/known_hosts</code><br/> — Connect to a remote host using a ssh connection with the libssh2 driver and use a different known_hosts file.</li> </ul> <h4> <a name="Remote_URI_parameters">Extra parameters</a> </h4> <p> Extra parameters can be added to remote URIs as part of the query string (the part following <q><code>?</code></q>). Remote URIs understand the extra parameters shown below. Any others are passed unmodified through to the back end. Note that parameter values must be <a href="http://xmlsoft.org/html/libxml-uri.html#xmlURIEscapeStr">URI-escaped</a>. </p> <table class="top_table"> <tr> <th> Name </th> <th> Transports </th> <th> Meaning </th> </tr> <tr> <td> <code>name</code> </td> <td> <i>any transport</i> </td> <td> The name passed to the remote virConnectOpen function. The name is normally formed by removing transport, hostname, port number, username and extra parameters from the remote URI, but in certain very complex cases it may be better to supply the name explicitly. </td> </tr> <tr> <td colspan="2"/> <td> Example: <code>name=qemu:///system</code> </td> </tr> <tr> <td> <code>command</code> </td> <td> ssh, ext </td> <td> The external command. For ext transport this is required. For ssh the default is <code>ssh</code>. The PATH is searched for the command. </td> </tr> <tr> <td colspan="2"/> <td> Example: <code>command=/opt/openssh/bin/ssh</code> </td> </tr> <tr> <td> <code>socket</code> </td> <td> unix, ssh, libssh2 </td> <td> The path to the Unix domain socket, which overrides the compiled-in default. For ssh transport, this is passed to the remote netcat command (see next). </td> </tr> <tr> <td colspan="2"/> <td> Example: <code>socket=/opt/libvirt/run/libvirt/libvirt-sock</code> </td> </tr> <tr> <td> <code>netcat</code> </td> <td> ssh, libssh2 </td> <td> The name of the netcat command on the remote machine. The default is <code>nc</code>. For ssh transport, libvirt constructs an ssh command which looks like: <pre><i>command</i> -p <i>port</i> [-l <i>username</i>] <i>hostname</i> <i>netcat</i> -U <i>socket</i> </pre> where <i>port</i>, <i>username</i>, <i>hostname</i> can be specified as part of the remote URI, and <i>command</i>, <i>netcat</i> and <i>socket</i> come from extra parameters (or sensible defaults). </td> </tr> <tr> <td colspan="2"/> <td> Example: <code>netcat=/opt/netcat/bin/nc</code> </td> </tr> <tr> <td> <code>keyfile</code> </td> <td> ssh, libssh2 </td> <td> The name of the private key file to use to authentication to the remote machine. If this option is not used the default keys are used. </td> </tr> <tr> <td colspan="2"/> <td> Example: <code>keyfile=/root/.ssh/example_key</code> </td> </tr> <tr> <td> <code>no_verify</code> </td> <td> ssh, tls </td> <td> SSH: If set to a non-zero value, this disables client's strict host key checking making it auto-accept new host keys. Existing host keys will still be validated. <br/> <br/> TLS: If set to a non-zero value, this disables client checks of the server's certificate. Note that to disable server checks of the client's certificate or IP address you must <a href="#Remote_libvirtd_configuration">change the libvirtd configuration</a>. </td> </tr> <tr> <td colspan="2"/> <td> Example: <code>no_verify=1</code> </td> </tr> <tr> <td> <code>no_tty</code> </td> <td> ssh </td> <td> If set to a non-zero value, this stops ssh from asking for a password if it cannot log in to the remote machine automatically (eg. using ssh-agent etc.). Use this when you don't have access to a terminal - for example in graphical programs which use libvirt. </td> </tr> <tr> <td colspan="2"/> <td> Example: <code>no_tty=1</code> </td> </tr> <tr> <td> <code>pkipath</code> </td> <td> tls</td> <td> Specifies x509 certificates path for the client. If any of the CA certificate, client certificate, or client key is missing, the connection will fail with a fatal error. </td> </tr> <tr> <td colspan="2"/> <td> Example: <code>pkipath=/tmp/pki/client</code> </td> </tr> <tr> <td> <code>known_hosts</code> </td> <td> libssh2 </td> <td> Path to the known_hosts file to verify the host key