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Vector Packet Processing
fib_path.c
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1 /*
2  * Copyright (c) 2016 Cisco and/or its affiliates.
3  * Licensed under the Apache License, Version 2.0 (the "License");
4  * you may not use this file except in compliance with the License.
5  * You may obtain a copy of the License at:
6  *
7  * http://www.apache.org/licenses/LICENSE-2.0
8  *
9  * Unless required by applicable law or agreed to in writing, software
10  * distributed under the License is distributed on an "AS IS" BASIS,
11  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
12  * See the License for the specific language governing permissions and
13  * limitations under the License.
14  */
15 
16 #include <vlib/vlib.h>
17 #include <vnet/vnet.h>
18 #include <vnet/ip/format.h>
19 #include <vnet/ip/ip.h>
20 #include <vnet/dpo/drop_dpo.h>
21 #include <vnet/dpo/receive_dpo.h>
23 #include <vnet/dpo/lookup_dpo.h>
24 
25 #include <vnet/adj/adj.h>
26 
27 #include <vnet/fib/fib_path.h>
28 #include <vnet/fib/fib_node.h>
29 #include <vnet/fib/fib_table.h>
30 #include <vnet/fib/fib_entry.h>
31 #include <vnet/fib/fib_path_list.h>
32 #include <vnet/fib/fib_internal.h>
33 #include <vnet/fib/fib_urpf_list.h>
34 
35 /**
36  * Enurmeration of path types
37  */
38 typedef enum fib_path_type_t_ {
39  /**
40  * Marker. Add new types after this one.
41  */
43  /**
44  * Attached-nexthop. An interface and a nexthop are known.
45  */
47  /**
48  * attached. Only the interface is known.
49  */
51  /**
52  * recursive. Only the next-hop is known.
53  */
55  /**
56  * special. nothing is known. so we drop.
57  */
59  /**
60  * exclusive. user provided adj.
61  */
63  /**
64  * deag. Link to a lookup adj in the next table
65  */
67  /**
68  * receive. it's for-us.
69  */
71  /**
72  * Marker. Add new types before this one, then update it.
73  */
75 } __attribute__ ((packed)) fib_path_type_t;
76 
77 /**
78  * The maximum number of path_types
79  */
80 #define FIB_PATH_TYPE_MAX (FIB_PATH_TYPE_LAST + 1)
81 
82 #define FIB_PATH_TYPES { \
83  [FIB_PATH_TYPE_ATTACHED_NEXT_HOP] = "attached-nexthop", \
84  [FIB_PATH_TYPE_ATTACHED] = "attached", \
85  [FIB_PATH_TYPE_RECURSIVE] = "recursive", \
86  [FIB_PATH_TYPE_SPECIAL] = "special", \
87  [FIB_PATH_TYPE_EXCLUSIVE] = "exclusive", \
88  [FIB_PATH_TYPE_DEAG] = "deag", \
89  [FIB_PATH_TYPE_RECEIVE] = "receive", \
90 }
91 
92 #define FOR_EACH_FIB_PATH_TYPE(_item) \
93  for (_item = FIB_PATH_TYPE_FIRST; _item <= FIB_PATH_TYPE_LAST; _item++)
94 
95 /**
96  * Enurmeration of path operational (i.e. derived) attributes
97  */
99  /**
100  * Marker. Add new types after this one.
101  */
103  /**
104  * The path forms part of a recursive loop.
105  */
107  /**
108  * The path is resolved
109  */
111  /**
112  * The path has become a permanent drop.
113  */
115  /**
116  * Marker. Add new types before this one, then update it.
117  */
119 } __attribute__ ((packed)) fib_path_oper_attribute_t;
120 
121 /**
122  * The maximum number of path operational attributes
123  */
124 #define FIB_PATH_OPER_ATTRIBUTE_MAX (FIB_PATH_OPER_ATTRIBUTE_LAST + 1)
125 
126 #define FIB_PATH_OPER_ATTRIBUTES { \
127  [FIB_PATH_OPER_ATTRIBUTE_RECURSIVE_LOOP] = "recursive-loop", \
128  [FIB_PATH_OPER_ATTRIBUTE_RESOLVED] = "resolved", \
129  [FIB_PATH_OPER_ATTRIBUTE_DROP] = "drop", \
130 }
131 
132 #define FOR_EACH_FIB_PATH_OPER_ATTRIBUTE(_item) \
133  for (_item = FIB_PATH_OPER_ATTRIBUTE_FIRST; \
134  _item <= FIB_PATH_OPER_ATTRIBUTE_LAST; \
135  _item++)
136 
137 /**
138  * Path flags from the attributes
139  */
145 } __attribute__ ((packed)) fib_path_oper_flags_t;
146 
147 /**
148  * A FIB path
149  */
150 typedef struct fib_path_t_ {
151  /**
152  * A path is a node in the FIB graph.
153  */
155 
156  /**
157  * The index of the path-list to which this path belongs
158  */
160 
161  /**
162  * This marks the start of the memory area used to hash
163  * the path
164  */
165  STRUCT_MARK(path_hash_start);
166 
167  /**
168  * Configuration Flags
169  */
171 
172  /**
173  * The type of the path. This is the selector for the union
174  */
175  fib_path_type_t fp_type;
176 
177  /**
178  * The protocol of the next-hop, i.e. the address family of the
179  * next-hop's address. We can't derive this from the address itself
180  * since the address can be all zeros
181  */
183 
184  /**
185  * UCMP [unnormalised] weigt
186  */
188 
189  /**
190  * per-type union of the data required to resolve the path
191  */
192  union {
193  struct {
194  /**
195  * The next-hop
196  */
197  ip46_address_t fp_nh;
198  /**
199  * The interface
200  */
203  struct {
204  /**
205  * The interface
206  */
208  } attached;
209  struct {
210  union
211  {
212  /**
213  * The next-hop
214  */
215  ip46_address_t fp_ip;
216  /**
217  * The local label to resolve through.
218  */
220  } fp_nh;
221  /**
222  * The FIB table index in which to find the next-hop.
223  * This needs to be fixed. We should lookup the adjacencies in
224  * a separate table of adjacencies, rather than from the FIB.
225  * Two reasons I can think of:
226  * - consider:
227  * int ip addr Gig0 10.0.0.1/24
228  * ip route 10.0.0.2/32 via Gig1 192.168.1.2
229  * ip route 1.1.1.1/32 via Gig0 10.0.0.2
230  * this is perfectly valid.
231  * Packets addressed to 10.0.0.2 should be sent via Gig1.
232  * Packets address to 1.1.1.1 should be sent via Gig0.
233  * when we perform the adj resolution from the FIB for the path
234  * "via Gig0 10.0.0.2" the lookup will result in the route via Gig1
235  * and so we will pick up the adj via Gig1 - which was not what the
236  * operator wanted.
237  * - we can only return link-type IPv4 and so not the link-type MPLS.
238  * more on this in a later commit.
239  *
240  * The table ID should only belong to a recursive path and indicate
241  * which FIB should be used to resolve the next-hop.
242  */
244  } recursive;
245  struct {
246  /**
247  * The FIB index in which to perfom the next lookup
248  */
250  } deag;
251  struct {
252  } special;
253  struct {
254  /**
255  * The user provided 'exclusive' DPO
256  */
258  } exclusive;
259  struct {
260  /**
261  * The interface on which the local address is configured
262  */
264  /**
265  * The next-hop
266  */
267  ip46_address_t fp_addr;
268  } receive;
269  };
270  STRUCT_MARK(path_hash_end);
271 
272  /**
273  * Memebers in this last section represent information that is
274  * dervied during resolution. It should not be copied to new paths
275  * nor compared.
276  */
277 
278  /**
279  * Operational Flags
280  */
282 
283  /**
284  * the resolving via fib. not part of the union, since it it not part
285  * of the path's hash.
286  */
288 
289  /**
290  * The Data-path objects through which this path resolves for IP.
291  */
293 
294  /**
295  * the index of this path in the parent's child list.
296  */
298 } fib_path_t;
299 
300 /*
301  * Array of strings/names for the path types and attributes
302  */
303 static const char *fib_path_type_names[] = FIB_PATH_TYPES;
304 static const char *fib_path_oper_attribute_names[] = FIB_PATH_OPER_ATTRIBUTES;
305 static const char *fib_path_cfg_attribute_names[] = FIB_PATH_CFG_ATTRIBUTES;
306 
307 /*
308  * The memory pool from which we allocate all the paths
309  */
311 
312 /*
313  * Debug macro
314  */
315 #ifdef FIB_DEBUG
316 #define FIB_PATH_DBG(_p, _fmt, _args...) \
317 { \
318  u8 *_tmp = NULL; \
319  _tmp = fib_path_format(fib_path_get_index(_p), _tmp); \
320  clib_warning("path:[%d:%s]:" _fmt, \
321  fib_path_get_index(_p), _tmp, \
322  ##_args); \
323  vec_free(_tmp); \
324 }
325 #else
326 #define FIB_PATH_DBG(_p, _fmt, _args...)
327 #endif
328 
329 static fib_path_t *
331 {
332  return (pool_elt_at_index(fib_path_pool, index));
333 }
334 
335 static fib_node_index_t
337 {
338  return (path - fib_path_pool);
339 }
340 
341 static fib_node_t *
343 {
344  return ((fib_node_t*)fib_path_get(index));
345 }
346 
347 static fib_path_t*
349 {
350 #if CLIB_DEBUG > 0
352 #endif
353  return ((fib_path_t*)node);
354 }
355 
356 u8 *
357 format_fib_path (u8 * s, va_list * args)
358 {
359  fib_path_t *path = va_arg (*args, fib_path_t *);
360  vnet_main_t * vnm = vnet_get_main();
361  fib_path_oper_attribute_t oattr;
363 
364  s = format (s, " index:%d ", fib_path_get_index(path));
365  s = format (s, "pl-index:%d ", path->fp_pl_index);
366  s = format (s, "%U ", format_fib_protocol, path->fp_nh_proto);
367  s = format (s, "weight=%d ", path->fp_weight);
368  s = format (s, "%s: ", fib_path_type_names[path->fp_type]);
369  if (FIB_PATH_OPER_FLAG_NONE != path->fp_oper_flags) {
370  s = format(s, " oper-flags:");
372  if ((1<<oattr) & path->fp_oper_flags) {
373  s = format (s, "%s,", fib_path_oper_attribute_names[oattr]);
374  }
375  }
376  }
377  if (FIB_PATH_CFG_FLAG_NONE != path->fp_cfg_flags) {
378  s = format(s, " cfg-flags:");
380  if ((1<<cattr) & path->fp_cfg_flags) {
381  s = format (s, "%s,", fib_path_cfg_attribute_names[cattr]);
382  }
383  }
384  }
385  s = format(s, "\n ");
386 
387  switch (path->fp_type)
388  {
390  s = format (s, "%U", format_ip46_address,
391  &path->attached_next_hop.fp_nh,
392  IP46_TYPE_ANY);
394  {
395  s = format (s, " if_index:%d", path->attached_next_hop.fp_interface);
396  }
397  else
398  {
399  s = format (s, " %U",
401  vnm,
403  vnm,
404  path->attached_next_hop.fp_interface));
406  path->attached_next_hop.fp_interface))
407  {
408  s = format (s, " (p2p)");
409  }
410  }
411  if (!dpo_id_is_valid(&path->fp_dpo))
412  {
413  s = format(s, "\n unresolved");
414  }
415  else
416  {
417  s = format(s, "\n %U",
419  &path->fp_dpo, 13);
420  }
421  break;
424  {
425  s = format (s, " if_index:%d", path->attached_next_hop.fp_interface);
426  }
427  else
428  {
429  s = format (s, " %U",
431  vnm,
433  vnm,
434  path->attached.fp_interface));
435  }
436  break;
438  if (FIB_PROTOCOL_MPLS == path->fp_nh_proto)
439  {
440  s = format (s, "via %U",
442  path->recursive.fp_nh.fp_local_label);
443  }
444  else
445  {
446  s = format (s, "via %U",
448  &path->recursive.fp_nh.fp_ip,
449  IP46_TYPE_ANY);
450  }
451  s = format (s, " in fib:%d",
452  path->recursive.fp_tbl_id,
453  path->fp_via_fib);
454  s = format (s, " via-fib:%d", path->fp_via_fib);
455  s = format (s, " via-dpo:[%U:%d]",
457  path->fp_dpo.dpoi_index);
458 
459  break;
462  case FIB_PATH_TYPE_DEAG:
464  if (dpo_id_is_valid(&path->fp_dpo))
465  {
466  s = format(s, "%U", format_dpo_id,
467  &path->fp_dpo, 2);
468  }
469  break;
470  }
471  return (s);
472 }
473 
474 u8 *
476 {
477  fib_path_t *path;
478 
479  path = fib_path_get(pi);
480  ASSERT(NULL != path);
481 
482  return (format (s, "%U", format_fib_path, path));
483 }
484 
485 u8 *
487  u32 indent,
488  u8 *s)
489 {
490  fib_path_t *path;
491 
492  path = fib_path_get(pi);
493  ASSERT(NULL != path);
494 
495  if (!dpo_id_is_valid(&path->fp_dpo))
496  {
497  s = format(s, " unresolved");
498  }
499  else
500  {
501  s = format(s, "%U", format_dpo_id,
502  &path->fp_dpo, 2);
503  }
504 
505  return (s);
506 }
507 
508 /*
509  * fib_path_last_lock_gone
510  *
511  * We don't share paths, we share path lists, so the [un]lock functions
512  * are no-ops
513  */
514 static void
516 {
517  ASSERT(0);
518 }
519 
520 static const adj_index_t
522  vnet_link_t link)
523 {
525  path->attached_next_hop.fp_interface))
526  {
527  /*
528  * if the interface is p2p then the adj for the specific
529  * neighbour on that link will never exist. on p2p links
530  * the subnet address (the attached route) links to the
531  * auto-adj (see below), we want that adj here too.
532  */
533  return (adj_nbr_add_or_lock(path->fp_nh_proto,
534  link,
535  &zero_addr,
536  path->attached_next_hop.fp_interface));
537  }
538  else
539  {
540  return (adj_nbr_add_or_lock(path->fp_nh_proto,
541  link,
542  &path->attached_next_hop.fp_nh,
543  path->attached_next_hop.fp_interface));
544  }
545 }
546 
547 static void
549 {
550  /*
551  * resolve directly via the adjacnecy discribed by the
552  * interface and next-hop
553  */
555  path->attached_next_hop.fp_interface))
556  {
558  }
559 
560  dpo_set(&path->fp_dpo,
564  path,
566 
567  /*
568  * become a child of the adjacency so we receive updates
569  * when its rewrite changes
570  */
573  fib_path_get_index(path));
574 }
575 
576 /*
577  * create of update the paths recursive adj
578  */
579 static void
582  dpo_id_t *dpo)
583 {
584  dpo_id_t via_dpo = DPO_INVALID;
585 
586  /*
587  * get the DPO to resolve through from the via-entry
588  */
590  fct,
591  &via_dpo);
592 
593 
594  /*
595  * hope for the best - clear if restrictions apply.
596  */
598 
599  /*
600  * Validate any recursion constraints and over-ride the via
601  * adj if not met
602  */
604  {
607  }
609  {
610  /*
611  * the via FIB must be a host route.
612  * note the via FIB just added will always be a host route
613  * since it is an RR source added host route. So what we need to
614  * check is whether the route has other sources. If it does then
615  * some other source has added it as a host route. If it doesn't
616  * then it was added only here and inherits forwarding from a cover.
617  * the cover is not a host route.
618  * The RR source is the lowest priority source, so we check if it
619  * is the best. if it is there are no other sources.
620  */
622  {
625 
626  /*
627  * PIC edge trigger. let the load-balance maps know
628  */
630  }
631  }
633  {
634  /*
635  * RR source entries inherit the flags from the cover, so
636  * we can check the via directly
637  */
639  {
642 
643  /*
644  * PIC edge trigger. let the load-balance maps know
645  */
647  }
648  }
649 
650  /*
651  * update the path's contributed DPO
652  */
653  dpo_copy(dpo, &via_dpo);
654 
655  FIB_PATH_DBG(path, "recursive update: %U",
656  fib_get_lookup_main(path->fp_nh_proto),
657  &path->fp_dpo, 2);
658 
659  dpo_reset(&via_dpo);
660 }
661 
662 /*
663  * fib_path_is_permanent_drop
664  *
665  * Return !0 if the path is configured to permanently drop,
666  * despite other attributes.
667  */
668 static int
670 {
671  return ((path->fp_cfg_flags & FIB_PATH_CFG_FLAG_DROP) ||
673 }
674 
675 /*
676  * fib_path_unresolve
677  *
678  * Remove our dependency on the resolution target
679  */
680 static void
682 {
683  /*
684  * the forced drop path does not need unresolving
685  */
686  if (fib_path_is_permanent_drop(path))
687  {
688  return;
689  }
690 
691  switch (path->fp_type)
692  {
694  if (FIB_NODE_INDEX_INVALID != path->fp_via_fib)
695  {
696  fib_prefix_t pfx;
697 
698  fib_entry_get_prefix(path->fp_via_fib, &pfx);
700  path->fp_sibling);
702  &pfx,
703  FIB_SOURCE_RR);
705  }
706  break;
710  path->fp_sibling);
712  break;
714  dpo_reset(&path->exclusive.fp_ex_dpo);
715  break;
718  case FIB_PATH_TYPE_DEAG:
719  /*
720  * these hold only the path's DPO, which is reset below.
721  */
722  break;
723  }
724 
725  /*
726  * release the adj we were holding and pick up the
727  * drop just in case.
