FD.io VPP  v17.10-9-gd594711
Vector Packet Processing
lisp_gpe_adjacency_t_ Struct Reference

A LISP GPE Adjacency. More...

+ Collaboration diagram for lisp_gpe_adjacency_t_:

Data Fields

fib_node_t fib_node
 The LISP adj is a part of the FIB control plane graph. More...
 
ip_address_t remote_rloc
 remote RLOC. More...
 
u32 vni
 The VNI. More...
 
u32 locks
 The number of locks/reference counts on the adjacency. More...
 
u32 lisp_l3_sub_index
 The index of the LISP L3 subinterface. More...
 
u32 sw_if_index
 The SW IF index of the sub-interface this adjacency uses. More...
 
u32 tunnel_index
 The index of the LISP GPE tunnel that provides the transport in the underlay. More...
 
u32 fib_entry_child_index
 This adjacency is a child of the FIB entry to reach the RLOC. More...
 
u8 flags
 LISP header fields in HOST byte order. More...
 
u8 ver_res
 
u8 res
 
u8 next_protocol
 

Detailed Description

A LISP GPE Adjacency.

A adjacency represents peer on an L3 sub-interface to which to send traffic. adjacencies are thus present in the EID space. The peer is identified by the key:{remote-rloc, sub-interface}, which is equivalent to the usal adjacency key {next-hop, interface}. So curiously the rloc address from the underlay is used as a next hop address in the overlay This is OK because: 1 - the RLOC is unique in the underlay AND there is only one underlay VRF per overlay 2 - the RLOC may overlap with an address in the overlay, but we do not create an adj-fib (i.e. a route in the overlay FIB for the rloc)

Definition at line 43 of file lisp_gpe_adjacency.h.

Field Documentation

u32 lisp_gpe_adjacency_t_::fib_entry_child_index

This adjacency is a child of the FIB entry to reach the RLOC.

This is so when the reachability of that RLOC changes, we can restack the FIB adjacnecies.

Definition at line 87 of file lisp_gpe_adjacency.h.

fib_node_t lisp_gpe_adjacency_t_::fib_node

The LISP adj is a part of the FIB control plane graph.

Definition at line 48 of file lisp_gpe_adjacency.h.

u8 lisp_gpe_adjacency_t_::flags

LISP header fields in HOST byte order.

Definition at line 92 of file lisp_gpe_adjacency.h.

u32 lisp_gpe_adjacency_t_::lisp_l3_sub_index

The index of the LISP L3 subinterface.

Definition at line 68 of file lisp_gpe_adjacency.h.

u32 lisp_gpe_adjacency_t_::locks

The number of locks/reference counts on the adjacency.

Definition at line 63 of file lisp_gpe_adjacency.h.

u8 lisp_gpe_adjacency_t_::next_protocol

Definition at line 95 of file lisp_gpe_adjacency.h.

ip_address_t lisp_gpe_adjacency_t_::remote_rloc

remote RLOC.

The adjacency's next-hop

Definition at line 53 of file lisp_gpe_adjacency.h.

u8 lisp_gpe_adjacency_t_::res

Definition at line 94 of file lisp_gpe_adjacency.h.

u32 lisp_gpe_adjacency_t_::sw_if_index

The SW IF index of the sub-interface this adjacency uses.

Cached for convenience from the LISP L3 sub-interface

Definition at line 74 of file lisp_gpe_adjacency.h.

u32 lisp_gpe_adjacency_t_::tunnel_index

The index of the LISP GPE tunnel that provides the transport in the underlay.

Definition at line 80 of file lisp_gpe_adjacency.h.

u8 lisp_gpe_adjacency_t_::ver_res

Definition at line 93 of file lisp_gpe_adjacency.h.

u32 lisp_gpe_adjacency_t_::vni

The VNI.

Used in combination with the local-rloc to get the sub-interface

Definition at line 58 of file lisp_gpe_adjacency.h.


The documentation for this struct was generated from the following file: