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bird/filter/data.h
Igor Putovny 977b82fba4 Basic route aggregation
Add a new protocol offering route aggregation.

User can specify list of route attributes in the configuration file and
run route aggregation on the export side of the pipe protocol. Routes are
sorted and for every group of equivalent routes new route is created and
exported to the routing table. It is also possible to specify filter
which will run for every route before aggregation.

Furthermore, it will be possible to set attributes of new routes
according to attributes of the aggregated routes.

This is a work in progress.

Original work by Igor Putovny, subsequent cleanups and finalization by
Maria Matejka.
2023-09-26 15:46:24 +02:00

358 lines
9.2 KiB
C

/*
* BIRD Internet Routing Daemon -- Dynamic data structures
*
* (c) 1999 Pavel Machek <pavel@ucw.cz>
* (c) 2018--2019 Maria Matejka <mq@jmq.cz>
*
* Can be freely distributed and used under the terms of the GNU GPL.
*/
#ifndef _BIRD_FILTER_DATA_H_
#define _BIRD_FILTER_DATA_H_
#include "nest/bird.h"
#include "nest/route.h"
/* Type numbers must be in 0..0xff range */
#define T_MASK 0xff
/* Internal types */
enum f_type {
/* Nothing. Simply nothing. */
T_VOID = 0,
T_NONE = 1, /* Special hack to represent missing arguments */
/* User visible types, which fit in int */
T_INT = 0x10,
T_BOOL = 0x11,
T_PAIR = 0x12, /* Notice that pair is stored as integer: first << 16 | second */
T_QUAD = 0x13,
/* Put enumerational types in 0x30..0x3f range */
T_ENUM_LO = 0x30,
T_ENUM_HI = 0x3f,
T_ENUM_RTS = 0x30,
T_ENUM_BGP_ORIGIN = 0x31,
T_ENUM_SCOPE = 0x32,
T_ENUM_RTC = 0x33,
T_ENUM_RTD = 0x34,
T_ENUM_ROA = 0x35,
T_ENUM_NETTYPE = 0x36,
T_ENUM_RA_PREFERENCE = 0x37,
T_ENUM_AF = 0x38,
/* new enums go here */
T_ENUM_EMPTY = 0x3f, /* Special hack for atomic_aggr */
#define T_ENUM T_ENUM_LO ... T_ENUM_HI
/* Bigger ones */
T_IP = 0x20,
T_NET = 0x21,
T_STRING = 0x22,
T_PATH_MASK = 0x23, /* mask for BGP path */
T_PATH = 0x24, /* BGP path */
T_CLIST = 0x25, /* Community list */
T_EC = 0x26, /* Extended community value, u64 */
T_ECLIST = 0x27, /* Extended community list */
T_LC = 0x28, /* Large community value, lcomm */
T_LCLIST = 0x29, /* Large community list */
T_RD = 0x2a, /* Route distinguisher for VPN addresses */
T_PATH_MASK_ITEM = 0x2b, /* Path mask item for path mask constructors */
T_BYTESTRING = 0x2c,
T_ROUTE = 0x78,
T_ROUTES_BLOCK = 0x79,
T_SET = 0x80,
T_PREFIX_SET = 0x81,
} PACKED;
struct f_method {
struct symbol *sym;
struct f_inst *(*new_inst)(struct f_inst *obj, struct f_inst *args);
const struct f_method *next;
uint arg_num;
enum f_type args_type[];
};
/* Filter value; size of this affects filter memory consumption */
struct f_val {
enum f_type type; /* T_* */
union {
uint i;
u64 ec;
lcomm lc;
ip_addr ip;
const net_addr *net;
const char *s;
const struct adata *bs;
const struct f_tree *t;
const struct f_trie *ti;
const struct adata *ad;
const struct f_path_mask *path_mask;
struct f_path_mask_item pmi;
struct rte *rte;
} val;
};
/* Dynamic attribute definition (eattrs) */
struct f_dynamic_attr {
u8 type; /* EA type (EAF_*) */
u8 bit; /* For bitfield accessors */
enum f_type f_type; /* Filter type */
uint ea_code; /* EA code */
uint flags;
};
enum f_sa_code {
SA_FROM = 1,
SA_GW,
SA_NET,
SA_PROTO,
SA_SOURCE,
SA_SCOPE,
SA_DEST,
SA_IFNAME,
SA_IFINDEX,
SA_WEIGHT,
SA_PREF,
SA_GW_MPLS,
SA_ONLINK,
} PACKED;
/* Static attribute definition (members of struct rta) */
struct f_static_attr {
enum f_type f_type; /* Filter type */
enum f_sa_code sa_code; /* Static attribute id */
int readonly:1; /* Don't allow writing */
};
/* Filter l-value type */
enum f_lval_type {
F_LVAL_VARIABLE,
F_LVAL_PREFERENCE,
F_LVAL_SA,
F_LVAL_EA,
};
/* Filter l-value */
struct f_lval {
enum f_lval_type type;
struct f_inst *rte;
union {
struct symbol *sym;
struct f_dynamic_attr da;
struct f_static_attr sa;
};
};
/* IP prefix range structure */
struct f_prefix {
net_addr net; /* The matching prefix must match this net */
u8 lo, hi; /* And its length must fit between lo and hi */
};
struct f_tree {
struct f_tree *left, *right;
struct f_val from, to;
void *data;
};
#ifdef ENABLE_COMPACT_TRIES
/* Compact 4-way tries */
#define TRIE_STEP 2
#define TRIE_STACK_LENGTH 65
#else
/* Faster 16-way tries */
#define TRIE_STEP 4
#define TRIE_STACK_LENGTH 33
#endif
struct f_trie_node4
{
ip4_addr addr, mask, accept;
u16 plen;
u16 local;
struct f_trie_node4 *c[1 << TRIE_STEP];
};
struct f_trie_node6
{
ip6_addr addr, mask, accept;
u16 plen;
u16 local;
struct f_trie_node6 *c[1 << TRIE_STEP];
};
struct f_trie_node
{
union {
struct f_trie_node4 v4;
struct f_trie_node6 v6;
};
};
struct f_trie
{
linpool *lp;
u8 zero;
s8 ipv4; /* -1 for undefined / empty */
u16 data_size; /* Additional data for each trie node */
u32 prefix_count; /* Works only for restricted tries (pxlen == l == h) */
struct f_trie_node root; /* Root trie node */
};
struct f_trie_walk_state
{
u8 ipv4;
u8 accept_length; /* Current inter-node prefix position */
u8 start_pos; /* Initial prefix position in stack[0] */
u8 local_pos; /* Current intra-node prefix position */
u8 stack_pos; /* Current node in stack below */
const struct f_trie_node *stack[TRIE_STACK_LENGTH];
};
struct f_tree *f_new_tree(void);
struct f_tree *build_tree(struct f_tree *);
const struct f_tree *find_tree(const struct f_tree *t, const struct f_val *val);
const struct f_tree *find_tree_linear(const struct f_tree *t, const struct f_val *val);
int same_tree(const struct f_tree *t0, const struct f_tree *t2);
int tree_node_count(const struct f_tree *t);
void tree_format(const struct f_tree *t, buffer *buf);
void tree_walk(const struct f_tree *t, void (*hook)(const struct f_tree *, void *), void *data);
struct f_trie *f_new_trie(linpool *lp, uint data_size);
void *trie_add_prefix(struct f_trie *t, const net_addr *n, uint l, uint h);
int trie_match_net(const struct f_trie *t, const net_addr *n);
int trie_match_longest_ip4(const struct f_trie *t, const net_addr_ip4 *net, net_addr_ip4 *dst, ip4_addr *found0);
int trie_match_longest_ip6(const struct f_trie *t, const net_addr_ip6 *net, net_addr_ip6 *dst, ip6_addr *found0);
void trie_walk_init(struct f_trie_walk_state *s, const struct f_trie *t, const net_addr *from);
int trie_walk_next(struct f_trie_walk_state *s, net_addr *net);
int trie_same(const struct f_trie *t1, const struct f_trie *t2);
void trie_format(const struct f_trie *t, buffer *buf);
static inline int
trie_match_next_longest_ip4(net_addr_ip4 *n, ip4_addr *found)
{
while (n->pxlen)
{
n->pxlen--;
ip4_clrbit(&n->prefix, n->pxlen);
if (ip4_getbit(*found, n->pxlen))
return 1;
}
return 0;
}
static inline int
trie_match_next_longest_ip6(net_addr_ip6 *n, ip6_addr *found)
{
while (n->pxlen)
{
n->pxlen--;
ip6_clrbit(&n->prefix, n->pxlen);
if (ip6_getbit(*found, n->pxlen))
return 1;
}
return 0;
}
#define TRIE_WALK_TO_ROOT_IP4(trie, net, dst) ({ \
net_addr_ip4 dst; \
ip4_addr _found; \
for (int _n = trie_match_longest_ip4(trie, net, &dst, &_found); \
_n; \
_n = trie_match_next_longest_ip4(&dst, &_found))
#define TRIE_WALK_TO_ROOT_IP6(trie, net, dst) ({ \
net_addr_ip6 dst; \
ip6_addr _found; \
for (int _n = trie_match_longest_ip6(trie, net, &dst, &_found); \
_n; \
_n = trie_match_next_longest_ip6(&dst, &_found))
#define TRIE_WALK_TO_ROOT_END })
#define TRIE_WALK(trie, net, from) ({ \
net_addr net; \
struct f_trie_walk_state tws_; \
trie_walk_init(&tws_, trie, from); \
while (trie_walk_next(&tws_, &net))
#define TRIE_WALK_END })
#define F_CMP_ERROR 999
const char *f_type_name(enum f_type t);
enum f_type f_type_element_type(enum f_type t);
struct sym_scope *f_type_method_scope(enum f_type t);
int val_same(const struct f_val *v1, const struct f_val *v2);
int val_compare(const struct f_val *v1, const struct f_val *v2);
void val_format(const struct f_val *v, buffer *buf);
char *val_format_str(struct linpool *lp, const struct f_val *v);
const char *val_dump(const struct f_val *v);
static inline int val_is_ip4(const struct f_val *v)
{ return (v->type == T_IP) && ipa_is_ip4(v->val.ip); }
int val_in_range(const struct f_val *v1, const struct f_val *v2);
int clist_set_type(const struct f_tree *set, struct f_val *v);
static inline int eclist_set_type(const struct f_tree *set)
{ return !set || set->from.type == T_EC; }
static inline int lclist_set_type(const struct f_tree *set)
{ return !set || set->from.type == T_LC; }
static inline int path_set_type(const struct f_tree *set)
{ return !set || set->from.type == T_INT; }
int clist_match_set(const struct adata *clist, const struct f_tree *set);
int eclist_match_set(const struct adata *list, const struct f_tree *set);
int lclist_match_set(const struct adata *list, const struct f_tree *set);
const struct adata *clist_filter(struct linpool *pool, const struct adata *list, const struct f_val *set, int pos);
const struct adata *eclist_filter(struct linpool *pool, const struct adata *list, const struct f_val *set, int pos);
const struct adata *lclist_filter(struct linpool *pool, const struct adata *list, const struct f_val *set, int pos);
/* Special undef value for paths and clists */
static inline int
val_is_undefined(struct f_val v)
{
return ((v.type == T_PATH) || (v.type == T_CLIST) ||
(v.type == T_ECLIST) || (v.type == T_LCLIST)) &&
(v.val.ad == &null_adata);
}
static inline struct f_val
val_empty(enum f_type t)
{
switch (t)
{
case T_PATH:
case T_CLIST:
case T_ECLIST:
case T_LCLIST:
return (struct f_val) { .type = t, .val.ad = &null_adata };
default:
return (struct f_val) { };
}
}
extern const struct f_val f_const_empty_prefix_set;
enum filter_return f_eval(const struct f_line *expr, struct linpool *tmp_pool, struct f_val *pres);
#endif