728  */
729  dpo_reset(&path->fp_dpo);
731 
732  return;
733 }
734 
737 {
738  switch (proto)
739  {
740  case FIB_PROTOCOL_IP4:
742  case FIB_PROTOCOL_IP6:
744  case FIB_PROTOCOL_MPLS:
746  }
748 }
749 
750 /*
751  * fib_path_back_walk_notify
752  *
753  * A back walk has reach this path.
754  */
758 {
759  fib_path_t *path;
760 
761  path = fib_path_from_fib_node(node);
762 
763  switch (path->fp_type)
764  {
767  {
768  /*
769  * modify the recursive adjacency to use the new forwarding
770  * of the via-fib.
771  * this update is visible to packets in flight in the DP.
772  */
774  path,
776  &path->fp_dpo);
777  }
780  {
781  /*
782  * ADJ updates (complete<->incomplete) do not need to propagate to
783  * recursive entries.
784  * The only reason its needed as far back as here, is that the adj
785  * and the incomplete adj are a different DPO type, so the LBs need
786  * to re-stack.
787  * If this walk was quashed in the fib_entry, then any non-fib_path
788  * children (like tunnels that collapse out the LB when they stack)
789  * would not see the update.
790  */
792  }
793  break;
795  /*
796 FIXME comment
797  * ADJ_UPDATE backwalk pass silently through here and up to
798  * the path-list when the multipath adj collapse occurs.
799  * The reason we do this is that the assumtption is that VPP
800  * runs in an environment where the Control-Plane is remote
801  * and hence reacts slowly to link up down. In order to remove
802  * this down link from the ECMP set quickly, we back-walk.
803  * VPP also has dedicated CPUs, so we are not stealing resources
804  * from the CP to do so.
805  */
807  {
809  {
810  /*
811  * alreday resolved. no need to walk back again
812  */
814  }
816  }
818  {
820  {
821  /*
822  * alreday unresolved. no need to walk back again
823  */
825  }
827  }
829  {
830  /*
831  * The interface this path resolves through has been deleted.
832  * This will leave the path in a permanent drop state. The route
833  * needs to be removed and readded (and hence the path-list deleted)
834  * before it can forward again.
835  */
836  fib_path_unresolve(path);
838  }
840  {
841  /*
842  * restack the DPO to pick up the correct DPO sub-type
843  */
844  uword if_is_up;
845  adj_index_t ai;
846 
848  vnet_get_main(),
849  path->attached_next_hop.fp_interface);
850 
851  if (if_is_up)
852  {
854  }
855 
857  path,
859 
860  dpo_set(&path->fp_dpo, DPO_ADJACENCY,
862  ai);
863  adj_unlock(ai);
864 
865  if (!if_is_up)
866  {
867  /*
868  * If the interface is not up there is no reason to walk
869  * back to children. if we did they would only evalute
870  * that this path is unresolved and hence it would
871  * not contribute the adjacency - so it would be wasted
872  * CPU time.
873  */
875  }
876  }
878  {
880  {
881  /*
882  * alreday unresolved. no need to walk back again
883  */
885  }
886  /*
887  * the adj has gone down. the path is no longer resolved.
888  */
890  }
891  break;
893  /*
894  * FIXME; this could schedule a lower priority walk, since attached
895  * routes are not usually in ECMP configurations so the backwalk to
896  * the FIB entry does not need to be high priority
897  */
899  {
901  }
903  {
905  }
907  {
908  fib_path_unresolve(path);
910  }
911  break;
912  case FIB_PATH_TYPE_DEAG:
913  /*
914  * FIXME When VRF delete is allowed this will need a poke.
915  */
919  /*
920  * these path types have no parents. so to be
921  * walked from one is unexpected.
922  */
923  ASSERT(0);
924  break;
925  }
926 
927  /*
928  * propagate the backwalk further to the path-list
929  */
931 
933 }
934 
935 static void
937 {
938  fib_show_memory_usage("Path",
939  pool_elts(fib_path_pool),
940  pool_len(fib_path_pool),
941  sizeof(fib_path_t));
942 }
943 
944 /*
945  * The FIB path's graph node virtual function table
946  */
947 static const fib_node_vft_t fib_path_vft = {
949  .fnv_last_lock = fib_path_last_lock_gone,
950  .fnv_back_walk = fib_path_back_walk_notify,
951  .fnv_mem_show = fib_path_memory_show,
952 };
953 
956 {
958 
960  cfg_flags |= FIB_PATH_CFG_FLAG_RESOLVE_HOST;
963 
964  return (cfg_flags);
965 }
966 
967 /*
968  * fib_path_create
969  *
970  * Create and initialise a new path object.
971  * return the index of the path.
972  */
975  fib_protocol_t nh_proto,
977  const fib_route_path_t *rpath)
978 {
979  fib_path_t *path;
980 
981  pool_get(fib_path_pool, path);
982  memset(path, 0, sizeof(*path));
983 
984  fib_node_init(&path->fp_node,
986 
987  dpo_reset(&path->fp_dpo);
988  path->fp_pl_index = pl_index;
989  path->fp_nh_proto = nh_proto;
991  path->fp_weight = rpath->frp_weight;
992  if (0 == path->fp_weight)
993  {
994  /*
995  * a weight of 0 is a meaningless value. We could either reject it, and thus force
996  * clients to always use 1, or we can accept it and fixup approrpiately.
997  */
998  path->fp_weight = 1;
999  }
1000  path->fp_cfg_flags = flags;
1002 
1003  /*
1004  * deduce the path's tpye from the parementers and save what is needed.
1005  */
1006  if (~0 != rpath->frp_sw_if_index)
1007  {
1008  if (flags & FIB_PATH_CFG_FLAG_LOCAL)
1009  {
1011  path->receive.fp_interface = rpath->frp_sw_if_index;
1012  path->receive.fp_addr = rpath->frp_addr;
1013  }
1014  else
1015  {
1016  if (ip46_address_is_zero(&rpath->frp_addr))
1017  {
1019  path->attached.fp_interface = rpath->frp_sw_if_index;
1020  }
1021  else
1022  {
1024  path->attached_next_hop.fp_interface = rpath->frp_sw_if_index;
1025  path->attached_next_hop.fp_nh = rpath->frp_addr;
1026  }
1027  }
1028  }
1029  else
1030  {
1031  if (ip46_address_is_zero(&rpath->frp_addr))
1032  {
1033  if (~0 == rpath->frp_fib_index)
1034  {
1036  }
1037  else
1038  {
1039  path->fp_type = FIB_PATH_TYPE_DEAG;
1040  path->deag.fp_tbl_id = rpath->frp_fib_index;
1041  }
1042  }
1043  else
1044  {
1046  if (FIB_PROTOCOL_MPLS == path->fp_nh_proto)
1047  {
1048  path->recursive.fp_nh.fp_local_label = rpath->frp_local_label;
1049  }
1050  else
1051  {
1052  path->recursive.fp_nh.fp_ip = rpath->frp_addr;
1053  }
1054  path->recursive.fp_tbl_id = rpath->frp_fib_index;
1055  }
1056  }
1057 
1058  FIB_PATH_DBG(path, "create");
1059 
1060  return (fib_path_get_index(path));
1061 }
1062 
1063 /*
1064  * fib_path_create_special
1065  *
1066  * Create and initialise a new path object.
1067  * return the index of the path.
1068  */
1071  fib_protocol_t nh_proto,
1073  const dpo_id_t *dpo)
1074 {
1075  fib_path_t *path;
1076 
1077  pool_get(fib_path_pool, path);
1078  memset(path, 0, sizeof(*path));
1079 
1080  fib_node_init(&path->fp_node,
1082  dpo_reset(&path->fp_dpo);
1083 
1084  path->fp_pl_index = pl_index;
1085  path->fp_weight = 1;
1086  path->fp_nh_proto = nh_proto;
1088  path->fp_cfg_flags = flags;
1089 
1090  if (FIB_PATH_CFG_FLAG_DROP & flags)
1091  {
1093  }
1094  else if (FIB_PATH_CFG_FLAG_LOCAL & flags)
1095  {
1097  path->attached.fp_interface = FIB_NODE_INDEX_INVALID;
1098  }
1099  else
1100  {
1102  ASSERT(NULL != dpo);
1103  dpo_copy(&path->exclusive.fp_ex_dpo, dpo);
1104  }
1105 
1106  return (fib_path_get_index(path));
1107 }
1108 
1109 /*
1110  * fib_path_copy
1111  *
1112  * Copy a path. return index of new path.
