da/d06/adj__midchain_8c_source.html

 /*
  * Copyright (c) 2016 Cisco and/or its affiliates.
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at:
  *
  *     http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #include <vnet/adj/adj_nbr.h>
 #include <vnet/adj/adj_internal.h>
 #include <vnet/adj/adj_l2.h>
 #include <vnet/adj/adj_midchain.h>
 #include <vnet/ethernet/arp_packet.h>
 #include <vnet/dpo/drop_dpo.h>
 #include <vnet/fib/fib_walk.h>

 /**
  * The two midchain tx feature node indices
  */
 static u32 adj_midchain_tx_feature_node[VNET_LINK_NUM];
 static u32 adj_midchain_tx_no_count_feature_node[VNET_LINK_NUM];

 /**
  * @brief Trace data for packets traversing the midchain tx node
  */
 typedef struct adj_midchain_tx_trace_t_
 {
     /**
      * @brief the midchain adj we are traversing
      */
     adj_index_t ai;
 } adj_midchain_tx_trace_t;

 always_inline uword
 adj_midchain_tx_inline (vlib_main_t * vm,
                         vlib_node_runtime_t * node,
                         vlib_frame_t * frame,
                         int interface_count)
 {
     u32 * from, * to_next, n_left_from, n_left_to_next;
     u32 next_index;
     vnet_main_t *vnm = vnet_get_main ();
     vnet_interface_main_t *im = &vnm->interface_main;
     u32 cpu_index = vm->cpu_index;

     /* Vector of buffer / pkt indices we're supposed to process */
     from = vlib_frame_vector_args (frame);

     /* Number of buffers / pkts */
     n_left_from = frame->n_vectors;

     /* Speculatively send the first buffer to the last disposition we used */
     next_index = node->cached_next_index;

     while (n_left_from > 0)
     {
         /* set up to enqueue to our disposition with index = next_index */
         vlib_get_next_frame (vm, node, next_index, to_next, n_left_to_next);


         while (n_left_from >= 4 && n_left_to_next > 2)
         {
             u32 bi0, adj_index0, next0;
             const ip_adjacency_t * adj0;
             const dpo_id_t *dpo0;
             vlib_buffer_t * b0;
             u32 bi1, adj_index1, next1;
             const ip_adjacency_t * adj1;
             const dpo_id_t *dpo1;
             vlib_buffer_t * b1;

             /* Prefetch next iteration. */
             {
                 vlib_buffer_t * p2, * p3;

                 p2 = vlib_get_buffer (vm, from[2]);
                 p3 = vlib_get_buffer (vm, from[3]);

                 vlib_prefetch_buffer_header (p2, LOAD);
                 vlib_prefetch_buffer_header (p3, LOAD);

                 CLIB_PREFETCH (p2->data, CLIB_CACHE_LINE_BYTES, STORE);
                 CLIB_PREFETCH (p3->data, CLIB_CACHE_LINE_BYTES, STORE);
             }

             bi0 = from[0];
             to_next[0] = bi0;
             bi1 = from[1];
             to_next[1] = bi1;

             from += 2;
             to_next += 2;
             n_left_from -= 2;
             n_left_to_next -= 2;

             b0 = vlib_get_buffer(vm, bi0);
             b1 = vlib_get_buffer(vm, bi1);

             /* Follow the DPO on which the midchain is stacked */
             adj_index0 = vnet_buffer(b0)->ip.adj_index[VLIB_TX];
             adj_index1 = vnet_buffer(b1)->ip.adj_index[VLIB_TX];

             adj0 = adj_get(adj_index0);
             adj1 = adj_get(adj_index1);

             dpo0 = &adj0->sub_type.midchain.next_dpo;
             dpo1 = &adj1->sub_type.midchain.next_dpo;

             next0 = dpo0->dpoi_next_node;
             next1 = dpo1->dpoi_next_node;

             vnet_buffer(b1)->ip.adj_index[VLIB_TX] = dpo1->dpoi_index;
             vnet_buffer(b0)->ip.adj_index[VLIB_TX] = dpo0->dpoi_index;

             if (interface_count)
             {
                 vlib_increment_combined_counter (im->combined_sw_if_counters
                                                  + VNET_INTERFACE_COUNTER_TX,
                                                  cpu_index,
                                                  adj0->rewrite_header.sw_if_index,
                                                  1,
                                                  vlib_buffer_length_in_chain (vm, b0));
                 vlib_increment_combined_counter (im->combined_sw_if_counters
                                                  + VNET_INTERFACE_COUNTER_TX,
                                                  cpu_index,
                                                  adj1->rewrite_header.sw_if_index,
                                                  1,
                                                  vlib_buffer_length_in_chain (vm, b1));
             }

             if (PREDICT_FALSE(b0->flags & VLIB_BUFFER_IS_TRACED))
             {
                 adj_midchain_tx_trace_t *tr = vlib_add_trace (vm, node,
                                                               b0, sizeof (*tr));
                 tr->ai = adj_index0;
             }
             if (PREDICT_FALSE(b1->flags & VLIB_BUFFER_IS_TRACED))
             {
                 adj_midchain_tx_trace_t *tr = vlib_add_trace (vm, node,
                                                               b1, sizeof (*tr));
                 tr->ai = adj_index1;
             }

             vlib_validate_buffer_enqueue_x2 (vm, node, next_index,
                                              to_next, n_left_to_next,
                                              bi0, bi1,
                                              next0, next1);
         }
         while (n_left_from > 0 && n_left_to_next > 0)
         {
             u32 bi0, adj_index0, next0;
             const ip_adjacency_t * adj0;
             const dpo_id_t *dpo0;
             vlib_buffer_t * b0;

             bi0 = from[0];
             to_next[0] = bi0;
             from += 1;
             to_next += 1;
             n_left_from -= 1;
             n_left_to_next -= 1;

             b0 = vlib_get_buffer(vm, bi0);

             /* Follow the DPO on which the midchain is stacked */
             adj_index0 = vnet_buffer(b0)->ip.adj_index[VLIB_TX];
             adj0 = adj_get(adj_index0);
             dpo0 = &adj0->sub_type.midchain.next_dpo;
             next0 = dpo0->dpoi_next_node;
             vnet_buffer(b0)->ip.adj_index[VLIB_TX] = dpo0->dpoi_index;

             if (interface_count)
             {
                 vlib_increment_combined_counter (im->combined_sw_if_counters
                                                  + VNET_INTERFACE_COUNTER_TX,
                                                  cpu_index,
                                                  adj0->rewrite_header.sw_if_index,
                                                  1,
                                                  vlib_buffer_length_in_chain (vm, b0));
             }

             if (PREDICT_FALSE(b0->flags & VLIB_BUFFER_IS_TRACED))
             {
                 adj_midchain_tx_trace_t *tr = vlib_add_trace (vm, node,
                                                               b0, sizeof (*tr));
                 tr->ai = adj_index0;
             }

             vlib_validate_buffer_enqueue_x1 (vm, node, next_index,
                                              to_next, n_left_to_next,
                                              bi0, next0);
         }

         vlib_put_next_frame (vm, node, next_index, n_left_to_next);
     }

     return frame->n_vectors;
 }

 static u8 *
 format_adj_midchain_tx_trace (u8 * s, va_list * args)
 {
     CLIB_UNUSED (vlib_main_t * vm) = va_arg (*args, vlib_main_t *);
     CLIB_UNUSED (vlib_node_t * node) = va_arg (*args, vlib_node_t *);
     adj_midchain_tx_trace_t *tr = va_arg (*args, adj_midchain_tx_trace_t*);

     s = format(s, "adj-midchain:[%d]:%U", tr->ai,
                format_ip_adjacency, tr->ai,
                FORMAT_IP_ADJACENCY_NONE);

     return (s);
 }

 static uword
 adj_midchain_tx (vlib_main_t * vm,
                  vlib_node_runtime_t * node,
                  vlib_frame_t * frame)
 {
     return (adj_midchain_tx_inline(vm, node, frame, 1));
 }

 VLIB_REGISTER_NODE (adj_midchain_tx_node, static) = {
     .function = adj_midchain_tx,
     .name = "adj-midchain-tx",
     .vector_size = sizeof (u32),

     .format_trace = format_adj_midchain_tx_trace,

     .n_next_nodes = 1,
     .next_nodes = {
         [0] = "error-drop",
     },
 };

 static uword
 adj_midchain_tx_no_count (vlib_main_t * vm,
                           vlib_node_runtime_t * node,
                           vlib_frame_t * frame)
 {
     return (adj_midchain_tx_inline(vm, node, frame, 0));
 }

 VLIB_REGISTER_NODE (adj_midchain_tx_no_count_node, static) = {
     .function = adj_midchain_tx_no_count,
     .name = "adj-midchain-tx-no-count",
     .vector_size = sizeof (u32),

     .format_trace = format_adj_midchain_tx_trace,

     .n_next_nodes = 1,
     .next_nodes = {
         [0] = "error-drop",
     },
 };

 VNET_FEATURE_INIT (adj_midchain_tx_ip4, static) = {
     .arc_name = "ip4-output",
     .node_name = "adj-midchain-tx",
     .runs_before = VNET_FEATURES ("interface-output"),
     .feature_index_ptr = &adj_midchain_tx_feature_node[VNET_LINK_IP4],
 };
 VNET_FEATURE_INIT (adj_midchain_tx_no_count_ip4, static) = {
     .arc_name = "ip4-output",
     .node_name = "adj-midchain-tx-no-count",
     .runs_before = VNET_FEATURES ("interface-output"),
     .feature_index_ptr = &adj_midchain_tx_no_count_feature_node[VNET_LINK_IP4],
 };
 VNET_FEATURE_INIT (adj_midchain_tx_ip6, static) = {
     .arc_name = "ip6-output",
     .node_name = "adj-midchain-tx",
     .runs_before = VNET_FEATURES ("interface-output"),
     .feature_index_ptr = &adj_midchain_tx_feature_node[VNET_LINK_IP6],
 };
 VNET_FEATURE_INIT (adj_midchain_tx_no_count_ip6, static) = {
     .arc_name = "ip6-output",
     .node_name = "adj-midchain-tx-no-count",
     .runs_before = VNET_FEATURES ("interface-output"),
     .feature_index_ptr = &adj_midchain_tx_no_count_feature_node[VNET_LINK_IP6],
 };
 VNET_FEATURE_INIT (adj_midchain_tx_mpls, static) = {
     .arc_name = "mpls-output",
     .node_name = "adj-midchain-tx",
     .runs_before = VNET_FEATURES ("interface-output"),
     .feature_index_ptr = &adj_midchain_tx_feature_node[VNET_LINK_MPLS],
 };
 VNET_FEATURE_INIT (adj_midchain_tx_no_count_mpls, static) = {
     .arc_name = "mpls-output",
     .node_name = "adj-midchain-tx-no-count",
     .runs_before = VNET_FEATURES ("interface-output"),
     .feature_index_ptr = &adj_midchain_tx_no_count_feature_node[VNET_LINK_MPLS],
 };
 VNET_FEATURE_INIT (adj_midchain_tx_ethernet, static) = {
     .arc_name = "ethernet-output",
     .node_name = "adj-midchain-tx",
     .runs_before = VNET_FEATURES ("error-drop"),
     .feature_index_ptr = &adj_midchain_tx_feature_node[VNET_LINK_ETHERNET],
 };
 VNET_FEATURE_INIT (adj_midchain_tx_no_count_ethernet, static) = {
     .arc_name = "ethernet-output",
     .node_name = "adj-midchain-tx-no-count",
     .runs_before = VNET_FEATURES ("error-drop"),
     .feature_index_ptr = &adj_midchain_tx_no_count_feature_node[VNET_LINK_ETHERNET],
 };

 static inline u32
 adj_get_midchain_node (vnet_link_t link)
 {
     switch (link) {
     case VNET_LINK_IP4:
         return (ip4_midchain_node.index);
     case VNET_LINK_IP6:
         return (ip6_midchain_node.index);
     case VNET_LINK_MPLS:
         return (mpls_midchain_node.index);
     case VNET_LINK_ETHERNET:
         return (adj_l2_midchain_node.index);
     case VNET_LINK_ARP:
         break;
     }
     ASSERT(0);
     return (0);
 }

 static u8
 adj_midchain_get_feature_arc_index_for_link_type (const ip_adjacency_t *adj)
 {
   u8 arc = (u8) ~0;
     switch (adj->ia_link)
     {
     case VNET_LINK_IP4:
         {
             arc = ip4_main.lookup_main.output_feature_arc_index;
             break;
         }
     case VNET_LINK_IP6:
         {
             arc = ip6_main.lookup_main.output_feature_arc_index;
             break;
         }
     case VNET_LINK_MPLS:
         {
             arc = mpls_main.output_feature_arc_index;
             break;
         }
     case VNET_LINK_ETHERNET:
         {
             arc = ethernet_main.output_feature_arc_index;
             break;
         }
     case VNET_LINK_ARP:
         ASSERT(0);
         break;
     }

     ASSERT (arc != (u8) ~0);

     return (arc);
 }

 /**
  * adj_nbr_midchain_update_rewrite
  *
  * Update the adjacency's rewrite string. A NULL string implies the
  * rewrite is reset (i.e. when ARP/ND etnry is gone).
  * NB: the adj being updated may be handling traffic in the DP.
  */
 void
 adj_nbr_midchain_update_rewrite (adj_index_t adj_index,
                                  adj_midchain_fixup_t fixup,
                                  adj_midchain_flag_t flags,
                                  u8 *rewrite)
 {
     ip_adjacency_t *adj;
     u8 arc_index;
     u32 feature_index;

     ASSERT(ADJ_INDEX_INVALID != adj_index);

     adj = adj_get(adj_index);

     /*
      * one time only update. since we don't support chainging the tunnel
      * src,dst, this is all we need.
      */
     ASSERT(adj->lookup_next_index == IP_LOOKUP_NEXT_ARP);
     /*
      * tunnels can always provide a rewrite.
      */
     ASSERT(NULL != rewrite);

     adj->sub_type.midchain.fixup_func = fixup;

     arc_index = adj_midchain_get_feature_arc_index_for_link_type (adj);
     feature_index = (flags & ADJ_MIDCHAIN_FLAG_NO_COUNT) ?
                     adj_midchain_tx_no_count_feature_node[adj->ia_link] :
                     adj_midchain_tx_feature_node[adj->ia_link];

     adj->sub_type.midchain.tx_function_node = (flags & ADJ_MIDCHAIN_FLAG_NO_COUNT) ?
                                                adj_midchain_tx_no_count_node.index :
                                                adj_midchain_tx_node.index;

     vnet_feature_enable_disable_with_index (arc_index, feature_index,
                                             adj->rewrite_header.sw_if_index,
                                             1 /* enable */, 0, 0);

     /*
      * stack the midchain on the drop so it's ready to forward in the adj-midchain-tx.
      * The graph arc used/created here is from the midchain-tx node to the
      * child's registered node. This is because post adj processing the next
      * node are any output features, then the midchain-tx.  from there we
      * need to get to the stacked child's node.
      */
     dpo_stack_from_node(adj->sub_type.midchain.tx_function_node,
                         &adj->sub_type.midchain.next_dpo,
                         drop_dpo_get(vnet_link_to_dpo_proto(adj->ia_link)));

     /*
      * update the rewirte with the workers paused.
      */
     adj_nbr_update_rewrite_internal(adj,
                                     IP_LOOKUP_NEXT_MIDCHAIN,
                                     adj_get_midchain_node(adj->ia_link),
                                     adj->sub_type.midchain.tx_function_node,
                                     rewrite);
 }

 /**
  * adj_nbr_midchain_unstack
  *
  * Unstack the adj. stack it on drop
  */
 void
 adj_nbr_midchain_unstack (adj_index_t adj_index)
 {
     ip_adjacency_t *adj;

     ASSERT(ADJ_INDEX_INVALID != adj_index);

     adj = adj_get(adj_index);

     /*
      * stack on the drop
      */
     dpo_stack(DPO_ADJACENCY_MIDCHAIN,
               vnet_link_to_dpo_proto(adj->ia_link),
               &adj->sub_type.midchain.next_dpo,
               drop_dpo_get(vnet_link_to_dpo_proto(adj->ia_link)));

     CLIB_MEMORY_BARRIER();
 }

 /**
  * adj_nbr_midchain_stack
  */
 void
 adj_nbr_midchain_stack (adj_index_t adj_index,
                         const dpo_id_t *next)
 {
     ip_adjacency_t *adj;

     ASSERT(ADJ_INDEX_INVALID != adj_index);

     adj = adj_get(adj_index);

     ASSERT(IP_LOOKUP_NEXT_MIDCHAIN == adj->lookup_next_index);

     dpo_stack_from_node(adj->sub_type.midchain.tx_function_node,
                         &adj->sub_type.midchain.next_dpo,
                         next);
 }

 u8*
 format_adj_midchain (u8* s, va_list *ap)
 {
     index_t index = va_arg(*ap, index_t);
     u32 indent = va_arg(*ap, u32);
     vnet_main_t * vnm = vnet_get_main();
     ip_adjacency_t * adj = adj_get(index);

     s = format (s, "%U", format_vnet_link, adj->ia_link);
     s = format (s, " via %U ",
                 format_ip46_address, &adj->sub_type.nbr.next_hop);
     s = format (s, " %U",
                 format_vnet_rewrite,
                 vnm->vlib_main, &adj->rewrite_header,
                 sizeof (adj->rewrite_data), indent);
     s = format (s, "\n%Ustacked-on:\n%U%U",
                 format_white_space, indent,
                 format_white_space, indent+2,
                 format_dpo_id, &adj->sub_type.midchain.next_dpo, indent+2);

     return (s);
 }

 static void
 adj_dpo_lock (dpo_id_t *dpo)
 {
     adj_lock(dpo->dpoi_index);
 }
 static void
 adj_dpo_unlock (dpo_id_t *dpo)
 {
     adj_unlock(dpo->dpoi_index);
 }

 const static dpo_vft_t adj_midchain_dpo_vft = {
     .dv_lock = adj_dpo_lock,
     .dv_unlock = adj_dpo_unlock,
     .dv_format = format_adj_midchain,
 };

 /**
  * @brief The per-protocol VLIB graph nodes that are assigned to a midchain
  *        object.
  *
  * this means that these graph nodes are ones from which a midchain is the
  * parent object in the DPO-graph.
  */
 const static char* const midchain_ip4_nodes[] =
 {
     "ip4-midchain",
     NULL,
 };
 const static char* const midchain_ip6_nodes[] =
 {
     "ip6-midchain",
     NULL,
 };
 const static char* const midchain_mpls_nodes[] =
 {
     "mpls-midchain",
     NULL,
 };
 const static char* const midchain_ethernet_nodes[] =
 {
     "adj-l2-midchain",
     NULL,
 };

 const static char* const * const midchain_nodes[DPO_PROTO_NUM] =
 {
     [DPO_PROTO_IP4]  = midchain_ip4_nodes,
     [DPO_PROTO_IP6]  = midchain_ip6_nodes,
     [DPO_PROTO_MPLS] = midchain_mpls_nodes,
     [DPO_PROTO_ETHERNET] = midchain_ethernet_nodes,
 };

 void
 adj_midchain_module_init (void)
 {
     dpo_register(DPO_ADJACENCY_MIDCHAIN, &adj_midchain_dpo_vft, midchain_nodes);
 }
adj_midchain_tx
static uword adj_midchain_tx(vlib_main_t *vm, vlib_node_runtime_t *node, vlib_frame_t *frame)
Definition: adj_midchain.c:222

format_ip46_address
format_function_t format_ip46_address
Definition: format.h:61

vlib_put_next_frame
void vlib_put_next_frame(vlib_main_t *vm, vlib_node_runtime_t *r, u32 next_index, u32 n_vectors_left)
Release pointer to next frame vector data.
Definition: main.c:459

midchain_ip6_nodes
static const char *const midchain_ip6_nodes[]
Definition: adj_midchain.c:531

dpo_stack_from_node
void dpo_stack_from_node(u32 child_node_index, dpo_id_t *dpo, const dpo_id_t *parent)
Stack one DPO object on another, and thus establish a child parent relationship.
Definition: dpo.c:413

dpo_vft_t_::dv_lock
dpo_lock_fn_t dv_lock
A reference counting lock function.
Definition: dpo.h:327

VNET_LINK_NUM
#define VNET_LINK_NUM
Number of link types.
Definition: interface.h:257

adj_midchain_tx_no_count_feature_node
static u32 adj_midchain_tx_no_count_feature_node[VNET_LINK_NUM]
Definition: adj_midchain.c:28

ip6_midchain_node
vlib_node_registration_t ip6_midchain_node
(constructor) VLIB_REGISTER_NODE (ip6_midchain_node)
Definition: ip6_forward.c:2301

vnet_interface_main_t
Definition: interface.h:589

CLIB_UNUSED
#define CLIB_UNUSED(x)
Definition: clib.h:79

dpo_vft_t_
A virtual function table regisitered for a DPO type.
Definition: dpo.h:322

adj_midchain_tx_node
static vlib_node_registration_t adj_midchain_tx_node
(constructor) VLIB_REGISTER_NODE (adj_midchain_tx_node)
Definition: adj_midchain.c:229

adj_lock
void adj_lock(adj_index_t adj_index)
An adjacency is a representation of an attached L3 peer.
Definition: adj.c:192

adj_midchain_tx_no_count
static uword adj_midchain_tx_no_count(vlib_main_t *vm, vlib_node_runtime_t *node, vlib_frame_t *frame)
Definition: adj_midchain.c:243

vnet_main_t::interface_main
vnet_interface_main_t interface_main
Definition: vnet.h:57

midchain_ip4_nodes
static const char *const midchain_ip4_nodes[]
The per-protocol VLIB graph nodes that are assigned to a midchain object.
Definition: adj_midchain.c:526

format_vnet_link
u8 * format_vnet_link(u8 *s, va_list ap)
Definition: fib_types.c:38

NULL
#define NULL
Definition: clib.h:55

ip_adjacency_t_
IP unicast adjacency.
Definition: lookup.h:188

ip4_midchain_node
vlib_node_registration_t ip4_midchain_node
(constructor) VLIB_REGISTER_NODE (ip4_midchain_node)
Definition: ip4_forward.c:2642

index_t
u32 index_t
A Data-Path Object is an object that represents actions that are applied to packets are they are swit...
Definition: dpo.h:41

arp_packet.h

ip4_main_t::lookup_main
ip_lookup_main_t lookup_main
Definition: ip4.h:97

adj_nbr_update_rewrite_internal
void adj_nbr_update_rewrite_internal(ip_adjacency_t *adj, ip_lookup_next_t adj_next_index, u32 complete_next_index, u32 next_index, u8 *rewrite)

adj_internal.h

vlib_buffer_length_in_chain
static uword vlib_buffer_length_in_chain(vlib_main_t *vm, vlib_buffer_t *b)
Get length in bytes of the buffer chain.
Definition: buffer_funcs.h:100

VNET_LINK_ARP
Definition: interface.h:242

DPO_PROTO_MPLS
Definition: dpo.h:69

vlib_frame_t
Definition: node.h:332

ip_adjacency_t_::sub_type
union ip_adjacency_t_::@175 sub_type

VNET_LINK_ETHERNET
Definition: interface.h:241

ip_adjacency_t_::ia_link
vnet_link_t ia_link
Definition: lookup.h:215

adj_nbr_midchain_update_rewrite
void adj_nbr_midchain_update_rewrite(adj_index_t adj_index, adj_midchain_fixup_t fixup, adj_midchain_flag_t flags, u8 *rewrite)
adj_nbr_midchain_update_rewrite
Definition: adj_midchain.c:375

drop_dpo_get
const dpo_id_t * drop_dpo_get(dpo_proto_t proto)
Definition: drop_dpo.c:25

ip_lookup_main_t::output_feature_arc_index
u8 output_feature_arc_index
Definition: lookup.h:390

vlib_node_runtime_t
Definition: node.h:412

ethernet_main
ethernet_main_t ethernet_main
Definition: ethernet.h:270

vnet_get_main
vnet_main_t * vnet_get_main(void)
Definition: misc.c:46

adj_get
static ip_adjacency_t * adj_get(adj_index_t adj_index)
Get a pointer to an adjacency object from its index.
Definition: adj.h:117

dpo_register
void dpo_register(dpo_type_t type, const dpo_vft_t *vft, const char *const *const *nodes)
For a given DPO type Register:
Definition: dpo.c:246

vnet_link_to_dpo_proto
dpo_proto_t vnet_link_to_dpo_proto(vnet_link_t linkt)
Definition: dpo.c:88

always_inline
#define always_inline
Definition: clib.h:84

vnet_interface_main_t::combined_sw_if_counters
vlib_combined_counter_main_t * combined_sw_if_counters
Definition: interface.h:615

format_white_space
u8 * format_white_space(u8 *s, va_list *va)
Definition: std-formats.c:113

vnet_feature_enable_disable_with_index
int vnet_feature_enable_disable_with_index(u8 arc_index, u32 feature_index, u32 sw_if_index, int enable_disable, void *feature_config, u32 n_feature_config_bytes)
Definition: feature.c:179

DPO_PROTO_IP4
Definition: dpo.h:63

fib_walk.h

adj_midchain.h

midchain_nodes
static const char *const *const midchain_nodes[DPO_PROTO_NUM]
Definition: adj_midchain.c:547

VNET_INTERFACE_COUNTER_TX
Definition: interface.h:579

ethernet_main_t::output_feature_arc_index
u8 output_feature_arc_index
Definition: ethernet.h:267

vlib_main_t::cpu_index
u32 cpu_index
Definition: main.h:159

adj_unlock
void adj_unlock(adj_index_t adj_index)
Release a reference counting lock on the adjacency.
Definition: adj.c:209

mpls_midchain_node
vlib_node_registration_t mpls_midchain_node
(constructor) VLIB_REGISTER_NODE (mpls_midchain_node)
Definition: mpls_output.c:337

format_vnet_rewrite
format_function_t format_vnet_rewrite
Definition: rewrite.h:292

adj_midchain_tx_inline
static uword adj_midchain_tx_inline(vlib_main_t *vm, vlib_node_runtime_t *node, vlib_frame_t *frame, int interface_count)
Definition: adj_midchain.c:42

mpls_main_t::output_feature_arc_index
u8 output_feature_arc_index
Definition: mpls.h:75

adj_l2_midchain_node
vlib_node_registration_t adj_l2_midchain_node
(constructor) VLIB_REGISTER_NODE (adj_l2_midchain_node)
Definition: adj_l2.c:181

midchain_mpls_nodes
static const char *const midchain_mpls_nodes[]
Definition: adj_midchain.c:536

drop_dpo.h

VNET_LINK_IP4
Definition: interface.h:235

dpo_id_t_
The identity of a DPO is a combination of its type and its instance number/index of objects of that t...
Definition: dpo.h:138

ADJ_INDEX_INVALID
#define ADJ_INDEX_INVALID
Invalid ADJ index - used when no adj is known likewise blazoned capitals INVALID speak volumes where ...
Definition: adj_types.h:36

vnet_main_t::vlib_main
vlib_main_t * vlib_main
Definition: vnet.h:79

adj_get_midchain_node
static u32 adj_get_midchain_node(vnet_link_t link)
Definition: adj_midchain.c:313

adj_midchain_tx_trace_t_
Trace data for packets traversing the midchain tx node.
Definition: adj_midchain.c:33

adj_midchain_module_init
void adj_midchain_module_init(void)
Module initialisation.
Definition: adj_midchain.c:556

adj_midchain_tx_trace_t_::ai
adj_index_t ai
the midchain adj we are traversing
Definition: adj_midchain.c:38

VNET_LINK_IP6
Definition: interface.h:239

PREDICT_FALSE
#define PREDICT_FALSE(x)
Definition: clib.h:97

adj_midchain_get_feature_arc_index_for_link_type
static u8 adj_midchain_get_feature_arc_index_for_link_type(const ip_adjacency_t *adj)
Definition: adj_midchain.c:332

adj_midchain_tx_no_count_node
static vlib_node_registration_t adj_midchain_tx_no_count_node
(constructor) VLIB_REGISTER_NODE (adj_midchain_tx_no_count_node)
Definition: adj_midchain.c:250

vlib_validate_buffer_enqueue_x2
#define vlib_validate_buffer_enqueue_x2(vm, node, next_index, to_next, n_left_to_next, bi0, bi1, next0, next1)
Finish enqueueing two buffers forward in the graph.
Definition: buffer_node.h:70

vlib_validate_buffer_enqueue_x1
#define vlib_validate_buffer_enqueue_x1(vm, node, next_index, to_next, n_left_to_next, bi0, next0)
Finish enqueueing one buffer forward in the graph.
Definition: buffer_node.h:216

adj_l2.h

vlib_get_next_frame
#define vlib_get_next_frame(vm, node, next_index, vectors, n_vectors_left)
Get pointer to next frame vector data by (vlib_node_runtime_t, next_index).
Definition: node_funcs.h:350

ADJ_MIDCHAIN_FLAG_NO_COUNT
Packets TX through the midchain do not increment the interface counters.
Definition: adj_midchain.h:44

DPO_PROTO_IP6
Definition: dpo.h:67

vlib_frame_t::n_vectors
u16 n_vectors
Definition: node.h:344

mpls_main
mpls_main_t mpls_main
Definition: mpls.c:25

CLIB_PREFETCH
#define CLIB_PREFETCH(addr, size, type)
Definition: cache.h:82

adj_dpo_unlock
static void adj_dpo_unlock(dpo_id_t *dpo)
Definition: adj_midchain.c:508

ip_adjacency_t_::nbr
struct ip_adjacency_t_::@175::@176 nbr
IP_LOOKUP_NEXT_ARP/IP_LOOKUP_NEXT_REWRITE.

format_adj_midchain_tx_trace
static u8 * format_adj_midchain_tx_trace(u8 *s, va_list *args)
Definition: adj_midchain.c:208

vlib_buffer_t
Definition: buffer.h:73

adj_index_t
u32 adj_index_t
An index for adjacencies.
Definition: adj_types.h:30

IP_LOOKUP_NEXT_ARP
This packet matches an "incomplete adjacency" and packets need to be passed to ARP to find rewrite st...
Definition: lookup.h:73

format_adj_midchain
u8 * format_adj_midchain(u8 *s, va_list *ap)
Format a midchain adjacency.
Definition: adj_midchain.c:480

vnet_main_t
Definition: vnet.h:52

vlib_node_runtime_t::cached_next_index
u16 cached_next_index
Definition: node.h:463

vlib_increment_combined_counter
static void vlib_increment_combined_counter(vlib_combined_counter_main_t *cm, u32 cpu_index, u32 index, u32 packet_increment, u32 byte_increment)
Increment a combined counter.
Definition: counter.h:241

ASSERT
#define ASSERT(truth)
Definition: error_bootstrap.h:69

FORMAT_IP_ADJACENCY_NONE
Definition: format.h:53

adj_nbr_midchain_stack
void adj_nbr_midchain_stack(adj_index_t adj_index, const dpo_id_t *next)
adj_nbr_midchain_stack
Definition: adj_midchain.c:463

u32
unsigned int u32
Definition: types.h:88

vnet_buffer
#define vnet_buffer(b)
Definition: buffer.h:361

ip6_main
ip6_main_t ip6_main
Definition: ip6_forward.c:2828

ip6_main_t::lookup_main
ip_lookup_main_t lookup_main
Definition: ip6.h:135

vnet_link_t
enum vnet_link_t_ vnet_link_t
Link Type: A description of the protocol of packets on the link.

IP_LOOKUP_NEXT_MIDCHAIN
This packets follow a mid-chain adjacency.
Definition: lookup.h:89

DPO_PROTO_ETHERNET
Definition: dpo.h:68

adj_midchain_fixup_t
void(* adj_midchain_fixup_t)(vlib_main_t *vm, struct ip_adjacency_t_ *adj, vlib_buffer_t *b0)
A function type for post-rewrite fixups on midchain adjacency.
Definition: lookup.h:170

adj_nbr_midchain_unstack
void adj_nbr_midchain_unstack(adj_index_t adj_index)
adj_nbr_midchain_unstack
Definition: adj_midchain.c:440

format_dpo_id
u8 * format_dpo_id(u8 *s, va_list *args)
Format a DPO_id_t oject
Definition: dpo.c:118

VLIB_BUFFER_IS_TRACED
#define VLIB_BUFFER_IS_TRACED
Definition: buffer.h:95

VNET_FEATURES
#define VNET_FEATURES(...)
Definition: feature.h:363

adj_dpo_lock
static void adj_dpo_lock(dpo_id_t *dpo)
Definition: adj_midchain.c:503

uword
u64 uword
Definition: types.h:112

vlib_add_trace
static void * vlib_add_trace(vlib_main_t *vm, vlib_node_runtime_t *r, vlib_buffer_t *b, u32 n_data_bytes)
Definition: trace_funcs.h:55

adj_midchain_flag_t
enum adj_midchain_flag_t_ adj_midchain_flag_t
Midchain Adjacency sub-type.

VLIB_TX
Definition: defs.h:47

DPO_PROTO_NUM
#define DPO_PROTO_NUM
Definition: dpo.h:72

dpo_id_t_::dpoi_index
index_t dpoi_index
the index of objects of that type
Definition: dpo.h:154

u8
unsigned char u8
Definition: types.h:56

ip_adjacency_t_::lookup_next_index
ip_lookup_next_t lookup_next_index
Definition: lookup.h:199

vlib_main_t
Definition: main.h:59

VNET_LINK_MPLS
Definition: interface.h:240

adj_midchain_tx_trace_t
struct adj_midchain_tx_trace_t_ adj_midchain_tx_trace_t
Trace data for packets traversing the midchain tx node.

adj_midchain_tx_feature_node
static u32 adj_midchain_tx_feature_node[VNET_LINK_NUM]
The two midchain tx feature node indices.
Definition: adj_midchain.c:27

vlib_node_t
Definition: node.h:215

vlib_frame_vector_args
static void * vlib_frame_vector_args(vlib_frame_t *f)
Get pointer to frame vector data.
Definition: node_funcs.h:253

DPO_ADJACENCY_MIDCHAIN
Definition: dpo.h:105

vlib_prefetch_buffer_header
#define vlib_prefetch_buffer_header(b, type)
Prefetch buffer metadata.
Definition: buffer.h:170

VLIB_REGISTER_NODE
#define VLIB_REGISTER_NODE(x,...)
Definition: node.h:143

format
u8 * format(u8 *s, const char *fmt,...)
Definition: format.c:418

ip4_main
ip4_main_t ip4_main
Global ip4 main structure.
Definition: ip4_forward.c:1099

vlib_buffer_t::data
u8 data[0]
Packet data.
Definition: buffer.h:158

adj_nbr.h

CLIB_MEMORY_BARRIER
#define CLIB_MEMORY_BARRIER()
Definition: clib.h:101

dpo_id_t_::dpoi_next_node
u16 dpoi_next_node
The next VLIB node to follow.
Definition: dpo.h:150

flags
u32 flags
Definition: vhost-user.h:75

CLIB_CACHE_LINE_BYTES
#define CLIB_CACHE_LINE_BYTES
Definition: cache.h:67

vlib_buffer_t::flags
u32 flags
buffer flags:   VLIB_BUFFER_IS_TRACED: trace this buffer.
Definition: buffer.h:85

midchain_ethernet_nodes
static const char *const midchain_ethernet_nodes[]
Definition: adj_midchain.c:541

vlib_get_buffer
static vlib_buffer_t * vlib_get_buffer(vlib_main_t *vm, u32 buffer_index)
Translate buffer index into buffer pointer.
Definition: buffer_funcs.h:57

VNET_FEATURE_INIT
VNET_FEATURE_INIT(adj_midchain_tx_ip4, static)

format_ip_adjacency
format_function_t format_ip_adjacency
Definition: format.h:58

dpo_stack
void dpo_stack(dpo_type_t child_type, dpo_proto_t child_proto, dpo_id_t *dpo, const dpo_id_t *parent)
Stack one DPO object on another, and thus establish a child-parent relationship.
Definition: dpo.c:398

ip_adjacency_t_::midchain
struct ip_adjacency_t_::@175::@177 midchain
IP_LOOKUP_NEXT_MIDCHAIN.