From: dlg Date: Fri, 23 Feb 2018 02:52:28 +0000 (+0000) Subject: provide some (probably too many) nvgre(4) examples X-Git-Url: http://artulab.com/gitweb/?a=commitdiff_plain;h=f25ef8878e598553ecfe3f089f55f2032493be2f;p=openbsd provide some (probably too many) nvgre(4) examples --- diff --git a/share/man/man4/gre.4 b/share/man/man4/gre.4 index 9ae70e838ef..2f622f1635c 100644 --- a/share/man/man4/gre.4 +++ b/share/man/man4/gre.4 @@ -1,4 +1,4 @@ -.\" $OpenBSD: gre.4,v 1.62 2018/02/22 23:03:34 dlg Exp $ +.\" $OpenBSD: gre.4,v 1.63 2018/02/23 02:52:28 dlg Exp $ .\" $NetBSD: gre.4,v 1.10 1999/12/22 14:55:49 kleink Exp $ .\" .\" Copyright 1998 (c) The NetBSD Foundation, Inc. @@ -28,7 +28,7 @@ .\" ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE .\" POSSIBILITY OF SUCH DAMAGE. .\" -.Dd $Mdocdate: February 22 2018 $ +.Dd $Mdocdate: February 23 2018 $ .Dt GRE 4 .Os .Sh NAME @@ -313,6 +313,7 @@ communication. .\" bridge(4) ioctls should go here too. .El .Sh EXAMPLES +.Ss Point-to-Point Layer 3 GRE tunnel interfaces (gre) .Nm gre Configuration example: .Bd -literal @@ -395,6 +396,154 @@ In most cases the following should work: .Bd -literal -offset indent pass quick on gre proto gre no state .Ed +.Ss Network Virtualization Using GRE interfaces (nvgre) +NVGRE can be used to build a distinct logical Ethernet network +on top of another network. +.Nm nvgre +is therefore like a +.Xr vlan 4 +interface configured on top of a physical Ethernet interface, +except it can sit on any IP network capable of multicast. +.Pp +The following shows a basic +.Nm nvgre +configuration and an equivalent +.Xr vlan 4 +configuration. +In the examples, 192.168.0.1/24 will be the network configured on +the relevent virtual interfaces. +The NVGRE underlay network will be configured on 100.64.10.0/24, +and will use 239.1.1.100 as the multicast group address. +.Pp +The +.Xr vlan 4 +interface only relies on Ethernet, it does not rely on IP configuration +on the parent interface: +.Bd -literal -offset indent +# ifconfig em0 up +# ifconfig vlan0 create +# ifconfig vlan0 parent em0 +# ifconfig vlan0 vnetid 10 +# ifconfig vlan0 inet 192.168.0.1/24 +# ifconfig vlan0 up +.Ed +.Pp +.Nm nvgre +relies on IP configuration on the parent interface, and an MTU large +enough to carry the encapsulated traffic: +.Bd -literal -offset indent +# ifconfig em0 mtu 1600 +# ifconfig em0 inet 100.64.10.1/24 +# ifconfig em0 up +# ifconfig nvgre0 create +# ifconfig nvgre0 parent em0 tunnel 100.64.10.1 239.1.1.100 +# ifconfig nvgre0 vnetid 10010 +# ifconfig nvgre0 inet 192.168.0.1/24 +# ifconfig nvgre0 up +.Ed +.Pp +NVGRE is intended for use in a multitenant datacentre environment to +provide each customer with distinct Ethernet networks as needed, +but without running into the limit on the number of VLAN tags, and +without requiring reconfiguration of the underlying Ethernet +infrastructure. +Another way to look at it is NVGRE can be used to construct multipoint +Ethernet VPNs across an IP core. +.Pp +For example, if a customer has multiple virtual machines running in +.Xr vmm 4 +on distinct physical hosts, +.Nm nvgre +and +.Xr bridge 4 +can be used to provide network connectivity between the +.Xr tap 4 +interfaces