1113  */
1116  fib_node_index_t path_list_index)
1117 {
1118  fib_path_t *path, *orig_path;
1119 
1120  pool_get(fib_path_pool, path);
1121 
1122  orig_path = fib_path_get(path_index);
1123  ASSERT(NULL != orig_path);
1124 
1125  memcpy(path, orig_path, sizeof(*path));
1126 
1127  FIB_PATH_DBG(path, "create-copy:%d", path_index);
1128 
1129  /*
1130  * reset the dynamic section
1131  */
1134  path->fp_pl_index = path_list_index;
1136  memset(&path->fp_dpo, 0, sizeof(path->fp_dpo));
1137  dpo_reset(&path->fp_dpo);
1138 
1139  return (fib_path_get_index(path));
1140 }
1141 
1142 /*
1143  * fib_path_destroy
1144  *
1145  * destroy a path that is no longer required
1146  */
1147 void
1149 {
1150  fib_path_t *path;
1151 
1152  path = fib_path_get(path_index);
1153 
1154  ASSERT(NULL != path);
1155  FIB_PATH_DBG(path, "destroy");
1156 
1157  fib_path_unresolve(path);
1158 
1159  fib_node_deinit(&path->fp_node);
1160  pool_put(fib_path_pool, path);
1161 }
1162 
1163 /*
1164  * fib_path_destroy
1165  *
1166  * destroy a path that is no longer required
1167  */
1168 uword
1170 {
1171  fib_path_t *path;
1172 
1173  path = fib_path_get(path_index);
1174 
1175  return (hash_memory(STRUCT_MARK_PTR(path, path_hash_start),
1176  (STRUCT_OFFSET_OF(fib_path_t, path_hash_end) -
1177  STRUCT_OFFSET_OF(fib_path_t, path_hash_start)),
1178  0));
1179 }
1180 
1181 /*
1182  * fib_path_cmp_i
1183  *
1184  * Compare two paths for equivalence.
1185  */
1186 static int
1188  const fib_path_t *path2)
1189 {
1190  int res;
1191 
1192  res = 1;
1193 
1194  /*
1195  * paths of different types and protocol are not equal.
1196  * different weights only are the same path.
1197  */
1198  if (path1->fp_type != path2->fp_type)
1199  {
1200  res = (path1->fp_type - path2->fp_type);
1201  }
1202  if (path1->fp_nh_proto != path2->fp_nh_proto)
1203  {
1204  res = (path1->fp_nh_proto - path2->fp_nh_proto);
1205  }
1206  else
1207  {
1208  /*
1209  * both paths are of the same type.
1210  * consider each type and its attributes in turn.
1211  */
1212  switch (path1->fp_type)
1213  {
1215  res = ip46_address_cmp(&path1->attached_next_hop.fp_nh,
1216  &path2->attached_next_hop.fp_nh);
1217  if (0 == res) {
1219  vnet_get_main(),
1220  path1->attached_next_hop.fp_interface,
1221  path2->attached_next_hop.fp_interface);
1222  }
1223  break;
1226  vnet_get_main(),
1227  path1->attached.fp_interface,
1228  path2->attached.fp_interface);
1229  break;
1231  res = ip46_address_cmp(&path1->recursive.fp_nh,
1232  &path2->recursive.fp_nh);
1233 
1234  if (0 == res)
1235  {
1236  res = (path1->recursive.fp_tbl_id - path2->recursive.fp_tbl_id);
1237  }
1238  break;
1239  case FIB_PATH_TYPE_DEAG:
1240  res = (path1->deag.fp_tbl_id - path2->deag.fp_tbl_id);
1241  break;
1242  case FIB_PATH_TYPE_SPECIAL:
1243  case FIB_PATH_TYPE_RECEIVE:
1245  res = 0;
1246  break;
1247  }
1248  }
1249  return (res);
1250 }
1251 
1252 /*
1253  * fib_path_cmp_for_sort
1254  *
1255  * Compare two paths for equivalence. Used during path sorting.
1256  * As usual 0 means equal.
1257  */
1258 int
1260  void * v2)
1261 {
1262  fib_node_index_t *pi1 = v1, *pi2 = v2;
1263  fib_path_t *path1, *path2;
1264 
1265  path1 = fib_path_get(*pi1);
1266  path2 = fib_path_get(*pi2);
1267 
1268  return (fib_path_cmp_i(path1, path2));
1269 }
1270 
1271 /*
1272  * fib_path_cmp
1273  *
1274  * Compare two paths for equivalence.
1275  */
1276 int
1278  fib_node_index_t pi2)
1279 {
1280  fib_path_t *path1, *path2;
1281 
1282  path1 = fib_path_get(pi1);
1283  path2 = fib_path_get(pi2);
1284 
1285  return (fib_path_cmp_i(path1, path2));
1286 }
1287 
1288 int
1290  const fib_route_path_t *rpath)
1291 {
1292  fib_path_t *path;
1293  int res;
1294 
1295  path = fib_path_get(path_index);
1296 
1297  res = 1;
1298 
1299  if (path->fp_weight != rpath->frp_weight)
1300  {
1301  res = (path->fp_weight - rpath->frp_weight);
1302  }
1303  else
1304  {
1305  /*
1306  * both paths are of the same type.
1307  * consider each type and its attributes in turn.
1308  */
1309  switch (path->fp_type)
1310  {
1312  res = ip46_address_cmp(&path->attached_next_hop.fp_nh,
1313  &rpath->frp_addr);
1314  if (0 == res)
1315  {
1317  vnet_get_main(),
1318  path->attached_next_hop.fp_interface,
1319  rpath->frp_sw_if_index);
1320  }
1321  break;
1324  vnet_get_main(),
1325  path->attached.fp_interface,
1326  rpath->frp_sw_if_index);
1327  break;
1329  if (FIB_PROTOCOL_MPLS == path->fp_nh_proto)
1330  {
1331  res = path->recursive.fp_nh.fp_local_label - rpath->frp_local_label;
1332  }
1333  else
1334  {
1335  res = ip46_address_cmp(&path->recursive.fp_nh.fp_ip,
1336  &rpath->frp_addr);
1337  }
1338 
1339  if (0 == res)
1340  {
1341  res = (path->recursive.fp_tbl_id - rpath->frp_fib_index);
1342  }
1343  break;
1344  case FIB_PATH_TYPE_DEAG:
1345  res = (path->deag.fp_tbl_id - rpath->frp_fib_index);
1346  break;
1347  case FIB_PATH_TYPE_SPECIAL:
1348  case FIB_PATH_TYPE_RECEIVE:
1350  res = 0;
1351  break;
1352  }
1353  }
1354  return (res);
1355 }
1356 
1357 /*
1358  * fib_path_recursive_loop_detect
1359  *
1360  * A forward walk of the FIB object graph to detect for a cycle/loop. This
1361  * walk is initiated when an entry is linking to a new path list or from an old.
1362  * The entry vector passed contains all the FIB entrys that are children of this
1363  * path (it is all the entries encountered on the walk so far). If this vector
1364  * contains the entry this path resolve via, then a loop is about to form.
1365  * The loop must be allowed to form, since we need the dependencies in place
1366  * so that we can track when the loop breaks.
1367  * However, we MUST not produce a loop in the forwarding graph (else packets
1368  * would loop around the switch path until the loop breaks), so we mark recursive
1369  * paths as looped so that they do not contribute forwarding information.
1370  * By marking the path as looped, an etry such as;
1371  * X/Y
1372  * via a.a.a.a (looped)
1373  * via b.b.b.b (not looped)
1374  * can still forward using the info provided by b.b.b.b only
1375  */
1376 int
1378  fib_node_index_t **entry_indicies)
1379 {
1380  fib_path_t *path;
1381 
1382  path = fib_path_get(path_index);
1383 
1384  /*
1385  * the forced drop path is never looped, cos it is never resolved.
1386  */
1387  if (fib_path_is_permanent_drop(path))
1388  {
1389  return (0);
1390  }
1391 
1392  switch (path->fp_type)
1393  {
1395  {
1396  fib_node_index_t *entry_index, *entries;
1397  int looped = 0;
1398  entries = *entry_indicies;
1399 
1400  vec_foreach(entry_index, entries) {
1401  if (*entry_index == path->fp_via_fib)
1402  {
1403  /*
1404  * the entry that is about to link to this path-list (or
1405  * one of this path-list's children) is the same entry that
1406  * this recursive path resolves through. this is a cycle.
1407  * abort the walk.
1408  */
1409  looped = 1;
1410  break;
1411  }
1412  }
1413 
1414  if (looped)
1415  {
1416  FIB_PATH_DBG(path, "recursive loop formed");
1418 
1419  dpo_copy(&path->fp_dpo,
1421  }
1422  else
1423  {
1424  /*
1425  * no loop here yet. keep forward walking the graph.
1426  */
1427  if (fib_entry_recursive_loop_detect(path->fp_via_fib, entry_indicies))
1428  {
1429  FIB_PATH_DBG(path, "recursive loop formed");
1431  }
1432  else
1433  {
1434  FIB_PATH_DBG(path, "recursive loop cleared");
1436  }
1437  }
1438  break;
1439  }
1442  case FIB_PATH_TYPE_SPECIAL:
1443  case FIB_PATH_TYPE_DEAG:
1444  case FIB_PATH_TYPE_RECEIVE:
1446  /*
1447  * these path types cannot be part of a loop, since they are the leaves
1448  * of the graph.
1449  */
1450  break;
1451  }
1452 
1453  return (fib_path_is_looped(path_index));
1454 }
1455 
1456 int
1458 {
1459  fib_path_t *path;
1460 
1461  path = fib_path_get(path_index);
1462 
1463  /*
1464  * hope for the best.
1465  */
1467 
1468  /*
1469  * the forced drop path resolves via the drop adj
1470  */
1471  if (fib_path_is_permanent_drop(path))
1472  {
1473  dpo_copy(&path->fp_dpo,
1476  return (fib_path_is_resolved(path_index));
1477  }
1478 
1479  switch (path->fp_type)
1480  {
1483  break;
1485  /*
1486  * path->attached.fp_interface
1487  */
1489  path->attached.fp_interface))
1490  {
1492  }
1494  path->attached.fp_interface))
1495  {
1496  /*
1497  * point-2-point interfaces do not require a glean, since
1498  * there is nothing to ARP. Install a rewrite/nbr adj instead
1499  */
1500  dpo_set(&path->fp_dpo,
1501  DPO_ADJACENCY,
1504  path->fp_nh_proto,
1506  &zero_addr,
1507  path->attached.fp_interface));
1508  }
1509  else
1510  {
1511  dpo_set(&path->fp_dpo,
1515  path->attached.fp_interface,
1516  NULL));
1517  }
1518  /*
1519  * become a child of the adjacency so we receive updates
1520  * when the interface state changes
1521  */
1522  path->fp_sibling = adj_child_add(path->fp_dpo.dpoi_index,
1524  fib_path_get_index(path));
1525 
1526  break;
1528  {
1529  /*
1530  * Create a RR source entry in the table for the address
1531  * that this path recurses through.
1532  * This resolve action is recursive, hence we may create
1533  * more paths in the process. more creates mean maybe realloc
1534  * of this path.
1535  */
1536  fib_node_index_t fei;
1537  fib_prefix_t pfx;
1538 
1540 
1541  if (FIB_PROTOCOL_MPLS == path->fp_nh_proto)
1542  {
1543  fib_prefix_from_mpls_label(path->recursive.fp_nh.fp_local_label, &pfx);
1544  }
1545  else
1546  {
1547  fib_prefix_from_ip46_addr(&path->recursive.fp_nh.fp_ip, &pfx);
1548  }
1549 
1550  fei = fib_table_entry_special_add(path->recursive.fp_tbl_id,
1551  &pfx,
1552  FIB_SOURCE_RR,
1555 
1556  path = fib_path_get(path_index);
1557  path->fp_via_fib = fei;
1558 
1559  /*
1560  * become a dependent child of the entry so the path is
1561  * informed when the forwarding for the entry changes.
1562  */
1565  fib_path_get_index(path));
1566 
1567  /*
1568  * create and configure the IP DPO
1569  */
1571  path,
1573  &path->fp_dpo);
1574 
1575  break;
1576  }
1577  case FIB_PATH_TYPE_SPECIAL:
1578  /*
1579  * Resolve via the drop
1580  */
1581  dpo_copy(&path->fp_dpo,
1583  break;
1584  case FIB_PATH_TYPE_DEAG:
1585  /*
1586  * Resolve via a lookup DPO.
1587  * FIXME. control plane should add routes with a table ID
1588  */
1589  lookup_dpo_add_or_lock_w_fib_index(path->deag.fp_tbl_id,
1593  &path->fp_dpo);
1594  break;
1595  case FIB_PATH_TYPE_RECEIVE:
1596  /*
1597  * Resolve via a receive DPO.
1598  */
1600  path->receive.fp_interface,
1601  &path->receive.fp_addr,
1602  &path->fp_dpo);
1603  break;
1605  /*
1606  * Resolve via the user provided DPO
1607  */
1608  dpo_copy(&path->fp_dpo, &path->exclusive.fp_ex_dpo);
1609  break;
1610  }
1611 
1612  return (fib_path_is_resolved(path_index));
1613 }
1614 
1615 u32
1617 {
1618  fib_path_t *path;
1619 
1620  path = fib_path_get(path_index);
1621 
1622  switch (path->fp_type)
1623  {
1625  return (path->attached_next_hop.fp_interface);
1627  return (path->attached.fp_interface);
1628  case FIB_PATH_TYPE_RECEIVE:
1629  return (path->receive.fp_interface);
1632  case FIB_PATH_TYPE_SPECIAL:
1633  case FIB_PATH_TYPE_DEAG:
1635  break;
1636  }
1637  return (~0);
1638 }
1639 
1642 {
1643  fib_path_t *path;
1644 
1645  path = fib_path_get(path_index);
1646 
1647  ASSERT(dpo_is_adj(&path->fp_dpo));
1648  if (dpo_is_adj(&path->fp_dpo))
1649  {
1650  return (path->fp_dpo.dpoi_index);
1651  }
1652  return (ADJ_INDEX_INVALID);
1653 }
1654 
1655 int
1657 {
1658  fib_path_t *path;
1659 
1660  path = fib_path_get(path_index);
1661 
1662  ASSERT(path);
1663 
1664  return (path->fp_weight);
1665 }
1666 
1667 /**
1668  * @brief Contribute the path's adjacency to the list passed.
1669  * By calling this function over all paths, recursively, a child
1670  * can construct its full set of forwarding adjacencies, and hence its
1671  * uRPF list.
1672  */
1673 void
1675  index_t urpf)
1676 {
1677  fib_path_t *path;
1678 
1679  if (!fib_path_is_resolved(path_index))
1680  return;
1681 
1682  path = fib_path_get(path_index);
1683 
1684  switch (path->fp_type)
1685  {
1687  fib_urpf_list_append(urpf, path->attached_next_hop.fp_interface);
1688  break;
1689 
1691  fib_urpf_list_append(urpf, path->attached.fp_interface);
1692  break;
1693 
1696  break;
1697 
1699  case FIB_PATH_TYPE_SPECIAL:
1700  /*
1701  * these path types may link to an adj, if that's what
1702  * the clinet gave
1703  */
1704  if (dpo_is_adj(&path->fp_dpo))
1705  {
1706  ip_adjacency_t *adj;
1707 
1708  adj = adj_get(path->fp_dpo.dpoi_index);
1709 
1710  fib_urpf_list_append(urpf, adj->rewrite_header.sw_if_index);
1711  }
1712  break;
1713 
1714  case FIB_PATH_TYPE_DEAG:
1715  case FIB_PATH_TYPE_RECEIVE:
1716  /*
1717  * these path types don't link to an adj
1718  */
1719  break;
1720  }
1721 }
1722 
1723 void
1726  dpo_id_t *dpo)
1727 {
1728  fib_path_t *path;
1729 
1730  path = fib_path_get(path_index);
1731 
1732  ASSERT(path);
1734 
1735  FIB_PATH_DBG(path, "contribute");
1736 
1737  /*
1738  * The DPO stored in the path was created when the path was resolved.
1739  * This then represents the path's 'native' protocol; IP.
1740  * For all others will need to go find something else.
1741  */
1742  if (fib_path_proto_to_chain_type(path->fp_nh_proto) == fct)
1743  {
1744  dpo_copy(dpo, &path->fp_dpo);
1745  }
1746  else
1747  {
1748  switch (path->fp_type)
1749  {
1751  switch (fct)
1752  {
1758  {
1759  adj_index_t ai;
1760 
1761  /*
1762  * get a appropriate link type adj.
1763  */
1765  path,
1767  dpo_set(dpo, DPO_ADJACENCY,
1769  adj_unlock(ai);
1770 
1771  break;
1772  }
1773  }
1774  break;
1776  switch (fct)
1777  {
1782  fib_path_recursive_adj_update(path, fct, dpo);
1783  break;
1785  ASSERT(0);
1786  break;
1787  }
1788  break;
1789  case FIB_PATH_TYPE_DEAG:
1790  switch (fct)
1791  {
1797  dpo);
1798  break;
1802  dpo_copy(dpo, &path->fp_dpo);
1803  break;
1805  ASSERT(0);
1806  break;
1807  }
1808  break;
1810  dpo_copy(dpo, &path->exclusive.fp_ex_dpo);
1811  break;
1813  case FIB_PATH_TYPE_RECEIVE:
1814  case FIB_PATH_TYPE_SPECIAL:
1815  ASSERT(0);
1816  break;
1817  }
1818 
1819  }
1820 }
1821 
1825  load_balance_path_t *hash_key)
1826 {
1827  load_balance_path_t *mnh;
1828  fib_path_t *path;
1829 
1830  path = fib_path_get(path_index);
1831 
1832  ASSERT(path);
1833 
1834  if (fib_path_is_resolved(path_index))
1835  {
1836  vec_add2(hash_key, mnh, 1);
1837 
1838  mnh->path_weight = path->fp_weight;
1839  mnh->path_index = path_index;
1840  fib_path_contribute_forwarding(path_index, fct, &mnh->path_dpo);
1841  }
1842 
1843  return (hash_key);
1844 }
1845 
1846 int
1848 {
1849  fib_path_t *path;
1850 
1851  path = fib_path_get(path_index);
1852 
1853  return (FIB_PATH_TYPE_RECURSIVE == path->fp_type);
1854 }
1855 
1856 int
1858 {
1859  fib_path_t *path;
1860 
1861  path = fib_path_get(path_index);
1862 
1863  return (FIB_PATH_TYPE_EXCLUSIVE == path->fp_type);
1864 }
1865 
1866 int
1868 {
1869  fib_path_t *path;
1870 
1871  path = fib_path_get(path_index);
1872 
1873  return (FIB_PATH_TYPE_DEAG == path->fp_type);
1874 }
1875 
1876 int
1878 {
1879  fib_path_t *path;
1880 
1881  path = fib_path_get(path_index);
1882 
1883  return (dpo_id_is_valid(&path->fp_dpo) &&
1885  !fib_path_is_looped(path_index) &&
1887 }
1888 
1889 int
1891 {
1892  fib_path_t *path;
1893 
1894  path = fib_path_get(path_index);
1895 
1897 }
1898 
1899 int
1901  fib_node_index_t path_index,
1902  void *ctx)
1903 {
1904  fib_route_path_encode_t **api_rpaths = ctx;
1905  fib_route_path_encode_t *api_rpath;
1906  fib_path_t *path;
1907 
1908  path = fib_path_get(path_index);
1909  if (!path)
1910  return (0);
1911  vec_add2(*api_rpaths, api_rpath, 1);
1912  api_rpath->rpath.frp_weight = path->fp_weight;
1913  api_rpath->rpath.frp_proto = path->fp_nh_proto;
1914  api_rpath->rpath.frp_sw_if_index = ~0;
1915  api_rpath->dpo = path->exclusive.fp_ex_dpo;
1916  switch (path->fp_type)
1917  {
1918  case FIB_PATH_TYPE_RECEIVE:
1919  api_rpath->rpath.frp_addr = path->receive.fp_addr;
1920  api_rpath->rpath.frp_sw_if_index = path->receive.fp_interface;
1921  break;
1923  api_rpath->rpath.frp_sw_if_index = path->attached.fp_interface;
1924  break;
1926  api_rpath->rpath.frp_sw_if_index = path->attached_next_hop.fp_interface;
1927  api_rpath->rpath.frp_addr = path->attached_next_hop.fp_nh;
1928  break;
1929  case FIB_PATH_TYPE_SPECIAL:
1930  break;
1931  case FIB_PATH_TYPE_DEAG:
1932  break;
1934  api_rpath->rpath.frp_addr = path->recursive.fp_nh.fp_ip;
1935  break;
1936  default:
1937  break;
1938  }
1939  return (1);
1940 }
1941 
1944 {
1945  fib_path_t *path;
1946 
1947  path = fib_path_get(path_index);
1948 
1949  return (path->fp_nh_proto);
1950 }
1951 
1952 void
1954 {
1955  fib_node_register_type (FIB_NODE_TYPE_PATH, &fib_path_vft);
1956 }
1957 
1958 static clib_error_t *
1960  unformat_input_t * input,
1961  vlib_cli_command_t * cmd)
1962 {
1963  fib_node_index_t pi;
1964  fib_path_t *path;
1965 
1966  if (unformat (input, "%d", &pi))
1967  {
1968  /*
1969  * show one in detail
1970  */
1971  if (!pool_is_free_index(fib_path_pool, pi))
1972  {
1973  path = fib_path_get(pi);
1974  u8 *s = fib_path_format(pi, NULL);
1975  s = format(s, "children:");
1977  vlib_cli_output (vm, "%s", s);
1978  vec_free(s);
1979  }
1980  else
1981  {
1982  vlib_cli_output (vm, "path %d invalid", pi);
1983  }
1984  }
1985  else
1986  {
1987  vlib_cli_output (vm, "FIB Paths");
1988  pool_foreach(path, fib_path_pool,
1989  ({
1990  vlib_cli_output (vm, "%U", format_fib_path, path);
1991  }));
1992  }
1993 
1994  return (NULL);
1995 }
1996 
1997 VLIB_CLI_COMMAND (show_fib_path, static) = {
1998  .path = "show fib paths",
1999  .function = show_fib_path_command,
2000  .short_help = "show fib paths",
2001 };
format_function_t format_ip46_address
Definition: format.h:61
int fib_path_is_resolved(fib_node_index_t path_index)
Definition: fib_path.c:1877
fib_protocol_t frp_proto
The protocol of the address below.
Definition: fib_types.h:290
int fib_path_resolve(fib_node_index_t path_index)
Definition: fib_path.c:1457
ip46_address_t frp_addr
The next-hop address.
Definition: fib_types.h:299
Recursive resolution source.
Definition: fib_entry.h:105
Contribute an object that is to be used to forward IP6 packets.
Definition: fib_types.h:85
void receive_dpo_add_or_lock(dpo_proto_t proto, u32 sw_if_index, const ip46_address_t *nh_addr, dpo_id_t *dpo)
Definition: receive_dpo.c:56
static fib_path_t * fib_path_from_fib_node(fib_node_t *node)
Definition: fib_path.c:348
uword fib_path_hash(fib_node_index_t path_index)
Definition: fib_path.c:1169
fib_node_index_t path_index
The index of the FIB path.
Definition: load_balance.h:70
A representation of a fib path for fib_path_encode to convey the information to the caller...
Definition: fib_types.h:335
void fib_path_contribute_forwarding(fib_node_index_t path_index, fib_forward_chain_type_t fct, dpo_id_t *dpo)
Definition: fib_path.c:1724
uword unformat(unformat_input_t *i, char *fmt,...)
Definition: unformat.c:966
fib_protocol_t fib_path_get_proto(fib_node_index_t path_index)
Definition: fib_path.c:1943
fib_path_oper_attribute_t_
Enurmeration of path operational (i.e.
Definition: fib_path.c:98
struct fib_path_t_::@134::@137 attached
void fib_path_contribute_urpf(fib_node_index_t path_index, index_t urpf)
Contribute the path&#39;s adjacency to the list passed.
Definition: fib_path.c:1674
A representation of a path as described by a route producer.
Definition: fib_types.h:285
u8 * format_dpo_type(u8 *s, va_list *args)
format a DPO type
Definition: dpo.c:108
dpo_id_t path_dpo
ID of the Data-path object.
Definition: load_balance.h:65
int dpo_is_adj(const dpo_id_t *dpo)
Return TRUE is the DPO is any type of adjacency.
Definition: dpo.c:237
adj_index_t adj_glean_add_or_lock(fib_protocol_t proto, u32 sw_if_index, const ip46_address_t *nh_addr)
Glean Adjacency.
Definition: adj_glean.c:50
#define FIB_PATH_OPER_ATTRIBUTES
Definition: fib_path.c:126
#define STRUCT_MARK_PTR(v, f)
Definition: clib.h:68
int fib_path_cmp(fib_node_index_t pi1, fib_node_index_t pi2)
Definition: fib_path.c:1277
void fib_node_init(fib_node_t *node, fib_node_type_t type)
Definition: fib_node.c:183
void lookup_dpo_add_or_lock_w_table_id(u32 table_id, dpo_proto_t proto, lookup_input_t input, lookup_table_t table_config, dpo_id_t *dpo)
Definition: lookup_dpo.c:130
u32 fib_entry_child_add(fib_node_index_t fib_entry_index, fib_node_type_t child_type, fib_node_index_t child_index)
Definition: fib_entry.c:472
static int dpo_id_is_valid(const dpo_id_t *dpoi)
Return true if the DPO object is valid, i.e.
Definition: dpo.h:177
void fib_entry_get_prefix(fib_node_index_t fib_entry_index, fib_prefix_t *pfx)
Definition: fib_entry.c:1433
#define NULL
Definition: clib.h:55
IP unicast adjacency.
Definition: lookup.h:188
void fib_path_module_init(void)
Definition: fib_path.c:1953
int fib_path_is_exclusive(fib_node_index_t path_index)
Definition: fib_path.c:1857
enum fib_node_back_walk_rc_t_ fib_node_back_walk_rc_t
Return code from a back walk function.
void fib_entry_contribute_forwarding(fib_node_index_t fib_entry_index, fib_forward_chain_type_t fct, dpo_id_t *dpo)
Definition: fib_entry.c:391
u32 mpls_label_t
A label value only, i.e.
Definition: packet.h:24
dpo_proto_t fib_forw_chain_type_to_dpo_proto(fib_forward_chain_type_t fct)
Convert from a chain type to the DPO proto it will install.
Definition: fib_types.c:311
void load_balance_map_path_state_change(fib_node_index_t path_index)
the state of a path has changed (it has no doubt gone down).
void fib_entry_child_remove(fib_node_index_t fib_entry_index, u32 sibling_index)
Definition: fib_entry.c:483
fib_node_index_t fp_tbl_id
The FIB table index in which to find the next-hop.
Definition: fib_path.c:243
void dpo_copy(dpo_id_t *dst, const dpo_id_t *src)
atomic copy a data-plane object.
Definition: dpo.c:221
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
word vnet_sw_interface_compare(vnet_main_t *vnm, uword sw_if_index0, uword sw_if_index1)
Definition: interface.c:1109
void lookup_dpo_add_or_lock_w_fib_index(fib_node_index_t fib_index, dpo_proto_t proto, lookup_input_t input, lookup_table_t table_config, dpo_id_t *dpo)
Definition: lookup_dpo.c:116
struct fib_path_t_::@134::@136 attached_next_hop
#define vec_add2(V, P, N)
Add N elements to end of vector V, return pointer to new elements in P.
Definition: vec.h:521
The path is resolved.
Definition: fib_path.c:110
Contribute an object that is to be used to forward IP4 packets.
Definition: fib_types.h:81
#define STRUCT_OFFSET_OF(t, f)
Definition: clib.h:62
void fib_node_deinit(fib_node_t *node)
Definition: fib_node.c:198
static vnet_sw_interface_t * vnet_get_sw_interface(vnet_main_t *vnm, u32 sw_if_index)
u8 * fib_path_adj_format(fib_node_index_t pi, u32 indent, u8 *s)
Definition: fib_path.c:486
dpo_id_t fp_ex_dpo
The user provided &#39;exclusive&#39; DPO.
Definition: fib_path.c:257
int fib_path_is_looped(fib_node_index_t path_index)
Definition: fib_path.c:1890
Definition: fib_entry.h:218
void adj_child_remove(adj_index_t adj_index, u32 sibling_index)
Remove a child dependent.
Definition: adj.c:245
#define pool_get(P, E)
Allocate an object E from a pool P (unspecified alignment).
Definition: pool.h:200
The path has become a permanent drop.
Definition: fib_path.c:114
int fib_path_cmp_for_sort(void *v1, void *v2)
Definition: fib_path.c:1259
#define ip46_address_cmp(ip46_1, ip46_2)
Definition: ip6_packet.h:80
#define pool_len(p)
Number of elements in pool vector.
Definition: pool.h:121
ip46_address_t fp_ip
The next-hop.
Definition: fib_path.c:215
enum fib_protocol_t_ fib_protocol_t
Protocol Type.
load_balance_path_t * fib_path_append_nh_for_multipath_hash(fib_node_index_t path_index, fib_forward_chain_type_t fct, load_balance_path_t *hash_key)
Definition: fib_path.c:1823
void fib_node_register_type(fib_node_type_t type, const fib_node_vft_t *vft)
fib_node_register_type
Definition: fib_node.c:58
const dpo_id_t * drop_dpo_get(dpo_proto_t proto)
Definition: drop_dpo.c:25
#define FIB_PATH_TYPES
Definition: fib_path.c:82
vnet_main_t * vnet_get_main(void)
Definition: misc.c:46
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
fib_node_index_t fib_path_create(fib_node_index_t pl_index, fib_protocol_t nh_proto, fib_path_cfg_flags_t flags, const fib_route_path_t *rpath)
Definition: fib_path.c:974
fib_path_type_t fp_type
The type of the path.
Definition: fib_path.c:175
#define pool_foreach(VAR, POOL, BODY)
Iterate through pool.
Definition: pool.h:348
u32 frp_sw_if_index
The interface.
Definition: fib_types.h:311
void fib_table_entry_special_remove(u32 fib_index, const fib_prefix_t *prefix, fib_source_t source)
Remove a &#39;special&#39; entry from the FIB.
Definition: fib_table.c:399
static const adj_index_t fib_path_attached_next_hop_get_adj(fib_path_t *path, vnet_link_t link)
Definition: fib_path.c:521
Recursion constraint of via a host prefix.
Definition: fib_types.h:261
fib_node_index_t fib_path_create_special(fib_node_index_t pl_index, fib_protocol_t nh_proto, fib_path_cfg_flags_t flags, const dpo_id_t *dpo)
Definition: fib_path.c:1070
fib_node_index_t fib_path_copy(fib_node_index_t path_index, fib_node_index_t path_list_index)
Definition: fib_path.c:1115
struct fib_path_t_::@134::@141 exclusive
Aggregrate type for a prefix.
Definition: fib_types.h:145
fib_path_cfg_flags_t fp_cfg_flags
Configuration Flags.
Definition: fib_path.c:170
void fib_entry_contribute_urpf(fib_node_index_t entry_index, index_t urpf)
Contribute the set of Adjacencies that this entry forwards with to build the uRPF list of its childre...
Definition: fib_entry.c:375
void fib_show_memory_usage(const char *name, u32 in_use_elts, u32 allocd_elts, size_t size_elt)
Show the memory usage for a type.
Definition: fib_node.c:221
fib_node_t fp_node
A path is a node in the FIB graph.
Definition: fib_path.c:154
void adj_unlock(adj_index_t adj_index)
Release a reference counting lock on the adjacency.
Definition: adj.c:209
dpo_id_t fp_dpo
The Data-path objects through which this path resolves for IP.
Definition: fib_path.c:292
#define FIB_PATH_CFG_ATTRIBUTES
Definition: fib_path.h:80
Contribute an object that is to be used to forward Ethernet packets.
Definition: fib_types.h:103
void fib_urpf_list_append(index_t ui, u32 sw_if_index)
Append another interface to the list.
Definition: fib_urpf_list.c:92
void fib_prefix_from_mpls_label(mpls_label_t label, fib_prefix_t *prf)
Big train switch; FIB debugs on or off.
Definition: fib_types.c:68
static void fib_path_attached_next_hop_set(fib_path_t *path)
Definition: fib_path.c:548
Definition: fib_entry.h:216
u8 * format_fib_path(u8 *s, va_list *args)
Definition: fib_path.c:357
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
u32 fp_sibling
the index of this path in the parent&#39;s child list.
Definition: fib_path.c:297
Contribute an object that is to be used to forward end-of-stack MPLS packets.
Definition: fib_types.h:97
fib_node_bw_reason_flag_t fnbw_reason
The reason/trigger for the backwalk.
Definition: fib_node.h:190
format_function_t format_vnet_sw_interface_name
#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
#define pool_elt_at_index(p, i)
Returns pointer to element at given index.
Definition: pool.h:369
fib_node_index_t fib_table_entry_special_add(u32 fib_index, const fib_prefix_t *prefix, fib_source_t source, fib_entry_flag_t flags, adj_index_t adj_index)
Add a &#39;special&#39; entry to the FIB that links to the adj passed A special entry is an entry that the FI...
Definition: fib_table.c:369
struct fib_path_t_ fib_path_t
A FIB path.
dpo_type_t dpoi_type
the type
Definition: dpo.h:142
int vnet_sw_interface_is_p2p(vnet_main_t *vnm, u32 sw_if_index)
Definition: interface.c:1135
fib_protocol_t fp_nh_proto
The protocol of the next-hop, i.e.
Definition: fib_path.c:182
STRUCT_MARK(path_hash_start)
This marks the start of the memory area used to hash the path.
adj_index_t fib_path_get_adj(fib_node_index_t path_index)
Definition: fib_path.c:1641
#define pool_put(P, E)
Free an object E in pool P.
Definition: pool.h:214
Recursion constraint of via an attahced prefix.
Definition: fib_types.h:265
u32 fp_weight
UCMP [unnormalised] weigt.
Definition: fib_path.c:187
fib_node_type_t fn_type
The node&#39;s type.
Definition: fib_node.h:278
enum fib_path_cfg_attribute_t_ fib_path_cfg_attribute_t
Given a route of the form; q.r.s.t/Y via <interface> <next-hop>
An node in the FIB graph.
Definition: fib_node.h:273
void vlib_cli_output(vlib_main_t *vm, char *fmt,...)
Definition: cli.c:576
static fib_path_t * fib_path_pool
Definition: fib_path.c:310
static fib_path_t * fib_path_get(fib_node_index_t index)
Definition: fib_path.c:330
ip46_address_t fp_nh
The next-hop.
Definition: fib_path.c:197
u32 fib_entry_get_resolving_interface(fib_node_index_t entry_index)
Definition: fib_entry.c:1301
fib_path_oper_flags_t_
Path flags from the attributes.
Definition: fib_path.c:140
#define FOR_EACH_FIB_PATH_OPER_ATTRIBUTE(_item)
Definition: fib_path.c:132
The path forms part of a recursive loop.
Definition: fib_path.c:106
vnet_link_t fib_forw_chain_type_to_link_type(fib_forward_chain_type_t fct)
Convert from a chain type to the adjacencies link type.
Definition: fib_types.c:288
fib_node_list_t fn_children
Vector of nodes that depend upon/use/share this node.
Definition: fib_node.h:290
int fib_path_is_recursive(fib_node_index_t path_index)
Definition: fib_path.c:1847
u8 * fib_path_format(fib_node_index_t pi, u8 *s)
Definition: fib_path.c:475
#define vec_free(V)
Free vector&#39;s memory (no header).
Definition: vec.h:300
#define MPLS_FIB_DEFAULT_TABLE_ID
Definition: mpls.h:33
u32 frp_weight
[un]equal cost path weight
Definition: fib_types.h:320
static void fib_path_last_lock_gone(fib_node_t *node)
Definition: fib_path.c:515
static fib_node_index_t fib_path_get_index(fib_path_t *path)
Definition: fib_path.c:336
A FIB path.
Definition: fib_path.c:150
int fib_entry_recursive_loop_detect(fib_node_index_t entry_index, fib_node_index_t **entry_indicies)
Definition: fib_entry.c:1250
fib_node_get_t fnv_get
Definition: fib_node.h:261
struct fib_path_t_::@134::@140 special
enum fib_path_oper_flags_t_ fib_path_oper_flags_t
Path flags from the attributes.
int fib_path_encode(fib_node_index_t path_list_index, fib_node_index_t path_index, void *ctx)
Definition: fib_path.c:1900
u32 fib_node_index_t
A typedef of a node index.
Definition: fib_types.h:28
#define pool_is_free_index(P, I)
Use free bitmap to query whether given index is free.
Definition: pool.h:211
u32 adj_index_t
An index for adjacencies.
Definition: adj_types.h:30
struct fib_path_t_::@134::@138 recursive
void fib_prefix_from_ip46_addr(const ip46_address_t *addr, fib_prefix_t *pfx)
Host prefix from ip.
Definition: fib_types.c:54
static void fib_path_memory_show(void)
Definition: fib_path.c:936
void dpo_set(dpo_id_t *dpo, dpo_type_t type, dpo_proto_t proto, index_t index)
Set/create a DPO ID The DPO will be locked.
Definition: dpo.c:154
static fib_node_back_walk_rc_t fib_path_back_walk_notify(fib_node_t *node, fib_node_back_walk_ctx_t *ctx)
Definition: fib_path.c:756
Context passed between object during a back walk.
Definition: fib_node.h:186
#define VLIB_CLI_COMMAND(x,...)
Definition: cli.h:154
u32 fp_pl_index
The index of the path-list to which this path belongs.
Definition: fib_path.c:159
static void fib_path_recursive_adj_update(fib_path_t *path, fib_forward_chain_type_t fct, dpo_id_t *dpo)
Definition: fib_path.c:580
static fib_forward_chain_type_t fib_path_proto_to_chain_type(fib_protocol_t proto)
Definition: fib_path.c:736
#define ASSERT(truth)
unsigned int u32
Definition: types.h:88
int fib_path_is_deag(fib_node_index_t path_index)
Definition: fib_path.c:1867
fib_node_index_t fp_via_fib
the resolving via fib.
Definition: fib_path.c:287
static int fib_path_is_permanent_drop(fib_path_t *path)
Definition: fib_path.c:669
enum vnet_link_t_ vnet_link_t
Link Type: A description of the protocol of packets on the link.
ip46_address_t fp_addr
The next-hop.
Definition: fib_path.c:267
uword hash_memory(void *p, word n_bytes, uword state)
Definition: hash.c:214
enum fib_forward_chain_type_t_ fib_forward_chain_type_t
FIB output chain type.
fib_route_path_flags_t frp_flags
flags on the path
Definition: fib_types.h:324
u32 fp_interface
The interface.
Definition: fib_path.c:201
static clib_error_t * show_fib_path_command(vlib_main_t *vm, unformat_input_t *input, vlib_cli_command_t *cmd)
Definition: fib_path.c:1959
dpo_proto_t fib_proto_to_dpo(fib_protocol_t fib_proto)
Definition: fib_types.c:220
int fib_path_get_weight(fib_node_index_t path_index)
Definition: fib_path.c:1656
u8 * format_dpo_id(u8 *s, va_list *args)
Format a DPO_id_t oject
Definition: dpo.c:118
u8 * format_fib_protocol(u8 *s, va_list ap)
Definition: fib_types.c:30
static uword vnet_sw_interface_is_admin_up(vnet_main_t *vnm, u32 sw_if_index)
u64 uword
Definition: types.h:112
format_function_t format_mpls_unicast_label
Definition: mpls.h:94
static void fib_path_unresolve(fib_path_t *path)
Definition: fib_path.c:681
mpls_label_t frp_local_label
The MPLS local Label to reursively resolve through.
Definition: fib_types.h:305
fib_path_oper_flags_t fp_oper_flags
Memebers in this last section represent information that is dervied during resolution.
Definition: fib_path.c:281
void fib_path_list_back_walk(fib_node_index_t path_list_index, fib_node_back_walk_ctx_t *ctx)
Attached-nexthop.
Definition: fib_path.c:46
u32 fib_path_get_resolving_interface(fib_node_index_t path_index)
Definition: fib_path.c:1616
index_t dpoi_index
the index of objects of that type
Definition: dpo.h:154
#define FIB_NODE_INDEX_INVALID
Definition: fib_types.h:29
unsigned char u8
Definition: types.h:56
struct fib_path_t_::@134::@142 receive
u32 path_weight
weight for the path.
Definition: load_balance.h:75
u32 adj_child_add(adj_index_t adj_index, fib_node_type_t child_type, fib_node_index_t child_index)
Add a child dependent to an adjacency.
Definition: adj.c:228
#define DPO_INVALID
An initialiser for DPOs declared on the stack.
Definition: dpo.h:165
#define FIB_PATH_DBG(_p, _fmt, _args...)
Definition: fib_path.c:326
One path from an [EU]CMP set that the client wants to add to a load-balance object.
Definition: load_balance.h:61
enum fib_path_cfg_flags_t_ fib_path_cfg_flags_t
Path config flags from the attributes.
int fib_path_recursive_loop_detect(fib_node_index_t path_index, fib_node_index_t **entry_indicies)
Definition: fib_path.c:1377
A FIB graph nodes virtual function table.
Definition: fib_node.h:260
static fib_path_cfg_flags_t fib_path_route_flags_to_cfg_flags(const fib_route_path_t *rpath)
Definition: fib_path.c:955
u8 * format(u8 *s, const char *fmt,...)
Definition: format.c:418
adj_index_t adj_nbr_add_or_lock(fib_protocol_t nh_proto, vnet_link_t link_type, const ip46_address_t *nh_addr, u32 sw_if_index)
Neighbour Adjacency sub-type.
Definition: adj_nbr.c:175
void dpo_reset(dpo_id_t *dpo)
reset a DPO ID The DPO will be unlocked.
Definition: dpo.c:191
mpls_label_t fp_local_label
The local label to resolve through.
Definition: fib_path.c:219
#define vec_foreach(var, vec)
Vector iterator.
fib_route_path_t rpath
Definition: fib_types.h:336
vnet_link_t fib_proto_to_link(fib_protocol_t proto)
Convert from a protocol to a link type.
Definition: fib_types.c:254
fib_path_type_t_
Enurmeration of path types.
Definition: fib_path.c:38
Contribute an object that is to be used to forward non-end-of-stack MPLS packets. ...
Definition: fib_types.h:90
struct _unformat_input_t unformat_input_t
u32 flags
Definition: vhost-user.h:75
u8 * fib_node_children_format(fib_node_list_t list, u8 *s)
Definition: fib_node.c:174
fib_source_t fib_entry_get_best_source(fib_node_index_t entry_index)
Definition: fib_entry.c:1311
#define ip46_address_is_zero(ip46)
Definition: ip6_packet.h:81
u32 frp_fib_index
The FIB index to lookup the nexthop Only valid for recursive paths.
Definition: fib_types.h:316
void fib_path_destroy(fib_node_index_t path_index)
Definition: fib_path.c:1148
#define FOR_EACH_FIB_PATH_CFG_ATTRIBUTE(_item)
Definition: fib_path.h:88
static int fib_path_cmp_i(const fib_path_t *path1, const fib_path_t *path2)
Definition: fib_path.c:1187
const ip46_address_t zero_addr
Definition: lookup.c:351
int fib_path_cmp_w_route_path(fib_node_index_t path_index, const fib_route_path_t *rpath)
Definition: fib_path.c:1289
static fib_node_t * fib_path_get_node(fib_node_index_t index)
Definition: fib_path.c:342
struct fib_path_t_::@134::@139 deag
fib_entry_flag_t fib_entry_get_flags(fib_node_index_t fib_entry_index)
Definition: fib_entry.c:278
static uword pool_elts(void *v)
Number of active elements in a pool.
Definition: pool.h:109