against. LibSSH2 supports OpenSSH-style known_hosts files, although it does not support all key types, so using files created by the OpenSSH binary may result into truncating the known_hosts file. It's recommended to use the default known_hosts file is located in libvirt's client local configuration directory e.g.: ~/.config/libvirt/known_hosts. Note: Use absolute paths. </td> </tr> <tr> <td colspan="2"/> <td> Example: <code>known_hosts=/root/.ssh/known_hosts</code> </td> </tr> <tr> <td> <code>sshauth</code> </td> <td> libssh2 </td> <td> A comma separated list of authentication methods to use. Default (is "agent,privkey,keyboard-interactive". The order of the methods is perserved. Some methods may require additional parameters. </td> </tr> <tr> <td colspan="2"/> <td> Example: <code>sshauth=privkey,agent</code> </td> </tr> </table> <h3> <a name="Remote_certificates">Generating TLS certificates</a> </h3> <h4> <a name="Remote_PKI">Public Key Infrastructure set up</a> </h4> <p> If you are unsure how to create TLS certificates, skip to the next section. </p> <table class="top_table"> <tr> <th> Location </th> <th> Machine </th> <th> Description </th> <th> Required fields </th> </tr> <tr> <td> <code>/etc/pki/CA/cacert.pem</code> </td> <td> Installed on all clients and servers </td> <td> CA's certificate (<a href="#Remote_TLS_CA">more info</a>)</td> <td> n/a </td> </tr> <tr> <td> <code>/etc/pki/libvirt/ private/serverkey.pem</code> </td> <td> Installed on the server </td> <td> Server's private key (<a href="#Remote_TLS_server_certificates">more info</a>)</td> <td> n/a </td> </tr> <tr> <td> <code>/etc/pki/libvirt/ servercert.pem</code> </td> <td> Installed on the server </td> <td> Server's certificate signed by the CA. (<a href="#Remote_TLS_server_certificates">more info</a>) </td> <td> CommonName (CN) must be the hostname of the server as it is seen by clients. </td> </tr> <tr> <td> <code>/etc/pki/libvirt/ private/clientkey.pem</code> </td> <td> Installed on the client </td> <td> Client's private key. (<a href="#Remote_TLS_client_certificates">more info</a>) </td> <td> n/a </td> </tr> <tr> <td> <code>/etc/pki/libvirt/ clientcert.pem</code> </td> <td> Installed on the client </td> <td> Client's certificate signed by the CA (<a href="#Remote_TLS_client_certificates">more info</a>) </td> <td> Distinguished Name (DN) can be checked against an access control list (<code>tls_allowed_dn_list</code>). </td> </tr> </table> <p> If 'pkipath' is specified in URI, then all the client certificates must be found in the path specified, otherwise the connection will fail with a fatal error. If 'pkipath' is not specified: </p> <ul> <li> For a non-root user, libvirt tries to find the certificates in $HOME/.pki/libvirt. If the required CA certificate cannot be found, then the global default location (/etc/pki/CA/cacert.pem) will be used. Likewise, if either the client certificate or the client key cannot be found, then the global default locations (/etc/pki/libvirt/clientcert.pem, /etc/pki/libvirt/private/clientkey.pem) will be used. </li> <li> For the root user, the global default locations will be used.</li> </ul> <h4> <a name="Remote_TLS_background">Background to TLS certificates</a> </h4> <p> Libvirt supports TLS certificates for verifying the identity of the server and clients. There are two distinct checks involved: </p> <ul> <li> The client should know that it is connecting to the right server. Checking done by client by matching the certificate that the server sends to the server's hostname. May be disabled by adding <code>?no_verify=1</code> to the <a href="#Remote_URI_parameters">remote URI</a>. </li> <li> The server should know that only permitted clients are connecting. This can be done based on client's IP address, or on client's IP address and client's certificate. Checking done by the server. May be enabled and disabled in the <a href="#Remote_libvirtd_configuration">libvirtd.conf file</a>. </li> </ul> <p> For full certificate checking you will need to have certificates issued by a recognised <a