connected to the virtual machines. + +If there are 3 virtual machines, all using tap0 on each hosts, and +those hosts are connected to the same network described above, +.Nm nvgre +with a distinct virtual network identifier and multicast group can +be created for them. +The following assumes nvgre1 and bridge1 have already been created +on each host: +.Pp +On physical host 1: +.Bd -literal -offset indent +hv0# ifconfig em0 inet 100.64.10.10/24 +hv0# ifconfig nvgre1 parent em0 tunnel 100.64.10.10 239.1.1.111 +hv0# ifconfig nvgre1 vnetid 10011 +hv0# ifconfig bridge1 add nvgre1 add tap0 up +.Ed +.Pp +On physical host 2: +.Bd -literal -offset indent +hv1# ifconfig em0 inet 100.64.10.11/24 +hv1# ifconfig nvgre1 parent em0 tunnel 100.64.10.11 239.1.1.111 +hv1# ifconfig nvgre1 vnetid 10011 +hv1# ifconfig bridge1 add nvgre1 add tap0 up +.Ed +.Pp +On physical host 3: +.Bd -literal -offset indent +hv2# ifconfig em0 inet 100.64.10.12/24 +hv2# ifconfig nvgre1 parent em0 tunnel 100.64.10.12 239.1.1.111 +hv2# ifconfig nvgre1 vnetid 10011 +hv2# ifconfig bridge1 add nvgre1 add tap0 up +.Ed +.Pp +Being able to carry working multicast and jumbo frames over the +public internet is unlikely, which makes it difficult to use NVGRE +to extended Ethernet VPNs between different sites. +.Nm nvgre +and +.Nm egre +can be bridged together to provide such connectivity. +.Pp +In this example the NVE device at the first site has a public IP +of 192.0.2.1, and uses 100.64.10.0/24 for the NVGRE underlay network. +The second site has a public IP 203.0.113.2, and uses 100.64.11.0/24 for +the NVGRE underlay. +.Nm egre +is explicitly configured to provide the same MTU as the +.Nm nvgre +interfaces, but allows the encapsulated frames to be fragmented. +Multiple +.Nm egre +interfaces are used to carry traffic for two different NVGRE networks, +so each interface must configure distinct virtual network identifiers. +.Pp +At the first site: +.Bd -literal -offset indent +nve0# ifconfig nvgre0 parent em0 tunnel 100.64.10.1 239.1.1.100 +nve0# ifconfig nvgre0 vnetid 10000 +nve0# ifconfig egre0 create +nve0# ifconfig egre0 tunnel 192.0.2.1 203.0.113.2 +nve0# ifconfig egre0 vnetid 10000 vnetflowid -tunneldf +nve0# ifconfig bridge0 add nvgre0 add egre0 up +nve0# ifconfig nvgre1 parent em0 tunnel 100.64.10.1 239.1.1.111 +nve0# ifconfig nvgre1 vnetid 10011 +nve0# ifconfig egre1 create +nve0# ifconfig egre1 tunnel 192.0.2.1 203.0.113.2 +nve0# ifconfig egre1 vnetid 10011 vnetflowid -tunneldf +nve0# ifconfig bridge0 add nvgre0 add egre0 up +.Ed +.Pp +At the second site: +.Bd -literal -offset indent +nve1# ifconfig nvgre0 parent em0 tunnel 100.64.11.1 239.1.1.100 +nve1# ifconfig nvgre0 vnetid 10000 +nve1# ifconfig egre0 create +nve1# ifconfig egre0 tunnel 203.0.113.2 192.0.2.1 +nve1# ifconfig egre0 vnetid 10000 vnetflowid -tunneldf +nve1# ifconfig bridge0 add nvgre0 add egre0 up +nve1# ifconfig nvgre1 parent em0 tunnel 100.64.11.1 239.1.1.111 +nve1# ifconfig nvgre1 vnetid 10011 +nve1# ifconfig egre1 create +nve1# ifconfig egre1 tunnel 203.0.113.2 192.0.2.1 +nve1# ifconfig egre1 vnetid 10011 vnetflowid -tunneldf +nve1# ifconfig bridge1 add nvgre1 add egre1 up +.Ed .Sh SEE ALSO .Xr inet 4 , .Xr ip 4 ,