href="http://en.wikipedia.org/wiki/Certificate_authority">Certificate Authority (CA)</a> for your server(s) and all clients. To avoid the expense of getting certificates from a commercial CA, you can set up your own CA and tell your server(s) and clients to trust certificates issues by your own CA. Follow the instructions in the next section. </p> <p> Be aware that the <a href="#Remote_libvirtd_configuration">default configuration for libvirtd</a> allows any client to connect provided they have a valid certificate issued by the CA for their own IP address. You may want to change this to make it less (or more) permissive, depending on your needs. </p> <h4> <a name="Remote_TLS_CA">Setting up a Certificate Authority (CA)</a> </h4> <p> You will need the <a href="http://www.gnu.org/software/gnutls/manual/html_node/Invoking-certtool.html">GnuTLS certtool program documented here</a>. In Fedora, it is in the <code>gnutls-utils</code> package. </p> <p> Create a private key for your CA: </p> <pre> certtool --generate-privkey > cakey.pem </pre> <p> and self-sign it by creating a file with the signature details called <code>ca.info</code> containing: </p> <pre> cn = <i>Name of your organization</i> ca cert_signing_key </pre> <pre> certtool --generate-self-signed --load-privkey cakey.pem \ --template ca.info --outfile cacert.pem </pre> <p> (You can delete <code>ca.info</code> file now if you want). </p> <p> Now you have two files which matter: </p> <ul> <li><code>cakey.pem</code> - Your CA's private key (keep this very secret!) </li> <li><code>cacert.pem</code> - Your CA's certificate (this is public). </li> </ul> <p><code>cacert.pem</code> has to be installed on clients and server(s) to let them know that they can trust certificates issued by your CA. </p> <p> The normal installation directory for <code>cacert.pem</code> is <code>/etc/pki/CA/cacert.pem</code> on all clients and servers. </p> <p> To see the contents of this file, do: </p> <pre><b>certtool -i --infile cacert.pem</b> X.509 certificate info: Version: 3 Serial Number (hex): 00 Subject: CN=Red Hat Emerging Technologies Issuer: CN=Red Hat Emerging Technologies Signature Algorithm: RSA-SHA Validity: Not Before: Mon Jun 18 16:22:18 2007 Not After: Tue Jun 17 16:22:18 2008 <i>[etc]</i> </pre> <p> This is all that is required to set up your CA. Keep the CA's private key carefully as you will need it when you come to issue certificates for your clients and servers. </p> <h4> <a name="Remote_TLS_server_certificates">Issuing server certificates</a> </h4> <p> For each server (libvirtd) you need to issue a certificate with the X.509 CommonName (CN) field set to the hostname of the server. The CN must match the hostname which clients will be using to connect to the server. </p> <p> In the example below, clients will be connecting to the server using a <a href="#Remote_URI_reference">URI</a> of <code>xen://oirase/</code>, so the CN must be "<code>oirase</code>". </p> <p> Make a private key for the server: </p> <pre> certtool --generate-privkey > serverkey.pem </pre> <p> and sign that key with the CA's private key by first creating a template file called <code>server.info</code> (only the CN field matters, which as explained above must be the server's hostname): </p> <pre> organization = <i>Name of your organization</i> cn = oirase tls_www_server encryption_key signing_key </pre> <p> and sign: </p> <pre> certtool --generate-certificate --load-privkey serverkey.pem \ --load-ca-certificate cacert.pem --load-ca-privkey cakey.pem \ --template server.info --outfile servercert.pem </pre> <p> This gives two files: </p> <ul> <li><code>serverkey.pem</code> - The server's private key. </li> <li><code>servercert.pem</code> - The server's public key. </li> </ul> <p> We can examine this certificate and its signature: </p> <pre><b>certtool -i --infile servercert.pem</b> X.509 certificate info: Version: 3 Serial Number (hex): 00 Subject: O=Red Hat Emerging Technologies,CN=oirase Issuer: CN=Red Hat Emerging Technologies Signature Algorithm: RSA-SHA Validity: Not Before: Mon Jun 18 16:34:49 2007 Not After: Tue Jun 17 16:34:49 2008 </pre> <p> Note the "Issuer" CN is "Red Hat Emerging Technologies" (the CA) and the "Subject" CN is "oirase" (the server). </p> <p> Finally we have two files to install: </p> <ul> <li><code>serverkey.pem</code> is the server's private key which should be copied to the server <i>only</i> as <code>/etc/pki/libvirt/private/serverkey.pem</code>. </li> <li><code>servercert.pem</code> is the server's certificate which can be installed on the server as <code>/etc/pki/libvirt/servercert.pem</code>. </li> </ul> <h4> <a name="Remote_TLS_client_certificates">Issuing client certificates</a> </h4> <p> For each client (ie. any program linked with libvirt, such as <a href="http://virt-manager.et.redhat.com/">virt-manager</a>) you need to issue a certificate with the X.509 Distinguished Name (DN) set to a suitable name. You can decide this on a company / organisation policy. For example, I use: </p> <pre> C=GB,ST=London,L=London,O=Red Hat,CN=<i>name_of_client</i> </pre> <p> The process is the same as for <a href="#Remote_TLS_server_certificates">setting up the server certificate</a> so here we just briefly cover the steps. </p> <ol> <li> Make a private key: <pre> certtool --generate-privkey > clientkey.pem </pre> </li> <li> Act as CA and sign the certificate. Create client.info containing: <pre> country = GB state = London locality = London organization = Red Hat cn = client1 tls_www_client encryption_key signing_key </pre> and sign by doing: <pre> certtool --generate-certificate --load-privkey clientkey.pem \ --load-ca-certificate cacert.pem --load-ca-privkey cakey.pem \ --template client.info --outfile clientcert.pem </pre> </li> <li> Install the certificates on the client machine: <pre> cp clientkey.pem /etc/pki/libvirt/private/clientkey.pem cp clientcert.pem /etc/pki/libvirt/clientcert.pem </pre> </li> </ol> <h4> <a name="Remote_TLS_troubleshooting">Troubleshooting TLS certificate problems</a> </h4> <dl> <dt> failed to verify client's certificate </dt> <dd> <p> On the server side, run the libvirtd server with the '--listen' and '--verbose' options while the client is connecting. The verbose log messages should tell you enough to diagnose the problem. </p> </dd> </dl> <p> You can use the virt-pki-validate shell script to analyze the setup on the client or server machines, preferably as root. It will try to point out the possible problems and provide solutions to fix the set up up to a point where you have secure remote access.</p> <h3> <a name="Remote_libvirtd_configuration">libvirtd configuration file</a> </h3> <p> Libvirtd (the remote daemon) is configured from a file called <code>/etc/libvirt/libvirtd.conf</code>, or specified on the command line using <code>-f filename</code> or <code>--config filename</code>. </p> <p> This file should contain lines of the form below. Blank lines and comments beginning with <code>#</code> are ignored. </p> <pre>setting = value</pre> <p>The following settings, values and default are:</p> <table class="top_table"> <tr> <th> Line </th> <th> Default </th> <th> Meaning </th> </tr> <tr> <td> listen_tls <i>[0|1]</i> </td> <td> 1 (on) </td> <td> Listen for secure TLS connections on the public TCP/IP port. Note: it is also necessary to start the server in listening mode by running it with --listen or editing /etc/sysconfig/libvirtd by uncommenting the LIBVIRTD_ARGS="--listen" line to cause the server to come up in listening mode whenever it is started. </td> </tr> <tr> <td> listen_tcp <i>[0|1]</i> </td> <td> 0 (off) </td> <td> Listen for unencrypted TCP connections on the public TCP/IP port. Note: it is also necessary to start the server in listening mode. </td> </tr> <tr> <td> tls_port <i>"service"</i> </td> <td> "16514" </td> <td> The port number or service name to listen on for secure TLS connections. </td> </tr> <tr> <td> tcp_port <i>"service"</i> </td> <td> "16509" </td> <td> The port number or service name to listen on for unencrypted TCP connections. </td> </tr> <tr> <td> mdns_adv <i>[0|1]</i> </td> <td> 0 (advertise with mDNS) </td> <td> If set to 1 then the virtualization service will be advertised over mDNS to hosts on the local LAN segment. </td> </tr> <tr> <td> mdns_name <i>"name"</i> </td> <td> "Virtualization Host HOSTNAME" </td> <td> The name to advertise for this host with Avahi mDNS. The default includes the machine's short hostname. This must be unique to the local LAN segment. </td> </tr> <tr> <td> unix_sock_group <i>"groupname"</i> </td> <td> "root" </td> <td> The UNIX group to own the UNIX domain socket. If the socket permissions allow group access, then applications running under matching group can access the socket. Only valid if running as root </td> </tr> <tr> <td> unix_sock_ro_perms <i>"octal-perms"</i> </td> <td> "0777" </td> <td> The permissions for the UNIX domain socket for read-only client connections. The default allows any user to monitor domains. </td> </tr> <tr> <td> unix_sock_rw_perms <i>"octal-perms"</i> </td> <td> "0700" </td> <td> The permissions for the UNIX domain socket for read-write client connections. The default allows only root to manage domains. </td> </tr> <tr> <td> tls_no_verify_certificate <i>[0|1]</i> </td> <td> 0 (certificates are verified) </td> <td> If set to 1 then if a client certificate check fails, it is not an error. </td> </tr> <tr> <td> tls_no_verify_address <i>[0|1]</i> </td> <td> 0 (addresses are verified) </td> <td> If set to 1 then if a client IP address check fails, it is not an error. </td> </tr> <tr> <td> key_file <i>"filename"</i> </td> <td> "/etc/pki/libvirt/ private/serverkey.pem" </td> <td> Change the path used to find the server's private key. If you set this to an empty string, then no private key is loaded. </td> </tr> <tr> <td> cert_file <i>"filename"</i> </td> <td> "/etc/pki/libvirt/ servercert.pem" </td> <td> Change the path used to find the server's certificate. If you set this to an empty string, then no certificate is loaded. </td> </tr> <tr> <td> ca_file <i>"filename"</i> </td> <td> "/etc/pki/CA/cacert.pem" </td> <td> Change the path used to find the trusted CA certificate. If you set this to an empty string, then no trusted CA certificate is loaded. </td> </tr> <tr> <td> crl_file <i>"filename"</i> </td> <td> (no CRL file is used) </td> <td> Change the path used to find the CA certificate revocation list (CRL) file. If you set this to an empty string, then no CRL is loaded. </td> </tr> <tr> <td> tls_allowed_dn_list ["DN1", "DN2"] </td> <td> (none - DNs are not checked) </td> <td> <p> Enable an access control list of client certificate Distinguished Names (DNs) which can connect to the TLS port on this server. </p> <p> The default is that DNs are not checked. </p> <p> This list may contain wildcards such as <code>"C=GB,ST=London,L=London,O=Red Hat,CN=*"</code> See the POSIX <code>fnmatch</code> function for the format of the wildcards. </p> <p> Note that if this is an empty list, <i>no client can connect</i>. </p> <p> Note also that GnuTLS returns DNs without spaces after commas between the fields (and this is what we check against), but the <code>openssl x509</code> tool shows spaces. </p> </td> </tr> </table> <h3> <a name="Remote_IPv6">IPv6 support</a> </h3> <p> The libvirtd service and libvirt remote client driver both use the <code>getaddrinfo()</code> functions for name resolution and are thus fully IPv6 enabled. ie, if a server has IPv6 address configured the daemon will listen for incoming connections on both IPv4 and IPv6 protocols. If a client has an IPv6 address configured and the DNS address resolved for a service is reachable over IPv6, then an IPv6 connection will be made, otherwise IPv4 will be used. In summary it should just 'do the right thing(tm)'. </p> <h3> <a name="Remote_limitations">Limitations</a> </h3> <ul> <li> Fine-grained authentication: libvirt in general, but in particular the remote case should support more fine-grained authentication for operations, rather than just read-write/read-only as at present. </li> </ul> <p> Please come and discuss these issues and more on <a href="https://www.redhat.com/mailman/listinfo/libvir-list" title="libvir-list mailing list">the mailing list</a>. </p> </body> </html>